From c447e3236d62724ba62d5a15dd1856ddf4201e41 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Tue, 26 Nov 2024 14:54:54 +0000 Subject: [PATCH 01/62] Update structure files for Structure Prediction test --- smact/tests/files/BaTiO3.txt | 66 ++--- smact/tests/files/CaTiO3.json | 191 ++++--------- smact/tests/files/CaTiO3.txt | 66 ++--- smact/tests/files/Fe.json | 1 + smact/tests/files/Fe.txt | 23 +- smact/tests/files/NaCl.json | 77 ++--- smact/tests/files/NaCl.txt | 20 +- smact/tests/files/pymatgen_structure.json | 334 ++++------------------ 8 files changed, 197 insertions(+), 581 deletions(-) create mode 100644 smact/tests/files/Fe.json diff --git a/smact/tests/files/BaTiO3.txt b/smact/tests/files/BaTiO3.txt index 84d23ec1..59da009b 100644 --- a/smact/tests/files/BaTiO3.txt +++ b/smact/tests/files/BaTiO3.txt @@ -1,48 +1,18 @@ -Ba2+ O2- Ti4+ -1.0 -7.71822632 0.0 0.07082158 -0.0 7.69401223 0.0 -0.07013077 0.0 7.71818196 -Ba O Ti -8 24 8 -Cartesian -5.938787271848143 5.770509172500001 2.184426135563748 Ba2+ -1.849569818151858 1.9235030575 5.604577404436252 Ba2+ -6.042561344869289 5.770509172500001 5.974003334886483 Ba2+ -1.7457957451307116 1.9235030575 1.815000205113517 Ba2+ -2.149293645049691 5.770509172500001 2.079409903401527 Ba2+ -5.63906344495031 1.9235030575 5.709593636598473 Ba2+ -2.1139442657406273 5.770509172500001 6.0080541125384315 Ba2+ -5.674412824259374 1.9235030575 1.7809494274615678 Ba2+ -3.5182267106260987 5.770509172500001 4.116287280059122 O2- -4.270130379373902 1.9235030575 3.672716259940878 O2- -4.150288174580298 5.770509172500001 7.377628882334052 O2- -3.6380689154197015 1.9235030575 0.4113746576659486 O2- -1.9301472280032608 7.378577963822165 0.3290122369887006 O2- -5.858209861996739 3.531571848822165 7.459991303011299 O2- -5.858209861996739 0.3154342661778351 7.459991303011299 O2- -1.9301472280032608 4.162440381177835 0.3290122369887006 O2- -4.187787146051468 7.37790773841681 1.9655674805225338 O2- -3.600569943948532 3.53090162341681 5.823436059477466 O2- -3.600569943948532 0.31610449158319043 5.823436059477466 O2- -4.187787146051468 4.16311060658319 1.9655674805225338 O2- -1.9640703531513992 0.31591891200820277 3.565606811910167 O2- -5.824286736848601 4.162925027008203 4.223396728089832 O2- -5.824286736848601 7.378093317991797 4.223396728089832 O2- -1.9640703531513992 3.531087202991797 3.565606811910167 O2- -0.44564748892417344 1.9235030575 7.497110111270531 O2- -7.342709601075827 5.770509172500001 0.2918934287294692 O2- -7.531378069520844 1.9235030575 4.305417205759414 O2- -0.25697902047915583 5.770509172500001 3.4835863342405866 O2- -7.424394483143924 3.5316806421550972 1.9997850771214472 O2- -0.3639626068560765 7.378686757155097 5.789218462878553 O2- -0.3639626068560765 4.162331587844903 5.789218462878553 O2- -7.424394483143924 0.3153254728449029 1.9997850771214472 O2- -3.894178545 3.847006115 3.8945017699999998 Ti4+ -3.894178545 0.0 3.8945017699999998 Ti4+ -0.035065385 3.847006115 3.85909098 Ti4+ -0.035065385 0.0 3.85909098 Ti4+ -3.85911316 3.847006115 0.03541079 Ti4+ -3.85911316 0.0 0.03541079 Ti4+ -0.0 3.847006115 0.0 Ti4+ -0.0 0.0 0.0 Ti4+ +Ba2+ O2- Ti4+ +1.0 +5.287674 -2.670508 0.0 +5.287674 2.670508 0.0 +3.93895 0.0 4.424453 +Ba O Ti +2 6 2 +Cartesian +9.240948736342 6.062109608251377e-17 2.8169563115870004 Ba2+ +5.273349263658 4.9761495873212886e-17 1.6074966884130002 Ba2+ +7.807412346486 1.0122213407960001 4.306620967704 O2- +8.357867072605998 -2.1021357708359996 2.500868964814 O2- +5.645214628605999 -1.0899144300399997 3.600615426947 O2- +8.869083371394 1.08991443004 0.823837573053 O2- +6.156430927393999 2.1021357708359996 1.923584035186 O2- +6.706885653513999 -1.0122213407959997 0.11783203229599999 O2- +12.348663138314 2.6002918693279753e-16 3.7642936412290005 Ti4+ +2.1656348616859997 1.752656922349161e-17 0.660159358771 Ti4+ diff --git a/smact/tests/files/CaTiO3.json b/smact/tests/files/CaTiO3.json index 2d032747..735342ca 100644 --- a/smact/tests/files/CaTiO3.json +++ b/smact/tests/files/CaTiO3.json @@ -4,159 +4,90 @@ "charge": 0, "lattice": { "matrix": [ - [5.40776, 0.0, 3.311297987278545e-16], - [8.856621316385947e-16, 5.507429, 3.3723276481906544e-16], - [0.0, 0.0, 7.694012] + [5.287674, -2.670508, 0.0], + [5.287674, 2.670508, 0.0], + [3.93895, 0.0, 4.424453] ], "pbc": [true, true, true], - "a": 5.40776, - "b": 5.507429, - "c": 7.694012, - "alpha": 90.0, - "beta": 90.0, - "gamma": 90.0, - "volume": 229.14963798636475 + "a": 5.923774920465834, + "b": 5.923774920465834, + "c": 5.923775101378259, + "alpha": 53.59156916755366, + "beta": 53.59156916755366, + "gamma": 53.5915681815752, + "volume": 124.95341697913328 }, + "properties": {}, "sites": [ { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.509094, 0.542875, 0.75], - "xyz": [2.7530581694400005, 2.989845518375, 5.7705090000000006], - "label": "Ca2+", - "properties": {} + "species": [{ "element": "Ca", "occu": 1 }], + "abc": [0.6366789999999999, 0.6366789999999999, 0.6366790000000001], + "properties": {}, + "label": "Ca", + "xyz": [9.240948736342, 6.062109608251377e-17, 2.8169563115870004] }, { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.49090599999999995, 0.457125, 0.25], - "xyz": [2.65470183056, 2.517583481625, 1.9235030000000002], - "label": "Ca2+", - "properties": {} + "species": [{ "element": "Ca", "occu": 1 }], + "abc": [0.36332099999999995, 0.36332099999999995, 0.36332100000000006], + "properties": {}, + "label": "Ca", + "xyz": [5.273349263658, 4.9761495873212886e-17, 1.6074966884130002] }, { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.990906, 0.042874999999999996, 0.75], - "xyz": [5.3585818305599995, 0.23613101837499997, 5.7705090000000006], - "label": "Ca2+", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.18620099999999998, 0.565238, 0.9733680000000001], + "properties": {}, + "label": "O", + "xyz": [7.807412346486, 1.0122213407960001, 4.306620967704] }, { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.009094000000000158, 0.957125, 0.25], - "xyz": [0.049178169440001696, 5.2712979816250005, 1.9235030000000002], - "label": "Ca2+", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.9733679999999998, 0.18620099999999995, 0.565238], + "properties": {}, + "label": "O", + "xyz": [8.357867072605998, -2.1021357708359996, 2.500868964814] }, { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.0, 0.5, 0.5], - "xyz": [4.4283106581929737e-16, 2.7537145, 3.847006], - "label": "Ti4+", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.4347619999999998, 0.026631999999999944, 0.813799], + "properties": {}, + "label": "O", + "xyz": [5.645214628605999, -1.0899144300399997, 3.600615426947] }, { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.0, 0.5, 0.0], - "xyz": [4.4283106581929737e-16, 2.7537145, 1.6861638240953272e-16], - "label": "Ti4+", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.5652379999999999, 0.9733679999999999, 0.186201], + "properties": {}, + "label": "O", + "xyz": [8.869083371394, 1.08991443004, 0.823837573053] }, { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.5, 0.0, 0.5], - "xyz": [2.70388, 0.0, 3.847006], - "label": "Ti4+", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.02663199999999999, 0.8137989999999999, 0.43476200000000004], + "properties": {}, + "label": "O", + "xyz": [6.156430927393999, 2.1021357708359996, 1.923584035186] }, { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.5, 0.0, 0.0], - "xyz": [2.70388, 0.0, 1.6556489936392726e-16], - "label": "Ti4+", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.8137989999999999, 0.4347619999999999, 0.026632], + "properties": {}, + "label": "O", + "xyz": [6.706885653513999, -1.0122213407959997, 0.11783203229599999] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.078086, 0.480194, 0.75], - "xyz": [0.4222703473600004, 2.644634361226, 5.770509], - "label": "O2-", - "properties": {} + "species": [{ "element": "Ti", "occu": 1 }], + "abc": [0.8507929999999999, 0.850793, 0.8507930000000001], + "properties": {}, + "label": "Ti", + "xyz": [12.348663138314, 2.6002918693279753e-16, 3.7642936412290005] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.921914, 0.519806, 0.25], - "xyz": [4.985489652640001, 2.862794638774, 1.9235030000000004], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.421914, 0.980194, 0.75], - "xyz": [2.2816096526400007, 5.398348861226, 5.7705090000000006], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.578086, 0.01980599999999999, 0.25], - "xyz": [3.12615034736, 0.10908013877399995, 1.9235030000000002], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.790623, 0.790038, 0.9589710000000002], - "xyz": [4.27549943448, 4.351078192302, 7.378334381652002], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.20937700000000004, 0.20996199999999998, 0.45897100000000024], - "xyz": [1.1322605655200004, 1.156350807698, 3.531328381652002], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.20937700000000004, 0.20996199999999998, 0.04102899999999976], - "xyz": [1.1322605655200004, 1.156350807698, 0.3156776183479983], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.790623, 0.790038, 0.5410289999999998], - "xyz": [4.27549943448, 4.351078192302, 4.162683618347999], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.709377, 0.290038, 0.9589710000000002], - "xyz": [3.8361405655200005, 1.597363692302, 7.378334381652002], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.2906230000000001, 0.709962, 0.45897100000000024], - "xyz": [1.571619434480001, 3.910065307698, 3.5313283816520022], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.2906230000000001, 0.709962, 0.04102899999999976], - "xyz": [1.571619434480001, 3.910065307698, 0.31567761834799846], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.709377, 0.290038, 0.5410289999999998], - "xyz": [3.8361405655200005, 1.597363692302, 4.162683618347998], - "label": "O2-", - "properties": {} + "species": [{ "element": "Ti", "occu": 1 }], + "abc": [0.14920699999999998, 0.14920699999999998, 0.149207], + "properties": {}, + "label": "Ti", + "xyz": [2.1656348616859997, 1.752656922349161e-17, 0.660159358771] } ] } diff --git a/smact/tests/files/CaTiO3.txt b/smact/tests/files/CaTiO3.txt index 3916cdea..aea3e2d0 100644 --- a/smact/tests/files/CaTiO3.txt +++ b/smact/tests/files/CaTiO3.txt @@ -1,48 +1,18 @@ -Ca2+ O2- Ti4+ -1.0 -7.71822632 0.0 0.07082158 -0.0 7.69401223 0.0 -0.07013077 0.0 7.71818196 -Ca O Ti -8 24 8 -Cartesian -5.938787271848143 5.770509172500001 2.184426135563748 Ca2+ -1.849569818151858 1.9235030575 5.604577404436252 Ca2+ -6.042561344869289 5.770509172500001 5.974003334886483 Ca2+ -1.7457957451307116 1.9235030575 1.815000205113517 Ca2+ -2.149293645049691 5.770509172500001 2.079409903401527 Ca2+ -5.63906344495031 1.9235030575 5.709593636598473 Ca2+ -2.1139442657406273 5.770509172500001 6.0080541125384315 Ca2+ -5.674412824259374 1.9235030575 1.7809494274615678 Ca2+ -3.5182267106260987 5.770509172500001 4.116287280059122 O2- -4.270130379373902 1.9235030575 3.672716259940878 O2- -4.150288174580298 5.770509172500001 7.377628882334052 O2- -3.6380689154197015 1.9235030575 0.4113746576659486 O2- -1.9301472280032608 7.378577963822165 0.3290122369887006 O2- -5.858209861996739 3.531571848822165 7.459991303011299 O2- -5.858209861996739 0.3154342661778351 7.459991303011299 O2- -1.9301472280032608 4.162440381177835 0.3290122369887006 O2- -4.187787146051468 7.37790773841681 1.9655674805225338 O2- -3.600569943948532 3.53090162341681 5.823436059477466 O2- -3.600569943948532 0.31610449158319043 5.823436059477466 O2- -4.187787146051468 4.16311060658319 1.9655674805225338 O2- -1.9640703531513992 0.31591891200820277 3.565606811910167 O2- -5.824286736848601 4.162925027008203 4.223396728089832 O2- -5.824286736848601 7.378093317991797 4.223396728089832 O2- -1.9640703531513992 3.531087202991797 3.565606811910167 O2- -0.44564748892417344 1.9235030575 7.497110111270531 O2- -7.342709601075827 5.770509172500001 0.2918934287294692 O2- -7.531378069520844 1.9235030575 4.305417205759414 O2- -0.25697902047915583 5.770509172500001 3.4835863342405866 O2- -7.424394483143924 3.5316806421550972 1.9997850771214472 O2- -0.3639626068560765 7.378686757155097 5.789218462878553 O2- -0.3639626068560765 4.162331587844903 5.789218462878553 O2- -7.424394483143924 0.3153254728449029 1.9997850771214472 O2- -3.894178545 3.847006115 3.8945017699999998 Ti4+ -3.894178545 0.0 3.8945017699999998 Ti4+ -0.035065385 3.847006115 3.85909098 Ti4+ -0.035065385 0.0 3.85909098 Ti4+ -3.85911316 3.847006115 0.03541079 Ti4+ -3.85911316 0.0 0.03541079 Ti4+ -0.0 3.847006115 0.0 Ti4+ -0.0 0.0 0.0 Ti4+ +Ca2+ O2- Ti4+ +1.0 +5.287674 -2.670508 0.0 +5.287674 2.670508 0.0 +3.93895 0.0 4.424453 +Ca O Ti +2 6 2 +Cartesian +9.240948736342 -8.69821668629811e-17 2.816956311587 Ca2+ +5.273349263658 -2.4040135599534552e-17 1.607496688413 Ca2+ +7.807412346486 1.012221340796 4.306620967704 O2- +8.357867072606 -2.102135770836 2.500868964814 O2- +5.645214628606 -1.0899144300399999 3.600615426947 O2- +8.869083371394 1.0899144300399999 0.823837573053 O2- +6.156430927394 2.102135770836 1.9235840351859999 O2- +6.706885653514 -1.0122213407960001 0.11783203229599999 O2- +12.348663138314 -1.840600229172651e-16 3.764293641229 Ti4+ +2.165634861686 -1.937424651288211e-17 0.660159358771 Ti4+ diff --git a/smact/tests/files/Fe.json b/smact/tests/files/Fe.json new file mode 100644 index 00000000..d335f1ce --- /dev/null +++ b/smact/tests/files/Fe.json @@ -0,0 +1 @@ +{"@module": "pymatgen.core.structure", "@class": "Structure", "charge": 0, "lattice": {"matrix": [[-0.0, -0.0, -2.39034144], [-1.24450189, -2.15554064, -0.0], [-1.24450189, 2.15554064, 0.0]], "pbc": [true, true, true], "a": 2.39034144, "b": 2.489003898129768, "c": 2.489003898129768, "alpha": 120.00000313997197, "beta": 90.0, "gamma": 90.0, "volume": 12.824537510566229}, "properties": {}, "sites": [{"species": [{"element": "Fe", "occu": 1}], "abc": [0.0, 0.0, 0.0], "properties": {}, "label": "Fe", "xyz": [0.0, 0.0, 0.0]}]} \ No newline at end of file diff --git a/smact/tests/files/Fe.txt b/smact/tests/files/Fe.txt index 1104dc8f..81185cdb 100644 --- a/smact/tests/files/Fe.txt +++ b/smact/tests/files/Fe.txt @@ -1,14 +1,9 @@ -Fe -1.0 -3.27376712 2e-08 -0.74680411 --0.17035922 3.26933155 -0.74680411 --0.00674311 -0.00710363 7.51945303 -Fe -6 -Cartesian -1.2021739034199286 2.99084763042396 5.269972870731059 Fe -1.8944908865800711 0.27138030957603954 0.7558719392689416 Fe -0.17242771658007133 1.9060460745760393 0.7558719392689416 Fe -2.4093639799999997 0.8137810875 3.0129224050000003 Fe -2.924237073419929 1.3561818654239604 5.269972870731059 Fe -0.68730081 2.4484468525 3.0129224050000003 Fe +Fe +1.0 +-0.0 -0.0 -2.39034144 +-1.24450189 -2.15554064 -0.0 +-1.24450189 2.15554064 0.0 +Fe +1 +Cartesian +0.0 0.0 0.0 Fe diff --git a/smact/tests/files/NaCl.json b/smact/tests/files/NaCl.json index eab7ce63..e83489ee 100644 --- a/smact/tests/files/NaCl.json +++ b/smact/tests/files/NaCl.json @@ -4,77 +4,34 @@ "charge": 0, "lattice": { "matrix": [ - [5.691694000000001, 0.0, 3.4851574194130984e-16], - [9.152942036428614e-16, 5.691694000000001, 3.4851574194130984e-16], - [0.0, 0.0, 5.691694000000001] + [3.50219, 0.0, 0.0], + [0.0, 3.50219, 0.0], + [0.0, 0.0, 3.50219] ], "pbc": [true, true, true], - "a": 5.691694000000001, - "b": 5.691694000000001, - "c": 5.691694000000001, + "a": 3.50219, + "b": 3.50219, + "c": 3.50219, "alpha": 90.0, "beta": 90.0, "gamma": 90.0, - "volume": 184.3845933297478 + "volume": 42.955532869553466 }, + "properties": {}, "sites": [ { - "species": [{ "element": "Na", "oxidation_state": 1, "occu": 1 }], - "abc": [0.0, 0.0, 0.0], - "xyz": [0.0, 0.0, 0.0], - "label": "Na+", - "properties": {} - }, - { - "species": [{ "element": "Na", "oxidation_state": 1, "occu": 1 }], - "abc": [0.0, 0.5, 0.5], - "xyz": [4.576471018214307e-16, 2.8458470000000005, 2.8458470000000005], - "label": "Na+", - "properties": {} - }, - { - "species": [{ "element": "Na", "oxidation_state": 1, "occu": 1 }], - "abc": [0.5, 0.0, 0.5], - "xyz": [2.8458470000000005, 0.0, 2.8458470000000005], - "label": "Na+", - "properties": {} - }, - { - "species": [{ "element": "Na", "oxidation_state": 1, "occu": 1 }], - "abc": [0.5, 0.5, 0.0], - "xyz": [2.845847000000001, 2.8458470000000005, 3.4851574194130984e-16], - "label": "Na+", - "properties": {} - }, - { - "species": [{ "element": "Cl", "oxidation_state": -1, "occu": 1 }], - "abc": [0.5, 0.0, 0.0], - "xyz": [2.8458470000000005, 0.0, 1.7425787097065492e-16], - "label": "Cl-", - "properties": {} - }, - { - "species": [{ "element": "Cl", "oxidation_state": -1, "occu": 1 }], + "species": [{ "element": "Cl", "occu": 1 }], "abc": [0.5, 0.5, 0.5], - "xyz": [2.845847000000001, 2.8458470000000005, 2.845847000000001], - "label": "Cl-", - "properties": {} + "properties": {}, + "label": "Cl", + "xyz": [1.751095, 1.751095, 1.751095] }, { - "species": [{ "element": "Cl", "oxidation_state": -1, "occu": 1 }], - "abc": [0.0, 0.0, 0.5], - "xyz": [0.0, 0.0, 2.8458470000000005], - "label": "Cl-", - "properties": {} - }, - { - "species": [{ "element": "Cl", "oxidation_state": -1, "occu": 1 }], - "abc": [0.0, 0.5, 0.0], - "xyz": [ - 4.576471018214307e-16, 2.8458470000000005, 1.7425787097065492e-16 - ], - "label": "Cl-", - "properties": {} + "species": [{ "element": "Na", "occu": 1 }], + "abc": [0.0, 0.0, 0.0], + "properties": {}, + "label": "Na", + "xyz": [0.0, 0.0, 0.0] } ] } diff --git a/smact/tests/files/NaCl.txt b/smact/tests/files/NaCl.txt index b57b3883..1f9b222c 100644 --- a/smact/tests/files/NaCl.txt +++ b/smact/tests/files/NaCl.txt @@ -1,10 +1,10 @@ -Cl1- Na1+ -1.0 -3.48543625 0.0 2.01231756 -1.16181208 3.28610081 2.01231756 -0.0 0.0 4.02463512 -Cl Na -1 1 -Cartesian -2.323624165 1.643050405 4.02463512 Cl1- -0.0 0.0 0.0 Na1+ +Cl1- Na1+ +1.0 +3.50219 0.0 0.0 +0.0 3.50219 0.0 +0.0 0.0 3.50219 +Cl Na +1 1 +Cartesian +1.751095 1.751095 1.751095 Cl1- +0.0 0.0 0.0 Na1+ diff --git a/smact/tests/files/pymatgen_structure.json b/smact/tests/files/pymatgen_structure.json index b6a5e582..735342ca 100644 --- a/smact/tests/files/pymatgen_structure.json +++ b/smact/tests/files/pymatgen_structure.json @@ -1,301 +1,93 @@ { "@module": "pymatgen.core.structure", "@class": "Structure", - "charge": null, + "charge": 0, "lattice": { "matrix": [ - [7.71822632, 0.0, 0.07082158], - [0.0, 7.69401223, 0.0], - [0.07013077, 0.0, 7.71818196] + [5.287674, -2.670508, 0.0], + [5.287674, 2.670508, 0.0], + [3.93895, 0.0, 4.424453] ], - "a": 7.718551238602646, - "b": 7.69401223, - "c": 7.718500572816604, - "alpha": 90.0, - "beta": 88.9536749677567, - "gamma": 90.0, - "volume": 458.2992887203482 + "pbc": [true, true, true], + "a": 5.923774920465834, + "b": 5.923774920465834, + "c": 5.923775101378259, + "alpha": 53.59156916755366, + "beta": 53.59156916755366, + "gamma": 53.5915681815752, + "volume": 124.95341697913328 }, + "properties": {}, "sites": [ { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.4510252, 0.75, 0.52918485], - "xyz": [3.5182267106260987, 5.770509172500001, 4.116287280059122], - "label": "O2-", - "properties": {} + "species": [{ "element": "Ca", "occu": 1 }], + "abc": [0.6366789999999999, 0.6366789999999999, 0.6366790000000001], + "properties": {}, + "label": "Ca", + "xyz": [9.240948736342, 6.062109608251377e-17, 2.8169563115870004] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.5489748, 0.25, 0.47081515], - "xyz": [4.270130379373902, 1.9235030575, 3.672716259940878], - "label": "O2-", - "properties": {} + "species": [{ "element": "Ca", "occu": 1 }], + "abc": [0.36332099999999995, 0.36332099999999995, 0.36332100000000006], + "properties": {}, + "label": "Ca", + "xyz": [5.273349263658, 4.9761495873212886e-17, 1.6074966884130002] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.52908429, 0.75, 0.95102167], - "xyz": [4.150288174580298, 5.770509172500001, 7.377628882334052], - "label": "O2-", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.18620099999999998, 0.565238, 0.9733680000000001], + "properties": {}, + "label": "O", + "xyz": [7.807412346486, 1.0122213407960001, 4.306620967704] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.47091571, 0.25, 0.04897833], - "xyz": [3.6380689154197015, 1.9235030575, 0.4113746576659486], - "label": "O2-", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.9733679999999998, 0.18620099999999995, 0.565238], + "properties": {}, + "label": "O", + "xyz": [8.357867072605998, -2.1021357708359996, 2.500868964814] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.24971001, 0.95900263, 0.04033688], - "xyz": [1.9301472280032608, 7.378577963822165, 0.3290122369887006], - "label": "O2-", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.4347619999999998, 0.026631999999999944, 0.813799], + "properties": {}, + "label": "O", + "xyz": [5.645214628605999, -1.0899144300399997, 3.600615426947] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.75028999, 0.45900263, 0.95966312], - "xyz": [5.858209861996739, 3.531571848822165, 7.459991303011299], - "label": "O2-", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.5652379999999999, 0.9733679999999999, 0.186201], + "properties": {}, + "label": "O", + "xyz": [8.869083371394, 1.08991443004, 0.823837573053] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.75028999, 0.04099737, 0.95966312], - "xyz": [5.858209861996739, 0.3154342661778351, 7.459991303011299], - "label": "O2-", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.02663199999999999, 0.8137989999999999, 0.43476200000000004], + "properties": {}, + "label": "O", + "xyz": [6.156430927393999, 2.1021357708359996, 1.923584035186] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.24971001, 0.54099737, 0.04033688], - "xyz": [1.9301472280032608, 4.162440381177835, 0.3290122369887006], - "label": "O2-", - "properties": {} + "species": [{ "element": "O", "occu": 1 }], + "abc": [0.8137989999999999, 0.4347619999999999, 0.026632], + "properties": {}, + "label": "O", + "xyz": [6.706885653513999, -1.0122213407959997, 0.11783203229599999] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.54031518, 0.95891552, 0.24970926], - "xyz": [4.187787146051468, 7.37790773841681, 1.9655674805225338], - "label": "O2-", - "properties": {} + "species": [{ "element": "Ti", "occu": 1 }], + "abc": [0.8507929999999999, 0.850793, 0.8507930000000001], + "properties": {}, + "label": "Ti", + "xyz": [12.348663138314, 2.6002918693279753e-16, 3.7642936412290005] }, { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.45968482, 0.45891552, 0.75029074], - "xyz": [3.600569943948532, 3.53090162341681, 5.823436059477466], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.45968482, 0.04108448, 0.75029074], - "xyz": [3.600569943948532, 0.31610449158319043, 5.823436059477466], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.54031518, 0.54108448, 0.24970926], - "xyz": [4.187787146051468, 4.16311060658319, 1.9655674805225338], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.25029491, 0.04106036, 0.45967827], - "xyz": [1.9640703531513992, 0.31591891200820277, 3.565606811910167], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.74970509, 0.54106036, 0.54032173], - "xyz": [5.824286736848601, 4.162925027008203, 4.223396728089832], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.74970509, 0.95893964, 0.54032173], - "xyz": [5.824286736848601, 7.378093317991797, 4.223396728089832], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.25029491, 0.45893964, 0.45967827], - "xyz": [1.9640703531513992, 3.531087202991797, 3.565606811910167], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.04891758, 0.25, 0.97090814], - "xyz": [0.44564748892417344, 1.9235030575, 7.497110111270531], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.95108242, 0.75, 0.02909186], - "xyz": [7.342709601075827, 5.770509172500001, 0.2918934287294692], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.9708036, 0.25, 0.54891986], - "xyz": [7.531378069520844, 1.9235030575, 4.305417205759414], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.0291964, 0.75, 0.45108014], - "xyz": [0.25697902047915583, 5.770509172500001, 3.4835863342405866], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.95965586, 0.45901677, 0.25029479], - "xyz": [7.424394483143924, 3.5316806421550972, 1.9997850771214472], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.04034414, 0.95901677, 0.74970521], - "xyz": [0.3639626068560765, 7.378686757155097, 5.789218462878553], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.04034414, 0.54098323, 0.74970521], - "xyz": [0.3639626068560765, 4.162331587844903, 5.789218462878553], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "O", "oxidation_state": -2, "occu": 1 }], - "abc": [0.95965586, 0.04098323, 0.25029479], - "xyz": [7.424394483143924, 0.3153254728449029, 1.9997850771214472], - "label": "O2-", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.76694203, 0.75, 0.27598599], - "xyz": [5.938787271848143, 5.770509172500001, 2.184426135563748], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.23305797, 0.25, 0.72401401], - "xyz": [1.849569818151858, 1.9235030575, 5.604577404436252], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.77592675, 0.75, 0.76689705], - "xyz": [6.042561344869289, 5.770509172500001, 5.974003334886483], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.22407325, 0.25, 0.23310295], - "xyz": [1.7457957451307116, 1.9235030575, 1.815000205113517], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.27604488, 0.75, 0.26688409], - "xyz": [2.149293645049691, 5.770509172500001, 2.079409903401527], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.72395512, 0.25, 0.73311591], - "xyz": [5.63906344495031, 1.9235030575, 5.709593636598473], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.26683905, 0.75, 0.77598017], - "xyz": [2.1139442657406273, 5.770509172500001, 6.0080541125384315], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ca", "oxidation_state": 2, "occu": 1 }], - "abc": [0.73316095, 0.25, 0.22401983], - "xyz": [5.674412824259374, 1.9235030575, 1.7809494274615678], - "label": "Ca2+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.5, 0.5, 0.5], - "xyz": [3.894178545, 3.847006115, 3.8945017699999998], - "label": "Ti4+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.5, 0.0, 0.5], - "xyz": [3.894178545, 0.0, 3.8945017699999998], - "label": "Ti4+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.0, 0.5, 0.5], - "xyz": [0.035065385, 3.847006115, 3.85909098], - "label": "Ti4+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.0, 0.0, 0.5], - "xyz": [0.035065385, 0.0, 3.85909098], - "label": "Ti4+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.5, 0.5, 0.0], - "xyz": [3.85911316, 3.847006115, 0.03541079], - "label": "Ti4+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.5, 0.0, 0.0], - "xyz": [3.85911316, 0.0, 0.03541079], - "label": "Ti4+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.0, 0.5, 0.0], - "xyz": [0.0, 3.847006115, 0.0], - "label": "Ti4+", - "properties": {} - }, - { - "species": [{ "element": "Ti", "oxidation_state": 4, "occu": 1 }], - "abc": [0.0, 0.0, 0.0], - "xyz": [0.0, 0.0, 0.0], - "label": "Ti4+", - "properties": {} + "species": [{ "element": "Ti", "occu": 1 }], + "abc": [0.14920699999999998, 0.14920699999999998, 0.149207], + "properties": {}, + "label": "Ti", + "xyz": [2.1656348616859997, 1.752656922349161e-17, 0.660159358771] } ] } From df02d8a1c7fd5bbeacf13098a61a3c91bdce55d3 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Tue, 26 Nov 2024 14:55:45 +0000 Subject: [PATCH 02/62] Fix routine of getting a SmactStructure from the Materials Project --- smact/structure_prediction/structure.py | 45 +++++++++++++++---------- 1 file changed, 28 insertions(+), 17 deletions(-) diff --git a/smact/structure_prediction/structure.py b/smact/structure_prediction/structure.py index 02e4da1a..fa578329 100644 --- a/smact/structure_prediction/structure.py +++ b/smact/structure_prediction/structure.py @@ -2,6 +2,7 @@ from __future__ import annotations +import os import re from collections import defaultdict from functools import reduce @@ -11,6 +12,7 @@ import numpy as np import pymatgen from pymatgen.analysis.bond_valence import BVAnalyzer +from pymatgen.core import SETTINGS from pymatgen.ext.matproj import MPRester from pymatgen.transformations.standard_transformations import ( OxidationStateDecorationTransformation, @@ -18,7 +20,7 @@ import smact -from .utilities import convert_next_gen_mprest_data, get_sign +from .utilities import get_sign class SmactStructure: @@ -106,6 +108,7 @@ def __eq__(self, other): """ if not isinstance(other, SmactStructure): return False + return all( [ self.species == other.species, @@ -295,7 +298,7 @@ def from_py_struct(structure: pymatgen.core.Structure, determine_oxi: str = "BV" @staticmethod def from_mp( species: list[tuple[str, int, int] | tuple[smact.Species, int]], - api_key: str, + api_key: str | None = None, determine_oxi: str = "BV", ): """ @@ -315,28 +318,36 @@ def from_mp( """ sanit_species = SmactStructure._sanitise_species(species) + eles = SmactStructure._get_ele_stoics(sanit_species) + formula = "".join(f"{ele}{stoic}" for ele, stoic in eles.items()) - with MPRester(api_key) as m: - eles = SmactStructure._get_ele_stoics(sanit_species) - formula = "".join(f"{ele}{stoic}" for ele, stoic in eles.items()) - try: - # Legacy API routine + if api_key is None: + api_key = os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_MAPI_KEY") + + # Legacy API routine + if len(api_key) != 32: + with MPRester(api_key) as m: structs = m.query( criteria={"reduced_cell_formula": formula}, properties=["structure"], ) - except NotImplementedError: - # New API routine - docs = m.summary.search(formula=formula, fields=["structure"]) - structs = [convert_next_gen_mprest_data(doc) for doc in docs] - if len(structs) == 0: - raise ValueError( - "Could not find composition in Materials Project Database, " "please supply a structure." - ) + else: + # New API routine + try: + from mp_api.client import MPRester as MPResterNew + + with MPResterNew(api_key, use_document_model=False) as m: + structs = m.materials.summary.search(formula=formula, fields=["structure"]) + except ImportError: + with MPRester(api_key) as m: + structs = m.get_structures(chemsys_formula=formula) + + if len(structs) == 0: + raise ValueError("Could not find composition in Materials Project Database, " "please supply a structure.") - # Default to first found structure - struct = structs[0]["structure"] + # Default to first found structure + struct = structs[0]["structure"] if isinstance(structs[0], dict) else structs[0] if 0 not in (spec[1] for spec in sanit_species): # If everything's charged if determine_oxi == "BV": From c1cb77de009898ea03c2b47269972cc9dffe37cf Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Tue, 26 Nov 2024 14:56:22 +0000 Subject: [PATCH 03/62] Enable SmactStructure MP testing --- smact/tests/test_structure.py | 7 +++++-- 1 file changed, 5 insertions(+), 2 deletions(-) diff --git a/smact/tests/test_structure.py b/smact/tests/test_structure.py index 7647d6d4..5b1e2675 100644 --- a/smact/tests/test_structure.py +++ b/smact/tests/test_structure.py @@ -21,6 +21,7 @@ from pymatgen.analysis.structure_prediction.substitution_probability import ( SubstitutionProbability, ) +from pymatgen.core import SETTINGS import smact from smact import Species @@ -215,13 +216,15 @@ def test_ele_stoics(self): with self.subTest(species=test.species): self.assertEqual(SmactStructure._get_ele_stoics(test.species), expected) - @unittest.skipUnless(os.environ.get("MPI_KEY"), "requires MPI key to be set.") + @unittest.skipUnless( + (os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_API_KEY")), "requires MP API key to be set." + ) def test_from_mp(self): """Test downloading structures from materialsproject.org.""" # TODO Needs ensuring that the structure query gets the same # structure as we have downloaded. # Need to modify the test for both legacy and next-gen queries - api_key = os.environ.get("MPI_KEY") + api_key = (os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_API_KEY")) for comp, species in self.TEST_SPECIES.items(): with self.subTest(comp=comp): From 845b843022f1e8578f238debb7acd630075c62e0 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Tue, 26 Nov 2024 15:27:45 +0000 Subject: [PATCH 04/62] Fix the SmactStructure equality --- smact/structure_prediction/structure.py | 9 ++++++++- 1 file changed, 8 insertions(+), 1 deletion(-) diff --git a/smact/structure_prediction/structure.py b/smact/structure_prediction/structure.py index fa578329..18e4c204 100644 --- a/smact/structure_prediction/structure.py +++ b/smact/structure_prediction/structure.py @@ -109,12 +109,19 @@ def __eq__(self, other): if not isinstance(other, SmactStructure): return False + sites_equal = True + for si, sj in zip(self.sites.values(), other.sites.values(), strict=False): + for ci, cj in zip(si, sj, strict=False): + if not np.allclose(ci, cj, atol=1e-7): + sites_equal = False + break + return all( [ self.species == other.species, np.array_equal(self.lattice_mat, other.lattice_mat), self.lattice_param == other.lattice_param, - self.sites == other.sites, + sites_equal, list(self.sites.keys()) == list(other.sites.keys()), ] ) From bf92ea5d3f7383397d34bbb6f8af50c8ab30dd80 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Tue, 26 Nov 2024 15:28:28 +0000 Subject: [PATCH 05/62] Run pre-commit --- smact/tests/test_structure.py | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/smact/tests/test_structure.py b/smact/tests/test_structure.py index 5b1e2675..56bee6e2 100644 --- a/smact/tests/test_structure.py +++ b/smact/tests/test_structure.py @@ -224,7 +224,7 @@ def test_from_mp(self): # TODO Needs ensuring that the structure query gets the same # structure as we have downloaded. # Need to modify the test for both legacy and next-gen queries - api_key = (os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_API_KEY")) + api_key = os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_API_KEY") for comp, species in self.TEST_SPECIES.items(): with self.subTest(comp=comp): From a738df95498c9f0575eb19e6a2870840f93ae188 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Tue, 26 Nov 2024 15:28:42 +0000 Subject: [PATCH 06/62] Run pre-commit --- smact/tests/files/Fe.json | 31 ++++++++++++++++++++++++++++++- 1 file changed, 30 insertions(+), 1 deletion(-) diff --git a/smact/tests/files/Fe.json b/smact/tests/files/Fe.json index d335f1ce..7d7e7b41 100644 --- a/smact/tests/files/Fe.json +++ b/smact/tests/files/Fe.json @@ -1 +1,30 @@ -{"@module": "pymatgen.core.structure", "@class": "Structure", "charge": 0, "lattice": {"matrix": [[-0.0, -0.0, -2.39034144], [-1.24450189, -2.15554064, -0.0], [-1.24450189, 2.15554064, 0.0]], "pbc": [true, true, true], "a": 2.39034144, "b": 2.489003898129768, "c": 2.489003898129768, "alpha": 120.00000313997197, "beta": 90.0, "gamma": 90.0, "volume": 12.824537510566229}, "properties": {}, "sites": [{"species": [{"element": "Fe", "occu": 1}], "abc": [0.0, 0.0, 0.0], "properties": {}, "label": "Fe", "xyz": [0.0, 0.0, 0.0]}]} \ No newline at end of file +{ + "@module": "pymatgen.core.structure", + "@class": "Structure", + "charge": 0, + "lattice": { + "matrix": [ + [-0.0, -0.0, -2.39034144], + [-1.24450189, -2.15554064, -0.0], + [-1.24450189, 2.15554064, 0.0] + ], + "pbc": [true, true, true], + "a": 2.39034144, + "b": 2.489003898129768, + "c": 2.489003898129768, + "alpha": 120.00000313997197, + "beta": 90.0, + "gamma": 90.0, + "volume": 12.824537510566229 + }, + "properties": {}, + "sites": [ + { + "species": [{ "element": "Fe", "occu": 1 }], + "abc": [0.0, 0.0, 0.0], + "properties": {}, + "label": "Fe", + "xyz": [0.0, 0.0, 0.0] + } + ] +} From 3d3e9904dc9925b6bd32beb8e7a186e803b59121 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Thu, 28 Nov 2024 14:23:13 +0000 Subject: [PATCH 07/62] Fix getting data from the Materials Project --- smact/structure_prediction/database.py | 26 +++++++++++++++----------- 1 file changed, 15 insertions(+), 11 deletions(-) diff --git a/smact/structure_prediction/database.py b/smact/structure_prediction/database.py index 2b66b664..3e245632 100644 --- a/smact/structure_prediction/database.py +++ b/smact/structure_prediction/database.py @@ -14,14 +14,16 @@ pathos_available = False ParallelPool = None +import os import sqlite3 from typing import TYPE_CHECKING +from pymatgen.core import SETTINGS from pymatgen.ext.matproj import MPRester from . import logger from .structure import SmactStructure -from .utilities import convert_next_gen_mprest_data, get_sign +from .utilities import get_sign if TYPE_CHECKING: from collections.abc import Sequence @@ -131,16 +133,23 @@ def add_mp_icsd( The number of structs added. """ + if mp_api_key is None: + # Try to get the API key from the environment + mp_api_key = SETTINGS.get("PMG_MAPI_KEY") or os.environ.get("MP_API_KEY") + if mp_data is None: # pragma: no cover - with MPRester(mp_api_key) as m: - try: + if len(mp_api_key) != 32: + with MPRester(mp_api_key) as m: data = m.query( criteria={"icsd_ids.0": {"$exists": True}}, properties=["structure", "material_id"], ) - except NotImplementedError: - docs = m.summary.search(theoretical=False, fields=["structure", "material_id"]) - data = [convert_next_gen_mprest_data(doc) for doc in docs] + else: + from mp_api.client import MPRester as MPResterNew + + with MPResterNew(mp_api_key, use_document_model=False) as m: + data = m.materials.summary.search(theoretical=False, fields=["structure", "material_id"]) + else: data = mp_data @@ -306,11 +315,6 @@ def parse_mprest( An oxidation-state-decorated :class:`SmactStructure`. """ - # Convert next gen query data to a dic - # TODO check if the data is the same type as MPDataDoc - if not isinstance(data, dict): - data = convert_next_gen_mprest_data(data) - try: return SmactStructure.from_py_struct(data["structure"], determine_oxi="BV") except: From 200df5c859492870d6f5101ef6cbf6b81e90550f Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Thu, 28 Nov 2024 14:25:20 +0000 Subject: [PATCH 08/62] Update oxidation decorate routine and add pymatgen conversion --- smact/structure_prediction/structure.py | 22 ++++++++++++++++------ 1 file changed, 16 insertions(+), 6 deletions(-) diff --git a/smact/structure_prediction/structure.py b/smact/structure_prediction/structure.py index 18e4c204..dec4bdec 100644 --- a/smact/structure_prediction/structure.py +++ b/smact/structure_prediction/structure.py @@ -11,6 +11,7 @@ import numpy as np import pymatgen +from pymatgen.core import Structure as pmg_Structure from pymatgen.analysis.bond_valence import BVAnalyzer from pymatgen.core import SETTINGS from pymatgen.ext.matproj import MPRester @@ -314,10 +315,8 @@ def from_mp( Args: ---- species: See :meth:`~.__init__`. - determine_oxi (str): The method to determine the assignments oxidation states in the structure. - Options are 'BV', 'comp_ICSD','both' for determining the oxidation states by bond valence, - ICSD statistics or trial both sequentially, respectively. - api_key: A www.materialsproject.org API key. + determine_oxi (str): The method to determine the assignments oxidation states in the structure. Options are 'BV', 'comp_ICSD','both' for determining the oxidation states by bond valence, ICSD statistics or trial both sequentially, respectively. + api_key (str| None): A www.materialsproject.org API key. Returns: ------- @@ -363,7 +362,7 @@ def from_mp( elif determine_oxi == "comp_ICSD": comp = struct.composition - oxi_transform = OxidationStateDecorationTransformation(comp.oxi_state_guesses()[0]) + oxi_transform = OxidationStateDecorationTransformation(comp.oxi_state_guesses(max_sites=-50)[0]) struct = oxi_transform.apply_transformation(struct) print("Charge assigned based on ICSD statistics") @@ -374,7 +373,7 @@ def from_mp( print("Oxidation states assigned using bond valence") except ValueError: comp = struct.composition - oxi_transform = OxidationStateDecorationTransformation(comp.oxi_state_guesses()[0]) + oxi_transform = OxidationStateDecorationTransformation(comp.oxi_state_guesses(max_sites=-50)[0]) struct = oxi_transform.apply_transformation(struct) print("Oxidation states assigned based on ICSD statistics") else: @@ -639,3 +638,14 @@ def as_poscar(self) -> str: poscar += f" {spec}\n" return poscar + + def as_py_struct(self) -> pymatgen.core.Structure: + """ + Represent the structure as a pymatgen Structure object. + + Returns: + ------- + pymatgen.core.Structure: pymatgen Structure object. + + """ + return pmg_Structure.from_str(self.as_poscar(), fmt="poscar") \ No newline at end of file From aa17c47092ca8957d4b892eb841e04c2e09dd860 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Thu, 28 Nov 2024 14:27:30 +0000 Subject: [PATCH 09/62] Remove deprecated function for converting next gen queries --- smact/structure_prediction/utilities.py | 26 ------------------------- 1 file changed, 26 deletions(-) diff --git a/smact/structure_prediction/utilities.py b/smact/structure_prediction/utilities.py index f3d59dd1..22f8b419 100644 --- a/smact/structure_prediction/utilities.py +++ b/smact/structure_prediction/utilities.py @@ -3,12 +3,6 @@ from __future__ import annotations import re -from typing import TYPE_CHECKING - -from . import logger - -if TYPE_CHECKING: - from pymatgen.core.structure import Structure def parse_spec(species: str) -> tuple[str, int]: @@ -109,23 +103,3 @@ def get_sign(charge: int) -> str: return "-" else: return "" - - -def convert_next_gen_mprest_data( - doc, -) -> dict[str, Structure | str | None]: - """Converts the `MPDataDoc` object returned by a next-gen MP query to a dictionary. - - Args: - ---- - doc (MPDataDoc): A MPDataDoc object (based on a pydantic model) with fields 'structure' and 'material_id' - Returns: - A dictionary containing at least the keys 'structure' and - 'material_id', with the associated values. - - """ - try: - return doc.dict(exclude={"fields_not_requested"}) - except: - logger.warn(f"Could not convert input:\n {doc}\n to a dictionary.") - raise TypeError("Input is not an MPDataDoc object.") From 00ab961381e66d265763fab57f2572ea646c4ac1 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Thu, 28 Nov 2024 14:27:52 +0000 Subject: [PATCH 10/62] Run pre-commit --- smact/structure_prediction/structure.py | 6 +++--- 1 file changed, 3 insertions(+), 3 deletions(-) diff --git a/smact/structure_prediction/structure.py b/smact/structure_prediction/structure.py index dec4bdec..821c7895 100644 --- a/smact/structure_prediction/structure.py +++ b/smact/structure_prediction/structure.py @@ -11,9 +11,9 @@ import numpy as np import pymatgen -from pymatgen.core import Structure as pmg_Structure from pymatgen.analysis.bond_valence import BVAnalyzer from pymatgen.core import SETTINGS +from pymatgen.core import Structure as pmg_Structure from pymatgen.ext.matproj import MPRester from pymatgen.transformations.standard_transformations import ( OxidationStateDecorationTransformation, @@ -638,7 +638,7 @@ def as_poscar(self) -> str: poscar += f" {spec}\n" return poscar - + def as_py_struct(self) -> pymatgen.core.Structure: """ Represent the structure as a pymatgen Structure object. @@ -648,4 +648,4 @@ def as_py_struct(self) -> pymatgen.core.Structure: pymatgen.core.Structure: pymatgen Structure object. """ - return pmg_Structure.from_str(self.as_poscar(), fmt="poscar") \ No newline at end of file + return pmg_Structure.from_str(self.as_poscar(), fmt="poscar") From bd2be0400db503322dbf114229b76e3056eaa017 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Thu, 28 Nov 2024 14:28:15 +0000 Subject: [PATCH 11/62] Remove comment about APIs --- smact/tests/test_structure.py | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/smact/tests/test_structure.py b/smact/tests/test_structure.py index 56bee6e2..bb6ca48f 100644 --- a/smact/tests/test_structure.py +++ b/smact/tests/test_structure.py @@ -223,7 +223,7 @@ def test_from_mp(self): """Test downloading structures from materialsproject.org.""" # TODO Needs ensuring that the structure query gets the same # structure as we have downloaded. - # Need to modify the test for both legacy and next-gen queries + api_key = os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_API_KEY") for comp, species in self.TEST_SPECIES.items(): From f389e4c3b6b7a49e1744c042f84c892059d6a520 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:49:14 +0000 Subject: [PATCH 12/62] Update mutation.py --- smact/structure_prediction/mutation.py | 7 ++----- 1 file changed, 2 insertions(+), 5 deletions(-) diff --git a/smact/structure_prediction/mutation.py b/smact/structure_prediction/mutation.py index 4b26bb87..a3d52c8c 100644 --- a/smact/structure_prediction/mutation.py +++ b/smact/structure_prediction/mutation.py @@ -412,7 +412,7 @@ def unary_substitute( Yields: ------ - Tuples of (:class:`SmactStructure`, probability). + Tuples of (:class:`SmactStructure`, probability, original species, new species). """ for specie in structure.get_spec_strs(): @@ -427,7 +427,4 @@ def unary_substitute( ] ): continue - yield ( - self._mutate_structure(structure, specie, new_spec), - prob, - ) + yield (self._mutate_structure(structure, specie, new_spec), prob, specie, new_spec) From 26295951248b0ae5b55f69c46c7ce125f069d523 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:49:31 +0000 Subject: [PATCH 13/62] Add reduced_formula --- smact/structure_prediction/structure.py | 17 +++++++++++++++++ 1 file changed, 17 insertions(+) diff --git a/smact/structure_prediction/structure.py b/smact/structure_prediction/structure.py index 821c7895..60b31a12 100644 --- a/smact/structure_prediction/structure.py +++ b/smact/structure_prediction/structure.py @@ -649,3 +649,20 @@ def as_py_struct(self) -> pymatgen.core.Structure: """ return pmg_Structure.from_str(self.as_poscar(), fmt="poscar") + + def reduced_formula(self) -> str: + """ + Generate a reduced formula for the structure. + + Returns: + ------- + str: Reduced formula of the structure. + + Examples: + -------- + >>> s = SmactStructure.from_file("tests/files/CaTiO3.txt") + >>> print(s.reduced_formula()) + CaTiO3 + + """ + return self.as_py_struct().composition.reduced_formula From ad5be4641ee7e3dba5d3e7736f90ecef3e6aef66 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:51:07 +0000 Subject: [PATCH 14/62] Add structure prediction tutorial --- docs/tutorials/structure_prediction.ipynb | 1080 +++++++++++++++++++++ 1 file changed, 1080 insertions(+) create mode 100644 docs/tutorials/structure_prediction.ipynb diff --git a/docs/tutorials/structure_prediction.ipynb b/docs/tutorials/structure_prediction.ipynb new file mode 100644 index 00000000..d4978ba2 --- /dev/null +++ b/docs/tutorials/structure_prediction.ipynb @@ -0,0 +1,1080 @@ +{ + "cells": [ + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "# Crystal Structure Prediction via Ionic Substitutions\n", + "\n", + "This notebook demonstrates how to use the `SMACT` _structure_prediction_ module." + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## 1. Getting Started\n", + "[![Open in Colab](https://colab.research.google.com/assets/colab-badge.svg)](https://colab.research.google.com/github/WMD-group/SMACT/blob/master/docs/tutorials/structure_prediction.ipynb)" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "# Install the required packages\n", + "try:\n", + " import google.colab\n", + "\n", + " IN_COLAB = True\n", + "except:\n", + " IN_COLAB = False\n", + "\n", + "if IN_COLAB:\n", + " !pip install \"smact[strict] @ git+https://github.com/WMD-group/SMACT.git@master\" --quiet" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "# Import the required packages\n", + "import os\n", + "from operator import itemgetter\n", + "\n", + "import pandas as pd\n", + "\n", + "from smact.structure_prediction.database import StructureDB, parse_mprest\n", + "from smact.structure_prediction.mutation import CationMutator\n", + "from smact.structure_prediction.prediction import StructurePredictor\n", + "from smact.structure_prediction.structure import SmactStructure\n", + "from smact.structure_prediction.utilities import parse_spec, unparse_spec\n", + "from pymatgen.ext.matproj import MPRester\n", + "import pymatviz as pmv\n", + "from pymatgen.core import SETTINGS\n", + "\n", + "\n", + "import seaborn as sns\n", + "import matplotlib.pyplot as plt\n", + "\n", + "sns.set_theme(context=\"notebook\")" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## 2. Introducing the Structure Prediction Module\n", + "\n", + "### The `SmactStructure` class" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "Here we will introduce users to the `SmactStructure` class which is used in the Structure Prediction module to represent structures. We can create instances of the `SmactStructure` class from POSCAR files, pymatgen `Structure` objects, or directly from a list of atomic positions and lattice vectors. We can also get the `SmactStructure` from the Materials Project database using the `from_mp` method.\n", + "\n", + "For the example below, we will get a structure of CsPbI3 from the Materials Project." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "data": { + "application/vnd.jupyter.widget-view+json": { + "model_id": "be047c84937d45c2ae6309149136d22a", + "version_major": 2, + "version_minor": 0 + }, + "text/plain": [ + "Retrieving SummaryDoc documents: 0%| | 0/3 [00:00" + ] + }, + "execution_count": null, + "metadata": {}, + "output_type": "execute_result" + }, + { + "data": { + "image/png": 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", + "text/plain": [ + "
" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], + "source": [ + "# We can print the SmactStructure object. This will show the structure in a POSCAR-like format\n", + "print(\"SmactStructure object:\")\n", + "print(cspbi3_sstruct)\n", + "\n", + "# We can visualise the structure as well\n", + "pmv.structure_2d(cspbi3_sstruct.as_py_struct())" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "For a `SmactStructure` object, we can get the list of species present" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "Species in CsPbI3:\n", + "Element, Valence, Stoichiometry\n", + "('Cs', 1, 1)\n", + "('I', -1, 3)\n", + "('Pb', 2, 1)\n", + "\n", + "Species in CsPbI3: ['Cs1+', 'I1-', 'Pb2+']\n", + "\n", + "Does the CsPbI3 structure contain Cs?: True\n" + ] + } + ], + "source": [ + "# Print the species in CsPbI3\n", + "print(f\"Species in CsPbI3:\")\n", + "print(\"Element, Valence, Stoichiometry\")\n", + "for spec in cspbi3_sstruct.species:\n", + " print(spec)\n", + "\n", + "# We can also print out just the string representation of the species\n", + "print(f\"\\nSpecies in CsPbI3: {cspbi3_sstruct.get_spec_strs()}\")\n", + "\n", + "# We can also check if a SmactStructure contains a specific species\n", + "has_cs1 = cspbi3_sstruct.has_species((\"Cs\",1))\n", + "print(f\"\\nDoes the CsPbI3 structure contain Cs?: {has_cs1}\")\n" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "We will return to using the `SmactStructure` object in the next section." + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "### The `CationMutator` class\n", + "\n", + "Here we will introduce users to the CationMutator in `smact.structure_prediction.mutation` module. The `CationMutator` class is used to handle the substitution probabilities of different ionic species. \n", + "\n", + "We can use the `sub_prob` method to get the substitution probabilities of two different ionic species. The `sub_prob` method takes two arguments, the first argument is the ionic species to be substituted, and the second argument is the ionic species to be substituted with. The `sub_prob` method returns the substitution probability of the two ionic species.\n", + "\n", + "Additionally, the `pair_corr` method computes the pair correlation." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "The probability of Ba2+ replacing Sr2+ is 0.00276 and the pair correlation is 3.86\n", + "The probability of Ba2+ replacing Cs1+ is 0.00569 and the pair correlation is 3.99\n", + "The probability of Ba2+ replacing Li1+ is 2.21e-05 and the pair correlation is 0.038\n" + ] + } + ], + "source": [ + "# Instantiate the CationMutator class\n", + "\n", + "mutator = CationMutator.from_json() # This gets the pymatgen lambda table when no arguments are passed\n", + "\n", + "# Calculate the probability of Ba2+ replacing Sr2+, Ba2+ replacing Cs1+ and Ba2+ replacing Li1+ in the lambda table\n", + "\n", + "p_Ba_Sr = mutator.sub_prob(\"Ba2+\", \"Sr2+\")\n", + "p_Ba_Cs = mutator.sub_prob(\"Ba2+\", \"Cs1+\")\n", + "p_Ba_Li = mutator.sub_prob(\"Ba2+\", \"Li1+\")\n", + "\n", + "# Calculate the pair correlation function for Ba2+ replacing Sr2+, Ba2+ replacing Cs1+ and Ba2+ replacing Li1+ in the lambda table\n", + "g_Ba_Sr = mutator.pair_corr(\"Ba2+\", \"Sr2+\")\n", + "g_Ba_Cs = mutator.pair_corr(\"Ba2+\", \"Cs1+\")\n", + "g_Ba_Li = mutator.pair_corr(\"Ba2+\", \"Li1+\")\n", + "\n", + "# Print the results\n", + "print(f\"The probability of Ba2+ replacing Sr2+ is {p_Ba_Sr:.3g} and the pair correlation is {g_Ba_Sr:.3g}\")\n", + "print(f\"The probability of Ba2+ replacing Cs1+ is {p_Ba_Cs:.3g} and the pair correlation is {g_Ba_Cs:.3g}\")\n", + "print(f\"The probability of Ba2+ replacing Li1+ is {p_Ba_Li:.3g} and the pair correlation is {g_Ba_Li:.3g}\")\n", + "\n" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "From the above outputs, we can see that Ba2+ is more likely to be substituted with Cs+, compared to Sr2+ with Li+ being two orders of magnitude less likely.\n", + "\n", + "The `CationMutator` can also be used to produce a list of possible structures with the `unary_substitute` method. The `unary_substitute` method takes a `SmactStructure` object and returns a list of `SmactStructure` objects with the cations substituted according to the substitution probabilities." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "Number of candidate structures: 59\n", + "Composition of the first candidate structure:\n", + "AgPbI3\n", + "The probability of Ag1+ replacing Cs1+ in CsPbI3 is 0.0262\n" + ] + }, + { + "data": { + "text/plain": [ + "(
,\n", + " array([,\n", + " ], dtype=object))" + ] + }, + "execution_count": null, + "metadata": {}, + "output_type": "execute_result" + }, + { + "data": { + "image/png": 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" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], + "source": [ + "# Let's substitute on CsPbI3\n", + "\n", + "candidate_structures = list(mutator.unary_substitute(cspbi3_sstruct,thresh=0.001))\n", + "\n", + "# Print the number of candidate structures\n", + "print(f\"Number of candidate structures: {len(candidate_structures)}\")\n", + "\n", + "# Print the composition of the first candidate structure\n", + "print(f\"Composition of the first candidate structure:\")\n", + "print(candidate_structures[0][0].reduced_formula())\n", + "\n", + "# Print the probability of the first candidate structure\n", + "original_spec = candidate_structures[0][2]\n", + "sub_spec = candidate_structures[0][3]\n", + "prob = candidate_structures[0][1]\n", + "print(f\"The probability of {sub_spec} replacing {original_spec} in {cspbi3_sstruct.reduced_formula()} is {prob:.3g}\")\n", + "\n", + "# Visualise the original structure and the first candidate structure\n", + "pmv.structure_2d([cspbi3_sstruct.as_py_struct(), candidate_structures[0][0].as_py_struct()])" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "Overall, with the threshold of 1 x 10-3, there are 59 possible substituted structures for CsPbI3. The returned list isn't sorted by probability, so let's first organise the list." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "data": { + "text/html": [ + "
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StructureProbabilityOriginal SpeciesSubstituted Species
0I1- Pb2+ Rb1+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6...0.165778Cs1+Rb1+
1Br1- Cs1+ Pb2+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 ...0.138700I1-Br1-
2I1- Pb2+ Tl1+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6...0.102270Cs1+Tl1+
3I1- K1+ Pb2+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6....0.089402Cs1+K1+
4I1- In1+ Pb2+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6...0.086309Cs1+In1+
\n", + "
" + ], + "text/plain": [ + " Structure Probability \\\n", + "0 I1- Pb2+ Rb1+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6... 0.165778 \n", + "1 Br1- Cs1+ Pb2+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 ... 0.138700 \n", + "2 I1- Pb2+ Tl1+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6... 0.102270 \n", + "3 I1- K1+ Pb2+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6.... 0.089402 \n", + "4 I1- In1+ Pb2+\\n1.0\\n6.27514229 0.0 -0.0\\n0.0 6... 0.086309 \n", + "\n", + " Original Species Substituted Species \n", + "0 Cs1+ Rb1+ \n", + "1 I1- Br1- \n", + "2 Cs1+ Tl1+ \n", + "3 Cs1+ K1+ \n", + "4 Cs1+ In1+ " + ] + }, + "execution_count": null, + "metadata": {}, + "output_type": "execute_result" + } + ], + "source": [ + "# Store the candidate structures in a dataframe\n", + "\n", + "candidate_df = pd.DataFrame(candidate_structures, columns=[\"Structure\", \"Probability\", \"Original Species\", \"Substituted Species\"])\n", + "# Sort the dataframe by probability\n", + "candidate_df = candidate_df.sort_values(by=\"Probability\", ascending=False).reset_index(drop=True)\n", + "\n", + "# Show the first 5 rows of the dataframe\n", + "candidate_df.head()" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "From the dataframe above, we can see that the most probable substitution is Cs+ with Rb+ with a probability of 0.166, followed by the substitution of of I- with Br- with a probability of 0.139." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "data": { + "text/plain": [ + "(
,\n", + " array([[,\n", + " ,\n", + " ],\n", + " [,\n", + " ,\n", + " ]],\n", + " dtype=object))" + ] + }, + "execution_count": null, + "metadata": {}, + "output_type": "execute_result" + }, + { + "data": { + "image/png": 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", + "text/plain": [ + "
" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], + "source": [ + "# Visualise the top 5 candidate structures\n", + "top_5_structures = [s.as_py_struct() for s in candidate_df[\"Structure\"].head().to_list()]\n", + "pmv.structure_2d([cspbi3_sstruct.as_py_struct()] + top_5_structures, n_cols=3)" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "### The `StructureDB` class\n", + "\n", + "Here we will introduce users to the `StructureDB` class. This is a minimalist SQLite database that stores `SmactStructure` objects." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "data": { + "text/plain": [ + "59" + ] + }, + "execution_count": null, + "metadata": {}, + "output_type": "execute_result" + } + ], + "source": [ + "# This either creates a new database or connects to an existing one\n", + "#\n", + "if os.path.exists(\"test_db.db\"):\n", + " os.remove(\"test_db.db\")\n", + "test_db = StructureDB(\"test_db.db\")\n", + "\n", + "# Add a table\n", + "test_db.add_table(\"test_table\")\n", + "\n", + "# Add the original structure to the database\n", + "test_db.add_struct(struct= cspbi3_sstruct,table=\"test_table\")\n", + "\n", + "# Add the candidate structures to the database\n", + "test_db.add_structs(structs=[s[0] for s in candidate_structures],table=\"test_table\")\n" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "There are 42 structures that contain Cs1+\n", + "There are 4 structures that contain Cs1+ and Pb2+\n" + ] + } + ], + "source": [ + "# Get the structures from the database\n", + "\n", + "# Get structs that contain Cs1+\n", + "\n", + "cs_structs = test_db.get_with_species(species=[(\"Cs\",1)],table=\"test_table\")\n", + "\n", + "# Print the number of structures\n", + "print(f\"There are {len(cs_structs)} structures that contain Cs1+\")\n", + "\n", + "# Get structs that contain Cs1+ and Pb2+\n", + "\n", + "cs_pb_structs = test_db.get_with_species(species=[(\"Cs\",1),(\"Pb\",2)],table=\"test_table\")\n", + "\n", + "# Print the number of structures\n", + "\n", + "print(f\"There are {len(cs_pb_structs)} structures that contain Cs1+ and Pb2+\")" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "The above code blocks demonstrates how to create a `StructureDB` object, store a list of `SmactStructure` objects, and retrieve a list of `SmactStructure` objects from the database by the species present in the structure.\n", + "\n", + "The following example demonstrates how to obtain structures from the Materials Project* and store them in the `StructureDB` object. \n", + "\n", + "* The below code assumes that the user has a Materials Project API key from the current (next-gen) version of the MP. If you do not have one, you can obtain one by signing up at https://materialsproject.org/" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "data": { + "application/vnd.jupyter.widget-view+json": { + "model_id": "a9e1b770f3ae401ab4504438fb7f8c2f", + "version_major": 2, + "version_minor": 0 + }, + "text/plain": [ + "Retrieving RobocrystallogapherDoc documents: 0%| | 0/9289 [00:003 perovskite structures from the Materials Project to the `StructureDB` object. Structures which cannot be assigned oxidation states are discarded. We can now use the `StructureDB` object to retrieve structures based on the species present in the structure." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "Number of perovskites with different anions:\n", + "F1-: 33\n", + "Cl1-: 12\n", + "Br1-: 6\n", + "I1-: 4\n", + "O2-: 152\n", + "S2-: 9\n", + "N3-: 4\n" + ] + }, + { + "data": { + "image/png": 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+ "text/plain": [ + "
" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], + "source": [ + "# Count the number of perovskites with different anions in the database\n", + "\n", + "anions = [\"F1-\",\"Cl1-\",\"Br1-\",\"I1-\",\"O2-\",\"S2-\",\"N3-\"]\n", + "\n", + "anion_counts_dict = {}\n", + "\n", + "for anion in anions:\n", + " anion_counts_dict[anion] = len(test_db.get_with_species(species=[parse_spec(anion)],table=\"mp_icsd_perovskites\"))\n", + "\n", + "# Print the counts\n", + "print(\"Number of perovskites with different anions:\")\n", + "for anion, count in anion_counts_dict.items():\n", + " print(f\"{anion}: {count}\")\n", + "\n", + "\n", + "# Plot the number of perovskites with different anions\n", + "anion_counts_df = pd.DataFrame(anion_counts_dict.items(),columns=[\"Anion\",\"Count\"])\n", + "\n", + "fig, ax = plt.subplots(figsize=(10,6))\n", + "sns.barplot(x=\"Anion\",y=\"Count\",data=anion_counts_df,ax=ax)\n", + "# Show values on the bars\n", + "for i, v in enumerate(anion_counts_df[\"Count\"]):\n", + " ax.text(i, v + 0.5, str(v), ha='center', va='bottom')\n", + "\n", + "ax.set_title(\"Number of ABO3 perovskites with different anions\")\n", + "plt.show()\n", + "\n" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "### The `StructurePredictor` class\n", + "\n", + "With a populated database, we can now introduce the final aspect of the Structure Prediction module, the `StructurePredictor` class. The `StructurePredictor` class is used to predict possible structures of a given composition. The `StructurePredictor` class requires a populated `StructureDB` object and a `CationMutator` object," + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "# Instantiate the StructurePredictor class\n", + "predictor = StructurePredictor(mutator=mutator,struct_db=test_db,table=\"mp_icsd_perovskites\")" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "To predict possible structures for a given set of ionic species, we can use the `predict_structs` method. The `predict_structs` method takes a list of ionic species and the probability threshold as arguments. The return format is a generator which yields tuples of the form (predicted structure, probability, original structure).\n" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "(N3- Ta5+ Zr4+\n", + "1.0\n", + "4.064437 0.0 0.0\n", + "0.0 4.064437 0.0\n", + "0.0 0.0 4.064437\n", + "N Ta Zr\n", + "3 1 1\n", + "Cartesian\n", + "2.0322185 0.0 2.0322185 N3-\n", + "2.0322185 2.0322185 0.0 N3-\n", + "0.0 2.0322185 2.0322185 N3-\n", + "2.0322185 2.0322185 2.0322185 Ta5+\n", + "0.0 0.0 0.0 Zr4+\n", + ", 0.02012124833175394, N3- Ta5+ Th4+\n", + "1.0\n", + "4.064437 0.0 0.0\n", + "0.0 4.064437 0.0\n", + "0.0 0.0 4.064437\n", + "N Ta Th\n", + "3 1 1\n", + "Cartesian\n", + "2.0322185 0.0 2.0322185 N3-\n", + "2.0322185 2.0322185 0.0 N3-\n", + "0.0 2.0322185 2.0322185 N3-\n", + "2.0322185 2.0322185 2.0322185 Ta5+\n", + "0.0 0.0 0.0 Th4+\n", + ")\n", + "\n", + "Using a threshold of 0.001, the species ['Zr4+', 'Ta5+', 'N3-'] can be substituted into the structure of ThTaN3 with probability 0.0201\n" + ] + }, + { + "data": { + "image/png": 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", + "text/plain": [ + "
" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], + "source": [ + "# Define a composition which contains the ions Zr4+, Ta5+ and N3-\n", + "Zr_Ta_N_species = [\n", + " (\"Zr\",4),\n", + " (\"Ta\",5),\n", + " (\"N\",-3),\n", + "]\n", + "parsed = [unparse_spec(s) for s in Zr_Ta_N_species]\n", + "threshold = 0.001\n", + "# Predict the possible structures that Zr4+, Ta5+ and N3- can be substituted onto\n", + "result =predictor.predict_structs(species = Zr_Ta_N_species,thresh=0.001,include_same=False)\n", + "\n", + "# Show the first result\n", + "\n", + "result_0 = next(result)\n", + "\n", + "print(result_0)\n", + "\n", + "print(f\"\\nUsing a threshold of {threshold}, the species {parsed} can be substituted into the structure of {result_0[2].reduced_formula()} with probability {result_0[1]:.3g}\")\n", + "\n", + "# Visualise the predicted and template structure\n", + "\n", + "structs = [result_0[0].as_py_struct(), result_0[2].as_py_struct()]\n", + "\n", + "pmv.structure_2d(structs)\n", + "plt.show()" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "Using the `StructurePredictor` class, we have shown that we can assign (Zr4+, Ta5+, N3-) to the perovskite ThTaN3, where Zr4+ substitutes for Th4+ with probability 0.0201.\n", + "\n", + "We will show an example below, where we try to substitute the species (Cs+, Pb2+, I-) into the structures in our database." + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "The composition CsPbI3 has a probability of 0.139 of substiutuing into the structure of CsPbBr3\n", + "The composition CsPbI3 has a probability of 0.139 of substiutuing into the structure of CsPbBr3\n", + "The composition CsPbI3 has a probability of 0.0473 of substiutuing into the structure of CsSnI3\n", + "The composition CsPbI3 has a probability of 0.0175 of substiutuing into the structure of CsDyI3\n", + "The composition CsPbI3 has a probability of 0.00415 of substiutuing into the structure of CsPbF3\n" + ] + }, + { + "data": { + "image/png": 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+ "text/plain": [ + "
" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], + "source": [ + "cs_pb_I_species = [\n", + " (\"Cs\",1),\n", + " (\"Pb\",2),\n", + " (\"I\",-1),\n", + "]\n", + "\n", + "# Get the results for the substitution\n", + "cspbi_results = list(predictor.predict_structs(species = cs_pb_I_species,thresh=0.001,include_same=False))\n", + "\n", + "# Sort the results by probabiblity\n", + "cspbi_results.sort(key=itemgetter(1),reverse=True)\n", + "\n", + "for result in cspbi_results:\n", + " print(f\"The composition {result[0].reduced_formula()} has a probability of {result[1]:.3g} of substiutuing into the structure of {result[2].reduced_formula()}\")\n", + "\n", + "# Visualise the predicted and original structures\n", + "\n", + "predicted_structs = [result[0].as_py_struct() for result in cspbi_results]\n", + "db_structs = [result[2].as_py_struct() for result in cspbi_results]\n", + "structures = predicted_structs + db_structs\n", + "\n", + "\n", + "pmv.structure_2d(structures,n_cols=5)\n", + "plt.show()" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "The visualisation above depicts all the CsPbI3 structures in the top row, and their templates in the bottom row." + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## 2. Next Steps\n", + "\n", + "This notebook has provided a simple introduction to the Structure Prediction module in SMACT.\n", + "\n", + "For more advance work:\n", + "\n", + "* Use the `smact_filter` function to build up a search space and attempt to predict the eneumerated compositions in a high-throughput manner\n", + "* Use the predicted structures as inputs to DFT/MLFF relaxation calculations\n", + "* Develop their own probability models to use with the `CationMutator` class." + ] + } + ], + "metadata": { + "kernelspec": { + "display_name": "smact_dev", + "language": "python", + "name": "python3" + }, + "language_info": { + "codemirror_mode": { + "name": "ipython", + "version": 3 + }, + "file_extension": ".py", + "mimetype": "text/x-python", + "name": "python", + "nbconvert_exporter": "python", + "pygments_lexer": "ipython3", + "version": "3.10.14" + } + }, + "nbformat": 4, + "nbformat_minor": 2 +} From 4c4af0be9d881edfb439f28444a1ba51cd8e65f0 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:51:16 +0000 Subject: [PATCH 15/62] Update tutorial.rst --- docs/tutorials.rst | 1 + 1 file changed, 1 insertion(+) diff --git a/docs/tutorials.rst b/docs/tutorials.rst index b30e670f..70c974b6 100644 --- a/docs/tutorials.rst +++ b/docs/tutorials.rst @@ -11,6 +11,7 @@ Tutorials are intended as a more complete example of `smact` being applied in re tutorials/smact_generation_of_solar_oxides tutorials/oxidation_states tutorials/smact_validity_of_GNoMe + tutorials/structure_prediction tutorials/crystal_space tutorials/crystal_space_visualisation tutorials/filtering_icsd_oxidation_states.ipynb From 82a5809bb04a32c34ee6f1c3a0a20d52eb551d64 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:51:37 +0000 Subject: [PATCH 16/62] Remove old examples --- .../Garnet_Database.ipynb | 865 - examples/Structure_Prediction/Garnets.db | Bin 2609152 -> 0 bytes .../Li-Garnet_Comps_sus.csv | 2505 - .../Li-Garnet_Generator.ipynb | 556 - .../Li-Garnets_SP-Pym-new.ipynb | 1280 - examples/Structure_Prediction/MP_garnets.csv | 55971 ---------------- .../_Materials Project .csv | 483 - 7 files changed, 61660 deletions(-) delete mode 100644 examples/Structure_Prediction/Garnet_Database.ipynb delete mode 100644 examples/Structure_Prediction/Garnets.db delete mode 100644 examples/Structure_Prediction/Li-Garnet_Comps_sus.csv delete mode 100644 examples/Structure_Prediction/Li-Garnet_Generator.ipynb delete mode 100644 examples/Structure_Prediction/Li-Garnets_SP-Pym-new.ipynb delete mode 100644 examples/Structure_Prediction/MP_garnets.csv delete mode 100644 examples/Structure_Prediction/_Materials Project .csv diff --git a/examples/Structure_Prediction/Garnet_Database.ipynb b/examples/Structure_Prediction/Garnet_Database.ipynb deleted file mode 100644 index 22862291..00000000 --- a/examples/Structure_Prediction/Garnet_Database.ipynb +++ /dev/null @@ -1,865 +0,0 @@ -{ - "cells": [ - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "# Create a database of structures\n", - "\n", - "This notebook provides a short demo on how to use SMACT and the Materials Project to generate a database of materials which could be used for structure prediction.\n", - "\n", - "In the example below, we generate a database of garnet materials" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "from __future__ import annotations\n", - "\n", - "import pandas as pd\n", - "from pymatgen.analysis import structure_matcher\n", - "from pymatgen.ext.matproj import MPRester\n", - "\n", - "# An optional utility to display a progress bar\n", - "# for long-running loops. `pip install tqdm`.\n", - "from smact.structure_prediction import (\n", - " database,\n", - ")" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Querying the MP for garnets" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "We have 482 entries with formula A3B2C3O12\n" - ] - }, - { - "data": { - "text/html": [ - "
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Materials IdFormulaSpacegroupFormation Energy (eV)E Above Hull (eV)Band Gap (eV)Has BandstructureVolumeNsitesTheoreticalCountDensity (gm/cc)Crystal SystemUnnamed: 13
0mp-1207933Y3Sc2(GaO4)3Ia3d-3.3930.03.595False1003.32580True482.05.017cubicNaN
1mp-1208208Y3Ga3(FeO6)2Ia3d-2.8780.02.630False971.32080TrueNaN5.331cubicNaN
2mp-1211646Li3Lu3(TeO6)2Ia3d-2.7980.03.112False918.32380TrueNaN7.182cubicNaN
3mp-6527Na3Li3In2F12Ia3d-3.0460.05.290True1072.33480FalseNaN3.391cubicNaN
4mp-556723Na3Fe2(AsO4)3Ia3d-1.9520.02.186True959.36380FalseNaN4.136cubicNaN
5mp-6247Na3Li3Fe2F12Ia3d-3.0360.04.068True995.93880FalseNaN2.864cubicNaN
6mp-15103Sr3Y2(GeO4)3Ia3d-3.0700.03.136True1165.60180FalseNaN4.847cubicNaN
7mp-1210576Nd3Sc2(FeO4)3Ia3d-3.1750.02.125False1069.49980TrueNaN5.479cubicNaN
8mp-1211226Li3Y3(TeO6)2Ia3d-2.7770.03.240False960.53380TrueNaN5.081cubicNaN
9mp-1211470Mn3Al2(GeO4)3Ia3d-2.4650.02.380False873.23180TrueNaN4.782cubicNaN
\n", - "
" - ], - "text/plain": [ - " Materials Id Formula Spacegroup Formation Energy (eV) \\\n", - "0 mp-1207933 Y3Sc2(GaO4)3 Ia3d -3.393 \n", - "1 mp-1208208 Y3Ga3(FeO6)2 Ia3d -2.878 \n", - "2 mp-1211646 Li3Lu3(TeO6)2 Ia3d -2.798 \n", - "3 mp-6527 Na3Li3In2F12 Ia3d -3.046 \n", - "4 mp-556723 Na3Fe2(AsO4)3 Ia3d -1.952 \n", - "5 mp-6247 Na3Li3Fe2F12 Ia3d -3.036 \n", - "6 mp-15103 Sr3Y2(GeO4)3 Ia3d -3.070 \n", - "7 mp-1210576 Nd3Sc2(FeO4)3 Ia3d -3.175 \n", - "8 mp-1211226 Li3Y3(TeO6)2 Ia3d -2.777 \n", - "9 mp-1211470 Mn3Al2(GeO4)3 Ia3d -2.465 \n", - "\n", - " E Above Hull (eV) Band Gap (eV) Has Bandstructure Volume Nsites \\\n", - "0 0.0 3.595 False 1003.325 80 \n", - "1 0.0 2.630 False 971.320 80 \n", - "2 0.0 3.112 False 918.323 80 \n", - "3 0.0 5.290 True 1072.334 80 \n", - "4 0.0 2.186 True 959.363 80 \n", - "5 0.0 4.068 True 995.938 80 \n", - "6 0.0 3.136 True 1165.601 80 \n", - "7 0.0 2.125 False 1069.499 80 \n", - "8 0.0 3.240 False 960.533 80 \n", - "9 0.0 2.380 False 873.231 80 \n", - "\n", - " Theoretical Count Density (gm/cc) Crystal System Unnamed: 13 \n", - "0 True 482.0 5.017 cubic NaN \n", - "1 True NaN 5.331 cubic NaN \n", - "2 True NaN 7.182 cubic NaN \n", - "3 False NaN 3.391 cubic NaN \n", - "4 False NaN 4.136 cubic NaN \n", - "5 False NaN 2.864 cubic NaN \n", - "6 False NaN 4.847 cubic NaN \n", - "7 True NaN 5.479 cubic NaN \n", - "8 True NaN 5.081 cubic NaN \n", - "9 True NaN 4.782 cubic NaN " - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "# Use the API Key\n", - "m = MPRester()\n", - "# We use a csv file downloaded from the web version of MP with the MP ids\n", - "mp_df = pd.read_csv(\"_Materials Project .csv\")\n", - "\n", - "# Extracts a list of mp-ids\n", - "mp_ids = mp_df[\"Materials Id\"].to_list()\n", - "\n", - "print(f\"We have {len(mp_ids)} entries with formula A3B2C3O12\")\n", - "mp_df.head(10)" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Query materials project\n", - "data = m.query(\n", - " criteria={\"task_id\": {\"$in\": mp_ids}},\n", - " properties=[\n", - " \"pretty_formula\",\n", - " \"material_id\",\n", - " \"spacegroup.symbol\",\n", - " \"icsd_ids\",\n", - " \"e_above_hull\",\n", - " \"exp\",\n", - " \"structure\",\n", - " \"cif\",\n", - " ],\n", - ")" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "### Structure matching\n", - "Here, we use the structure of Ca3Fe2(SiO4)3 to filter our query data for only materials which form the garnet structure." - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# get structure of Ca3Fe2(SiO4)3\n", - "SM = structure_matcher.StructureMatcher(attempt_supercell=True)\n", - "\n", - "known_garnet = m.query(\n", - " \"mp-6672\",\n", - " properties=[\n", - " \"pretty_formula\",\n", - " \"material_id\",\n", - " \"spacegroup.symbol\",\n", - " \"icsd_ids\",\n", - " \"e_above_hull\",\n", - " \"exp\",\n", - " \"structure\",\n", - " \"cif\",\n", - " ],\n", - ")\n", - "known_garnet_structure = known_garnet[0][\"structure\"]" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "247\n" - ] - } - ], - "source": [ - "# Iterate over query data and verify if they have the correct structure\n", - "fitted_data = []\n", - "for i in data:\n", - " if SM.fit_anonymous(i[\"structure\"], known_garnet_structure):\n", - " fitted_data.append(i)\n", - "print(len(fitted_data))" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "### Sorting out experimental data\n", - "Here, we determine which garnet structures are experimental (i.e. have a corresponding structure in the ICSD) or theoretical (i.e. has had electronic structure calculations done and submitted to the MP).\n" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "51\n", - "196\n" - ] - } - ], - "source": [ - "experimental_list = []\n", - "theoretical_list = []\n", - "for i in fitted_data:\n", - " if len(i[\"icsd_ids\"]) != 0:\n", - " experimental_list.append(i)\n", - " else:\n", - " theoretical_list.append(i)\n", - "print(len(experimental_list))\n", - "print(len(theoretical_list))" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Other garnet structures\n", - "Garnet materials with formulae A3B2C3D12 and X3Y5Z12 both have the same crystal structure however, the pymatgen structure matcher is unable to match a garnet with the former formula to a garnet with the latter formula. As well, querying the MP for the quarternary formula will not produce results containing the ternary formula and vice versa.\n", - "\n", - "Hence, for this particular example we also query for garnets with the ternary formula." - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stderr", - "output_type": "stream", - "text": [ - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for He. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Ne. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Ar. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Rf. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Db. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Sg. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Bh. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Hs. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Mt. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Ds. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Rg. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Cn. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Nh. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Fl. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Mc. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Lv. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Ts. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n", - "/home/aonw/anaconda3/envs/structure_prediction_test_env/lib/python3.8/site-packages/pymatgen/core/periodic_table.py:209: UserWarning: No electronegativity for Og. Setting to NaN. This has no physical meaning, and is mainly done to avoid errors caused by the code expecting a float.\n", - " warnings.warn(\n" - ] - }, - { - "name": "stdout", - "output_type": "stream", - "text": [ - "There are 112 materials with formula X3Y2Y3O12 in the MP\n", - "\n", - "Of the 112 materials, 43 match the structure of YAG\n", - "\n", - "There are 30 experimental garnet structures with formula X3Y5O12\n", - "There are 13 theoretical structures with formula X3Y5O12\n", - "Considering formulas A3B2C3O12 and X3Y5O12, suggest there are 290 materials with the garnet structure in the Materials Project\n", - "\n", - "Of these 290 materials, 81 are experimental \n", - "\n", - "Of these 290 materials, 209 are theoretical \n" - ] - } - ], - "source": [ - "# Query materials project for X3Y5O12\n", - "data_2 = m.query(\n", - " \"*3*5O12\",\n", - " properties=[\n", - " \"pretty_formula\",\n", - " \"material_id\",\n", - " \"spacegroup.symbol\",\n", - " \"icsd_ids\",\n", - " \"e_above_hull\",\n", - " \"exp\",\n", - " \"structure\",\n", - " \"cif\",\n", - " ],\n", - ")\n", - "print(f\"There are {len(data_2)} materials with formula X3Y2Y3O12 in the MP\")\n", - "print(\"\")\n", - "\n", - "# get structure of YAG\n", - "YAG = m.query(\n", - " \"mp-3050\",\n", - " properties=[\n", - " \"pretty_formula\",\n", - " \"material_id\",\n", - " \"spacegroup.symbol\",\n", - " \"icsd_ids\",\n", - " \"e_above_hull\",\n", - " \"exp\",\n", - " \"structure\",\n", - " \"cif\",\n", - " ],\n", - ")\n", - "YAG_structure = YAG[0][\"structure\"]\n", - "\n", - "# Iterate over query data and verify if they have the correct structure\n", - "fitted_data_2 = []\n", - "for i in data_2:\n", - " if SM.fit_anonymous(i[\"structure\"], YAG_structure):\n", - " fitted_data_2.append(i)\n", - "print(f\"Of the {len(data_2)} materials, {len(fitted_data_2)} match the structure of YAG\")\n", - "print(\"\")\n", - "\n", - "# Find the number of experimental and theoretical materials\n", - "experimental_list_2 = []\n", - "theoretical_list_2 = []\n", - "for i in fitted_data_2:\n", - " if len(i[\"icsd_ids\"]) != 0:\n", - " experimental_list_2.append(i)\n", - " else:\n", - " theoretical_list_2.append(i)\n", - "print(f\"There are {len(experimental_list_2)} experimental garnet structures with formula X3Y5O12\")\n", - "print(f\"There are {len(theoretical_list_2)} theoretical structures with formula X3Y5O12\")\n", - "\n", - "print(\n", - " f\"Considering formulas A3B2C3O12 and X3Y5O12, suggest there are {len(fitted_data)+len(fitted_data_2)} materials with the garnet structure in the Materials Project\"\n", - ")\n", - "print(\"\")\n", - "print(\n", - " f\"Of these {len(fitted_data)+len(fitted_data_2)} materials, {len(experimental_list)+len(experimental_list_2)} are experimental \"\n", - ")\n", - "print(\"\")\n", - "print(\n", - " f\"Of these {len(fitted_data)+len(fitted_data_2)} materials, {len(theoretical_list)+len(theoretical_list_2)} are theoretical \"\n", - ")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "(290, 8)\n" - ] - }, - { - "data": { - "text/html": [ - "
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pretty_formulamaterial_idspacegroup.symbolicsd_idse_above_hullexpstructurecif
0Na3Ti2(GeO4)3mp-1012670Ia-3d[]0.037919{'tags': ['Substituion']}[[4.65848625 6.211315 3.1056575 ] Na, [ 7.76...# generated using pymatgen\\ndata_Na3Ti2(GeO4)3...
1Na3V2(GeO4)3mp-1012686Ia-3d[]0.056257{'tags': []}[[4.616742 6.155656 3.077828] Na, [7.6945700e+...# generated using pymatgen\\ndata_Na3V2(GeO4)3\\...
2Li3Cr2(GeO4)3mp-1012879Ia-3d[]0.132669{'tags': []}[[4.51952625 6.026035 3.0130175 ] Li, [7.532...# generated using pymatgen\\ndata_Li3Cr2(GeO4)3...
3Li3Ti2(GeO4)3mp-1013749Ia-3d[]0.085313{'tags': ['Substituion']}[[4.567539 6.090052 3.045026] Li, [7.612565 0....# generated using pymatgen\\ndata_Li3Ti2(GeO4)3...
4Na3Co2(GeO4)3mp-1013794Ia-3d[]0.141169{'tags': []}[[4.54758375 6.063445 3.0317225 ] Na, [7.579...# generated using pymatgen\\ndata_Na3Co2(GeO4)3...
\n", - "
" - ], - "text/plain": [ - " pretty_formula material_id spacegroup.symbol icsd_ids e_above_hull \\\n", - "0 Na3Ti2(GeO4)3 mp-1012670 Ia-3d [] 0.037919 \n", - "1 Na3V2(GeO4)3 mp-1012686 Ia-3d [] 0.056257 \n", - "2 Li3Cr2(GeO4)3 mp-1012879 Ia-3d [] 0.132669 \n", - "3 Li3Ti2(GeO4)3 mp-1013749 Ia-3d [] 0.085313 \n", - "4 Na3Co2(GeO4)3 mp-1013794 Ia-3d [] 0.141169 \n", - "\n", - " exp \\\n", - "0 {'tags': ['Substituion']} \n", - "1 {'tags': []} \n", - "2 {'tags': []} \n", - "3 {'tags': ['Substituion']} \n", - "4 {'tags': []} \n", - "\n", - " structure \\\n", - "0 [[4.65848625 6.211315 3.1056575 ] Na, [ 7.76... \n", - "1 [[4.616742 6.155656 3.077828] Na, [7.6945700e+... \n", - "2 [[4.51952625 6.026035 3.0130175 ] Li, [7.532... \n", - "3 [[4.567539 6.090052 3.045026] Li, [7.612565 0.... \n", - "4 [[4.54758375 6.063445 3.0317225 ] Na, [7.579... \n", - "\n", - " cif \n", - "0 # generated using pymatgen\\ndata_Na3Ti2(GeO4)3... \n", - "1 # generated using pymatgen\\ndata_Na3V2(GeO4)3\\... \n", - "2 # generated using pymatgen\\ndata_Li3Cr2(GeO4)3... \n", - "3 # generated using pymatgen\\ndata_Li3Ti2(GeO4)3... \n", - "4 # generated using pymatgen\\ndata_Na3Co2(GeO4)3... " - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "new_fitted_data = fitted_data + fitted_data_2\n", - "new_theoretical_list = theoretical_list + theoretical_list_2\n", - "new_experimental_list = experimental_list + experimental_list_2\n", - "df_new = pd.DataFrame(new_fitted_data)\n", - "\n", - "df_new.to_csv(\"MP_garnets.csv\", index=False)\n", - "print(df_new.shape)\n", - "df_new.head()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "theoretical = []\n", - "for i in df_new[\"icsd_ids\"]:\n", - " if len(i) != 0:\n", - " theoretical.append(\"No\")\n", - " else:\n", - " theoretical.append(\"Yes\")\n", - "df_new[\"theoretical?\"] = theoretical" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Storing in SMACT compatible database\n", - "Now that we have all filtered query data, we now proceed to store the results in a locally accessible database." - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# This creates the database object\n", - "DB = database.StructureDB(\"Garnets.db\")\n", - "\n", - "# These create tables within the database\n", - "DB.add_table(\"Garnets\")\n", - "DB.add_table(\"Experimental\")\n", - "DB.add_table(\"Theoretical\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stderr", - "output_type": "stream", - "text": [ - "Couldn't decorate mp-1012670 with oxidation states.\n", - "Couldn't decorate mp-1012686 with oxidation states.\n", - "Couldn't decorate mp-1012879 with oxidation states.\n", - "Couldn't decorate mp-1013749 with oxidation states.\n", - "Couldn't decorate mp-1013794 with oxidation states.\n", - "Couldn't decorate mp-1013795 with oxidation states.\n", - "Couldn't decorate mp-1013796 with oxidation states.\n", - "Couldn't decorate mp-1013797 with oxidation states.\n", - "Couldn't decorate mp-1013807 with oxidation states.\n", - "Couldn't decorate mp-1013808 with oxidation states.\n", - "Couldn't decorate mp-1013842 with oxidation states.\n", - "Couldn't decorate mp-1013849 with oxidation states.\n", - "Couldn't decorate mp-1013864 with oxidation states.\n", - "Couldn't decorate mp-1013916 with oxidation states.\n", - "Couldn't decorate mp-1157153 with oxidation states.\n", - "Couldn't decorate mp-1207912 with oxidation states.\n", - "Couldn't decorate mp-1210549 with oxidation states.\n", - "Couldn't decorate mp-1211091 with oxidation states.\n", - "Couldn't decorate mp-1214140 with oxidation states.\n", - "Couldn't decorate mp-1214159 with oxidation states.\n", - "Couldn't decorate mp-1214233 with oxidation states.\n", - "Couldn't decorate mp-1012670 with oxidation states.\n", - "Couldn't decorate mp-1012686 with oxidation states.\n", - "Couldn't decorate mp-1012879 with oxidation states.\n", - "Couldn't decorate mp-1013749 with oxidation states.\n", - "Couldn't decorate mp-1013794 with oxidation states.\n", - "Couldn't decorate mp-1013795 with oxidation states.\n", - "Couldn't decorate mp-1013796 with oxidation states.\n", - "Couldn't decorate mp-1013797 with oxidation states.\n", - "Couldn't decorate mp-1013807 with oxidation states.\n", - "Couldn't decorate mp-1013808 with oxidation states.\n", - "Couldn't decorate mp-1013842 with oxidation states.\n", - "Couldn't decorate mp-1013849 with oxidation states.\n", - "Couldn't decorate mp-1013864 with oxidation states.\n", - "Couldn't decorate mp-1013916 with oxidation states.\n", - "Couldn't decorate mp-1157153 with oxidation states.\n", - "Couldn't decorate mp-1207912 with oxidation states.\n", - "Couldn't decorate mp-1210549 with oxidation states.\n", - "Couldn't decorate mp-1211091 with oxidation states.\n", - "Couldn't decorate mp-1214140 with oxidation states.\n", - "Couldn't decorate mp-1214159 with oxidation states.\n", - "Couldn't decorate mp-1214233 with oxidation states.\n" - ] - }, - { - "data": { - "text/plain": [ - "188" - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "# Create an iterable of the query data\n", - "structs = []\n", - "for i in new_fitted_data:\n", - " structs.append(database.parse_mprest(i))\n", - "\n", - "exp_structs = []\n", - "for i in new_experimental_list:\n", - " exp_structs.append(database.parse_mprest(i))\n", - "\n", - "theo_structs = []\n", - "for i in new_theoretical_list:\n", - " theo_structs.append(database.parse_mprest(i))\n", - "\n", - "# Uncomment the line below the first time you run this notebook\n", - "DB.add_structs(structs, \"Garnets\")\n", - "DB.add_structs(exp_structs, \"Experimental\")\n", - "DB.add_structs(theo_structs, \"Theoretical\")" - ] - } - ], - "metadata": { - "kernelspec": { - "display_name": "Python 3", - "language": "python", - "name": "python3" - }, - "language_info": { - "codemirror_mode": { - 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-Na3Li3(NO6)2,Na1+,N3+,Li1+,O1-,748.6942256022455 -Li3Mg3(CO6)2,Mg1+,C3+,Li1+,O1-,748.7314052975248 -Na3Li3(CO6)2,Na1+,C3+,Li1+,O1-,751.9406815250331 -Li3Mg3Al2O12,Mg1+,Al3+,Li1+,O1-,806.2364251527346 -Li3Mg3(SiO6)2,Mg1+,Si3+,Li1+,O1-,807.4877055341622 -Na3Li3Al2O12,Na1+,Al3+,Li1+,O1-,809.8352969133894 -Na3Li3(SiO6)2,Na1+,Si3+,Li1+,O1-,811.0776741746962 -Li3Mg3(SO6)2,Mg1+,S3+,Li1+,O1-,811.8671768886368 -Na3Li3(SO6)2,Na1+,S3+,Li1+,O1-,815.4245001940415 -Li3S2O15,O1-,S6+,Li1+,O1-,835.7812423063667 -Li3Mg3(BO6)2,Mg1+,B3+,Li1+,O1-,856.1968526071666 -Na3Li3(BO6)2,Na1+,B3+,Li1+,O1-,860.829054992781 -Li3Mg3(AuO6)2,Mg1+,Au3+,Li1+,O1-,903.1575807984093 -Na3Li3(AuO6)2,Na1+,Au3+,Li1+,O1-,905.511721323094 -Li3Mg3(ClO6)2,Mg1+,Cl3+,Li1+,O1-,914.8509071413831 -Na3Li3(ClO6)2,Na1+,Cl3+,Li1+,O1-,919.4920050752137 -Li3Cl2O15,O1-,Cl6+,Li1+,O1-,946.011998070662 -Li3Mg3(FeO6)2,Mg1+,Fe3+,Li1+,O1-,946.7961918450167 -Na3Li3(FeO6)2,Na1+,Fe3+,Li1+,O1-,951.276577506408 -Li3Fe2O15,O1-,Fe6+,Li1+,O1-,976.6823980413633 -Li3Mg3Ti2O12,Mg1+,Ti3+,Li1+,O1-,978.0323112381536 -Li3Mg3(NiO6)2,Mg1+,Ni3+,Li1+,O1-,982.3205436825383 -Na3Li3Ti2O12,Na1+,Ti3+,Li1+,O1-,983.0285307764727 -Na3Li3(NiO6)2,Na1+,Ni3+,Li1+,O1-,987.0881346638605 -Li3Mg3(CuO6)2,Mg1+,Cu3+,Li1+,O1-,994.490856609664 -Na3Li3(CuO6)2,Na1+,Cu3+,Li1+,O1-,999.2627273226606 -Li3Mg3(AgO6)2,Mg1+,Ag3+,Li1+,O1-,1040.8287122268416 -Li3Ca3(AuO6)2,Ca1+,Au3+,Li1+,O1-,1042.3038814151646 -Na3Li3(AgO6)2,Na1+,Ag3+,Li1+,O1-,1045.117860687982 -Li3Ca3(NO6)2,Ca1+,N3+,Li1+,O1-,1046.3838463737097 -Li3Fe3(AuO6)2,Fe1+,Au3+,Li1+,O1-,1048.6271226253953 -Li3Fe3(AuO6)2,Fe5+,Au3+,Li1+,O2-,1048.6271226253953 -Li3Ca3(CO6)2,Ca1+,C3+,Li1+,O1-,1052.4923320615048 -Li3Mg3Mn2O12,Mg1+,Mn3+,Li1+,O1-,1055.814427296754 -Li3Fe3(NO6)2,Fe1+,N3+,Li1+,O1-,1057.9005211524418 -Li3Fe3(NO6)2,Fe5+,N3-,Li1+,O1-,1057.9005211524418 -Li3Fe3(NO6)2,Fe5+,N3+,Li1+,O2-,1057.9005211524418 -Li3AuO6,Li1+,Au3+,Li1+,O1-,1059.3888887364494 -Na3Li3Mn2O12,Na1+,Mn3+,Li1+,O1-,1061.4138398510088 -Li3Fe3(CO6)2,Fe5+,C3+,Li1+,O2-,1063.4081670302755 -Li3Fe3(CO6)2,Fe5+,C3-,Li1+,O1-,1063.4081670302755 -Li3Fe3(CO6)2,Fe1+,C3+,Li1+,O1-,1063.4081670302755 -Li3Ti3(AuO6)2,Ti1+,Au3+,Li1+,O1-,1075.6950818859134 -Li3Cd3(AuO6)2,Cd1+,Au3+,Li1+,O1-,1076.0682986711977 -Li3Ca3(SO6)2,Ca1+,S3+,Li1+,O1-,1077.4314302993255 -Li3Ca3(SiO6)2,Ca1+,Si3+,Li1+,O1-,1079.0147905764543 -Li3Ca3Al2O12,Ca1+,Al3+,Li1+,O1-,1079.4655728835269 -Li3Fe3(SO6)2,Fe5+,S3+,Li1+,O2-,1084.7082708634434 -Li3Fe3(SO6)2,Fe3+,S6+,Li1+,O2-,1084.7082708634434 -Li3Fe3(SO6)2,Fe1+,S3+,Li1+,O1-,1084.7082708634434 -Li3Fe3(SiO6)2,Fe5+,Si3+,Li1+,O2-,1086.25273697671 -Li3Fe3(SiO6)2,Fe5+,Si3-,Li1+,O1-,1086.25273697671 -Li3Fe3(SiO6)2,Fe1+,Si3+,Li1+,O1-,1086.25273697671 -Li3Al2(FeO4)3,Fe5+,Al3+,Li1+,O2-,1086.6912202822887 -Li3Al2(FeO4)3,Fe1+,Al3+,Li1+,O1-,1086.6912202822887 -Li3NO6,Li1+,N3+,Li1+,O1-,1088.912304196181 -Li3Mn2O15,O1-,Mn6+,Li1+,O1-,1093.1747919131046 -Li3CO6,Li1+,C3+,Li1+,O1-,1098.0364837099405 -Li3Cd3(NO6)2,Cd1+,N3+,Li1+,O1-,1099.989931879303 -Li3Cd3(CO6)2,Cd1+,C3+,Li1+,O1-,1104.1621738944123 -Li3Ag3(AuO6)2,Ag1+,Au3+,Li1+,O1-,1107.570978033944 -Li3Ti3(NO6)2,Ti1+,N3+,Li1+,O1-,1111.3104537572751 -Li3Cd3(SO6)2,Cd1+,S3+,Li1+,O1-,1116.9156278269456 -Li3Ti3(CO6)2,Ti1+,C3+,Li1+,O1-,1117.7250339214095 -Li3Cd3(SiO6)2,Cd1+,Si3+,Li1+,O1-,1118.450601580483 -Li3Al2Cd3O12,Cd1+,Al3+,Li1+,O1-,1118.883589397073 -Li3SO6,Li1+,S3+,Li1+,O1-,1125.166908017227 -Li3SiO6,Li1+,Si3+,Li1+,O1-,1128.604346712913 -Li3AlO6,Li1+,Al3+,Li1+,O1-,1129.5916437085064 -Li3Mn3(AuO6)2,Mn5+,Au3+,Li1+,O2-,1132.8323135029038 -Li3Mn3(AuO6)2,Mn1+,Au3+,Li1+,O1-,1132.8323135029038 -Li3Ti3(SO6)2,Ti1+,S3+,Li1+,O1-,1135.0570257578943 -Li3Ti3(SO6)2,Ti3+,S6+,Li1+,O2-,1135.0570257578943 -Li3Ti3(SiO6)2,Ti1+,Si3+,Li1+,O1-,1137.6623351441801 -Li3Ti3Al2O12,Ti1+,Al3+,Li1+,O1-,1138.4029850282336 -Li3Mg3(GaO6)2,Mg1+,Ga3+,Li1+,O1-,1140.3677246735947 -Na3Li3(GaO6)2,Na1+,Ga3+,Li1+,O1-,1146.3660801220278 -Li3Fe3(BO6)2,Fe5+,B3+,Li1+,O2-,1147.4557482496327 -Li3Fe3(BO6)2,Fe1+,B3+,Li1+,O1-,1147.4557482496327 -Li3Ca3(BO6)2,Ca1+,B3+,Li1+,O1-,1147.6751182360706 -Li3Mg3(GeO6)2,Mg1+,Ge3+,Li1+,O1-,1150.6498213037817 -Li3Ag3(NO6)2,Ag1+,N3+,Li1+,O1-,1152.4932419001127 -Na3Li3(GeO6)2,Na1+,Ge3+,Li1+,O1-,1156.6612323315017 -Li3Ag3(CO6)2,Ag1+,C3+,Li1+,O1-,1157.1409198956967 -Li3Fe3(ClO6)2,Fe5+,Cl3+,Li1+,O2-,1162.0013260741998 -Li3Fe3(ClO6)2,Fe1+,Cl3+,Li1+,O1-,1162.0013260741998 -Li3Fe3(ClO6)2,Fe3+,Cl6+,Li1+,O2-,1162.0013260741998 -Li3Cd3(BO6)2,Cd1+,B3+,Li1+,O1-,1163.4316463251228 -Li3Ca3(ClO6)2,Ca1+,Cl3+,Li1+,O1-,1163.8971392414715 -Li3Ag3(SO6)2,Ag1+,S3+,Li1+,O1-,1166.6455305000213 -Li3Ag3(SO6)2,Ag3+,S6+,Li1+,O2-,1166.6455305000213 -Li3Fe5O12,Fe5+,Fe3+,Li1+,O2-,1167.3178321797704 -Li3Fe5O12,Fe1+,Fe3+,Li1+,O1-,1167.3178321797704 -Li3Fe5O12,Fe3+,Fe6+,Li1+,O2-,1167.3178321797704 -Li3Si2(AgO4)3,Ag1+,Si3+,Li1+,O1-,1168.883719878486 -Li3Al2(AgO4)3,Ag1+,Al3+,Li1+,O1-,1169.5153131226552 -Li3Ca3(FeO6)2,Ca1+,Fe3+,Li1+,O1-,1169.6052388385299 -Li3Cd3(ClO6)2,Cd1+,Cl3+,Li1+,O1-,1172.7341506982473 -Li3Cd3(FeO6)2,Cd1+,Fe3+,Li1+,O1-,1176.025797489886 -Li3Zn3(AuO6)2,Zn1+,Au3+,Li1+,O1-,1183.3697537272903 -Li3Fe3(NiO6)2,Fe1+,Ni3+,Li1+,O1-,1193.5650431070508 -Li3Fe3(NiO6)2,Fe5+,Ni3+,Li1+,O2-,1193.5650431070508 -Li3Cd3(NiO6)2,Cd1+,Ni3+,Li1+,O1-,1195.5252311983359 -Li3Ca3(NiO6)2,Ca1+,Ni3+,Li1+,O1-,1198.579777931012 -Li3Fe3(CuO6)2,Fe1+,Cu3+,Li1+,O1-,1199.4258269109346 -Li3Fe3(CuO6)2,Fe5+,Cu3+,Li1+,O2-,1199.4258269109346 -Li3Ti2(FeO4)3,Fe1+,Ti3+,Li1+,O1-,1199.7366855652608 -Li3Ti2(FeO4)3,Fe5+,Ti3+,Li1+,O2-,1199.7366855652608 -Li3Cd3(CuO6)2,Cd1+,Cu3+,Li1+,O1-,1199.8891515619796 -Li3Ti2Cd3O12,Cd1+,Ti3+,Li1+,O1-,1200.1408213411692 -Li3Ca3(CuO6)2,Ca1+,Cu3+,Li1+,O1-,1204.9372606444363 -Li3Ca3Ti2O12,Ca1+,Ti3+,Li1+,O1-,1205.685475990464 -Li3Cd3(AgO6)2,Cd1+,Ag3+,Li1+,O1-,1206.4569281307604 -Li3Ti3(BO6)2,Ti1+,B3+,Li1+,O1-,1207.438495731126 -Li3Fe3(AgO6)2,Fe1+,Ag3+,Li1+,O1-,1207.932262259616 -Li3Fe3(AgO6)2,Fe5+,Ag3+,Li1+,O2-,1207.932262259616 -Li3Se2O15,O1-,Se6+,Li1+,O1-,1211.986846064566 -Li3Ca3(AgO6)2,Ca1+,Ag3+,Li1+,O1-,1213.286631478707 -Li3Ti3(ClO6)2,Ti3+,Cl6+,Li1+,O2-,1215.8808282637854 -Li3Ti3(ClO6)2,Ti1+,Cl3+,Li1+,O1-,1215.8808282637854 -Li3Ti3(FeO6)2,Ti1+,Fe3+,Li1+,O1-,1216.774889832833 -Li3Ti3(FeO6)2,Ti3+,Fe6+,Li1+,O2-,1216.774889832833 -Li3Ag3(BO6)2,Ag1+,B3+,Li1+,O1-,1218.0856508394343 -Li3Mn3(NO6)2,Mn5+,N3+,Li1+,O2-,1218.1271091265435 -Li3Mn3(NO6)2,Mn1+,N3+,Li1+,O1-,1218.1271091265435 -Li3Mn3(NO6)2,Mn5+,N3-,Li1+,O1-,1218.1271091265435 -Li3Ag3(ClO6)2,Ag3+,Cl6+,Li1+,O2-,1223.1617792343625 -Li3Ag3(ClO6)2,Ag1+,Cl3+,Li1+,O1-,1223.1617792343625 -Li3Fe2(AgO4)3,Ag1+,Fe3+,Li1+,O1-,1223.349355295024 -Li3Fe2(AgO4)3,Ag3+,Fe6+,Li1+,O2-,1223.349355295024 -Li3Mn3(CO6)2,Mn1+,C3+,Li1+,O1-,1225.2645519029584 -Li3Mn3(CO6)2,Mn5+,C3-,Li1+,O1-,1225.2645519029584 -Li3Mn3(CO6)2,Mn5+,C3+,Li1+,O2-,1225.2645519029584 -Li3BO6,Li1+,B3+,Li1+,O1-,1230.716193007309 -Li3Mn3(SO6)2,Mn3+,S6+,Li1+,O2-,1232.0004597066957 -Li3Mn3(SO6)2,Mn5+,S3+,Li1+,O2-,1232.0004597066957 -Li3Mn3(SO6)2,Mn1+,S3+,Li1+,O1-,1232.0004597066957 -Li3Mn3(SiO6)2,Mn5+,Si3+,Li1+,O2-,1236.2570011519226 -Li3Mn3(SiO6)2,Mn5+,Si3-,Li1+,O1-,1236.2570011519226 -Li3Mn3(SiO6)2,Mn1+,Si3+,Li1+,O1-,1236.2570011519226 -Li3FeO6,Li1+,Fe3+,Li1+,O1-,1237.3007985433014 -Li3Mn3Al2O12,Mn5+,Al3+,Li1+,O2-,1237.4656333696776 -Li3Mn3Al2O12,Mn1+,Al3+,Li1+,O1-,1237.4656333696776 -Li3ClO6,Li1+,Cl3+,Li1+,O1-,1238.7950803953968 -Li3Mn2Cd3O12,Cd1+,Mn3+,Li1+,O1-,1242.0093171512292 -Li3Ni2(AgO4)3,Ag1+,Ni3+,Li1+,O1-,1242.8429053702685 -Li3Ti3(NiO6)2,Ti1+,Ni3+,Li1+,O1-,1243.7533188857155 -Li3Cu2(AgO4)3,Ag1+,Cu3+,Li1+,O1-,1246.6043437922185 -Li3Ag5O12,Ag1+,Ag3+,Li1+,O1-,1247.7855681155845 -Li3Ti3(CuO6)2,Ti1+,Cu3+,Li1+,O1-,1248.8968142875578 -Li3Ti2(AgO4)3,Ag1+,Ti3+,Li1+,O1-,1249.1787449395274 -Li3Ti3(AgO6)2,Ti1+,Ag3+,Li1+,O1-,1250.0944851833392 -Li3Ti5O12,Ti1+,Ti3+,Li1+,O1-,1252.6550876389028 -Li3Mn2(FeO4)3,Fe1-,Mn6+,Li1+,O1-,1256.1101289241803 -Li3Mn2(FeO4)3,Fe1+,Mn3+,Li1+,O1-,1256.1101289241803 -Li3Mn2(FeO4)3,Fe5+,Mn3+,Li1+,O2-,1256.1101289241803 -Li3Mn2(FeO4)3,Fe3+,Mn6+,Li1+,O2-,1256.1101289241803 -Li3Ca3Mn2O12,Ca1+,Mn3+,Li1+,O1-,1267.8892218289614 -Li3NiO6,Li1+,Ni3+,Li1+,O1-,1273.3823402053868 -Li3AgO6,Li1+,Ag3+,Li1+,O1-,1274.971471500875 -Li3CuO6,Li1+,Cu3+,Li1+,O1-,1279.4793236396781 -Li3Cd3(GaO6)2,Cd1+,Ga3+,Li1+,O1-,1286.1638695462243 -Li3TiO6,Li1+,Ti3+,Li1+,O1-,1287.5501559327301 -Li3Mn2(AgO4)3,Ag3+,Mn6+,Li1+,O2-,1290.8570832560144 -Li3Mn2(AgO4)3,Ag1+,Mn3+,Li1+,O1-,1290.8570832560144 -Li3Cd3(GeO6)2,Cd1+,Ge3+,Li1+,O1-,1291.314123620365 -Li3Mn3(FeO6)2,Mn5+,Fe3+,Li1+,O2-,1300.7531422156344 -Li3Mn3(FeO6)2,Mn1+,Fe3+,Li1+,O1-,1300.7531422156344 -Li3Mn3(FeO6)2,Mn3+,Fe6+,Li1+,O2-,1300.7531422156344 -Li3Zn3(NO6)2,Zn1+,N3+,Li1+,O1-,1304.8459214169711 -Li3Mn3(ClO6)2,Mn1+,Cl3+,Li1+,O1-,1307.5372500533322 -Li3Mn3(ClO6)2,Mn3+,Cl6+,Li1+,O2-,1307.5372500533322 -Li3Mn3(ClO6)2,Mn5+,Cl3+,Li1+,O2-,1307.5372500533322 -Li3Ti3Mn2O12,Ti1+,Mn3+,Li1+,O1-,1310.3171313635085 -Li3Ti3Mn2O12,Ti3+,Mn6+,Li1+,O2-,1310.3171313635085 -Li3Mn3(BO6)2,Mn1+,B3+,Li1+,O1-,1310.8576242717522 -Li3Mn3(BO6)2,Mn5+,B3+,Li1+,O2-,1310.8576242717522 -Li3Zn3(SO6)2,Zn1+,S3+,Li1+,O1-,1311.1791294850423 -Li3Zn3(CO6)2,Zn1+,C3+,Li1+,O1-,1312.2650175193426 -Li3Ga2(FeO4)3,Fe1+,Ga3+,Li1+,O1-,1313.8776537293033 -Li3Ga2(FeO4)3,Fe5+,Ga3+,Li1+,O2-,1313.8776537293033 -Li3Zn3(SiO6)2,Zn1+,Si3+,Li1+,O1-,1316.5028638445378 -Li3Mg3In2O12,Mg1+,In3+,Li1+,O1-,1317.862345808849 -Li3Al2Zn3O12,Zn1+,Al3+,Li1+,O1-,1318.012161941516 -Li3Mn3(AgO6)2,Mn5+,Ag3+,Li1+,O2-,1318.1560140246243 -Li3Mn3(AgO6)2,Mn1+,Ag3+,Li1+,O1-,1318.1560140246243 -Li3Fe3(GeO6)2,Fe1+,Ge3+,Li1+,O1-,1320.3830521346922 -Li3Fe3(GeO6)2,Fe5+,Ge3-,Li1+,O1-,1320.3830521346922 -Li3Fe3(GeO6)2,Fe5+,Ge3+,Li1+,O2-,1320.3830521346922 -Na3Li3In2O12,Na1+,In3+,Li1+,O1-,1324.1722790445863 -Li3Mn3(NiO6)2,Mn5+,Ni3+,Li1+,O2-,1325.6090079459636 -Li3Mn3(NiO6)2,Mn1+,Ni3+,Li1+,O1-,1325.6090079459636 -Li3Mn3(CuO6)2,Mn5+,Cu3+,Li1+,O2-,1328.9623384408685 -Li3Mn3(CuO6)2,Mn1+,Cu3+,Li1+,O1-,1328.9623384408685 -Li3Ca3(GaO6)2,Ca1+,Ga3+,Li1+,O1-,1330.7026221185456 -Li3In3(AuO6)2,In1+,Au3+,Li1+,O1-,1331.255494923629 -Li3Mg3(CoO6)2,Mg1+,Co3+,Li1+,O1-,1333.3832998193077 -Li3Ga2(AgO4)3,Ag1+,Ga3+,Li1+,O1-,1333.7648387314416 -Li3Fe3(SeO6)2,Fe3+,Se6+,Li1+,O2-,1333.9939673487766 -Li3Ca3(GeO6)2,Ca1+,Ge3+,Li1+,O1-,1337.6461178040759 -Li3Ti2Mn3O12,Mn5+,Ti3+,Li1+,O2-,1337.8561317731146 -Li3Ti2Mn3O12,Mn1+,Ti3+,Li1+,O1-,1337.8561317731146 -Li3Ag3(GeO6)2,Ag1+,Ge3+,Li1+,O1-,1338.6106858672815 -Na3Li3(CoO6)2,Na1+,Co3+,Li1+,O1-,1341.6111532619798 -Li3Co3(AuO6)2,Co5+,Au3+,Li1+,O2-,1346.1132100174987 -Li3Co3(AuO6)2,Co1+,Au3+,Li1+,O1-,1346.1132100174987 -Li3Ag3(SeO6)2,Ag3+,Se6+,Li1+,O2-,1348.8304007659644 -Li3MnO6,Li1+,Mn3+,Li1+,O1-,1364.3849965280983 -Li3Ti3(GaO6)2,Ti1+,Ga3+,Li1+,O1-,1367.6404037568457 -Li3Zn3(FeO6)2,Zn1+,Fe3+,Li1+,O1-,1368.552739523994 -Li3Zn3(AgO6)2,Zn1+,Ag3+,Li1+,O1-,1373.78974844233 -Li3Ti3(GeO6)2,Ti1+,Ge3+,Li1+,O1-,1373.8309672296095 -Li3Zn3(ClO6)2,Zn1+,Cl3+,Li1+,O1-,1380.6541447754428 -Li3Cd3In2O12,Cd1+,In3+,Li1+,O1-,1386.62174766008 -Li3Ti3(SeO6)2,Ti3+,Se6+,Li1+,O2-,1386.7617483329986 -Li3Mn5O12,Mn1+,Mn3+,Li1+,O1-,1390.5374913058768 -Li3Mn5O12,Mn3+,Mn6+,Li1+,O2-,1390.5374913058768 -Li3Mn5O12,Mn5+,Mn3+,Li1+,O2-,1390.5374913058768 -Li3Zn3(NiO6)2,Zn1+,Ni3+,Li1+,O1-,1391.1917187027477 -Li3Zn3(BO6)2,Zn1+,B3+,Li1+,O1-,1392.0996097196708 -Li3Zn3(CuO6)2,Zn1+,Cu3+,Li1+,O1-,1393.1613840399841 -Li3Ti2Zn3O12,Zn1+,Ti3+,Li1+,O1-,1405.4899115807227 -Li3Cd3(CoO6)2,Cd1+,Co3+,Li1+,O1-,1407.506771930131 -Li3In2(AgO4)3,Ag1+,In3+,Li1+,O1-,1430.4056985882503 -Li3GaO6,Li1+,Ga3+,Li1+,O1-,1436.2874070452615 -Li3In2(FeO4)3,Fe5+,In3+,Li1+,O2-,1438.1852197457388 -Li3In2(FeO4)3,Fe1+,In3+,Li1+,O1-,1438.1852197457388 -Li3Mn3(GaO6)2,Mn1+,Ga3+,Li1+,O1-,1440.9215215169506 -Li3Mn3(GaO6)2,Mn5+,Ga3+,Li1+,O2-,1440.9215215169506 -Li3GeO6,Li1+,Ge3+,Li1+,O1-,1443.4269294635158 -Li3V3(AuO6)2,V1+,Au3+,Li1+,O1-,1444.217745276132 -Li3V3(AuO6)2,V5+,Au3+,Li1+,O2-,1444.217745276132 -Li3Mn3(GeO6)2,Mn1+,Ge3+,Li1+,O1-,1446.0433669136542 -Li3Mn3(GeO6)2,Mn5+,Ge3+,Li1+,O2-,1446.0433669136542 -Li3Mn3(GeO6)2,Mn5+,Ge3-,Li1+,O1-,1446.0433669136542 -Li3Mn2Zn3O12,Zn1+,Mn3+,Li1+,O1-,1453.1389712947241 -Li3Y3(AuO6)2,Y1+,Au3+,Li1+,O1-,1454.9519477386063 -Li3Mn3(SeO6)2,Mn3+,Se6+,Li1+,O2-,1456.7576093534583 -Li3Co2(AgO4)3,Ag1+,Co3+,Li1+,O1-,1459.2052103023507 -Li3Mg3V2O12,Mg1+,V3+,Li1+,O1-,1461.0230595505113 -Li3Ca3In2O12,Ca1+,In3+,Li1+,O1-,1462.7630553321233 -Li3Zr3(AuO6)2,Zr1+,Au3+,Li1+,O1-,1463.9966888202289 -Na3Li3V2O12,Na1+,V3+,Li1+,O1-,1470.9063442806275 -Li3Y2Mg3O12,Mg1+,Y3+,Li1+,O1-,1471.754844485673 -Li3Fe3(CoO6)2,Fe5+,Co3+,Li1+,O2-,1477.7516066838243 -Li3Fe3(CoO6)2,Fe1+,Co3+,Li1+,O1-,1477.7516066838243 -Na3Li3Y2O12,Na1+,Y3+,Li1+,O1-,1480.0974730808305 -Li3Mg3Zr2O12,Mg1+,Zr3+,Li1+,O1-,1482.9276763492921 -Li3V2Cd3O12,Cd1+,V3+,Li1+,O1-,1485.213790767685 -Li3Ti3In2O12,Ti1+,In3+,Li1+,O1-,1488.7508429274633 -Li3Y2Cd3O12,Cd1+,Y3+,Li1+,O1-,1489.5248746153968 -Na3Li3Zr2O12,Na1+,Zr3+,Li1+,O1-,1491.2819491508674 -Li3Zr2Cd3O12,Cd1+,Zr3+,Li1+,O1-,1496.553568561665 -Li3Zn3(GaO6)2,Zn1+,Ga3+,Li1+,O1-,1497.2624782857915 -Li3Zn3(GeO6)2,Zn1+,Ge3+,Li1+,O1-,1501.501110905054 -Li3In3(SO6)2,In1+,S3+,Li1+,O1-,1507.0667869542285 -Li3In3(SO6)2,In3+,S6+,Li1+,O2-,1507.0667869542285 -Li3Ca3(CoO6)2,Ca1+,Co3+,Li1+,O1-,1512.5721101298227 -Li3In3(SiO6)2,In1+,Si3+,Li1+,O1-,1513.6456525226233 -Li3In3(NO6)2,In1+,N3+,Li1+,O1-,1514.425324355799 -Li3Al2In3O12,In1+,Al3+,Li1+,O1-,1515.501066374903 -Li3In3(AgO6)2,In1+,Ag3+,Li1+,O1-,1519.252963300941 -Li3In3(CO6)2,In1+,C3+,Li1+,O1-,1521.3918600522422 -Li3Cd3(PO6)2,Cd1+,P3+,Li1+,O1-,1532.3429825045812 -Li3In3(FeO6)2,In3+,Fe6+,Li1+,O2-,1537.800926154307 -Li3In3(FeO6)2,In1+,Fe3+,Li1+,O1-,1537.800926154307 -Li3Y2(AgO4)3,Ag1+,Y3+,Li1+,O1-,1538.4492800029573 -Li3V2(AgO4)3,Ag1+,V3+,Li1+,O1-,1539.8659007612994 -Li3Mg3(PO6)2,Mg1+,P3+,Li1+,O1-,1541.2029896922766 -Li3Ti3(CoO6)2,Ti1+,Co3+,Li1+,O1-,1542.230187411871 -Li3Zr2(AgO4)3,Ag1+,Zr3+,Li1+,O1-,1545.2956897256854 -Li3Mn3In2O12,Mn1+,In3+,Li1+,O1-,1546.9177321793952 -Li3Mn3In2O12,Mn5+,In3+,Li1+,O2-,1546.9177321793952 -Na3Li3(PO6)2,Na1+,P3+,Li1+,O1-,1553.1549142197962 -Li3In3(CuO6)2,In1+,Cu3+,Li1+,O1-,1553.2705069160788 -Li3In3(NiO6)2,In1+,Ni3+,Li1+,O1-,1554.0368240672365 -Li3In3(ClO6)2,In3+,Cl6+,Li1+,O2-,1558.035186965178 -Li3In3(ClO6)2,In1+,Cl3+,Li1+,O1-,1558.035186965178 -Li3Ti2In3O12,In1+,Ti3+,Li1+,O1-,1570.4891763263859 -Sr3Li3(AuO6)2,Sr1+,Au3+,Li1+,O1-,1570.782081818943 -Li3InO6,Li1+,In3+,Li1+,O1-,1576.130624847283 -Li3Y2(FeO4)3,Fe1+,Y3+,Li1+,O1-,1577.161525541397 -Li3Y2(FeO4)3,Fe5+,Y3+,Li1+,O2-,1577.161525541397 -Li3In3(BO6)2,In1+,B3+,Li1+,O1-,1581.65135522735 -Li3V2(FeO4)3,Fe1+,V3+,Li1+,O1-,1585.1319422238757 -Li3V2(FeO4)3,Fe5+,V3+,Li1+,O2-,1585.1319422238757 -Li3Zr2(FeO4)3,Fe1+,Zr3+,Li1+,O1-,1585.5876025322016 -Li3Zr2(FeO4)3,Fe5+,Zr3+,Li1+,O2-,1585.5876025322016 -Li3Zn3In2O12,Zn1+,In3+,Li1+,O1-,1590.0892592645946 -Li3Co3(AgO6)2,Co5+,Ag3+,Li1+,O2-,1590.550921560428 -Li3Co3(AgO6)2,Co1+,Ag3+,Li1+,O1-,1590.550921560428 -Li3Ag3(PO6)2,Ag1+,P3+,Li1+,O1-,1591.7160232004685 -Li3Cr3(AuO6)2,Cr5+,Au3+,Li1+,O2-,1595.4880755408983 -Li3Cr3(AuO6)2,Cr1+,Au3+,Li1+,O1-,1595.4880755408983 -Li3Sc3(AuO6)2,Sc1+,Au3+,Li1+,O1-,1596.9044272054757 -Li3Co3(SO6)2,Co5+,S3+,Li1+,O2-,1597.6843037202461 -Li3Co3(SO6)2,Co3+,S6+,Li1+,O2-,1597.6843037202461 -Li3Co3(SO6)2,Co1+,S3+,Li1+,O1-,1597.6843037202461 -Li3Cr2Cd3O12,Cd1+,Cr3+,Li1+,O1-,1602.68839415266 -Li3Sc2Cd3O12,Cd1+,Sc3+,Li1+,O1-,1603.941038722407 -Li3Mn2In3O12,In1+,Mn3+,Li1+,O1-,1604.053892919883 -Li3Mn2In3O12,In3+,Mn6+,Li1+,O2-,1604.053892919883 -Li3Co3(SiO6)2,Co5+,Si3+,Li1+,O2-,1608.3552652690366 -Li3Co3(SiO6)2,Co5+,Si3-,Li1+,O1-,1608.3552652690366 -Li3Co3(SiO6)2,Co1+,Si3+,Li1+,O1-,1608.3552652690366 -Li3Mn3(CoO6)2,Mn5+,Co3+,Li1+,O2-,1611.2282891300958 -Li3Mn3(CoO6)2,Mn1+,Co3+,Li1+,O1-,1611.2282891300958 -Li3Al2(CoO4)3,Co1+,Al3+,Li1+,O1-,1611.3833686941348 -Li3Al2(CoO4)3,Co5+,Al3+,Li1+,O2-,1611.3833686941348 -Li3Co3(NO6)2,Co5+,N3-,Li1+,O1-,1615.83349552881 -Li3Co3(NO6)2,Co1+,N3+,Li1+,O1-,1615.83349552881 -Li3Co3(NO6)2,Co5+,N3+,Li1+,O2-,1615.83349552881 -Li3Ca3Y2O12,Ca1+,Y3+,Li1+,O1-,1617.1005644386983 -Li3Ca3Zr2O12,Ca1+,Zr3+,Li1+,O1-,1625.9405956727653 -Li3Co3(CO6)2,Co1+,C3+,Li1+,O1-,1626.6023813621894 -Li3Co3(CO6)2,Co5+,C3+,Li1+,O2-,1626.6023813621894 -Li3Co3(CO6)2,Co5+,C3-,Li1+,O1-,1626.6023813621894 -Li3Fe2(CoO4)3,Co5+,Fe3+,Li1+,O2-,1630.099942971887 -Li3Fe2(CoO4)3,Co3+,Fe6+,Li1+,O2-,1630.099942971887 -Li3Fe2(CoO4)3,Co1+,Fe3+,Li1+,O1-,1630.099942971887 -Li3Fe2(CoO4)3,Co1-,Fe6+,Li1+,O1-,1630.099942971887 -Li3In3(GaO6)2,In1+,Ga3+,Li1+,O1-,1632.3849695959243 -Li3Ca3V2O12,Ca1+,V3+,Li1+,O1-,1632.9101875048286 -Li3In3(GeO6)2,In1+,Ge3+,Li1+,O1-,1634.6072548878387 -Li3Y2Ti3O12,Ti1+,Y3+,Li1+,O1-,1638.8586906164685 -Li3In3(SeO6)2,In3+,Se6+,Li1+,O2-,1639.2977081048973 -Li3Zr2Ti3O12,Ti1+,Zr3+,Li1+,O1-,1647.128185028972 -Li3Co3(CuO6)2,Co5+,Cu3+,Li1+,O2-,1647.8376431565807 -Li3Co3(CuO6)2,Co1+,Cu3+,Li1+,O1-,1647.8376431565807 -Li3Co3(NiO6)2,Co1+,Ni3+,Li1+,O1-,1650.667599193877 -Li3Co3(NiO6)2,Co5+,Ni3+,Li1+,O2-,1650.667599193877 -Li3Ti3V2O12,Ti1+,V3+,Li1+,O1-,1657.4670117682792 -Li3Mg3Cr2O12,Mg1+,Cr3+,Li1+,O1-,1658.3022300454427 -Li3Fe3(PO6)2,Fe5+,P3-,Li1+,O1-,1659.3650316432131 -Li3Fe3(PO6)2,Fe5+,P3+,Li1+,O2-,1659.3650316432131 -Li3Fe3(PO6)2,Fe1+,P3+,Li1+,O1-,1659.3650316432131 -Li3Cr2(AgO4)3,Ag1+,Cr3+,Li1+,O1-,1659.6604439075684 -Li3Cr2(AgO4)3,Ag3+,Cr6+,Li1+,O2-,1659.6604439075684 -Li3Zn3(CoO6)2,Zn1+,Co3+,Li1+,O1-,1659.7234772086626 -Li3Sc2(AgO4)3,Ag1+,Sc3+,Li1+,O1-,1662.2211154187717 -Li3Mg3Sc2O12,Mg1+,Sc3+,Li1+,O1-,1662.5208858087417 -Li3Co3(ClO6)2,Co3+,Cl6+,Li1+,O2-,1665.87460319568 -Li3Co3(ClO6)2,Co1+,Cl3+,Li1+,O1-,1665.87460319568 -Li3Co3(ClO6)2,Co5+,Cl3+,Li1+,O2-,1665.87460319568 -Na3Li3Cr2O12,Na1+,Cr3+,Li1+,O1-,1670.1492307246435 -Na3Li3Sc2O12,Na1+,Sc3+,Li1+,O1-,1674.8614491872584 -Li3CoO6,Li1+,Co3+,Li1+,O1-,1676.074407322407 -Li3Ti2(CoO4)3,Co1+,Ti3+,Li1+,O1-,1677.1140639232497 -Li3Ti2(CoO4)3,Co5+,Ti3+,Li1+,O2-,1677.1140639232497 -Li3In5O12,In1+,In3+,Li1+,O1-,1692.2394014633007 -Li3Y3(AgO6)2,Y1+,Ag3+,Li1+,O1-,1695.6722049247792 -Li3Y2Mn3O12,Mn1+,Y3+,Li1+,O1-,1696.7198776879593 -Li3Y2Mn3O12,Mn5+,Y3+,Li1+,O2-,1696.7198776879593 -Li3Zr2Mn3O12,Mn5+,Zr3+,Li1+,O2-,1704.1971899857117 -Li3Zr2Mn3O12,Mn1+,Zr3+,Li1+,O1-,1704.1971899857117 -Li3Zr3(AgO6)2,Zr1+,Ag3+,Li1+,O1-,1704.628180002911 -Li3Hf2Cd3O12,Cd1+,Hf3+,Li1+,O1-,1708.8805779926724 -Li3Co3(BO6)2,Co1+,B3+,Li1+,O1-,1712.0424970604263 -Li3Co3(BO6)2,Co5+,B3+,Li1+,O2-,1712.0424970604263 -Li3Mn2(CoO4)3,Co5+,Mn3+,Li1+,O2-,1718.9259166034815 -Li3Mn2(CoO4)3,Co1-,Mn6+,Li1+,O1-,1718.9259166034815 -Li3Mn2(CoO4)3,Co3+,Mn6+,Li1+,O2-,1718.9259166034815 -Li3Mn2(CoO4)3,Co1+,Mn3+,Li1+,O1-,1718.9259166034815 -Li3Ca3(PO6)2,Ca1+,P3+,Li1+,O1-,1720.8632340000358 -Li3Mn3V2O12,Mn1+,V3+,Li1+,O1-,1723.6670435178146 -Li3Mn3V2O12,Mn5+,V3+,Li1+,O2-,1723.6670435178146 -Li3V3(AgO6)2,V1+,Ag3+,Li1+,O1-,1728.8055403665126 -Li3V3(AgO6)2,V5+,Ag3+,Li1+,O2-,1728.8055403665126 -Li3Y3(SO6)2,Y1+,S3+,Li1+,O1-,1730.9399833555083 -Li3Y3(SO6)2,Y3+,S6+,Li1+,O2-,1730.9399833555083 -Li3Y2Zn3O12,Zn1+,Y3+,Li1+,O1-,1735.6852848534004 -Li3Cr2O15,O1-,Cr6+,Li1+,O1-,1737.4159759346194 -Li3Y3(SiO6)2,Y1+,Si3+,Li1+,O1-,1741.7996139101726 -Li3Zr3(SO6)2,Zr3+,S6+,Li1+,O2-,1741.9164436747233 -Li3Zr3(SO6)2,Zr1+,S3+,Li1+,O1-,1741.9164436747233 -Li3Zr2Zn3O12,Zn1+,Zr3+,Li1+,O1-,1742.4600686942217 -Li3Ti3(PO6)2,Ti1+,P3+,Li1+,O1-,1742.8516978421897 -Li3Cr2(FeO4)3,Fe5+,Cr3+,Li1+,O2-,1743.3306974602708 -Li3Cr2(FeO4)3,Fe3+,Cr6+,Li1+,O2-,1743.3306974602708 -Li3Cr2(FeO4)3,Fe1+,Cr3+,Li1+,O1-,1743.3306974602708 -Li3Cr2(FeO4)3,Fe1-,Cr6+,Li1+,O1-,1743.3306974602708 -Li3Y3Al2O12,Y1+,Al3+,Li1+,O1-,1744.8696181259074 -Li3Cd3(AsO6)2,Cd1+,As3+,Li1+,O1-,1744.8816388814275 -Li3Y3(FeO6)2,Y3+,Fe6+,Li1+,O2-,1747.7060572793685 -Li3Y3(FeO6)2,Y1+,Fe3+,Li1+,O1-,1747.7060572793685 -Li3Sc2(FeO4)3,Fe5+,Sc3+,Li1+,O2-,1749.2464125747742 -Li3Sc2(FeO4)3,Fe1+,Sc3+,Li1+,O1-,1749.2464125747742 -Li3Ga2(CoO4)3,Co1+,Ga3+,Li1+,O1-,1749.8144936433036 -Li3Ga2(CoO4)3,Co5+,Ga3+,Li1+,O2-,1749.8144936433036 -Li3Hf2(AgO4)3,Ag1+,Hf3+,Li1+,O1-,1751.3395337633608 -Li3Co3(GeO6)2,Co5+,Ge3+,Li1+,O2-,1751.4525377705395 -Li3Co3(GeO6)2,Co5+,Ge3-,Li1+,O1-,1751.4525377705395 -Li3Co3(GeO6)2,Co1+,Ge3+,Li1+,O1-,1751.4525377705395 -Li3Zr3(SiO6)2,Zr1+,Si3+,Li1+,O1-,1752.7978906819537 -Li3Co3(SeO6)2,Co3+,Se6+,Li1+,O2-,1754.8817954477956 -Li3Y3(NO6)2,Y1+,N3+,Li1+,O1-,1755.356191326218 -Li3Zr3Al2O12,Zr1+,Al3+,Li1+,O1-,1755.8733221351135 -Li3Zr3(FeO6)2,Zr3+,Fe6+,Li1+,O2-,1757.614876379565 -Li3Zr3(FeO6)2,Zr1+,Fe3+,Li1+,O1-,1757.614876379565 -Li3Y3(CuO6)2,Y1+,Cu3+,Li1+,O1-,1759.8285828312319 -Li3In3(CoO6)2,In1+,Co3+,Li1+,O1-,1763.4964184041153 -Li3Y3(NiO6)2,Y1+,Ni3+,Li1+,O1-,1764.0530814716174 -Li3Y3(CO6)2,Y1+,C3+,Li1+,O1-,1765.308201342555 -Li3V2Zn3O12,Zn1+,V3+,Li1+,O1-,1766.7663288876781 -Li3Zr3(NO6)2,Zr1+,N3+,Li1+,O1-,1766.7731387215426 -Li3Zr3(CuO6)2,Zr1+,Cu3+,Li1+,O1-,1769.3512726461986 -Li3Zr3(NiO6)2,Zr1+,Ni3+,Li1+,O1-,1773.6801647229408 -Li3Zr3(CO6)2,Zr1+,C3+,Li1+,O1-,1776.6788531920683 -Li3YO6,Li1+,Y3+,Li1+,O1-,1782.0370129578164 -Li3V3(SO6)2,V3+,S6+,Li1+,O2-,1785.1077657064716 -Li3V3(SO6)2,V1+,S3+,Li1+,O1-,1785.1077657064716 -Li3V3(SO6)2,V5+,S3+,Li1+,O2-,1785.1077657064716 -Li3Hf2Mg3O12,Mg1+,Hf3+,Li1+,O1-,1786.2754134518977 -Li3Y3(ClO6)2,Y3+,Cl6+,Li1+,O2-,1786.3505398006155 -Li3Y3(ClO6)2,Y1+,Cl3+,Li1+,O1-,1786.3505398006155 -Li3Y3Ti2O12,Y1+,Ti3+,Li1+,O1-,1790.6335723729153 -Li3ZrO6,Li1+,Zr3+,Li1+,O1-,1791.1512693985967 -Li3La2Cd3O12,Cd1+,La3+,Li1+,O1-,1791.4505831627953 -Na3Li3Hf2O12,Na1+,Hf3+,Li1+,O1-,1794.220817407383 -Li3Ce2Cd3O12,Cd1+,Ce3+,Li1+,O1-,1795.2662520920637 -Li3Zr3(ClO6)2,Zr3+,Cl6+,Li1+,O2-,1796.5022215891172 -Li3Zr3(ClO6)2,Zr1+,Cl3+,Li1+,O1-,1796.5022215891172 -Li3Pr2Cd3O12,Cd1+,Pr3+,Li1+,O1-,1797.7495723159584 -Li3V3(SiO6)2,V1+,Si3+,Li1+,O1-,1799.921671135885 -Li3V3(SiO6)2,V5+,Si3-,Li1+,O1-,1799.921671135885 -Li3V3(SiO6)2,V5+,Si3+,Li1+,O2-,1799.921671135885 -Li3Zr3Ti2O12,Zr1+,Ti3+,Li1+,O1-,1800.3011910581156 -Li3V3(FeO6)2,V5+,Fe3+,Li1+,O2-,1800.4771538701818 -Li3V3(FeO6)2,V1+,Fe3+,Li1+,O1-,1800.4771538701818 -Li3V3(FeO6)2,V3+,Fe6+,Li1+,O2-,1800.4771538701818 -Li3Ag3(AsO6)2,Ag1+,As3+,Li1+,O1-,1800.8710355612627 -Li3Al2V3O12,V5+,Al3+,Li1+,O2-,1804.1308014524723 -Li3Al2V3O12,V1+,Al3+,Li1+,O1-,1804.1308014524723 -Li3Ca3Cr2O12,Ca1+,Cr3+,Li1+,O1-,1808.000192201207 -Li3Nd2Cd3O12,Cd1+,Nd3+,Li1+,O1-,1808.1061349061124 -Li3In2(CoO4)3,Co1+,In3+,Li1+,O1-,1808.770891162399 -Li3In2(CoO4)3,Co5+,In3+,Li1+,O2-,1808.770891162399 -Li3Mn3(PO6)2,Mn5+,P3-,Li1+,O1-,1810.9454866292403 -Li3Mn3(PO6)2,Mn1+,P3+,Li1+,O1-,1810.9454866292403 -Li3Mn3(PO6)2,Mn5+,P3+,Li1+,O2-,1810.9454866292403 -Li3V3(CuO6)2,V1+,Cu3+,Li1+,O1-,1813.7522139303633 -Li3V3(CuO6)2,V5+,Cu3+,Li1+,O2-,1813.7522139303633 -Li3Y2In3O12,In1+,Y3+,Li1+,O1-,1815.6781526946334 -Li3Ca3Sc2O12,Ca1+,Sc3+,Li1+,O1-,1816.7303235056613 -Li3V3(NiO6)2,V1+,Ni3+,Li1+,O1-,1820.0562659941852 -Li3V3(NiO6)2,V5+,Ni3+,Li1+,O2-,1820.0562659941852 -Li3Zr2In3O12,In1+,Zr3+,Li1+,O1-,1820.5940157178861 -Li3V3(NO6)2,V1+,N3+,Li1+,O1-,1821.5578819657992 -Li3V3(NO6)2,V5+,N3+,Li1+,O2-,1821.5578819657992 -Li3V3(NO6)2,V5+,N3-,Li1+,O1-,1821.5578819657992 -Li3Y3Mn2O12,Y1+,Mn3+,Li1+,O1-,1823.3430261992412 -Li3Y3Mn2O12,Y3+,Mn6+,Li1+,O2-,1823.3430261992412 -Li3Ti3Cr2O12,Ti3+,Cr6+,Li1+,O2-,1823.5582275759161 -Li3Ti3Cr2O12,Ti1+,Cr3+,Li1+,O1-,1823.5582275759161 -Li3Hf2(FeO4)3,Fe1+,Hf3+,Li1+,O1-,1825.7069960999868 -Li3Hf2(FeO4)3,Fe5+,Hf3+,Li1+,O2-,1825.7069960999868 -Li3Sm2Cd3O12,Cd1+,Sm3+,Li1+,O1-,1826.686521649595 -Li3Cd3(SbO6)2,Cd1+,Sb3+,Li1+,O1-,1826.9668616004055 -Li3Eu2Cd3O12,Cd1+,Eu3+,Li1+,O1-,1831.4697776333037 -Li3Sc2Ti3O12,Ti1+,Sc3+,Li1+,O1-,1832.3221142993507 -Li3Zr3Mn2O12,Zr3+,Mn6+,Li1+,O2-,1832.3999496347776 -Li3Zr3Mn2O12,Zr1+,Mn3+,Li1+,O1-,1832.3999496347776 -Li3V3(CO6)2,V5+,C3+,Li1+,O2-,1835.0969571810624 -Li3V3(CO6)2,V5+,C3-,Li1+,O1-,1835.0969571810624 -Li3V3(CO6)2,V1+,C3+,Li1+,O1-,1835.0969571810624 -Li3Y3(BO6)2,Y1+,B3+,Li1+,O1-,1836.0826238809984 -Li3La2(AgO4)3,Ag1+,La3+,Li1+,O1-,1839.4199294760626 -Li3VO6,Li1+,V3+,Li1+,O1-,1839.856009356173 -Sr3Li3(AgO6)2,Sr1+,Ag3+,Li1+,O1-,1842.6981184306555 -Li3Ce2(AgO4)3,Ag1+,Ce3+,Li1+,O1-,1843.1570641315695 -Li3Y3(GaO6)2,Y1+,Ga3+,Li1+,O1-,1844.756258831575 -Li3Y3(GeO6)2,Y1+,Ge3+,Li1+,O1-,1845.2720800539873 -Li3Pr2(AgO4)3,Ag1+,Pr3+,Li1+,O1-,1845.5890765949223 -Li3Y3(SeO6)2,Y3+,Se6+,Li1+,O2-,1846.3572746146838 -Li3Zr3(BO6)2,Zr1+,B3+,Li1+,O1-,1846.5382875905955 -Li3Gd2Cd3O12,Cd1+,Gd3+,Li1+,O1-,1846.981801374312 -Li3V2In3O12,In1+,V3+,Li1+,O1-,1848.984332616049 -Li3Tb2Cd3O12,Cd1+,Tb3+,Li1+,O1-,1851.8193293117463 -Li3Zn3(PO6)2,Zn1+,P3+,Li1+,O1-,1851.8781128930366 -Li3Zr3(GaO6)2,Zr1+,Ga3+,Li1+,O1-,1853.147409518387 -Li3Zr3(GeO6)2,Zr1+,Ge3+,Li1+,O1-,1853.5800653341307 -Li3V3(ClO6)2,V5+,Cl3+,Li1+,O2-,1854.1339143179084 -Li3V3(ClO6)2,V3+,Cl6+,Li1+,O2-,1854.1339143179084 -Li3V3(ClO6)2,V1+,Cl3+,Li1+,O1-,1854.1339143179084 -Li3Zr3(SeO6)2,Zr3+,Se6+,Li1+,O2-,1854.4905881027512 -Li3Nd2(AgO4)3,Ag1+,Nd3+,Li1+,O1-,1855.7299973184772 -Li3Ti2V3O12,V1+,Ti3+,Li1+,O1-,1855.8266032590027 -Li3Ti2V3O12,V5+,Ti3+,Li1+,O2-,1855.8266032590027 -Li3Dy2Cd3O12,Cd1+,Dy3+,Li1+,O1-,1862.0171812132078 -Li3Ho2Cd3O12,Cd1+,Ho3+,Li1+,O1-,1868.8558267996307 -Li3Ca3Hf2O12,Ca1+,Hf3+,Li1+,O1-,1872.3133406702148 -Li3Sm2(AgO4)3,Ag1+,Sm3+,Li1+,O1-,1873.9167766840544 -Li3Er2Cd3O12,Cd1+,Er3+,Li1+,O1-,1875.3379620397238 -Li3Ag3(SbO6)2,Ag1+,Sb3+,Li1+,O1-,1877.6658319020273 -Li3Eu2(AgO4)3,Ag1+,Eu3+,Li1+,O1-,1878.597305593728 -Li3Tm2Cd3O12,Cd1+,Tm3+,Li1+,O1-,1879.9590371724069 -Li3Hf2Ti3O12,Ti1+,Hf3+,Li1+,O1-,1880.2475704965316 -Li3Mg3(AsO6)2,Mg1+,As3+,Li1+,O1-,1880.9279249909318 -Li3Mn3Cr2O12,Mn5+,Cr3+,Li1+,O2-,1882.1528271328311 -Li3Mn3Cr2O12,Mn3+,Cr6+,Li1+,O2-,1882.1528271328311 -Li3Mn3Cr2O12,Mn1+,Cr3+,Li1+,O1-,1882.1528271328311 -Li3Y3In2O12,Y1+,In3+,Li1+,O1-,1884.1629717922808 -Li3Zr3In2O12,Zr1+,In3+,Li1+,O1-,1891.1146368826173 -Li3Yb2Cd3O12,Cd1+,Yb3+,Li1+,O1-,1891.1387514830458 -Li3Gd3(AuO6)2,Gd1+,Au3+,Li1+,O1-,1891.3427414056482 -Li3Sc2Mn3O12,Mn5+,Sc3+,Li1+,O2-,1892.2837029408533 -Li3Sc2Mn3O12,Mn1+,Sc3+,Li1+,O1-,1892.2837029408533 -Na3Li3(AsO6)2,Na1+,As3+,Li1+,O1-,1893.5515559905496 -Li3Gd2(AgO4)3,Ag1+,Gd3+,Li1+,O1-,1893.7722494371976 -Li3Mn2V3O12,V1-,Mn6+,Li1+,O1-,1894.43157153847 -Li3Mn2V3O12,V1+,Mn3+,Li1+,O1-,1894.43157153847 -Li3Mn2V3O12,V5+,Mn3+,Li1+,O2-,1894.43157153847 -Li3Mn2V3O12,V3+,Mn6+,Li1+,O2-,1894.43157153847 -Li3Lu2Cd3O12,Cd1+,Lu3+,Li1+,O1-,1896.315462917736 -Li3Tb3(AuO6)2,Tb1+,Au3+,Li1+,O1-,1896.949231225298 -Li3Tb2(AgO4)3,Ag1+,Tb3+,Li1+,O1-,1898.5034259030888 -Li3Dy2(AgO4)3,Ag1+,Dy3+,Li1+,O1-,1908.475164971714 -Li3Ho2(AgO4)3,Ag1+,Ho3+,Li1+,O1-,1915.1607242841192 -Li3Zn3Cr2O12,Zn1+,Cr3+,Li1+,O1-,1915.3709201126626 -Li3V3(SeO6)2,V3+,Se6+,Li1+,O2-,1915.9288815443035 -Li3V3(GeO6)2,V5+,Ge3-,Li1+,O1-,1916.3229568290787 -Li3V3(GeO6)2,V5+,Ge3+,Li1+,O2-,1916.3229568290787 -Li3V3(GeO6)2,V1+,Ge3+,Li1+,O1-,1916.3229568290787 -Li3V3(GaO6)2,V5+,Ga3+,Li1+,O2-,1916.5114951642918 -Li3V3(GaO6)2,V1+,Ga3+,Li1+,O1-,1916.5114951642918 -Li3Hf2Mn3O12,Mn5+,Hf3+,Li1+,O2-,1917.0261330593087 -Li3Hf2Mn3O12,Mn1+,Hf3+,Li1+,O1-,1917.0261330593087 -Li3La2Mg3O12,Mg1+,La3+,Li1+,O1-,1918.4460302798514 -Li3Fe3(AsO6)2,Fe1+,As3+,Li1+,O1-,1918.8727145158189 -Li3Fe3(AsO6)2,Fe5+,As3-,Li1+,O1-,1918.8727145158189 -Li3Fe3(AsO6)2,Fe5+,As3+,Li1+,O2-,1918.8727145158189 -Li3In3(PO6)2,In1+,P3+,Li1+,O1-,1919.0247532544813 -Sr3Li3(SO6)2,Sr1+,S3+,Li1+,O1-,1919.510683286471 -Sr3Li3(FeO6)2,Sr1+,Fe3+,Li1+,O1-,1921.1179813329275 -Li3Er2(AgO4)3,Ag1+,Er3+,Li1+,O1-,1921.496675310217 -Li3Ce2Mg3O12,Mg1+,Ce3+,Li1+,O1-,1923.5004491461277 -Li3Cr3(AgO6)2,Cr1+,Ag3+,Li1+,O1-,1924.6501996012255 -Li3Cr3(AgO6)2,Cr5+,Ag3+,Li1+,O2-,1924.6501996012255 -Li3Sc2Zn3O12,Zn1+,Sc3+,Li1+,O1-,1925.8013891058758 -Li3Tm2(AgO4)3,Ag1+,Tm3+,Li1+,O1-,1926.0128958300077 -Li3Pr2Mg3O12,Mg1+,Pr3+,Li1+,O1-,1926.7825644471877 -Li3V3(BO6)2,V1+,B3+,Li1+,O1-,1927.1183897838753 -Li3V3(BO6)2,V5+,B3+,Li1+,O2-,1927.1183897838753 -Na3Li3La2O12,Na1+,La3+,Li1+,O1-,1928.447443625534 -Sr3Li3(CuO6)2,Sr1+,Cu3+,Li1+,O1-,1928.887044065725 -Li3Co5O12,Co1+,Co3+,Li1+,O1-,1929.2340744650387 -Li3Co5O12,Co5+,Co3+,Li1+,O2-,1929.2340744650387 -Sr3Li3(SiO6)2,Sr1+,Si3+,Li1+,O1-,1933.2710096215676 -Na3Li3Ce2O12,Na1+,Ce3+,Li1+,O1-,1933.4942633621024 -Sr3Li3(NiO6)2,Sr1+,Ni3+,Li1+,O1-,1935.9055856835353 -Na3Li3Pr2O12,Na1+,Pr3+,Li1+,O1-,1936.7712810986527 -Li3Yb2(AgO4)3,Ag1+,Yb3+,Li1+,O1-,1936.9367311334934 -Sr3Li3Al2O12,Sr1+,Al3+,Li1+,O1-,1937.1615668095442 -Li3Hf2Zn3O12,Zn1+,Hf3+,Li1+,O1-,1937.843494997799 -Li3Sc3(AgO6)2,Sc1+,Ag3+,Li1+,O1-,1938.8536013748721 -Li3Nd2Mg3O12,Mg1+,Nd3+,Li1+,O1-,1940.4078404109403 -Li3Lu2(AgO4)3,Ag1+,Lu3+,Li1+,O1-,1941.9939022133813 -Li3La2(FeO4)3,Fe1+,La3+,Li1+,O1-,1943.6193814608548 -Li3La2(FeO4)3,Fe5+,La3+,Li1+,O2-,1943.6193814608548 -Li3Ce2(FeO4)3,Fe1+,Ce3+,Li1+,O1-,1947.8575585074273 -Li3Ce2(FeO4)3,Fe5+,Ce3+,Li1+,O2-,1947.8575585074273 -Na3Li3Nd2O12,Na1+,Nd3+,Li1+,O1-,1950.374022771123 -Li3Pr2(FeO4)3,Fe1+,Pr3+,Li1+,O1-,1950.6124369701197 -Li3Pr2(FeO4)3,Fe5+,Pr3+,Li1+,O2-,1950.6124369701197 -Li3V3In2O12,V5+,In3+,Li1+,O2-,1952.5862192061065 -Li3V3In2O12,V1+,In3+,Li1+,O1-,1952.5862192061065 -Sr3Li3(NO6)2,Sr1+,N3+,Li1+,O1-,1957.6351845542847 -Li3Nd2(FeO4)3,Fe1+,Nd3+,Li1+,O1-,1962.0725476604987 -Li3Nd2(FeO4)3,Fe5+,Nd3+,Li1+,O2-,1962.0725476604987 -K3Li3(AuO6)2,K1+,Au3+,Li1+,O1-,1963.8443742960217 -Li3Cr2In3O12,In1+,Cr3+,Li1+,O1-,1964.0158061403802 -Li3Cr2In3O12,In3+,Cr6+,Li1+,O2-,1964.0158061403802 -Li3Sm2Mg3O12,Mg1+,Sm3+,Li1+,O1-,1964.6021456531394 -Sr3Li3Ti2O12,Sr1+,Ti3+,Li1+,O1-,1969.1776374853916 -Sr3Li3(CO6)2,Sr1+,C3+,Li1+,O1-,1969.279995965557 -Li3Hf2In3O12,In1+,Hf3+,Li1+,O1-,1969.384078618338 -Li3Eu2Mg3O12,Mg1+,Eu3+,Li1+,O1-,1970.7792031595225 -Sr3Li3(ClO6)2,Sr1+,Cl3+,Li1+,O1-,1972.974584956909 -Li3Sc2In3O12,In1+,Sc3+,Li1+,O1-,1973.115676720759 -Na3Li3Sm2O12,Na1+,Sm3+,Li1+,O1-,1974.522864159886 -Li3Y2(CoO4)3,Co5+,Y3+,Li1+,O2-,1979.3244439503621 -Li3Y2(CoO4)3,Co1+,Y3+,Li1+,O1-,1979.3244439503621 -Li3Mg3(SbO6)2,Mg1+,Sb3+,Li1+,O1-,1979.9280416770273 -Na3Li3Eu2O12,Na1+,Eu3+,Li1+,O1-,1980.6871971813714 -Li3Sm2(FeO4)3,Fe1+,Sm3+,Li1+,O1-,1982.516355127837 -Li3Sm2(FeO4)3,Fe5+,Sm3+,Li1+,O2-,1982.516355127837 -Li3Zr2(CoO4)3,Co1+,Zr3+,Li1+,O1-,1984.354722335533 -Li3Zr2(CoO4)3,Co5+,Zr3+,Li1+,O2-,1984.354722335533 -Li3PO6,Li1+,P3+,Li1+,O1-,1985.3488634338846 -Li3Eu2(FeO4)3,Fe5+,Eu3+,Li1+,O2-,1987.7552833728007 -Li3Eu2(FeO4)3,Fe1+,Eu3+,Li1+,O1-,1987.7552833728007 -Li3Gd2Mg3O12,Mg1+,Gd3+,Li1+,O1-,1990.6684228799988 -Na3Li3(SbO6)2,Na1+,Sb3+,Li1+,O1-,1991.044134751812 -Li3Ca3(AsO6)2,Ca1+,As3+,Li1+,O1-,1994.5967326095015 -Li3Tb2Mg3O12,Mg1+,Tb3+,Li1+,O1-,1996.8267251398524 -Li3Fe3(SbO6)2,Fe5+,Sb3+,Li1+,O2-,1997.1603094743332 -Li3Fe3(SbO6)2,Fe5+,Sb3-,Li1+,O1-,1997.1603094743332 -Li3Fe3(SbO6)2,Fe1+,Sb3+,Li1+,O1-,1997.1603094743332 -Sr3Li3Mn2O12,Sr1+,Mn3+,Li1+,O1-,1997.7904298114386 -Li3Ti3(AsO6)2,Ti1+,As3+,Li1+,O1-,2000.133133172678 -Na3Li3Gd2O12,Na1+,Gd3+,Li1+,O1-,2000.5323598322789 -Li3Y3(CoO6)2,Y1+,Co3+,Li1+,O1-,2000.599938326053 -Li3Gd2(FeO4)3,Fe5+,Gd3+,Li1+,O2-,2004.677838753298 -Li3Gd2(FeO4)3,Fe1+,Gd3+,Li1+,O1-,2004.677838753298 -Li3Ca3La2O12,Ca1+,La3+,Li1+,O1-,2005.3963756125493 -Li3Cd3(ReO6)2,Cd1+,Re3+,Li1+,O1-,2006.3921276825474 -Na3Li3Tb2O12,Na1+,Tb3+,Li1+,O1-,2006.6760660181726 -Li3Zr3(CoO6)2,Zr1+,Co3+,Li1+,O1-,2007.497379971834 -Li3La2Ti3O12,Ti1+,La3+,Li1+,O1-,2009.417806291475 -Li3Ca3Ce2O12,Ca1+,Ce3+,Li1+,O1-,2009.7175556163581 -Li3Dy2Mg3O12,Mg1+,Dy3+,Li1+,O1-,2009.7406254932616 -Sr3Li3(GeO6)2,Sr1+,Ge3+,Li1+,O1-,2009.9095620010314 -Li3Tb2(FeO4)3,Fe5+,Tb3+,Li1+,O2-,2009.934338439548 -Li3Tb2(FeO4)3,Fe1+,Tb3+,Li1+,O1-,2009.934338439548 -Sr3Li3(GaO6)2,Sr1+,Ga3+,Li1+,O1-,2010.9519773157122 -Li3Ca3Pr2O12,Ca1+,Pr3+,Li1+,O1-,2012.5250725728295 -Li3Ce2Ti3O12,Ti1+,Ce3+,Li1+,O1-,2013.5650927167385 -Li3Hf3(FeO6)2,Hf3+,Fe6+,Li1+,O2-,2014.0578374414724 -Li3Pr2Ti3O12,Ti1+,Pr3+,Li1+,O1-,2016.2602758463574 -Li3Ho2Mg3O12,Mg1+,Ho3+,Li1+,O1-,2018.349189520894 -Li3Hf3(SO6)2,Hf3+,S6+,Li1+,O2-,2018.430709988654 -Na3Li3Dy2O12,Na1+,Dy3+,Li1+,O1-,2019.5578930442855 -Li3Dy2(FeO4)3,Fe1+,Dy3+,Li1+,O1-,2020.983034257564 -Li3Dy2(FeO4)3,Fe5+,Dy3+,Li1+,O2-,2020.983034257564 -Li3Hg3(AuO6)2,Hg1+,Au3+,Li1+,O1-,2021.377622797335 -Li3Ca3Nd2O12,Ca1+,Nd3+,Li1+,O1-,2024.1930527350246 -Li3Er2Mg3O12,Mg1+,Er3+,Li1+,O1-,2026.471151576593 -Li3Nd2Ti3O12,Ti1+,Nd3+,Li1+,O1-,2027.4668600194018 -Na3Li3Ho2O12,Na1+,Ho3+,Li1+,O1-,2028.1439743524597 -Li3Ho2(FeO4)3,Fe1+,Ho3+,Li1+,O1-,2028.3677548196074 -Li3Ho2(FeO4)3,Fe5+,Ho3+,Li1+,O2-,2028.3677548196074 -Sr3Li3In2O12,Sr1+,In3+,Li1+,O1-,2029.32235076742 -Li3HfO6,Li1+,Hf3+,Li1+,O1-,2030.171745294935 -Li3Tm2Mg3O12,Mg1+,Tm3+,Li1+,O1-,2032.2389146028763 -Li3Er2(FeO4)3,Fe5+,Er3+,Li1+,O2-,2035.3494235585608 -Li3Er2(FeO4)3,Fe1+,Er3+,Li1+,O1-,2035.3494235585608 -Na3Li3Er2O12,Na1+,Er3+,Li1+,O1-,2036.2439162740664 -Li3Y5O12,Y1+,Y3+,Li1+,O1-,2037.3303944404847 -Li3Cr3(FeO6)2,Cr5+,Fe3+,Li1+,O2-,2038.2581804854628 -Li3Cr3(FeO6)2,Cr3+,Fe6+,Li1+,O2-,2038.2581804854628 -Li3Cr3(FeO6)2,Cr1+,Fe3+,Li1+,O1-,2038.2581804854628 -Li3Tm2(FeO4)3,Fe5+,Tm3+,Li1+,O2-,2040.3159107883523 -Li3Tm2(FeO4)3,Fe1+,Tm3+,Li1+,O1-,2040.3159107883523 -Li3Y3Zr2O12,Y1+,Zr3+,Li1+,O1-,2041.2711475935087 -Sr3Li3(BO6)2,Sr1+,B3+,Li1+,O1-,2041.5875557864924 -Na3Li3Tm2O12,Na1+,Tm3+,Li1+,O1-,2041.9955653778172 -Li3Y2Zr3O12,Zr1+,Y3+,Li1+,O1-,2043.2208965985974 -Li3Cr3(CuO6)2,Cr1+,Cu3+,Li1+,O1-,2044.0633229420437 -Li3Cr3(CuO6)2,Cr5+,Cu3+,Li1+,O2-,2044.0633229420437 -Li3Ca3Sm2O12,Ca1+,Sm3+,Li1+,O1-,2044.9633289563496 -Li3Yb2Mg3O12,Mg1+,Yb3+,Li1+,O1-,2046.1164956344526 -Li3La2Mn3O12,Mn1+,La3+,Li1+,O1-,2046.4582057077232 -Li3La2Mn3O12,Mn5+,La3+,Li1+,O2-,2046.4582057077232 -Li3Mn3(AsO6)2,Mn1+,As3+,Li1+,O1-,2046.5331243836715 -Li3Mn3(AsO6)2,Mn5+,As3+,Li1+,O2-,2046.5331243836715 -Li3Mn3(AsO6)2,Mn5+,As3-,Li1+,O1-,2046.5331243836715 -Li3Zr5O12,Zr1+,Zr3+,Li1+,O1-,2047.0798542999196 -Li3Sm2Ti3O12,Ti1+,Sm3+,Li1+,O1-,2047.4376111640684 -Li3Cr3(SO6)2,Cr5+,S3+,Li1+,O2-,2049.1225569896205 -Li3Cr3(SO6)2,Cr3+,S6+,Li1+,O2-,2049.1225569896205 -Li3Cr3(SO6)2,Cr1+,S3+,Li1+,O1-,2049.1225569896205 -Li3V2(CoO4)3,Co1+,V3+,Li1+,O1-,2049.2724091046607 -Li3V2(CoO4)3,Co5+,V3+,Li1+,O2-,2049.2724091046607 -Li3Ca3Eu2O12,Ca1+,Eu3+,Li1+,O1-,2050.2767914360593 -Li3Ce2Mn3O12,Mn5+,Ce3+,Li1+,O2-,2050.3354446248663 -Li3Ce2Mn3O12,Mn1+,Ce3+,Li1+,O1-,2050.3354446248663 -Li3Yb2(FeO4)3,Fe5+,Yb3+,Li1+,O2-,2052.29458883076 -Li3Yb2(FeO4)3,Fe1+,Yb3+,Li1+,O1-,2052.29458883076 -Li3Lu2Mg3O12,Mg1+,Lu3+,Li1+,O1-,2052.5061321627377 -Li3Eu2Ti3O12,Ti1+,Eu3+,Li1+,O1-,2052.55103091597 -Li3Re2(AgO4)3,Ag1+,Re3+,Li1+,O1-,2052.5913631790345 -Li3Re2(AgO4)3,Ag3+,Re6+,Li1+,O2-,2052.5913631790345 -Li3Pr2Mn3O12,Mn5+,Pr3+,Li1+,O2-,2052.8556446389366 -Li3Pr2Mn3O12,Mn1+,Pr3+,Li1+,O1-,2052.8556446389366 -Li3Hf3(ClO6)2,Hf3+,Cl6+,Li1+,O2-,2053.284713054989 -Li3Cr3(NiO6)2,Cr1+,Ni3+,Li1+,O1-,2054.9237552574514 -Li3Cr3(NiO6)2,Cr5+,Ni3+,Li1+,O2-,2054.9237552574514 -Na3Li3Yb2O12,Na1+,Yb3+,Li1+,O1-,2055.832754205117 -Li3Lu2(FeO4)3,Fe5+,Lu3+,Li1+,O2-,2057.8237421893486 -Li3Lu2(FeO4)3,Fe1+,Lu3+,Li1+,O1-,2057.8237421893486 -Li3Sc3(FeO6)2,Sc3+,Fe6+,Li1+,O2-,2060.9019410295327 -Li3Sc3(FeO6)2,Sc1+,Fe3+,Li1+,O1-,2060.9019410295327 -Na3Li3Lu2O12,Na1+,Lu3+,Li1+,O1-,2062.2030230720084 -Li3Nd2Mn3O12,Mn5+,Nd3+,Li1+,O2-,2063.338973684735 -Li3Nd2Mn3O12,Mn1+,Nd3+,Li1+,O1-,2063.338973684735 -Li3La2Zn3O12,Zn1+,La3+,Li1+,O1-,2063.755544229839 -Li3CrO6,Li1+,Cr3+,Li1+,O1-,2065.2061570175724 -Li3Sc3(CuO6)2,Sc1+,Cu3+,Li1+,O1-,2066.2307503561005 -Li3Hf3Mn2O12,Hf3+,Mn6+,Li1+,O2-,2066.570402001888 -Li3Ca3(SbO6)2,Ca1+,Sb3+,Li1+,O1-,2067.003856254698 -Li3Ce2Zn3O12,Zn1+,Ce3+,Li1+,O1-,2067.395326218223 -Li3Ca3Gd2O12,Ca1+,Gd3+,Li1+,O1-,2067.4147378317466 -Li3Zn3(AsO6)2,Zn1+,As3+,Li1+,O1-,2067.7868116216905 -Li3Cr3(SiO6)2,Cr5+,Si3-,Li1+,O1-,2068.7706879767775 -Li3Cr3(SiO6)2,Cr5+,Si3+,Li1+,O2-,2068.7706879767775 -Li3Cr3(SiO6)2,Cr1+,Si3+,Li1+,O1-,2068.7706879767775 -Li3Ti3(SbO6)2,Ti1+,Sb3+,Li1+,O1-,2068.8555861217387 -Li3Gd2Ti3O12,Ti1+,Gd3+,Li1+,O1-,2069.0562525785613 -Li3Pr2Zn3O12,Zn1+,Pr3+,Li1+,O1-,2069.761836765032 -Li3Hf3(SeO6)2,Hf3+,Se6+,Li1+,O2-,2069.86426262114 -Li3Ca3Tb2O12,Ca1+,Tb3+,Li1+,O1-,2072.730271370202 -Li3Tb2Ti3O12,Ti1+,Tb3+,Li1+,O1-,2074.179416922809 -Li3Al2Cr3O12,Cr1+,Al3+,Li1+,O1-,2074.352396532263 -Li3Al2Cr3O12,Cr5+,Al3+,Li1+,O2-,2074.352396532263 -Li3Sc3(SO6)2,Sc1+,S3+,Li1+,O1-,2074.9386246497734 -Li3Sc3(SO6)2,Sc3+,S6+,Li1+,O2-,2074.9386246497734 -Li3La2In3O12,In1+,La3+,Li1+,O1-,2075.936889647341 -Li3Sc3(NiO6)2,Sc1+,Ni3+,Li1+,O1-,2078.0469902943887 -Li3Ce2In3O12,In1+,Ce3+,Li1+,O1-,2078.8972632655837 -Li3Nd2Zn3O12,Zn1+,Nd3+,Li1+,O1-,2079.6114213819455 -Li3Pr2In3O12,In1+,Pr3+,Li1+,O1-,2080.8240189225144 -Li3In3(AsO6)2,In1+,As3+,Li1+,O1-,2081.3275954479695 -Li3Sm2Mn3O12,Mn1+,Sm3+,Li1+,O1-,2082.0381489385713 -Li3Sm2Mn3O12,Mn5+,Sm3+,Li1+,O2-,2082.0381489385713 -Li3Ca3Dy2O12,Ca1+,Dy3+,Li1+,O1-,2083.89091524684 -Li3Dy2Ti3O12,Ti1+,Dy3+,Li1+,O1-,2084.942138203813 -Li3Eu2Mn3O12,Mn1+,Eu3+,Li1+,O1-,2086.8295561697187 -Li3Eu2Mn3O12,Mn5+,Eu3+,Li1+,O2-,2086.8295561697187 -Li3ScO6,Li1+,Sc3+,Li1+,O1-,2087.8117917028035 -Li3Nd2In3O12,In1+,Nd3+,Li1+,O1-,2088.8601387306803 -Li3Ca3Ho2O12,Ca1+,Ho3+,Li1+,O1-,2091.3413039625684 -Li3Ho2Ti3O12,Ti1+,Ho3+,Li1+,O1-,2092.1314038823716 -Li3Sc3(SiO6)2,Sc1+,Si3+,Li1+,O1-,2096.123075363948 -Li3Sm2Zn3O12,Zn1+,Sm3+,Li1+,O1-,2097.2024738405566 -Li3Ca3Er2O12,Ca1+,Er3+,Li1+,O1-,2098.3783220221226 -Li3Er2Ti3O12,Ti1+,Er3+,Li1+,O1-,2098.925108418334 -Li3Ti2Cr3O12,Cr5+,Ti3+,Li1+,O2-,2101.39799082142 -Li3Ti2Cr3O12,Cr1+,Ti3+,Li1+,O1-,2101.39799082142 -Li3Eu2Zn3O12,Zn1+,Eu3+,Li1+,O1-,2101.714544270256 -Li3Sc3Al2O12,Sc1+,Al3+,Li1+,O1-,2102.148658675656 -Li3Gd2Mn3O12,Mn1+,Gd3+,Li1+,O1-,2102.305317859139 -Li3Gd2Mn3O12,Mn5+,Gd3+,Li1+,O2-,2102.305317859139 -Li3Sm2In3O12,In1+,Sm3+,Li1+,O1-,2103.2802487861745 -Li3Ca3Tm2O12,Ca1+,Tm3+,Li1+,O1-,2103.380203327911 -Li3Tm2Ti3O12,Ti1+,Tm3+,Li1+,O1-,2103.756006789256 -Li3Y3V2O12,Y1+,V3+,Li1+,O1-,2104.035825617907 -Li3Mn3(SbO6)2,Mn1+,Sb3+,Li1+,O1-,2105.910939200211 -Li3Mn3(SbO6)2,Mn5+,Sb3-,Li1+,O1-,2105.910939200211 -Li3Mn3(SbO6)2,Mn5+,Sb3+,Li1+,O2-,2105.910939200211 -Li3Eu2In3O12,In1+,Eu3+,Li1+,O1-,2106.993074064983 -Li3Tb2Mn3O12,Mn5+,Tb3+,Li1+,O2-,2107.112030516853 -Li3Tb2Mn3O12,Mn1+,Tb3+,Li1+,O1-,2107.112030516853 -Li3Cr3(NO6)2,Cr1+,N3+,Li1+,O1-,2109.3115348995443 -Li3Cr3(NO6)2,Cr5+,N3-,Li1+,O1-,2109.3115348995443 -Li3Cr3(NO6)2,Cr5+,N3+,Li1+,O2-,2109.3115348995443 -Li3Zr3V2O12,Zr1+,V3+,Li1+,O1-,2109.8980438866106 -Li3V3(CoO6)2,V1+,Co3+,Li1+,O1-,2112.267677206286 -Li3V3(CoO6)2,V5+,Co3+,Li1+,O2-,2112.267677206286 -Li3Cr3(ClO6)2,Cr1+,Cl3+,Li1+,O1-,2113.583540610052 -Li3Cr3(ClO6)2,Cr3+,Cl6+,Li1+,O2-,2113.583540610052 -Li3Cr3(ClO6)2,Cr5+,Cl3+,Li1+,O2-,2113.583540610052 -Li3Yb2Ti3O12,Ti1+,Yb3+,Li1+,O1-,2115.4012374148892 -Li3Ca3Yb2O12,Ca1+,Yb3+,Li1+,O1-,2115.4306584691176 -Li3Gd2Zn3O12,Zn1+,Gd3+,Li1+,O1-,2116.300929260854 -Li3Dy2Mn3O12,Mn5+,Dy3+,Li1+,O2-,2117.2147227117507 -Li3Dy2Mn3O12,Mn1+,Dy3+,Li1+,O1-,2117.2147227117507 -Li3Gd2In3O12,In1+,Gd3+,Li1+,O1-,2119.035323315857 -Li3Lu2Ti3O12,Ti1+,Lu3+,Li1+,O1-,2120.773417401099 -Li3Tb2Zn3O12,Zn1+,Tb3+,Li1+,O1-,2120.8354043611616 -Li3Ca3Lu2O12,Ca1+,Lu3+,Li1+,O1-,2120.9864714214305 -Li3Zn3(SbO6)2,Zn1+,Sb3+,Li1+,O1-,2121.2553029378932 -Li3Tb2In3O12,In1+,Tb3+,Li1+,O1-,2122.791284171723 -Li3In3(SbO6)2,In1+,Sb3+,Li1+,O1-,2123.3150072590834 -Li3Ho2Mn3O12,Mn1+,Ho3+,Li1+,O1-,2123.9667072596694 -Li3Ho2Mn3O12,Mn5+,Ho3+,Li1+,O2-,2123.9667072596694 -Li3Cr3(CO6)2,Cr5+,C3+,Li1+,O2-,2125.665798172471 -Li3Cr3(CO6)2,Cr5+,C3-,Li1+,O1-,2125.665798172471 -Li3Cr3(CO6)2,Cr1+,C3+,Li1+,O1-,2125.665798172471 -Li3Sc3Ti2O12,Sc1+,Ti3+,Li1+,O1-,2127.8640003989376 -Li3Hf2(CoO4)3,Co1+,Hf3+,Li1+,O1-,2128.274446137917 -Li3Hf2(CoO4)3,Co5+,Hf3+,Li1+,O2-,2128.274446137917 -Li3Er2Mn3O12,Mn1+,Er3+,Li1+,O1-,2130.349845078186 -Li3Er2Mn3O12,Mn5+,Er3+,Li1+,O2-,2130.349845078186 -Li3Dy2Zn3O12,Zn1+,Dy3+,Li1+,O1-,2130.3720981937295 -Li3Dy2In3O12,In1+,Dy3+,Li1+,O1-,2130.7099030251293 -Li3Cr3(SeO6)2,Cr3+,Se6+,Li1+,O2-,2132.1466589434585 -Li3Mn2Cr3O12,Cr1+,Mn3+,Li1+,O1-,2132.492660705261 -Li3Mn2Cr3O12,Cr3+,Mn6+,Li1+,O2-,2132.492660705261 -Li3Mn2Cr3O12,Cr1-,Mn6+,Li1+,O1-,2132.492660705261 -Li3Mn2Cr3O12,Cr5+,Mn3+,Li1+,O2-,2132.492660705261 -Li3Tm2Mn3O12,Mn5+,Tm3+,Li1+,O2-,2134.8903660302617 -Li3Tm2Mn3O12,Mn1+,Tm3+,Li1+,O1-,2134.8903660302617 -Li3Ho2In3O12,In1+,Ho3+,Li1+,O1-,2136.020700631127 -Li3Ho2Zn3O12,Zn1+,Ho3+,Li1+,O1-,2136.7504852866837 -Li3Cr3(GeO6)2,Cr5+,Ge3-,Li1+,O1-,2137.854545588941 -Li3Cr3(GeO6)2,Cr5+,Ge3+,Li1+,O2-,2137.854545588941 -Li3Cr3(GeO6)2,Cr1+,Ge3+,Li1+,O1-,2137.854545588941 -Li3Cr3(GaO6)2,Cr1+,Ga3+,Li1+,O1-,2140.5847829641352 -Li3Cr3(GaO6)2,Cr5+,Ga3+,Li1+,O2-,2140.5847829641352 -Li3Sc3(NO6)2,Sc1+,N3+,Li1+,O1-,2140.9930050640605 -Li3Er2In3O12,In1+,Er3+,Li1+,O1-,2141.0550805920425 -Li3Sc3(ClO6)2,Sc1+,Cl3+,Li1+,O1-,2142.234181410593 -Li3Sc3(ClO6)2,Sc3+,Cl6+,Li1+,O2-,2142.234181410593 -Li3Cr3In2O12,Cr5+,In3+,Li1+,O2-,2142.699043730525 -Li3Cr3In2O12,Cr1+,In3+,Li1+,O1-,2142.699043730525 -Li3Er2Zn3O12,Zn1+,Er3+,Li1+,O1-,2142.7838853258536 -Li3Y2V3O12,V1+,Y3+,Li1+,O1-,2144.378381163378 -Li3Y2V3O12,V5+,Y3+,Li1+,O2-,2144.378381163378 -Li3Tm2In3O12,In1+,Tm3+,Li1+,O1-,2144.6443231973717 -Li3Yb2Mn3O12,Mn5+,Yb3+,Li1+,O2-,2145.840989456639 -Li3Yb2Mn3O12,Mn1+,Yb3+,Li1+,O1-,2145.840989456639 -Li3Tm2Zn3O12,Zn1+,Tm3+,Li1+,O1-,2147.077670087752 -Li3Zr2V3O12,V5+,Zr3+,Li1+,O2-,2148.2325019526966 -Li3Zr2V3O12,V1+,Zr3+,Li1+,O1-,2148.2325019526966 -Li3Lu2Mn3O12,Mn5+,Lu3+,Li1+,O2-,2150.895292796502 -Li3Lu2Mn3O12,Mn1+,Lu3+,Li1+,O1-,2150.895292796502 -Li3Yb2In3O12,In1+,Yb3+,Li1+,O1-,2153.328644119919 -Li3Sc3(SeO6)2,Sc3+,Se6+,Li1+,O2-,2156.6419820291762 -Li3Lu2In3O12,In1+,Lu3+,Li1+,O1-,2157.350310922419 -Li3Yb2Zn3O12,Zn1+,Yb3+,Li1+,O1-,2157.440220319132 -Li3Y3Hf2O12,Y1+,Hf3+,Li1+,O1-,2157.8455741322005 -Li3Sc3(CO6)2,Sc1+,C3+,Li1+,O1-,2158.616779842816 -Li3Sc3Mn2O12,Sc1+,Mn3+,Li1+,O1-,2159.575971853775 -Li3Sc3Mn2O12,Sc3+,Mn6+,Li1+,O2-,2159.575971853775 -Li3Hf2Zr3O12,Zr1+,Hf3+,Li1+,O1-,2161.4911677719056 -Li3Lu2Zn3O12,Zn1+,Lu3+,Li1+,O1-,2162.2264343257925 -Li3Co3(PO6)2,Co1+,P3+,Li1+,O1-,2163.0302941909695 -Li3Co3(PO6)2,Co5+,P3-,Li1+,O1-,2163.0302941909695 -Li3Co3(PO6)2,Co5+,P3+,Li1+,O2-,2163.0302941909695 -Li3Sc3(GeO6)2,Sc1+,Ge3+,Li1+,O1-,2163.2224984689333 -Li3Gd3(AgO6)2,Gd1+,Ag3+,Li1+,O1-,2163.6167944496856 -Li3Sc3In2O12,Sc1+,In3+,Li1+,O1-,2164.537546500072 -Li3Sc3(GaO6)2,Sc1+,Ga3+,Li1+,O1-,2166.3749249645166 -Li3Tb3(AgO6)2,Tb1+,Ag3+,Li1+,O1-,2168.815250159266 -Sr3Li3(CoO6)2,Sr1+,Co3+,Li1+,O1-,2173.850948994881 -Li3Fe3(ReO6)2,Fe3+,Re6+,Li1+,O2-,2187.8921543621595 -Li3Fe3(ReO6)2,Fe1+,Re3+,Li1+,O1-,2187.8921543621595 -Li3Fe3(ReO6)2,Fe5+,Re3-,Li1+,O1-,2187.8921543621595 -Li3Fe3(ReO6)2,Fe5+,Re3+,Li1+,O2-,2187.8921543621595 -Sr3Li3Y2O12,Sr1+,Y3+,Li1+,O1-,2194.905671493334 -Sr3Li3Zr2O12,Sr1+,Zr3+,Li1+,O1-,2197.759448906118 -Li3La3(FeO6)2,La3+,Fe6+,Li1+,O2-,2201.2830282028385 -Li3Mg3(ReO6)2,Mg1+,Re3+,Li1+,O1-,2201.455819448851 -Li3Cr2(CoO4)3,Co5+,Cr3+,Li1+,O2-,2202.518625194951 -Li3Cr2(CoO4)3,Co3+,Cr6+,Li1+,O2-,2202.518625194951 -Li3Cr2(CoO4)3,Co1+,Cr3+,Li1+,O1-,2202.518625194951 -Li3Cr2(CoO4)3,Co1-,Cr6+,Li1+,O1-,2202.518625194951 -Li3Y3(PO6)2,Y1+,P3+,Li1+,O1-,2202.942079169356 -Li3Ce3(FeO6)2,Ce3+,Fe6+,Li1+,O2-,2205.664789519769 -Li3Zr3(PO6)2,Zr1+,P3+,Li1+,O1-,2207.9769836269697 -Li3Pr3(FeO6)2,Pr3+,Fe6+,Li1+,O2-,2208.5072944530034 -Li3Cd3(MoO6)2,Cd1+,Mo3+,Li1+,O1-,2208.864112028001 -Na3Li3(ReO6)2,Na1+,Re3+,Li1+,O1-,2211.7178647603337 -Li3LaO6,Li1+,La3+,Li1+,O1-,2213.5577075471774 -Li3CeO6,Li1+,Ce3+,Li1+,O1-,2217.7341074838264 -Li3Cr3(BO6)2,Cr5+,B3+,Li1+,O2-,2218.7272572197403 -Li3Cr3(BO6)2,Cr1+,B3+,Li1+,O1-,2218.7272572197403 -Li3La3(SO6)2,La3+,S6+,Li1+,O2-,2219.241366774183 -Li3Nd3(FeO6)2,Nd3+,Fe6+,Li1+,O2-,2220.283934192938 -Li3PrO6,Li1+,Pr3+,Li1+,O1-,2220.444128778877 -Li3Sc2(CoO4)3,Co1+,Sc3+,Li1+,O1-,2221.8032001183064 -Li3Sc2(CoO4)3,Co5+,Sc3+,Li1+,O2-,2221.8032001183064 -Li3Ce3(SO6)2,Ce3+,S6+,Li1+,O2-,2223.828463697799 -Li3Pr3(SO6)2,Pr3+,S6+,Li1+,O2-,2226.802533341671 -Li3NdO6,Li1+,Nd3+,Li1+,O1-,2231.6780650069295 -Li3Y3Cr2O12,Y1+,Cr3+,Li1+,O1-,2233.4697255330125 -Li3Y3Cr2O12,Y3+,Cr6+,Li1+,O2-,2233.4697255330125 -Li3Zr3Cr2O12,Zr3+,Cr6+,Li1+,O2-,2237.7865804091584 -Li3Zr3Cr2O12,Zr1+,Cr3+,Li1+,O1-,2237.7865804091584 -Li3Nd3(SO6)2,Nd3+,S6+,Li1+,O2-,2239.1105296842848 -Li3Sm3(FeO6)2,Sm3+,Fe6+,Li1+,O2-,2241.1021449851196 -Li3V5O12,V1+,V3+,Li1+,O1-,2244.7191402011404 -Li3V5O12,V5+,V3+,Li1+,O2-,2244.7191402011404 -Li3Eu3(FeO6)2,Eu3+,Fe6+,Li1+,O2-,2246.398183080475 -Li3Y3Sc2O12,Y1+,Sc3+,Li1+,O1-,2250.4744908067305 -Li3SmO6,Li1+,Sm3+,Li1+,O1-,2251.561310490255 -Li3Ti3(ReO6)2,Ti1+,Re3+,Li1+,O1-,2253.171517998416 -Li3Ti3(ReO6)2,Ti3+,Re6+,Li1+,O2-,2253.171517998416 -Li3La3(SeO6)2,La3+,Se6+,Li1+,O2-,2254.5137958276855 -Li3Zr3Sc2O12,Zr1+,Sc3+,Li1+,O1-,2254.69163040259 -Li3EuO6,Li1+,Eu3+,Li1+,O1-,2256.6244790414885 -Li3Sc3(BO6)2,Sc1+,B3+,Li1+,O1-,2257.2145032778494 -Li3Hf2V3O12,V5+,Hf3+,Li1+,O2-,2257.3463546484923 -Li3Hf2V3O12,V1+,Hf3+,Li1+,O1-,2257.3463546484923 -Li3Ca3(ReO6)2,Ca1+,Re3+,Li1+,O1-,2257.7631906839156 -Li3La3(ClO6)2,La3+,Cl6+,Li1+,O2-,2258.0619509606704 -Li3Ce3(SeO6)2,Ce3+,Se6+,Li1+,O2-,2258.3951283037277 -Li3In3(ReO6)2,In1+,Re3+,Li1+,O1-,2260.2601013376807 -Li3In3(ReO6)2,In3+,Re6+,Li1+,O2-,2260.2601013376807 -Li3Sm3(SO6)2,Sm3+,S6+,Li1+,O2-,2260.8141085109896 -Li3Pr3(SeO6)2,Pr3+,Se6+,Li1+,O2-,2260.914187410499 -Li3Ce3(ClO6)2,Ce3+,Cl6+,Li1+,O2-,2262.4046649920224 -Li3Gd3(CuO6)2,Gd1+,Cu3+,Li1+,O1-,2262.672766774372 -Li3La3Mn2O12,La3+,Mn6+,Li1+,O2-,2262.6887377379994 -Li3Gd3(FeO6)2,Gd3+,Fe6+,Li1+,O2-,2263.3982697520073 -Li3Gd3(FeO6)2,Gd1+,Fe3+,Li1+,O1-,2263.3982697520073 -Li3Pr3(ClO6)2,Pr3+,Cl6+,Li1+,O2-,2265.220521491596 -Li3Eu3(SO6)2,Eu3+,S6+,Li1+,O2-,2266.324417217562 -Li3Ce3Mn2O12,Ce3+,Mn6+,Li1+,O2-,2266.781076854434 -Li3Tb3(CuO6)2,Tb1+,Cu3+,Li1+,O1-,2267.825860643626 -Li3Re2O15,O1-,Re6+,Li1+,O1-,2268.4061664992705 -Li3Tb3(FeO6)2,Tb1+,Fe3+,Li1+,O1-,2268.6458641238414 -Li3Tb3(FeO6)2,Tb3+,Fe6+,Li1+,O2-,2268.6458641238414 -Li3AsO6,Li1+,As3+,Li1+,O1-,2269.4217720779593 -Li3Pr3Mn2O12,Pr3+,Mn6+,Li1+,O2-,2269.435777532951 -Li3Ag3(MoO6)2,Ag1+,Mo3+,Li1+,O1-,2270.304176683138 -Li3Ag3(MoO6)2,Ag3+,Mo6+,Li1+,O2-,2270.304176683138 -Li3Nd3(SeO6)2,Nd3+,Se6+,Li1+,O2-,2271.36075417649 -Li3Gd3(NiO6)2,Gd1+,Ni3+,Li1+,O1-,2271.9026037199706 -Li3GdO6,Li1+,Gd3+,Li1+,O1-,2272.8907349744263 -Li3Nd3(ClO6)2,Nd3+,Cl6+,Li1+,O2-,2276.8757193475926 -Li3Tb3(NiO6)2,Tb1+,Ni3+,Li1+,O1-,2277.060186164777 -Li3TbO6,Li1+,Tb3+,Li1+,O1-,2277.9160255997626 -Li3Mn3(ReO6)2,Mn3+,Re6+,Li1+,O2-,2278.646040914923 -Li3Mn3(ReO6)2,Mn5+,Re3-,Li1+,O1-,2278.646040914923 -Li3Mn3(ReO6)2,Mn1+,Re3+,Li1+,O1-,2278.646040914923 -Li3Mn3(ReO6)2,Mn5+,Re3+,Li1+,O2-,2278.646040914923 -Li3Dy3(FeO6)2,Dy3+,Fe6+,Li1+,O2-,2279.6253425776026 -Li3Nd3Mn2O12,Nd3+,Mn6+,Li1+,O2-,2280.433895998942 -Li3La2(CoO4)3,Co1+,La3+,Li1+,O1-,2280.4401571963776 -Li3La2(CoO4)3,Co5+,La3+,Li1+,O2-,2280.4401571963776 -Li3Ag2(HgO4)3,Hg1+,Ag3+,Li1+,O1-,2281.782300721075 -Sr3Li3Hf2O12,Sr1+,Hf3+,Li1+,O1-,2282.072616319973 -Sr3Li3V2O12,Sr1+,V3+,Li1+,O1-,2282.772247604919 -Li3Ce2(CoO4)3,Co1+,Ce3+,Li1+,O1-,2283.402329770982 -Li3Ce2(CoO4)3,Co5+,Ce3+,Li1+,O2-,2283.402329770982 -Li3Gd3(SO6)2,Gd1+,S3+,Li1+,O1-,2283.9823597247373 -Li3Gd3(SO6)2,Gd3+,S6+,Li1+,O2-,2283.9823597247373 -Li3Zn3(ReO6)2,Zn1+,Re3+,Li1+,O1-,2284.515919498045 -Li3Pr2(CoO4)3,Co5+,Pr3+,Li1+,O2-,2285.327947887875 -Li3Pr2(CoO4)3,Co1+,Pr3+,Li1+,O1-,2285.327947887875 -Li3Ho3(FeO6)2,Ho3+,Fe6+,Li1+,O2-,2286.925894836933 -Li3DyO6,Li1+,Dy3+,Li1+,O1-,2288.436821788963 -Li3Cd3(IO6)2,Cd1+,I3+,Li1+,O1-,2289.1349058852134 -Li3Tb3(SO6)2,Tb3+,S6+,Li1+,O2-,2289.423817287505 -Li3Tb3(SO6)2,Tb1+,S3+,Li1+,O1-,2289.423817287505 -Li3Sm3(SeO6)2,Sm3+,Se6+,Li1+,O2-,2289.8671454114174 -Li3Nd2(CoO4)3,Co5+,Nd3+,Li1+,O2-,2293.3397580061214 -Li3Nd2(CoO4)3,Co1+,Nd3+,Li1+,O1-,2293.3397580061214 -Li3Er3(FeO6)2,Er3+,Fe6+,Li1+,O2-,2293.8002582166787 -Li3Eu3(SeO6)2,Eu3+,Se6+,Li1+,O2-,2294.5831243517337 -Li3La2Y3O12,Y1+,La3+,Li1+,O1-,2295.0361770074214 -Li3HoO6,Li1+,Ho3+,Li1+,O1-,2295.4372128568575 -Li3Sm3(ClO6)2,Sm3+,Cl6+,Li1+,O2-,2297.4358527700942 -Li3Ce2Y3O12,Y1+,Ce3+,Li1+,O1-,2297.601265969816 -Li3Gd3(SiO6)2,Gd1+,Si3+,Li1+,O1-,2297.7783741809503 -Li3La2Zr3O12,Zr1+,La3+,Li1+,O1-,2297.8110810440435 -Li3Tm3(FeO6)2,Tm3+,Fe6+,Li1+,O2-,2298.674095004666 -Li3Pr2Y3O12,Y1+,Pr3+,Li1+,O1-,2299.269933689381 -Li3Sm3Mn2O12,Sm3+,Mn6+,Li1+,O2-,2299.8741424943723 -Li3Ce2Zr3O12,Zr1+,Ce3+,Li1+,O1-,2300.3441413668984 -Li3Dy3(SO6)2,Dy3+,S6+,Li1+,O2-,2300.7949026602014 -Li3Gd3Al2O12,Gd1+,Al3+,Li1+,O1-,2301.6582420509308 -Li3Pr2Zr3O12,Zr1+,Pr3+,Li1+,O1-,2301.992052355379 -Li3ErO6,Li1+,Er3+,Li1+,O1-,2302.032467093591 -Li3Eu3(ClO6)2,Eu3+,Cl6+,Li1+,O2-,2302.6574139098 -Li3Gd3In2O12,Gd1+,In3+,Li1+,O1-,2302.7191589428066 -Li3SbO6,Li1+,Sb3+,Li1+,O1-,2302.959937027254 -Li3Tb3(SiO6)2,Tb1+,Si3+,Li1+,O1-,2303.1849266827917 -Li3Eu3Mn2O12,Eu3+,Mn6+,Li1+,O2-,2304.819281580563 -Li3Gd3Ti2O12,Gd1+,Ti3+,Li1+,O1-,2305.591261204988 -Li3Nd2Y3O12,Y1+,Nd3+,Li1+,O1-,2306.2226784329805 -Li3TmO6,Li1+,Tm3+,Li1+,O1-,2306.7104944011035 -Li3Tb3Al2O12,Tb1+,Al3+,Li1+,O1-,2307.0546229311576 -Li3Tb3In2O12,Tb1+,In3+,Li1+,O1-,2307.078440889275 -Li3Sm2(CoO4)3,Co1+,Sm3+,Li1+,O1-,2307.6375832885924 -Li3Sm2(CoO4)3,Co5+,Sm3+,Li1+,O2-,2307.6375832885924 -Li3Ho3(SO6)2,Ho3+,S6+,Li1+,O2-,2308.3453689571556 -Li3Nd2Zr3O12,Zr1+,Nd3+,Li1+,O1-,2308.858980417094 -Li3Gd3(SeO6)2,Gd3+,Se6+,Li1+,O2-,2309.743380837992 -Li3Yb3(FeO6)2,Yb3+,Fe6+,Li1+,O2-,2310.373864810678 -Li3Tb3Ti2O12,Tb1+,Ti3+,Li1+,O1-,2310.675441283386 -Li3Eu2(CoO4)3,Co1+,Eu3+,Li1+,O1-,2311.302672867394 -Li3Eu2(CoO4)3,Co5+,Eu3+,Li1+,O2-,2311.302672867394 -Li3Tb3(SeO6)2,Tb3+,Se6+,Li1+,O2-,2314.429886732557 -Li3Er3(SO6)2,Er3+,S6+,Li1+,O2-,2315.447422369038 -Li3Lu3(FeO6)2,Lu3+,Fe6+,Li1+,O2-,2315.7480020174085 -Li3Gd3(GeO6)2,Gd1+,Ge3+,Li1+,O1-,2315.9844877204896 -Li3YbO6,Li1+,Yb3+,Li1+,O1-,2317.9472530475123 -Li3Sm2Y3O12,Y1+,Sm3+,Li1+,O1-,2318.670762515791 -Li3Gd3(GaO6)2,Gd1+,Ga3+,Li1+,O1-,2318.9296561044393 -Li3Gd3(ClO6)2,Gd1+,Cl3+,Li1+,O1-,2319.3943175642025 -Li3Gd3(ClO6)2,Gd3+,Cl6+,Li1+,O2-,2319.3943175642025 -Li3Tm3(SO6)2,Tm3+,S6+,Li1+,O2-,2320.4782088048332 -Li3Gd3Mn2O12,Gd3+,Mn6+,Li1+,O2-,2320.6920294698966 -Li3Gd3Mn2O12,Gd1+,Mn3+,Li1+,O1-,2320.6920294698966 -Li3Tb3(GeO6)2,Tb1+,Ge3+,Li1+,O1-,2320.704375168477 -Li3Sm2Zr3O12,Zr1+,Sm3+,Li1+,O1-,2321.156116593357 -Li3Eu2Y3O12,Y1+,Eu3+,Li1+,O1-,2321.8700322613236 -Li3LuO6,Li1+,Lu3+,Li1+,O1-,2323.1120436044994 -Li3Gd2(CoO4)3,Co5+,Gd3+,Li1+,O2-,2323.1446355912244 -Li3Gd2(CoO4)3,Co1+,Gd3+,Li1+,O1-,2323.1446355912244 -Li3Tb3(GaO6)2,Tb1+,Ga3+,Li1+,O1-,2323.664902633818 -Li3Dy3(SeO6)2,Dy3+,Se6+,Li1+,O2-,2324.2458541114224 -Li3Eu2Zr3O12,Zr1+,Eu3+,Li1+,O1-,2324.3171505427904 -Li3Tb3(ClO6)2,Tb3+,Cl6+,Li1+,O2-,2324.5532581058583 -Li3Tb3(ClO6)2,Tb1+,Cl3+,Li1+,O1-,2324.5532581058583 -Li3Tb3Mn2O12,Tb3+,Mn6+,Li1+,O2-,2325.5913389097254 -Li3Tb3Mn2O12,Tb1+,Mn3+,Li1+,O1-,2325.5913389097254 -Li3Tb2(CoO4)3,Co1+,Tb3+,Li1+,O1-,2326.8239770108553 -Li3Tb2(CoO4)3,Co5+,Tb3+,Li1+,O2-,2326.8239770108553 -Li3Gd3(NO6)2,Gd1+,N3+,Li1+,O1-,2329.4038052191254 -Li3Ho3(SeO6)2,Ho3+,Se6+,Li1+,O2-,2330.780594236047 -Li3Gd2Y3O12,Y1+,Gd3+,Li1+,O1-,2332.2302898234693 -Li3Yb3(SO6)2,Yb3+,S6+,Li1+,O2-,2332.539596601185 -Li3Gd2Zr3O12,Zr1+,Gd3+,Li1+,O1-,2334.5551580186366 -Li3Dy2(CoO4)3,Co5+,Dy3+,Li1+,O2-,2334.559141208526 -Li3Dy2(CoO4)3,Co1+,Dy3+,Li1+,O1-,2334.559141208526 -Li3Tb3(NO6)2,Tb1+,N3+,Li1+,O1-,2334.8009995746265 -Li3Dy3(ClO6)2,Dy3+,Cl6+,Li1+,O2-,2335.335956530274 -Li3Tb2Y3O12,Y1+,Tb3+,Li1+,O1-,2335.4565469424674 -Li3Dy3Mn2O12,Dy3+,Mn6+,Li1+,O2-,2335.8416510439274 -Li3Co3(AsO6)2,Co5+,As3+,Li1+,O2-,2336.017471109483 -Li3Co3(AsO6)2,Co5+,As3-,Li1+,O1-,2336.017471109483 -Li3Co3(AsO6)2,Co1+,As3+,Li1+,O1-,2336.017471109483 -Li3Er3(SeO6)2,Er3+,Se6+,Li1+,O2-,2336.9395841528058 -Li3Tb2Zr3O12,Zr1+,Tb3+,Li1+,O1-,2337.743835462308 -Li3Lu3(SO6)2,Lu3+,S6+,Li1+,O2-,2338.072684208505 -Li3Gd3(CO6)2,Gd1+,C3+,Li1+,O1-,2339.7102008052084 -Li3Ho2(CoO4)3,Co5+,Ho3+,Li1+,O2-,2339.730310679915 -Li3Ho2(CoO4)3,Co1+,Ho3+,Li1+,O1-,2339.730310679915 -Li3Tm3(SeO6)2,Tm3+,Se6+,Li1+,O2-,2341.309602817053 -Li3Dy2Y3O12,Y1+,Dy3+,Li1+,O1-,2342.250485949402 -Li3Ho3(ClO6)2,Ho3+,Cl6+,Li1+,O2-,2342.4972199556496 -Li3Ho3Mn2O12,Ho3+,Mn6+,Li1+,O2-,2342.657020878175 -Li3Dy2Zr3O12,Zr1+,Dy3+,Li1+,O1-,2344.459399143154 -Li3Er2(CoO4)3,Co5+,Er3+,Li1+,O2-,2344.6200861185266 -Li3Er2(CoO4)3,Co1+,Er3+,Li1+,O1-,2344.6200861185266 -Li3Cr3(CoO6)2,Cr5+,Co3+,Li1+,O2-,2345.0040765775625 -Li3Cr3(CoO6)2,Cr1+,Co3+,Li1+,O1-,2345.0040765775625 -Li3Tb3(CO6)2,Tb1+,C3+,Li1+,O1-,2345.064998442784 -Li3Y3(AsO6)2,Y1+,As3+,Li1+,O1-,2345.6409839229 -Li3Y3Ho2O12,Y1+,Ho3+,Li1+,O1-,2346.8009862539257 -Li3Ag3(IO6)2,Ag1+,I3+,Li1+,O1-,2347.1443770994383 -Li3Tm2(CoO4)3,Co1+,Tm3+,Li1+,O1-,2348.098981392445 -Li3Tm2(CoO4)3,Co5+,Tm3+,Li1+,O2-,2348.098981392445 -Li3Zr3(AsO6)2,Zr1+,As3+,Li1+,O1-,2348.4208690131395 -Li3Ho2Zr3O12,Zr1+,Ho3+,Li1+,O1-,2348.9579817167287 -Li3Hf3Cr2O12,Hf3+,Cr6+,Li1+,O2-,2349.0492773484707 -Li3Er3Mn2O12,Er3+,Mn6+,Li1+,O2-,2349.0742773811635 -Li3Er3(ClO6)2,Er3+,Cl6+,Li1+,O2-,2349.234269995066 -Li3Y3Er2O12,Y1+,Er3+,Li1+,O1-,2351.1101971638523 -Li3Y2Cr3O12,Cr5+,Y3+,Li1+,O2-,2351.40559420346 -Li3Y2Cr3O12,Cr1+,Y3+,Li1+,O1-,2351.40559420346 -Li3Co3(SbO6)2,Co5+,Sb3+,Li1+,O2-,2351.440015471572 -Li3Co3(SbO6)2,Co5+,Sb3-,Li1+,O1-,2351.440015471572 -Li3Co3(SbO6)2,Co1+,Sb3+,Li1+,O1-,2351.440015471572 -Li3Yb3(SeO6)2,Yb3+,Se6+,Li1+,O2-,2351.8113833724524 -Li3Er2Zr3O12,Zr1+,Er3+,Li1+,O1-,2353.218454729553 -Li3Zr2Cr3O12,Cr1+,Zr3+,Li1+,O1-,2353.496394843666 -Li3Zr2Cr3O12,Cr5+,Zr3+,Li1+,O2-,2353.496394843666 -Li3Tm3Mn2O12,Tm3+,Mn6+,Li1+,O2-,2353.623885303064 -Li3Tm3(ClO6)2,Tm3+,Cl6+,Li1+,O2-,2354.007140550989 -Li3Y3Tm2O12,Y1+,Tm3+,Li1+,O1-,2354.179795818157 -Li3Tm2Zr3O12,Zr1+,Tm3+,Li1+,O1-,2356.2535890127697 -Li3Yb2(CoO4)3,Co5+,Yb3+,Li1+,O2-,2356.491443126288 -Li3Yb2(CoO4)3,Co1+,Yb3+,Li1+,O1-,2356.491443126288 -Li3Lu3(SeO6)2,Lu3+,Se6+,Li1+,O2-,2356.6406605892034 -Li3Y3(SbO6)2,Y1+,Sb3+,Li1+,O1-,2357.8988051158326 -Li3Zr3(SbO6)2,Zr1+,Sb3+,Li1+,O1-,2360.2051923280824 -Li3Lu2(CoO4)3,Co1+,Lu3+,Li1+,O1-,2360.3660754852763 -Li3Lu2(CoO4)3,Co5+,Lu3+,Li1+,O2-,2360.3660754852763 -Li3Yb2Y3O12,Y1+,Yb3+,Li1+,O1-,2361.597750327075 -Li3Yb2Zr3O12,Zr1+,Yb3+,Li1+,O1-,2363.589127516101 -Li3Yb3Mn2O12,Yb3+,Mn6+,Li1+,O2-,2364.5448414847174 -Li3Y3Lu2O12,Y1+,Lu3+,Li1+,O1-,2365.028629517485 -Li3Yb3(ClO6)2,Yb3+,Cl6+,Li1+,O2-,2365.452321989214 -Li3Lu2Zr3O12,Zr1+,Lu3+,Li1+,O1-,2366.982304861016 -Li3Lu3Mn2O12,Lu3+,Mn6+,Li1+,O2-,2369.5610070537523 -Li3Lu3(ClO6)2,Lu3+,Cl6+,Li1+,O2-,2370.7037446878817 -Li3Cu2(HgO4)3,Hg1+,Cu3+,Li1+,O1-,2378.284801871723 -Li3Fe2(HgO4)3,Hg1+,Fe3+,Li1+,O1-,2380.8308497317967 -Li3Sc3(CoO6)2,Sc1+,Co3+,Li1+,O1-,2381.263540357646 -Li3V3(PO6)2,V5+,P3-,Li1+,O1-,2383.109656555608 -Li3V3(PO6)2,V5+,P3+,Li1+,O2-,2383.109656555608 -Li3V3(PO6)2,V1+,P3+,Li1+,O1-,2383.109656555608 -Li3Ag3(TeO6)2,Ag3+,Te6+,Li1+,O2-,2383.6922848375307 -Li3Y2Sc3O12,Sc1+,Y3+,Li1+,O1-,2383.7860863119226 -Li3Zr2Sc3O12,Sc1+,Zr3+,Li1+,O1-,2385.6769992268482 -Li3Ni2(HgO4)3,Hg1+,Ni3+,Li1+,O1-,2387.4309180334276 -Li3Gd3(BO6)2,Gd1+,B3+,Li1+,O1-,2391.8878236072615 -Sr3Li3(PO6)2,Sr1+,P3+,Li1+,O1-,2395.6649849514347 -Li3Tb3(BO6)2,Tb1+,B3+,Li1+,O1-,2396.891954508479 -Li3Cd3(WO6)2,Cd1+,W3+,Li1+,O1-,2400.360433278328 -Li3In2(HgO4)3,Hg1+,In3+,Li1+,O1-,2401.991607530124 -Li3Hg3(SO6)2,Hg1+,S3+,Li1+,O1-,2404.7251682512137 -Li3V3Cr2O12,V1+,Cr3+,Li1+,O1-,2404.9109037385615 -Li3V3Cr2O12,V3+,Cr6+,Li1+,O2-,2404.9109037385615 -Li3V3Cr2O12,V5+,Cr3+,Li1+,O2-,2404.9109037385615 -Sr3Li3Cr2O12,Sr1+,Cr3+,Li1+,O1-,2412.41714222624 -Li3Hf2Cr3O12,Cr1+,Hf3+,Li1+,O1-,2412.774032938997 -Li3Hf2Cr3O12,Cr5+,Hf3+,Li1+,O2-,2412.774032938997 -Li3Si2(HgO4)3,Hg1+,Si3+,Li1+,O1-,2417.564812586017 -Li3Ti2(HgO4)3,Hg1+,Ti3+,Li1+,O1-,2419.0558087388627 -Li3Al2(HgO4)3,Hg1+,Al3+,Li1+,O1-,2421.168379123661 -Li3Hg3(GeO6)2,Hg1+,Ge3+,Li1+,O1-,2422.1844345324107 -Li3Ga2(HgO4)3,Hg1+,Ga3+,Li1+,O1-,2425.377644644549 -Li3Cd3(BrO6)2,Cd1+,Br3+,Li1+,O1-,2429.407029699511 -Li3Mn2(HgO4)3,Hg1+,Mn3+,Li1+,O1-,2430.297004455208 -Li3La2V3O12,V1+,La3+,Li1+,O1-,2431.062552618595 -Li3La2V3O12,V5+,La3+,Li1+,O2-,2431.062552618595 -Li3Sc2V3O12,V5+,Sc3+,Li1+,O2-,2431.4660159503505 -Li3Sc2V3O12,V1+,Sc3+,Li1+,O1-,2431.4660159503505 -Sr3Li3La2O12,Sr1+,La3+,Li1+,O1-,2433.018149728819 -Li3Ce2V3O12,V1+,Ce3+,Li1+,O1-,2433.5700725979423 -Li3Ce2V3O12,V5+,Ce3+,Li1+,O2-,2433.5700725979423 -Sr3Li3Sc2O12,Sr1+,Sc3+,Li1+,O1-,2433.9928060377783 -Li3Hg3(ClO6)2,Hg1+,Cl3+,Li1+,O1-,2434.0135052634023 -Sr3Li3Ce2O12,Sr1+,Ce3+,Li1+,O1-,2435.1543931680562 -Li3Pr2V3O12,V1+,Pr3+,Li1+,O1-,2435.199772772063 -Li3Pr2V3O12,V5+,Pr3+,Li1+,O2-,2435.199772772063 -Sr3Li3Pr2O12,Sr1+,Pr3+,Li1+,O1-,2436.544046524111 -K3Li3(AgO6)2,K1+,Ag3+,Li1+,O1-,2436.5930312719443 -Li3Hf2Sc3O12,Sc1+,Hf3+,Li1+,O1-,2438.760804560774 -Li3Nd2V3O12,V1+,Nd3+,Li1+,O1-,2441.977312263128 -Li3Nd2V3O12,V5+,Nd3+,Li1+,O2-,2441.977312263128 -Sr3Li3Nd2O12,Sr1+,Nd3+,Li1+,O1-,2442.333920208836 -Li3Gd3Y2O12,Gd1+,Y3+,Li1+,O1-,2444.623636400532 -Li3Gd3Zr2O12,Gd1+,Zr3+,Li1+,O1-,2445.454501416241 -Li3Gd3(CoO6)2,Gd1+,Co3+,Li1+,O1-,2447.70496183609 -Li3Hg3(NO6)2,Hg1+,N3+,Li1+,O1-,2448.313148172939 -Li3Tb3Y2O12,Tb1+,Y3+,Li1+,O1-,2448.421124169944 -Li3Tb3Zr2O12,Tb1+,Zr3+,Li1+,O1-,2449.227010669295 -Rb3Li3(AuO6)2,Rb1+,Au3+,Li1+,O1-,2451.255062232132 -Li3Tb3(CoO6)2,Tb1+,Co3+,Li1+,O1-,2451.7651934544624 -Sr3Li3Sm2O12,Sr1+,Sm3+,Li1+,O1-,2452.6987394831353 -Li3Ag3(WO6)2,Ag1+,W3+,Li1+,O1-,2452.740248759983 -Li3Ag3(WO6)2,Ag3+,W6+,Li1+,O2-,2452.740248759983 -Li3Sm2V3O12,V1+,Sm3+,Li1+,O1-,2454.060213371054 -Li3Sm2V3O12,V5+,Sm3+,Li1+,O2-,2454.060213371054 -Sr3Li3Eu2O12,Sr1+,Eu3+,Li1+,O1-,2455.362326350898 -Li3Eu2V3O12,V1+,Eu3+,Li1+,O1-,2457.155005695461 -Li3Eu2V3O12,V5+,Eu3+,Li1+,O2-,2457.155005695461 -Li3Hg3(CO6)2,Hg1+,C3+,Li1+,O1-,2457.587652479015 -Sr3Li3Gd2O12,Sr1+,Gd3+,Li1+,O1-,2463.9871279277345 -Sr3Li3Tb2O12,Sr1+,Tb3+,Li1+,O1-,2466.6727198146505 -Li3Gd2V3O12,V5+,Gd3+,Li1+,O2-,2467.147292992343 -Li3Gd2V3O12,V1+,Gd3+,Li1+,O1-,2467.147292992343 -Li3Tb2V3O12,V1+,Tb3+,Li1+,O1-,2470.2497472534387 -Li3Tb2V3O12,V5+,Tb3+,Li1+,O2-,2470.2497472534387 -Li3Gd3Hf2O12,Gd1+,Hf3+,Li1+,O1-,2471.3517158822974 -Li3Y3(ReO6)2,Y3+,Re6+,Li1+,O2-,2471.8485596557116 -Li3Y3(ReO6)2,Y1+,Re3+,Li1+,O1-,2471.8485596557116 -Sr3Li3Dy2O12,Sr1+,Dy3+,Li1+,O1-,2472.3277511322312 -Li3Zr3(ReO6)2,Zr3+,Re6+,Li1+,O2-,2472.8861902489903 -Li3Zr3(ReO6)2,Zr1+,Re3+,Li1+,O1-,2472.8861902489903 -Li3Tb3Hf2O12,Tb1+,Hf3+,Li1+,O1-,2474.370732405998 -Li3ReO6,Li1+,Re3+,Li1+,O1-,2474.8269457710617 -Sr3Li3Ho2O12,Sr1+,Ho3+,Li1+,O1-,2476.115151289742 -Li3Dy2V3O12,V5+,Dy3+,Li1+,O2-,2476.7687318565104 -Li3Dy2V3O12,V1+,Dy3+,Li1+,O1-,2476.7687318565104 -Sr3Li3Er2O12,Sr1+,Er3+,Li1+,O1-,2479.701523265174 -Li3Co3(ReO6)2,Co1+,Re3+,Li1+,O1-,2479.9280929304323 -Li3Co3(ReO6)2,Co3+,Re6+,Li1+,O2-,2479.9280929304323 -Li3Co3(ReO6)2,Co5+,Re3-,Li1+,O1-,2479.9280929304323 -Li3Co3(ReO6)2,Co5+,Re3+,Li1+,O2-,2479.9280929304323 -Li3Ho2V3O12,V1+,Ho3+,Li1+,O1-,2481.124301571757 -Li3Ho2V3O12,V5+,Ho3+,Li1+,O2-,2481.124301571757 -Sr3Li3Tm2O12,Sr1+,Tm3+,Li1+,O1-,2482.256099121447 -Li3V2Cr3O12,Cr1+,V3+,Li1+,O1-,2484.468407993336 -Li3V2Cr3O12,Cr5+,V3+,Li1+,O2-,2484.468407993336 -Li3Er2V3O12,V5+,Er3+,Li1+,O2-,2485.24098050398 -Li3Er2V3O12,V1+,Er3+,Li1+,O1-,2485.24098050398 -Li3Tm2V3O12,V1+,Tm3+,Li1+,O1-,2488.1687351366445 -Li3Tm2V3O12,V5+,Tm3+,Li1+,O2-,2488.1687351366445 -Sr3Li3Yb2O12,Sr1+,Yb3+,Li1+,O1-,2488.429044248912 -Sr3Li3Lu2O12,Sr1+,Lu3+,Li1+,O1-,2491.2838970661446 -Li3Yb2V3O12,V5+,Yb3+,Li1+,O2-,2495.2278303710036 -Li3Yb2V3O12,V1+,Yb3+,Li1+,O1-,2495.2278303710036 -Li3Ag3(BrO6)2,Ag1+,Br3+,Li1+,O1-,2497.9943937937605 -Li3Lu2V3O12,V1+,Lu3+,Li1+,O1-,2498.485062976689 -Li3Lu2V3O12,V5+,Lu3+,Li1+,O2-,2498.485062976689 -Li3Hg3(BO6)2,Hg1+,B3+,Li1+,O1-,2501.990533931877 -Li3Hf3(ReO6)2,Hf3+,Re6+,Li1+,O2-,2502.580262796514 -Sr3Li3(SbO6)2,Sr1+,Sb3+,Li1+,O1-,2502.7968739528237 -Li3Fe3(MoO6)2,Fe3+,Mo6+,Li1+,O2-,2507.669982112113 -Li3Fe3(MoO6)2,Fe1+,Mo3+,Li1+,O1-,2507.669982112113 -Li3Fe3(MoO6)2,Fe5+,Mo3+,Li1+,O2-,2507.669982112113 -Sr3Li3(AsO6)2,Sr1+,As3+,Li1+,O1-,2512.1631796955808 -Li3V3(SbO6)2,V5+,Sb3+,Li1+,O2-,2513.3356523726184 -Li3V3(SbO6)2,V5+,Sb3-,Li1+,O1-,2513.3356523726184 -Li3V3(SbO6)2,V1+,Sb3+,Li1+,O1-,2513.3356523726184 -Li3In3(MoO6)2,In3+,Mo6+,Li1+,O2-,2521.9588926006522 -Li3In3(MoO6)2,In1+,Mo3+,Li1+,O1-,2521.9588926006522 -Li3V3(AsO6)2,V5+,As3-,Li1+,O1-,2526.6164678403866 -Li3V3(AsO6)2,V5+,As3+,Li1+,O2-,2526.6164678403866 -Li3V3(AsO6)2,V1+,As3+,Li1+,O1-,2526.6164678403866 -Li3Sc3V2O12,Sc1+,V3+,Li1+,O1-,2528.5690125298825 -Li3Y2(HgO4)3,Hg1+,Y3+,Li1+,O1-,2530.4884585057903 -Li3Zr2(HgO4)3,Hg1+,Zr3+,Li1+,O1-,2530.8116936456922 -Li3Gd3V2O12,Gd1+,V3+,Li1+,O1-,2533.261160802839 -Li3Tb3V2O12,Tb1+,V3+,Li1+,O1-,2536.86008468873 -Li3Co2(HgO4)3,Hg1+,Co3+,Li1+,O1-,2538.660189108463 -Li3Hf2(HgO4)3,Hg1+,Hf3+,Li1+,O1-,2541.1189025831927 -Li3In3(IO6)2,In1+,I3+,Li1+,O1-,2577.6090641951732 -Li3Fe3(IO6)2,Fe1+,I3+,Li1+,O1-,2580.2409216327733 -Li3Fe3(IO6)2,Fe5+,I3+,Li1+,O2-,2580.2409216327733 -Li3Ta2Cd3O12,Cd1+,Ta3+,Li1+,O1-,2586.731311824482 -Li3Mg3(MoO6)2,Mg1+,Mo3+,Li1+,O1-,2589.7121673127995 -Li3La3Cr2O12,La3+,Cr6+,Li1+,O2-,2592.4725408933564 -Li3Ce3Cr2O12,Ce3+,Cr6+,Li1+,O2-,2594.972868700791 -Sr3Li3(ReO6)2,Sr1+,Re3+,Li1+,O1-,2595.2430980775853 -Li3Pr3Cr2O12,Pr3+,Cr6+,Li1+,O2-,2596.594726698051 -Li3Nd3Cr2O12,Nd3+,Cr6+,Li1+,O2-,2603.313018488821 -Li3La2Cr3O12,Cr5+,La3+,Li1+,O2-,2604.670228518038 -Li3La2Cr3O12,Cr1+,La3+,Li1+,O1-,2604.670228518038 -Li3La2Gd3O12,Gd1+,La3+,Li1+,O1-,2605.104435504125 -Li3Ce2Gd3O12,Gd1+,Ce3+,Li1+,O1-,2606.34632458739 -Li3Ce2Cr3O12,Cr5+,Ce3+,Li1+,O2-,2606.5179271230063 -Li3Ce2Cr3O12,Cr1+,Ce3+,Li1+,O1-,2606.5179271230063 -Na3Li3(MoO6)2,Na1+,Mo3+,Li1+,O1-,2607.1197423668773 -Li3Pr2Gd3O12,Gd1+,Pr3+,Li1+,O1-,2607.1551171685787 -Li3La2Tb3O12,Tb1+,La3+,Li1+,O1-,2607.6756187564847 -Li3Pr2Cr3O12,Cr5+,Pr3+,Li1+,O2-,2607.7188291649463 -Li3Pr2Cr3O12,Cr1+,Pr3+,Li1+,O1-,2607.7188291649463 -Li3Ti3(MoO6)2,Ti3+,Mo6+,Li1+,O2-,2608.402237620209 -Li3Ti3(MoO6)2,Ti1+,Mo3+,Li1+,O1-,2608.402237620209 -Li3Tb3Ce2O12,Tb1+,Ce3+,Li1+,O1-,2608.9046531491263 -Li3Tb3Pr2O12,Tb1+,Pr3+,Li1+,O1-,2609.705091217416 -Li3Nd2Gd3O12,Gd1+,Nd3+,Li1+,O1-,2610.5327805421675 -Li3Nd2Cr3O12,Cr1+,Nd3+,Li1+,O1-,2612.7134052784463 -Li3Nd2Cr3O12,Cr5+,Nd3+,Li1+,O2-,2612.7134052784463 -Li3In3(TeO6)2,In3+,Te6+,Li1+,O2-,2612.8245012922325 -Li3Tb3Nd2O12,Tb1+,Nd3+,Li1+,O1-,2613.0480115627024 -Li3V2(HgO4)3,Hg1+,V3+,Li1+,O1-,2613.664753235462 -Li3Sm3Cr2O12,Sm3+,Cr6+,Li1+,O2-,2615.1847925739166 -Li3Sm2Gd3O12,Gd1+,Sm3+,Li1+,O1-,2616.6113426175434 -Li3V3(ReO6)2,V1+,Re3+,Li1+,O1-,2617.7240617661873 -Li3V3(ReO6)2,V5+,Re3+,Li1+,O2-,2617.7240617661873 -Li3V3(ReO6)2,V5+,Re3-,Li1+,O1-,2617.7240617661873 -Li3V3(ReO6)2,V3+,Re6+,Li1+,O2-,2617.7240617661873 -Li3Zn3(MoO6)2,Zn1+,Mo3+,Li1+,O1-,2618.0539330509673 -Li3Eu2Gd3O12,Gd1+,Eu3+,Li1+,O1-,2618.180103911628 -Li3Eu3Cr2O12,Eu3+,Cr6+,Li1+,O2-,2618.2039860230366 -Li3Tb3Sm2O12,Tb1+,Sm3+,Li1+,O1-,2619.064646151614 -Li3Tb3Eu2O12,Tb1+,Eu3+,Li1+,O1-,2620.6175498154366 -Li3Sm2Cr3O12,Cr1+,Sm3+,Li1+,O1-,2621.6188931809925 -Li3Sm2Cr3O12,Cr5+,Sm3+,Li1+,O2-,2621.6188931809925 -Li3Gd5O12,Gd1+,Gd3+,Li1+,O1-,2623.278666930647 -Li3Eu2Cr3O12,Cr1+,Eu3+,Li1+,O1-,2623.900108230305 -Li3Eu2Cr3O12,Cr5+,Eu3+,Li1+,O2-,2623.900108230305 -Li3Tb2Gd3O12,Gd1+,Tb3+,Li1+,O1-,2624.8721664098703 -Li3Fe3(TeO6)2,Fe3+,Te6+,Li1+,O2-,2625.2535595895715 -Li3Tb3Gd2O12,Tb1+,Gd3+,Li1+,O1-,2625.6649279645085 -Li3Tb5O12,Tb1+,Tb3+,Li1+,O1-,2627.2425410262854 -Li3Gd3Cr2O12,Gd3+,Cr6+,Li1+,O2-,2627.8929641193167 -Li3Gd3Cr2O12,Gd1+,Cr3+,Li1+,O1-,2627.8929641193167 -Li3Gd3(PO6)2,Gd1+,P3+,Li1+,O1-,2627.9643099846394 -Li3Gd3Dy2O12,Gd1+,Dy3+,Li1+,O1-,2628.2368123008923 -Li3Mn3(MoO6)2,Mn3+,Mo6+,Li1+,O2-,2628.720503356978 -Li3Mn3(MoO6)2,Mn5+,Mo3+,Li1+,O2-,2628.720503356978 -Li3Mn3(MoO6)2,Mn1+,Mo3+,Li1+,O1-,2628.720503356978 -Li3Ca3(MoO6)2,Ca1+,Mo3+,Li1+,O1-,2630.3860059002172 -Li3Gd3Ho2O12,Gd1+,Ho3+,Li1+,O1-,2630.497272922027 -Li3Tb3Dy2O12,Tb1+,Dy3+,Li1+,O1-,2630.5738164563413 -Li3Tb3Cr2O12,Tb3+,Cr6+,Li1+,O2-,2630.8829858664626 -Li3Tb3Cr2O12,Tb1+,Cr3+,Li1+,O1-,2630.8829858664626 -Li3Tb3(PO6)2,Tb1+,P3+,Li1+,O1-,2631.1211305876304 -Li3Gd2Cr3O12,Cr5+,Gd3+,Li1+,O2-,2631.2662692935696 -Li3Gd2Cr3O12,Cr1+,Gd3+,Li1+,O1-,2631.2662692935696 -Li3Gd3Er2O12,Gd1+,Er3+,Li1+,O1-,2632.6429681248983 -Li3Tb3Ho2O12,Tb1+,Ho3+,Li1+,O1-,2632.8119900908773 -Li3Tb2Cr3O12,Cr5+,Tb3+,Li1+,O2-,2633.5535701490767 -Li3Tb2Cr3O12,Cr1+,Tb3+,Li1+,O1-,2633.5535701490767 -Li3Gd3Tm2O12,Gd1+,Tm3+,Li1+,O1-,2634.1744528073405 -Li3Tb3Er2O12,Tb1+,Er3+,Li1+,O1-,2634.936628136132 -Li3Tb3Tm2O12,Tb1+,Tm3+,Li1+,O1-,2636.4531418815836 -Li3Dy3Cr2O12,Dy3+,Cr6+,Li1+,O2-,2637.137788011558 -Li3Yb2Gd3O12,Gd1+,Yb3+,Li1+,O1-,2637.885876990912 -Li3Dy2Cr3O12,Cr5+,Dy3+,Li1+,O2-,2638.3600644620005 -Li3Dy2Cr3O12,Cr1+,Dy3+,Li1+,O1-,2638.3600644620005 -Li3Gd3Lu2O12,Gd1+,Lu3+,Li1+,O1-,2639.6074701996076 -Li3Tb3Yb2O12,Tb1+,Yb3+,Li1+,O1-,2640.128487609276 -Li3La2Sc3O12,Sc1+,La3+,Li1+,O1-,2640.4257581325146 -Li3Ho3Cr2O12,Ho3+,Cr6+,Li1+,O2-,2641.295888304243 -Li3Ho2Cr3O12,Cr1+,Ho3+,Li1+,O1-,2641.5717129219947 -Li3Ho2Cr3O12,Cr5+,Ho3+,Li1+,O2-,2641.5717129219947 -Li3Tb3Lu2O12,Tb1+,Lu3+,Li1+,O1-,2641.8334426219417 -Li3Ce2Sc3O12,Sc1+,Ce3+,Li1+,O1-,2642.1977429779663 -Li3Ta2(AgO4)3,Ag1+,Ta3+,Li1+,O1-,2642.2758419485626 -Li3Cr5O12,Cr1+,Cr3+,Li1+,O1-,2642.518670302623 -Li3Cr5O12,Cr3+,Cr6+,Li1+,O2-,2642.518670302623 -Li3Cr5O12,Cr5+,Cr3+,Li1+,O2-,2642.518670302623 -Li3Pr2Sc3O12,Sc1+,Pr3+,Li1+,O1-,2643.3491959626117 -Li3Cr3(PO6)2,Cr1+,P3+,Li1+,O1-,2644.069897691204 -Li3Cr3(PO6)2,Cr5+,P3-,Li1+,O1-,2644.069897691204 -Li3Cr3(PO6)2,Cr5+,P3+,Li1+,O2-,2644.069897691204 -Li3Er2Cr3O12,Cr5+,Er3+,Li1+,O2-,2644.6073996537293 -Li3Er2Cr3O12,Cr1+,Er3+,Li1+,O1-,2644.6073996537293 -Li3Er3Cr2O12,Er3+,Cr6+,Li1+,O2-,2645.2106012203985 -Li3Tm2Cr3O12,Cr1+,Tm3+,Li1+,O1-,2646.7664711230036 -Li3Tm2Cr3O12,Cr5+,Tm3+,Li1+,O2-,2646.7664711230036 -Li3Gd3Sc2O12,Gd1+,Sc3+,Li1+,O1-,2647.5667526838715 -Li3Tm3Cr2O12,Tm3+,Cr6+,Li1+,O2-,2647.985702904296 -Li3Nd2Sc3O12,Sc1+,Nd3+,Li1+,O1-,2648.1360909934892 -Li3Tb3Sc2O12,Tb1+,Sc3+,Li1+,O1-,2650.48393216425 -Li3Yb2Cr3O12,Cr1+,Yb3+,Li1+,O1-,2651.9725784920943 -Li3Yb2Cr3O12,Cr5+,Yb3+,Li1+,O2-,2651.9725784920943 -Li3In3(WO6)2,In1+,W3+,Li1+,O1-,2652.452057398142 -Li3In3(WO6)2,In3+,W6+,Li1+,O2-,2652.452057398142 -Li3Lu2Cr3O12,Cr5+,Lu3+,Li1+,O2-,2654.3749802605425 -Li3Lu2Cr3O12,Cr1+,Lu3+,Li1+,O1-,2654.3749802605425 -Li3Yb3Cr2O12,Yb3+,Cr6+,Li1+,O2-,2654.64611784747 -Li3Sm2Sc3O12,Sc1+,Sm3+,Li1+,O1-,2656.6631987028522 -K3Li3In2O12,K1+,In3+,Li1+,O1-,2657.002319084686 -Li3Lu3Cr2O12,Lu3+,Cr6+,Li1+,O2-,2657.704883754361 -Li3Eu2Sc3O12,Sc1+,Eu3+,Li1+,O1-,2658.8458249763094 -Li3La2(HgO4)3,Hg1+,La3+,Li1+,O1-,2664.008237520006 -Li3Ce2(HgO4)3,Hg1+,Ce3+,Li1+,O1-,2664.9723817058875 -K3Li3(CuO6)2,K1+,Cu3+,Li1+,O1-,2665.3698239314863 -Li3Gd3(SbO6)2,Gd1+,Sb3+,Li1+,O1-,2665.535880411057 -Li3Mg3(IO6)2,Mg1+,I3+,Li1+,O1-,2665.5931071916966 -Li3Pr2(HgO4)3,Hg1+,Pr3+,Li1+,O1-,2665.600599999398 -Li3Gd2Sc3O12,Sc1+,Gd3+,Li1+,O1-,2665.8890111698574 -Li3Tb3(SbO6)2,Tb1+,Sb3+,Li1+,O1-,2667.8760483001047 -Li3Tb2Sc3O12,Sc1+,Tb3+,Li1+,O1-,2668.074587225292 -Li3Nd2(HgO4)3,Hg1+,Nd3+,Li1+,O1-,2668.226797615164 -Li3Fe3(WO6)2,Fe5+,W3+,Li1+,O2-,2672.384613039998 -Li3Fe3(WO6)2,Fe1+,W3+,Li1+,O1-,2672.384613039998 -Li3Fe3(WO6)2,Fe3+,W6+,Li1+,O2-,2672.384613039998 -Li3Fe3(WO6)2,Fe1-,W6+,Li1+,O1-,2672.384613039998 -Li3Dy2Sc3O12,Sc1+,Dy3+,Li1+,O1-,2672.665102955634 -Li3Sm2(HgO4)3,Hg1+,Sm3+,Li1+,O1-,2672.9637737022435 -Li3Ti3(IO6)2,Ti1+,I3+,Li1+,O1-,2673.5966791567985 -Li3Eu2(HgO4)3,Hg1+,Eu3+,Li1+,O1-,2674.1885527027025 -Li3Ho2Sc3O12,Sc1+,Ho3+,Li1+,O1-,2675.730764454243 -Li3Sc2Cr3O12,Cr1+,Sc3+,Li1+,O1-,2676.1840471882115 -Li3Sc2Cr3O12,Cr5+,Sc3+,Li1+,O2-,2676.1840471882115 -Li3Zn3(IO6)2,Zn1+,I3+,Li1+,O1-,2677.1706324554566 -Li3Gd2(HgO4)3,Hg1+,Gd3+,Li1+,O1-,2678.175564691364 -Li3Er2Sc3O12,Sc1+,Er3+,Li1+,O1-,2678.6272319386862 -Li3Tb2(HgO4)3,Hg1+,Tb3+,Li1+,O1-,2679.4236762944324 -Li3Tm2Sc3O12,Sc1+,Tm3+,Li1+,O1-,2680.686559079703 -K3Li3(FeO6)2,K1+,Fe3+,Li1+,O1-,2680.7161690780486 -Na3Li3(IO6)2,Na1+,I3+,Li1+,O1-,2681.5469135852823 -Li3Dy2(HgO4)3,Hg1+,Dy3+,Li1+,O1-,2682.062201898269 -Li3Ho2(HgO4)3,Hg1+,Ho3+,Li1+,O1-,2683.8372479886434 -Li3Er2(HgO4)3,Hg1+,Er3+,Li1+,O1-,2685.5239709415287 -Li3Yb2Sc3O12,Sc1+,Yb3+,Li1+,O1-,2685.6496706970197 -Li3Tm2(HgO4)3,Hg1+,Tm3+,Li1+,O1-,2686.728937484389 -Li3Lu2Sc3O12,Sc1+,Lu3+,Li1+,O1-,2687.938756172551 -Li3Yb2(HgO4)3,Hg1+,Yb3+,Li1+,O1-,2689.6527837729 -Li3Mn3(IO6)2,Mn5+,I3+,Li1+,O2-,2689.7320108775375 -Li3Mn3(IO6)2,Mn1+,I3+,Li1+,O1-,2689.7320108775375 -K3Li3(NiO6)2,K1+,Ni3+,Li1+,O1-,2690.644037117526 -Li3Gd3(AsO6)2,Gd1+,As3+,Li1+,O1-,2690.8276396826977 -Li3Lu2(HgO4)3,Hg1+,Lu3+,Li1+,O1-,2691.01083553925 -Li3Tb3(AsO6)2,Tb1+,As3+,Li1+,O1-,2693.2775263553744 -Li3Sc3Cr2O12,Sc1+,Cr3+,Li1+,O1-,2693.8038398414205 -Li3Sc3Cr2O12,Sc3+,Cr6+,Li1+,O2-,2693.8038398414205 -Li3Cr2(HgO4)3,Hg1+,Cr3+,Li1+,O1-,2694.7172912915403 -Li3Ca3(IO6)2,Ca1+,I3+,Li1+,O1-,2695.8564372748374 -Li3Cr3(SbO6)2,Cr1+,Sb3+,Li1+,O1-,2696.2404876763785 -Li3Cr3(SbO6)2,Cr5+,Sb3-,Li1+,O1-,2696.2404876763785 -Li3Cr3(SbO6)2,Cr5+,Sb3+,Li1+,O2-,2696.2404876763785 -Li3Hg3(PO6)2,Hg1+,P3+,Li1+,O1-,2697.983416771956 -Li3La3(ReO6)2,La3+,Re6+,Li1+,O2-,2698.98727497557 -Li3Ce3(ReO6)2,Ce3+,Re6+,Li1+,O2-,2700.435510807816 -Li3Sc3(PO6)2,Sc1+,P3+,Li1+,O1-,2700.6989762934477 -Li3Pr3(ReO6)2,Pr3+,Re6+,Li1+,O2-,2701.376969307341 -Li3Mo2O15,O1-,Mo6+,Li1+,O1-,2704.732335749977 -Li3Nd3(ReO6)2,Nd3+,Re6+,Li1+,O2-,2705.2940805484873 -Li3Sm3(ReO6)2,Sm3+,Re6+,Li1+,O2-,2712.284685525506 -Li3Sc2(HgO4)3,Hg1+,Sc3+,Li1+,O1-,2712.60326494788 -Li3Eu3(ReO6)2,Eu3+,Re6+,Li1+,O2-,2714.0766815179554 -Li3Hg3(SbO6)2,Hg1+,Sb3+,Li1+,O1-,2718.922814712858 -Li3Gd3(ReO6)2,Gd3+,Re6+,Li1+,O2-,2719.866737282964 -Li3Gd3(ReO6)2,Gd1+,Re3+,Li1+,O1-,2719.866737282964 -Li3Ti3(TeO6)2,Ti3+,Te6+,Li1+,O2-,2720.158439074924 -Li3Tb3(ReO6)2,Tb3+,Re6+,Li1+,O2-,2721.665756360947 -Li3Tb3(ReO6)2,Tb1+,Re3+,Li1+,O1-,2721.665756360947 -Li3Dy3(ReO6)2,Dy3+,Re6+,Li1+,O2-,2725.4479180125318 -Li3Ho3(ReO6)2,Ho3+,Re6+,Li1+,O2-,2727.976428897534 -Li3Er3(ReO6)2,Er3+,Re6+,Li1+,O2-,2730.367372126835 -Li3Sc5O12,Sc1+,Sc3+,Li1+,O1-,2730.7442656613175 -Li3Tm3(ReO6)2,Tm3+,Re6+,Li1+,O2-,2732.068454230796 -Li3Mn3(TeO6)2,Mn3+,Te6+,Li1+,O2-,2734.697502892306 -Li3Yb3(ReO6)2,Yb3+,Re6+,Li1+,O2-,2736.1721802276784 -Li3Sc3(SbO6)2,Sc1+,Sb3+,Li1+,O1-,2737.3412259158076 -Li3Lu3(ReO6)2,Lu3+,Re6+,Li1+,O2-,2738.0668115865265 -Li3Cr3(AsO6)2,Cr5+,As3+,Li1+,O2-,2742.4761104511676 -Li3Cr3(AsO6)2,Cr5+,As3-,Li1+,O1-,2742.4761104511676 -Li3Cr3(AsO6)2,Cr1+,As3+,Li1+,O1-,2742.4761104511676 -K3Li3(GeO6)2,K1+,Ge3+,Li1+,O1-,2743.0243797364983 -Li3Hg3(AsO6)2,Hg1+,As3+,Li1+,O1-,2745.990425422711 -Li3Zn3(WO6)2,Zn1+,W3+,Li1+,O1-,2751.700220464753 -K3Li3(GaO6)2,K1+,Ga3+,Li1+,O1-,2753.498523181546 -Li3Ti3(WO6)2,Ti3+,W6+,Li1+,O2-,2754.104976019781 -Li3Ti3(WO6)2,Ti1+,W3+,Li1+,O1-,2754.104976019781 -Li3In3(BrO6)2,In1+,Br3+,Li1+,O1-,2754.284402612938 -Li3Mg3(WO6)2,Mg1+,W3+,Li1+,O1-,2756.2055907248546 -Li3Hf3(MoO6)2,Hf3+,Mo6+,Li1+,O2-,2757.6401949528477 -Li3Re2(HgO4)3,Hg1+,Re3+,Li1+,O1-,2761.50526731344 -Li3Mn3(WO6)2,Mn3+,W6+,Li1+,O2-,2765.4836547965783 -Li3Mn3(WO6)2,Mn1+,W3+,Li1+,O1-,2765.4836547965783 -Li3Mn3(WO6)2,Mn5+,W3+,Li1+,O2-,2765.4836547965783 -Li3Cr3(ReO6)2,Cr1+,Re3+,Li1+,O1-,2768.3771213897776 -Li3Cr3(ReO6)2,Cr3+,Re6+,Li1+,O2-,2768.3771213897776 -Li3Cr3(ReO6)2,Cr5+,Re3-,Li1+,O1-,2768.3771213897776 -Li3Cr3(ReO6)2,Cr5+,Re3+,Li1+,O2-,2768.3771213897776 -Li3Ta3(AuO6)2,Ta5+,Au3+,Li1+,O2-,2768.837996099171 -Na3Li3(WO6)2,Na1+,W3+,Li1+,O1-,2769.9127054000046 -K3Li3(SO6)2,K1+,S3+,Li1+,O1-,2770.1510270248614 -K3Li3Ti2O12,K1+,Ti3+,Li1+,O1-,2773.6653291681214 -Li3Ca3(WO6)2,Ca1+,W3+,Li1+,O1-,2775.4321280470726 -K3Li3Mn2O12,K1+,Mn3+,Li1+,O1-,2785.8864626367535 -Li3Sc3(AsO6)2,Sc1+,As3+,Li1+,O1-,2793.2782530907043 -Li3Sc3(ReO6)2,Sc1+,Re3+,Li1+,O1-,2804.236802721124 -Li3Sc3(ReO6)2,Sc3+,Re6+,Li1+,O2-,2804.236802721124 -K3Li3(SiO6)2,K1+,Si3+,Li1+,O1-,2806.623456405002 -Li3Fe3(BrO6)2,Fe5+,Br3+,Li1+,O2-,2815.240999498666 -Li3Fe3(BrO6)2,Fe1+,Br3+,Li1+,O1-,2815.240999498666 -Li3Hf3(TeO6)2,Hf3+,Te6+,Li1+,O2-,2816.3378096630768 -K3Li3Al2O12,K1+,Al3+,Li1+,O1-,2817.009182682624 -Li3Zr3(MoO6)2,Zr1+,Mo3+,Li1+,O1-,2818.477233146974 -Li3Zr3(MoO6)2,Zr3+,Mo6+,Li1+,O2-,2818.477233146974 -Li3Y3(MoO6)2,Y3+,Mo6+,Li1+,O2-,2820.7402042273957 -Li3Y3(MoO6)2,Y1+,Mo3+,Li1+,O1-,2820.7402042273957 -Li3Te2O15,O1-,Te6+,Li1+,O1-,2825.373148790537 -K3Li3(ClO6)2,K1+,Cl3+,Li1+,O1-,2828.6484827190493 -Li3Hf3(WO6)2,Hf3+,W6+,Li1+,O2-,2828.670018382284 -Li3Ta2In3O12,In1+,Ta3+,Li1+,O1-,2838.945192855137 -Li3W2O15,O1-,W6+,Li1+,O1-,2845.65341912572 -K3Li3Hf2O12,K1+,Hf3+,Li1+,O1-,2846.9666086296907 -Li3Zr3(IO6)2,Zr1+,I3+,Li1+,O1-,2854.643277235018 -Li3Y3(IO6)2,Y1+,I3+,Li1+,O1-,2857.058116749274 -Li3Co3(MoO6)2,Co1+,Mo3+,Li1+,O1-,2885.2780654484473 -Li3Co3(MoO6)2,Co3+,Mo6+,Li1+,O2-,2885.2780654484473 -Li3Co3(MoO6)2,Co5+,Mo3+,Li1+,O2-,2885.2780654484473 -Li3Zr3(TeO6)2,Zr3+,Te6+,Li1+,O2-,2892.6998664397615 -Li3Y3(TeO6)2,Y3+,Te6+,Li1+,O2-,2895.4703498895215 -Li3Zr3(WO6)2,Zr1+,W3+,Li1+,O1-,2898.756192869832 -Li3Zr3(WO6)2,Zr3+,W6+,Li1+,O2-,2898.756192869832 -Li3Y3(WO6)2,Y3+,W6+,Li1+,O2-,2901.2085680661194 -Li3Y3(WO6)2,Y1+,W3+,Li1+,O1-,2901.2085680661194 -Li3Ta2(FeO4)3,Fe1+,Ta3+,Li1+,O1-,2903.484858185129 -Li3Ta2(FeO4)3,Fe5+,Ta3+,Li1+,O2-,2903.484858185129 -K3Li3(NO6)2,K1+,N3+,Li1+,O1-,2909.558390513233 -Li3Zn3(BrO6)2,Zn1+,Br3+,Li1+,O1-,2916.335003835804 -Li3Co3(IO6)2,Co5+,I3+,Li1+,O2-,2920.4596694413135 -Li3Co3(IO6)2,Co1+,I3+,Li1+,O1-,2920.4596694413135 -K3Li3Zr2O12,K1+,Zr3+,Li1+,O1-,2931.061515490811 -K3Li3Y2O12,K1+,Y3+,Li1+,O1-,2934.0834347924015 -Li3Ti3(BrO6)2,Ti1+,Br3+,Li1+,O1-,2936.4916214796344 -K3Li3(CO6)2,K1+,C3+,Li1+,O1-,2936.7204497982534 -Li3Mn3(BrO6)2,Mn5+,Br3+,Li1+,O2-,2945.0724258978853 -Li3Mn3(BrO6)2,Mn1+,Br3+,Li1+,O1-,2945.0724258978853 -Cs3Li3(AuO6)2,Cs1+,Au3+,Li1+,O1-,2953.5422960964606 -Rb3Li3(AgO6)2,Rb1+,Ag3+,Li1+,O1-,2954.79642768086 -Li3Co3(WO6)2,Co1+,W3+,Li1+,O1-,2960.318950709042 -Li3Co3(WO6)2,Co1-,W6+,Li1+,O1-,2960.318950709042 -Li3Co3(WO6)2,Co3+,W6+,Li1+,O2-,2960.318950709042 -Li3Co3(WO6)2,Co5+,W3+,Li1+,O2-,2960.318950709042 -Li3Co3(TeO6)2,Co3+,Te6+,Li1+,O2-,2964.091620580672 -Li3Mg3(BrO6)2,Mg1+,Br3+,Li1+,O1-,2968.5084666026846 -Li3Ta2Zn3O12,Zn1+,Ta3+,Li1+,O1-,2974.794707375903 -Li3Ca3(BrO6)2,Ca1+,Br3+,Li1+,O1-,2975.461076196826 -Li3Cd3(RuO6)2,Cd1+,Ru3+,Li1+,O1-,2976.614248975789 -Sr3Li3(MoO6)2,Sr1+,Mo3+,Li1+,O1-,2979.5217118928485 -Na3Li3(BrO6)2,Na1+,Br3+,Li1+,O1-,2990.5649125268737 -Li3Ta2Ti3O12,Ti1+,Ta3+,Li1+,O1-,2993.563481613074 -Li3Ta2Mn3O12,Mn5+,Ta3+,Li1+,O2-,2998.1623437708945 -Li3Ta2Mn3O12,Mn1+,Ta3+,Li1+,O1-,2998.1623437708945 -Li3Cd3(RhO6)2,Cd1+,Rh3+,Li1+,O1-,3001.0114309558467 -Sr3Li3(IO6)2,Sr1+,I3+,Li1+,O1-,3002.552064351614 -K3Li3(CoO6)2,K1+,Co3+,Li1+,O1-,3005.0990620971265 -Li3Mg3Ta2O12,Mg1+,Ta3+,Li1+,O1-,3021.8188519013183 -Li3Ca3Ta2O12,Ca1+,Ta3+,Li1+,O1-,3023.1197505600294 -Li3MoO6,Li1+,Mo3+,Li1+,O1-,3026.5962396961077 -Sr3Li3(WO6)2,Sr1+,W3+,Li1+,O1-,3027.2596690507135 -Li3La3(MoO6)2,La3+,Mo6+,Li1+,O2-,3034.0891463008566 -Li3Ce3(MoO6)2,Ce3+,Mo6+,Li1+,O2-,3034.379265682622 -Li3Pr3(MoO6)2,Pr3+,Mo6+,Li1+,O2-,3034.5676176663874 -Li3Nd3(MoO6)2,Nd3+,Mo6+,Li1+,O2-,3035.3492111143996 -Li3Sm3(MoO6)2,Sm3+,Mo6+,Li1+,O2-,3036.73578991133 -Li3Eu3(MoO6)2,Eu3+,Mo6+,Li1+,O2-,3037.0895334560864 -Na3Li3Ta2O12,Na1+,Ta3+,Li1+,O1-,3037.277321105595 -Li3Gd3(MoO6)2,Gd3+,Mo6+,Li1+,O2-,3038.227805986406 -Li3Gd3(MoO6)2,Gd1+,Mo3+,Li1+,O1-,3038.227805986406 -Li3Tb3(MoO6)2,Tb1+,Mo3+,Li1+,O1-,3038.5800238544202 -Li3Tb3(MoO6)2,Tb3+,Mo6+,Li1+,O2-,3038.5800238544202 -Li3Dy3(MoO6)2,Dy3+,Mo6+,Li1+,O2-,3039.318275203716 -Li3Ho3(MoO6)2,Ho3+,Mo6+,Li1+,O2-,3039.8101423972043 -Li3Er3(MoO6)2,Er3+,Mo6+,Li1+,O2-,3040.2740159439977 -Li3Tm3(MoO6)2,Tm3+,Mo6+,Li1+,O2-,3040.6033206222855 -Li3Yb3(MoO6)2,Yb3+,Mo6+,Li1+,O2-,3041.395265160003 -Li3Lu3(MoO6)2,Lu3+,Mo6+,Li1+,O2-,3041.7597177615066 -K3Li3(BO6)2,K1+,B3+,Li1+,O1-,3045.5521479805548 -Li3Hg3(MoO6)2,Hg1+,Mo3+,Li1+,O1-,3046.2078294165585 -Li3Ag3(RuO6)2,Ag1+,Ru3+,Li1+,O1-,3051.3678231326785 -Li3Ag3(RuO6)2,Ag3+,Ru6+,Li1+,O2-,3051.3678231326785 -Li3Gd3(IO6)2,Gd1+,I3+,Li1+,O1-,3052.257046049641 -Li3Tb3(IO6)2,Tb1+,I3+,Li1+,O1-,3052.51140080135 -Li3IO6,Li1+,I3+,Li1+,O1-,3055.0813754926835 -Li3Hg3(IO6)2,Hg1+,I3+,Li1+,O1-,3058.0672008924344 -Li3La3(WO6)2,La3+,W6+,Li1+,O2-,3064.842006898412 -Li3Ce3(WO6)2,Ce3+,W6+,Li1+,O2-,3064.969578669519 -Li3Pr3(WO6)2,Pr3+,W6+,Li1+,O2-,3065.052507242314 -Li3Nd3(WO6)2,Nd3+,W6+,Li1+,O2-,3065.397526977805 -Li3Sm3(WO6)2,Sm3+,W6+,Li1+,O2-,3066.013180999399 -Li3Eu3(WO6)2,Eu3+,W6+,Li1+,O2-,3066.1709834870694 -Li3Gd3(WO6)2,Gd3+,W6+,Li1+,O2-,3066.680807849269 -Li3Gd3(WO6)2,Gd1+,W3+,Li1+,O1-,3066.680807849269 -Li3Tb3(WO6)2,Tb1+,W3+,Li1+,O1-,3066.8392003437903 -Li3Tb3(WO6)2,Tb3+,W6+,Li1+,O2-,3066.8392003437903 -Li3Nb2Cd3O12,Cd1+,Nb3+,Li1+,O1-,3067.164138863294 -Li3Dy3(WO6)2,Dy3+,W6+,Li1+,O2-,3067.172174272596 -Li3Ho3(WO6)2,Ho3+,W6+,Li1+,O2-,3067.394762677074 -Li3Er3(WO6)2,Er3+,W6+,Li1+,O2-,3067.6052285523574 -Li3Tm3(WO6)2,Tm3+,W6+,Li1+,O2-,3067.7549612575085 -Li3Yb3(WO6)2,Yb3+,W6+,Li1+,O2-,3068.1161547515053 -Li3Lu3(WO6)2,Lu3+,W6+,Li1+,O2-,3068.282900764685 -Li3Hg3(WO6)2,Hg1+,W3+,Li1+,O1-,3070.3450949862545 -Li3Ag3(RhO6)2,Ag1+,Rh3+,Li1+,O1-,3075.843247806547 -Li3Ag3(RhO6)2,Ag3+,Rh6+,Li1+,O2-,3075.843247806547 -Li3WO6,Li1+,W3+,Li1+,O1-,3079.786628989481 -Li3La3(TeO6)2,La3+,Te6+,Li1+,O2-,3080.8801128648865 -Li3Ce3(TeO6)2,Ce3+,Te6+,Li1+,O2-,3080.9582740764536 -Li3Pr3(TeO6)2,Pr3+,Te6+,Li1+,O2-,3081.0090444588827 -Li3Nd3(TeO6)2,Nd3+,Te6+,Li1+,O2-,3081.2199456048334 -Li3Sm3(TeO6)2,Sm3+,Te6+,Li1+,O2-,3081.5949762799482 -Li3Eu3(TeO6)2,Eu3+,Te6+,Li1+,O2-,3081.6908353842236 -Li3Gd3(TeO6)2,Gd3+,Te6+,Li1+,O2-,3081.999791863037 -Li3Tb3(TeO6)2,Tb3+,Te6+,Li1+,O2-,3082.095548347501 -Li3Dy3(TeO6)2,Dy3+,Te6+,Li1+,O2-,3082.296493684353 -Li3Ho3(TeO6)2,Ho3+,Te6+,Li1+,O2-,3082.4305554314974 -Li3Er3(TeO6)2,Er3+,Te6+,Li1+,O2-,3082.5571194176737 -Li3Tm3(TeO6)2,Tm3+,Te6+,Li1+,O2-,3082.647045357975 -Li3Yb3(TeO6)2,Yb3+,Te6+,Li1+,O2-,3082.8635735832904 -Li3Lu3(TeO6)2,Lu3+,Te6+,Li1+,O2-,3082.963345972191 -Li3V3(MoO6)2,V5+,Mo3+,Li1+,O2-,3085.12586895939 -Li3V3(MoO6)2,V3+,Mo6+,Li1+,O2-,3085.12586895939 -Li3V3(MoO6)2,V1+,Mo3+,Li1+,O1-,3085.12586895939 -Li3Zr3(BrO6)2,Zr1+,Br3+,Li1+,O1-,3090.9614452082155 -Li3Y3(BrO6)2,Y1+,Br3+,Li1+,O1-,3096.301889436684 -Li3V3(IO6)2,V5+,I3+,Li1+,O2-,3101.689513736428 -Li3V3(IO6)2,V1+,I3+,Li1+,O1-,3101.689513736428 -Li3Zr3Ta2O12,Zr1+,Ta3+,Li1+,O1-,3102.4880397258053 -Li3Y3Ta2O12,Y1+,Ta3+,Li1+,O1-,3106.6411263094997 -K3Li3Lu2O12,K1+,Lu3+,Li1+,O1-,3106.812949207604 -K3Li3Yb2O12,K1+,Yb3+,Li1+,O1-,3106.8517801265234 -K3Li3Tm2O12,K1+,Tm3+,Li1+,O1-,3106.9360102154096 -K3Li3Er2O12,K1+,Er3+,Li1+,O1-,3106.9709749217873 -K3Li3Ho2O12,K1+,Ho3+,Li1+,O1-,3107.0201684818617 -K3Li3Dy2O12,K1+,Dy3+,Li1+,O1-,3107.072255116578 -K3Li3Tb2O12,K1+,Tb3+,Li1+,O1-,3107.1502870387035 -K3Li3Gd2O12,K1+,Gd3+,Li1+,O1-,3107.1874543813815 -K3Li3Eu2O12,K1+,Eu3+,Li1+,O1-,3107.3072984346218 -K3Li3Sm2O12,K1+,Sm3+,Li1+,O1-,3107.3444586637906 -K3Li3Nd2O12,K1+,Nd3+,Li1+,O1-,3107.4897343931334 -K3Li3Pr2O12,K1+,Pr3+,Li1+,O1-,3107.57135666731 -K3Li3Ce2O12,K1+,Ce3+,Li1+,O1-,3107.5909976477155 -K3Li3La2O12,K1+,La3+,Li1+,O1-,3107.621228946547 -Li3V3(WO6)2,V1+,W3+,Li1+,O1-,3114.7103114423535 -Li3V3(WO6)2,V5+,W3+,Li1+,O2-,3114.7103114423535 -Li3V3(WO6)2,V3+,W6+,Li1+,O2-,3114.7103114423535 -Rb3Li3In2O12,Rb1+,In3+,Li1+,O1-,3121.026215444916 -Li3Ag3(PdO6)2,Ag3+,Pd6+,Li1+,O2-,3122.037999072152 -Li3Nb2(AgO4)3,Ag1+,Nb3+,Li1+,O1-,3145.3162964713506 -Li3V3(TeO6)2,V3+,Te6+,Li1+,O2-,3146.600341504893 -K3Li3V2O12,K1+,V3+,Li1+,O1-,3181.4780632217557 -Li3Ta3(AgO6)2,Ta5+,Ag3+,Li1+,O2-,3182.1563411265997 -Li3Ta2(CoO4)3,Co5+,Ta3+,Li1+,O2-,3190.7863821500614 -Li3Ta2(CoO4)3,Co1+,Ta3+,Li1+,O1-,3190.7863821500614 -Rb3Li3(CuO6)2,Rb1+,Cu3+,Li1+,O1-,3207.2370936517714 -Rb3Li3Hf2O12,Rb1+,Hf3+,Li1+,O1-,3207.4848293244536 -Li3Co3(BrO6)2,Co5+,Br3+,Li1+,O2-,3209.7051702668246 -Li3Co3(BrO6)2,Co1+,Br3+,Li1+,O1-,3209.7051702668246 -K3Li3(ReO6)2,K1+,Re3+,Li1+,O1-,3212.616552841488 -Li3Ta2(HgO4)3,Hg1+,Ta3+,Li1+,O1-,3218.103688764999 -Li3Tb3Ta2O12,Tb1+,Ta3+,Li1+,O1-,3232.1430806017765 -Li3Gd3Ta2O12,Gd1+,Ta3+,Li1+,O1-,3232.7777505749955 -Li3Cd3(BiO6)2,Cd1+,Bi3+,Li1+,O1-,3233.0471722594493 -Rb3Li3(FeO6)2,Rb1+,Fe3+,Li1+,O1-,3233.275355253454 -Li3Hg3(BrO6)2,Hg1+,Br3+,Li1+,O1-,3234.4368365233854 -Sr3Li3Ta2O12,Sr1+,Ta3+,Li1+,O1-,3234.508879456222 -K3Li3(SbO6)2,K1+,Sb3+,Li1+,O1-,3235.434017042672 -Rb3Li3(NiO6)2,Rb1+,Ni3+,Li1+,O1-,3235.4827601490606 -Rb3Li3(GeO6)2,Rb1+,Ge3+,Li1+,O1-,3251.2742083309467 -Li3Tb3(BrO6)2,Tb1+,Br3+,Li1+,O1-,3254.2199707240356 -Li3Gd3(BrO6)2,Gd1+,Br3+,Li1+,O1-,3255.137949566886 -Li3Cr3(WO6)2,Cr1+,W3+,Li1+,O1-,3264.196783067007 -Li3Cr3(WO6)2,Cr3+,W6+,Li1+,O2-,3264.196783067007 -Li3Cr3(WO6)2,Cr5+,W3+,Li1+,O2-,3264.196783067007 -Rb3Li3(GaO6)2,Rb1+,Ga3+,Li1+,O1-,3264.2260474231152 -Sr3Li3(BrO6)2,Sr1+,Br3+,Li1+,O1-,3264.7696133245254 -Li3In3(RuO6)2,In3+,Ru6+,Li1+,O2-,3278.178659269343 -Li3In3(RuO6)2,In1+,Ru3+,Li1+,O1-,3278.178659269343 -Li3Cr3(IO6)2,Cr5+,I3+,Li1+,O2-,3278.582057966534 -Li3Cr3(IO6)2,Cr1+,I3+,Li1+,O1-,3278.582057966534 -Li3Cr3(MoO6)2,Cr1+,Mo3+,Li1+,O1-,3281.6500949465126 -Li3Cr3(MoO6)2,Cr3+,Mo6+,Li1+,O2-,3281.6500949465126 -Li3Cr3(MoO6)2,Cr5+,Mo3+,Li1+,O2-,3281.6500949465126 -Li3Ag3(BiO6)2,Ag1+,Bi3+,Li1+,O1-,3294.5580235654265 -Li3Ta3In2O12,Ta5+,In3+,Li1+,O2-,3296.853248402327 -Li3In3(RhO6)2,In3+,Rh6+,Li1+,O2-,3300.8942172309935 -Li3In3(RhO6)2,In1+,Rh3+,Li1+,O1-,3300.8942172309935 -Rb3Li3Mn2O12,Rb1+,Mn3+,Li1+,O1-,3314.9127529598795 -Li3Sc3(WO6)2,Sc1+,W3+,Li1+,O1-,3314.932468126248 -Li3Sc3(WO6)2,Sc3+,W6+,Li1+,O2-,3314.932468126248 -Rb3Li3Ti2O12,Rb1+,Ti3+,Li1+,O1-,3318.9435868316173 -Li3Cr3(TeO6)2,Cr3+,Te6+,Li1+,O2-,3322.870843316574 -Li3Sc3(IO6)2,Sc1+,I3+,Li1+,O1-,3339.4278468081784 -Li3Hf2Ta3O12,Ta5+,Hf3+,Li1+,O2-,3340.9299889639005 -Li3In3(PdO6)2,In3+,Pd6+,Li1+,O2-,3343.7842240158484 -Rb3Li3(SO6)2,Rb1+,S3+,Li1+,O1-,3348.6567524616153 -Li3Sc3(MoO6)2,Sc3+,Mo6+,Li1+,O2-,3349.599614159249 -Li3Sc3(MoO6)2,Sc1+,Mo3+,Li1+,O1-,3349.599614159249 -K3Li3Cr2O12,K1+,Cr3+,Li1+,O1-,3350.2294041343657 -Li3Ta2V3O12,V1+,Ta3+,Li1+,O1-,3354.0000037936265 -Li3Ta2V3O12,V5+,Ta3+,Li1+,O2-,3354.0000037936265 -Li3Hf3(RuO6)2,Hf3+,Ru6+,Li1+,O2-,3359.331154520427 -Rb3Li3Zr2O12,Rb1+,Zr3+,Li1+,O1-,3370.1837379570434 -Li3TaO6,Li1+,Ta3+,Li1+,O1-,3371.7761870948343 -Li3Nb2In3O12,In1+,Nb3+,Li1+,O1-,3374.4746855584935 -Li3Ta3(CuO6)2,Ta5+,Cu3+,Li1+,O2-,3375.514711139979 -Rb3Li3Y2O12,Rb1+,Y3+,Li1+,O1-,3375.702489633803 -Li3Hf3(RhO6)2,Hf3+,Rh6+,Li1+,O2-,3377.1866753981353 -Li3Ta3(SeO6)2,Ta3+,Se6+,Li1+,O2-,3381.370395113095 -Rb3Li3(SiO6)2,Rb1+,Si3+,Li1+,O1-,3384.2359450176273 -Rb3Li3(ClO6)2,Rb1+,Cl3+,Li1+,O1-,3384.8307762718723 -Li3Sc3(TeO6)2,Sc3+,Te6+,Li1+,O2-,3385.1277902536717 -K3Li3(AsO6)2,K1+,As3+,Li1+,O1-,3390.636225687509 -Rb3Li3Al2O12,Rb1+,Al3+,Li1+,O1-,3394.2978472130862 -Li3Ta3(FeO6)2,Ta5+,Fe3+,Li1+,O2-,3395.9420922667573 -Li3Ta3(FeO6)2,Ta3+,Fe6+,Li1+,O2-,3395.9420922667573 -Li3Ta3(NiO6)2,Ta5+,Ni3+,Li1+,O2-,3396.3638306259704 -Li3Ta3(GeO6)2,Ta5+,Ge3+,Li1+,O2-,3402.1537252270814 -Li3Ta3(GeO6)2,Ta5+,Ge3-,Li1+,O1-,3402.1537252270814 -K3Li3Sc2O12,K1+,Sc3+,Li1+,O1-,3410.7206307821725 -Li3Hf3(PdO6)2,Hf3+,Pd6+,Li1+,O2-,3410.9946897690193 -Li3Ta3(GaO6)2,Ta5+,Ga3+,Li1+,O2-,3411.944264353929 -Li3Tl2Cd3O12,Cd1+,Tl3+,Li1+,O1-,3419.6768220452027 -Li3Nb3(AuO6)2,Nb5+,Au3+,Li1+,O2-,3422.0483440172084 -Li3Nb3(AuO6)2,Nb1+,Au3+,Li1+,O1-,3422.0483440172084 -Rb3Li3Lu2O12,Rb1+,Lu3+,Li1+,O1-,3426.305116063759 -K3Li3(PO6)2,K1+,P3+,Li1+,O1-,3427.829261400725 -Rb3Li3Yb2O12,Rb1+,Yb3+,Li1+,O1-,3427.8475926383835 -Rb3Li3Tm2O12,Rb1+,Tm3+,Li1+,O1-,3431.183223947853 -Rb3Li3Er2O12,Rb1+,Er3+,Li1+,O1-,3432.5637783096267 -Rb3Li3Ho2O12,Rb1+,Ho3+,Li1+,O1-,3434.5020943088743 -Rb3Li3Dy2O12,Rb1+,Dy3+,Li1+,O1-,3436.5492549160226 -Li3V3(BrO6)2,V1+,Br3+,Li1+,O1-,3436.5540815338063 -Li3V3(BrO6)2,V5+,Br3+,Li1+,O2-,3436.5540815338063 -Rb3Li3Tb2O12,Rb1+,Tb3+,Li1+,O1-,3439.606278934057 -Rb3Li3Gd2O12,Rb1+,Gd3+,Li1+,O1-,3441.0582259564394 -Rb3Li3Eu2O12,Rb1+,Eu3+,Li1+,O1-,3445.7218496038017 -Rb3Li3Sm2O12,Rb1+,Sm3+,Li1+,O1-,3447.1623213884936 -Li3Ta3Mn2O12,Ta3+,Mn6+,Li1+,O2-,3450.903319936502 -Li3Ta3Mn2O12,Ta5+,Mn3-,Li1+,O1-,3450.903319936502 -Li3Ta3Mn2O12,Ta5+,Mn3+,Li1+,O2-,3450.903319936502 -Rb3Li3Nd2O12,Rb1+,Nd3+,Li1+,O1-,3452.768577458826 -Li3Ta3Ti2O12,Ta5+,Ti3+,Li1+,O2-,3455.8369066127643 -Rb3Li3Pr2O12,Rb1+,Pr3+,Li1+,O1-,3455.900933978399 -Rb3Li3Ce2O12,Rb1+,Ce3+,Li1+,O1-,3456.6528147529825 -Rb3Li3La2O12,Rb1+,La3+,Li1+,O1-,3457.808695643793 -Li3In3(BiO6)2,In1+,Bi3+,Li1+,O1-,3465.9759445612144 -Rb3Li3(CoO6)2,Rb1+,Co3+,Li1+,O1-,3474.9833546416976 -Cs3Li3(AgO6)2,Cs1+,Ag3+,Li1+,O1-,3478.6552376149984 -Li3Zr2Ta3O12,Ta5+,Zr3+,Li1+,O2-,3478.7777314717814 -Li3Ta3(SO6)2,Ta3+,S6+,Li1+,O2-,3480.4455056166616 -Li3Ta3(SO6)2,Ta5+,S3+,Li1+,O2-,3480.4455056166616 -Li3Y2Ta3O12,Ta5+,Y3+,Li1+,O2-,3483.142384026998 -Li3Tl2(AgO4)3,Ag1+,Tl3+,Li1+,O1-,3484.476976513642 -Rb3Li3(NO6)2,Rb1+,N3+,Li1+,O1-,3491.0826442192247 -Li3BrO6,Li1+,Br3+,Li1+,O1-,3491.1576355431025 -Li3Fe3(RuO6)2,Fe1+,Ru3+,Li1+,O1-,3493.826855291105 -Li3Fe3(RuO6)2,Fe5+,Ru3+,Li1+,O2-,3493.826855291105 -Li3Fe3(RuO6)2,Fe3+,Ru6+,Li1+,O2-,3493.826855291105 -Li3Ta3(ClO6)2,Ta5+,Cl3+,Li1+,O2-,3503.0033096956004 -Li3Ta3(ClO6)2,Ta3+,Cl6+,Li1+,O2-,3503.0033096956004 -Li3Ta2Cr3O12,Cr1+,Ta3+,Li1+,O1-,3503.6337327339847 -Li3Ta2Cr3O12,Cr5+,Ta3+,Li1+,O2-,3503.6337327339847 -Li3Lu2Ta3O12,Ta5+,Lu3+,Li1+,O2-,3503.9081563291475 -Li3Ta3(SiO6)2,Ta5+,Si3-,Li1+,O1-,3504.7632261731897 -Li3Ta3(SiO6)2,Ta5+,Si3+,Li1+,O2-,3504.7632261731897 -Li3Yb2Ta3O12,Ta5+,Yb3+,Li1+,O2-,3505.321069380978 -Rb3Li3(ReO6)2,Rb1+,Re3+,Li1+,O1-,3506.087449972268 -Li3Tm2Ta3O12,Ta5+,Tm3+,Li1+,O2-,3508.3647288144994 -Li3Er2Ta3O12,Ta5+,Er3+,Li1+,O2-,3509.6197477724368 -Li3Ho2Ta3O12,Ta5+,Ho3+,Li1+,O2-,3511.3771971864403 -Li3Ta3Al2O12,Ta5+,Al3+,Li1+,O2-,3511.593969782935 -Li3Dy2Ta3O12,Ta5+,Dy3+,Li1+,O2-,3513.2275085664364 -Rb3Li3(CO6)2,Rb1+,C3+,Li1+,O1-,3515.2907120784457 -Li3Tb2Ta3O12,Ta5+,Tb3+,Li1+,O2-,3515.9794969426184 -Li3Bi3(AuO6)2,Bi5+,Au3+,Li1+,O2-,3517.117632985407 -Li3Bi3(AuO6)2,Bi1+,Au3+,Li1+,O1-,3517.117632985407 -Li3Gd2Ta3O12,Ta5+,Gd3+,Li1+,O2-,3517.2819407171705 -Li3Eu2Ta3O12,Ta5+,Eu3+,Li1+,O2-,3521.4453580159457 -Li3Fe3(RhO6)2,Fe3+,Rh6+,Li1+,O2-,3522.048007904985 -Li3Fe3(RhO6)2,Fe5+,Rh3+,Li1+,O2-,3522.048007904985 -Li3Fe3(RhO6)2,Fe1+,Rh3+,Li1+,O1-,3522.048007904985 -Li3Sm2Ta3O12,Ta5+,Sm3+,Li1+,O2-,3522.7251980595147 -Li3Nd2Ta3O12,Ta5+,Nd3+,Li1+,O2-,3527.678986327779 -Li3Pr2Ta3O12,Ta5+,Pr3+,Li1+,O2-,3530.4280295055664 -Li3Ce2Ta3O12,Ta5+,Ce3+,Li1+,O2-,3531.0859137903485 -Li3La2Ta3O12,Ta5+,La3+,Li1+,O2-,3532.0957974625267 -Li3Zn3(RuO6)2,Zn1+,Ru3+,Li1+,O1-,3556.0626051649356 -Li3Ta3(CoO6)2,Ta5+,Co3+,Li1+,O2-,3557.240803056734 -Li3Ta3(ReO6)2,Ta3+,Re6+,Li1+,O2-,3561.885715525755 -Li3Ta3(ReO6)2,Ta5+,Re3+,Li1+,O2-,3561.885715525755 -Li3Ta3(ReO6)2,Ta5+,Re3-,Li1+,O1-,3561.885715525755 -Li3Sc3Ta2O12,Sc1+,Ta3+,Li1+,O1-,3561.909816489347 -Li3Fe3(PdO6)2,Fe3+,Pd6+,Li1+,O2-,3575.1093914470694 -Li3Ta3(NO6)2,Ta5+,N3-,Li1+,O1-,3576.88697237485 -Li3Ta3(NO6)2,Ta5+,N3+,Li1+,O2-,3576.88697237485 -Rb3Li3(SbO6)2,Rb1+,Sb3+,Li1+,O1-,3577.523728174345 -Li3Zn3(RhO6)2,Zn1+,Rh3+,Li1+,O1-,3582.595244593105 -Li3Ta3(CO6)2,Ta5+,C3+,Li1+,O2-,3592.6407682405024 -Li3Ta3(CO6)2,Ta5+,C3-,Li1+,O1-,3592.6407682405024 -Rb3Li3(BO6)2,Rb1+,B3+,Li1+,O1-,3596.1068467765135 -Li3Hg3(RuO6)2,Hg1+,Ru3+,Li1+,O1-,3605.7509310769924 -Cs3Li3In2O12,Cs1+,In3+,Li1+,O1-,3608.1051257513745 -Li3Mn3(RuO6)2,Mn1+,Ru3+,Li1+,O1-,3617.3632270186617 -Li3Mn3(RuO6)2,Mn5+,Ru3+,Li1+,O2-,3617.3632270186617 -Li3Mn3(RuO6)2,Mn3+,Ru6+,Li1+,O2-,3617.3632270186617 -Cs3Li3Hf2O12,Cs1+,Hf3+,Li1+,O1-,3617.8163728544314 -Li3Ta3(SbO6)2,Ta5+,Sb3-,Li1+,O1-,3620.0409327878083 -Li3Ta3(SbO6)2,Ta5+,Sb3+,Li1+,O2-,3620.0409327878083 -Rb3Li3V2O12,Rb1+,V3+,Li1+,O1-,3621.5507487101263 -Li3Hg3(RhO6)2,Hg1+,Rh3+,Li1+,O1-,3621.559769689595 -Li3Nb2(FeO4)3,Fe5+,Nb3+,Li1+,O2-,3626.433124731659 -Li3Nb2(FeO4)3,Fe1+,Nb3+,Li1+,O1-,3626.433124731659 -Li3Ti3(RuO6)2,Ti3+,Ru6+,Li1+,O2-,3634.965324923088 -Li3Ti3(RuO6)2,Ti1+,Ru3+,Li1+,O1-,3634.965324923088 -Li3Cr3(BrO6)2,Cr1+,Br3+,Li1+,O1-,3642.898507241889 -Li3Cr3(BrO6)2,Cr5+,Br3+,Li1+,O2-,3642.898507241889 -Li3Ta3(BO6)2,Ta5+,B3+,Li1+,O2-,3643.9136794518095 -Li3Mn3(RhO6)2,Mn5+,Rh3+,Li1+,O2-,3644.938699750301 -Li3Mn3(RhO6)2,Mn3+,Rh6+,Li1+,O2-,3644.938699750301 -Li3Mn3(RhO6)2,Mn1+,Rh3+,Li1+,O1-,3644.938699750301 -Li3Lu3(RuO6)2,Lu3+,Ru6+,Li1+,O2-,3647.115283945384 -Li3Zr3(RuO6)2,Zr1+,Ru3+,Li1+,O1-,3648.008692068488 -Li3Zr3(RuO6)2,Zr3+,Ru6+,Li1+,O2-,3648.008692068488 -Li3Yb3(RuO6)2,Yb3+,Ru6+,Li1+,O2-,3650.501383292448 -Li3Tl2In3O12,In1+,Tl3+,Li1+,O1-,3653.427448489519 -Li3Ta3V2O12,Ta5+,V3+,Li1+,O2-,3656.3842507899662 -Li3Tm3(RuO6)2,Tm3+,Ru6+,Li1+,O2-,3657.8576807808527 -Li3Y3(RuO6)2,Y1+,Ru3+,Li1+,O1-,3658.700505161306 -Li3Y3(RuO6)2,Y3+,Ru6+,Li1+,O2-,3658.700505161306 -Li3Er3(RuO6)2,Er3+,Ru6+,Li1+,O2-,3660.9159179206854 -Li3Ti3(RhO6)2,Ti1+,Rh3+,Li1+,O1-,3663.466303160392 -Li3Ti3(RhO6)2,Ti3+,Rh6+,Li1+,O2-,3663.466303160392 -Li3Lu3(RhO6)2,Lu3+,Rh6+,Li1+,O2-,3664.051128117264 -Li3Fe3(BiO6)2,Fe1+,Bi3+,Li1+,O1-,3664.943362967543 -Li3Fe3(BiO6)2,Fe5+,Bi3-,Li1+,O1-,3664.943362967543 -Li3Fe3(BiO6)2,Fe5+,Bi3+,Li1+,O2-,3664.943362967543 -Li3Ho3(RuO6)2,Ho3+,Ru6+,Li1+,O2-,3665.2232495997014 -Li3Yb3(RhO6)2,Yb3+,Rh6+,Li1+,O2-,3667.52837759617 -Li3Dy3(RuO6)2,Dy3+,Ru6+,Li1+,O2-,3669.7897005038917 -Li3Zr3(RhO6)2,Zr3+,Rh6+,Li1+,O2-,3671.0856641669748 -Li3Zr3(RhO6)2,Zr1+,Rh3+,Li1+,O1-,3671.0856641669748 -Li3Tm3(RhO6)2,Tm3+,Rh6+,Li1+,O2-,3675.0821216048857 -Li3Tb3(RuO6)2,Tb1+,Ru3+,Li1+,O1-,3676.6419804339166 -Li3Tb3(RuO6)2,Tb3+,Ru6+,Li1+,O2-,3676.6419804339166 -Li3Er3(RhO6)2,Er3+,Rh6+,Li1+,O2-,3678.222210729682 -Li3Gd3(RuO6)2,Gd3+,Ru6+,Li1+,O2-,3679.9105182350227 -Li3Gd3(RuO6)2,Gd1+,Ru3+,Li1+,O1-,3679.9105182350227 -Li3Y3(RhO6)2,Y3+,Rh6+,Li1+,O2-,3681.9543781166362 -Li3Y3(RhO6)2,Y1+,Rh3+,Li1+,O1-,3681.9543781166362 -Li3Nb2(HgO4)3,Hg1+,Nb3+,Li1+,O1-,3682.6245411628743 -Li3Ho3(RhO6)2,Ho3+,Rh6+,Li1+,O2-,3682.6445940792746 -Li3Nb2Zn3O12,Zn1+,Nb3+,Li1+,O1-,3683.9810121300707 -Li3Dy3(RhO6)2,Dy3+,Rh6+,Li1+,O2-,3687.3327220870196 -Li3Eu3(RuO6)2,Eu3+,Ru6+,Li1+,O2-,3690.4705965841563 -Li3Sm3(RuO6)2,Sm3+,Ru6+,Li1+,O2-,3693.751459235288 -Li3Tb3(RhO6)2,Tb1+,Rh3+,Li1+,O1-,3694.3670159191474 -Li3Tb3(RhO6)2,Tb3+,Rh6+,Li1+,O2-,3694.3670159191474 -Li3Lu3(PdO6)2,Lu3+,Pd6+,Li1+,O2-,3696.113793515548 -Li3Mn3(PdO6)2,Mn3+,Pd6+,Li1+,O2-,3696.781687961809 -Li3Hg3(BiO6)2,Hg1+,Bi3+,Li1+,O1-,3696.98378949729 -Li3Gd3(RhO6)2,Gd3+,Rh6+,Li1+,O2-,3697.7221329217023 -Li3Gd3(RhO6)2,Gd1+,Rh3+,Li1+,O1-,3697.7221329217023 -Li3Yb3(PdO6)2,Yb3+,Pd6+,Li1+,O2-,3699.7613613727194 -Li3Ca3(RuO6)2,Ca1+,Ru3+,Li1+,O1-,3701.3485683023105 -Li3Zn3(BiO6)2,Zn1+,Bi3+,Li1+,O1-,3705.0009213986496 -Li3Nd3(RuO6)2,Nd3+,Ru6+,Li1+,O2-,3706.6073613943345 -Li3Tm3(PdO6)2,Tm3+,Pd6+,Li1+,O2-,3707.683947905324 -Li3Eu3(RhO6)2,Eu3+,Rh6+,Li1+,O2-,3708.560867988201 -Li3Er3(PdO6)2,Er3+,Pd6+,Li1+,O2-,3710.9769031244095 -Li3Sm3(RhO6)2,Sm3+,Rh6+,Li1+,O2-,3711.9279738872915 -Li3Pr3(RuO6)2,Pr3+,Ru6+,Li1+,O2-,3713.851097452335 -Li3Zr3(PdO6)2,Zr3+,Pd6+,Li1+,O2-,3714.595930549307 -Li3Ce3(RuO6)2,Ce3+,Ru6+,Li1+,O2-,3715.5964093542975 -Li3Ho3(PdO6)2,Ho3+,Pd6+,Li1+,O2-,3715.614117648695 -Li3Ti3(PdO6)2,Ti3+,Pd6+,Li1+,O2-,3717.012427431697 -Li3La3(RuO6)2,La3+,Ru6+,Li1+,O2-,3718.2844801319025 -Li3Dy3(PdO6)2,Dy3+,Pd6+,Li1+,O2-,3720.52939925476 -Li3Nd3(RhO6)2,Nd3+,Rh6+,Li1+,O2-,3725.1203026524377 -Li3Y3(PdO6)2,Y3+,Pd6+,Li1+,O2-,3725.791337867063 -Li3Tb3(PdO6)2,Tb3+,Pd6+,Li1+,O2-,3727.90339237251 -Li3Sc3(BrO6)2,Sc1+,Br3+,Li1+,O1-,3730.1765206188575 -Li3Ca3(RhO6)2,Ca1+,Rh3+,Li1+,O1-,3730.6332173355345 -Li3Gd3(PdO6)2,Gd3+,Pd6+,Li1+,O2-,3731.4200554531744 -Li3Pr3(RhO6)2,Pr3+,Rh6+,Li1+,O2-,3732.5525383468644 -Li3Ce3(RhO6)2,Ce3+,Rh6+,Li1+,O2-,3734.343153095898 -Li3La3(RhO6)2,La3+,Rh6+,Li1+,O2-,3737.1009108938583 -K3Li3(WO6)2,K1+,W3+,Li1+,O1-,3738.943898220484 -Li3Tl3(AuO6)2,Tl1+,Au3+,Li1+,O1-,3740.35972973031 -Li3Ta3Cr2O12,Ta5+,Cr3+,Li1+,O2-,3740.4343136017287 -Li3Ta3Cr2O12,Ta3+,Cr6+,Li1+,O2-,3740.4343136017287 -Li3Ta3(AsO6)2,Ta5+,As3+,Li1+,O2-,3742.0932003025414 -Li3Ta3(AsO6)2,Ta5+,As3-,Li1+,O1-,3742.0932003025414 -Li3Eu3(PdO6)2,Eu3+,Pd6+,Li1+,O2-,3742.77855381183 -Cs3Li3(CuO6)2,Cs1+,Cu3+,Li1+,O1-,3745.3271909016717 -Li3Sm3(PdO6)2,Sm3+,Pd6+,Li1+,O2-,3746.3064699764745 -Rb3Li3Cr2O12,Rb1+,Cr3+,Li1+,O1-,3747.7297555491746 -Rb3Li3(AsO6)2,Rb1+,As3+,Li1+,O1-,3749.6158707102873 -Li3Mn3Nb2O12,Mn1+,Nb3+,Li1+,O1-,3754.189644787213 -Li3Mn3Nb2O12,Mn5+,Nb3+,Li1+,O2-,3754.189644787213 -Li3Mn3(BiO6)2,Mn5+,Bi3+,Li1+,O2-,3755.553089742806 -Li3Mn3(BiO6)2,Mn1+,Bi3+,Li1+,O1-,3755.553089742806 -Li3Mn3(BiO6)2,Mn5+,Bi3-,Li1+,O1-,3755.553089742806 -Li3Nd3(PdO6)2,Nd3+,Pd6+,Li1+,O2-,3760.1258554177175 -Li3Zr3(BiO6)2,Zr1+,Bi3+,Li1+,O1-,3762.2535984908377 -Li3Zr3Nb2O12,Zr1+,Nb3+,Li1+,O1-,3763.424632578024 -Li3Tb3(BiO6)2,Tb1+,Bi3+,Li1+,O1-,3764.356985647589 -Li3Mg3(RuO6)2,Mg1+,Ru3+,Li1+,O1-,3765.403668348259 -Li3Tb3Nb2O12,Tb1+,Nb3+,Li1+,O1-,3765.8141222262925 -Li3Gd3(BiO6)2,Gd1+,Bi3+,Li1+,O1-,3767.3855669332606 -Li3Pr3(PdO6)2,Pr3+,Pd6+,Li1+,O2-,3767.909256331562 -Cs3Li3(GeO6)2,Cs1+,Ge3+,Li1+,O1-,3768.1518626802363 -Li3Gd3Nb2O12,Gd1+,Nb3+,Li1+,O1-,3769.658903362693 -Li3Ce3(PdO6)2,Ce3+,Pd6+,Li1+,O2-,3769.784249196044 -Li3Y3(BiO6)2,Y1+,Bi3+,Li1+,O1-,3771.2596009678728 -Li3Ti3(BiO6)2,Ti1+,Bi3+,Li1+,O1-,3772.0349865491976 -Li3La3(PdO6)2,La3+,Pd6+,Li1+,O2-,3772.671787213873 -Cs3Li3(NiO6)2,Cs1+,Ni3+,Li1+,O1-,3775.2226261660935 -Li3Y3Nb2O12,Y1+,Nb3+,Li1+,O1-,3775.58518828644 -Li3Sc2Ta3O12,Ta5+,Sc3+,Li1+,O2-,3776.979914019405 -Li3Ti3Nb2O12,Ti1+,Nb3+,Li1+,O1-,3777.6746955662097 -Cs3Li3(FeO6)2,Cs1+,Fe3+,Li1+,O1-,3777.701101476364 -Cs3Li3(GaO6)2,Cs1+,Ga3+,Li1+,O1-,3782.6646655948803 -Na3Li3(RuO6)2,Na1+,Ru3+,Li1+,O1-,3792.0281964925953 -Li3Mg3(RhO6)2,Mg1+,Rh3+,Li1+,O1-,3797.0290624317204 -Li3Ta3(PO6)2,Ta5+,P3+,Li1+,O2-,3797.7108575606508 -Li3Ta3(PO6)2,Ta5+,P3-,Li1+,O1-,3797.7108575606508 -Rb3Li3Sc2O12,Rb1+,Sc3+,Li1+,O1-,3803.181216429872 -Cs3Li3Lu2O12,Cs1+,Lu3+,Li1+,O1-,3807.254693780586 -Cs3Li3Yb2O12,Cs1+,Yb3+,Li1+,O1-,3810.1011066770866 -Cs3Li3Tm2O12,Cs1+,Tm3+,Li1+,O1-,3816.242931524062 -Cs3Li3Er2O12,Cs1+,Er3+,Li1+,O1-,3818.7794932784027 -Sr3Li3(RuO6)2,Sr1+,Ru3+,Li1+,O1-,3819.8475160950807 -Cs3Li3Ho2O12,Cs1+,Ho3+,Li1+,O1-,3822.3355167322748 -Li3Ca3(BiO6)2,Ca1+,Bi3+,Li1+,O1-,3823.606218074684 -Na3Li3(RhO6)2,Na1+,Rh3+,Li1+,O1-,3823.709057439387 -Cs3Li3Dy2O12,Cs1+,Dy3+,Li1+,O1-,3826.084467459359 -Cs3Li3Tb2O12,Cs1+,Tb3+,Li1+,O1-,3831.6698897117394 -Cs3Li3Gd2O12,Cs1+,Gd3+,Li1+,O1-,3834.317320780268 -Rb3Li3(PO6)2,Rb1+,P3+,Li1+,O1-,3836.471074569799 -Cs3Li3Zr2O12,Cs1+,Zr3+,Li1+,O1-,3841.551847742232 -Sr3Li3(RhO6)2,Sr1+,Rh3+,Li1+,O1-,3842.364958499563 -Cs3Li3Eu2O12,Cs1+,Eu3+,Li1+,O1-,3842.797430664846 -Cs3Li3Mn2O12,Cs1+,Mn3+,Li1+,O1-,3844.6027096748508 -Cs3Li3Sm2O12,Cs1+,Sm3+,Li1+,O1-,3845.409530995532 -Li3Tl2(HgO4)3,Hg1+,Tl3+,Li1+,O1-,3846.7435057960406 -K3Li3(IO6)2,K1+,I3+,Li1+,O1-,3846.86357184355 -Cs3Li3Y2O12,Cs1+,Y3+,Li1+,O1-,3848.8442422926178 -Li3Co3(RuO6)2,Co3+,Ru6+,Li1+,O2-,3849.44850058272 -Li3Co3(RuO6)2,Co1+,Ru3+,Li1+,O1-,3849.44850058272 -Li3Co3(RuO6)2,Co5+,Ru3+,Li1+,O2-,3849.44850058272 -Li3Ca3Nb2O12,Ca1+,Nb3+,Li1+,O1-,3852.5737682826834 -Cs3Li3Nd2O12,Cs1+,Nd3+,Li1+,O1-,3855.543605771298 -Cs3Li3Ti2O12,Cs1+,Ti3+,Li1+,O1-,3858.4138548226024 -Cs3Li3Pr2O12,Cs1+,Pr3+,Li1+,O1-,3861.1836214355944 -Cs3Li3Ce2O12,Cs1+,Ce3+,Li1+,O1-,3862.5350796884472 -Cs3Li3La2O12,Cs1+,La3+,Li1+,O1-,3864.61093004244 -Cs3Li3(ReO6)2,Cs1+,Re3+,Li1+,O1-,3866.794246981172 -Li3Co3(RhO6)2,Co3+,Rh6+,Li1+,O2-,3875.038019183514 -Li3Co3(RhO6)2,Co5+,Rh3+,Li1+,O2-,3875.038019183514 -Li3Co3(RhO6)2,Co1+,Rh3+,Li1+,O1-,3875.038019183514 -Li3Mg3(BiO6)2,Mg1+,Bi3+,Li1+,O1-,3876.236834431447 -Li3Ta3(WO6)2,Ta5+,W3+,Li1+,O2-,3890.299153032498 -Li3Ta3(WO6)2,Ta3+,W6+,Li1+,O2-,3890.299153032498 -Sr3Li3(BiO6)2,Sr1+,Bi3+,Li1+,O1-,3893.9741277382773 -Na3Li3(BiO6)2,Na1+,Bi3+,Li1+,O1-,3895.2745895060584 -Li3Tl2(FeO4)3,Fe5+,Tl3+,Li1+,O2-,3896.73944586699 -Li3Tl2(FeO4)3,Fe1+,Tl3+,Li1+,O1-,3896.73944586699 -Cs3Li3(SO6)2,Cs1+,S3+,Li1+,O1-,3907.1022580286863 -K3Li3(MoO6)2,K1+,Mo3+,Li1+,O1-,3917.5799109064583 -Li3Co3(PdO6)2,Co3+,Pd6+,Li1+,O2-,3923.1649983508732 -Li3Co3(BiO6)2,Co5+,Bi3-,Li1+,O1-,3923.5637929318086 -Li3Co3(BiO6)2,Co5+,Bi3+,Li1+,O2-,3923.5637929318086 -Li3Co3(BiO6)2,Co1+,Bi3+,Li1+,O1-,3923.5637929318086 -Li3Tl2Zn3O12,Zn1+,Tl3+,Li1+,O1-,3929.115023622864 -Cs3Li3(ClO6)2,Cs1+,Cl3+,Li1+,O1-,3930.1878299123955 -Li3Tb3Tl2O12,Tb1+,Tl3+,Li1+,O1-,3931.7234323639973 -Li3Mg3Nb2O12,Mg1+,Nb3+,Li1+,O1-,3934.0221039176104 -Li3Gd3Tl2O12,Gd1+,Tl3+,Li1+,O1-,3935.5468657107394 -Li3Ru2O15,O1-,Ru6+,Li1+,O1-,3941.152036703431 -Sr3Li3Nb2O12,Sr1+,Nb3+,Li1+,O1-,3941.3913492321017 -Cs3Li3(SiO6)2,Cs1+,Si3+,Li1+,O1-,3941.75482283107 -Rb3Li3(WO6)2,Rb1+,W3+,Li1+,O1-,3946.5892666643726 -Cs3Li3Al2O12,Cs1+,Al3+,Li1+,O1-,3951.514723765349 -Na3Li3Nb2O12,Na1+,Nb3+,Li1+,O1-,3962.999126749825 -Li3Zr3Tl2O12,Zr1+,Tl3+,Li1+,O1-,3967.568436413158 -Cs3Li3(CoO6)2,Cs1+,Co3+,Li1+,O1-,3967.6393711789656 -Li3Ta3(IO6)2,Ta5+,I3+,Li1+,O2-,3969.7978296259266 -Li3Rh2O15,O1-,Rh6+,Li1+,O1-,3973.08352531476 -Li3Y3Tl2O12,Y1+,Tl3+,Li1+,O1-,3978.275052250088 -Cs3Li3(SbO6)2,Cs1+,Sb3+,Li1+,O1-,3980.715224808129 -Li3Mn3Tl2O12,Mn1+,Tl3+,Li1+,O1-,3989.2105361323847 -Li3Mn3Tl2O12,Mn5+,Tl3+,Li1+,O2-,3989.2105361323847 -Li3Nb2(CoO4)3,Co5+,Nb3+,Li1+,O2-,3990.010199275185 -Li3Nb2(CoO4)3,Co1+,Nb3+,Li1+,O1-,3990.010199275185 -K3Li3Ta2O12,K1+,Ta3+,Li1+,O1-,3995.7371611819917 -Li3Ta3(TeO6)2,Ta3+,Te6+,Li1+,O2-,3996.1861285086284 -Li3Ti3Tl2O12,Ti1+,Tl3+,Li1+,O1-,4012.368145989576 -Li3Ta3(MoO6)2,Ta3+,Mo6+,Li1+,O2-,4016.789498493065 -Li3Ta3(MoO6)2,Ta5+,Mo3+,Li1+,O2-,4016.789498493065 -Li3Ag2(BiO4)3,Bi5+,Ag3+,Li1+,O2-,4023.834881392911 -Li3Ag2(BiO4)3,Bi1+,Ag3+,Li1+,O1-,4023.834881392911 -Li3Pd2O15,O1-,Pd6+,Li1+,O1-,4032.842750193179 -Cs3Li3(NO6)2,Cs1+,N3+,Li1+,O1-,4049.3719503146876 -Li3Ta5O12,Ta5+,Ta3+,Li1+,O2-,4050.0926665635848 -Rb3Li3(IO6)2,Rb1+,I3+,Li1+,O1-,4066.447969784413 -Cs3Li3(CO6)2,Cs1+,C3+,Li1+,O1-,4071.6660476391075 -Li3Hf2(BiO4)3,Bi1+,Hf3+,Li1+,O1-,4072.1129203826736 -Li3Hf2(BiO4)3,Bi5+,Hf3+,Li1+,O2-,4072.1129203826736 -Li3Ca3Tl2O12,Ca1+,Tl3+,Li1+,O1-,4072.1489845735414 -Li3V3(RuO6)2,V3+,Ru6+,Li1+,O2-,4086.398031069412 -Li3V3(RuO6)2,V1+,Ru3+,Li1+,O1-,4086.398031069412 -Li3V3(RuO6)2,V5+,Ru3+,Li1+,O2-,4086.398031069412 -Cs3Li3V2O12,Cs1+,V3+,Li1+,O1-,4096.006807330572 -Li3V3(BiO6)2,V5+,Bi3+,Li1+,O2-,4097.519898836284 -Li3V3(BiO6)2,V1+,Bi3+,Li1+,O1-,4097.519898836284 -Li3V3(BiO6)2,V5+,Bi3-,Li1+,O1-,4097.519898836284 -Sr3Li3Tl2O12,Sr1+,Tl3+,Li1+,O1-,4103.168165614856 -Li3V3(RhO6)2,V3+,Rh6+,Li1+,O2-,4111.538988536731 -Li3V3(RhO6)2,V1+,Rh3+,Li1+,O1-,4111.538988536731 -Li3V3(RhO6)2,V5+,Rh3+,Li1+,O2-,4111.538988536731 -Li3In2(BiO4)3,Bi1+,In3+,Li1+,O1-,4118.572124560382 -Li3In2(BiO4)3,Bi5+,In3+,Li1+,O2-,4118.572124560382 -Cs3Li3(BO6)2,Cs1+,B3+,Li1+,O1-,4136.425719743563 -Li3Mg3Tl2O12,Mg1+,Tl3+,Li1+,O1-,4142.410612336345 -Rb3Li3(MoO6)2,Rb1+,Mo3+,Li1+,O1-,4142.853901502226 -Li3Nb3(AgO6)2,Nb1+,Ag3+,Li1+,O1-,4154.293021402507 -Li3Nb3(AgO6)2,Nb5+,Ag3+,Li1+,O2-,4154.293021402507 -Li3Tl2(CoO4)3,Co1+,Tl3+,Li1+,O1-,4155.648351083472 -Li3Tl2(CoO4)3,Co5+,Tl3+,Li1+,O2-,4155.648351083472 -Li3V3(PdO6)2,V3+,Pd6+,Li1+,O2-,4158.786911153241 -Rb3Li3Ta2O12,Rb1+,Ta3+,Li1+,O1-,4161.846693266116 -Na3Li3Tl2O12,Na1+,Tl3+,Li1+,O1-,4163.222712043622 -Cs3Li3(AsO6)2,Cs1+,As3+,Li1+,O1-,4170.247842184 -Cs3Li3Cr2O12,Cs1+,Cr3+,Li1+,O1-,4195.691076459607 -Li3Hf2Nb3O12,Nb1+,Hf3+,Li1+,O1-,4200.667853885991 -Li3Hf2Nb3O12,Nb5+,Hf3+,Li1+,O2-,4200.667853885991 -Li3Lu2(BiO4)3,Bi1+,Lu3+,Li1+,O1-,4227.900858290094 -Li3Lu2(BiO4)3,Bi5+,Lu3+,Li1+,O2-,4227.900858290094 -Li3Yb2(BiO4)3,Bi1+,Yb3+,Li1+,O1-,4231.5665643760485 -Li3Yb2(BiO4)3,Bi5+,Yb3+,Li1+,O2-,4231.5665643760485 -Li3Cr3(BiO6)2,Cr1+,Bi3+,Li1+,O1-,4233.500795472701 -Li3Cr3(BiO6)2,Cr5+,Bi3+,Li1+,O2-,4233.500795472701 -Li3Cr3(BiO6)2,Cr5+,Bi3-,Li1+,O1-,4233.500795472701 -Li3Tm2(BiO4)3,Bi5+,Tm3+,Li1+,O2-,4239.456976056104 -Li3Tm2(BiO4)3,Bi1+,Tm3+,Li1+,O1-,4239.456976056104 -Li3Nb2V3O12,V5+,Nb3+,Li1+,O2-,4240.086342072343 -Li3Nb2V3O12,V1+,Nb3+,Li1+,O1-,4240.086342072343 -Li3Er2(BiO4)3,Bi5+,Er3+,Li1+,O2-,4242.708053905602 -Li3Er2(BiO4)3,Bi1+,Er3+,Li1+,O1-,4242.708053905602 -Cs3Li3(WO6)2,Cs1+,W3+,Li1+,O1-,4245.01994792792 -Li3Ho2(BiO4)3,Bi5+,Ho3+,Li1+,O2-,4247.258261255362 -Li3Ho2(BiO4)3,Bi1+,Ho3+,Li1+,O1-,4247.258261255362 -Cs3Li3Sc2O12,Cs1+,Sc3+,Li1+,O1-,4248.884342089107 -Li3Ta3(BrO6)2,Ta5+,Br3+,Li1+,O2-,4251.137180804595 -Li3Dy2(BiO4)3,Bi5+,Dy3+,Li1+,O2-,4252.045877380432 -Li3Dy2(BiO4)3,Bi1+,Dy3+,Li1+,O1-,4252.045877380432 -Li3Bi3(SeO6)2,Bi3+,Se6+,Li1+,O2-,4255.0326408246365 -Li3Tb2(BiO4)3,Bi1+,Tb3+,Li1+,O1-,4259.160827973069 -Li3Tb2(BiO4)3,Bi5+,Tb3+,Li1+,O2-,4259.160827973069 -Li3Gd2(BiO4)3,Bi5+,Gd3+,Li1+,O2-,4262.525763326538 -Li3Gd2(BiO4)3,Bi1+,Gd3+,Li1+,O1-,4262.525763326538 -Li3BiO6,Li1+,Bi3+,Li1+,O1-,4264.389358127292 -Li3Re2(BiO4)3,Bi5+,Re3+,Li1+,O2-,4268.429454260167 -Li3Re2(BiO4)3,Bi3+,Re6+,Li1+,O2-,4268.429454260167 -Li3Re2(BiO4)3,Bi1+,Re3+,Li1+,O1-,4268.429454260167 -Li3Eu2(BiO4)3,Bi5+,Eu3+,Li1+,O2-,4273.271923650306 -Li3Eu2(BiO4)3,Bi1+,Eu3+,Li1+,O1-,4273.271923650306 -Li3Cr3(RuO6)2,Cr1+,Ru3+,Li1+,O1-,4273.842272824958 -Li3Cr3(RuO6)2,Cr3+,Ru6+,Li1+,O2-,4273.842272824958 -Li3Cr3(RuO6)2,Cr5+,Ru3+,Li1+,O2-,4273.842272824958 -Li3Sm2(BiO4)3,Bi5+,Sm3+,Li1+,O2-,4276.572171117875 -Li3Sm2(BiO4)3,Bi1+,Sm3+,Li1+,O1-,4276.572171117875 -Li3Cu2(BiO4)3,Bi5+,Cu3+,Li1+,O2-,4277.543028952815 -Li3Cu2(BiO4)3,Bi1+,Cu3+,Li1+,O1-,4277.543028952815 -Li3Ge2(BiO4)3,Bi5+,Ge3+,Li1+,O2-,4285.252432142142 -Li3Ge2(BiO4)3,Bi5+,Ge3-,Li1+,O1-,4285.252432142142 -Li3Ge2(BiO4)3,Bi1+,Ge3+,Li1+,O1-,4285.252432142142 -Li3Nd2(BiO4)3,Bi5+,Nd3+,Li1+,O2-,4289.332332365159 -Li3Nd2(BiO4)3,Bi1+,Nd3+,Li1+,O1-,4289.332332365159 -Li3Tl3(AgO6)2,Tl1+,Ag3+,Li1+,O1-,4291.973981813035 -Li3Nb3In2O12,Nb5+,In3+,Li1+,O2-,4292.26035092318 -Li3Nb3In2O12,Nb1+,In3+,Li1+,O1-,4292.26035092318 -Cs3Li3(PO6)2,Cs1+,P3+,Li1+,O1-,4293.6462580253265 -Li3Pr2(BiO4)3,Bi5+,Pr3+,Li1+,O2-,4296.403923313727 -Li3Pr2(BiO4)3,Bi1+,Pr3+,Li1+,O1-,4296.403923313727 -Li3Cr3(RhO6)2,Cr5+,Rh3+,Li1+,O2-,4297.647294684737 -Li3Cr3(RhO6)2,Cr1+,Rh3+,Li1+,O1-,4297.647294684737 -Li3Cr3(RhO6)2,Cr3+,Rh6+,Li1+,O2-,4297.647294684737 -Li3Ce2(BiO4)3,Bi1+,Ce3+,Li1+,O1-,4298.095249149767 -Li3Ce2(BiO4)3,Bi5+,Ce3+,Li1+,O2-,4298.095249149767 -Li3Ga2(BiO4)3,Bi5+,Ga3+,Li1+,O2-,4299.463543310223 -Li3Ga2(BiO4)3,Bi1+,Ga3+,Li1+,O1-,4299.463543310223 -Li3La2(BiO4)3,Bi5+,La3+,Li1+,O2-,4300.690760688787 -Li3La2(BiO4)3,Bi1+,La3+,Li1+,O1-,4300.690760688787 -Li3Ni2(BiO4)3,Bi1+,Ni3+,Li1+,O1-,4305.706624229296 -Li3Ni2(BiO4)3,Bi5+,Ni3+,Li1+,O2-,4305.706624229296 -Li3Sc3(BiO6)2,Sc1+,Bi3+,Li1+,O1-,4307.643192700378 -Li3Hf2Tl3O12,Tl1+,Hf3+,Li1+,O1-,4308.799085198923 -Li3Fe2(BiO4)3,Bi5+,Fe3+,Li1+,O2-,4310.7668635247155 -Li3Fe2(BiO4)3,Bi3+,Fe6+,Li1+,O2-,4310.7668635247155 -Li3Fe2(BiO4)3,Bi1+,Fe3+,Li1+,O1-,4310.7668635247155 -Li3Zr2(BiO4)3,Bi1+,Zr3+,Li1+,O1-,4323.462514857588 -Li3Zr2(BiO4)3,Bi5+,Zr3+,Li1+,O2-,4323.462514857588 -Li3Y2(BiO4)3,Bi5+,Y3+,Li1+,O2-,4331.315045362539 -Li3Y2(BiO4)3,Bi1+,Y3+,Li1+,O1-,4331.315045362539 -Li3RuO6,Li1+,Ru3+,Li1+,O1-,4332.5411883276565 -Li3Tl2V3O12,V5+,Tl3+,Li1+,O2-,4338.854935305974 -Li3Tl2V3O12,V1+,Tl3+,Li1+,O1-,4338.854935305974 -Li3Cr3(PdO6)2,Cr3+,Pd6+,Li1+,O2-,4342.38915171666 -K3Li3(BrO6)2,K1+,Br3+,Li1+,O1-,4348.989903835065 -Li3Mn2(BiO4)3,Bi3+,Mn6+,Li1+,O2-,4362.608259575285 -Li3Mn2(BiO4)3,Bi1+,Mn3+,Li1+,O1-,4362.608259575285 -Li3Mn2(BiO4)3,Bi5+,Mn3+,Li1+,O2-,4362.608259575285 -Li3RhO6,Li1+,Rh3+,Li1+,O1-,4363.17777366152 -Li3Sc3(RuO6)2,Sc1+,Ru3+,Li1+,O1-,4378.637243350018 -Li3Sc3(RuO6)2,Sc3+,Ru6+,Li1+,O2-,4378.637243350018 -Li3Ti2(BiO4)3,Bi5+,Ti3+,Li1+,O2-,4380.880842252892 -Li3Ti2(BiO4)3,Bi1+,Ti3+,Li1+,O1-,4380.880842252892 -Li3Tl3In2O12,Tl1+,In3+,Li1+,O1-,4384.418242221474 -Cs3Li3(IO6)2,Cs1+,I3+,Li1+,O1-,4384.437610848579 -Li3Cd3(OsO6)2,Cd1+,Os3+,Li1+,O1-,4389.04167268488 -Li3Sc3(RhO6)2,Sc1+,Rh3+,Li1+,O1-,4402.655588274859 -Li3Sc3(RhO6)2,Sc3+,Rh6+,Li1+,O2-,4402.655588274859 -Li3Bi3(SbO6)2,Bi5+,Sb3-,Li1+,O1-,4406.138226880104 -Li3Bi3(SbO6)2,Bi1+,Sb3+,Li1+,O1-,4406.138226880104 -Li3Bi3(SbO6)2,Bi5+,Sb3+,Li1+,O2-,4406.138226880104 -Li3Cd3(IrO6)2,Cd1+,Ir3+,Li1+,O1-,4409.075587052004 -Li3Lu2Nb3O12,Nb1+,Lu3+,Li1+,O1-,4422.001401501522 -Li3Lu2Nb3O12,Nb5+,Lu3+,Li1+,O2-,4422.001401501522 -Li3Yb2Nb3O12,Nb1+,Yb3+,Li1+,O1-,4428.084140906083 -Li3Yb2Nb3O12,Nb5+,Yb3+,Li1+,O2-,4428.084140906083 -Cs3Li3Ta2O12,Cs1+,Ta3+,Li1+,O1-,4430.580541856141 -Li3Nb2Cr3O12,Cr1+,Nb3+,Li1+,O1-,4432.172000685302 -Li3Nb2Cr3O12,Cr5+,Nb3+,Li1+,O2-,4432.172000685302 -Li3Bi3(SO6)2,Bi5+,S3+,Li1+,O2-,4435.543602242317 -Li3Bi3(SO6)2,Bi3+,S6+,Li1+,O2-,4435.543602242317 -Li3Bi3(SO6)2,Bi1+,S3+,Li1+,O1-,4435.543602242317 -Li3Cd3(PtO6)2,Cd1+,Pt3+,Li1+,O1-,4437.683627861149 -Li3Tm2Nb3O12,Nb5+,Tm3+,Li1+,O2-,4441.232953288253 -Li3Tm2Nb3O12,Nb1+,Tm3+,Li1+,O1-,4441.232953288253 -Li3Er2Nb3O12,Nb5+,Er3+,Li1+,O2-,4446.672911786986 -Li3Er2Nb3O12,Nb1+,Er3+,Li1+,O1-,4446.672911786986 -Li3Sc3(PdO6)2,Sc3+,Pd6+,Li1+,O2-,4447.766510914183 -Li3Bi3(ClO6)2,Bi5+,Cl3+,Li1+,O2-,4448.91161714048 -Li3Bi3(ClO6)2,Bi1+,Cl3+,Li1+,O1-,4448.91161714048 -Li3Bi3(ClO6)2,Bi3+,Cl6+,Li1+,O2-,4448.91161714048 -Li3Co2(BiO4)3,Bi5+,Co3+,Li1+,O2-,4452.000126062084 -Li3Co2(BiO4)3,Bi1+,Co3+,Li1+,O1-,4452.000126062084 -Li3Ho2Nb3O12,Nb1+,Ho3+,Li1+,O1-,4454.308624353689 -Li3Ho2Nb3O12,Nb5+,Ho3+,Li1+,O2-,4454.308624353689 -Li3Dy2Nb3O12,Nb1+,Dy3+,Li1+,O1-,4462.370504316691 -Li3Dy2Nb3O12,Nb5+,Dy3+,Li1+,O2-,4462.370504316691 -Li3Hf3(OsO6)2,Hf3+,Os6+,Li1+,O2-,4463.237869855197 -Li3Si2(BiO4)3,Bi5+,Si3+,Li1+,O2-,4466.063344375888 -Li3Si2(BiO4)3,Bi1+,Si3+,Li1+,O1-,4466.063344375888 -Li3Lu2Tl3O12,Tl1+,Lu3+,Li1+,O1-,4467.8323754993735 -Li3Ag3(OsO6)2,Ag3+,Os6+,Li1+,O2-,4470.25090731572 -Li3Ag3(OsO6)2,Ag1+,Os3+,Li1+,O1-,4470.25090731572 -Cs3Li3(MoO6)2,Cs1+,Mo3+,Li1+,O1-,4471.82073199991 -Li3Yb2Tl3O12,Tl1+,Yb3+,Li1+,O1-,4472.330174497462 -Li3Nb3(ReO6)2,Nb1+,Re3+,Li1+,O1-,4473.814890032738 -Li3Nb3(ReO6)2,Nb3+,Re6+,Li1+,O2-,4473.814890032738 -Li3Nb3(ReO6)2,Nb5+,Re3-,Li1+,O1-,4473.814890032738 -Li3Nb3(ReO6)2,Nb5+,Re3+,Li1+,O2-,4473.814890032738 -Li3Tb2Nb3O12,Nb1+,Tb3+,Li1+,O1-,4474.404317328882 -Li3Tb2Nb3O12,Nb5+,Tb3+,Li1+,O2-,4474.404317328882 -Li3Al2(BiO4)3,Bi1+,Al3+,Li1+,O1-,4474.626204805595 -Li3Al2(BiO4)3,Bi5+,Al3+,Li1+,O2-,4474.626204805595 -Li3Tl2Cr3O12,Cr1+,Tl3+,Li1+,O1-,4475.461755439087 -Li3Tl2Cr3O12,Cr5+,Tl3+,Li1+,O2-,4475.461755439087 -Li3Hf3(IrO6)2,Hf3+,Ir6+,Li1+,O2-,4479.505346335431 -Li3Gd2Nb3O12,Nb1+,Gd3+,Li1+,O1-,4480.117737824119 -Li3Gd2Nb3O12,Nb5+,Gd3+,Li1+,O2-,4480.117737824119 -Li3Tm2Tl3O12,Tl1+,Tm3+,Li1+,O1-,4482.012824989183 -Li3Er2Tl3O12,Tl1+,Er3+,Li1+,O1-,4486.002819341624 -Li3Ag3(IrO6)2,Ag1+,Ir3+,Li1+,O1-,4490.230855171025 -Li3Ag3(IrO6)2,Ag3+,Ir6+,Li1+,O2-,4490.230855171025 -Rb3Li3(BrO6)2,Rb1+,Br3+,Li1+,O1-,4490.344137741579 -Li3Ho2Tl3O12,Tl1+,Ho3+,Li1+,O1-,4491.587667053858 -Li3Dy2Tl3O12,Tl1+,Dy3+,Li1+,O1-,4497.464477003962 -Li3Eu2Nb3O12,Nb5+,Eu3+,Li1+,O2-,4498.460018765928 -Li3Eu2Nb3O12,Nb1+,Eu3+,Li1+,O1-,4498.460018765928 -Li3Hf3(PtO6)2,Hf3+,Pt6+,Li1+,O2-,4502.7771877962905 -Li3Sm2Nb3O12,Nb5+,Sm3+,Li1+,O2-,4504.1226653632475 -Li3Sm2Nb3O12,Nb1+,Sm3+,Li1+,O1-,4504.1226653632475 -Li3Tl3(ReO6)2,Tl3+,Re6+,Li1+,O2-,4504.326591980823 -Li3Tl3(ReO6)2,Tl1+,Re3+,Li1+,O1-,4504.326591980823 -Li3Tb2Tl3O12,Tl1+,Tb3+,Li1+,O1-,4506.199176721019 -Li3Gd2Tl3O12,Tl1+,Gd3+,Li1+,O1-,4510.330604418879 -Li3Ta3(BiO6)2,Ta5+,Bi3+,Li1+,O2-,4513.271918350692 -Li3Ta3(BiO6)2,Ta5+,Bi3-,Li1+,O1-,4513.271918350692 -Li3Ag3(PtO6)2,Ag1+,Pt3+,Li1+,O1-,4518.7574547663235 -Li3Ag3(PtO6)2,Ag3+,Pt6+,Li1+,O2-,4518.7574547663235 -Li3Nb3(SeO6)2,Nb3+,Se6+,Li1+,O2-,4521.06720752636 -Li3Eu2Tl3O12,Tl1+,Eu3+,Li1+,O1-,4523.52654944443 -Li3Nd2Nb3O12,Nb5+,Nd3+,Li1+,O2-,4526.148854795757 -Li3Nd2Nb3O12,Nb1+,Nd3+,Li1+,O1-,4526.148854795757 -Li3Sm2Tl3O12,Tl1+,Sm3+,Li1+,O1-,4527.579741182479 -Li3Pr2Nb3O12,Nb1+,Pr3+,Li1+,O1-,4538.446722406138 -Li3Pr2Nb3O12,Nb5+,Pr3+,Li1+,O2-,4538.446722406138 -Li3Ce2Nb3O12,Nb5+,Ce3+,Li1+,O2-,4541.397733362354 -Li3Ce2Nb3O12,Nb1+,Ce3+,Li1+,O1-,4541.397733362354 -Li3Tl3(SeO6)2,Tl3+,Se6+,Li1+,O2-,4542.169227584058 -Li3Nd2Tl3O12,Tl1+,Nd3+,Li1+,O1-,4543.253724237174 -Li3NbO6,Li1+,Nb3+,Li1+,O1-,4544.176419322413 -Li3La2Nb3O12,Nb5+,La3+,Li1+,O2-,4545.933678100674 -Li3La2Nb3O12,Nb1+,La3+,Li1+,O1-,4545.933678100674 -Li3Sc3Nb2O12,Sc1+,Nb3+,Li1+,O1-,4546.442249338503 -Li3Pr2Tl3O12,Tl1+,Pr3+,Li1+,O1-,4551.941927149861 -Li3Ce2Tl3O12,Tl1+,Ce3+,Li1+,O1-,4554.020090622137 -Li3La2Tl3O12,Tl1+,La3+,Li1+,O1-,4557.209386130875 -Li3Sc3Tl2O12,Sc1+,Tl3+,Li1+,O1-,4557.261011583717 -Li3V2(BiO4)3,Bi5+,V3+,Li1+,O2-,4557.476742704218 -Li3V2(BiO4)3,Bi1+,V3+,Li1+,O1-,4557.476742704218 -Li3TlO6,Li1+,Tl3+,Li1+,O1-,4557.702192416191 -Li3Bi3(NO6)2,Bi5+,N3-,Li1+,O1-,4562.3898902290275 -Li3Bi3(NO6)2,Bi1+,N3+,Li1+,O1-,4562.3898902290275 -Li3Bi3(NO6)2,Bi5+,N3+,Li1+,O2-,4562.3898902290275 -Li3Nb3(CuO6)2,Nb5+,Cu3+,Li1+,O2-,4569.505867300251 -Li3Nb3(CuO6)2,Nb1+,Cu3+,Li1+,O1-,4569.505867300251 -Li3Nb3(GeO6)2,Nb5+,Ge3-,Li1+,O1-,4573.092195355844 -Li3Nb3(GeO6)2,Nb5+,Ge3+,Li1+,O2-,4573.092195355844 -Li3Nb3(GeO6)2,Nb1+,Ge3+,Li1+,O1-,4573.092195355844 -Li3Tl3(CuO6)2,Tl1+,Cu3+,Li1+,O1-,4574.293193371189 -Li3Tl3(GeO6)2,Tl1+,Ge3+,Li1+,O1-,4576.554985005339 -Li3Bi3(WO6)2,Bi1+,W3+,Li1+,O1-,4576.739159061715 -Li3Bi3(WO6)2,Bi3+,W6+,Li1+,O2-,4576.739159061715 -Li3Bi3(WO6)2,Bi5+,W3+,Li1+,O2-,4576.739159061715 -Li3Bi3(CO6)2,Bi5+,C3-,Li1+,O1-,4581.164451438008 -Li3Bi3(CO6)2,Bi1+,C3+,Li1+,O1-,4581.164451438008 -Li3Bi3(CO6)2,Bi5+,C3+,Li1+,O2-,4581.164451438008 -Li3Bi3(AsO6)2,Bi5+,As3+,Li1+,O2-,4592.231286937897 -Li3Bi3(AsO6)2,Bi1+,As3+,Li1+,O1-,4592.231286937897 -Li3Bi3(AsO6)2,Bi5+,As3-,Li1+,O1-,4592.231286937897 -Li3Tl3(GaO6)2,Tl1+,Ga3+,Li1+,O1-,4592.729454180015 -Li3Nb3(GaO6)2,Nb5+,Ga3+,Li1+,O2-,4597.807394942865 -Li3Nb3(GaO6)2,Nb1+,Ga3+,Li1+,O1-,4597.807394942865 -Li3Ta3(RuO6)2,Ta3+,Ru6+,Li1+,O2-,4600.360250784863 -Li3Ta3(RuO6)2,Ta5+,Ru3+,Li1+,O2-,4600.360250784863 -Li3Zr2Tl3O12,Tl1+,Zr3+,Li1+,O1-,4604.550840592507 -Li3Tl3(NiO6)2,Tl1+,Ni3+,Li1+,O1-,4605.921487460943 -Li3Hg3(OsO6)2,Hg1+,Os3+,Li1+,O1-,4611.644172968098 -Li3Tl3(FeO6)2,Tl3+,Fe6+,Li1+,O2-,4612.880132867533 -Li3Tl3(FeO6)2,Tl1+,Fe3+,Li1+,O1-,4612.880132867533 -Li3Ta3(RhO6)2,Ta3+,Rh6+,Li1+,O2-,4613.340449655426 -Li3Ta3(RhO6)2,Ta5+,Rh3+,Li1+,O2-,4613.340449655426 -Li3Y2Tl3O12,Tl1+,Y3+,Li1+,O1-,4613.80956574635 -Li3Zr2Nb3O12,Nb5+,Zr3+,Li1+,O2-,4615.170573902064 -Li3Zr2Nb3O12,Nb1+,Zr3+,Li1+,O1-,4615.170573902064 -Li3Nb3(NiO6)2,Nb5+,Ni3+,Li1+,O2-,4618.4286867471665 -Li3Nb3(NiO6)2,Nb1+,Ni3+,Li1+,O1-,4618.4286867471665 -Li3In3(OsO6)2,In3+,Os6+,Li1+,O2-,4622.383761292432 -Li3In3(OsO6)2,In1+,Os3+,Li1+,O1-,4622.383761292432 -Li3Hg3(IrO6)2,Hg1+,Ir3+,Li1+,O1-,4626.520262634529 -Li3Y2Nb3O12,Nb5+,Y3+,Li1+,O2-,4629.128865127343 -Li3Y2Nb3O12,Nb1+,Y3+,Li1+,O1-,4629.128865127343 -Li3Nb3(FeO6)2,Nb3+,Fe6+,Li1+,O2-,4629.363354903728 -Li3Nb3(FeO6)2,Nb5+,Fe3+,Li1+,O2-,4629.363354903728 -Li3Nb3(FeO6)2,Nb1+,Fe3+,Li1+,O1-,4629.363354903728 -Li3Bi3(BO6)2,Bi1+,B3+,Li1+,O1-,4630.18508693618 -Li3Bi3(BO6)2,Bi5+,B3+,Li1+,O2-,4630.18508693618 -Li3Cr2(BiO4)3,Bi3+,Cr6+,Li1+,O2-,4632.023232443535 -Li3Cr2(BiO4)3,Bi5+,Cr3+,Li1+,O2-,4632.023232443535 -Li3Cr2(BiO4)3,Bi1+,Cr3+,Li1+,O1-,4632.023232443535 -Li3Ta3(PdO6)2,Ta3+,Pd6+,Li1+,O2-,4637.919534574022 -Li3In3(IrO6)2,In3+,Ir6+,Li1+,O2-,4641.279349196638 -Li3In3(IrO6)2,In1+,Ir3+,Li1+,O1-,4641.279349196638 -Li3Hg3(PtO6)2,Hg1+,Pt3+,Li1+,O1-,4647.811693974321 -Li3Mn2Tl3O12,Tl3+,Mn6+,Li1+,O2-,4666.071080241032 -Li3Mn2Tl3O12,Tl1-,Mn6+,Li1+,O1-,4666.071080241032 -Li3Mn2Tl3O12,Tl1+,Mn3+,Li1+,O1-,4666.071080241032 -Li3In3(PtO6)2,In3+,Pt6+,Li1+,O2-,4668.264027464389 -Li3In3(PtO6)2,In1+,Pt3+,Li1+,O1-,4668.264027464389 -Li3Tl3(SbO6)2,Tl1+,Sb3+,Li1+,O1-,4672.241386677728 -Li3Ta3Tl2O12,Ta5+,Tl3+,Li1+,O2-,4677.055635066354 -Li3Sc2(BiO4)3,Bi5+,Sc3+,Li1+,O2-,4678.766562575405 -Li3Sc2(BiO4)3,Bi1+,Sc3+,Li1+,O1-,4678.766562575405 -Li3Ti2Tl3O12,Tl1+,Ti3+,Li1+,O1-,4689.27325244871 -Li3Ta3Nb2O12,Ta5+,Nb3+,Li1+,O2-,4699.29410555086 -Li3Mn2Nb3O12,Nb1+,Mn3+,Li1+,O1-,4712.182272413594 -Li3Mn2Nb3O12,Nb1-,Mn6+,Li1+,O1-,4712.182272413594 -Li3Mn2Nb3O12,Nb5+,Mn3+,Li1+,O2-,4712.182272413594 -Li3Mn2Nb3O12,Nb3+,Mn6+,Li1+,O2-,4712.182272413594 -Li3Nb3(SbO6)2,Nb1+,Sb3+,Li1+,O1-,4712.776206905023 -Li3Nb3(SbO6)2,Nb5+,Sb3-,Li1+,O1-,4712.776206905023 -Li3Nb3(SbO6)2,Nb5+,Sb3+,Li1+,O2-,4712.776206905023 -Li3Lu3(OsO6)2,Lu3+,Os6+,Li1+,O2-,4715.562064961463 -Li3Bi3(IO6)2,Bi5+,I3+,Li1+,O2-,4721.60198405594 -Li3Bi3(IO6)2,Bi1+,I3+,Li1+,O1-,4721.60198405594 -Li3Yb3(OsO6)2,Yb3+,Os6+,Li1+,O2-,4723.957965321337 -Li3Bi3(PO6)2,Bi5+,P3+,Li1+,O2-,4725.530879558944 -Li3Bi3(PO6)2,Bi5+,P3-,Li1+,O1-,4725.530879558944 -Li3Bi3(PO6)2,Bi1+,P3+,Li1+,O1-,4725.530879558944 -K3Li3(BiO6)2,K1+,Bi3+,Li1+,O1-,4726.474782156519 -Li3Ta2(BiO4)3,Bi5+,Ta3+,Li1+,O2-,4728.653765169232 -Li3Ta2(BiO4)3,Bi1+,Ta3+,Li1+,O1-,4728.653765169232 -Li3Lu3(IrO6)2,Lu3+,Ir6+,Li1+,O2-,4731.089172685169 -Li3Yb3(IrO6)2,Yb3+,Ir6+,Li1+,O2-,4739.535591163431 -Li3Tm3(OsO6)2,Tm3+,Os6+,Li1+,O2-,4742.141115338475 -Li3Bi3(TeO6)2,Bi3+,Te6+,Li1+,O2-,4745.008434121159 -Li3Er3(OsO6)2,Er3+,Os6+,Li1+,O2-,4749.677549794859 -Li3Ti2Nb3O12,Nb1+,Ti3+,Li1+,O1-,4749.707743780899 -Li3Ti2Nb3O12,Nb5+,Ti3+,Li1+,O2-,4749.707743780899 -Li3Lu3(PtO6)2,Lu3+,Pt6+,Li1+,O2-,4753.300071071088 -Li3Tl3(CoO6)2,Tl1+,Co3+,Li1+,O1-,4754.200085525807 -Li3Tl3(SO6)2,Tl1+,S3+,Li1+,O1-,4755.732838614993 -Li3Tl3(SO6)2,Tl3+,S6+,Li1+,O2-,4755.732838614993 -Li3Tm3(IrO6)2,Tm3+,Ir6+,Li1+,O2-,4757.827083447478 -Li3Ho3(OsO6)2,Ho3+,Os6+,Li1+,O2-,4760.269467288937 -Li3Yb3(PtO6)2,Yb3+,Pt6+,Li1+,O2-,4761.81775696687 -Li3Er3(IrO6)2,Er3+,Ir6+,Li1+,O2-,4765.407995510211 -Li3Tl3(ClO6)2,Tl1+,Cl3+,Li1+,O1-,4766.88733739731 -Li3Tl3(ClO6)2,Tl3+,Cl6+,Li1+,O2-,4766.88733739731 -Rb3Li3(BiO6)2,Rb1+,Bi3+,Li1+,O1-,4767.508510110688 -Cs3Li3(BrO6)2,Cs1+,Br3+,Li1+,O1-,4768.877008434477 -Li3Dy3(OsO6)2,Dy3+,Os6+,Li1+,O2-,4771.469716475887 -Li3Ho3(IrO6)2,Ho3+,Ir6+,Li1+,O2-,4776.0619997370795 -Li3Tm3(PtO6)2,Tm3+,Pt6+,Li1+,O2-,4780.262048257339 -Li3Dy3(IrO6)2,Dy3+,Ir6+,Li1+,O2-,4787.327363415969 -Li3Er3(PtO6)2,Er3+,Pt6+,Li1+,O2-,4787.9056715263605 -Li3Tb3(OsO6)2,Tb3+,Os6+,Li1+,O2-,4788.221014710642 -Li3Tb3(OsO6)2,Tb1+,Os3+,Li1+,O1-,4788.221014710642 -Li3Tl3(SiO6)2,Tl1+,Si3+,Li1+,O1-,4789.618604463458 -Li3Gd3(OsO6)2,Gd1+,Os3+,Li1+,O1-,4796.188036008141 -Li3Gd3(OsO6)2,Gd3+,Os6+,Li1+,O2-,4796.188036008141 -Li3Ho3(PtO6)2,Ho3+,Pt6+,Li1+,O2-,4798.647197900596 -Li3Al2Tl3O12,Tl1+,Al3+,Li1+,O1-,4799.127539205567 -Li3Tb3(IrO6)2,Tb3+,Ir6+,Li1+,O2-,4804.175015899292 -Li3Tb3(IrO6)2,Tb1+,Ir3+,Li1+,O1-,4804.175015899292 -Li3Bi3(MoO6)2,Bi5+,Mo3+,Li1+,O2-,4809.893596294046 -Li3Bi3(MoO6)2,Bi3+,Mo6+,Li1+,O2-,4809.893596294046 -Li3Bi3(MoO6)2,Bi1+,Mo3+,Li1+,O1-,4809.893596294046 -Li3Dy3(PtO6)2,Dy3+,Pt6+,Li1+,O2-,4810.004330188124 -Li3Gd3(IrO6)2,Gd1+,Ir3+,Li1+,O1-,4812.187429782494 -Li3Gd3(IrO6)2,Gd3+,Ir6+,Li1+,O2-,4812.187429782494 -Li3Tl3(WO6)2,Tl3+,W6+,Li1+,O2-,4817.134054099973 -Li3Tl3(WO6)2,Tl1+,W3+,Li1+,O1-,4817.134054099973 -Li3Tl3(WO6)2,Tl1-,W6+,Li1+,O1-,4817.134054099973 -Li3Eu3(OsO6)2,Eu3+,Os6+,Li1+,O2-,4821.825641236797 -Li3Tb3(PtO6)2,Tb1+,Pt3+,Li1+,O1-,4826.987737134326 -Li3Tb3(PtO6)2,Tb3+,Pt6+,Li1+,O2-,4826.987737134326 -Li3Sm3(OsO6)2,Sm3+,Os6+,Li1+,O2-,4829.759168283453 -Li3Gd3(PtO6)2,Gd1+,Pt3+,Li1+,O1-,4835.06408749776 -Li3Gd3(PtO6)2,Gd3+,Pt6+,Li1+,O2-,4835.06408749776 -Li3Eu3(IrO6)2,Eu3+,Ir6+,Li1+,O2-,4837.969207945218 -Li3Sm3(IrO6)2,Sm3+,Ir6+,Li1+,O2-,4845.9467621735075 -Li3Nb3(CoO6)2,Nb5+,Co3+,Li1+,O2-,4848.070622031626 -Li3Nb3(CoO6)2,Nb1+,Co3+,Li1+,O1-,4848.070622031626 -Li3Nb3(SO6)2,Nb1+,S3+,Li1+,O1-,4859.6037604963885 -Li3Nb3(SO6)2,Nb5+,S3+,Li1+,O2-,4859.6037604963885 -Li3Nb3(SO6)2,Nb3+,S6+,Li1+,O2-,4859.6037604963885 -Li3Nd3(OsO6)2,Nd3+,Os6+,Li1+,O2-,4860.702583562719 -Li3Eu3(PtO6)2,Eu3+,Pt6+,Li1+,O2-,4861.048859554633 -Li3Tl3V2O12,Tl1+,V3+,Li1+,O1-,4866.450262849968 -Li3Sm3(PtO6)2,Sm3+,Pt6+,Li1+,O2-,4869.088379659753 -Li3Nb3(ClO6)2,Nb5+,Cl3+,Li1+,O2-,4876.139407632738 -Li3Nb3(ClO6)2,Nb1+,Cl3+,Li1+,O1-,4876.139407632738 -Li3Nb3(ClO6)2,Nb3+,Cl6+,Li1+,O2-,4876.139407632738 -Li3Nd3(IrO6)2,Nd3+,Ir6+,Li1+,O2-,4877.059247411444 -Li3Pr3(OsO6)2,Pr3+,Os6+,Li1+,O2-,4878.037640302215 -Li3Ce3(OsO6)2,Ce3+,Os6+,Li1+,O2-,4882.203634129349 -Li3Tl3(AsO6)2,Tl1+,As3+,Li1+,O1-,4886.510207070258 -Li3La3(OsO6)2,La3+,Os6+,Li1+,O2-,4888.611834936826 -Li3Pr3(IrO6)2,Pr3+,Ir6+,Li1+,O2-,4894.487176250542 -Li3Tl3(NO6)2,Tl1+,N3+,Li1+,O1-,4898.169112101221 -Li3Ce3(IrO6)2,Ce3+,Ir6+,Li1+,O2-,4898.675291947369 -Li3Nd3(PtO6)2,Nd3+,Pt6+,Li1+,O2-,4900.438713624221 -Li3La3(IrO6)2,La3+,Ir6+,Li1+,O2-,4905.117371712022 -Li3Nb3(WO6)2,Nb1+,W3+,Li1+,O1-,4908.207755326042 -Li3Nb3(WO6)2,Nb3+,W6+,Li1+,O2-,4908.207755326042 -Li3Nb3(WO6)2,Nb5+,W3+,Li1+,O2-,4908.207755326042 -Li3Nb3(SiO6)2,Nb5+,Si3+,Li1+,O2-,4915.689670993891 -Li3Nb3(SiO6)2,Nb5+,Si3-,Li1+,O1-,4915.689670993891 -Li3Nb3(SiO6)2,Nb1+,Si3+,Li1+,O1-,4915.689670993891 -Li3Pr3(PtO6)2,Pr3+,Pt6+,Li1+,O2-,4917.9972199656495 -Li3Tl3(CO6)2,Tl1+,C3+,Li1+,O1-,4918.825297466279 -Li3Ce3(PtO6)2,Ce3+,Pt6+,Li1+,O2-,4922.2164306826 -Li3La3(PtO6)2,La3+,Pt6+,Li1+,O2-,4928.70612530324 -Li3Nb3Al2O12,Nb5+,Al3+,Li1+,O2-,4931.538565453104 -Li3Nb3Al2O12,Nb1+,Al3+,Li1+,O1-,4931.538565453104 -Cs3Li3(BiO6)2,Cs1+,Bi3+,Li1+,O1-,4937.883164769672 -Li3Tl3Cr2O12,Tl1+,Cr3+,Li1+,O1-,4941.401508605926 -Li3Tl3Cr2O12,Tl3+,Cr6+,Li1+,O2-,4941.401508605926 -Li3Tl3Cr2O12,Tl1-,Cr6+,Li1+,O1-,4941.401508605926 -Li3Tl3(BO6)2,Tl1+,B3+,Li1+,O1-,4969.59942906203 -K3Li3(RuO6)2,K1+,Ru3+,Li1+,O1-,4969.643590886775 -Li3Ta2Tl3O12,Tl1+,Ta3+,Li1+,O1-,4971.983010544008 -Rb3Li3(RuO6)2,Rb1+,Ru3+,Li1+,O1-,4973.482749621962 -K3Li3Tl2O12,K1+,Tl3+,Li1+,O1-,4987.241020938118 -Rb3Li3Tl2O12,Rb1+,Tl3+,Li1+,O1-,4987.388520406595 -Li3Tl3(IO6)2,Tl1+,I3+,Li1+,O1-,4989.198729468216 -Rb3Li3(RhO6)2,Rb1+,Rh3+,Li1+,O1-,4989.941783345397 -K3Li3(RhO6)2,K1+,Rh3+,Li1+,O1-,4990.401172410075 -Li3Sc2Tl3O12,Tl1+,Sc3+,Li1+,O1-,4993.604972448258 -Li3Tl3(TeO6)2,Tl3+,Te6+,Li1+,O2-,5012.5594531902 -Li3Zr3(OsO6)2,Zr3+,Os6+,Li1+,O2-,5025.892216347975 -Li3Zr3(OsO6)2,Zr1+,Os3+,Li1+,O1-,5025.892216347975 -Li3Nb3V2O12,Nb1+,V3+,Li1+,O1-,5026.109645421236 -Li3Nb3V2O12,Nb5+,V3+,Li1+,O2-,5026.109645421236 -Li3Zr3(IrO6)2,Zr3+,Ir6+,Li1+,O2-,5044.482294506809 -Li3Zr3(IrO6)2,Zr1+,Ir3+,Li1+,O1-,5044.482294506809 -Li3Nb3(AsO6)2,Nb1+,As3+,Li1+,O1-,5044.690534666492 -Li3Nb3(AsO6)2,Nb5+,As3-,Li1+,O1-,5044.690534666492 -Li3Nb3(AsO6)2,Nb5+,As3+,Li1+,O2-,5044.690534666492 -Li3Y3(OsO6)2,Y1+,Os3+,Li1+,O1-,5045.5095146956655 -Li3Y3(OsO6)2,Y3+,Os6+,Li1+,O2-,5045.5095146956655 -Li3Bi3(BrO6)2,Bi5+,Br3+,Li1+,O2-,5049.972137879979 -Li3Bi3(BrO6)2,Bi1+,Br3+,Li1+,O1-,5049.972137879979 -Li3Tl3(PO6)2,Tl1+,P3+,Li1+,O1-,5051.011293869411 -Li3Y3(IrO6)2,Y3+,Ir6+,Li1+,O2-,5064.158998601048 -Li3Y3(IrO6)2,Y1+,Ir3+,Li1+,O1-,5064.158998601048 -Li3Zr3(PtO6)2,Zr1+,Pt3+,Li1+,O1-,5071.008484743956 -Li3Zr3(PtO6)2,Zr3+,Pt6+,Li1+,O2-,5071.008484743956 -Li3Zn3(OsO6)2,Zn1+,Os3+,Li1+,O1-,5089.874665422339 -Li3Y3(PtO6)2,Y1+,Pt3+,Li1+,O1-,5090.7675721096675 -Li3Y3(PtO6)2,Y3+,Pt6+,Li1+,O2-,5090.7675721096675 -Li3Tl3(MoO6)2,Tl3+,Mo6+,Li1+,O2-,5094.968078167448 -Li3Tl3(MoO6)2,Tl1+,Mo3+,Li1+,O1-,5094.968078167448 -Li3Fe3(OsO6)2,Fe5+,Os3+,Li1+,O2-,5100.069557372214 -Li3Fe3(OsO6)2,Fe3+,Os6+,Li1+,O2-,5100.069557372214 -Li3Fe3(OsO6)2,Fe1+,Os3+,Li1+,O1-,5100.069557372214 -Li3Nb3(NO6)2,Nb1+,N3+,Li1+,O1-,5100.94620261899 -Li3Nb3(NO6)2,Nb5+,N3-,Li1+,O1-,5100.94620261899 -Li3Nb3(NO6)2,Nb5+,N3+,Li1+,O2-,5100.94620261899 -Li3Zn3(IrO6)2,Zn1+,Ir3+,Li1+,O1-,5109.95872847196 -Li3Fe3(IrO6)2,Fe5+,Ir3+,Li1+,O2-,5120.854127854006 -Li3Fe3(IrO6)2,Fe1+,Ir3+,Li1+,O1-,5120.854127854006 -Li3Fe3(IrO6)2,Fe3+,Ir6+,Li1+,O2-,5120.854127854006 -Li3Ta2Nb3O12,Nb1+,Ta3+,Li1+,O1-,5124.354068818945 -Li3Ta2Nb3O12,Nb5+,Ta3+,Li1+,O2-,5124.354068818945 -Rb3Li3Nb2O12,Rb1+,Nb3+,Li1+,O1-,5124.979990289329 -Cs3Li3Tl2O12,Cs1+,Tl3+,Li1+,O1-,5128.629242137966 -Li3Bi5O12,Bi5+,Bi3+,Li1+,O2-,5130.614355620951 -Li3Bi5O12,Bi1+,Bi3+,Li1+,O1-,5130.614355620951 -Li3Nb3(CO6)2,Nb1+,C3+,Li1+,O1-,5136.571750819707 -Li3Nb3(CO6)2,Nb5+,C3-,Li1+,O1-,5136.571750819707 -Li3Nb3(CO6)2,Nb5+,C3+,Li1+,O2-,5136.571750819707 -Li3Zn3(PtO6)2,Zn1+,Pt3+,Li1+,O1-,5138.585589684224 -Li3Nb3Cr2O12,Nb1+,Cr3+,Li1+,O1-,5142.585864348685 -Li3Nb3Cr2O12,Nb3+,Cr6+,Li1+,O2-,5142.585864348685 -Li3Nb3Cr2O12,Nb5+,Cr3+,Li1+,O2-,5142.585864348685 -Li3Fe3(PtO6)2,Fe5+,Pt3+,Li1+,O2-,5150.465893888637 -Li3Fe3(PtO6)2,Fe3+,Pt6+,Li1+,O2-,5150.465893888637 -Li3Fe3(PtO6)2,Fe1+,Pt3+,Li1+,O1-,5150.465893888637 -Cs3Li3(RuO6)2,Cs1+,Ru3+,Li1+,O1-,5153.022755943865 -K3Li3Nb2O12,K1+,Nb3+,Li1+,O1-,5161.867552989353 -Cs3Li3(RhO6)2,Cs1+,Rh3+,Li1+,O1-,5165.809617117223 -Li3Nb3(IO6)2,Nb5+,I3+,Li1+,O2-,5171.39061234393 -Li3Nb3(IO6)2,Nb1+,I3+,Li1+,O1-,5171.39061234393 -Sr3Li3(OsO6)2,Sr1+,Os3+,Li1+,O1-,5179.34070739712 -Sr3Li3(IrO6)2,Sr1+,Ir3+,Li1+,O1-,5197.455487659831 -Li3Mn3(OsO6)2,Mn5+,Os3+,Li1+,O2-,5200.312338931132 -Li3Mn3(OsO6)2,Mn1+,Os3+,Li1+,O1-,5200.312338931132 -Li3Mn3(OsO6)2,Mn3+,Os6+,Li1+,O2-,5200.312338931132 -Li3Nb3(TeO6)2,Nb3+,Te6+,Li1+,O2-,5204.874211457147 -Li3Mn3(IrO6)2,Mn5+,Ir3+,Li1+,O2-,5220.648373813937 -Li3Mn3(IrO6)2,Mn1+,Ir3+,Li1+,O1-,5220.648373813937 -Li3Mn3(IrO6)2,Mn3+,Ir6+,Li1+,O2-,5220.648373813937 -Li3Nb3(BO6)2,Nb5+,B3+,Li1+,O2-,5221.454146172125 -Li3Nb3(BO6)2,Nb1+,B3+,Li1+,O1-,5221.454146172125 -Sr3Li3(PtO6)2,Sr1+,Pt3+,Li1+,O1-,5223.299860783204 -Li3Sc2Nb3O12,Nb5+,Sc3+,Li1+,O2-,5229.687098232779 -Li3Sc2Nb3O12,Nb1+,Sc3+,Li1+,O1-,5229.687098232779 -Li3Mn3(PtO6)2,Mn1+,Pt3+,Li1+,O1-,5249.6198013348385 -Li3Mn3(PtO6)2,Mn3+,Pt6+,Li1+,O2-,5249.6198013348385 -Li3Mn3(PtO6)2,Mn5+,Pt3+,Li1+,O2-,5249.6198013348385 -Li3Ti3(OsO6)2,Ti3+,Os6+,Li1+,O2-,5259.224608509862 -Li3Ti3(OsO6)2,Ti1+,Os3+,Li1+,O1-,5259.224608509862 -Li3Ti3(IrO6)2,Ti1+,Ir3+,Li1+,O1-,5279.826923315734 -Li3Ti3(IrO6)2,Ti3+,Ir6+,Li1+,O2-,5279.826923315734 -Cs3Li3Nb2O12,Cs1+,Nb3+,Li1+,O1-,5281.156672960272 -Li3Tl2(BiO4)3,Bi1+,Tl3+,Li1+,O1-,5287.912138785362 -Li3Tl2(BiO4)3,Bi5+,Tl3+,Li1+,O2-,5287.912138785362 -Li3Ti3(PtO6)2,Ti1+,Pt3+,Li1+,O1-,5309.167022955732 -Li3Ti3(PtO6)2,Ti3+,Pt6+,Li1+,O2-,5309.167022955732 -Li3Nb3(PO6)2,Nb1+,P3+,Li1+,O1-,5333.707924665162 -Li3Nb3(PO6)2,Nb5+,P3-,Li1+,O1-,5333.707924665162 -Li3Nb3(PO6)2,Nb5+,P3+,Li1+,O2-,5333.707924665162 -Li3Bi3(RuO6)2,Bi1+,Ru3+,Li1+,O1-,5338.5509316180005 -Li3Bi3(RuO6)2,Bi3+,Ru6+,Li1+,O2-,5338.5509316180005 -Li3Bi3(RuO6)2,Bi5+,Ru3+,Li1+,O2-,5338.5509316180005 -Li3Nb3(MoO6)2,Nb3+,Mo6+,Li1+,O2-,5345.428111360867 -Li3Nb3(MoO6)2,Nb1+,Mo3+,Li1+,O1-,5345.428111360867 -Li3Nb3(MoO6)2,Nb5+,Mo3+,Li1+,O2-,5345.428111360867 -Li3Tl3(BrO6)2,Tl1+,Br3+,Li1+,O1-,5347.680253591671 -Li3Bi3(RhO6)2,Bi1+,Rh3+,Li1+,O1-,5347.8953066658505 -Li3Bi3(RhO6)2,Bi5+,Rh3+,Li1+,O2-,5347.8953066658505 -Li3Bi3(RhO6)2,Bi3+,Rh6+,Li1+,O2-,5347.8953066658505 -Li3Co3(OsO6)2,Co1+,Os3+,Li1+,O1-,5354.018528328885 -Li3Co3(OsO6)2,Co5+,Os3+,Li1+,O2-,5354.018528328885 -Li3Co3(OsO6)2,Co3+,Os6+,Li1+,O2-,5354.018528328885 -Li3Ca3(OsO6)2,Ca1+,Os3+,Li1+,O1-,5362.210862415624 -Li3Bi3(PdO6)2,Bi3+,Pd6+,Li1+,O2-,5365.605450139037 -Li3Tl3(BiO6)2,Tl1+,Bi3+,Li1+,O1-,5367.433003477295 -Li3Co3(IrO6)2,Co5+,Ir3+,Li1+,O2-,5373.25054460188 -Li3Co3(IrO6)2,Co1+,Ir3+,Li1+,O1-,5373.25054460188 -Li3Co3(IrO6)2,Co3+,Ir6+,Li1+,O2-,5373.25054460188 -Li3Ca3(IrO6)2,Ca1+,Ir3+,Li1+,O1-,5382.913732686368 -Li3Co3(PtO6)2,Co1+,Pt3+,Li1+,O1-,5400.654541389081 -Li3Co3(PtO6)2,Co5+,Pt3+,Li1+,O2-,5400.654541389081 -Li3Co3(PtO6)2,Co3+,Pt6+,Li1+,O2-,5400.654541389081 -Li3Ca3(PtO6)2,Ca1+,Pt3+,Li1+,O1-,5412.384485005762 -Li3Nb2(BiO4)3,Bi1+,Nb3+,Li1+,O1-,5441.124246877171 -Li3Nb2(BiO4)3,Bi5+,Nb3+,Li1+,O2-,5441.124246877171 -Li3Ta3(OsO6)2,Ta5+,Os3+,Li1+,O2-,5502.316263508352 -Li3Ta3(OsO6)2,Ta3+,Os6+,Li1+,O2-,5502.316263508352 -Li3Ta3(IrO6)2,Ta3+,Ir6+,Li1+,O2-,5514.856634908801 -Li3Ta3(IrO6)2,Ta5+,Ir3+,Li1+,O2-,5514.856634908801 -Li3Mg3(OsO6)2,Mg1+,Os3+,Li1+,O1-,5527.089986832601 -Li3Tl5O12,Tl1+,Tl3+,Li1+,O1-,5528.251143992912 -Li3Ta3(PtO6)2,Ta3+,Pt6+,Li1+,O2-,5532.797566795923 -Li3Ta3(PtO6)2,Ta5+,Pt3+,Li1+,O2-,5532.797566795923 -Li3Mg3(IrO6)2,Mg1+,Ir3+,Li1+,O1-,5548.276931286155 -Na3Li3(OsO6)2,Na1+,Os3+,Li1+,O1-,5557.041660788119 -Na3Li3(IrO6)2,Na1+,Ir3+,Li1+,O1-,5578.175423351125 -Li3Mg3(PtO6)2,Mg1+,Pt3+,Li1+,O1-,5578.408039783471 -Li3V3(OsO6)2,V5+,Os3+,Li1+,O2-,5582.6841243730905 -Li3V3(OsO6)2,V1+,Os3+,Li1+,O1-,5582.6841243730905 -Li3V3(OsO6)2,V3+,Os6+,Li1+,O2-,5582.6841243730905 -Li3V3(IrO6)2,V1+,Ir3+,Li1+,O1-,5601.319362628476 -Li3V3(IrO6)2,V3+,Ir6+,Li1+,O2-,5601.319362628476 -Li3V3(IrO6)2,V5+,Ir3+,Li1+,O2-,5601.319362628476 -Na3Li3(PtO6)2,Na1+,Pt3+,Li1+,O1-,5608.228327172669 -Li3V3(PtO6)2,V1+,Pt3+,Li1+,O1-,5627.862382564468 -Li3V3(PtO6)2,V3+,Pt6+,Li1+,O2-,5627.862382564468 -Li3V3(PtO6)2,V5+,Pt3+,Li1+,O2-,5627.862382564468 -Li3Tl3(RuO6)2,Tl3+,Ru6+,Li1+,O2-,5627.872066072583 -Li3Tl3(RuO6)2,Tl1+,Ru3+,Li1+,O1-,5627.872066072583 -Li3Tl3(RhO6)2,Tl1+,Rh3+,Li1+,O1-,5636.311955871847 -Li3Tl3(RhO6)2,Tl3+,Rh6+,Li1+,O2-,5636.311955871847 -Li3Tl3(PdO6)2,Tl3+,Pd6+,Li1+,O2-,5652.305671792137 -Li3Nb3(BiO6)2,Nb5+,Bi3+,Li1+,O2-,5655.82223837574 -Li3Nb3(BiO6)2,Nb1+,Bi3+,Li1+,O1-,5655.82223837574 -Li3Nb3(BiO6)2,Nb5+,Bi3-,Li1+,O1-,5655.82223837574 -Li3Cr3(OsO6)2,Cr1+,Os3+,Li1+,O1-,5719.199718764051 -Li3Cr3(OsO6)2,Cr3+,Os6+,Li1+,O2-,5719.199718764051 -Li3Cr3(OsO6)2,Cr5+,Os3+,Li1+,O2-,5719.199718764051 -Li3Os2O15,O1-,Os6+,Li1+,O1-,5722.418342237484 -Li3Nb2Tl3O12,Tl1+,Nb3+,Li1+,O1-,5736.5123566674865 -Li3Cr3(IrO6)2,Cr3+,Ir6+,Li1+,O2-,5737.03644305831 -Li3Cr3(IrO6)2,Cr1+,Ir3+,Li1+,O1-,5737.03644305831 -Li3Cr3(IrO6)2,Cr5+,Ir3+,Li1+,O2-,5737.03644305831 -Li3Nb3(BrO6)2,Nb1+,Br3+,Li1+,O1-,5740.227462970582 -Li3Nb3(BrO6)2,Nb5+,Br3+,Li1+,O2-,5740.227462970582 -Li3Ir2O15,O1-,Ir6+,Li1+,O1-,5743.2204361733775 -Li3Cr3(PtO6)2,Cr5+,Pt3+,Li1+,O2-,5762.443481124011 -Li3Cr3(PtO6)2,Cr1+,Pt3+,Li1+,O1-,5762.443481124011 -Li3Cr3(PtO6)2,Cr3+,Pt6+,Li1+,O2-,5762.443481124011 -Li3Pt2O15,O1-,Pt6+,Li1+,O1-,5772.78772684959 -Li3Sc3(OsO6)2,Sc1+,Os3+,Li1+,O1-,5840.254842281536 -Li3Sc3(OsO6)2,Sc3+,Os6+,Li1+,O2-,5840.254842281536 -Li3Sc3(IrO6)2,Sc1+,Ir3+,Li1+,O1-,5857.9490329268665 -Li3Sc3(IrO6)2,Sc3+,Ir6+,Li1+,O2-,5857.9490329268665 -Li3Nb3Tl2O12,Nb5+,Tl3+,Li1+,O2-,5879.323867423353 -Li3Nb3Tl2O12,Nb1+,Tl3+,Li1+,O1-,5879.323867423353 -Li3Sc3(PtO6)2,Sc1+,Pt3+,Li1+,O1-,5883.143695183688 -Li3Sc3(PtO6)2,Sc3+,Pt6+,Li1+,O2-,5883.143695183688 -Li3Bi3(OsO6)2,Bi5+,Os3+,Li1+,O2-,6070.466318695773 -Li3Bi3(OsO6)2,Bi1+,Os3+,Li1+,O1-,6070.466318695773 -Li3Bi3(OsO6)2,Bi3+,Os6+,Li1+,O2-,6070.466318695773 -Li3OsO6,Li1+,Os3+,Li1+,O1-,6078.982079105186 -Li3Bi3(IrO6)2,Bi5+,Ir3+,Li1+,O2-,6080.300868083494 -Li3Bi3(IrO6)2,Bi3+,Ir6+,Li1+,O2-,6080.300868083494 -Li3Bi3(IrO6)2,Bi1+,Ir3+,Li1+,O1-,6080.300868083494 -Cs3Li3(OsO6)2,Cs1+,Os3+,Li1+,O1-,6086.678306381692 -Li3Bi3(PtO6)2,Bi5+,Pt3+,Li1+,O2-,6094.37892554424 -Li3Bi3(PtO6)2,Bi3+,Pt6+,Li1+,O2-,6094.37892554424 -Li3Bi3(PtO6)2,Bi1+,Pt3+,Li1+,O1-,6094.37892554424 -Li3IrO6,Li1+,Ir3+,Li1+,O1-,6098.40620716524 -Cs3Li3(IrO6)2,Cs1+,Ir3+,Li1+,O1-,6098.701747481478 -Rb3Li3(OsO6)2,Rb1+,Os3+,Li1+,O1-,6101.196074942166 -Rb3Li3(IrO6)2,Rb1+,Ir3+,Li1+,O1-,6115.156365606079 -Cs3Li3(PtO6)2,Cs1+,Pt3+,Li1+,O1-,6115.881982586778 -Li3PtO6,Li1+,Pt3+,Li1+,O1-,6125.996702825297 -Li3Nb3(RuO6)2,Nb3+,Ru6+,Li1+,O2-,6131.548347414714 -Li3Nb3(RuO6)2,Nb5+,Ru3+,Li1+,O2-,6131.548347414714 -Li3Nb3(RuO6)2,Nb1+,Ru3+,Li1+,O1-,6131.548347414714 -Rb3Li3(PtO6)2,Rb1+,Pt3+,Li1+,O1-,6135.07182792576 -Li3Nb3(RhO6)2,Nb5+,Rh3+,Li1+,O2-,6141.384335011688 -Li3Nb3(RhO6)2,Nb1+,Rh3+,Li1+,O1-,6141.384335011688 -Li3Nb3(RhO6)2,Nb3+,Rh6+,Li1+,O2-,6141.384335011688 -Li3Nb3(PdO6)2,Nb3+,Pd6+,Li1+,O2-,6159.931572806949 -Li3Nb5O12,Nb5+,Nb3+,Li1+,O2-,6305.969179492305 -Li3Nb5O12,Nb1+,Nb3+,Li1+,O1-,6305.969179492305 -K3Li3(OsO6)2,K1+,Os3+,Li1+,O1-,6319.092920662223 -Li3Tl3(OsO6)2,Tl1+,Os3+,Li1+,O1-,6325.390241603773 -Li3Tl3(OsO6)2,Tl3+,Os6+,Li1+,O2-,6325.390241603773 -Li3Tl3(IrO6)2,Tl3+,Ir6+,Li1+,O2-,6334.499876363155 -Li3Tl3(IrO6)2,Tl1+,Ir3+,Li1+,O1-,6334.499876363155 -K3Li3(IrO6)2,K1+,Ir3+,Li1+,O1-,6334.559167537035 -Li3Tl3(PtO6)2,Tl1+,Pt3+,Li1+,O1-,6347.539049366037 -Li3Tl3(PtO6)2,Tl3+,Pt6+,Li1+,O2-,6347.539049366037 -K3Li3(PtO6)2,K1+,Pt3+,Li1+,O1-,6356.5743093610845 -Li3Nb3(OsO6)2,Nb1+,Os3+,Li1+,O1-,6993.581215046959 -Li3Nb3(OsO6)2,Nb3+,Os6+,Li1+,O2-,6993.581215046959 -Li3Nb3(OsO6)2,Nb5+,Os3+,Li1+,O2-,6993.581215046959 -Li3Nb3(IrO6)2,Nb3+,Ir6+,Li1+,O2-,7003.137385213681 -Li3Nb3(IrO6)2,Nb5+,Ir3+,Li1+,O2-,7003.137385213681 -Li3Nb3(IrO6)2,Nb1+,Ir3+,Li1+,O1-,7003.137385213681 -Li3Nb3(PtO6)2,Nb1+,Pt3+,Li1+,O1-,7016.773962441364 -Li3Nb3(PtO6)2,Nb3+,Pt6+,Li1+,O2-,7016.773962441364 -Li3Nb3(PtO6)2,Nb5+,Pt3+,Li1+,O2-,7016.773962441364 diff --git a/examples/Structure_Prediction/Li-Garnet_Generator.ipynb b/examples/Structure_Prediction/Li-Garnet_Generator.ipynb deleted file mode 100644 index 9d2a4b30..00000000 --- a/examples/Structure_Prediction/Li-Garnet_Generator.ipynb +++ /dev/null @@ -1,556 +0,0 @@ -{ - "cells": [ - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Imports\n", - "from __future__ import annotations\n", - "\n", - "import itertools\n", - "import multiprocessing\n", - "from datetime import datetime\n", - "\n", - "import smact\n", - "from smact import (\n", - " element_dictionary,\n", - " neutral_ratios,\n", - " ordered_elements,\n", - ")\n", - "from smact.screening import pauling_test, smact_filter" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Generate the dictionary of elements\n", - "all_el = element_dictionary(elements=ordered_elements(1, 83)) # A dictionary of all element objects\n", - "symbols_list = list(all_el.keys())\n", - "all_els = [all_el[symbol] for symbol in symbols_list]\n", - "dont_want = [\"He\", \"Ne\", \"Ar\", \"Kr\", \"Xe\", \"Pm\", \"Tc\"]\n", - "\n", - "for unwanted in dont_want:\n", - " symbols_list.remove(unwanted)\n", - "all_els = [all_el[symbol] for symbol in symbols_list]\n", - "coord_els = [el.coord_envs for el in all_els]" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Elements for A\n", - "\n", - "# A requires elements which can take a coordination state of 8\n", - "A_els = []\n", - "B_els = []\n", - "\n", - "for el in all_els:\n", - " if el.coord_envs == None:\n", - " continue\n", - " CNs = [i.split(\"_\")[0] for i in el.coord_envs]\n", - " if \"8\" in CNs:\n", - " A_els.append(el)\n", - " if \"6\" in CNs:\n", - " B_els.append(el)" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Elements for C and D\n", - "C_list = [\"Li\"]\n", - "D_list = [\"O\"]\n", - "C_els = [all_el[symbol] for symbol in C_list]\n", - "D_els = [all_el[symbol] for symbol in D_list]" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "The number of allowed elements for (A) are: 45 \n", - "\n", - "The number of allowed elements for {B} are':75 \n", - "\n" - ] - } - ], - "source": [ - "print(f\"The number of allowed elements for (A) are: {len(A_els)} \\n\")\n", - "print(\"The number of allowed elements for {B} are':\" f\"{len(B_els)} \\n\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "We have generated 3375 potential compounds\n" - ] - } - ], - "source": [ - "# Generate the A-B-C-D combinations\n", - "\n", - "ABCD_pairs = [(x, y, z, a) for x in A_els for y in B_els for z in C_els for a in D_els]\n", - "\n", - "# Prove to ourselves that we have all unique chemical systems\n", - "print(f\"We have generated {len(ABCD_pairs)} potential compounds\")\n", - "\n", - "# for i in oxide_systems:\n", - "# print(f\"{i[0].symbol} {i[1].symbol} {i[2].symbol} {i[3].symbol}\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "def smact_filter(els, stoichs=[[3], [2], [3], [12]], species_unique=True):\n", - " \"\"\"Function that applies the charge neutrality and electronegativity\n", - " tests in one go for simple application in external scripts that\n", - " wish to apply the general 'smact test'.\n", - "\n", - " Args:\n", - " els (tuple/list): A list of smact.Element objects\n", - " threshold (int): Threshold for stoichiometry limit, default = 8\n", - " species_unique (bool): Whether or not to consider elements in different\n", - " oxidation states as unique in the results.\n", - "\n", - " Returns:\n", - " allowed_comps (list): Allowed compositions for that chemical system\n", - " in the form [(elements), (oxidation states), (ratios)] if species_unique=True\n", - " or in the form [(elements), (ratios)] if species_unique=False.\n", - " \"\"\"\n", - " compositions = []\n", - "\n", - " # Get symbols and electronegativities\n", - " symbols = tuple(e.symbol for e in els)\n", - " electronegs = [e.pauling_eneg for e in els]\n", - " ox_combos = [e.oxidation_states for e in els]\n", - " for ox_states in itertools.product(*ox_combos):\n", - " # Test for charge balance\n", - " cn_e, cn_r = neutral_ratios(ox_states, stoichs=stoichs)\n", - " # Electronegativity test\n", - " if cn_e:\n", - " electroneg_OK = pauling_test(ox_states, electronegs)\n", - " if electroneg_OK:\n", - " for ratio in cn_r:\n", - " compositions.append(tuple([symbols, ox_states, ratio]))\n", - "\n", - " # Return list depending on whether we are interested in unique species combinations\n", - " # or just unique element combinations.\n", - " if species_unique:\n", - " return compositions\n", - " else:\n", - " compositions = [(i[0], i[2]) for i in compositions]\n", - " compositions = list(set(compositions))\n", - " return compositions" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "Time taken to generate list: 0:00:00.175910\n" - ] - } - ], - "source": [ - "# Use multiprocessing and smact_filter to quickly generate our list of compositions\n", - "start = datetime.now()\n", - "if __name__ == \"__main__\": # Always use pool protected in an if statement\n", - " with multiprocessing.Pool(24) as p: # start 4 worker processes\n", - " result = p.map(smact_filter, ABCD_pairs)\n", - "print(f\"Time taken to generate list: {datetime.now() - start}\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "Number of compositions: --> 2504 <--\n", - "Each list entry looks like this:\n", - " elements, oxidation states, stoichiometries\n", - "(('Li', 'B', 'Li', 'O'), (1, 3, 1, -1), (3, 2, 3, 12))\n", - "(('Li', 'C', 'Li', 'O'), (1, 3, 1, -1), (3, 2, 3, 12))\n", - "(('Li', 'N', 'Li', 'O'), (1, 3, 1, -1), (3, 2, 3, 12))\n", - "(('Li', 'Al', 'Li', 'O'), (1, 3, 1, -1), (3, 2, 3, 12))\n", - "(('Li', 'Si', 'Li', 'O'), (1, 3, 1, -1), (3, 2, 3, 12))\n" - ] - } - ], - "source": [ - "# Flatten the list of lists\n", - "flat_list = [item for sublist in result for item in sublist]\n", - "print(f\"Number of compositions: --> {len(flat_list)} <--\")\n", - "print(\"Each list entry looks like this:\\n elements, oxidation states, stoichiometries\")\n", - "for i in flat_list[:5]:\n", - " print(i)" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "Each list entry now looks like this: \n", - "Li3BO6\n", - "Li3CO6\n", - "Li3NO6\n", - "Li3AlO6\n", - "Li3SiO6\n" - ] - } - ], - "source": [ - "from pymatgen import Composition\n", - "\n", - "\n", - "def comp_maker(comp):\n", - " form = []\n", - " for el, ammt in zip(comp[0], comp[2]):\n", - " form.append(el)\n", - " form.append(ammt)\n", - " form = \"\".join(str(e) for e in form)\n", - " pmg_form = Composition(form).reduced_formula\n", - " return pmg_form\n", - "\n", - "\n", - "if __name__ == \"__main__\":\n", - " with multiprocessing.Pool() as p:\n", - " pretty_formulas = p.map(comp_maker, flat_list)\n", - "\n", - "print(\"Each list entry now looks like this: \")\n", - "for i in pretty_formulas[:5]:\n", - " print(i)" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "Time taken to calculate sus factors: 0:00:01.067193\n" - ] - } - ], - "source": [ - "# Calculate sustainability\n", - "def sus_calc(comp):\n", - " sus_factor = 0\n", - " for i in Composition(comp).elements:\n", - " sus_factor += Composition(comp).get_wt_fraction(i) * smact.Element(i.symbol).HHI_r\n", - " return sus_factor\n", - "\n", - "\n", - "# Compute sustainability\n", - "start = datetime.now()\n", - "if __name__ == \"__main__\":\n", - " with multiprocessing.Pool() as p:\n", - " sus_factors = p.map(sus_calc, pretty_formulas)\n", - "# sus_factors=[sus_calc(Composition(i)) for i in pretty_formulas]\n", - "print(f\"Time taken to calculate sus factors: {datetime.now()-start}\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# We want to be able to feed in a list of species into a structure predictor\n", - "# Need to our list in the form of [(A,x), (B,y), (C,z)]\n", - "# Where A,B,C are species, dtype-string\n", - "# x,y,z are the charges/oxidation state - dtype: int\n", - "from smact.structure_prediction.utilities import unparse_spec\n", - "\n", - "species = []\n", - "A = []\n", - "B = []\n", - "C = []\n", - "D = []\n", - "for i in range(len(flat_list)):\n", - " species.append(pretty_formulas[i])\n", - " A.append(unparse_spec((flat_list[i][0][0], flat_list[i][1][0])))\n", - " B.append(unparse_spec((flat_list[i][0][1], flat_list[i][1][1])))\n", - " C.append(unparse_spec((flat_list[i][0][2], flat_list[i][1][2])))\n", - " D.append(unparse_spec((flat_list[i][0][3], flat_list[i][1][3])))" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/html": [ - "
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" - ], - "text/plain": [ - " Pretty Formula A B C D sus_factor\n", - "0 Li3Mg3(NO6)2 Mg1+ N3+ Li1+ O1- 745.566611\n", - "1 Na3Li3(NO6)2 Na1+ N3+ Li1+ O1- 748.694226\n", - "2 Li3Mg3(CO6)2 Mg1+ C3+ Li1+ O1- 748.731405\n", - "3 Na3Li3(CO6)2 Na1+ C3+ Li1+ O1- 751.940682\n", - "4 Li3Mg3Al2O12 Mg1+ Al3+ Li1+ O1- 806.236425" - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "import pandas as pd\n", - "\n", - "columns = [\"Pretty Formula\", \"A\", \"B\", \"C\", \"D\"]\n", - "df_list = [[species[i], A[i], B[i], C[i], D[i]] for i in range(len(species))]\n", - "df = pd.DataFrame(data=df_list, columns=columns)\n", - "df[\"sus_factor\"] = sus_factors\n", - "df = df.sort_values(by=\"sus_factor\", ascending=True)\n", - "df = df.reset_index(drop=True)\n", - "\n", - "df.head()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/html": [ - "
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Pretty FormulaABCDsus_factor
0Li3Mg3(NO6)2Mg1+N3+Li1+O1-745.566611
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4Li3Mg3Al2O12Mg1+Al3+Li1+O1-806.236425
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" - ], - "text/plain": [ - " Pretty Formula A B C D sus_factor\n", - "0 Li3Mg3(NO6)2 Mg1+ N3+ Li1+ O1- 745.566611\n", - "1 Na3Li3(NO6)2 Na1+ N3+ Li1+ O1- 748.694226\n", - "2 Li3Mg3(CO6)2 Mg1+ C3+ Li1+ O1- 748.731405\n", - "3 Na3Li3(CO6)2 Na1+ C3+ Li1+ O1- 751.940682\n", - "4 Li3Mg3Al2O12 Mg1+ Al3+ Li1+ O1- 806.236425" - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "df.to_csv(\"./Li-Garnet_Comps_sus.csv\", index=False)\n", - "df.head()" - ] - } - ], - "metadata": { - "kernelspec": { - "display_name": "Python 3", - "language": "python", - "name": "python3" - }, - "language_info": { - "codemirror_mode": { - "name": "ipython", - "version": 3 - }, - "file_extension": ".py", - "mimetype": "text/x-python", - "name": "python", - "nbconvert_exporter": "python", - "pygments_lexer": "ipython3", - "version": "3.8.10" - } - }, - "nbformat": 4, - "nbformat_minor": 4 -} diff --git a/examples/Structure_Prediction/Li-Garnets_SP-Pym-new.ipynb b/examples/Structure_Prediction/Li-Garnets_SP-Pym-new.ipynb deleted file mode 100644 index f5f09f64..00000000 --- a/examples/Structure_Prediction/Li-Garnets_SP-Pym-new.ipynb +++ /dev/null @@ -1,1280 +0,0 @@ -{ - "cells": [ - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "from __future__ import annotations\n", - "\n", - "import os\n", - "from datetime import datetime\n", - "from operator import itemgetter\n", - "\n", - "import pandas as pd\n", - "\n", - "from smact.structure_prediction.database import StructureDB\n", - "from smact.structure_prediction.mutation import CationMutator\n", - "from smact.structure_prediction.prediction import StructurePredictor\n", - "from smact.structure_prediction.structure import SmactStructure\n", - "from smact.structure_prediction.utilities import parse_spec" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "# Structure Prediction\n", - "\n", - "In this notebook, we aim to do a test of the structure substitution algorithm implemented in SMACT\n", - "\n", - "Before we can do predictions, we need to create our cation mutator, database and a table, and a list of hypothetical compositions\n", - "\n", - "## Procedure\n", - "* Create a list of hypothetical compositions\n", - "* Create a database of structures\n", - "* Create Cation Mutator\n", - "* Predict structures" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Part 1: Compositions\n", - "These compositions have generated in a different notebook and the results have been loaded in" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/html": [ - "
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Pretty FormulaABCDsus_factor
0Li3Mg3(NO6)2Mg1+N3+Li1+O1-745.566611
1Na3Li3(NO6)2Na1+N3+Li1+O1-748.694226
2Li3Mg3(CO6)2Mg1+C3+Li1+O1-748.731405
3Na3Li3(CO6)2Na1+C3+Li1+O1-751.940682
4Li3Mg3Al2O12Mg1+Al3+Li1+O1-806.236425
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" - ], - "text/plain": [ - " Pretty Formula A B C D sus_factor\n", - "0 Li3Mg3(NO6)2 Mg1+ N3+ Li1+ O1- 745.566611\n", - "1 Na3Li3(NO6)2 Na1+ N3+ Li1+ O1- 748.694226\n", - "2 Li3Mg3(CO6)2 Mg1+ C3+ Li1+ O1- 748.731405\n", - "3 Na3Li3(CO6)2 Na1+ C3+ Li1+ O1- 751.940682\n", - "4 Li3Mg3Al2O12 Mg1+ Al3+ Li1+ O1- 806.236425" - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "comps = pd.read_csv(\"Li-Garnet_Comps_sus.csv\")\n", - "comps.head()" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Part 2: Database\n", - "\n", - "\n", - "Let's follow this procedure\n", - "1. Create a SMACT database and add a table which contains the result of our query\n", - "\n" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "DB = StructureDB(\"Test.db\")\n", - "SP = StructurePredictor(CM, DB, \"Garnets\")" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Part 3: Cation Mutator\n", - "\n", - "In order to set up the cation mutator, we must do the following:\n", - "1. Generate a dataframe of lambda values for all species we which to consider\n", - "2. Instantiate the CationMutator class with the lambda dataframe\n", - "\n" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Create the CationMutator class\n", - "\n", - "# Here we use the default lambda table\n", - "CM = CationMutator.from_json()" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Part 4: Structure Prediction\n", - "\n", - "#### Prerequisites: Part 1, Part 2 & Part 3\n", - "\n", - "Procedure:\n", - "1. Instantiate the StructurePredictor class with the cation mutator (part 1), database (part 2) and table (part 2)\n", - "2. Predict Structures\n", - "3. Compare predicted structures with Database" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Corrections\n", - "cond_df = CM.complete_cond_probs()\n", - "species = list(cond_df.columns)\n", - "\n", - "comps_copy = comps[[\"A\", \"B\", \"C\", \"D\"]]\n", - "\n", - "df_copy_bool = comps_copy.isin(species)" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/html": [ - "
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ABCD
0Fe5+Au3+Li1+O2-
1Fe5+N3+Li1+O2-
2Fe5+C3+Li1+O2-
3Fe3+S6+Li1+O2-
4Fe5+Al3+Li1+O2-
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" - ], - "text/plain": [ - " A B C D\n", - "0 Fe5+ Au3+ Li1+ O2-\n", - "1 Fe5+ N3+ Li1+ O2-\n", - "2 Fe5+ C3+ Li1+ O2-\n", - "3 Fe3+ S6+ Li1+ O2-\n", - "4 Fe5+ Al3+ Li1+ O2-" - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "x = comps_copy[df_copy_bool].fillna(0)\n", - "x = x[x.A != 0]\n", - "x = x[x.B != 0]\n", - "x = x[x.C != 0]\n", - "x = x[x.D != 0]\n", - "x = x.reset_index(drop=True)\n", - "\n", - "# x.to_csv(\"./Garnet_Comps_Corrected_Pym.csv\", index=False)\n", - "x.head()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/html": [ - "
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ABCDPretty Formulasus_factor
0Fe5+Au3+Li1+O2-Li3Fe3(AuO6)21048.627123
1Fe5+N3+Li1+O2-Li3Fe3(NO6)21057.900521
2Fe5+C3+Li1+O2-Li3Fe3(CO6)21063.408167
3Fe3+S6+Li1+O2-Li3Fe3(SO6)21084.708271
4Fe5+Al3+Li1+O2-Li3Al2(FeO4)31086.691220
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" - ], - "text/plain": [ - " A B C D Pretty Formula sus_factor\n", - "0 Fe5+ Au3+ Li1+ O2- Li3Fe3(AuO6)2 1048.627123\n", - "1 Fe5+ N3+ Li1+ O2- Li3Fe3(NO6)2 1057.900521\n", - "2 Fe5+ C3+ Li1+ O2- Li3Fe3(CO6)2 1063.408167\n", - "3 Fe3+ S6+ Li1+ O2- Li3Fe3(SO6)2 1084.708271\n", - "4 Fe5+ Al3+ Li1+ O2- Li3Al2(FeO4)3 1086.691220" - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "inner_merged = pd.merge(x, comps)\n", - "inner_merged.to_csv(\"./Li-Garnet_Comps_Corrected_Pym.csv\", index=False)\n", - "inner_merged.head()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - " A B C D Pretty Formula sus_factor\n", - "0 Fe5+ Au3+ Li1+ O2- Li3Fe3(AuO6)2 1048.627123\n", - "1 Fe5+ N3+ Li1+ O2- Li3Fe3(NO6)2 1057.900521\n", - "2 Fe5+ C3+ Li1+ O2- Li3Fe3(CO6)2 1063.408167\n", - "3 Fe3+ S6+ Li1+ O2- Li3Fe3(SO6)2 1084.708271\n", - "4 Fe5+ Al3+ Li1+ O2- Li3Al2(FeO4)3 1086.691220\n", - "\n", - "We have reduced our search space from 2504 to 691\n" - ] - } - ], - "source": [ - "print(inner_merged.head())\n", - "print(\"\")\n", - "print(f\"We have reduced our search space from {comps.shape[0]} to {inner_merged.shape[0]}\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# x=x[:100]" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "Time taken to predict the crystal structures of our search space of 691 with a threshold of 0.0001 is 0:01:28.345660 \n", - "\n" - ] - } - ], - "source": [ - "# Create a list of test species\n", - "test_specs_list = [\n", - " [\n", - " parse_spec(inner_merged[\"A\"][i]),\n", - " parse_spec(inner_merged[\"B\"][i]),\n", - " parse_spec(inner_merged[\"C\"][i]),\n", - " parse_spec(inner_merged[\"D\"][i]),\n", - " ]\n", - " for i in range(inner_merged.shape[0])\n", - "]\n", - "\n", - "# Set up a for loop to store\n", - "\n", - "start = datetime.now()\n", - "\n", - "preds = []\n", - "parents_list = []\n", - "probs_list = []\n", - "for test_specs in test_specs_list:\n", - " predictions = list(SP.predict_structs(test_specs, thresh=10e-4, include_same=False))\n", - " predictions.sort(key=itemgetter(1), reverse=True)\n", - " parents = [x[2].composition() for x in predictions]\n", - " probs = [x[1] for x in predictions]\n", - " preds.append(predictions)\n", - " parents_list.append(parents)\n", - " probs_list.append(probs)\n", - "print(\n", - " f\"Time taken to predict the crystal structures of our search space of {inner_merged.shape[0]} with a threshold of 0.0001 is {datetime.now()-start} \"\n", - ")\n", - "# print(parents_list)\n", - "print(\"\")\n", - "# print(probs_list)" - ] - }, - { - "cell_type": "markdown", - "metadata": {}, - "source": [ - "## Part 5: Storing the results" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Add predictions to dataframe\n", - "import pymatgen as mg\n", - "\n", - "pred_structs = []\n", - "probs = []\n", - "parent_structs = []\n", - "parent_pretty_formula = []\n", - "for i in preds:\n", - " if len(i) == 0:\n", - " pred_structs.append(None)\n", - " probs.append(None)\n", - " parent_structs.append(None)\n", - " parent_pretty_formula.append(None)\n", - " else:\n", - " pred_structs.append(i[0][0].as_poscar())\n", - " probs.append(i[0][1])\n", - " parent_structs.append(i[0][2].as_poscar())\n", - " parent_pretty_formula.append(\n", - " mg.Structure.from_str(i[0][2].as_poscar(), fmt=\"poscar\").composition.reduced_formula\n", - " )" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/html": [ - "
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ABCDPretty Formulasus_factorpredicted_structureprobabilityParent formulaparent_structure
35Fe3+Se6+Li1+O2-Li3Fe3(SeO6)21333.993967NoneNaNNoneNone
36Mn5+Ti3+Li1+O2-Li3Ti2Mn3O121337.856132Li1+ Mn5+ O2- Ti3+\\n1.0\\n-5.961372 5.961372 5....0.003172Li3Ti2(PO4)3Li1+ O2- P5+ Ti3+\\n1.0\\n-5.961372 5.961372 5.9...
37Ag3+Se6+Li1+O2-Li3Ag3(SeO6)21348.830401NoneNaNNoneNone
38Ti3+Se6+Li1+O2-Li3Ti3(SeO6)21386.761748NoneNaNNoneNone
39Mn3+Mn6+Li1+O2-Li3Mn5O121390.537491NoneNaNNoneNone
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" - ], - "text/plain": [ - " A B C D Pretty Formula sus_factor \\\n", - "35 Fe3+ Se6+ Li1+ O2- Li3Fe3(SeO6)2 1333.993967 \n", - "36 Mn5+ Ti3+ Li1+ O2- Li3Ti2Mn3O12 1337.856132 \n", - "37 Ag3+ Se6+ Li1+ O2- Li3Ag3(SeO6)2 1348.830401 \n", - "38 Ti3+ Se6+ Li1+ O2- Li3Ti3(SeO6)2 1386.761748 \n", - "39 Mn3+ Mn6+ Li1+ O2- Li3Mn5O12 1390.537491 \n", - "\n", - " predicted_structure probability \\\n", - "35 None NaN \n", - "36 Li1+ Mn5+ O2- Ti3+\\n1.0\\n-5.961372 5.961372 5.... 0.003172 \n", - "37 None NaN \n", - "38 None NaN \n", - "39 None NaN \n", - "\n", - " Parent formula parent_structure \n", - "35 None None \n", - "36 Li3Ti2(PO4)3 Li1+ O2- P5+ Ti3+\\n1.0\\n-5.961372 5.961372 5.9... \n", - "37 None None \n", - "38 None None \n", - "39 None None " - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "# Add prediction results to dataframe\n", - "inner_merged[\"predicted_structure\"] = pred_structs\n", - "inner_merged[\"probability\"] = probs\n", - "inner_merged[\"Parent formula\"] = parent_pretty_formula\n", - "inner_merged[\"parent_structure\"] = parent_structs\n", - "\n", - "inner_merged[35:40]" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# output the intermediary results into a dataframe\n", - "outdir = \"./Li-SP_results\"\n", - "if not os.path.exists(outdir):\n", - " os.mkdir(outdir)\n", - "fullpath = os.path.join(outdir, \"pred_results.csv\")\n", - "inner_merged.to_csv(fullpath)" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/html": [ - "
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ABCDPretty Formulasus_factorpredicted_structureprobabilityParent formulaparent_structure
0Mn5+Ti3+Li1+O2-Li3Ti2Mn3O121337.856132Li1+ Mn5+ O2- Ti3+\\n1.0\\n-5.961372 5.961372 5....0.003172Li3Ti2(PO4)3Li1+ O2- P5+ Ti3+\\n1.0\\n-5.961372 5.961372 5.9...
1Mn5+Mn3+Li1+O2-Li3Mn5O121390.537491Li1+ Mn5+ Mn3+ O2-\\n1.0\\n-5.919846 5.919846 5....0.003172Li3Mn2(PO4)3Li1+ Mn3+ O2- P5+\\n1.0\\n-5.919846 5.919846 5.9...
2Mn5+V3+Li1+O2-Li3Mn3V2O121723.667044Li1+ Mn5+ O2- V3+\\n1.0\\n-5.916063 5.916063 5.9...0.003172Li3V2(PO4)3Li1+ O2- P5+ V3+\\n1.0\\n-5.916063 5.916063 5.91...
3Y3+S6+Li1+O2-Li3Y3(SO6)21730.939983Li1+ O2- S6+ Y3+\\n1.0\\n-6.215615 6.215615 6.21...0.006341Li3Y3(TeO6)2Li1+ O2- Te6+ Y3+\\n1.0\\n-6.215615 6.215615 6.2...
4Fe5+Cr3+Li1+O2-Li3Cr2(FeO4)31743.330697Cr3+ Fe5+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6....0.001940Li3Cr2(AsO4)3As5+ Cr3+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6....
\n", - "
" - ], - "text/plain": [ - " A B C D Pretty Formula sus_factor \\\n", - "0 Mn5+ Ti3+ Li1+ O2- Li3Ti2Mn3O12 1337.856132 \n", - "1 Mn5+ Mn3+ Li1+ O2- Li3Mn5O12 1390.537491 \n", - "2 Mn5+ V3+ Li1+ O2- Li3Mn3V2O12 1723.667044 \n", - "3 Y3+ S6+ Li1+ O2- Li3Y3(SO6)2 1730.939983 \n", - "4 Fe5+ Cr3+ Li1+ O2- Li3Cr2(FeO4)3 1743.330697 \n", - "\n", - " predicted_structure probability \\\n", - "0 Li1+ Mn5+ O2- Ti3+\\n1.0\\n-5.961372 5.961372 5.... 0.003172 \n", - "1 Li1+ Mn5+ Mn3+ O2-\\n1.0\\n-5.919846 5.919846 5.... 0.003172 \n", - "2 Li1+ Mn5+ O2- V3+\\n1.0\\n-5.916063 5.916063 5.9... 0.003172 \n", - "3 Li1+ O2- S6+ Y3+\\n1.0\\n-6.215615 6.215615 6.21... 0.006341 \n", - "4 Cr3+ Fe5+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6.... 0.001940 \n", - "\n", - " Parent formula parent_structure \n", - "0 Li3Ti2(PO4)3 Li1+ O2- P5+ Ti3+\\n1.0\\n-5.961372 5.961372 5.9... \n", - "1 Li3Mn2(PO4)3 Li1+ Mn3+ O2- P5+\\n1.0\\n-5.919846 5.919846 5.9... \n", - "2 Li3V2(PO4)3 Li1+ O2- P5+ V3+\\n1.0\\n-5.916063 5.916063 5.91... \n", - "3 Li3Y3(TeO6)2 Li1+ O2- Te6+ Y3+\\n1.0\\n-6.215615 6.215615 6.2... \n", - "4 Li3Cr2(AsO4)3 As5+ Cr3+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6.... " - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "# Filter dataframe to remove blank entries from dataframe\n", - "results = inner_merged.dropna()\n", - "results = results.reset_index(drop=True)\n", - "results.head()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Check if composition exists in our local database\n", - "\n", - "in_db = []\n", - "for i in results[\"predicted_structure\"]:\n", - " comp = SmactStructure.from_poscar(i).composition()\n", - " if len(DB.get_structs(comp, \"Garnets\")) != 0:\n", - " in_db.append(\"Yes\")\n", - " else:\n", - " in_db.append(\"No\")\n", - "results[\"In DB?\"] = in_db" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stdout", - "output_type": "stream", - "text": [ - "No 194\n", - "Yes 14\n", - "Name: In DB?, dtype: int64\n" - ] - }, - { - "data": { - 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\n", - "text/plain": [ - "
" - ] - }, - "metadata": {}, - "output_type": "display_data" - } - ], - "source": [ - "print(results[\"In DB?\"].value_counts())\n", - "\n", - "\n", - "# Check the ratio of In DB?:Not in DB\n", - "in_db_count = results[\"In DB?\"].value_counts()\n", - "from matplotlib import pyplot as plt\n", - "\n", - "fig = plt.figure()\n", - "ax = fig.add_axes([0, 0, 1, 1])\n", - "ax.axis(\"equal\")\n", - "ax.pie(in_db_count, labels=[\"No\", \"Yes\"], autopct=\"%1.2f%%\")\n", - "plt.savefig(f\"{outdir}/Li-Garnets_Li-In_DB_SP.png\")\n", - "plt.show()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "image/png": 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kqQm1BndETAI+CizuNnoecFP1+Sbgk3XWIEnSUFL3Efe3gL8DdnQbNyEzNwBU7++quQZJkoaM2oI7Ij4GvJSZ/erTPCIuiIiVEbFy48aNLa5OkqQy1XnEfQLwiYh4DvgJcHJE3Az8PiIOA6jeX+pp4cy8ITM7M7Nz/PjxNZYpSVI5agvuzPxKZk7KzA7gL4F7M/Ms4A7gnGq2c4Db66pBkqShZjB+x30t8JGIeBr4SDUsSZKa0NRDRgYqM+8D7qs+bwJOacd2JUkaauw5TZKkghjckiQVxOCWJKkgBrckSQUxuCVJKojBLUlSQQxuSZIKYnBLklQQg1uSpIIY3JIkFcTgliSpIAa3JEkFMbglSSqIwS1JUkEMbkmSCmJwS5JUEINbkqSCGNySJBXE4JYkqSAGtyRJBTG4JUkqiMEtSVJBDG5JkgpicEuSVBCDW5KkghjckiQVxOCWJKkgBrckSQUxuCVJKojBLUlSQQxuSZIKYnBLklQQg1uSpIIY3JIkFcTgliSpIAa3JEkFMbglSSqIwS1JUkEMbkmSCmJwS5JUEINbkqSCGNySJBXE4JYkqSAGtyRJBTG4JUkqiMEtSVJBDG5JkgpicEuSVBCDW5KkghjckiQVxOCWJKkgBrckSQUxuCVJKojBLUlSQQxuSZIKYnBLklQQg1uSpIIY3JIkFcTgliSpIAa3JEkFqS24I2JyRKyIiDUR8UREXFyNPyQifhkRT1fv4+qqQZKkoabOI+7twOWZOQM4DvhiRLwf+DJwT2ZOB+6phiVJUhNqC+7M3JCZD1ef/wisASYC84CbqtluAj5ZVw2SJA01bbnGHREdwDHAg8CEzNwAjXAH3tWOGiRJGgpqD+6IGAvcClySma/2YbkLImJlRKzcuHFjfQVKklSQWoM7IvajEdpLM/O2avTvI+KwavphwEs9LZuZN2RmZ2Z2jh8/vs4yJUkqRp13lQdwI7AmM/+h26Q7gHOqz+cAt9dVgyRJQ82oGtd9AnA2sDoiHqnG/T1wLbAsIs4H1gFn1FiDJElDSm3BnZn3A7GHyafUtV1JkoYye06TJKkgBrckSQUxuIehiZOnEBEtf02cPGWwd02Shrw6b07TPmp91wuc+f3ftHy9t3x+TsvXKUl6M4+4JUkqiMEtSVJBDG5JkgpicEuSVBCDW5KkghjckiQVxOCWJKkgBrckSQUxuCVJKojBLUlSQQxuSZIKYnBrn1bHA1F8GIqkkvmQEe3T6nggig9DkVQyj7glSSqIwS1JUkEMbknSsFL6vTNe45YkDSul3zvjEbckSQUxuCVJKojBLUlSQQxuSZIKYnBLklQQg1uSpIIY3JIkFcTgliSpIAa3JEkFMbglSSqIwS1JUkEMbkmSCmJwS5JUEINbkqSCGNySJBXE4JYkqSAGtyRJBTG4JUkqiMEtSVJBDG5pHzZx8hQioqWviZOnDPZuSRqAUYNdgKQ9W9/1Amd+/zctXectn5/T0vVJai+PuCVJKojBLUlSQQxuSZIKYnBLklQQg1uSpIJ4V/m+bsQoImKwq5Ak7SMM7n3dju3+HEiStIunyiVJKohH3NI+bOR+o1t+hmTkfqNbuj5J7WVwS/uwN7ZtJZd8tKXrjPPuaun6JLWXp8olSSqIwa3Wqe6Ab+WrlDp9eIcPRJHaxVPlap1S7oCvoU7wbn0fiCK1h0fckiQVxOCWJKkgnirXvm3EqNafLq1jnZTzM6sRYG98hZg4eQrru15o+XoPnzSZF19Y1/L1qj0Mbu3bdmyv5edQrV7nzvWWYAcM6/0vSR33DYD3DpTOU+WSJBVkUI64I+J04NvASGBxZl47GHUMWzWdKh7uPAVdjzra9B0HjuXlV//Y8vWqDKX3SNj24I6IkcB3gY8AXcBvI+KOzHyy3bUMWzWcfgZPldZxCnq4tyl4Wl+tV3qPhINxqvxY4HeZ+UxmbgV+AswbhDokSSrOYAT3RKD7bZJd1ThJktSLyMz2bjDiDOC0zPzravhs4NjM/NJu810AXFANHgE81c9NvhP4Qz+XVd/Z3u1jW7ePbd0+tnXDezJzfE8TBuPmtC5gcrfhScD63WfKzBuAGwa6sYhYmZmdA12PmmN7t49t3T62dfvY1r0bjFPlvwWmR8TUiBgN/CVwxyDUIUlScdp+xJ2Z2yPiQuAXNH4O9oPMfKLddUiSVKJB+R13Zv4M+FmbNjfg0+3qE9u7fWzr9rGt28e27kXbb06TJEn9Z5enkiQVpOjgjojTI+KpiPhdRHy5h+kREQur6Y9FxOxml9Wb9betI2JyRKyIiDUR8UREXNz+6ssykL/ravrIiFgVET9tX9XlGuD3yMERsTwi1lZ/48e3t/qyDLCtL62+Qx6PiB9HxJj2Vr8PycwiXzRubPvfwDRgNPAo8P7d5vkL4G4ggOOAB5td1lfL2vowYHb1+UDgX23retq62/TLgP8G/HSw92dffw20vYGbgL+uPo8GDh7sfdpXXwP8HpkIPAu8rRpeBpw72Ps0WK+Sj7ib6Tp1HvCP2fC/gIMj4rAml9Wf9LutM3NDZj4MkJl/BNZgT3l7M5C/ayJiEvBRYHE7iy5Yv9s7Ig4C/hy4ESAzt2bmy22svTQD+tumcTP12yJiFPB2euj/Y7goObib6Tp1T/PY7WrfDKStd4mIDuAY4MHWlzhkDLStvwX8HY1nnqh3A2nvacBGYEl1aWJxRBxQZ7GF63dbZ+aLwPXAOmAD8Epm/kuNte7TSg7unp71t/st8nuap5ll9ScDaevGxIixwK3AJZn5agtrG2r63dYR8THgpcx8qPVlDVkD+dseBcwGvpeZxwCbAe+X2bOB/G2Po3E0PhU4HDggIs5qcX3FKDm4m+k6dU/zNNXtqnYZSFsTEfvRCO2lmXlbjXUOBQNp6xOAT0TEczROQ54cETfXV+qQMNDvka7M3HkGaTmNIFfPBtLWpwLPZubGzNwG3Aa09oHaBSk5uJvpOvUOYEF1p+JxNE6vbGhyWf1Jv9s6IoLGNcA1mfkP7S27SP1u68z8SmZOysyOarl7M3PYHpU0aSDt/W/ACxFxRDXfKcCTbau8PAP5zl4HHBcRb6++U06hcb/MsDQoPae1Qu6h69SI+EI1fRGN3tn+Avgd8Dpw3t6WHYTdKMJA2prGUeDZwOqIeKQa9/fZ6D1PuxlgW6uPWtDeXwKWVkH0DP5b7NEAv7MfjIjlwMPAdmAVw7iHNXtOkySpICWfKpckadgxuCVJKojBLUlSQQxuSZIKYnBLklQQg1sahiLitT7O/8OI+HQP4zsjYmH1+dyI+K/V5y9ExIJu4w9vRd2SCv4dt6S9i4iRmflGndvIzJXAyh7GL+o2eC7wOPZOKLWER9xSgSKio3oG9E3Vc4uXV71KPRcR/zki7gfOiIi/iojV1TOMr9ttHd+IiIcj4p6IGF+N+5uI+G1EPBoRt0bE27stcmpE/M+I+NeqX3Qi4sTo4bnfEXF1RPyH6ii9k0YnJY9ExEcj4p+7zfeRiLAbXKkPDG6pXEcAN2Tm0cCrwN9W47dk5lzgfwDXAScDs4APRsQnq3kOAB7OzNnAr4CrqvG3ZeYHM/MDNLqUPL/b9jqAD9N4bOiiiBjTW4GZuZzGEfn8zJxFo2esGTv/o0CjZ6wlfdttaXgzuKVyvZCZv64+3wzMrT7fUr1/ELivejDDdmApjedHQ+Oxn7f0sOzM6qh6NTAf+LNu21uWmTsy82ka3Xse2deCs9FV44+AsyLiYOB44O6+rkcazrzGLZVr9/6Kdw5vrt57ekRib+v6IfDJzHw0Is4FTmxie321BLgT2AL8U/WfCklN8ohbKteUiDi++vxXwP27TX8Q+HBEvDMiRlbz/KqaNgLYeZf4Z7steyCwoXoU6/zd1ndGRIyIiPcC04Cnmqzzj9V6AcjM9TRuVPtPNP6jIKkPDG6pXGuAcyLiMeAQ4HvdJ1aPQ/wKsAJ4lMY17duryZuBP4uIh2hcA/8v1fgraQT+L4G1u23vKRrBfzfwhczc0mSdP6RxTfyRiHhbNW4pjVP9PgZT6iOfDiYVKCI6gJ9m5szBrqU/qt97r8rMGwe7Fqk0XuOW1FbVUf5m4PLBrkUqkUfckiQVxGvckiQVxOCWJKkgBrckSQUxuCVJKojBLUlSQQxuSZIK8v8BRCAr0z/9DzcAAAAASUVORK5CYII=\n", - "text/plain": [ - "
" - ] - }, - "metadata": { - "needs_background": "light" - }, - "output_type": "display_data" - } - ], - "source": [ - "import matplotlib.pyplot as plt\n", - "import seaborn as sns\n", - "\n", - "plt.figure(figsize=(8, 6))\n", - "ax1 = sns.histplot(data=results, x=\"probability\", hue=\"In DB?\", multiple=\"stack\")\n", - "# ax2=sns.histplot(new_series, label=\"New Garnets\")\n", - "# plt.savefig(\"Prediction_Probability_Distribution_pym.png\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "image/png": 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4Fe5+Cr3+Li1+O2-Li3Cr2(FeO4)31743.330697Cr3+ Fe5+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6....0.001940Li3Cr2(AsO4)3As5+ Cr3+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6....No
\n", - "
" - ], - "text/plain": [ - " A B C D Pretty Formula sus_factor \\\n", - "0 Mn5+ Ti3+ Li1+ O2- Li3Ti2Mn3O12 1337.856132 \n", - "1 Mn5+ Mn3+ Li1+ O2- Li3Mn5O12 1390.537491 \n", - "2 Mn5+ V3+ Li1+ O2- Li3Mn3V2O12 1723.667044 \n", - "3 Y3+ S6+ Li1+ O2- Li3Y3(SO6)2 1730.939983 \n", - "4 Fe5+ Cr3+ Li1+ O2- Li3Cr2(FeO4)3 1743.330697 \n", - "\n", - " predicted_structure probability \\\n", - "0 Li1+ Mn5+ O2- Ti3+\\n1.0\\n-5.961372 5.961372 5.... 0.003172 \n", - "1 Li1+ Mn5+ Mn3+ O2-\\n1.0\\n-5.919846 5.919846 5.... 0.003172 \n", - "2 Li1+ Mn5+ O2- V3+\\n1.0\\n-5.916063 5.916063 5.9... 0.003172 \n", - "3 Li1+ O2- S6+ Y3+\\n1.0\\n-6.215615 6.215615 6.21... 0.006341 \n", - "4 Cr3+ Fe5+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6.... 0.001940 \n", - "\n", - " Parent formula parent_structure In DB? \n", - "0 Li3Ti2(PO4)3 Li1+ O2- P5+ Ti3+\\n1.0\\n-5.961372 5.961372 5.9... No \n", - "1 Li3Mn2(PO4)3 Li1+ Mn3+ O2- P5+\\n1.0\\n-5.919846 5.919846 5.9... No \n", - "2 Li3V2(PO4)3 Li1+ O2- P5+ V3+\\n1.0\\n-5.916063 5.916063 5.91... No \n", - "3 Li3Y3(TeO6)2 Li1+ O2- Te6+ Y3+\\n1.0\\n-6.215615 6.215615 6.2... No \n", - "4 Li3Cr2(AsO4)3 As5+ Cr3+ Li1+ O2-\\n1.0\\n-6.068257 6.068257 6.... No " - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "results.head()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# new_structures=" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# pym_Li_DB=StructureDB(\"pym_Li.DB\")\n", - "# pym_Li_DB.add_table(\"New\")\n", - "# pym_Li_DB.add_table(\"not_new\")\n", - "# pym_Li_DB.add_structs(new_structures,\"New\")\n", - "# pym_Li_DB.add_structs(exist_structures,\"not_new\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# pym_Li_DB.add_table(\"not_new\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "text/plain": [ - "14" - ] - }, - "execution_count": null, - "metadata": {}, - "output_type": "execute_result" - } - ], - "source": [ - "# pym_Li_DB.add_structs(new_structures,\"New\")\n", - "# pym_Li_DB.add_structs(exist_structures,\"not_new\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [], - "source": [ - "# Periodic table BS\n", - "# Get element names\n", - "from pymatgen.util.plotting import periodic_table_heatmap\n", - "\n", - "A_els = pd.Series([parse_spec(i)[0] for i in results[\"A\"]])\n", - "B_els = pd.Series([parse_spec(i)[0] for i in results[\"B\"]])\n", - "C_els = pd.Series([parse_spec(i)[0] for i in results[\"C\"]])\n", - "\n", - "# get dict of counts\n", - "A_els_counts = A_els.value_counts().to_dict()\n", - "B_els_counts = B_els.value_counts().to_dict()\n", - "C_els_counts = C_els.value_counts().to_dict()" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "name": "stderr", - "output_type": "stream", - "text": [ - "/rds/general/user/aoo216/home/anaconda3/envs/exploration/lib/python3.9/site-packages/pymatgen/util/plotting.py:236: MatplotlibDeprecationWarning: You are modifying the state of a globally registered colormap. In future versions, you will not be able to modify a registered colormap in-place. To remove this warning, you can make a copy of the colormap first. cmap = copy.copy(mpl.cm.get_cmap(\"YlOrRd\"))\n", - " cbar.cmap.set_under(blank_color)\n" - ] - }, - { - "data": { - "image/png": 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\n", - "text/plain": [ - "
" - ] - }, - "metadata": { - "needs_background": "light" - }, - "output_type": "display_data" - } - ], - "source": [ - "ax1 = periodic_table_heatmap(elemental_data=A_els_counts, cbar_label=\"Counts\")\n", - "ax1.savefig(f\"{outdir}/periodic_table_A.png\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "image/png": 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\n", - "text/plain": [ - "
" - ] - }, - "metadata": { - "needs_background": "light" - }, - "output_type": "display_data" - } - ], - "source": [ - "ax2 = periodic_table_heatmap(elemental_data=B_els_counts, cbar_label=\"Counts\")\n", - "ax2.savefig(f\"{outdir}/periodic_table_B.png\")" - ] - }, - { - "cell_type": "code", - "execution_count": null, - "metadata": {}, - "outputs": [ - { - "data": { - "image/png": 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\n", - "text/plain": [ - "
" - ] - }, - "metadata": { - "needs_background": "light" - }, - "output_type": "display_data" - } - ], - "source": [ - "ax3 = periodic_table_heatmap(elemental_data=C_els_counts, cbar_label=\"Counts\")\n", - "ax3.savefig(f\"{outdir}/periodic_table_C.png\")" - ] - } - ], - "metadata": { - "kernelspec": { - "display_name": "Python 3", - "language": "python", - "name": "python3" - }, - "language_info": { - "codemirror_mode": { - "name": "ipython", - "version": 3 - }, - "file_extension": ".py", - "mimetype": "text/x-python", - "name": "python", - "nbconvert_exporter": "python", - "pygments_lexer": "ipython3", - "version": "3.8.10" - } - }, - "nbformat": 4, - "nbformat_minor": 4 -} diff --git a/examples/Structure_Prediction/MP_garnets.csv b/examples/Structure_Prediction/MP_garnets.csv deleted file mode 100644 index 463f6ff3..00000000 --- a/examples/Structure_Prediction/MP_garnets.csv +++ /dev/null @@ -1,55971 +0,0 @@ -pretty_formula,material_id,spacegroup.symbol,icsd_ids,e_above_hull,exp,structure,cif -Na3Ti2(GeO4)3,mp-1012670,Ia-3d,[],0.03791873956249692,{'tags': ['Substituion']},"Full Formula (Na12 Ti8 Ge12 O48) -Reduced Formula: Na3Ti2(GeO4)3 -abc : 10.758313 10.758313 10.758313 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.75 0.625 0.875 -0.001 - 1 Na 0.25 0.875 0.625 -0.001 - 2 Na 0.625 0.25 0.875 -0.001 - 3 Na 0.875 0.75 0.625 -0.001 - 4 Na 0.875 0.625 0.25 -0.001 - 5 Na 0.625 0.875 0.75 -0.001 - 6 Na 0.25 0.375 0.125 -0.001 - 7 Na 0.75 0.125 0.375 -0.001 - 8 Na 0.375 0.75 0.125 -0.001 - 9 Na 0.125 0.25 0.375 -0.001 - 10 Na 0.125 0.375 0.75 -0.001 - 11 Na 0.375 0.125 0.25 -0.001 - 12 Ti 0.5 0 0.5 -0.028 - 13 Ti 0 0.5 0 -0.028 - 14 Ti 0.5 0.5 0.5 -0.028 - 15 Ti 0 0 0.5 -0.028 - 16 Ti 0 0 0 -0.028 - 17 Ti 0 0.5 0.5 -0.028 - 18 Ti 0.5 0.5 0 -0.028 - 19 Ti 0.5 0 0 -0.028 - 20 Ge 0.375 0.625 0.75 -0.005 - 21 Ge 0.625 0.375 0.25 -0.005 - 22 Ge 0.625 0.75 0.375 -0.006 - 23 Ge 0.25 0.125 0.875 -0.006 - 24 Ge 0.875 0.25 0.125 -0.006 - 25 Ge 0.75 0.375 0.625 -0.006 - 26 Ge 0.25 0.625 0.375 -0.006 - 27 Ge 0.75 0.875 0.125 -0.006 - 28 Ge 0.125 0.75 0.875 -0.005 - 29 Ge 0.375 0.25 0.625 -0.006 - 30 Ge 0.875 0.125 0.75 -0.006 - 31 Ge 0.125 0.875 0.25 -0.005 - 32 O 0.510197 0.397572 0.81648 0.081 - 33 O 0.81648 0.510197 0.397572 0.073 - 34 O 0.806282 0.887375 0.989803 0.077 - 35 O 0.418907 0.102428 0.612625 0.076 - 36 O 0.887375 0.397572 0.081093 0.079 - 37 O 0.68352 0.081093 0.693718 0.076 - 38 O 0.81648 0.806282 0.418907 0.07 - 39 O 0.397572 0.81648 0.510197 0.074 - 40 O 0.612625 0.693718 0.510197 0.072 - 41 O 0.418907 0.81648 0.806282 0.075 - 42 O 0.397572 0.081093 0.887375 0.073 - 43 O 0.102428 0.989803 0.68352 0.071 - 44 O 0.989803 0.68352 0.102428 0.077 - 45 O 0.806282 0.418907 0.81648 0.08 - 46 O 0.510197 0.612625 0.693718 0.075 - 47 O 0.693718 0.510197 0.612625 0.075 - 48 O 0.081093 0.887375 0.397572 0.072 - 49 O 0.989803 0.806282 0.887375 0.073 - 50 O 0.081093 0.693718 0.68352 0.072 - 51 O 0.387375 0.306282 0.489803 0.073 - 52 O 0.612625 0.418907 0.102428 0.08 - 53 O 0.102428 0.612625 0.418907 0.072 - 54 O 0.693718 0.68352 0.081093 0.08 - 55 O 0.68352 0.102428 0.989803 0.075 - 56 O 0.489803 0.602428 0.18352 0.08 - 57 O 0.18352 0.489803 0.602428 0.074 - 58 O 0.193718 0.112625 0.010197 0.076 - 59 O 0.581093 0.897572 0.387375 0.075 - 60 O 0.112625 0.602428 0.918907 0.078 - 61 O 0.31648 0.918907 0.306282 0.074 - 62 O 0.18352 0.193718 0.581093 0.071 - 63 O 0.602428 0.18352 0.489803 0.074 - 64 O 0.31648 0.897572 0.010197 0.075 - 65 O 0.306282 0.31648 0.918907 0.078 - 66 O 0.897572 0.387375 0.581093 0.072 - 67 O 0.112625 0.010197 0.193718 0.073 - 68 O 0.387375 0.581093 0.897572 0.08 - 69 O 0.918907 0.306282 0.31648 0.074 - 70 O 0.010197 0.193718 0.112625 0.074 - 71 O 0.918907 0.112625 0.602428 0.074 - 72 O 0.306282 0.489803 0.387375 0.072 - 73 O 0.489803 0.387375 0.306282 0.073 - 74 O 0.193718 0.581093 0.18352 0.078 - 75 O 0.010197 0.31648 0.897572 0.078 - 76 O 0.897572 0.010197 0.31648 0.071 - 77 O 0.602428 0.918907 0.112625 0.072 - 78 O 0.581093 0.18352 0.193718 0.072 - 79 O 0.887375 0.989803 0.806282 0.076","# generated using pymatgen -data_Na3Ti2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.75831316 -_cell_length_b 10.75831316 -_cell_length_c 10.75831316 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Ti2(GeO4)3 -_chemical_formula_sum 'Na12 Ti8 Ge12 O48' -_cell_volume 958.54091437 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.75000000 0.62500000 0.87500000 1 - Na Na1 1 0.25000000 0.87500000 0.62500000 1 - Na Na2 1 0.62500000 0.25000000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.87500000 0.62500000 0.25000000 1 - Na Na5 1 0.62500000 0.87500000 0.75000000 1 - Na Na6 1 0.25000000 0.37500000 0.12500000 1 - Na Na7 1 0.75000000 0.12500000 0.37500000 1 - Na Na8 1 0.37500000 0.75000000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Ti Ti12 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti13 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti14 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti15 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti16 1 0.00000000 0.00000000 0.00000000 1 - Ti Ti17 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti18 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51019700 0.39757200 0.81648000 1 - O O33 1 0.81648000 0.51019700 0.39757200 1 - O O34 1 0.80628200 0.88737500 0.98980300 1 - O O35 1 0.41890700 0.10242800 0.61262500 1 - O O36 1 0.88737500 0.39757200 0.08109300 1 - O O37 1 0.68352000 0.08109300 0.69371800 1 - O O38 1 0.81648000 0.80628200 0.41890700 1 - O O39 1 0.39757200 0.81648000 0.51019700 1 - O O40 1 0.61262500 0.69371800 0.51019700 1 - O O41 1 0.41890700 0.81648000 0.80628200 1 - O O42 1 0.39757200 0.08109300 0.88737500 1 - O O43 1 0.10242800 0.98980300 0.68352000 1 - O O44 1 0.98980300 0.68352000 0.10242800 1 - O O45 1 0.80628200 0.41890700 0.81648000 1 - O O46 1 0.51019700 0.61262500 0.69371800 1 - O O47 1 0.69371800 0.51019700 0.61262500 1 - O O48 1 0.08109300 0.88737500 0.39757200 1 - O O49 1 0.98980300 0.80628200 0.88737500 1 - O O50 1 0.08109300 0.69371800 0.68352000 1 - O O51 1 0.38737500 0.30628200 0.48980300 1 - O O52 1 0.61262500 0.41890700 0.10242800 1 - O O53 1 0.10242800 0.61262500 0.41890700 1 - O O54 1 0.69371800 0.68352000 0.08109300 1 - O O55 1 0.68352000 0.10242800 0.98980300 1 - O O56 1 0.48980300 0.60242800 0.18352000 1 - O O57 1 0.18352000 0.48980300 0.60242800 1 - O O58 1 0.19371800 0.11262500 0.01019700 1 - O O59 1 0.58109300 0.89757200 0.38737500 1 - O O60 1 0.11262500 0.60242800 0.91890700 1 - O O61 1 0.31648000 0.91890700 0.30628200 1 - O O62 1 0.18352000 0.19371800 0.58109300 1 - O O63 1 0.60242800 0.18352000 0.48980300 1 - O O64 1 0.31648000 0.89757200 0.01019700 1 - O O65 1 0.30628200 0.31648000 0.91890700 1 - O O66 1 0.89757200 0.38737500 0.58109300 1 - O O67 1 0.11262500 0.01019700 0.19371800 1 - O O68 1 0.38737500 0.58109300 0.89757200 1 - O O69 1 0.91890700 0.30628200 0.31648000 1 - O O70 1 0.01019700 0.19371800 0.11262500 1 - O O71 1 0.91890700 0.11262500 0.60242800 1 - O O72 1 0.30628200 0.48980300 0.38737500 1 - O O73 1 0.48980300 0.38737500 0.30628200 1 - O O74 1 0.19371800 0.58109300 0.18352000 1 - O O75 1 0.01019700 0.31648000 0.89757200 1 - O O76 1 0.89757200 0.01019700 0.31648000 1 - O O77 1 0.60242800 0.91890700 0.11262500 1 - O O78 1 0.58109300 0.18352000 0.19371800 1 - O O79 1 0.88737500 0.98980300 0.80628200 1 -" -Na3V2(GeO4)3,mp-1012686,Ia-3d,[],0.05625650788888681,{'tags': []},"Full Formula (Na12 V8 Ge12 O48) -Reduced Formula: Na3V2(GeO4)3 -abc : 10.661909 10.661909 10.661909 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.75 0.625 0.875 -0 - 1 Na 0.25 0.875 0.625 0 - 2 Na 0.625 0.25 0.875 0 - 3 Na 0.875 0.75 0.625 -0 - 4 Na 0.875 0.625 0.25 0 - 5 Na 0.625 0.875 0.75 -0 - 6 Na 0.25 0.375 0.125 -0 - 7 Na 0.75 0.125 0.375 0 - 8 Na 0.375 0.75 0.125 0 - 9 Na 0.125 0.25 0.375 -0 - 10 Na 0.125 0.375 0.75 0 - 11 Na 0.375 0.125 0.25 -0 - 12 V 0.5 0 0.5 0.039 - 13 V 0 0.5 0 0.965 - 14 V 0.5 0.5 0.5 -0.966 - 15 V 0 0 0.5 0.965 - 16 V 0 0 0 0.068 - 17 V 0 0.5 0.5 0.035 - 18 V 0.5 0.5 0 0.04 - 19 V 0.5 0 0 0.965 - 20 Ge 0.375 0.625 0.75 -0 - 21 Ge 0.625 0.375 0.25 -0 - 22 Ge 0.625 0.75 0.375 0 - 23 Ge 0.25 0.125 0.875 0.008 - 24 Ge 0.875 0.25 0.125 0.008 - 25 Ge 0.75 0.375 0.625 -0 - 26 Ge 0.25 0.625 0.375 -0 - 27 Ge 0.75 0.875 0.125 0.008 - 28 Ge 0.125 0.75 0.875 0.008 - 29 Ge 0.375 0.25 0.625 0 - 30 Ge 0.875 0.125 0.75 0.008 - 31 Ge 0.125 0.875 0.25 0.008 - 32 O 0.510679 0.398744 0.818945 -0.003 - 33 O 0.818945 0.510679 0.398744 -0.003 - 34 O 0.808265 0.888065 0.989321 -0.003 - 35 O 0.420201 0.101256 0.611935 -0.002 - 36 O 0.888065 0.398744 0.079799 -0.013 - 37 O 0.681055 0.079799 0.691735 -0.003 - 38 O 0.818945 0.808265 0.420201 -0.012 - 39 O 0.398744 0.818945 0.510679 -0.003 - 40 O 0.611935 0.691735 0.510679 0.011 - 41 O 0.420201 0.818945 0.808265 -0.012 - 42 O 0.398744 0.079799 0.888065 -0.013 - 43 O 0.101256 0.989321 0.681055 -0.013 - 44 O 0.989321 0.681055 0.101256 -0.013 - 45 O 0.808265 0.420201 0.818945 -0.012 - 46 O 0.510679 0.611935 0.691735 0.011 - 47 O 0.691735 0.510679 0.611935 0.01 - 48 O 0.079799 0.888065 0.398744 -0.013 - 49 O 0.989321 0.808265 0.888065 -0.003 - 50 O 0.079799 0.691735 0.681055 -0.002 - 51 O 0.388065 0.308265 0.489321 0.011 - 52 O 0.611935 0.420201 0.101256 -0.002 - 53 O 0.101256 0.611935 0.420201 -0.002 - 54 O 0.691735 0.681055 0.079799 -0.003 - 55 O 0.681055 0.101256 0.989321 -0.013 - 56 O 0.489321 0.601256 0.181055 -0.003 - 57 O 0.181055 0.489321 0.601256 -0.003 - 58 O 0.191735 0.111935 0.010679 -0.003 - 59 O 0.579799 0.898744 0.388065 -0.002 - 60 O 0.111935 0.601256 0.920201 -0.013 - 61 O 0.318945 0.920201 0.308265 -0.003 - 62 O 0.181055 0.191735 0.579799 -0.012 - 63 O 0.601256 0.181055 0.489321 -0.003 - 64 O 0.318945 0.898744 0.010679 -0.013 - 65 O 0.308265 0.318945 0.920201 -0.003 - 66 O 0.898744 0.388065 0.579799 -0.002 - 67 O 0.111935 0.010679 0.191735 -0.003 - 68 O 0.388065 0.579799 0.898744 -0.002 - 69 O 0.920201 0.308265 0.318945 -0.002 - 70 O 0.010679 0.191735 0.111935 -0.003 - 71 O 0.920201 0.111935 0.601256 -0.013 - 72 O 0.308265 0.489321 0.388065 0.01 - 73 O 0.489321 0.388065 0.308265 0.011 - 74 O 0.191735 0.579799 0.181055 -0.012 - 75 O 0.010679 0.318945 0.898744 -0.013 - 76 O 0.898744 0.010679 0.318945 -0.013 - 77 O 0.601256 0.920201 0.111935 -0.013 - 78 O 0.579799 0.181055 0.191735 -0.012 - 79 O 0.888065 0.989321 0.808265 -0.003","# generated using pymatgen -data_Na3V2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.66190895 -_cell_length_b 10.66190895 -_cell_length_c 10.66190895 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3V2(GeO4)3 -_chemical_formula_sum 'Na12 V8 Ge12 O48' -_cell_volume 933.00295033 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.75000000 0.62500000 0.87500000 1 - Na Na1 1 0.25000000 0.87500000 0.62500000 1 - Na Na2 1 0.62500000 0.25000000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.87500000 0.62500000 0.25000000 1 - Na Na5 1 0.62500000 0.87500000 0.75000000 1 - Na Na6 1 0.25000000 0.37500000 0.12500000 1 - Na Na7 1 0.75000000 0.12500000 0.37500000 1 - Na Na8 1 0.37500000 0.75000000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - V V12 1 0.50000000 0.00000000 0.50000000 1 - V V13 1 0.00000000 0.50000000 0.00000000 1 - V V14 1 0.50000000 0.50000000 0.50000000 1 - V V15 1 0.00000000 0.00000000 0.50000000 1 - V V16 1 0.00000000 0.00000000 0.00000000 1 - V V17 1 0.00000000 0.50000000 0.50000000 1 - V V18 1 0.50000000 0.50000000 0.00000000 1 - V V19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51067900 0.39874400 0.81894500 1 - O O33 1 0.81894500 0.51067900 0.39874400 1 - O O34 1 0.80826500 0.88806500 0.98932100 1 - O O35 1 0.42020100 0.10125600 0.61193500 1 - O O36 1 0.88806500 0.39874400 0.07979900 1 - O O37 1 0.68105500 0.07979900 0.69173500 1 - O O38 1 0.81894500 0.80826500 0.42020100 1 - O O39 1 0.39874400 0.81894500 0.51067900 1 - O O40 1 0.61193500 0.69173500 0.51067900 1 - O O41 1 0.42020100 0.81894500 0.80826500 1 - O O42 1 0.39874400 0.07979900 0.88806500 1 - O O43 1 0.10125600 0.98932100 0.68105500 1 - O O44 1 0.98932100 0.68105500 0.10125600 1 - O O45 1 0.80826500 0.42020100 0.81894500 1 - O O46 1 0.51067900 0.61193500 0.69173500 1 - O O47 1 0.69173500 0.51067900 0.61193500 1 - O O48 1 0.07979900 0.88806500 0.39874400 1 - O O49 1 0.98932100 0.80826500 0.88806500 1 - O O50 1 0.07979900 0.69173500 0.68105500 1 - O O51 1 0.38806500 0.30826500 0.48932100 1 - O O52 1 0.61193500 0.42020100 0.10125600 1 - O O53 1 0.10125600 0.61193500 0.42020100 1 - O O54 1 0.69173500 0.68105500 0.07979900 1 - O O55 1 0.68105500 0.10125600 0.98932100 1 - O O56 1 0.48932100 0.60125600 0.18105500 1 - O O57 1 0.18105500 0.48932100 0.60125600 1 - O O58 1 0.19173500 0.11193500 0.01067900 1 - O O59 1 0.57979900 0.89874400 0.38806500 1 - O O60 1 0.11193500 0.60125600 0.92020100 1 - O O61 1 0.31894500 0.92020100 0.30826500 1 - O O62 1 0.18105500 0.19173500 0.57979900 1 - O O63 1 0.60125600 0.18105500 0.48932100 1 - O O64 1 0.31894500 0.89874400 0.01067900 1 - O O65 1 0.30826500 0.31894500 0.92020100 1 - O O66 1 0.89874400 0.38806500 0.57979900 1 - O O67 1 0.11193500 0.01067900 0.19173500 1 - O O68 1 0.38806500 0.57979900 0.89874400 1 - O O69 1 0.92020100 0.30826500 0.31894500 1 - O O70 1 0.01067900 0.19173500 0.11193500 1 - O O71 1 0.92020100 0.11193500 0.60125600 1 - O O72 1 0.30826500 0.48932100 0.38806500 1 - O O73 1 0.48932100 0.38806500 0.30826500 1 - O O74 1 0.19173500 0.57979900 0.18105500 1 - O O75 1 0.01067900 0.31894500 0.89874400 1 - O O76 1 0.89874400 0.01067900 0.31894500 1 - O O77 1 0.60125600 0.92020100 0.11193500 1 - O O78 1 0.57979900 0.18105500 0.19173500 1 - O O79 1 0.88806500 0.98932100 0.80826500 1 -" -Li3Cr2(GeO4)3,mp-1012879,Ia-3d,[],0.13266934454162982,{'tags': []},"Full Formula (Li12 Cr8 Ge12 O48) -Reduced Formula: Li3Cr2(GeO4)3 -abc : 10.437399 10.437399 10.437399 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.625 0.875 0.002 - 1 Li 0.25 0.875 0.625 0.002 - 2 Li 0.625 0.25 0.875 0 - 3 Li 0.875 0.75 0.625 0 - 4 Li 0.875 0.625 0.25 0.002 - 5 Li 0.625 0.875 0.75 0.002 - 6 Li 0.25 0.375 0.125 0.002 - 7 Li 0.75 0.125 0.375 0.002 - 8 Li 0.375 0.75 0.125 0 - 9 Li 0.125 0.25 0.375 0 - 10 Li 0.125 0.375 0.75 0.002 - 11 Li 0.375 0.125 0.25 0.002 - 12 Cr 0.5 0 0.5 2.009 - 13 Cr 0 0.5 0 2.008 - 14 Cr 0.5 0.5 0.5 2.008 - 15 Cr 0 0 0.5 2.008 - 16 Cr 0 0 0 2.008 - 17 Cr 0 0.5 0.5 2.008 - 18 Cr 0.5 0.5 0 2.008 - 19 Cr 0.5 0 0 2.008 - 20 Ge 0.375 0.625 0.75 0.019 - 21 Ge 0.625 0.375 0.25 0.019 - 22 Ge 0.625 0.75 0.375 0.02 - 23 Ge 0.25 0.125 0.875 0.019 - 24 Ge 0.875 0.25 0.125 0.02 - 25 Ge 0.75 0.375 0.625 0.019 - 26 Ge 0.25 0.625 0.375 0.019 - 27 Ge 0.75 0.875 0.125 0.019 - 28 Ge 0.125 0.75 0.875 0.02 - 29 Ge 0.375 0.25 0.625 0.02 - 30 Ge 0.875 0.125 0.75 0.019 - 31 Ge 0.125 0.875 0.25 0.019 - 32 O 0.518932 0.401919 0.820335 -0.079 - 33 O 0.820335 0.518932 0.401919 -0.083 - 34 O 0.801402 0.882987 0.981068 -0.085 - 35 O 0.418415 0.098081 0.617013 -0.08 - 36 O 0.882987 0.401919 0.081585 -0.079 - 37 O 0.679665 0.081585 0.698598 -0.083 - 38 O 0.820335 0.801402 0.418415 -0.079 - 39 O 0.401919 0.820335 0.518932 -0.086 - 40 O 0.617013 0.698598 0.518932 -0.079 - 41 O 0.418415 0.820335 0.801402 -0.085 - 42 O 0.401919 0.081585 0.882987 -0.083 - 43 O 0.098081 0.981068 0.679665 -0.083 - 44 O 0.981068 0.679665 0.098081 -0.086 - 45 O 0.801402 0.418415 0.820335 -0.083 - 46 O 0.518932 0.617013 0.698598 -0.085 - 47 O 0.698598 0.518932 0.617013 -0.083 - 48 O 0.081585 0.882987 0.401919 -0.085 - 49 O 0.981068 0.801402 0.882987 -0.08 - 50 O 0.081585 0.698598 0.679665 -0.079 - 51 O 0.382987 0.301402 0.481068 -0.079 - 52 O 0.617013 0.418415 0.098081 -0.083 - 53 O 0.098081 0.617013 0.418415 -0.085 - 54 O 0.698598 0.679665 0.081585 -0.085 - 55 O 0.679665 0.098081 0.981068 -0.079 - 56 O 0.481068 0.598081 0.179665 -0.079 - 57 O 0.179665 0.481068 0.598081 -0.083 - 58 O 0.198598 0.117013 0.018932 -0.085 - 59 O 0.581585 0.901919 0.382987 -0.08 - 60 O 0.117013 0.598081 0.918415 -0.079 - 61 O 0.320335 0.918415 0.301402 -0.083 - 62 O 0.179665 0.198598 0.581585 -0.079 - 63 O 0.598081 0.179665 0.481068 -0.086 - 64 O 0.320335 0.901919 0.018932 -0.079 - 65 O 0.301402 0.320335 0.918415 -0.085 - 66 O 0.901919 0.382987 0.581585 -0.085 - 67 O 0.117013 0.018932 0.198598 -0.084 - 68 O 0.382987 0.581585 0.901919 -0.083 - 69 O 0.918415 0.301402 0.320335 -0.079 - 70 O 0.018932 0.198598 0.117013 -0.08 - 71 O 0.918415 0.117013 0.598081 -0.085 - 72 O 0.301402 0.481068 0.382987 -0.083 - 73 O 0.481068 0.382987 0.301402 -0.085 - 74 O 0.198598 0.581585 0.179665 -0.083 - 75 O 0.018932 0.320335 0.901919 -0.086 - 76 O 0.901919 0.018932 0.320335 -0.083 - 77 O 0.598081 0.918415 0.117013 -0.083 - 78 O 0.581585 0.179665 0.198598 -0.085 - 79 O 0.882987 0.981068 0.801402 -0.084","# generated using pymatgen -data_Li3Cr2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.43739879 -_cell_length_b 10.43739879 -_cell_length_c 10.43739879 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Cr2(GeO4)3 -_chemical_formula_sum 'Li12 Cr8 Ge12 O48' -_cell_volume 875.29599372 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.62500000 0.87500000 1 - Li Li1 1 0.25000000 0.87500000 0.62500000 1 - Li Li2 1 0.62500000 0.25000000 0.87500000 1 - Li Li3 1 0.87500000 0.75000000 0.62500000 1 - Li Li4 1 0.87500000 0.62500000 0.25000000 1 - Li Li5 1 0.62500000 0.87500000 0.75000000 1 - Li Li6 1 0.25000000 0.37500000 0.12500000 1 - Li Li7 1 0.75000000 0.12500000 0.37500000 1 - Li Li8 1 0.37500000 0.75000000 0.12500000 1 - Li Li9 1 0.12500000 0.25000000 0.37500000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.37500000 0.12500000 0.25000000 1 - Cr Cr12 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr13 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr14 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr16 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr18 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51893200 0.40191900 0.82033500 1 - O O33 1 0.82033500 0.51893200 0.40191900 1 - O O34 1 0.80140200 0.88298700 0.98106800 1 - O O35 1 0.41841500 0.09808100 0.61701300 1 - O O36 1 0.88298700 0.40191900 0.08158500 1 - O O37 1 0.67966500 0.08158500 0.69859800 1 - O O38 1 0.82033500 0.80140200 0.41841500 1 - O O39 1 0.40191900 0.82033500 0.51893200 1 - O O40 1 0.61701300 0.69859800 0.51893200 1 - O O41 1 0.41841500 0.82033500 0.80140200 1 - O O42 1 0.40191900 0.08158500 0.88298700 1 - O O43 1 0.09808100 0.98106800 0.67966500 1 - O O44 1 0.98106800 0.67966500 0.09808100 1 - O O45 1 0.80140200 0.41841500 0.82033500 1 - O O46 1 0.51893200 0.61701300 0.69859800 1 - O O47 1 0.69859800 0.51893200 0.61701300 1 - O O48 1 0.08158500 0.88298700 0.40191900 1 - O O49 1 0.98106800 0.80140200 0.88298700 1 - O O50 1 0.08158500 0.69859800 0.67966500 1 - O O51 1 0.38298700 0.30140200 0.48106800 1 - O O52 1 0.61701300 0.41841500 0.09808100 1 - O O53 1 0.09808100 0.61701300 0.41841500 1 - O O54 1 0.69859800 0.67966500 0.08158500 1 - O O55 1 0.67966500 0.09808100 0.98106800 1 - O O56 1 0.48106800 0.59808100 0.17966500 1 - O O57 1 0.17966500 0.48106800 0.59808100 1 - O O58 1 0.19859800 0.11701300 0.01893200 1 - O O59 1 0.58158500 0.90191900 0.38298700 1 - O O60 1 0.11701300 0.59808100 0.91841500 1 - O O61 1 0.32033500 0.91841500 0.30140200 1 - O O62 1 0.17966500 0.19859800 0.58158500 1 - O O63 1 0.59808100 0.17966500 0.48106800 1 - O O64 1 0.32033500 0.90191900 0.01893200 1 - O O65 1 0.30140200 0.32033500 0.91841500 1 - O O66 1 0.90191900 0.38298700 0.58158500 1 - O O67 1 0.11701300 0.01893200 0.19859800 1 - O O68 1 0.38298700 0.58158500 0.90191900 1 - O O69 1 0.91841500 0.30140200 0.32033500 1 - O O70 1 0.01893200 0.19859800 0.11701300 1 - O O71 1 0.91841500 0.11701300 0.59808100 1 - O O72 1 0.30140200 0.48106800 0.38298700 1 - O O73 1 0.48106800 0.38298700 0.30140200 1 - O O74 1 0.19859800 0.58158500 0.17966500 1 - O O75 1 0.01893200 0.32033500 0.90191900 1 - O O76 1 0.90191900 0.01893200 0.32033500 1 - O O77 1 0.59808100 0.91841500 0.11701300 1 - O O78 1 0.58158500 0.17966500 0.19859800 1 - O O79 1 0.88298700 0.98106800 0.80140200 1 -" -Li3Ti2(GeO4)3,mp-1013749,Ia-3d,[],0.08531258648055129,{'tags': ['Substituion']},"Full Formula (Li12 Ti8 Ge12 O48) -Reduced Formula: Li3Ti2(GeO4)3 -abc : 10.548279 10.548279 10.548279 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.625 0.875 -0.001 - 1 Li 0.25 0.875 0.625 -0.001 - 2 Li 0.625 0.25 0.875 -0.001 - 3 Li 0.875 0.75 0.625 -0.001 - 4 Li 0.875 0.625 0.25 -0.001 - 5 Li 0.625 0.875 0.75 -0.001 - 6 Li 0.25 0.375 0.125 -0.001 - 7 Li 0.75 0.125 0.375 -0.001 - 8 Li 0.375 0.75 0.125 -0.001 - 9 Li 0.125 0.25 0.375 -0.001 - 10 Li 0.125 0.375 0.75 -0.001 - 11 Li 0.375 0.125 0.25 -0.001 - 12 Ti 0.5 0 0.5 -0.026 - 13 Ti 0 0.5 0 -0.026 - 14 Ti 0.5 0.5 0.5 -0.026 - 15 Ti 0 0 0.5 -0.026 - 16 Ti 0 0 0 -0.026 - 17 Ti 0 0.5 0.5 -0.026 - 18 Ti 0.5 0.5 0 -0.026 - 19 Ti 0.5 0 0 -0.026 - 20 Ge 0.375 0.625 0.75 -0.005 - 21 Ge 0.625 0.375 0.25 -0.005 - 22 Ge 0.625 0.75 0.375 -0.005 - 23 Ge 0.25 0.125 0.875 -0.005 - 24 Ge 0.875 0.25 0.125 -0.005 - 25 Ge 0.75 0.375 0.625 -0.005 - 26 Ge 0.25 0.625 0.375 -0.005 - 27 Ge 0.75 0.875 0.125 -0.005 - 28 Ge 0.125 0.75 0.875 -0.005 - 29 Ge 0.375 0.25 0.625 -0.005 - 30 Ge 0.875 0.125 0.75 -0.005 - 31 Ge 0.125 0.875 0.25 -0.005 - 32 O 0.517515 0.399966 0.817851 0.075 - 33 O 0.817851 0.517515 0.399966 0.075 - 34 O 0.800336 0.882451 0.982485 0.075 - 35 O 0.417885 0.100034 0.617549 0.075 - 36 O 0.882451 0.399966 0.082115 0.075 - 37 O 0.682149 0.082115 0.699664 0.075 - 38 O 0.817851 0.800336 0.417885 0.075 - 39 O 0.399966 0.817851 0.517515 0.075 - 40 O 0.617549 0.699664 0.517515 0.075 - 41 O 0.417885 0.817851 0.800336 0.075 - 42 O 0.399966 0.082115 0.882451 0.075 - 43 O 0.100034 0.982485 0.682149 0.075 - 44 O 0.982485 0.682149 0.100034 0.075 - 45 O 0.800336 0.417885 0.817851 0.075 - 46 O 0.517515 0.617549 0.699664 0.075 - 47 O 0.699664 0.517515 0.617549 0.075 - 48 O 0.082115 0.882451 0.399966 0.075 - 49 O 0.982485 0.800336 0.882451 0.075 - 50 O 0.082115 0.699664 0.682149 0.075 - 51 O 0.382451 0.300336 0.482485 0.075 - 52 O 0.617549 0.417885 0.100034 0.075 - 53 O 0.100034 0.617549 0.417885 0.075 - 54 O 0.699664 0.682149 0.082115 0.075 - 55 O 0.682149 0.100034 0.982485 0.075 - 56 O 0.482485 0.600034 0.182149 0.075 - 57 O 0.182149 0.482485 0.600034 0.075 - 58 O 0.199664 0.117549 0.017515 0.075 - 59 O 0.582115 0.899966 0.382451 0.075 - 60 O 0.117549 0.600034 0.917885 0.075 - 61 O 0.317851 0.917885 0.300336 0.075 - 62 O 0.182149 0.199664 0.582115 0.075 - 63 O 0.600034 0.182149 0.482485 0.075 - 64 O 0.317851 0.899966 0.017515 0.075 - 65 O 0.300336 0.317851 0.917885 0.075 - 66 O 0.899966 0.382451 0.582115 0.075 - 67 O 0.117549 0.017515 0.199664 0.075 - 68 O 0.382451 0.582115 0.899966 0.075 - 69 O 0.917885 0.300336 0.317851 0.075 - 70 O 0.017515 0.199664 0.117549 0.075 - 71 O 0.917885 0.117549 0.600034 0.075 - 72 O 0.300336 0.482485 0.382451 0.075 - 73 O 0.482485 0.382451 0.300336 0.075 - 74 O 0.199664 0.582115 0.182149 0.075 - 75 O 0.017515 0.317851 0.899966 0.075 - 76 O 0.899966 0.017515 0.317851 0.075 - 77 O 0.600034 0.917885 0.117549 0.075 - 78 O 0.582115 0.182149 0.199664 0.075 - 79 O 0.882451 0.982485 0.800336 0.075","# generated using pymatgen -data_Li3Ti2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.54827948 -_cell_length_b 10.54827948 -_cell_length_c 10.54827948 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Ti2(GeO4)3 -_chemical_formula_sum 'Li12 Ti8 Ge12 O48' -_cell_volume 903.48925917 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.62500000 0.87500000 1 - Li Li1 1 0.25000000 0.87500000 0.62500000 1 - Li Li2 1 0.62500000 0.25000000 0.87500000 1 - Li Li3 1 0.87500000 0.75000000 0.62500000 1 - Li Li4 1 0.87500000 0.62500000 0.25000000 1 - Li Li5 1 0.62500000 0.87500000 0.75000000 1 - Li Li6 1 0.25000000 0.37500000 0.12500000 1 - Li Li7 1 0.75000000 0.12500000 0.37500000 1 - Li Li8 1 0.37500000 0.75000000 0.12500000 1 - Li Li9 1 0.12500000 0.25000000 0.37500000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.37500000 0.12500000 0.25000000 1 - Ti Ti12 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti13 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti14 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti15 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti16 1 0.00000000 0.00000000 0.00000000 1 - Ti Ti17 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti18 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51751500 0.39996600 0.81785100 1 - O O33 1 0.81785100 0.51751500 0.39996600 1 - O O34 1 0.80033600 0.88245100 0.98248500 1 - O O35 1 0.41788500 0.10003400 0.61754900 1 - O O36 1 0.88245100 0.39996600 0.08211500 1 - O O37 1 0.68214900 0.08211500 0.69966400 1 - O O38 1 0.81785100 0.80033600 0.41788500 1 - O O39 1 0.39996600 0.81785100 0.51751500 1 - O O40 1 0.61754900 0.69966400 0.51751500 1 - O O41 1 0.41788500 0.81785100 0.80033600 1 - O O42 1 0.39996600 0.08211500 0.88245100 1 - O O43 1 0.10003400 0.98248500 0.68214900 1 - O O44 1 0.98248500 0.68214900 0.10003400 1 - O O45 1 0.80033600 0.41788500 0.81785100 1 - O O46 1 0.51751500 0.61754900 0.69966400 1 - O O47 1 0.69966400 0.51751500 0.61754900 1 - O O48 1 0.08211500 0.88245100 0.39996600 1 - O O49 1 0.98248500 0.80033600 0.88245100 1 - O O50 1 0.08211500 0.69966400 0.68214900 1 - O O51 1 0.38245100 0.30033600 0.48248500 1 - O O52 1 0.61754900 0.41788500 0.10003400 1 - O O53 1 0.10003400 0.61754900 0.41788500 1 - O O54 1 0.69966400 0.68214900 0.08211500 1 - O O55 1 0.68214900 0.10003400 0.98248500 1 - O O56 1 0.48248500 0.60003400 0.18214900 1 - O O57 1 0.18214900 0.48248500 0.60003400 1 - O O58 1 0.19966400 0.11754900 0.01751500 1 - O O59 1 0.58211500 0.89996600 0.38245100 1 - O O60 1 0.11754900 0.60003400 0.91788500 1 - O O61 1 0.31785100 0.91788500 0.30033600 1 - O O62 1 0.18214900 0.19966400 0.58211500 1 - O O63 1 0.60003400 0.18214900 0.48248500 1 - O O64 1 0.31785100 0.89996600 0.01751500 1 - O O65 1 0.30033600 0.31785100 0.91788500 1 - O O66 1 0.89996600 0.38245100 0.58211500 1 - O O67 1 0.11754900 0.01751500 0.19966400 1 - O O68 1 0.38245100 0.58211500 0.89996600 1 - O O69 1 0.91788500 0.30033600 0.31785100 1 - O O70 1 0.01751500 0.19966400 0.11754900 1 - O O71 1 0.91788500 0.11754900 0.60003400 1 - O O72 1 0.30033600 0.48248500 0.38245100 1 - O O73 1 0.48248500 0.38245100 0.30033600 1 - O O74 1 0.19966400 0.58211500 0.18214900 1 - O O75 1 0.01751500 0.31785100 0.89996600 1 - O O76 1 0.89996600 0.01751500 0.31785100 1 - O O77 1 0.60003400 0.91788500 0.11754900 1 - O O78 1 0.58211500 0.18214900 0.19966400 1 - O O79 1 0.88245100 0.98248500 0.80033600 1 -" -Na3Co2(GeO4)3,mp-1013794,Ia-3d,[],0.1411694620059487,{'tags': []},"Full Formula (Na12 Co8 Ge12 O48) -Reduced Formula: Na3Co2(GeO4)3 -abc : 10.502195 10.502195 10.502195 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.75 0.625 0.875 0.002 - 1 Na 0.25 0.875 0.625 0.002 - 2 Na 0.625 0.25 0.875 0.002 - 3 Na 0.875 0.75 0.625 0.002 - 4 Na 0.875 0.625 0.25 0.002 - 5 Na 0.625 0.875 0.75 0.002 - 6 Na 0.25 0.375 0.125 0.002 - 7 Na 0.75 0.125 0.375 0.002 - 8 Na 0.375 0.75 0.125 0.002 - 9 Na 0.125 0.25 0.375 0.002 - 10 Na 0.125 0.375 0.75 0.002 - 11 Na 0.375 0.125 0.25 0.002 - 12 Co 0.5 0 0.5 1.062 - 13 Co 0 0.5 0 1.062 - 14 Co 0.5 0.5 0.5 1.062 - 15 Co 0 0 0.5 1.062 - 16 Co 0 0 0 1.062 - 17 Co 0 0.5 0.5 1.062 - 18 Co 0.5 0.5 0 1.062 - 19 Co 0.5 0 0 1.062 - 20 Ge 0.375 0.625 0.75 -0.004 - 21 Ge 0.625 0.375 0.25 -0.004 - 22 Ge 0.625 0.75 0.375 -0.004 - 23 Ge 0.25 0.125 0.875 -0.004 - 24 Ge 0.875 0.25 0.125 -0.004 - 25 Ge 0.75 0.375 0.625 -0.004 - 26 Ge 0.25 0.625 0.375 -0.004 - 27 Ge 0.75 0.875 0.125 -0.004 - 28 Ge 0.125 0.75 0.875 -0.004 - 29 Ge 0.375 0.25 0.625 -0.004 - 30 Ge 0.875 0.125 0.75 -0.004 - 31 Ge 0.125 0.875 0.25 -0.004 - 32 O 0.5146 0.403228 0.821704 0.059 - 33 O 0.821704 0.5146 0.403228 0.059 - 34 O 0.807104 0.888628 0.9854 0.059 - 35 O 0.418476 0.096772 0.611372 0.059 - 36 O 0.888628 0.403228 0.081524 0.059 - 37 O 0.678296 0.081524 0.692896 0.059 - 38 O 0.821704 0.807104 0.418476 0.059 - 39 O 0.403228 0.821704 0.5146 0.059 - 40 O 0.611372 0.692896 0.5146 0.059 - 41 O 0.418476 0.821704 0.807104 0.059 - 42 O 0.403228 0.081524 0.888628 0.059 - 43 O 0.096772 0.9854 0.678296 0.059 - 44 O 0.9854 0.678296 0.096772 0.059 - 45 O 0.807104 0.418476 0.821704 0.059 - 46 O 0.5146 0.611372 0.692896 0.059 - 47 O 0.692896 0.5146 0.611372 0.059 - 48 O 0.081524 0.888628 0.403228 0.059 - 49 O 0.9854 0.807104 0.888628 0.059 - 50 O 0.081524 0.692896 0.678296 0.059 - 51 O 0.388628 0.307104 0.4854 0.059 - 52 O 0.611372 0.418476 0.096772 0.059 - 53 O 0.096772 0.611372 0.418476 0.059 - 54 O 0.692896 0.678296 0.081524 0.059 - 55 O 0.678296 0.096772 0.9854 0.059 - 56 O 0.4854 0.596772 0.178296 0.059 - 57 O 0.178296 0.4854 0.596772 0.059 - 58 O 0.192896 0.111372 0.0146 0.059 - 59 O 0.581524 0.903228 0.388628 0.059 - 60 O 0.111372 0.596772 0.918476 0.059 - 61 O 0.321704 0.918476 0.307104 0.059 - 62 O 0.178296 0.192896 0.581524 0.059 - 63 O 0.596772 0.178296 0.4854 0.059 - 64 O 0.321704 0.903228 0.0146 0.059 - 65 O 0.307104 0.321704 0.918476 0.059 - 66 O 0.903228 0.388628 0.581524 0.059 - 67 O 0.111372 0.0146 0.192896 0.059 - 68 O 0.388628 0.581524 0.903228 0.059 - 69 O 0.918476 0.307104 0.321704 0.059 - 70 O 0.0146 0.192896 0.111372 0.059 - 71 O 0.918476 0.111372 0.596772 0.059 - 72 O 0.307104 0.4854 0.388628 0.059 - 73 O 0.4854 0.388628 0.307104 0.059 - 74 O 0.192896 0.581524 0.178296 0.059 - 75 O 0.0146 0.321704 0.903228 0.059 - 76 O 0.903228 0.0146 0.321704 0.059 - 77 O 0.596772 0.918476 0.111372 0.059 - 78 O 0.581524 0.178296 0.192896 0.059 - 79 O 0.888628 0.9854 0.807104 0.059","# generated using pymatgen -data_Na3Co2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.50219481 -_cell_length_b 10.50219481 -_cell_length_c 10.50219481 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Co2(GeO4)3 -_chemical_formula_sum 'Na12 Co8 Ge12 O48' -_cell_volume 891.69908083 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.75000000 0.62500000 0.87500000 1 - Na Na1 1 0.25000000 0.87500000 0.62500000 1 - Na Na2 1 0.62500000 0.25000000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.87500000 0.62500000 0.25000000 1 - Na Na5 1 0.62500000 0.87500000 0.75000000 1 - Na Na6 1 0.25000000 0.37500000 0.12500000 1 - Na Na7 1 0.75000000 0.12500000 0.37500000 1 - Na Na8 1 0.37500000 0.75000000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Co Co12 1 0.50000000 0.00000000 0.50000000 1 - Co Co13 1 0.00000000 0.50000000 0.00000000 1 - Co Co14 1 0.50000000 0.50000000 0.50000000 1 - Co Co15 1 0.00000000 0.00000000 0.50000000 1 - Co Co16 1 0.00000000 0.00000000 0.00000000 1 - Co Co17 1 0.00000000 0.50000000 0.50000000 1 - Co Co18 1 0.50000000 0.50000000 0.00000000 1 - Co Co19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51460000 0.40322800 0.82170400 1 - O O33 1 0.82170400 0.51460000 0.40322800 1 - O O34 1 0.80710400 0.88862800 0.98540000 1 - O O35 1 0.41847600 0.09677200 0.61137200 1 - O O36 1 0.88862800 0.40322800 0.08152400 1 - O O37 1 0.67829600 0.08152400 0.69289600 1 - O O38 1 0.82170400 0.80710400 0.41847600 1 - O O39 1 0.40322800 0.82170400 0.51460000 1 - O O40 1 0.61137200 0.69289600 0.51460000 1 - O O41 1 0.41847600 0.82170400 0.80710400 1 - O O42 1 0.40322800 0.08152400 0.88862800 1 - O O43 1 0.09677200 0.98540000 0.67829600 1 - O O44 1 0.98540000 0.67829600 0.09677200 1 - O O45 1 0.80710400 0.41847600 0.82170400 1 - O O46 1 0.51460000 0.61137200 0.69289600 1 - O O47 1 0.69289600 0.51460000 0.61137200 1 - O O48 1 0.08152400 0.88862800 0.40322800 1 - O O49 1 0.98540000 0.80710400 0.88862800 1 - O O50 1 0.08152400 0.69289600 0.67829600 1 - O O51 1 0.38862800 0.30710400 0.48540000 1 - O O52 1 0.61137200 0.41847600 0.09677200 1 - O O53 1 0.09677200 0.61137200 0.41847600 1 - O O54 1 0.69289600 0.67829600 0.08152400 1 - O O55 1 0.67829600 0.09677200 0.98540000 1 - O O56 1 0.48540000 0.59677200 0.17829600 1 - O O57 1 0.17829600 0.48540000 0.59677200 1 - O O58 1 0.19289600 0.11137200 0.01460000 1 - O O59 1 0.58152400 0.90322800 0.38862800 1 - O O60 1 0.11137200 0.59677200 0.91847600 1 - O O61 1 0.32170400 0.91847600 0.30710400 1 - O O62 1 0.17829600 0.19289600 0.58152400 1 - O O63 1 0.59677200 0.17829600 0.48540000 1 - O O64 1 0.32170400 0.90322800 0.01460000 1 - O O65 1 0.30710400 0.32170400 0.91847600 1 - O O66 1 0.90322800 0.38862800 0.58152400 1 - O O67 1 0.11137200 0.01460000 0.19289600 1 - O O68 1 0.38862800 0.58152400 0.90322800 1 - O O69 1 0.91847600 0.30710400 0.32170400 1 - O O70 1 0.01460000 0.19289600 0.11137200 1 - O O71 1 0.91847600 0.11137200 0.59677200 1 - O O72 1 0.30710400 0.48540000 0.38862800 1 - O O73 1 0.48540000 0.38862800 0.30710400 1 - O O74 1 0.19289600 0.58152400 0.17829600 1 - O O75 1 0.01460000 0.32170400 0.90322800 1 - O O76 1 0.90322800 0.01460000 0.32170400 1 - O O77 1 0.59677200 0.91847600 0.11137200 1 - O O78 1 0.58152400 0.17829600 0.19289600 1 - O O79 1 0.88862800 0.98540000 0.80710400 1 -" -Li3Ge3(MoO6)2,mp-1013795,Ia-3d,[],0.08171873832637466,{'tags': []},"Full Formula (Li12 Ge12 Mo8 O48) -Reduced Formula: Li3Ge3(MoO6)2 -abc : 10.718966 10.718966 10.718966 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.625 0.875 0.002 - 1 Li 0.25 0.875 0.625 0.002 - 2 Li 0.625 0.25 0.875 0.001 - 3 Li 0.875 0.75 0.625 0.001 - 4 Li 0.875 0.625 0.25 0.001 - 5 Li 0.625 0.875 0.75 0.001 - 6 Li 0.25 0.375 0.125 0.002 - 7 Li 0.75 0.125 0.375 0.002 - 8 Li 0.375 0.75 0.125 0.001 - 9 Li 0.125 0.25 0.375 0.001 - 10 Li 0.125 0.375 0.75 0.001 - 11 Li 0.375 0.125 0.25 0.001 - 12 Ge 0.375 0.625 0.75 0.026 - 13 Ge 0.625 0.375 0.25 0.026 - 14 Ge 0.625 0.75 0.375 0.028 - 15 Ge 0.25 0.125 0.875 0.025 - 16 Ge 0.875 0.25 0.125 0.026 - 17 Ge 0.75 0.375 0.625 0.025 - 18 Ge 0.25 0.625 0.375 0.025 - 19 Ge 0.75 0.875 0.125 0.025 - 20 Ge 0.125 0.75 0.875 0.026 - 21 Ge 0.375 0.25 0.625 0.028 - 22 Ge 0.875 0.125 0.75 0.028 - 23 Ge 0.125 0.875 0.25 0.028 - 24 Mo 0.5 0 0.5 1.802 - 25 Mo 0 0.5 0 1.086 - 26 Mo 0.5 0.5 0.5 1.801 - 27 Mo 0 0 0.5 1.802 - 28 Mo 0 0 0 1.801 - 29 Mo 0 0.5 0.5 1.093 - 30 Mo 0.5 0.5 0 1.086 - 31 Mo 0.5 0 0 1.093 - 32 O 0.516748 0.398067 0.814674 -0.011 - 33 O 0.814674 0.516748 0.398067 -0.007 - 34 O 0.797926 0.881318 0.983252 0.002 - 35 O 0.416608 0.101933 0.618682 -0.005 - 36 O 0.881318 0.398067 0.083392 -0.001 - 37 O 0.685326 0.083392 0.702074 -0.001 - 38 O 0.814674 0.797926 0.416608 -0.001 - 39 O 0.398067 0.814674 0.516748 0.014 - 40 O 0.618682 0.702074 0.516748 -0.01 - 41 O 0.416608 0.814674 0.797926 -0.002 - 42 O 0.398067 0.083392 0.881318 -0.008 - 43 O 0.101933 0.983252 0.685326 0.015 - 44 O 0.983252 0.685326 0.101933 -0.011 - 45 O 0.797926 0.416608 0.814674 -0.009 - 46 O 0.516748 0.618682 0.702074 0.01 - 47 O 0.702074 0.516748 0.618682 0.002 - 48 O 0.083392 0.881318 0.398067 -0.005 - 49 O 0.983252 0.797926 0.881318 0.01 - 50 O 0.083392 0.702074 0.685326 -0.002 - 51 O 0.381318 0.297926 0.483252 -0.01 - 52 O 0.618682 0.416608 0.101933 -0.001 - 53 O 0.101933 0.618682 0.416608 -0.008 - 54 O 0.702074 0.685326 0.083392 -0.009 - 55 O 0.685326 0.101933 0.983252 -0.007 - 56 O 0.483252 0.601933 0.185326 -0.011 - 57 O 0.185326 0.483252 0.601933 -0.007 - 58 O 0.202074 0.118682 0.016748 0.002 - 59 O 0.583392 0.898067 0.381318 -0.005 - 60 O 0.118682 0.601933 0.916608 -0.001 - 61 O 0.314674 0.916608 0.297926 -0.001 - 62 O 0.185326 0.202074 0.583392 -0.001 - 63 O 0.601933 0.185326 0.483252 0.014 - 64 O 0.314674 0.898067 0.016748 -0.007 - 65 O 0.297926 0.314674 0.916608 -0.009 - 66 O 0.898067 0.381318 0.583392 -0.008 - 67 O 0.118682 0.016748 0.202074 -0.01 - 68 O 0.381318 0.583392 0.898067 -0.001 - 69 O 0.916608 0.297926 0.314674 -0.002 - 70 O 0.016748 0.202074 0.118682 0.01 - 71 O 0.916608 0.118682 0.601933 -0.005 - 72 O 0.297926 0.483252 0.381318 0.002 - 73 O 0.483252 0.381318 0.297926 0.01 - 74 O 0.202074 0.583392 0.185326 -0.009 - 75 O 0.016748 0.314674 0.898067 -0.011 - 76 O 0.898067 0.016748 0.314674 0.015 - 77 O 0.601933 0.916608 0.118682 -0.008 - 78 O 0.583392 0.185326 0.202074 -0.002 - 79 O 0.881318 0.983252 0.797926 -0.01","# generated using pymatgen -data_Li3Ge3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.71896616 -_cell_length_b 10.71896616 -_cell_length_c 10.71896616 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Ge3(MoO6)2 -_chemical_formula_sum 'Li12 Ge12 Mo8 O48' -_cell_volume 948.06215193 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.62500000 0.87500000 1 - Li Li1 1 0.25000000 0.87500000 0.62500000 1 - Li Li2 1 0.62500000 0.25000000 0.87500000 1 - Li Li3 1 0.87500000 0.75000000 0.62500000 1 - Li Li4 1 0.87500000 0.62500000 0.25000000 1 - Li Li5 1 0.62500000 0.87500000 0.75000000 1 - Li Li6 1 0.25000000 0.37500000 0.12500000 1 - Li Li7 1 0.75000000 0.12500000 0.37500000 1 - Li Li8 1 0.37500000 0.75000000 0.12500000 1 - Li Li9 1 0.12500000 0.25000000 0.37500000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.37500000 0.12500000 0.25000000 1 - Ge Ge12 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge13 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge14 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge15 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge16 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge17 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge18 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge19 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge22 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge23 1 0.12500000 0.87500000 0.25000000 1 - Mo Mo24 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo25 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo26 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo27 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo28 1 0.00000000 0.00000000 0.00000000 1 - Mo Mo29 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo30 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.51674800 0.39806700 0.81467400 1 - O O33 1 0.81467400 0.51674800 0.39806700 1 - O O34 1 0.79792600 0.88131800 0.98325200 1 - O O35 1 0.41660800 0.10193300 0.61868200 1 - O O36 1 0.88131800 0.39806700 0.08339200 1 - O O37 1 0.68532600 0.08339200 0.70207400 1 - O O38 1 0.81467400 0.79792600 0.41660800 1 - O O39 1 0.39806700 0.81467400 0.51674800 1 - O O40 1 0.61868200 0.70207400 0.51674800 1 - O O41 1 0.41660800 0.81467400 0.79792600 1 - O O42 1 0.39806700 0.08339200 0.88131800 1 - O O43 1 0.10193300 0.98325200 0.68532600 1 - O O44 1 0.98325200 0.68532600 0.10193300 1 - O O45 1 0.79792600 0.41660800 0.81467400 1 - O O46 1 0.51674800 0.61868200 0.70207400 1 - O O47 1 0.70207400 0.51674800 0.61868200 1 - O O48 1 0.08339200 0.88131800 0.39806700 1 - O O49 1 0.98325200 0.79792600 0.88131800 1 - O O50 1 0.08339200 0.70207400 0.68532600 1 - O O51 1 0.38131800 0.29792600 0.48325200 1 - O O52 1 0.61868200 0.41660800 0.10193300 1 - O O53 1 0.10193300 0.61868200 0.41660800 1 - O O54 1 0.70207400 0.68532600 0.08339200 1 - O O55 1 0.68532600 0.10193300 0.98325200 1 - O O56 1 0.48325200 0.60193300 0.18532600 1 - O O57 1 0.18532600 0.48325200 0.60193300 1 - O O58 1 0.20207400 0.11868200 0.01674800 1 - O O59 1 0.58339200 0.89806700 0.38131800 1 - O O60 1 0.11868200 0.60193300 0.91660800 1 - O O61 1 0.31467400 0.91660800 0.29792600 1 - O O62 1 0.18532600 0.20207400 0.58339200 1 - O O63 1 0.60193300 0.18532600 0.48325200 1 - O O64 1 0.31467400 0.89806700 0.01674800 1 - O O65 1 0.29792600 0.31467400 0.91660800 1 - O O66 1 0.89806700 0.38131800 0.58339200 1 - O O67 1 0.11868200 0.01674800 0.20207400 1 - O O68 1 0.38131800 0.58339200 0.89806700 1 - O O69 1 0.91660800 0.29792600 0.31467400 1 - O O70 1 0.01674800 0.20207400 0.11868200 1 - O O71 1 0.91660800 0.11868200 0.60193300 1 - O O72 1 0.29792600 0.48325200 0.38131800 1 - O O73 1 0.48325200 0.38131800 0.29792600 1 - O O74 1 0.20207400 0.58339200 0.18532600 1 - O O75 1 0.01674800 0.31467400 0.89806700 1 - O O76 1 0.89806700 0.01674800 0.31467400 1 - O O77 1 0.60193300 0.91660800 0.11868200 1 - O O78 1 0.58339200 0.18532600 0.20207400 1 - O O79 1 0.88131800 0.98325200 0.79792600 1 -" -Li3Ni2(GeO4)3,mp-1013796,Ia-3d,[],0.20592570913888864,{'tags': []},"Full Formula (Li12 Ni8 Ge12 O48) -Reduced Formula: Li3Ni2(GeO4)3 -abc : 10.263496 10.263496 10.263496 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.625 0.875 0.003 - 1 Li 0.25 0.875 0.625 0.003 - 2 Li 0.625 0.25 0.875 0.003 - 3 Li 0.875 0.75 0.625 0.003 - 4 Li 0.875 0.625 0.25 0.003 - 5 Li 0.625 0.875 0.75 0.003 - 6 Li 0.25 0.375 0.125 0.003 - 7 Li 0.75 0.125 0.375 0.003 - 8 Li 0.375 0.75 0.125 0.003 - 9 Li 0.125 0.25 0.375 0.003 - 10 Li 0.125 0.375 0.75 0.003 - 11 Li 0.375 0.125 0.25 0.003 - 12 Ni 0.5 0 0.5 0.536 - 13 Ni 0 0.5 0 0.536 - 14 Ni 0.5 0.5 0.5 0.536 - 15 Ni 0 0 0.5 0.536 - 16 Ni 0 0 0 0.536 - 17 Ni 0 0.5 0.5 0.536 - 18 Ni 0.5 0.5 0 0.536 - 19 Ni 0.5 0 0 0.536 - 20 Ge 0.375 0.625 0.75 0.014 - 21 Ge 0.625 0.375 0.25 0.014 - 22 Ge 0.625 0.75 0.375 0.014 - 23 Ge 0.25 0.125 0.875 0.014 - 24 Ge 0.875 0.25 0.125 0.014 - 25 Ge 0.75 0.375 0.625 0.014 - 26 Ge 0.25 0.625 0.375 0.014 - 27 Ge 0.75 0.875 0.125 0.014 - 28 Ge 0.125 0.75 0.875 0.014 - 29 Ge 0.375 0.25 0.625 0.014 - 30 Ge 0.875 0.125 0.75 0.014 - 31 Ge 0.125 0.875 0.25 0.014 - 32 O 0.522983 0.403709 0.824217 -0.151 - 33 O 0.824217 0.522983 0.403709 -0.151 - 34 O 0.801234 0.880726 0.977017 -0.151 - 35 O 0.420508 0.096291 0.619274 -0.151 - 36 O 0.880726 0.403709 0.079492 -0.151 - 37 O 0.675783 0.079492 0.698766 -0.151 - 38 O 0.824217 0.801234 0.420508 -0.151 - 39 O 0.403709 0.824217 0.522983 -0.151 - 40 O 0.619274 0.698766 0.522983 -0.151 - 41 O 0.420508 0.824217 0.801234 -0.151 - 42 O 0.403709 0.079492 0.880726 -0.151 - 43 O 0.096291 0.977017 0.675783 -0.151 - 44 O 0.977017 0.675783 0.096291 -0.151 - 45 O 0.801234 0.420508 0.824217 -0.151 - 46 O 0.522983 0.619274 0.698766 -0.151 - 47 O 0.698766 0.522983 0.619274 -0.151 - 48 O 0.079492 0.880726 0.403709 -0.151 - 49 O 0.977017 0.801234 0.880726 -0.151 - 50 O 0.079492 0.698766 0.675783 -0.151 - 51 O 0.380726 0.301234 0.477017 -0.151 - 52 O 0.619274 0.420508 0.096291 -0.151 - 53 O 0.096291 0.619274 0.420508 -0.151 - 54 O 0.698766 0.675783 0.079492 -0.151 - 55 O 0.675783 0.096291 0.977017 -0.151 - 56 O 0.477017 0.596291 0.175783 -0.151 - 57 O 0.175783 0.477017 0.596291 -0.151 - 58 O 0.198766 0.119274 0.022983 -0.151 - 59 O 0.579492 0.903709 0.380726 -0.151 - 60 O 0.119274 0.596291 0.920508 -0.151 - 61 O 0.324217 0.920508 0.301234 -0.151 - 62 O 0.175783 0.198766 0.579492 -0.151 - 63 O 0.596291 0.175783 0.477017 -0.151 - 64 O 0.324217 0.903709 0.022983 -0.151 - 65 O 0.301234 0.324217 0.920508 -0.151 - 66 O 0.903709 0.380726 0.579492 -0.151 - 67 O 0.119274 0.022983 0.198766 -0.151 - 68 O 0.380726 0.579492 0.903709 -0.151 - 69 O 0.920508 0.301234 0.324217 -0.151 - 70 O 0.022983 0.198766 0.119274 -0.151 - 71 O 0.920508 0.119274 0.596291 -0.151 - 72 O 0.301234 0.477017 0.380726 -0.151 - 73 O 0.477017 0.380726 0.301234 -0.151 - 74 O 0.198766 0.579492 0.175783 -0.151 - 75 O 0.022983 0.324217 0.903709 -0.151 - 76 O 0.903709 0.022983 0.324217 -0.151 - 77 O 0.596291 0.920508 0.119274 -0.151 - 78 O 0.579492 0.175783 0.198766 -0.151 - 79 O 0.880726 0.977017 0.801234 -0.151","# generated using pymatgen -data_Li3Ni2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.26349569 -_cell_length_b 10.26349569 -_cell_length_c 10.26349569 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Ni2(GeO4)3 -_chemical_formula_sum 'Li12 Ni8 Ge12 O48' -_cell_volume 832.26958196 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.62500000 0.87500000 1 - Li Li1 1 0.25000000 0.87500000 0.62500000 1 - Li Li2 1 0.62500000 0.25000000 0.87500000 1 - Li Li3 1 0.87500000 0.75000000 0.62500000 1 - Li Li4 1 0.87500000 0.62500000 0.25000000 1 - Li Li5 1 0.62500000 0.87500000 0.75000000 1 - Li Li6 1 0.25000000 0.37500000 0.12500000 1 - Li Li7 1 0.75000000 0.12500000 0.37500000 1 - Li Li8 1 0.37500000 0.75000000 0.12500000 1 - Li Li9 1 0.12500000 0.25000000 0.37500000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.37500000 0.12500000 0.25000000 1 - Ni Ni12 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni13 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni14 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni15 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni16 1 0.00000000 0.00000000 0.00000000 1 - Ni Ni17 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni18 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.52298300 0.40370900 0.82421700 1 - O O33 1 0.82421700 0.52298300 0.40370900 1 - O O34 1 0.80123400 0.88072600 0.97701700 1 - O O35 1 0.42050800 0.09629100 0.61927400 1 - O O36 1 0.88072600 0.40370900 0.07949200 1 - O O37 1 0.67578300 0.07949200 0.69876600 1 - O O38 1 0.82421700 0.80123400 0.42050800 1 - O O39 1 0.40370900 0.82421700 0.52298300 1 - O O40 1 0.61927400 0.69876600 0.52298300 1 - O O41 1 0.42050800 0.82421700 0.80123400 1 - O O42 1 0.40370900 0.07949200 0.88072600 1 - O O43 1 0.09629100 0.97701700 0.67578300 1 - O O44 1 0.97701700 0.67578300 0.09629100 1 - O O45 1 0.80123400 0.42050800 0.82421700 1 - O O46 1 0.52298300 0.61927400 0.69876600 1 - O O47 1 0.69876600 0.52298300 0.61927400 1 - O O48 1 0.07949200 0.88072600 0.40370900 1 - O O49 1 0.97701700 0.80123400 0.88072600 1 - O O50 1 0.07949200 0.69876600 0.67578300 1 - O O51 1 0.38072600 0.30123400 0.47701700 1 - O O52 1 0.61927400 0.42050800 0.09629100 1 - O O53 1 0.09629100 0.61927400 0.42050800 1 - O O54 1 0.69876600 0.67578300 0.07949200 1 - O O55 1 0.67578300 0.09629100 0.97701700 1 - O O56 1 0.47701700 0.59629100 0.17578300 1 - O O57 1 0.17578300 0.47701700 0.59629100 1 - O O58 1 0.19876600 0.11927400 0.02298300 1 - O O59 1 0.57949200 0.90370900 0.38072600 1 - O O60 1 0.11927400 0.59629100 0.92050800 1 - O O61 1 0.32421700 0.92050800 0.30123400 1 - O O62 1 0.17578300 0.19876600 0.57949200 1 - O O63 1 0.59629100 0.17578300 0.47701700 1 - O O64 1 0.32421700 0.90370900 0.02298300 1 - O O65 1 0.30123400 0.32421700 0.92050800 1 - O O66 1 0.90370900 0.38072600 0.57949200 1 - O O67 1 0.11927400 0.02298300 0.19876600 1 - O O68 1 0.38072600 0.57949200 0.90370900 1 - O O69 1 0.92050800 0.30123400 0.32421700 1 - O O70 1 0.02298300 0.19876600 0.11927400 1 - O O71 1 0.92050800 0.11927400 0.59629100 1 - O O72 1 0.30123400 0.47701700 0.38072600 1 - O O73 1 0.47701700 0.38072600 0.30123400 1 - O O74 1 0.19876600 0.57949200 0.17578300 1 - O O75 1 0.02298300 0.32421700 0.90370900 1 - O O76 1 0.90370900 0.02298300 0.32421700 1 - O O77 1 0.59629100 0.92050800 0.11927400 1 - O O78 1 0.57949200 0.17578300 0.19876600 1 - O O79 1 0.88072600 0.97701700 0.80123400 1 -" -Na3Ge3(MoO6)2,mp-1013797,Ia-3d,[],0.05516567520535531,{'tags': []},"Full Formula (Na12 Ge12 Mo8 O48) -Reduced Formula: Na3Ge3(MoO6)2 -abc : 10.912436 10.912436 10.912436 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.75 0.625 0.875 0 - 1 Na 0.25 0.875 0.625 0 - 2 Na 0.625 0.25 0.875 0 - 3 Na 0.875 0.75 0.625 0 - 4 Na 0.875 0.625 0.25 0 - 5 Na 0.625 0.875 0.75 0 - 6 Na 0.25 0.375 0.125 0 - 7 Na 0.75 0.125 0.375 0 - 8 Na 0.375 0.75 0.125 0 - 9 Na 0.125 0.25 0.375 0 - 10 Na 0.125 0.375 0.75 0 - 11 Na 0.375 0.125 0.25 0 - 12 Ge 0.375 0.625 0.75 0.031 - 13 Ge 0.625 0.375 0.25 0.031 - 14 Ge 0.625 0.75 0.375 0.031 - 15 Ge 0.25 0.125 0.875 0.029 - 16 Ge 0.875 0.25 0.125 0.031 - 17 Ge 0.75 0.375 0.625 0.029 - 18 Ge 0.25 0.625 0.375 0.029 - 19 Ge 0.75 0.875 0.125 0.029 - 20 Ge 0.125 0.75 0.875 0.031 - 21 Ge 0.375 0.25 0.625 0.031 - 22 Ge 0.875 0.125 0.75 0.031 - 23 Ge 0.125 0.875 0.25 0.031 - 24 Mo 0.5 0 0.5 1.497 - 25 Mo 0 0.5 0 1.572 - 26 Mo 0.5 0.5 0.5 1.572 - 27 Mo 0 0 0.5 1.497 - 28 Mo 0 0 0 1.572 - 29 Mo 0 0.5 0.5 1.497 - 30 Mo 0.5 0.5 0 1.572 - 31 Mo 0.5 0 0 1.497 - 32 O 0.50956 0.394605 0.814159 -0.018 - 33 O 0.814159 0.50956 0.394605 -0.022 - 34 O 0.804599 0.885045 0.99044 -0.018 - 35 O 0.419554 0.105395 0.614955 -0.017 - 36 O 0.885045 0.394605 0.080446 -0.02 - 37 O 0.685841 0.080446 0.695401 -0.022 - 38 O 0.814159 0.804599 0.419554 -0.022 - 39 O 0.394605 0.814159 0.50956 -0.02 - 40 O 0.614955 0.695401 0.50956 -0.02 - 41 O 0.419554 0.814159 0.804599 -0.017 - 42 O 0.394605 0.080446 0.885045 -0.02 - 43 O 0.105395 0.99044 0.685841 -0.02 - 44 O 0.99044 0.685841 0.105395 -0.018 - 45 O 0.804599 0.419554 0.814159 -0.018 - 46 O 0.50956 0.614955 0.695401 -0.018 - 47 O 0.695401 0.50956 0.614955 -0.018 - 48 O 0.080446 0.885045 0.394605 -0.017 - 49 O 0.99044 0.804599 0.885045 -0.018 - 50 O 0.080446 0.695401 0.685841 -0.017 - 51 O 0.385045 0.304599 0.49044 -0.02 - 52 O 0.614955 0.419554 0.105395 -0.02 - 53 O 0.105395 0.614955 0.419554 -0.02 - 54 O 0.695401 0.685841 0.080446 -0.018 - 55 O 0.685841 0.105395 0.99044 -0.022 - 56 O 0.49044 0.605395 0.185841 -0.018 - 57 O 0.185841 0.49044 0.605395 -0.022 - 58 O 0.195401 0.114955 0.00956 -0.018 - 59 O 0.580446 0.894605 0.385045 -0.017 - 60 O 0.114955 0.605395 0.919554 -0.02 - 61 O 0.314159 0.919554 0.304599 -0.022 - 62 O 0.185841 0.195401 0.580446 -0.022 - 63 O 0.605395 0.185841 0.49044 -0.02 - 64 O 0.314159 0.894605 0.00956 -0.022 - 65 O 0.304599 0.314159 0.919554 -0.018 - 66 O 0.894605 0.385045 0.580446 -0.02 - 67 O 0.114955 0.00956 0.195401 -0.02 - 68 O 0.385045 0.580446 0.894605 -0.02 - 69 O 0.919554 0.304599 0.314159 -0.017 - 70 O 0.00956 0.195401 0.114955 -0.018 - 71 O 0.919554 0.114955 0.605395 -0.017 - 72 O 0.304599 0.49044 0.385045 -0.018 - 73 O 0.49044 0.385045 0.304599 -0.018 - 74 O 0.195401 0.580446 0.185841 -0.018 - 75 O 0.00956 0.314159 0.894605 -0.018 - 76 O 0.894605 0.00956 0.314159 -0.02 - 77 O 0.605395 0.919554 0.114955 -0.02 - 78 O 0.580446 0.185841 0.195401 -0.017 - 79 O 0.885045 0.99044 0.804599 -0.02","# generated using pymatgen -data_Na3Ge3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.91243624 -_cell_length_b 10.91243624 -_cell_length_c 10.91243624 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Ge3(MoO6)2 -_chemical_formula_sum 'Na12 Ge12 Mo8 O48' -_cell_volume 1000.32993815 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.75000000 0.62500000 0.87500000 1 - Na Na1 1 0.25000000 0.87500000 0.62500000 1 - Na Na2 1 0.62500000 0.25000000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.87500000 0.62500000 0.25000000 1 - Na Na5 1 0.62500000 0.87500000 0.75000000 1 - Na Na6 1 0.25000000 0.37500000 0.12500000 1 - Na Na7 1 0.75000000 0.12500000 0.37500000 1 - Na Na8 1 0.37500000 0.75000000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Ge Ge12 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge13 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge14 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge15 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge16 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge17 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge18 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge19 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge22 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge23 1 0.12500000 0.87500000 0.25000000 1 - Mo Mo24 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo25 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo26 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo27 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo28 1 0.00000000 0.00000000 0.00000000 1 - Mo Mo29 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo30 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.50956000 0.39460500 0.81415900 1 - O O33 1 0.81415900 0.50956000 0.39460500 1 - O O34 1 0.80459900 0.88504500 0.99044000 1 - O O35 1 0.41955400 0.10539500 0.61495500 1 - O O36 1 0.88504500 0.39460500 0.08044600 1 - O O37 1 0.68584100 0.08044600 0.69540100 1 - O O38 1 0.81415900 0.80459900 0.41955400 1 - O O39 1 0.39460500 0.81415900 0.50956000 1 - O O40 1 0.61495500 0.69540100 0.50956000 1 - O O41 1 0.41955400 0.81415900 0.80459900 1 - O O42 1 0.39460500 0.08044600 0.88504500 1 - O O43 1 0.10539500 0.99044000 0.68584100 1 - O O44 1 0.99044000 0.68584100 0.10539500 1 - O O45 1 0.80459900 0.41955400 0.81415900 1 - O O46 1 0.50956000 0.61495500 0.69540100 1 - O O47 1 0.69540100 0.50956000 0.61495500 1 - O O48 1 0.08044600 0.88504500 0.39460500 1 - O O49 1 0.99044000 0.80459900 0.88504500 1 - O O50 1 0.08044600 0.69540100 0.68584100 1 - O O51 1 0.38504500 0.30459900 0.49044000 1 - O O52 1 0.61495500 0.41955400 0.10539500 1 - O O53 1 0.10539500 0.61495500 0.41955400 1 - O O54 1 0.69540100 0.68584100 0.08044600 1 - O O55 1 0.68584100 0.10539500 0.99044000 1 - O O56 1 0.49044000 0.60539500 0.18584100 1 - O O57 1 0.18584100 0.49044000 0.60539500 1 - O O58 1 0.19540100 0.11495500 0.00956000 1 - O O59 1 0.58044600 0.89460500 0.38504500 1 - O O60 1 0.11495500 0.60539500 0.91955400 1 - O O61 1 0.31415900 0.91955400 0.30459900 1 - O O62 1 0.18584100 0.19540100 0.58044600 1 - O O63 1 0.60539500 0.18584100 0.49044000 1 - O O64 1 0.31415900 0.89460500 0.00956000 1 - O O65 1 0.30459900 0.31415900 0.91955400 1 - O O66 1 0.89460500 0.38504500 0.58044600 1 - O O67 1 0.11495500 0.00956000 0.19540100 1 - O O68 1 0.38504500 0.58044600 0.89460500 1 - O O69 1 0.91955400 0.30459900 0.31415900 1 - O O70 1 0.00956000 0.19540100 0.11495500 1 - O O71 1 0.91955400 0.11495500 0.60539500 1 - O O72 1 0.30459900 0.49044000 0.38504500 1 - O O73 1 0.49044000 0.38504500 0.30459900 1 - O O74 1 0.19540100 0.58044600 0.18584100 1 - O O75 1 0.00956000 0.31415900 0.89460500 1 - O O76 1 0.89460500 0.00956000 0.31415900 1 - O O77 1 0.60539500 0.91955400 0.11495500 1 - O O78 1 0.58044600 0.18584100 0.19540100 1 - O O79 1 0.88504500 0.99044000 0.80459900 1 -" -Li3Co2(GeO4)3,mp-1013807,Ia-3d,[],0.1397036302088024,{'tags': []},"Full Formula (Li12 Co8 Ge12 O48) -Reduced Formula: Li3Co2(GeO4)3 -abc : 10.272599 10.272599 10.272599 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.625 0.875 0.002 - 1 Li 0.25 0.875 0.625 0.002 - 2 Li 0.625 0.25 0.875 0.003 - 3 Li 0.875 0.75 0.625 0.001 - 4 Li 0.875 0.625 0.25 0.002 - 5 Li 0.625 0.875 0.75 0.003 - 6 Li 0.25 0.375 0.125 0.002 - 7 Li 0.75 0.125 0.375 0.002 - 8 Li 0.375 0.75 0.125 0.003 - 9 Li 0.125 0.25 0.375 0.001 - 10 Li 0.125 0.375 0.75 0.002 - 11 Li 0.375 0.125 0.25 0.003 - 12 Co 0.5 0 0.5 1.474 - 13 Co 0 0.5 0 1.08 - 14 Co 0.5 0.5 0.5 1.096 - 15 Co 0 0 0.5 1.111 - 16 Co 0 0 0 1.13 - 17 Co 0 0.5 0.5 1.12 - 18 Co 0.5 0.5 0 1.127 - 19 Co 0.5 0 0 1.1 - 20 Ge 0.375 0.625 0.75 -0.002 - 21 Ge 0.625 0.375 0.25 -0.002 - 22 Ge 0.625 0.75 0.375 -0.002 - 23 Ge 0.25 0.125 0.875 -0.002 - 24 Ge 0.875 0.25 0.125 -0.002 - 25 Ge 0.75 0.375 0.625 -0.001 - 26 Ge 0.25 0.625 0.375 -0.001 - 27 Ge 0.75 0.875 0.125 -0.002 - 28 Ge 0.125 0.75 0.875 -0.002 - 29 Ge 0.375 0.25 0.625 -0.002 - 30 Ge 0.875 0.125 0.75 -0.002 - 31 Ge 0.125 0.875 0.25 -0.002 - 32 O 0.521772 0.403626 0.824436 0.032 - 33 O 0.824436 0.521772 0.403626 0.046 - 34 O 0.802664 0.881855 0.978228 0.045 - 35 O 0.420809 0.096374 0.618145 0.041 - 36 O 0.881855 0.403626 0.079191 0.044 - 37 O 0.675564 0.079191 0.697336 0.047 - 38 O 0.824436 0.802664 0.420809 0.059 - 39 O 0.403626 0.824436 0.521772 0.054 - 40 O 0.618145 0.697336 0.521772 0.046 - 41 O 0.420809 0.824436 0.802664 0.054 - 42 O 0.403626 0.079191 0.881855 0.024 - 43 O 0.096374 0.978228 0.675564 0.043 - 44 O 0.978228 0.675564 0.096374 0.047 - 45 O 0.802664 0.420809 0.824436 0.033 - 46 O 0.521772 0.618145 0.697336 0.048 - 47 O 0.697336 0.521772 0.618145 0.042 - 48 O 0.079191 0.881855 0.403626 0.037 - 49 O 0.978228 0.802664 0.881855 0.051 - 50 O 0.079191 0.697336 0.675564 0.063 - 51 O 0.381855 0.302664 0.478228 0.046 - 52 O 0.618145 0.420809 0.096374 0.034 - 53 O 0.096374 0.618145 0.420809 0.036 - 54 O 0.697336 0.675564 0.079191 0.062 - 55 O 0.675564 0.096374 0.978228 0.046 - 56 O 0.478228 0.596374 0.175564 0.032 - 57 O 0.175564 0.478228 0.596374 0.046 - 58 O 0.197336 0.118145 0.021772 0.045 - 59 O 0.579191 0.903626 0.381855 0.041 - 60 O 0.118145 0.596374 0.920809 0.044 - 61 O 0.324436 0.920809 0.302664 0.047 - 62 O 0.175564 0.197336 0.579191 0.059 - 63 O 0.596374 0.175564 0.478228 0.054 - 64 O 0.324436 0.903626 0.021772 0.046 - 65 O 0.302664 0.324436 0.920809 0.062 - 66 O 0.903626 0.381855 0.579191 0.036 - 67 O 0.118145 0.021772 0.197336 0.035 - 68 O 0.381855 0.579191 0.903626 0.034 - 69 O 0.920809 0.302664 0.324436 0.063 - 70 O 0.021772 0.197336 0.118145 0.051 - 71 O 0.920809 0.118145 0.596374 0.037 - 72 O 0.302664 0.478228 0.381855 0.042 - 73 O 0.478228 0.381855 0.302664 0.048 - 74 O 0.197336 0.579191 0.175564 0.033 - 75 O 0.021772 0.324436 0.903626 0.047 - 76 O 0.903626 0.021772 0.324436 0.043 - 77 O 0.596374 0.920809 0.118145 0.024 - 78 O 0.579191 0.175564 0.197336 0.054 - 79 O 0.881855 0.978228 0.802664 0.035","# generated using pymatgen -data_Li3Co2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.27259935 -_cell_length_b 10.27259935 -_cell_length_c 10.27259935 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Co2(GeO4)3 -_chemical_formula_sum 'Li12 Co8 Ge12 O48' -_cell_volume 834.48620129 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.62500000 0.87500000 1 - Li Li1 1 0.25000000 0.87500000 0.62500000 1 - Li Li2 1 0.62500000 0.25000000 0.87500000 1 - Li Li3 1 0.87500000 0.75000000 0.62500000 1 - Li Li4 1 0.87500000 0.62500000 0.25000000 1 - Li Li5 1 0.62500000 0.87500000 0.75000000 1 - Li Li6 1 0.25000000 0.37500000 0.12500000 1 - Li Li7 1 0.75000000 0.12500000 0.37500000 1 - Li Li8 1 0.37500000 0.75000000 0.12500000 1 - Li Li9 1 0.12500000 0.25000000 0.37500000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.37500000 0.12500000 0.25000000 1 - Co Co12 1 0.50000000 0.00000000 0.50000000 1 - Co Co13 1 0.00000000 0.50000000 0.00000000 1 - Co Co14 1 0.50000000 0.50000000 0.50000000 1 - Co Co15 1 0.00000000 0.00000000 0.50000000 1 - Co Co16 1 0.00000000 0.00000000 0.00000000 1 - Co Co17 1 0.00000000 0.50000000 0.50000000 1 - Co Co18 1 0.50000000 0.50000000 0.00000000 1 - Co Co19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.52177200 0.40362600 0.82443600 1 - O O33 1 0.82443600 0.52177200 0.40362600 1 - O O34 1 0.80266400 0.88185500 0.97822800 1 - O O35 1 0.42080900 0.09637400 0.61814500 1 - O O36 1 0.88185500 0.40362600 0.07919100 1 - O O37 1 0.67556400 0.07919100 0.69733600 1 - O O38 1 0.82443600 0.80266400 0.42080900 1 - O O39 1 0.40362600 0.82443600 0.52177200 1 - O O40 1 0.61814500 0.69733600 0.52177200 1 - O O41 1 0.42080900 0.82443600 0.80266400 1 - O O42 1 0.40362600 0.07919100 0.88185500 1 - O O43 1 0.09637400 0.97822800 0.67556400 1 - O O44 1 0.97822800 0.67556400 0.09637400 1 - O O45 1 0.80266400 0.42080900 0.82443600 1 - O O46 1 0.52177200 0.61814500 0.69733600 1 - O O47 1 0.69733600 0.52177200 0.61814500 1 - O O48 1 0.07919100 0.88185500 0.40362600 1 - O O49 1 0.97822800 0.80266400 0.88185500 1 - O O50 1 0.07919100 0.69733600 0.67556400 1 - O O51 1 0.38185500 0.30266400 0.47822800 1 - O O52 1 0.61814500 0.42080900 0.09637400 1 - O O53 1 0.09637400 0.61814500 0.42080900 1 - O O54 1 0.69733600 0.67556400 0.07919100 1 - O O55 1 0.67556400 0.09637400 0.97822800 1 - O O56 1 0.47822800 0.59637400 0.17556400 1 - O O57 1 0.17556400 0.47822800 0.59637400 1 - O O58 1 0.19733600 0.11814500 0.02177200 1 - O O59 1 0.57919100 0.90362600 0.38185500 1 - O O60 1 0.11814500 0.59637400 0.92080900 1 - O O61 1 0.32443600 0.92080900 0.30266400 1 - O O62 1 0.17556400 0.19733600 0.57919100 1 - O O63 1 0.59637400 0.17556400 0.47822800 1 - O O64 1 0.32443600 0.90362600 0.02177200 1 - O O65 1 0.30266400 0.32443600 0.92080900 1 - O O66 1 0.90362600 0.38185500 0.57919100 1 - O O67 1 0.11814500 0.02177200 0.19733600 1 - O O68 1 0.38185500 0.57919100 0.90362600 1 - O O69 1 0.92080900 0.30266400 0.32443600 1 - O O70 1 0.02177200 0.19733600 0.11814500 1 - O O71 1 0.92080900 0.11814500 0.59637400 1 - O O72 1 0.30266400 0.47822800 0.38185500 1 - O O73 1 0.47822800 0.38185500 0.30266400 1 - O O74 1 0.19733600 0.57919100 0.17556400 1 - O O75 1 0.02177200 0.32443600 0.90362600 1 - O O76 1 0.90362600 0.02177200 0.32443600 1 - O O77 1 0.59637400 0.92080900 0.11814500 1 - O O78 1 0.57919100 0.17556400 0.19733600 1 - O O79 1 0.88185500 0.97822800 0.80266400 1 -" -Na3Ni2(GeO4)3,mp-1013808,Ia-3d,[],0.16633166741071292,{'tags': []},"Full Formula (Na12 Ni8 Ge12 O48) -Reduced Formula: Na3Ni2(GeO4)3 -abc : 10.504039 10.504039 10.504039 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.75 0.625 0.875 -0 - 1 Na 0.25 0.875 0.625 -0 - 2 Na 0.625 0.25 0.875 -0 - 3 Na 0.875 0.75 0.625 -0 - 4 Na 0.875 0.625 0.25 -0 - 5 Na 0.625 0.875 0.75 -0 - 6 Na 0.25 0.375 0.125 -0 - 7 Na 0.75 0.125 0.375 -0 - 8 Na 0.375 0.75 0.125 -0 - 9 Na 0.125 0.25 0.375 -0 - 10 Na 0.125 0.375 0.75 -0 - 11 Na 0.375 0.125 0.25 -0 - 12 Ni 0.5 0 0.5 0.636 - 13 Ni 0 0.5 0 0.636 - 14 Ni 0.5 0.5 0.5 0.636 - 15 Ni 0 0 0.5 0.636 - 16 Ni 0 0 0 0.636 - 17 Ni 0 0.5 0.5 0.636 - 18 Ni 0.5 0.5 0 0.636 - 19 Ni 0.5 0 0 0.636 - 20 Ge 0.375 0.625 0.75 0.003 - 21 Ge 0.625 0.375 0.25 0.003 - 22 Ge 0.625 0.75 0.375 0.003 - 23 Ge 0.25 0.125 0.875 0.003 - 24 Ge 0.875 0.25 0.125 0.003 - 25 Ge 0.75 0.375 0.625 0.003 - 26 Ge 0.25 0.625 0.375 0.003 - 27 Ge 0.75 0.875 0.125 0.003 - 28 Ge 0.125 0.75 0.875 0.003 - 29 Ge 0.375 0.25 0.625 0.003 - 30 Ge 0.875 0.125 0.75 0.003 - 31 Ge 0.125 0.875 0.25 0.003 - 32 O 0.514781 0.402453 0.821708 -0.019 - 33 O 0.821708 0.514781 0.402453 -0.019 - 34 O 0.806927 0.887672 0.985219 -0.019 - 35 O 0.419255 0.097547 0.612328 -0.019 - 36 O 0.887672 0.402453 0.080745 -0.019 - 37 O 0.678292 0.080745 0.693073 -0.019 - 38 O 0.821708 0.806927 0.419255 -0.019 - 39 O 0.402453 0.821708 0.514781 -0.019 - 40 O 0.612328 0.693073 0.514781 -0.019 - 41 O 0.419255 0.821708 0.806927 -0.019 - 42 O 0.402453 0.080745 0.887672 -0.019 - 43 O 0.097547 0.985219 0.678292 -0.019 - 44 O 0.985219 0.678292 0.097547 -0.019 - 45 O 0.806927 0.419255 0.821708 -0.019 - 46 O 0.514781 0.612328 0.693073 -0.019 - 47 O 0.693073 0.514781 0.612328 -0.019 - 48 O 0.080745 0.887672 0.402453 -0.019 - 49 O 0.985219 0.806927 0.887672 -0.019 - 50 O 0.080745 0.693073 0.678292 -0.019 - 51 O 0.387672 0.306927 0.485219 -0.019 - 52 O 0.612328 0.419255 0.097547 -0.019 - 53 O 0.097547 0.612328 0.419255 -0.019 - 54 O 0.693073 0.678292 0.080745 -0.019 - 55 O 0.678292 0.097547 0.985219 -0.019 - 56 O 0.485219 0.597547 0.178292 -0.019 - 57 O 0.178292 0.485219 0.597547 -0.019 - 58 O 0.193073 0.112328 0.014781 -0.019 - 59 O 0.580745 0.902453 0.387672 -0.019 - 60 O 0.112328 0.597547 0.919255 -0.019 - 61 O 0.321708 0.919255 0.306927 -0.019 - 62 O 0.178292 0.193073 0.580745 -0.019 - 63 O 0.597547 0.178292 0.485219 -0.019 - 64 O 0.321708 0.902453 0.014781 -0.019 - 65 O 0.306927 0.321708 0.919255 -0.019 - 66 O 0.902453 0.387672 0.580745 -0.019 - 67 O 0.112328 0.014781 0.193073 -0.019 - 68 O 0.387672 0.580745 0.902453 -0.019 - 69 O 0.919255 0.306927 0.321708 -0.019 - 70 O 0.014781 0.193073 0.112328 -0.019 - 71 O 0.919255 0.112328 0.597547 -0.019 - 72 O 0.306927 0.485219 0.387672 -0.019 - 73 O 0.485219 0.387672 0.306927 -0.019 - 74 O 0.193073 0.580745 0.178292 -0.019 - 75 O 0.014781 0.321708 0.902453 -0.019 - 76 O 0.902453 0.014781 0.321708 -0.019 - 77 O 0.597547 0.919255 0.112328 -0.019 - 78 O 0.580745 0.178292 0.193073 -0.019 - 79 O 0.887672 0.985219 0.806927 -0.019","# generated using pymatgen -data_Na3Ni2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.50403944 -_cell_length_b 10.50403944 -_cell_length_c 10.50403944 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Ni2(GeO4)3 -_chemical_formula_sum 'Na12 Ni8 Ge12 O48' -_cell_volume 892.16902473 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.75000000 0.62500000 0.87500000 1 - Na Na1 1 0.25000000 0.87500000 0.62500000 1 - Na Na2 1 0.62500000 0.25000000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.87500000 0.62500000 0.25000000 1 - Na Na5 1 0.62500000 0.87500000 0.75000000 1 - Na Na6 1 0.25000000 0.37500000 0.12500000 1 - Na Na7 1 0.75000000 0.12500000 0.37500000 1 - Na Na8 1 0.37500000 0.75000000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Ni Ni12 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni13 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni14 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni15 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni16 1 0.00000000 0.00000000 0.00000000 1 - Ni Ni17 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni18 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51478100 0.40245300 0.82170800 1 - O O33 1 0.82170800 0.51478100 0.40245300 1 - O O34 1 0.80692700 0.88767200 0.98521900 1 - O O35 1 0.41925500 0.09754700 0.61232800 1 - O O36 1 0.88767200 0.40245300 0.08074500 1 - O O37 1 0.67829200 0.08074500 0.69307300 1 - O O38 1 0.82170800 0.80692700 0.41925500 1 - O O39 1 0.40245300 0.82170800 0.51478100 1 - O O40 1 0.61232800 0.69307300 0.51478100 1 - O O41 1 0.41925500 0.82170800 0.80692700 1 - O O42 1 0.40245300 0.08074500 0.88767200 1 - O O43 1 0.09754700 0.98521900 0.67829200 1 - O O44 1 0.98521900 0.67829200 0.09754700 1 - O O45 1 0.80692700 0.41925500 0.82170800 1 - O O46 1 0.51478100 0.61232800 0.69307300 1 - O O47 1 0.69307300 0.51478100 0.61232800 1 - O O48 1 0.08074500 0.88767200 0.40245300 1 - O O49 1 0.98521900 0.80692700 0.88767200 1 - O O50 1 0.08074500 0.69307300 0.67829200 1 - O O51 1 0.38767200 0.30692700 0.48521900 1 - O O52 1 0.61232800 0.41925500 0.09754700 1 - O O53 1 0.09754700 0.61232800 0.41925500 1 - O O54 1 0.69307300 0.67829200 0.08074500 1 - O O55 1 0.67829200 0.09754700 0.98521900 1 - O O56 1 0.48521900 0.59754700 0.17829200 1 - O O57 1 0.17829200 0.48521900 0.59754700 1 - O O58 1 0.19307300 0.11232800 0.01478100 1 - O O59 1 0.58074500 0.90245300 0.38767200 1 - O O60 1 0.11232800 0.59754700 0.91925500 1 - O O61 1 0.32170800 0.91925500 0.30692700 1 - O O62 1 0.17829200 0.19307300 0.58074500 1 - O O63 1 0.59754700 0.17829200 0.48521900 1 - O O64 1 0.32170800 0.90245300 0.01478100 1 - O O65 1 0.30692700 0.32170800 0.91925500 1 - O O66 1 0.90245300 0.38767200 0.58074500 1 - O O67 1 0.11232800 0.01478100 0.19307300 1 - O O68 1 0.38767200 0.58074500 0.90245300 1 - O O69 1 0.91925500 0.30692700 0.32170800 1 - O O70 1 0.01478100 0.19307300 0.11232800 1 - O O71 1 0.91925500 0.11232800 0.59754700 1 - O O72 1 0.30692700 0.48521900 0.38767200 1 - O O73 1 0.48521900 0.38767200 0.30692700 1 - O O74 1 0.19307300 0.58074500 0.17829200 1 - O O75 1 0.01478100 0.32170800 0.90245300 1 - O O76 1 0.90245300 0.01478100 0.32170800 1 - O O77 1 0.59754700 0.91925500 0.11232800 1 - O O78 1 0.58074500 0.17829200 0.19307300 1 - O O79 1 0.88767200 0.98521900 0.80692700 1 -" -Na3Mn2(GeO4)3,mp-1013842,Ia-3d,[],0.0647134936964262,{'tags': []},"Full Formula (Na12 Mn8 Ge12 O48) -Reduced Formula: Na3Mn2(GeO4)3 -abc : 10.626928 10.622435 10.624966 -angles: 109.461315 109.478247 109.467949 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.625029 0.250036 0.874901 0.003 - 1 Na 0.875217 0.750432 0.625041 0.003 - 2 Na 0.749967 0.625007 0.875073 0.003 - 3 Na 0.249764 0.875191 0.624762 0.003 - 4 Na 0.874996 0.625372 0.250134 0.003 - 5 Na 0.625149 0.875084 0.750125 0.003 - 6 Na 0.374971 0.749964 0.125098 0.003 - 7 Na 0.124783 0.249568 0.374958 0.003 - 8 Na 0.250033 0.374993 0.124927 0.003 - 9 Na 0.750236 0.12481 0.375238 0.003 - 10 Na 0.125004 0.374628 0.749866 0.003 - 11 Na 0.37485 0.124916 0.249874 0.003 - 12 Mn 0.500001 0.5 0.499999 3.168 - 13 Mn 0.500002 0.500002 0 3.168 - 14 Mn 0.499999 0 0.500001 3.169 - 15 Mn 0 0.499999 0.499998 3.17 - 16 Mn 0.500001 1e-06 1e-06 3.168 - 17 Mn 0 1e-06 0.500001 3.167 - 18 Mn 0 0.500001 0 3.168 - 19 Mn 1e-06 0.999999 0.999999 3.169 - 20 Ge 0.874933 0.124838 0.74977 0.021 - 21 Ge 0.125064 0.875157 0.250229 0.021 - 22 Ge 0.250074 0.62499 0.375003 0.021 - 23 Ge 0.124993 0.749981 0.875048 0.021 - 24 Ge 0.750194 0.87508 0.125158 0.02 - 25 Ge 0.374825 0.249877 0.625013 0.021 - 26 Ge 0.625178 0.750124 0.37499 0.02 - 27 Ge 0.875004 0.25002 0.124954 0.021 - 28 Ge 0.249807 0.124918 0.874842 0.02 - 29 Ge 0.749925 0.375011 0.624997 0.021 - 30 Ge 0.374946 0.624997 0.75003 0.02 - 31 Ge 0.625052 0.375001 0.249972 0.021 - 32 O 0.805384 0.417901 0.81869 -0.109 - 33 O 0.081084 0.88666 0.400252 -0.107 - 34 O 0.681312 0.099187 0.986693 -0.113 - 35 O 0.694741 0.513543 0.612579 -0.113 - 36 O 0.694462 0.681136 0.081528 -0.106 - 37 O 0.513266 0.612464 0.69462 -0.113 - 38 O 0.099336 0.612652 0.418043 -0.114 - 39 O 0.612048 0.694617 0.513228 -0.113 - 40 O 0.400832 0.81874 0.513536 -0.112 - 41 O 0.887042 0.986633 0.80549 -0.107 - 42 O 0.986471 0.805214 0.887246 -0.114 - 43 O 0.081987 0.694609 0.681271 -0.115 - 44 O 0.612752 0.417952 0.099192 -0.112 - 45 O 0.513218 0.400888 0.818717 -0.111 - 46 O 0.681293 0.082155 0.694493 -0.109 - 47 O 0.418466 0.099587 0.612958 -0.108 - 48 O 0.818751 0.513352 0.400682 -0.115 - 49 O 0.401146 0.082556 0.887953 -0.112 - 50 O 0.09979 0.986434 0.680883 -0.106 - 51 O 0.599168 0.181258 0.486462 -0.112 - 52 O 0.986851 0.681403 0.098911 -0.111 - 53 O 0.819112 0.805569 0.418924 -0.107 - 54 O 0.887422 0.400973 0.082198 -0.112 - 55 O 0.805521 0.887653 0.986769 -0.112 - 56 O 0.194616 0.582098 0.181308 -0.108 - 57 O 0.918914 0.113339 0.599749 -0.105 - 58 O 0.31869 0.900814 0.013309 -0.109 - 59 O 0.305259 0.486457 0.387421 -0.112 - 60 O 0.305541 0.318867 0.918475 -0.105 - 61 O 0.486733 0.387536 0.30538 -0.114 - 62 O 0.900664 0.387346 0.581954 -0.115 - 63 O 0.387952 0.305386 0.486773 -0.112 - 64 O 0.194478 0.112348 0.01323 -0.111 - 65 O 0.112577 0.59903 0.917802 -0.109 - 66 O 0.180889 0.194432 0.581077 -0.107 - 67 O 0.582227 0.181226 0.19481 -0.113 - 68 O 0.01315 0.318597 0.90109 -0.109 - 69 O 0.900212 0.013569 0.319118 -0.107 - 70 O 0.598855 0.917445 0.112047 -0.113 - 71 O 0.181247 0.486647 0.599317 -0.114 - 72 O 0.581533 0.900414 0.387042 -0.104 - 73 O 0.318707 0.917844 0.305507 -0.109 - 74 O 0.486782 0.599112 0.181284 -0.109 - 75 O 0.387247 0.582047 0.900808 -0.111 - 76 O 0.918012 0.30539 0.318726 -0.114 - 77 O 0.013531 0.194786 0.112754 -0.113 - 78 O 0.112957 0.013365 0.194508 -0.107 - 79 O 0.417773 0.818774 0.80519 -0.113","# generated using pymatgen -data_Na3Mn2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.62692797 -_cell_length_b 10.62243543 -_cell_length_c 10.62496609 -_cell_angle_alpha 109.46131482 -_cell_angle_beta 109.47824686 -_cell_angle_gamma 109.46794854 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Mn2(GeO4)3 -_chemical_formula_sum 'Na12 Mn8 Ge12 O48' -_cell_volume 923.35872841 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.62502900 0.25003600 0.87490100 1 - Na Na1 1 0.87521700 0.75043200 0.62504100 1 - Na Na2 1 0.74996700 0.62500700 0.87507300 1 - Na Na3 1 0.24976400 0.87519100 0.62476200 1 - Na Na4 1 0.87499600 0.62537200 0.25013400 1 - Na Na5 1 0.62514900 0.87508400 0.75012500 1 - Na Na6 1 0.37497100 0.74996400 0.12509800 1 - Na Na7 1 0.12478300 0.24956800 0.37495800 1 - Na Na8 1 0.25003300 0.37499300 0.12492700 1 - Na Na9 1 0.75023600 0.12481000 0.37523800 1 - Na Na10 1 0.12500400 0.37462800 0.74986600 1 - Na Na11 1 0.37485000 0.12491600 0.24987400 1 - Mn Mn12 1 0.50000100 0.50000000 0.49999900 1 - Mn Mn13 1 0.50000200 0.50000200 0.00000000 1 - Mn Mn14 1 0.49999900 0.00000000 0.50000100 1 - Mn Mn15 1 0.00000000 0.49999900 0.49999800 1 - Mn Mn16 1 0.50000100 0.00000100 0.00000100 1 - Mn Mn17 1 0.00000000 0.00000100 0.50000100 1 - Mn Mn18 1 0.00000000 0.50000100 0.00000000 1 - Mn Mn19 1 0.00000100 0.99999900 0.99999900 1 - Ge Ge20 1 0.87493300 0.12483800 0.74977000 1 - Ge Ge21 1 0.12506400 0.87515700 0.25022900 1 - Ge Ge22 1 0.25007400 0.62499000 0.37500300 1 - Ge Ge23 1 0.12499300 0.74998100 0.87504800 1 - Ge Ge24 1 0.75019400 0.87508000 0.12515800 1 - Ge Ge25 1 0.37482500 0.24987700 0.62501300 1 - Ge Ge26 1 0.62517800 0.75012400 0.37499000 1 - Ge Ge27 1 0.87500400 0.25002000 0.12495400 1 - Ge Ge28 1 0.24980700 0.12491800 0.87484200 1 - Ge Ge29 1 0.74992500 0.37501100 0.62499700 1 - Ge Ge30 1 0.37494600 0.62499700 0.75003000 1 - Ge Ge31 1 0.62505200 0.37500100 0.24997200 1 - O O32 1 0.80538400 0.41790100 0.81869000 1 - O O33 1 0.08108400 0.88666000 0.40025200 1 - O O34 1 0.68131200 0.09918700 0.98669300 1 - O O35 1 0.69474100 0.51354300 0.61257900 1 - O O36 1 0.69446200 0.68113600 0.08152800 1 - O O37 1 0.51326600 0.61246400 0.69462000 1 - O O38 1 0.09933600 0.61265200 0.41804300 1 - O O39 1 0.61204800 0.69461700 0.51322800 1 - O O40 1 0.40083200 0.81874000 0.51353600 1 - O O41 1 0.88704200 0.98663300 0.80549000 1 - O O42 1 0.98647100 0.80521400 0.88724600 1 - O O43 1 0.08198700 0.69460900 0.68127100 1 - O O44 1 0.61275200 0.41795200 0.09919200 1 - O O45 1 0.51321800 0.40088800 0.81871700 1 - O O46 1 0.68129300 0.08215500 0.69449300 1 - O O47 1 0.41846600 0.09958700 0.61295800 1 - O O48 1 0.81875100 0.51335200 0.40068200 1 - O O49 1 0.40114600 0.08255600 0.88795300 1 - O O50 1 0.09979000 0.98643400 0.68088300 1 - O O51 1 0.59916800 0.18125800 0.48646200 1 - O O52 1 0.98685100 0.68140300 0.09891100 1 - O O53 1 0.81911200 0.80556900 0.41892400 1 - O O54 1 0.88742200 0.40097300 0.08219800 1 - O O55 1 0.80552100 0.88765300 0.98676900 1 - O O56 1 0.19461600 0.58209800 0.18130800 1 - O O57 1 0.91891400 0.11333900 0.59974900 1 - O O58 1 0.31869000 0.90081400 0.01330900 1 - O O59 1 0.30525900 0.48645700 0.38742100 1 - O O60 1 0.30554100 0.31886700 0.91847500 1 - O O61 1 0.48673300 0.38753600 0.30538000 1 - O O62 1 0.90066400 0.38734600 0.58195400 1 - O O63 1 0.38795200 0.30538600 0.48677300 1 - O O64 1 0.19447800 0.11234800 0.01323000 1 - O O65 1 0.11257700 0.59903000 0.91780200 1 - O O66 1 0.18088900 0.19443200 0.58107700 1 - O O67 1 0.58222700 0.18122600 0.19481000 1 - O O68 1 0.01315000 0.31859700 0.90109000 1 - O O69 1 0.90021200 0.01356900 0.31911800 1 - O O70 1 0.59885500 0.91744500 0.11204700 1 - O O71 1 0.18124700 0.48664700 0.59931700 1 - O O72 1 0.58153300 0.90041400 0.38704200 1 - O O73 1 0.31870700 0.91784400 0.30550700 1 - O O74 1 0.48678200 0.59911200 0.18128400 1 - O O75 1 0.38724700 0.58204700 0.90080800 1 - O O76 1 0.91801200 0.30539000 0.31872600 1 - O O77 1 0.01353100 0.19478600 0.11275400 1 - O O78 1 0.11295700 0.01336500 0.19450800 1 - O O79 1 0.41777300 0.81877400 0.80519000 1 -" -Li3Fe2(GeO4)3,mp-1013849,Ia-3d,[],0.13262567836666506,{'tags': []},"Full Formula (Li12 Fe8 Ge12 O48) -Reduced Formula: Li3Fe2(GeO4)3 -abc : 10.505856 10.505856 10.505856 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.625 0.875 0.005 - 1 Li 0.25 0.875 0.625 0.005 - 2 Li 0.625 0.25 0.875 0.005 - 3 Li 0.875 0.75 0.625 0.005 - 4 Li 0.875 0.625 0.25 0.005 - 5 Li 0.625 0.875 0.75 0.005 - 6 Li 0.25 0.375 0.125 0.005 - 7 Li 0.75 0.125 0.375 0.005 - 8 Li 0.375 0.75 0.125 0.005 - 9 Li 0.125 0.25 0.375 0.005 - 10 Li 0.125 0.375 0.75 0.005 - 11 Li 0.375 0.125 0.25 0.005 - 12 Fe 0.5 0 0.5 3.98 - 13 Fe 0 0.5 0 3.98 - 14 Fe 0.5 0.5 0.5 3.98 - 15 Fe 0 0 0.5 3.98 - 16 Fe 0 0 0 3.98 - 17 Fe 0 0.5 0.5 3.98 - 18 Fe 0.5 0.5 0 3.98 - 19 Fe 0.5 0 0 3.98 - 20 Ge 0.375 0.625 0.75 0.035 - 21 Ge 0.625 0.375 0.25 0.035 - 22 Ge 0.625 0.75 0.375 0.035 - 23 Ge 0.25 0.125 0.875 0.035 - 24 Ge 0.875 0.25 0.125 0.035 - 25 Ge 0.75 0.375 0.625 0.035 - 26 Ge 0.25 0.625 0.375 0.035 - 27 Ge 0.75 0.875 0.125 0.035 - 28 Ge 0.125 0.75 0.875 0.035 - 29 Ge 0.375 0.25 0.625 0.035 - 30 Ge 0.875 0.125 0.75 0.035 - 31 Ge 0.125 0.875 0.25 0.035 - 32 O 0.520351 0.399699 0.819534 -0.081 - 33 O 0.819534 0.520351 0.399699 -0.081 - 34 O 0.799183 0.879348 0.979649 -0.081 - 35 O 0.419835 0.100301 0.620652 -0.081 - 36 O 0.879348 0.399699 0.080165 -0.081 - 37 O 0.680466 0.080165 0.700817 -0.081 - 38 O 0.819534 0.799183 0.419835 -0.081 - 39 O 0.399699 0.819534 0.520351 -0.081 - 40 O 0.620652 0.700817 0.520351 -0.081 - 41 O 0.419835 0.819534 0.799183 -0.081 - 42 O 0.399699 0.080165 0.879348 -0.081 - 43 O 0.100301 0.979649 0.680466 -0.081 - 44 O 0.979649 0.680466 0.100301 -0.081 - 45 O 0.799183 0.419835 0.819534 -0.081 - 46 O 0.520351 0.620652 0.700817 -0.081 - 47 O 0.700817 0.520351 0.620652 -0.081 - 48 O 0.080165 0.879348 0.399699 -0.081 - 49 O 0.979649 0.799183 0.879348 -0.081 - 50 O 0.080165 0.700817 0.680466 -0.081 - 51 O 0.379348 0.299183 0.479649 -0.081 - 52 O 0.620652 0.419835 0.100301 -0.081 - 53 O 0.100301 0.620652 0.419835 -0.081 - 54 O 0.700817 0.680466 0.080165 -0.081 - 55 O 0.680466 0.100301 0.979649 -0.081 - 56 O 0.479649 0.600301 0.180466 -0.081 - 57 O 0.180466 0.479649 0.600301 -0.081 - 58 O 0.200817 0.120652 0.020351 -0.081 - 59 O 0.580165 0.899699 0.379348 -0.081 - 60 O 0.120652 0.600301 0.919835 -0.081 - 61 O 0.319534 0.919835 0.299183 -0.081 - 62 O 0.180466 0.200817 0.580165 -0.081 - 63 O 0.600301 0.180466 0.479649 -0.081 - 64 O 0.319534 0.899699 0.020351 -0.081 - 65 O 0.299183 0.319534 0.919835 -0.081 - 66 O 0.899699 0.379348 0.580165 -0.081 - 67 O 0.120652 0.020351 0.200817 -0.081 - 68 O 0.379348 0.580165 0.899699 -0.081 - 69 O 0.919835 0.299183 0.319534 -0.081 - 70 O 0.020351 0.200817 0.120652 -0.081 - 71 O 0.919835 0.120652 0.600301 -0.081 - 72 O 0.299183 0.479649 0.379348 -0.081 - 73 O 0.479649 0.379348 0.299183 -0.081 - 74 O 0.200817 0.580165 0.180466 -0.081 - 75 O 0.020351 0.319534 0.899699 -0.081 - 76 O 0.899699 0.020351 0.319534 -0.081 - 77 O 0.600301 0.919835 0.120652 -0.081 - 78 O 0.580165 0.180466 0.200817 -0.081 - 79 O 0.879348 0.979649 0.799183 -0.081","# generated using pymatgen -data_Li3Fe2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.50585636 -_cell_length_b 10.50585636 -_cell_length_c 10.50585636 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Fe2(GeO4)3 -_chemical_formula_sum 'Li12 Fe8 Ge12 O48' -_cell_volume 892.63206982 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.62500000 0.87500000 1 - Li Li1 1 0.25000000 0.87500000 0.62500000 1 - Li Li2 1 0.62500000 0.25000000 0.87500000 1 - Li Li3 1 0.87500000 0.75000000 0.62500000 1 - Li Li4 1 0.87500000 0.62500000 0.25000000 1 - Li Li5 1 0.62500000 0.87500000 0.75000000 1 - Li Li6 1 0.25000000 0.37500000 0.12500000 1 - Li Li7 1 0.75000000 0.12500000 0.37500000 1 - Li Li8 1 0.37500000 0.75000000 0.12500000 1 - Li Li9 1 0.12500000 0.25000000 0.37500000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.37500000 0.12500000 0.25000000 1 - Fe Fe12 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe13 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe14 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe18 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.52035100 0.39969900 0.81953400 1 - O O33 1 0.81953400 0.52035100 0.39969900 1 - O O34 1 0.79918300 0.87934800 0.97964900 1 - O O35 1 0.41983500 0.10030100 0.62065200 1 - O O36 1 0.87934800 0.39969900 0.08016500 1 - O O37 1 0.68046600 0.08016500 0.70081700 1 - O O38 1 0.81953400 0.79918300 0.41983500 1 - O O39 1 0.39969900 0.81953400 0.52035100 1 - O O40 1 0.62065200 0.70081700 0.52035100 1 - O O41 1 0.41983500 0.81953400 0.79918300 1 - O O42 1 0.39969900 0.08016500 0.87934800 1 - O O43 1 0.10030100 0.97964900 0.68046600 1 - O O44 1 0.97964900 0.68046600 0.10030100 1 - O O45 1 0.79918300 0.41983500 0.81953400 1 - O O46 1 0.52035100 0.62065200 0.70081700 1 - O O47 1 0.70081700 0.52035100 0.62065200 1 - O O48 1 0.08016500 0.87934800 0.39969900 1 - O O49 1 0.97964900 0.79918300 0.87934800 1 - O O50 1 0.08016500 0.70081700 0.68046600 1 - O O51 1 0.37934800 0.29918300 0.47964900 1 - O O52 1 0.62065200 0.41983500 0.10030100 1 - O O53 1 0.10030100 0.62065200 0.41983500 1 - O O54 1 0.70081700 0.68046600 0.08016500 1 - O O55 1 0.68046600 0.10030100 0.97964900 1 - O O56 1 0.47964900 0.60030100 0.18046600 1 - O O57 1 0.18046600 0.47964900 0.60030100 1 - O O58 1 0.20081700 0.12065200 0.02035100 1 - O O59 1 0.58016500 0.89969900 0.37934800 1 - O O60 1 0.12065200 0.60030100 0.91983500 1 - O O61 1 0.31953400 0.91983500 0.29918300 1 - O O62 1 0.18046600 0.20081700 0.58016500 1 - O O63 1 0.60030100 0.18046600 0.47964900 1 - O O64 1 0.31953400 0.89969900 0.02035100 1 - O O65 1 0.29918300 0.31953400 0.91983500 1 - O O66 1 0.89969900 0.37934800 0.58016500 1 - O O67 1 0.12065200 0.02035100 0.20081700 1 - O O68 1 0.37934800 0.58016500 0.89969900 1 - O O69 1 0.91983500 0.29918300 0.31953400 1 - O O70 1 0.02035100 0.20081700 0.12065200 1 - O O71 1 0.91983500 0.12065200 0.60030100 1 - O O72 1 0.29918300 0.47964900 0.37934800 1 - O O73 1 0.47964900 0.37934800 0.29918300 1 - O O74 1 0.20081700 0.58016500 0.18046600 1 - O O75 1 0.02035100 0.31953400 0.89969900 1 - O O76 1 0.89969900 0.02035100 0.31953400 1 - O O77 1 0.60030100 0.91983500 0.12065200 1 - O O78 1 0.58016500 0.18046600 0.20081700 1 - O O79 1 0.87934800 0.97964900 0.79918300 1 -" -Na3Fe2(GeO4)3,mp-1013864,Ia-3d,[],0.10499306512499995,{'tags': []},"Full Formula (Na12 Fe8 Ge12 O48) -Reduced Formula: Na3Fe2(GeO4)3 -abc : 10.742377 10.742377 10.742377 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.75 0.625 0.875 0.003 - 1 Na 0.25 0.875 0.625 0.003 - 2 Na 0.625 0.25 0.875 0.003 - 3 Na 0.875 0.75 0.625 0.003 - 4 Na 0.875 0.625 0.25 0.003 - 5 Na 0.625 0.875 0.75 0.003 - 6 Na 0.25 0.375 0.125 0.003 - 7 Na 0.75 0.125 0.375 0.003 - 8 Na 0.375 0.75 0.125 0.003 - 9 Na 0.125 0.25 0.375 0.003 - 10 Na 0.125 0.375 0.75 0.003 - 11 Na 0.375 0.125 0.25 0.003 - 12 Fe 0.5 0 0.5 4.092 - 13 Fe 0 0.5 0 4.031 - 14 Fe 0.5 0.5 0.5 4.031 - 15 Fe 0 0 0.5 4.092 - 16 Fe 0 0 0 4.031 - 17 Fe 0 0.5 0.5 4.092 - 18 Fe 0.5 0.5 0 4.031 - 19 Fe 0.5 0 0 4.092 - 20 Ge 0.375 0.625 0.75 0.04 - 21 Ge 0.625 0.375 0.25 0.04 - 22 Ge 0.625 0.75 0.375 0.04 - 23 Ge 0.25 0.125 0.875 0.04 - 24 Ge 0.875 0.25 0.125 0.04 - 25 Ge 0.75 0.375 0.625 0.04 - 26 Ge 0.25 0.625 0.375 0.04 - 27 Ge 0.75 0.875 0.125 0.04 - 28 Ge 0.125 0.75 0.875 0.04 - 29 Ge 0.375 0.25 0.625 0.04 - 30 Ge 0.875 0.125 0.75 0.04 - 31 Ge 0.125 0.875 0.25 0.04 - 32 O 0.51244 0.397857 0.816879 -0.101 - 33 O 0.816879 0.51244 0.397857 -0.07 - 34 O 0.804439 0.885417 0.98756 -0.114 - 35 O 0.419022 0.102143 0.614583 -0.09 - 36 O 0.885417 0.397857 0.080978 -0.105 - 37 O 0.683121 0.080978 0.695561 -0.07 - 38 O 0.816879 0.804439 0.419022 -0.07 - 39 O 0.397857 0.816879 0.51244 -0.069 - 40 O 0.614583 0.695561 0.51244 -0.105 - 41 O 0.419022 0.816879 0.804439 -0.09 - 42 O 0.397857 0.080978 0.885417 -0.069 - 43 O 0.102143 0.98756 0.683121 -0.069 - 44 O 0.98756 0.683121 0.102143 -0.101 - 45 O 0.804439 0.419022 0.816879 -0.114 - 46 O 0.51244 0.614583 0.695561 -0.101 - 47 O 0.695561 0.51244 0.614583 -0.114 - 48 O 0.080978 0.885417 0.397857 -0.09 - 49 O 0.98756 0.804439 0.885417 -0.101 - 50 O 0.080978 0.695561 0.683121 -0.09 - 51 O 0.385417 0.304439 0.48756 -0.105 - 52 O 0.614583 0.419022 0.102143 -0.105 - 53 O 0.102143 0.614583 0.419022 -0.069 - 54 O 0.695561 0.683121 0.080978 -0.114 - 55 O 0.683121 0.102143 0.98756 -0.07 - 56 O 0.48756 0.602143 0.183121 -0.101 - 57 O 0.183121 0.48756 0.602143 -0.07 - 58 O 0.195561 0.114583 0.01244 -0.114 - 59 O 0.580978 0.897857 0.385417 -0.09 - 60 O 0.114583 0.602143 0.919022 -0.105 - 61 O 0.316879 0.919022 0.304439 -0.07 - 62 O 0.183121 0.195561 0.580978 -0.07 - 63 O 0.602143 0.183121 0.48756 -0.069 - 64 O 0.316879 0.897857 0.01244 -0.07 - 65 O 0.304439 0.316879 0.919022 -0.114 - 66 O 0.897857 0.385417 0.580978 -0.069 - 67 O 0.114583 0.01244 0.195561 -0.105 - 68 O 0.385417 0.580978 0.897857 -0.105 - 69 O 0.919022 0.304439 0.316879 -0.09 - 70 O 0.01244 0.195561 0.114583 -0.101 - 71 O 0.919022 0.114583 0.602143 -0.09 - 72 O 0.304439 0.48756 0.385417 -0.114 - 73 O 0.48756 0.385417 0.304439 -0.101 - 74 O 0.195561 0.580978 0.183121 -0.114 - 75 O 0.01244 0.316879 0.897857 -0.101 - 76 O 0.897857 0.01244 0.316879 -0.069 - 77 O 0.602143 0.919022 0.114583 -0.069 - 78 O 0.580978 0.183121 0.195561 -0.09 - 79 O 0.885417 0.98756 0.804439 -0.105","# generated using pymatgen -data_Na3Fe2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.74237656 -_cell_length_b 10.74237656 -_cell_length_c 10.74237656 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Fe2(GeO4)3 -_chemical_formula_sum 'Na12 Fe8 Ge12 O48' -_cell_volume 954.28747845 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.75000000 0.62500000 0.87500000 1 - Na Na1 1 0.25000000 0.87500000 0.62500000 1 - Na Na2 1 0.62500000 0.25000000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.87500000 0.62500000 0.25000000 1 - Na Na5 1 0.62500000 0.87500000 0.75000000 1 - Na Na6 1 0.25000000 0.37500000 0.12500000 1 - Na Na7 1 0.75000000 0.12500000 0.37500000 1 - Na Na8 1 0.37500000 0.75000000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Fe Fe12 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe13 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe14 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe18 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51244000 0.39785700 0.81687900 1 - O O33 1 0.81687900 0.51244000 0.39785700 1 - O O34 1 0.80443900 0.88541700 0.98756000 1 - O O35 1 0.41902200 0.10214300 0.61458300 1 - O O36 1 0.88541700 0.39785700 0.08097800 1 - O O37 1 0.68312100 0.08097800 0.69556100 1 - O O38 1 0.81687900 0.80443900 0.41902200 1 - O O39 1 0.39785700 0.81687900 0.51244000 1 - O O40 1 0.61458300 0.69556100 0.51244000 1 - O O41 1 0.41902200 0.81687900 0.80443900 1 - O O42 1 0.39785700 0.08097800 0.88541700 1 - O O43 1 0.10214300 0.98756000 0.68312100 1 - O O44 1 0.98756000 0.68312100 0.10214300 1 - O O45 1 0.80443900 0.41902200 0.81687900 1 - O O46 1 0.51244000 0.61458300 0.69556100 1 - O O47 1 0.69556100 0.51244000 0.61458300 1 - O O48 1 0.08097800 0.88541700 0.39785700 1 - O O49 1 0.98756000 0.80443900 0.88541700 1 - O O50 1 0.08097800 0.69556100 0.68312100 1 - O O51 1 0.38541700 0.30443900 0.48756000 1 - O O52 1 0.61458300 0.41902200 0.10214300 1 - O O53 1 0.10214300 0.61458300 0.41902200 1 - O O54 1 0.69556100 0.68312100 0.08097800 1 - O O55 1 0.68312100 0.10214300 0.98756000 1 - O O56 1 0.48756000 0.60214300 0.18312100 1 - O O57 1 0.18312100 0.48756000 0.60214300 1 - O O58 1 0.19556100 0.11458300 0.01244000 1 - O O59 1 0.58097800 0.89785700 0.38541700 1 - O O60 1 0.11458300 0.60214300 0.91902200 1 - O O61 1 0.31687900 0.91902200 0.30443900 1 - O O62 1 0.18312100 0.19556100 0.58097800 1 - O O63 1 0.60214300 0.18312100 0.48756000 1 - O O64 1 0.31687900 0.89785700 0.01244000 1 - O O65 1 0.30443900 0.31687900 0.91902200 1 - O O66 1 0.89785700 0.38541700 0.58097800 1 - O O67 1 0.11458300 0.01244000 0.19556100 1 - O O68 1 0.38541700 0.58097800 0.89785700 1 - O O69 1 0.91902200 0.30443900 0.31687900 1 - O O70 1 0.01244000 0.19556100 0.11458300 1 - O O71 1 0.91902200 0.11458300 0.60214300 1 - O O72 1 0.30443900 0.48756000 0.38541700 1 - O O73 1 0.48756000 0.38541700 0.30443900 1 - O O74 1 0.19556100 0.58097800 0.18312100 1 - O O75 1 0.01244000 0.31687900 0.89785700 1 - O O76 1 0.89785700 0.01244000 0.31687900 1 - O O77 1 0.60214300 0.91902200 0.11458300 1 - O O78 1 0.58097800 0.18312100 0.19556100 1 - O O79 1 0.88541700 0.98756000 0.80443900 1 -" -Li3V2(GeO4)3,mp-1013916,Ia-3d,[],0.09020315108929378,{'tags': []},"Full Formula (Li12 V8 Ge12 O48) -Reduced Formula: Li3V2(GeO4)3 -abc : 10.487069 10.487069 10.487069 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.625 0.875 0 - 1 Li 0.25 0.875 0.625 0 - 2 Li 0.625 0.25 0.875 0 - 3 Li 0.875 0.75 0.625 0 - 4 Li 0.875 0.625 0.25 0 - 5 Li 0.625 0.875 0.75 0 - 6 Li 0.25 0.375 0.125 0 - 7 Li 0.75 0.125 0.375 0 - 8 Li 0.375 0.75 0.125 0 - 9 Li 0.125 0.25 0.375 0 - 10 Li 0.125 0.375 0.75 0 - 11 Li 0.375 0.125 0.25 0 - 12 V 0.5 0 0.5 0.621 - 13 V 0 0.5 0 0.621 - 14 V 0.5 0.5 0.5 0.621 - 15 V 0 0 0.5 0.621 - 16 V 0 0 0 0.621 - 17 V 0 0.5 0.5 0.621 - 18 V 0.5 0.5 0 0.621 - 19 V 0.5 0 0 0.621 - 20 Ge 0.375 0.625 0.75 0.01 - 21 Ge 0.625 0.375 0.25 0.01 - 22 Ge 0.625 0.75 0.375 0.01 - 23 Ge 0.25 0.125 0.875 0.01 - 24 Ge 0.875 0.25 0.125 0.01 - 25 Ge 0.75 0.375 0.625 0.01 - 26 Ge 0.25 0.625 0.375 0.01 - 27 Ge 0.75 0.875 0.125 0.01 - 28 Ge 0.125 0.75 0.875 0.01 - 29 Ge 0.375 0.25 0.625 0.01 - 30 Ge 0.875 0.125 0.75 0.01 - 31 Ge 0.125 0.875 0.25 0.01 - 32 O 0.516538 0.399164 0.820625 -0.024 - 33 O 0.820625 0.516538 0.399164 -0.024 - 34 O 0.804087 0.882626 0.983462 -0.024 - 35 O 0.421461 0.100836 0.617374 -0.024 - 36 O 0.882626 0.399164 0.078539 -0.024 - 37 O 0.679375 0.078539 0.695913 -0.024 - 38 O 0.820625 0.804087 0.421461 -0.024 - 39 O 0.399164 0.820625 0.516538 -0.024 - 40 O 0.617374 0.695913 0.516538 -0.024 - 41 O 0.421461 0.820625 0.804087 -0.024 - 42 O 0.399164 0.078539 0.882626 -0.024 - 43 O 0.100836 0.983462 0.679375 -0.024 - 44 O 0.983462 0.679375 0.100836 -0.024 - 45 O 0.804087 0.421461 0.820625 -0.024 - 46 O 0.516538 0.617374 0.695913 -0.024 - 47 O 0.695913 0.516538 0.617374 -0.024 - 48 O 0.078539 0.882626 0.399164 -0.024 - 49 O 0.983462 0.804087 0.882626 -0.024 - 50 O 0.078539 0.695913 0.679375 -0.024 - 51 O 0.382626 0.304087 0.483462 -0.024 - 52 O 0.617374 0.421461 0.100836 -0.024 - 53 O 0.100836 0.617374 0.421461 -0.024 - 54 O 0.695913 0.679375 0.078539 -0.024 - 55 O 0.679375 0.100836 0.983462 -0.024 - 56 O 0.483462 0.600836 0.179375 -0.024 - 57 O 0.179375 0.483462 0.600836 -0.024 - 58 O 0.195913 0.117374 0.016538 -0.024 - 59 O 0.578539 0.899164 0.382626 -0.024 - 60 O 0.117374 0.600836 0.921461 -0.024 - 61 O 0.320625 0.921461 0.304087 -0.024 - 62 O 0.179375 0.195913 0.578539 -0.024 - 63 O 0.600836 0.179375 0.483462 -0.024 - 64 O 0.320625 0.899164 0.016538 -0.024 - 65 O 0.304087 0.320625 0.921461 -0.024 - 66 O 0.899164 0.382626 0.578539 -0.024 - 67 O 0.117374 0.016538 0.195913 -0.024 - 68 O 0.382626 0.578539 0.899164 -0.024 - 69 O 0.921461 0.304087 0.320625 -0.024 - 70 O 0.016538 0.195913 0.117374 -0.024 - 71 O 0.921461 0.117374 0.600836 -0.024 - 72 O 0.304087 0.483462 0.382626 -0.024 - 73 O 0.483462 0.382626 0.304087 -0.024 - 74 O 0.195913 0.578539 0.179375 -0.024 - 75 O 0.016538 0.320625 0.899164 -0.024 - 76 O 0.899164 0.016538 0.320625 -0.024 - 77 O 0.600836 0.921461 0.117374 -0.024 - 78 O 0.578539 0.179375 0.195913 -0.024 - 79 O 0.882626 0.983462 0.804087 -0.024","# generated using pymatgen -data_Li3V2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.48706881 -_cell_length_b 10.48706881 -_cell_length_c 10.48706881 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3V2(GeO4)3 -_chemical_formula_sum 'Li12 V8 Ge12 O48' -_cell_volume 887.85176411 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.62500000 0.87500000 1 - Li Li1 1 0.25000000 0.87500000 0.62500000 1 - Li Li2 1 0.62500000 0.25000000 0.87500000 1 - Li Li3 1 0.87500000 0.75000000 0.62500000 1 - Li Li4 1 0.87500000 0.62500000 0.25000000 1 - Li Li5 1 0.62500000 0.87500000 0.75000000 1 - Li Li6 1 0.25000000 0.37500000 0.12500000 1 - Li Li7 1 0.75000000 0.12500000 0.37500000 1 - Li Li8 1 0.37500000 0.75000000 0.12500000 1 - Li Li9 1 0.12500000 0.25000000 0.37500000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.37500000 0.12500000 0.25000000 1 - V V12 1 0.50000000 0.00000000 0.50000000 1 - V V13 1 0.00000000 0.50000000 0.00000000 1 - V V14 1 0.50000000 0.50000000 0.50000000 1 - V V15 1 0.00000000 0.00000000 0.50000000 1 - V V16 1 0.00000000 0.00000000 0.00000000 1 - V V17 1 0.00000000 0.50000000 0.50000000 1 - V V18 1 0.50000000 0.50000000 0.00000000 1 - V V19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51653800 0.39916400 0.82062500 1 - O O33 1 0.82062500 0.51653800 0.39916400 1 - O O34 1 0.80408700 0.88262600 0.98346200 1 - O O35 1 0.42146100 0.10083600 0.61737400 1 - O O36 1 0.88262600 0.39916400 0.07853900 1 - O O37 1 0.67937500 0.07853900 0.69591300 1 - O O38 1 0.82062500 0.80408700 0.42146100 1 - O O39 1 0.39916400 0.82062500 0.51653800 1 - O O40 1 0.61737400 0.69591300 0.51653800 1 - O O41 1 0.42146100 0.82062500 0.80408700 1 - O O42 1 0.39916400 0.07853900 0.88262600 1 - O O43 1 0.10083600 0.98346200 0.67937500 1 - O O44 1 0.98346200 0.67937500 0.10083600 1 - O O45 1 0.80408700 0.42146100 0.82062500 1 - O O46 1 0.51653800 0.61737400 0.69591300 1 - O O47 1 0.69591300 0.51653800 0.61737400 1 - O O48 1 0.07853900 0.88262600 0.39916400 1 - O O49 1 0.98346200 0.80408700 0.88262600 1 - O O50 1 0.07853900 0.69591300 0.67937500 1 - O O51 1 0.38262600 0.30408700 0.48346200 1 - O O52 1 0.61737400 0.42146100 0.10083600 1 - O O53 1 0.10083600 0.61737400 0.42146100 1 - O O54 1 0.69591300 0.67937500 0.07853900 1 - O O55 1 0.67937500 0.10083600 0.98346200 1 - O O56 1 0.48346200 0.60083600 0.17937500 1 - O O57 1 0.17937500 0.48346200 0.60083600 1 - O O58 1 0.19591300 0.11737400 0.01653800 1 - O O59 1 0.57853900 0.89916400 0.38262600 1 - O O60 1 0.11737400 0.60083600 0.92146100 1 - O O61 1 0.32062500 0.92146100 0.30408700 1 - O O62 1 0.17937500 0.19591300 0.57853900 1 - O O63 1 0.60083600 0.17937500 0.48346200 1 - O O64 1 0.32062500 0.89916400 0.01653800 1 - O O65 1 0.30408700 0.32062500 0.92146100 1 - O O66 1 0.89916400 0.38262600 0.57853900 1 - O O67 1 0.11737400 0.01653800 0.19591300 1 - O O68 1 0.38262600 0.57853900 0.89916400 1 - O O69 1 0.92146100 0.30408700 0.32062500 1 - O O70 1 0.01653800 0.19591300 0.11737400 1 - O O71 1 0.92146100 0.11737400 0.60083600 1 - O O72 1 0.30408700 0.48346200 0.38262600 1 - O O73 1 0.48346200 0.38262600 0.30408700 1 - O O74 1 0.19591300 0.57853900 0.17937500 1 - O O75 1 0.01653800 0.32062500 0.89916400 1 - O O76 1 0.89916400 0.01653800 0.32062500 1 - O O77 1 0.60083600 0.92146100 0.11737400 1 - O O78 1 0.57853900 0.17937500 0.19591300 1 - O O79 1 0.88262600 0.98346200 0.80408700 1 -" -Ca3Ga2(GeO4)3,mp-1019565,Ia-3d,[195450],0.0,"{'tags': ['garnet family', 'Tricalcium digallium tris(tetraoxogermanate)']}","Full Formula (Ca12 Ga8 Ge12 O48) -Reduced Formula: Ca3Ga2(GeO4)3 -abc : 10.737279 10.737279 10.737279 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0 - 1 Ca 0.75 0.125 0.375 -0 - 2 Ca 0.375 0.125 0.25 -0 - 3 Ca 0.125 0.375 0.75 -0 - 4 Ca 0.125 0.25 0.375 -0 - 5 Ca 0.375 0.75 0.125 -0 - 6 Ca 0.75 0.625 0.875 -0 - 7 Ca 0.25 0.875 0.625 -0 - 8 Ca 0.625 0.875 0.75 -0 - 9 Ca 0.875 0.625 0.25 -0 - 10 Ca 0.875 0.75 0.625 -0 - 11 Ca 0.625 0.25 0.875 -0 - 12 Ga 0 0.5 0 -0 - 13 Ga 0 0 0.5 -0 - 14 Ga 0.5 0 0 -0 - 15 Ga 0.5 0.5 0.5 -0 - 16 Ga 0.5 0.5 0 -0 - 17 Ga 0.5 0 0.5 -0 - 18 Ga 0 0.5 0.5 -0 - 19 Ga 0 0 0 -0 - 20 Ge 0.25 0.125 0.875 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.125 0.875 0.25 -0 - 23 Ge 0.375 0.625 0.75 -0 - 24 Ge 0.875 0.25 0.125 -0 - 25 Ge 0.625 0.75 0.375 -0 - 26 Ge 0.75 0.875 0.125 -0 - 27 Ge 0.25 0.625 0.375 -0 - 28 Ge 0.875 0.125 0.75 -0 - 29 Ge 0.625 0.375 0.25 -0 - 30 Ge 0.125 0.75 0.875 -0 - 31 Ge 0.375 0.25 0.625 -0 - 32 O 0.017604 0.315763 0.899755 0 - 33 O 0.916008 0.117849 0.600245 0 - 34 O 0.583992 0.184237 0.201841 0 - 35 O 0.482396 0.382151 0.298159 0 - 36 O 0.315763 0.899755 0.017604 0 - 37 O 0.117849 0.600245 0.916008 0 - 38 O 0.184237 0.201841 0.583992 0 - 39 O 0.382151 0.298159 0.482396 0 - 40 O 0.899755 0.017604 0.315763 0 - 41 O 0.600245 0.916008 0.117849 0 - 42 O 0.201841 0.583992 0.184237 0 - 43 O 0.298159 0.482396 0.382151 0 - 44 O 0.982396 0.684237 0.100245 0 - 45 O 0.083992 0.882151 0.399755 0 - 46 O 0.416008 0.815763 0.798159 0 - 47 O 0.517604 0.617849 0.701841 0 - 48 O 0.684237 0.100245 0.982396 0 - 49 O 0.882151 0.399755 0.083992 0 - 50 O 0.815763 0.798159 0.416008 0 - 51 O 0.617849 0.701841 0.517604 0 - 52 O 0.100245 0.982396 0.684237 0 - 53 O 0.399755 0.083992 0.882151 0 - 54 O 0.798159 0.416008 0.815763 0 - 55 O 0.701841 0.517604 0.617849 0 - 56 O 0.517604 0.399755 0.815763 0 - 57 O 0.416008 0.100245 0.617849 0 - 58 O 0.083992 0.701841 0.684237 0 - 59 O 0.982396 0.798159 0.882151 0 - 60 O 0.815763 0.517604 0.399755 0 - 61 O 0.617849 0.416008 0.100245 0 - 62 O 0.684237 0.083992 0.701841 0 - 63 O 0.882151 0.982396 0.798159 0 - 64 O 0.399755 0.815763 0.517604 0 - 65 O 0.100245 0.617849 0.416008 0 - 66 O 0.701841 0.684237 0.083992 0 - 67 O 0.798159 0.882151 0.982396 0 - 68 O 0.482396 0.600245 0.184237 0 - 69 O 0.583992 0.899755 0.382151 0 - 70 O 0.916008 0.298159 0.315763 0 - 71 O 0.017604 0.201841 0.117849 0 - 72 O 0.184237 0.482396 0.600245 0 - 73 O 0.382151 0.583992 0.899755 0 - 74 O 0.315763 0.916008 0.298159 0 - 75 O 0.117849 0.017604 0.201841 0 - 76 O 0.600245 0.184237 0.482396 0 - 77 O 0.899755 0.382151 0.583992 0 - 78 O 0.298159 0.315763 0.916008 0 - 79 O 0.201841 0.117849 0.017604 0","# generated using pymatgen -data_Ca3Ga2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.73727914 -_cell_length_b 10.73727914 -_cell_length_c 10.73727914 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ga2(GeO4)3 -_chemical_formula_sum 'Ca12 Ga8 Ge12 O48' -_cell_volume 952.92965001 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca5 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca6 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca7 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca8 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca11 1 0.62500000 0.25000000 0.87500000 1 - Ga Ga12 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga13 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga14 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga15 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga16 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga18 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge23 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge26 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge27 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge28 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge29 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge30 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.01760400 0.31576300 0.89975500 1 - O O33 1 0.91600800 0.11784900 0.60024500 1 - O O34 1 0.58399200 0.18423700 0.20184100 1 - O O35 1 0.48239600 0.38215100 0.29815900 1 - O O36 1 0.31576300 0.89975500 0.01760400 1 - O O37 1 0.11784900 0.60024500 0.91600800 1 - O O38 1 0.18423700 0.20184100 0.58399200 1 - O O39 1 0.38215100 0.29815900 0.48239600 1 - O O40 1 0.89975500 0.01760400 0.31576300 1 - O O41 1 0.60024500 0.91600800 0.11784900 1 - O O42 1 0.20184100 0.58399200 0.18423700 1 - O O43 1 0.29815900 0.48239600 0.38215100 1 - O O44 1 0.98239600 0.68423700 0.10024500 1 - O O45 1 0.08399200 0.88215100 0.39975500 1 - O O46 1 0.41600800 0.81576300 0.79815900 1 - O O47 1 0.51760400 0.61784900 0.70184100 1 - O O48 1 0.68423700 0.10024500 0.98239600 1 - O O49 1 0.88215100 0.39975500 0.08399200 1 - O O50 1 0.81576300 0.79815900 0.41600800 1 - O O51 1 0.61784900 0.70184100 0.51760400 1 - O O52 1 0.10024500 0.98239600 0.68423700 1 - O O53 1 0.39975500 0.08399200 0.88215100 1 - O O54 1 0.79815900 0.41600800 0.81576300 1 - O O55 1 0.70184100 0.51760400 0.61784900 1 - O O56 1 0.51760400 0.39975500 0.81576300 1 - O O57 1 0.41600800 0.10024500 0.61784900 1 - O O58 1 0.08399200 0.70184100 0.68423700 1 - O O59 1 0.98239600 0.79815900 0.88215100 1 - O O60 1 0.81576300 0.51760400 0.39975500 1 - O O61 1 0.61784900 0.41600800 0.10024500 1 - O O62 1 0.68423700 0.08399200 0.70184100 1 - O O63 1 0.88215100 0.98239600 0.79815900 1 - O O64 1 0.39975500 0.81576300 0.51760400 1 - O O65 1 0.10024500 0.61784900 0.41600800 1 - O O66 1 0.70184100 0.68423700 0.08399200 1 - O O67 1 0.79815900 0.88215100 0.98239600 1 - O O68 1 0.48239600 0.60024500 0.18423700 1 - O O69 1 0.58399200 0.89975500 0.38215100 1 - O O70 1 0.91600800 0.29815900 0.31576300 1 - O O71 1 0.01760400 0.20184100 0.11784900 1 - O O72 1 0.18423700 0.48239600 0.60024500 1 - O O73 1 0.38215100 0.58399200 0.89975500 1 - O O74 1 0.31576300 0.91600800 0.29815900 1 - O O75 1 0.11784900 0.01760400 0.20184100 1 - O O76 1 0.60024500 0.18423700 0.48239600 1 - O O77 1 0.89975500 0.38215100 0.58399200 1 - O O78 1 0.29815900 0.31576300 0.91600800 1 - O O79 1 0.20184100 0.11784900 0.01760400 1 -" -Na3Al2(PO4)3,mp-1020161,Ia-3d,[190755],0.03467887071874998,{'tags': ['Trisodium dialuminium triphosphate']},"Full Formula (Na12 Al8 P12 O48) -Reduced Formula: Na3Al2(PO4)3 -abc : 10.142108 10.142108 10.142108 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.125 0.375 0.75 0 - 1 Na 0.375 0.125 0.25 0 - 2 Na 0.375 0.75 0.125 0 - 3 Na 0.125 0.25 0.375 0 - 4 Na 0.75 0.125 0.375 0 - 5 Na 0.25 0.375 0.125 0 - 6 Na 0.875 0.625 0.25 0 - 7 Na 0.625 0.875 0.75 0 - 8 Na 0.625 0.25 0.875 0 - 9 Na 0.875 0.75 0.625 0 - 10 Na 0.25 0.875 0.625 0 - 11 Na 0.75 0.625 0.875 0 - 12 Al 0 0.5 0 0 - 13 Al 0 0 0.5 0 - 14 Al 0.5 0 0 0 - 15 Al 0.5 0.5 0.5 0 - 16 Al 0.5 0.5 0 0 - 17 Al 0.5 0 0.5 0 - 18 Al 0 0.5 0.5 0 - 19 Al 0 0 0 0 - 20 P 0.375 0.625 0.75 0 - 21 P 0.125 0.875 0.25 0 - 22 P 0.625 0.75 0.375 0 - 23 P 0.875 0.25 0.125 0 - 24 P 0.75 0.375 0.625 0 - 25 P 0.25 0.125 0.875 0 - 26 P 0.625 0.375 0.25 0 - 27 P 0.875 0.125 0.75 0 - 28 P 0.375 0.25 0.625 0 - 29 P 0.125 0.75 0.875 0 - 30 P 0.25 0.625 0.375 0 - 31 P 0.75 0.875 0.125 0 - 32 O 0.086018 0.889637 0.388966 -0 - 33 O 0.000672 0.697052 0.111034 -0 - 34 O 0.499328 0.610363 0.696381 -0 - 35 O 0.413982 0.802948 0.803619 -0 - 36 O 0.889637 0.388966 0.086018 -0 - 37 O 0.697052 0.111034 0.000672 -0 - 38 O 0.610363 0.696381 0.499328 -0 - 39 O 0.802948 0.803619 0.413982 -0 - 40 O 0.388966 0.086018 0.889637 -0 - 41 O 0.111034 0.000672 0.697052 -0 - 42 O 0.696381 0.499328 0.610363 -0 - 43 O 0.803619 0.413982 0.802948 -0 - 44 O 0.913982 0.110363 0.611034 -0 - 45 O 0.999328 0.302948 0.888966 -0 - 46 O 0.500672 0.389637 0.303619 -0 - 47 O 0.586018 0.197052 0.196381 -0 - 48 O 0.110363 0.611034 0.913982 -0 - 49 O 0.302948 0.888966 0.999328 -0 - 50 O 0.389637 0.303619 0.500672 -0 - 51 O 0.197052 0.196381 0.586018 -0 - 52 O 0.611034 0.913982 0.110363 -0 - 53 O 0.888966 0.999328 0.302948 -0 - 54 O 0.303619 0.500672 0.389637 -0 - 55 O 0.196381 0.586018 0.197052 -0 - 56 O 0.586018 0.888966 0.389637 -0 - 57 O 0.500672 0.611034 0.197052 -0 - 58 O 0.999328 0.196381 0.110363 -0 - 59 O 0.913982 0.303619 0.302948 -0 - 60 O 0.389637 0.586018 0.888966 -0 - 61 O 0.197052 0.500672 0.611034 -0 - 62 O 0.110363 0.999328 0.196381 -0 - 63 O 0.302948 0.913982 0.303619 -0 - 64 O 0.888966 0.389637 0.586018 -0 - 65 O 0.611034 0.197052 0.500672 -0 - 66 O 0.196381 0.110363 0.999328 -0 - 67 O 0.303619 0.302948 0.913982 -0 - 68 O 0.413982 0.111034 0.610363 -0 - 69 O 0.499328 0.388966 0.802948 -0 - 70 O 0.000672 0.803619 0.889637 -0 - 71 O 0.086018 0.696381 0.697052 -0 - 72 O 0.610363 0.413982 0.111034 -0 - 73 O 0.802948 0.499328 0.388966 -0 - 74 O 0.889637 0.000672 0.803619 -0 - 75 O 0.697052 0.086018 0.696381 -0 - 76 O 0.111034 0.610363 0.413982 -0 - 77 O 0.388966 0.802948 0.499328 -0 - 78 O 0.803619 0.889637 0.000672 -0 - 79 O 0.696381 0.697052 0.086018 -0","# generated using pymatgen -data_Na3Al2(PO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.14210837 -_cell_length_b 10.14210837 -_cell_length_c 10.14210837 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Al2(PO4)3 -_chemical_formula_sum 'Na12 Al8 P12 O48' -_cell_volume 803.08747007 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.12500000 0.37500000 0.75000000 1 - Na Na1 1 0.37500000 0.12500000 0.25000000 1 - Na Na2 1 0.37500000 0.75000000 0.12500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.75000000 0.12500000 0.37500000 1 - Na Na5 1 0.25000000 0.37500000 0.12500000 1 - Na Na6 1 0.87500000 0.62500000 0.25000000 1 - Na Na7 1 0.62500000 0.87500000 0.75000000 1 - Na Na8 1 0.62500000 0.25000000 0.87500000 1 - Na Na9 1 0.87500000 0.75000000 0.62500000 1 - Na Na10 1 0.25000000 0.87500000 0.62500000 1 - Na Na11 1 0.75000000 0.62500000 0.87500000 1 - Al Al12 1 0.00000000 0.50000000 0.00000000 1 - Al Al13 1 0.00000000 0.00000000 0.50000000 1 - Al Al14 1 0.50000000 0.00000000 0.00000000 1 - Al Al15 1 0.50000000 0.50000000 0.50000000 1 - Al Al16 1 0.50000000 0.50000000 0.00000000 1 - Al Al17 1 0.50000000 0.00000000 0.50000000 1 - Al Al18 1 0.00000000 0.50000000 0.50000000 1 - Al Al19 1 0.00000000 0.00000000 0.00000000 1 - P P20 1 0.37500000 0.62500000 0.75000000 1 - P P21 1 0.12500000 0.87500000 0.25000000 1 - P P22 1 0.62500000 0.75000000 0.37500000 1 - P P23 1 0.87500000 0.25000000 0.12500000 1 - P P24 1 0.75000000 0.37500000 0.62500000 1 - P P25 1 0.25000000 0.12500000 0.87500000 1 - P P26 1 0.62500000 0.37500000 0.25000000 1 - P P27 1 0.87500000 0.12500000 0.75000000 1 - P P28 1 0.37500000 0.25000000 0.62500000 1 - P P29 1 0.12500000 0.75000000 0.87500000 1 - P P30 1 0.25000000 0.62500000 0.37500000 1 - P P31 1 0.75000000 0.87500000 0.12500000 1 - O O32 1 0.08601800 0.88963700 0.38896600 1 - O O33 1 0.00067200 0.69705200 0.11103400 1 - O O34 1 0.49932800 0.61036300 0.69638100 1 - O O35 1 0.41398200 0.80294800 0.80361900 1 - O O36 1 0.88963700 0.38896600 0.08601800 1 - O O37 1 0.69705200 0.11103400 0.00067200 1 - O O38 1 0.61036300 0.69638100 0.49932800 1 - O O39 1 0.80294800 0.80361900 0.41398200 1 - O O40 1 0.38896600 0.08601800 0.88963700 1 - O O41 1 0.11103400 0.00067200 0.69705200 1 - O O42 1 0.69638100 0.49932800 0.61036300 1 - O O43 1 0.80361900 0.41398200 0.80294800 1 - O O44 1 0.91398200 0.11036300 0.61103400 1 - O O45 1 0.99932800 0.30294800 0.88896600 1 - O O46 1 0.50067200 0.38963700 0.30361900 1 - O O47 1 0.58601800 0.19705200 0.19638100 1 - O O48 1 0.11036300 0.61103400 0.91398200 1 - O O49 1 0.30294800 0.88896600 0.99932800 1 - O O50 1 0.38963700 0.30361900 0.50067200 1 - O O51 1 0.19705200 0.19638100 0.58601800 1 - O O52 1 0.61103400 0.91398200 0.11036300 1 - O O53 1 0.88896600 0.99932800 0.30294800 1 - O O54 1 0.30361900 0.50067200 0.38963700 1 - O O55 1 0.19638100 0.58601800 0.19705200 1 - O O56 1 0.58601800 0.88896600 0.38963700 1 - O O57 1 0.50067200 0.61103400 0.19705200 1 - O O58 1 0.99932800 0.19638100 0.11036300 1 - O O59 1 0.91398200 0.30361900 0.30294800 1 - O O60 1 0.38963700 0.58601800 0.88896600 1 - O O61 1 0.19705200 0.50067200 0.61103400 1 - O O62 1 0.11036300 0.99932800 0.19638100 1 - O O63 1 0.30294800 0.91398200 0.30361900 1 - O O64 1 0.88896600 0.38963700 0.58601800 1 - O O65 1 0.61103400 0.19705200 0.50067200 1 - O O66 1 0.19638100 0.11036300 0.99932800 1 - O O67 1 0.30361900 0.30294800 0.91398200 1 - O O68 1 0.41398200 0.11103400 0.61036300 1 - O O69 1 0.49932800 0.38896600 0.80294800 1 - O O70 1 0.00067200 0.80361900 0.88963700 1 - O O71 1 0.08601800 0.69638100 0.69705200 1 - O O72 1 0.61036300 0.41398200 0.11103400 1 - O O73 1 0.80294800 0.49932800 0.38896600 1 - O O74 1 0.88963700 0.00067200 0.80361900 1 - O O75 1 0.69705200 0.08601800 0.69638100 1 - O O76 1 0.11103400 0.61036300 0.41398200 1 - O O77 1 0.38896600 0.80294800 0.49932800 1 - O O78 1 0.80361900 0.88963700 0.00067200 1 - O O79 1 0.69638100 0.69705200 0.08601800 1 -" -Al2Cu3(SiO4)3,mp-1154457,Ia-3d,[],0.17217967150000124,{'tags': []},"Full Formula (Al8 Cu12 Si12 O48) -Reduced Formula: Al2Cu3(SiO4)3 -abc : 10.083444 10.083444 10.083444 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0 -0.002 - 1 Al 0.5 0 0 -0.002 - 2 Al 0.5 0.5 0 -0.002 - 3 Al 0 0.5 0.5 -0.002 - 4 Al 0 0 0.5 -0.002 - 5 Al 0.5 0.5 0.5 -0.002 - 6 Al 0 0.5 0 -0.002 - 7 Al 0.5 0 0.5 -0.002 - 8 Cu 0.875 0.75 0.625 0.592 - 9 Cu 0.875 0.625 0.25 0.592 - 10 Cu 0.625 0.875 0.75 0.592 - 11 Cu 0.25 0.875 0.625 0.592 - 12 Cu 0.75 0.625 0.875 0.592 - 13 Cu 0.625 0.25 0.875 0.592 - 14 Cu 0.125 0.25 0.375 0.592 - 15 Cu 0.125 0.375 0.75 0.592 - 16 Cu 0.375 0.125 0.25 0.592 - 17 Cu 0.75 0.125 0.375 0.592 - 18 Cu 0.25 0.375 0.125 0.592 - 19 Cu 0.375 0.75 0.125 0.592 - 20 Si 0.125 0.75 0.875 -0.003 - 21 Si 0.75 0.875 0.125 -0.003 - 22 Si 0.25 0.625 0.375 -0.003 - 23 Si 0.625 0.75 0.375 -0.003 - 24 Si 0.875 0.125 0.75 -0.003 - 25 Si 0.375 0.25 0.625 -0.003 - 26 Si 0.375 0.625 0.75 -0.003 - 27 Si 0.25 0.125 0.875 -0.003 - 28 Si 0.625 0.375 0.25 -0.003 - 29 Si 0.125 0.875 0.25 -0.003 - 30 Si 0.75 0.375 0.625 -0.003 - 31 Si 0.875 0.25 0.125 -0.003 - 32 O 0.575554 0.890946 0.377922 0.092 - 33 O 0.377922 0.575554 0.890946 0.092 - 34 O 0.302368 0.315392 0.924446 0.092 - 35 O 0.486976 0.609054 0.184608 0.092 - 36 O 0.315392 0.890946 0.013024 0.092 - 37 O 0.122078 0.013024 0.197632 0.092 - 38 O 0.377922 0.302368 0.486976 0.092 - 39 O 0.890946 0.377922 0.575554 0.092 - 40 O 0.184608 0.197632 0.575554 0.092 - 41 O 0.486976 0.377922 0.302368 0.092 - 42 O 0.890946 0.013024 0.315392 0.092 - 43 O 0.609054 0.924446 0.122078 0.092 - 44 O 0.924446 0.122078 0.609054 0.092 - 45 O 0.302368 0.486976 0.377922 0.092 - 46 O 0.575554 0.184608 0.197632 0.092 - 47 O 0.197632 0.575554 0.184608 0.092 - 48 O 0.013024 0.315392 0.890946 0.092 - 49 O 0.924446 0.302368 0.315392 0.092 - 50 O 0.013024 0.197632 0.122078 0.092 - 51 O 0.815392 0.802368 0.424446 0.092 - 52 O 0.315392 0.924446 0.302368 0.092 - 53 O 0.609054 0.184608 0.486976 0.092 - 54 O 0.197632 0.122078 0.013024 0.092 - 55 O 0.122078 0.609054 0.924446 0.092 - 56 O 0.424446 0.109054 0.622078 0.092 - 57 O 0.622078 0.424446 0.109054 0.092 - 58 O 0.697632 0.684608 0.075554 0.092 - 59 O 0.513024 0.390946 0.815392 0.092 - 60 O 0.684608 0.109054 0.986976 0.092 - 61 O 0.877922 0.986976 0.802368 0.092 - 62 O 0.622078 0.697632 0.513024 0.092 - 63 O 0.109054 0.622078 0.424446 0.092 - 64 O 0.877922 0.390946 0.075554 0.092 - 65 O 0.802368 0.877922 0.986976 0.092 - 66 O 0.390946 0.815392 0.513024 0.092 - 67 O 0.684608 0.075554 0.697632 0.092 - 68 O 0.815392 0.513024 0.390946 0.092 - 69 O 0.986976 0.802368 0.877922 0.092 - 70 O 0.075554 0.697632 0.684608 0.092 - 71 O 0.986976 0.684608 0.109054 0.092 - 72 O 0.802368 0.424446 0.815392 0.092 - 73 O 0.424446 0.815392 0.802368 0.092 - 74 O 0.697632 0.513024 0.622078 0.092 - 75 O 0.075554 0.877922 0.390946 0.092 - 76 O 0.390946 0.075554 0.877922 0.092 - 77 O 0.109054 0.986976 0.684608 0.092 - 78 O 0.513024 0.622078 0.697632 0.092 - 79 O 0.184608 0.486976 0.609054 0.092","# generated using pymatgen -data_Al2Cu3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.08344381 -_cell_length_b 10.08344381 -_cell_length_c 10.08344381 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Cu3(SiO4)3 -_chemical_formula_sum 'Al8 Cu12 Si12 O48' -_cell_volume 789.23213002 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.00000000 1 - Al Al1 1 0.50000000 0.00000000 0.00000000 1 - Al Al2 1 0.50000000 0.50000000 0.00000000 1 - Al Al3 1 0.00000000 0.50000000 0.50000000 1 - Al Al4 1 0.00000000 0.00000000 0.50000000 1 - Al Al5 1 0.50000000 0.50000000 0.50000000 1 - Al Al6 1 0.00000000 0.50000000 0.00000000 1 - Al Al7 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu8 1 0.87500000 0.75000000 0.62500000 1 - Cu Cu9 1 0.87500000 0.62500000 0.25000000 1 - Cu Cu10 1 0.62500000 0.87500000 0.75000000 1 - Cu Cu11 1 0.25000000 0.87500000 0.62500000 1 - Cu Cu12 1 0.75000000 0.62500000 0.87500000 1 - Cu Cu13 1 0.62500000 0.25000000 0.87500000 1 - Cu Cu14 1 0.12500000 0.25000000 0.37500000 1 - Cu Cu15 1 0.12500000 0.37500000 0.75000000 1 - Cu Cu16 1 0.37500000 0.12500000 0.25000000 1 - Cu Cu17 1 0.75000000 0.12500000 0.37500000 1 - Cu Cu18 1 0.25000000 0.37500000 0.12500000 1 - Cu Cu19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.87500000 0.12500000 0.75000000 1 - Si Si25 1 0.37500000 0.25000000 0.62500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.25000000 0.12500000 0.87500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.12500000 0.87500000 0.25000000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.87500000 0.25000000 0.12500000 1 - O O32 1 0.57555400 0.89094600 0.37792200 1 - O O33 1 0.37792200 0.57555400 0.89094600 1 - O O34 1 0.30236800 0.31539200 0.92444600 1 - O O35 1 0.48697600 0.60905400 0.18460800 1 - O O36 1 0.31539200 0.89094600 0.01302400 1 - O O37 1 0.12207800 0.01302400 0.19763200 1 - O O38 1 0.37792200 0.30236800 0.48697600 1 - O O39 1 0.89094600 0.37792200 0.57555400 1 - O O40 1 0.18460800 0.19763200 0.57555400 1 - O O41 1 0.48697600 0.37792200 0.30236800 1 - O O42 1 0.89094600 0.01302400 0.31539200 1 - O O43 1 0.60905400 0.92444600 0.12207800 1 - O O44 1 0.92444600 0.12207800 0.60905400 1 - O O45 1 0.30236800 0.48697600 0.37792200 1 - O O46 1 0.57555400 0.18460800 0.19763200 1 - O O47 1 0.19763200 0.57555400 0.18460800 1 - O O48 1 0.01302400 0.31539200 0.89094600 1 - O O49 1 0.92444600 0.30236800 0.31539200 1 - O O50 1 0.01302400 0.19763200 0.12207800 1 - O O51 1 0.81539200 0.80236800 0.42444600 1 - O O52 1 0.31539200 0.92444600 0.30236800 1 - O O53 1 0.60905400 0.18460800 0.48697600 1 - O O54 1 0.19763200 0.12207800 0.01302400 1 - O O55 1 0.12207800 0.60905400 0.92444600 1 - O O56 1 0.42444600 0.10905400 0.62207800 1 - O O57 1 0.62207800 0.42444600 0.10905400 1 - O O58 1 0.69763200 0.68460800 0.07555400 1 - O O59 1 0.51302400 0.39094600 0.81539200 1 - O O60 1 0.68460800 0.10905400 0.98697600 1 - O O61 1 0.87792200 0.98697600 0.80236800 1 - O O62 1 0.62207800 0.69763200 0.51302400 1 - O O63 1 0.10905400 0.62207800 0.42444600 1 - O O64 1 0.87792200 0.39094600 0.07555400 1 - O O65 1 0.80236800 0.87792200 0.98697600 1 - O O66 1 0.39094600 0.81539200 0.51302400 1 - O O67 1 0.68460800 0.07555400 0.69763200 1 - O O68 1 0.81539200 0.51302400 0.39094600 1 - O O69 1 0.98697600 0.80236800 0.87792200 1 - O O70 1 0.07555400 0.69763200 0.68460800 1 - O O71 1 0.98697600 0.68460800 0.10905400 1 - O O72 1 0.80236800 0.42444600 0.81539200 1 - O O73 1 0.42444600 0.81539200 0.80236800 1 - O O74 1 0.69763200 0.51302400 0.62207800 1 - O O75 1 0.07555400 0.87792200 0.39094600 1 - O O76 1 0.39094600 0.07555400 0.87792200 1 - O O77 1 0.10905400 0.98697600 0.68460800 1 - O O78 1 0.51302400 0.62207800 0.69763200 1 - O O79 1 0.18460800 0.48697600 0.60905400 1 -" -Ca3Ti2(SiO4)3,mp-1154470,Ia-3d,[],0.023295220124968097,{'tags': []},"Full Formula (Ca12 Ti8 Si12 O48) -Reduced Formula: Ca3Ti2(SiO4)3 -abc : 10.629589 10.629589 10.629589 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.75 0.125 0.375 0.003 - 1 Ca 0.25 0.375 0.125 0.004 - 2 Ca 0.125 0.25 0.375 0.004 - 3 Ca 0.375 0.75 0.125 0.004 - 4 Ca 0.75 0.625 0.875 0.004 - 5 Ca 0.125 0.375 0.75 0.004 - 6 Ca 0.625 0.875 0.75 0.004 - 7 Ca 0.25 0.875 0.625 0.003 - 8 Ca 0.875 0.625 0.25 0.004 - 9 Ca 0.625 0.25 0.875 0.004 - 10 Ca 0.875 0.75 0.625 0.004 - 11 Ca 0.375 0.125 0.25 0.004 - 12 Ti 0 0 0 0.864 - 13 Ti 0.5 0 0 0.869 - 14 Ti 0 0.5 0 0.864 - 15 Ti 0.5 0.5 0 0.864 - 16 Ti 0 0.5 0.5 0.869 - 17 Ti 0.5 0 0.5 0.869 - 18 Ti 0.5 0.5 0.5 0.864 - 19 Ti 0 0 0.5 0.869 - 20 Si 0.125 0.875 0.25 0.013 - 21 Si 0.875 0.125 0.75 0.013 - 22 Si 0.25 0.625 0.375 0.012 - 23 Si 0.375 0.25 0.625 0.013 - 24 Si 0.75 0.875 0.125 0.012 - 25 Si 0.125 0.75 0.875 0.013 - 26 Si 0.375 0.625 0.75 0.013 - 27 Si 0.625 0.75 0.375 0.013 - 28 Si 0.875 0.25 0.125 0.013 - 29 Si 0.25 0.125 0.875 0.012 - 30 Si 0.75 0.375 0.625 0.012 - 31 Si 0.625 0.375 0.25 0.013 - 32 O 0.492084 0.383776 0.295827 -0 - 33 O 0.303743 0.891692 0.007916 0 - 34 O 0.608308 0.912051 0.116224 -0.001 - 35 O 0.587949 0.196257 0.204173 -0.001 - 36 O 0.116224 0.007916 0.204173 -0.002 - 37 O 0.196257 0.204173 0.587949 0 - 38 O 0.196257 0.492084 0.608308 0 - 39 O 0.204173 0.587949 0.196257 -0.001 - 40 O 0.383776 0.587949 0.891692 -0.002 - 41 O 0.912051 0.295827 0.303743 -0.001 - 42 O 0.295827 0.303743 0.912051 -0.001 - 43 O 0.204173 0.116224 0.007916 -0.001 - 44 O 0.492084 0.608308 0.196257 -0 - 45 O 0.891692 0.383776 0.587949 -0.001 - 46 O 0.007916 0.204173 0.116224 -0 - 47 O 0.608308 0.196257 0.492084 -0.001 - 48 O 0.587949 0.891692 0.383776 -0.001 - 49 O 0.007916 0.303743 0.891692 -0 - 50 O 0.912051 0.116224 0.608308 -0.001 - 51 O 0.616224 0.412051 0.108308 -0.002 - 52 O 0.116224 0.608308 0.912051 -0.002 - 53 O 0.295827 0.492084 0.383776 -0.001 - 54 O 0.891692 0.007916 0.303743 -0.001 - 55 O 0.303743 0.912051 0.295827 0 - 56 O 0.507916 0.616224 0.704173 -0 - 57 O 0.696257 0.108308 0.992084 0 - 58 O 0.391692 0.087949 0.883776 -0.001 - 59 O 0.412051 0.803743 0.795827 -0.001 - 60 O 0.883776 0.992084 0.795827 -0.002 - 61 O 0.803743 0.795827 0.412051 0 - 62 O 0.803743 0.507916 0.391692 0 - 63 O 0.795827 0.412051 0.803743 -0.001 - 64 O 0.696257 0.087949 0.704173 0 - 65 O 0.108308 0.992084 0.696257 -0.001 - 66 O 0.704173 0.507916 0.616224 -0.001 - 67 O 0.616224 0.704173 0.507916 -0.002 - 68 O 0.883776 0.391692 0.087949 -0.002 - 69 O 0.087949 0.883776 0.391692 -0.001 - 70 O 0.992084 0.696257 0.108308 -0 - 71 O 0.412051 0.108308 0.616224 -0.001 - 72 O 0.391692 0.803743 0.507916 -0.001 - 73 O 0.992084 0.795827 0.883776 -0 - 74 O 0.108308 0.616224 0.412051 -0.001 - 75 O 0.507916 0.391692 0.803743 -0 - 76 O 0.795827 0.883776 0.992084 -0.001 - 77 O 0.704173 0.696257 0.087949 -0.001 - 78 O 0.087949 0.704173 0.696257 -0.001 - 79 O 0.383776 0.295827 0.492084 -0.002","# generated using pymatgen -data_Ca3Ti2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.62958888 -_cell_length_b 10.62958888 -_cell_length_c 10.62958888 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ti2(SiO4)3 -_chemical_formula_sum 'Ca12 Ti8 Si12 O48' -_cell_volume 924.54384560 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca1 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca2 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca3 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca4 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca5 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca6 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca7 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca8 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca10 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca11 1 0.37500000 0.12500000 0.25000000 1 - Ti Ti12 1 0.00000000 0.00000000 0.00000000 1 - Ti Ti13 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti14 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti15 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti16 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti17 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti18 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti19 1 0.00000000 0.00000000 0.50000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.49208400 0.38377600 0.29582700 1 - O O33 1 0.30374300 0.89169200 0.00791600 1 - O O34 1 0.60830800 0.91205100 0.11622400 1 - O O35 1 0.58794900 0.19625700 0.20417300 1 - O O36 1 0.11622400 0.00791600 0.20417300 1 - O O37 1 0.19625700 0.20417300 0.58794900 1 - O O38 1 0.19625700 0.49208400 0.60830800 1 - O O39 1 0.20417300 0.58794900 0.19625700 1 - O O40 1 0.38377600 0.58794900 0.89169200 1 - O O41 1 0.91205100 0.29582700 0.30374300 1 - O O42 1 0.29582700 0.30374300 0.91205100 1 - O O43 1 0.20417300 0.11622400 0.00791600 1 - O O44 1 0.49208400 0.60830800 0.19625700 1 - O O45 1 0.89169200 0.38377600 0.58794900 1 - O O46 1 0.00791600 0.20417300 0.11622400 1 - O O47 1 0.60830800 0.19625700 0.49208400 1 - O O48 1 0.58794900 0.89169200 0.38377600 1 - O O49 1 0.00791600 0.30374300 0.89169200 1 - O O50 1 0.91205100 0.11622400 0.60830800 1 - O O51 1 0.61622400 0.41205100 0.10830800 1 - O O52 1 0.11622400 0.60830800 0.91205100 1 - O O53 1 0.29582700 0.49208400 0.38377600 1 - O O54 1 0.89169200 0.00791600 0.30374300 1 - O O55 1 0.30374300 0.91205100 0.29582700 1 - O O56 1 0.50791600 0.61622400 0.70417300 1 - O O57 1 0.69625700 0.10830800 0.99208400 1 - O O58 1 0.39169200 0.08794900 0.88377600 1 - O O59 1 0.41205100 0.80374300 0.79582700 1 - O O60 1 0.88377600 0.99208400 0.79582700 1 - O O61 1 0.80374300 0.79582700 0.41205100 1 - O O62 1 0.80374300 0.50791600 0.39169200 1 - O O63 1 0.79582700 0.41205100 0.80374300 1 - O O64 1 0.69625700 0.08794900 0.70417300 1 - O O65 1 0.10830800 0.99208400 0.69625700 1 - O O66 1 0.70417300 0.50791600 0.61622400 1 - O O67 1 0.61622400 0.70417300 0.50791600 1 - O O68 1 0.88377600 0.39169200 0.08794900 1 - O O69 1 0.08794900 0.88377600 0.39169200 1 - O O70 1 0.99208400 0.69625700 0.10830800 1 - O O71 1 0.41205100 0.10830800 0.61622400 1 - O O72 1 0.39169200 0.80374300 0.50791600 1 - O O73 1 0.99208400 0.79582700 0.88377600 1 - O O74 1 0.10830800 0.61622400 0.41205100 1 - O O75 1 0.50791600 0.39169200 0.80374300 1 - O O76 1 0.79582700 0.88377600 0.99208400 1 - O O77 1 0.70417300 0.69625700 0.08794900 1 - O O78 1 0.08794900 0.70417300 0.69625700 1 - O O79 1 0.38377600 0.29582700 0.49208400 1 -" -Mg3Si3(AgO6)2,mp-1154476,Ia-3d,[],0.2025084179166612,{'tags': []},"Full Formula (Mg12 Si12 Ag8 O48) -Reduced Formula: Mg3Si3(AgO6)2 -abc : 10.419115 10.419115 10.419115 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 -0 - 1 Mg 0.75 0.125 0.375 -0 - 2 Mg 0.375 0.125 0.25 -0 - 3 Mg 0.125 0.375 0.75 -0 - 4 Mg 0.25 0.875 0.625 -0 - 5 Mg 0.125 0.25 0.375 0 - 6 Mg 0.625 0.25 0.875 0 - 7 Mg 0.75 0.625 0.875 -0 - 8 Mg 0.875 0.75 0.625 0 - 9 Mg 0.875 0.625 0.25 -0 - 10 Mg 0.625 0.875 0.75 -0 - 11 Mg 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 -0 - 13 Si 0.875 0.25 0.125 -0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 -0 - 16 Si 0.25 0.125 0.875 0 - 17 Si 0.375 0.625 0.75 0 - 18 Si 0.375 0.25 0.625 -0 - 19 Si 0.875 0.125 0.75 -0 - 20 Si 0.625 0.375 0.25 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 -0 - 24 Ag 0.5 0 0 0.001 - 25 Ag 0.5 0.5 0 -0.001 - 26 Ag 0 0.5 0.5 0 - 27 Ag 0 0 0.5 -0 - 28 Ag 0.5 0.5 0.5 0 - 29 Ag 0 0.5 0 0.001 - 30 Ag 0.5 0 0.5 -0.001 - 31 Ag 0 0 0 -0 - 32 O 0.597776 0.896954 0.368592 -0.001 - 33 O 0.368592 0.597776 0.896954 -0 - 34 O 0.270816 0.299179 0.902224 0 - 35 O 0.471637 0.603046 0.200821 -0.001 - 36 O 0.299179 0.896954 0.028363 -0 - 37 O 0.131408 0.028363 0.229184 0 - 38 O 0.368592 0.270816 0.471637 -0 - 39 O 0.896954 0.368592 0.597776 -0 - 40 O 0.200821 0.229184 0.597776 -0.001 - 41 O 0.471637 0.368592 0.270816 0 - 42 O 0.896954 0.028363 0.299179 0 - 43 O 0.603046 0.902224 0.131408 0.001 - 44 O 0.902224 0.131408 0.603046 0 - 45 O 0.270816 0.471637 0.368592 0 - 46 O 0.597776 0.200821 0.229184 0 - 47 O 0.229184 0.597776 0.200821 0 - 48 O 0.028363 0.299179 0.896954 -0 - 49 O 0.902224 0.270816 0.299179 -0.001 - 50 O 0.028363 0.229184 0.131408 -0 - 51 O 0.799179 0.770816 0.402224 -0.001 - 52 O 0.200821 0.471637 0.603046 0.001 - 53 O 0.603046 0.200821 0.471637 -0 - 54 O 0.229184 0.131408 0.028363 0 - 55 O 0.131408 0.603046 0.902224 0 - 56 O 0.402224 0.103046 0.631408 -0.001 - 57 O 0.631408 0.402224 0.103046 -0 - 58 O 0.729184 0.700821 0.097776 0 - 59 O 0.528363 0.396954 0.799179 -0.001 - 60 O 0.700821 0.103046 0.971637 -0 - 61 O 0.868592 0.971637 0.770816 0 - 62 O 0.631408 0.729184 0.528363 -0 - 63 O 0.103046 0.631408 0.402224 -0 - 64 O 0.868592 0.396954 0.097776 0 - 65 O 0.770816 0.868592 0.971637 0 - 66 O 0.396954 0.799179 0.528363 -0 - 67 O 0.700821 0.097776 0.729184 0 - 68 O 0.799179 0.528363 0.396954 0.001 - 69 O 0.971637 0.770816 0.868592 -0 - 70 O 0.097776 0.729184 0.700821 -0.001 - 71 O 0.971637 0.700821 0.103046 -0 - 72 O 0.770816 0.402224 0.799179 0 - 73 O 0.402224 0.799179 0.770816 0 - 74 O 0.729184 0.528363 0.631408 0 - 75 O 0.097776 0.868592 0.396954 0 - 76 O 0.396954 0.097776 0.868592 0.001 - 77 O 0.103046 0.971637 0.700821 0 - 78 O 0.528363 0.631408 0.729184 0 - 79 O 0.299179 0.902224 0.270816 0","# generated using pymatgen -data_Mg3Si3(AgO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.41911526 -_cell_length_b 10.41911526 -_cell_length_c 10.41911526 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Si3(AgO6)2 -_chemical_formula_sum 'Mg12 Si12 Ag8 O48' -_cell_volume 870.70419399 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Ag Ag24 1 0.50000000 0.00000000 0.00000000 1 - Ag Ag25 1 0.50000000 0.50000000 0.00000000 1 - Ag Ag26 1 0.00000000 0.50000000 0.50000000 1 - Ag Ag27 1 0.00000000 0.00000000 0.50000000 1 - Ag Ag28 1 0.50000000 0.50000000 0.50000000 1 - Ag Ag29 1 0.00000000 0.50000000 0.00000000 1 - Ag Ag30 1 0.50000000 0.00000000 0.50000000 1 - Ag Ag31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59777600 0.89695400 0.36859200 1 - O O33 1 0.36859200 0.59777600 0.89695400 1 - O O34 1 0.27081600 0.29917900 0.90222400 1 - O O35 1 0.47163700 0.60304600 0.20082100 1 - O O36 1 0.29917900 0.89695400 0.02836300 1 - O O37 1 0.13140800 0.02836300 0.22918400 1 - O O38 1 0.36859200 0.27081600 0.47163700 1 - O O39 1 0.89695400 0.36859200 0.59777600 1 - O O40 1 0.20082100 0.22918400 0.59777600 1 - O O41 1 0.47163700 0.36859200 0.27081600 1 - O O42 1 0.89695400 0.02836300 0.29917900 1 - O O43 1 0.60304600 0.90222400 0.13140800 1 - O O44 1 0.90222400 0.13140800 0.60304600 1 - O O45 1 0.27081600 0.47163700 0.36859200 1 - O O46 1 0.59777600 0.20082100 0.22918400 1 - O O47 1 0.22918400 0.59777600 0.20082100 1 - O O48 1 0.02836300 0.29917900 0.89695400 1 - O O49 1 0.90222400 0.27081600 0.29917900 1 - O O50 1 0.02836300 0.22918400 0.13140800 1 - O O51 1 0.79917900 0.77081600 0.40222400 1 - O O52 1 0.20082100 0.47163700 0.60304600 1 - O O53 1 0.60304600 0.20082100 0.47163700 1 - O O54 1 0.22918400 0.13140800 0.02836300 1 - O O55 1 0.13140800 0.60304600 0.90222400 1 - O O56 1 0.40222400 0.10304600 0.63140800 1 - O O57 1 0.63140800 0.40222400 0.10304600 1 - O O58 1 0.72918400 0.70082100 0.09777600 1 - O O59 1 0.52836300 0.39695400 0.79917900 1 - O O60 1 0.70082100 0.10304600 0.97163700 1 - O O61 1 0.86859200 0.97163700 0.77081600 1 - O O62 1 0.63140800 0.72918400 0.52836300 1 - O O63 1 0.10304600 0.63140800 0.40222400 1 - O O64 1 0.86859200 0.39695400 0.09777600 1 - O O65 1 0.77081600 0.86859200 0.97163700 1 - O O66 1 0.39695400 0.79917900 0.52836300 1 - O O67 1 0.70082100 0.09777600 0.72918400 1 - O O68 1 0.79917900 0.52836300 0.39695400 1 - O O69 1 0.97163700 0.77081600 0.86859200 1 - O O70 1 0.09777600 0.72918400 0.70082100 1 - O O71 1 0.97163700 0.70082100 0.10304600 1 - O O72 1 0.77081600 0.40222400 0.79917900 1 - O O73 1 0.40222400 0.79917900 0.77081600 1 - O O74 1 0.72918400 0.52836300 0.63140800 1 - O O75 1 0.09777600 0.86859200 0.39695400 1 - O O76 1 0.39695400 0.09777600 0.86859200 1 - O O77 1 0.10304600 0.97163700 0.70082100 1 - O O78 1 0.52836300 0.63140800 0.72918400 1 - O O79 1 0.29917900 0.90222400 0.27081600 1 -" -Y2Mn3(SiO4)3,mp-1154524,Ia-3d,[],0.11522715133332895,{'tags': []},"Full Formula (Y8 Mn12 Si12 O48) -Reduced Formula: Y2Mn3(SiO4)3 -abc : 10.781358 10.781358 10.781358 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0.5 -0.004 - 1 Y 0 0 0 -0.004 - 2 Y 0.5 0 0 -0.004 - 3 Y 0 0.5 0 -0.004 - 4 Y 0.5 0.5 0 -0.004 - 5 Y 0 0.5 0.5 -0.004 - 6 Y 0.5 0 0.5 -0.004 - 7 Y 0.5 0.5 0.5 -0.004 - 8 Mn 0.875 0.625 0.25 4.674 - 9 Mn 0.625 0.25 0.875 4.674 - 10 Mn 0.875 0.75 0.625 4.674 - 11 Mn 0.75 0.625 0.875 4.674 - 12 Mn 0.25 0.875 0.625 4.674 - 13 Mn 0.625 0.875 0.75 4.674 - 14 Mn 0.125 0.375 0.75 4.674 - 15 Mn 0.375 0.75 0.125 4.674 - 16 Mn 0.125 0.25 0.375 4.674 - 17 Mn 0.25 0.375 0.125 4.674 - 18 Mn 0.75 0.125 0.375 4.674 - 19 Mn 0.375 0.125 0.25 4.674 - 20 Si 0.125 0.875 0.25 0.007 - 21 Si 0.25 0.125 0.875 0.007 - 22 Si 0.75 0.375 0.625 0.007 - 23 Si 0.625 0.375 0.25 0.007 - 24 Si 0.625 0.75 0.375 0.007 - 25 Si 0.375 0.625 0.75 0.007 - 26 Si 0.125 0.75 0.875 0.007 - 27 Si 0.75 0.875 0.125 0.007 - 28 Si 0.875 0.25 0.125 0.007 - 29 Si 0.375 0.25 0.625 0.007 - 30 Si 0.25 0.625 0.375 0.007 - 31 Si 0.875 0.125 0.75 0.007 - 32 O 0.481321 0.372801 0.277023 0.027 - 33 O 0.295702 0.89148 0.018679 0.027 - 34 O 0.60852 0.904222 0.127199 0.027 - 35 O 0.595778 0.204298 0.222977 0.027 - 36 O 0.127199 0.018679 0.222977 0.027 - 37 O 0.204298 0.222977 0.595778 0.027 - 38 O 0.204298 0.481321 0.60852 0.027 - 39 O 0.222977 0.595778 0.204298 0.027 - 40 O 0.372801 0.595778 0.89148 0.027 - 41 O 0.904222 0.277023 0.295702 0.027 - 42 O 0.277023 0.295702 0.904222 0.027 - 43 O 0.222977 0.127199 0.018679 0.027 - 44 O 0.481321 0.60852 0.204298 0.027 - 45 O 0.89148 0.372801 0.595778 0.027 - 46 O 0.018679 0.222977 0.127199 0.027 - 47 O 0.60852 0.204298 0.481321 0.027 - 48 O 0.595778 0.89148 0.372801 0.027 - 49 O 0.018679 0.295702 0.89148 0.027 - 50 O 0.904222 0.127199 0.60852 0.027 - 51 O 0.627199 0.404222 0.10852 0.027 - 52 O 0.372801 0.277023 0.481321 0.027 - 53 O 0.277023 0.481321 0.372801 0.027 - 54 O 0.89148 0.018679 0.295702 0.027 - 55 O 0.295702 0.904222 0.277023 0.027 - 56 O 0.518679 0.627199 0.722977 0.027 - 57 O 0.704298 0.10852 0.981321 0.027 - 58 O 0.39148 0.095778 0.872801 0.027 - 59 O 0.404222 0.795702 0.777023 0.027 - 60 O 0.872801 0.981321 0.777023 0.027 - 61 O 0.795702 0.777023 0.404222 0.027 - 62 O 0.795702 0.518679 0.39148 0.027 - 63 O 0.777023 0.404222 0.795702 0.027 - 64 O 0.704298 0.095778 0.722977 0.027 - 65 O 0.10852 0.981321 0.704298 0.027 - 66 O 0.722977 0.518679 0.627199 0.027 - 67 O 0.627199 0.722977 0.518679 0.027 - 68 O 0.872801 0.39148 0.095778 0.027 - 69 O 0.095778 0.872801 0.39148 0.027 - 70 O 0.981321 0.704298 0.10852 0.027 - 71 O 0.404222 0.10852 0.627199 0.027 - 72 O 0.39148 0.795702 0.518679 0.027 - 73 O 0.981321 0.777023 0.872801 0.027 - 74 O 0.10852 0.627199 0.404222 0.027 - 75 O 0.518679 0.39148 0.795702 0.027 - 76 O 0.777023 0.872801 0.981321 0.027 - 77 O 0.722977 0.704298 0.095778 0.027 - 78 O 0.095778 0.722977 0.704298 0.027 - 79 O 0.127199 0.60852 0.904222 0.027","# generated using pymatgen -data_Y2Mn3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.78135810 -_cell_length_b 10.78135810 -_cell_length_c 10.78135810 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Mn3(SiO4)3 -_chemical_formula_sum 'Y8 Mn12 Si12 O48' -_cell_volume 964.71387044 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.50000000 1 - Y Y1 1 0.00000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.00000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.00000000 1 - Y Y4 1 0.50000000 0.50000000 0.00000000 1 - Y Y5 1 0.00000000 0.50000000 0.50000000 1 - Y Y6 1 0.50000000 0.00000000 0.50000000 1 - Y Y7 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn8 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn9 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn10 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn11 1 0.75000000 0.62500000 0.87500000 1 - Mn Mn12 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn13 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn14 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn15 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn16 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn17 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn18 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.25000000 0.12500000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.37500000 0.25000000 0.62500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.48132100 0.37280100 0.27702300 1 - O O33 1 0.29570200 0.89148000 0.01867900 1 - O O34 1 0.60852000 0.90422200 0.12719900 1 - O O35 1 0.59577800 0.20429800 0.22297700 1 - O O36 1 0.12719900 0.01867900 0.22297700 1 - O O37 1 0.20429800 0.22297700 0.59577800 1 - O O38 1 0.20429800 0.48132100 0.60852000 1 - O O39 1 0.22297700 0.59577800 0.20429800 1 - O O40 1 0.37280100 0.59577800 0.89148000 1 - O O41 1 0.90422200 0.27702300 0.29570200 1 - O O42 1 0.27702300 0.29570200 0.90422200 1 - O O43 1 0.22297700 0.12719900 0.01867900 1 - O O44 1 0.48132100 0.60852000 0.20429800 1 - O O45 1 0.89148000 0.37280100 0.59577800 1 - O O46 1 0.01867900 0.22297700 0.12719900 1 - O O47 1 0.60852000 0.20429800 0.48132100 1 - O O48 1 0.59577800 0.89148000 0.37280100 1 - O O49 1 0.01867900 0.29570200 0.89148000 1 - O O50 1 0.90422200 0.12719900 0.60852000 1 - O O51 1 0.62719900 0.40422200 0.10852000 1 - O O52 1 0.37280100 0.27702300 0.48132100 1 - O O53 1 0.27702300 0.48132100 0.37280100 1 - O O54 1 0.89148000 0.01867900 0.29570200 1 - O O55 1 0.29570200 0.90422200 0.27702300 1 - O O56 1 0.51867900 0.62719900 0.72297700 1 - O O57 1 0.70429800 0.10852000 0.98132100 1 - O O58 1 0.39148000 0.09577800 0.87280100 1 - O O59 1 0.40422200 0.79570200 0.77702300 1 - O O60 1 0.87280100 0.98132100 0.77702300 1 - O O61 1 0.79570200 0.77702300 0.40422200 1 - O O62 1 0.79570200 0.51867900 0.39148000 1 - O O63 1 0.77702300 0.40422200 0.79570200 1 - O O64 1 0.70429800 0.09577800 0.72297700 1 - O O65 1 0.10852000 0.98132100 0.70429800 1 - O O66 1 0.72297700 0.51867900 0.62719900 1 - O O67 1 0.62719900 0.72297700 0.51867900 1 - O O68 1 0.87280100 0.39148000 0.09577800 1 - O O69 1 0.09577800 0.87280100 0.39148000 1 - O O70 1 0.98132100 0.70429800 0.10852000 1 - O O71 1 0.40422200 0.10852000 0.62719900 1 - O O72 1 0.39148000 0.79570200 0.51867900 1 - O O73 1 0.98132100 0.77702300 0.87280100 1 - O O74 1 0.10852000 0.62719900 0.40422200 1 - O O75 1 0.51867900 0.39148000 0.79570200 1 - O O76 1 0.77702300 0.87280100 0.98132100 1 - O O77 1 0.72297700 0.70429800 0.09577800 1 - O O78 1 0.09577800 0.72297700 0.70429800 1 - O O79 1 0.12719900 0.60852000 0.90422200 1 -" -Zn3Si3(SbO6)2,mp-1154534,Ia-3d,[],0.31064848687499413,{'tags': []},"Full Formula (Zn12 Si12 Sb8 O48) -Reduced Formula: Zn3Si3(SbO6)2 -abc : 10.728920 10.728920 10.728920 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 0 - 1 Zn 0.75 0.125 0.375 0 - 2 Zn 0.375 0.125 0.25 0 - 3 Zn 0.125 0.375 0.75 0 - 4 Zn 0.25 0.875 0.625 0 - 5 Zn 0.125 0.25 0.375 0 - 6 Zn 0.625 0.25 0.875 0 - 7 Zn 0.75 0.625 0.875 0 - 8 Zn 0.875 0.75 0.625 0 - 9 Zn 0.875 0.625 0.25 0 - 10 Zn 0.625 0.875 0.75 0 - 11 Zn 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 0 - 13 Si 0.875 0.25 0.125 0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 0 - 16 Si 0.25 0.125 0.875 0 - 17 Si 0.375 0.625 0.75 0 - 18 Si 0.375 0.25 0.625 0 - 19 Si 0.875 0.125 0.75 0 - 20 Si 0.625 0.375 0.25 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 0 - 24 Sb 0.5 0 0 0 - 25 Sb 0.5 0.5 0 0 - 26 Sb 0 0.5 0.5 0 - 27 Sb 0 0 0.5 0 - 28 Sb 0.5 0.5 0.5 0 - 29 Sb 0 0.5 0 0 - 30 Sb 0.5 0 0.5 0 - 31 Sb 0 0 0 0 - 32 O 0.597348 0.892481 0.369439 -0 - 33 O 0.369439 0.597348 0.892481 -0 - 34 O 0.272092 0.295133 0.902652 -0 - 35 O 0.476958 0.607519 0.204867 -0 - 36 O 0.295133 0.892481 0.023042 -0 - 37 O 0.130561 0.023042 0.227908 -0 - 38 O 0.369439 0.272092 0.476958 -0 - 39 O 0.892481 0.369439 0.597348 -0 - 40 O 0.204867 0.227908 0.597348 -0 - 41 O 0.476958 0.369439 0.272092 -0 - 42 O 0.892481 0.023042 0.295133 -0 - 43 O 0.607519 0.902652 0.130561 -0 - 44 O 0.902652 0.130561 0.607519 -0 - 45 O 0.272092 0.476958 0.369439 -0 - 46 O 0.597348 0.204867 0.227908 -0 - 47 O 0.227908 0.597348 0.204867 -0 - 48 O 0.023042 0.295133 0.892481 -0 - 49 O 0.902652 0.272092 0.295133 -0 - 50 O 0.023042 0.227908 0.130561 -0 - 51 O 0.795133 0.772092 0.402652 -0 - 52 O 0.204867 0.476958 0.607519 -0 - 53 O 0.607519 0.204867 0.476958 -0 - 54 O 0.227908 0.130561 0.023042 -0 - 55 O 0.130561 0.607519 0.902652 -0 - 56 O 0.402652 0.107519 0.630561 -0 - 57 O 0.630561 0.402652 0.107519 -0 - 58 O 0.727908 0.704867 0.097348 -0 - 59 O 0.523042 0.392481 0.795133 -0 - 60 O 0.704867 0.107519 0.976958 -0 - 61 O 0.869439 0.976958 0.772092 -0 - 62 O 0.630561 0.727908 0.523042 -0 - 63 O 0.107519 0.630561 0.402652 -0 - 64 O 0.869439 0.392481 0.097348 -0 - 65 O 0.772092 0.869439 0.976958 -0 - 66 O 0.392481 0.795133 0.523042 -0 - 67 O 0.704867 0.097348 0.727908 -0 - 68 O 0.795133 0.523042 0.392481 -0 - 69 O 0.976958 0.772092 0.869439 -0 - 70 O 0.097348 0.727908 0.704867 -0 - 71 O 0.976958 0.704867 0.107519 -0 - 72 O 0.772092 0.402652 0.795133 -0 - 73 O 0.402652 0.795133 0.772092 -0 - 74 O 0.727908 0.523042 0.630561 -0 - 75 O 0.097348 0.869439 0.392481 -0 - 76 O 0.392481 0.097348 0.869439 -0 - 77 O 0.107519 0.976958 0.704867 -0 - 78 O 0.523042 0.630561 0.727908 -0 - 79 O 0.295133 0.902652 0.272092 -0","# generated using pymatgen -data_Zn3Si3(SbO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.72892026 -_cell_length_b 10.72892026 -_cell_length_c 10.72892026 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Si3(SbO6)2 -_chemical_formula_sum 'Zn12 Si12 Sb8 O48' -_cell_volume 950.70584012 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Sb Sb24 1 0.50000000 0.00000000 0.00000000 1 - Sb Sb25 1 0.50000000 0.50000000 0.00000000 1 - Sb Sb26 1 0.00000000 0.50000000 0.50000000 1 - Sb Sb27 1 0.00000000 0.00000000 0.50000000 1 - Sb Sb28 1 0.50000000 0.50000000 0.50000000 1 - Sb Sb29 1 0.00000000 0.50000000 0.00000000 1 - Sb Sb30 1 0.50000000 0.00000000 0.50000000 1 - Sb Sb31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59734800 0.89248100 0.36943900 1 - O O33 1 0.36943900 0.59734800 0.89248100 1 - O O34 1 0.27209200 0.29513300 0.90265200 1 - O O35 1 0.47695800 0.60751900 0.20486700 1 - O O36 1 0.29513300 0.89248100 0.02304200 1 - O O37 1 0.13056100 0.02304200 0.22790800 1 - O O38 1 0.36943900 0.27209200 0.47695800 1 - O O39 1 0.89248100 0.36943900 0.59734800 1 - O O40 1 0.20486700 0.22790800 0.59734800 1 - O O41 1 0.47695800 0.36943900 0.27209200 1 - O O42 1 0.89248100 0.02304200 0.29513300 1 - O O43 1 0.60751900 0.90265200 0.13056100 1 - O O44 1 0.90265200 0.13056100 0.60751900 1 - O O45 1 0.27209200 0.47695800 0.36943900 1 - O O46 1 0.59734800 0.20486700 0.22790800 1 - O O47 1 0.22790800 0.59734800 0.20486700 1 - O O48 1 0.02304200 0.29513300 0.89248100 1 - O O49 1 0.90265200 0.27209200 0.29513300 1 - O O50 1 0.02304200 0.22790800 0.13056100 1 - O O51 1 0.79513300 0.77209200 0.40265200 1 - O O52 1 0.20486700 0.47695800 0.60751900 1 - O O53 1 0.60751900 0.20486700 0.47695800 1 - O O54 1 0.22790800 0.13056100 0.02304200 1 - O O55 1 0.13056100 0.60751900 0.90265200 1 - O O56 1 0.40265200 0.10751900 0.63056100 1 - O O57 1 0.63056100 0.40265200 0.10751900 1 - O O58 1 0.72790800 0.70486700 0.09734800 1 - O O59 1 0.52304200 0.39248100 0.79513300 1 - O O60 1 0.70486700 0.10751900 0.97695800 1 - O O61 1 0.86943900 0.97695800 0.77209200 1 - O O62 1 0.63056100 0.72790800 0.52304200 1 - O O63 1 0.10751900 0.63056100 0.40265200 1 - O O64 1 0.86943900 0.39248100 0.09734800 1 - O O65 1 0.77209200 0.86943900 0.97695800 1 - O O66 1 0.39248100 0.79513300 0.52304200 1 - O O67 1 0.70486700 0.09734800 0.72790800 1 - O O68 1 0.79513300 0.52304200 0.39248100 1 - O O69 1 0.97695800 0.77209200 0.86943900 1 - O O70 1 0.09734800 0.72790800 0.70486700 1 - O O71 1 0.97695800 0.70486700 0.10751900 1 - O O72 1 0.77209200 0.40265200 0.79513300 1 - O O73 1 0.40265200 0.79513300 0.77209200 1 - O O74 1 0.72790800 0.52304200 0.63056100 1 - O O75 1 0.09734800 0.86943900 0.39248100 1 - O O76 1 0.39248100 0.09734800 0.86943900 1 - O O77 1 0.10751900 0.97695800 0.70486700 1 - O O78 1 0.52304200 0.63056100 0.72790800 1 - O O79 1 0.29513300 0.90265200 0.27209200 1 -" -Ca3Si3(NiO6)2,mp-1154587,Ia-3d,[],0.04982142170833459,{'tags': []},"Full Formula (Ca12 Si12 Ni8 O48) -Reduced Formula: Ca3Si3(NiO6)2 -abc : 10.540180 10.540180 10.540180 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0.001 - 1 Ca 0.75 0.125 0.375 0.001 - 2 Ca 0.375 0.125 0.25 0.001 - 3 Ca 0.125 0.375 0.75 0.001 - 4 Ca 0.25 0.875 0.625 0.001 - 5 Ca 0.125 0.25 0.375 0.001 - 6 Ca 0.625 0.25 0.875 0.001 - 7 Ca 0.75 0.625 0.875 0.001 - 8 Ca 0.875 0.75 0.625 0.001 - 9 Ca 0.875 0.625 0.25 0.001 - 10 Ca 0.625 0.875 0.75 0.001 - 11 Ca 0.375 0.75 0.125 0.001 - 12 Si 0.125 0.75 0.875 0.015 - 13 Si 0.875 0.25 0.125 0.015 - 14 Si 0.75 0.375 0.625 0.015 - 15 Si 0.125 0.875 0.25 0.015 - 16 Si 0.25 0.125 0.875 0.015 - 17 Si 0.375 0.625 0.75 0.015 - 18 Si 0.375 0.25 0.625 0.015 - 19 Si 0.875 0.125 0.75 0.015 - 20 Si 0.625 0.375 0.25 0.015 - 21 Si 0.75 0.875 0.125 0.015 - 22 Si 0.25 0.625 0.375 0.015 - 23 Si 0.625 0.75 0.375 0.015 - 24 Ni 0.5 0 0 1.636 - 25 Ni 0.5 0.5 0 1.636 - 26 Ni 0 0.5 0.5 1.636 - 27 Ni 0 0 0.5 1.636 - 28 Ni 0.5 0.5 0.5 1.636 - 29 Ni 0 0.5 0 1.636 - 30 Ni 0.5 0 0.5 1.636 - 31 Ni 0 0 0 1.636 - 32 O 0.587872 0.892393 0.382397 -0.094 - 33 O 0.382397 0.587872 0.892393 -0.094 - 34 O 0.294525 0.30452 0.912128 -0.094 - 35 O 0.490004 0.607607 0.19548 -0.094 - 36 O 0.30452 0.892393 0.009996 -0.094 - 37 O 0.117603 0.009996 0.205475 -0.094 - 38 O 0.382397 0.294525 0.490004 -0.094 - 39 O 0.892393 0.382397 0.587872 -0.094 - 40 O 0.19548 0.205475 0.587872 -0.094 - 41 O 0.490004 0.382397 0.294525 -0.094 - 42 O 0.892393 0.009996 0.30452 -0.094 - 43 O 0.607607 0.912128 0.117603 -0.094 - 44 O 0.912128 0.117603 0.607607 -0.094 - 45 O 0.294525 0.490004 0.382397 -0.094 - 46 O 0.587872 0.19548 0.205475 -0.094 - 47 O 0.205475 0.587872 0.19548 -0.094 - 48 O 0.009996 0.30452 0.892393 -0.094 - 49 O 0.912128 0.294525 0.30452 -0.094 - 50 O 0.009996 0.205475 0.117603 -0.094 - 51 O 0.80452 0.794525 0.412128 -0.094 - 52 O 0.19548 0.490004 0.607607 -0.094 - 53 O 0.607607 0.19548 0.490004 -0.094 - 54 O 0.205475 0.117603 0.009996 -0.094 - 55 O 0.117603 0.607607 0.912128 -0.094 - 56 O 0.412128 0.107607 0.617603 -0.094 - 57 O 0.617603 0.412128 0.107607 -0.094 - 58 O 0.705475 0.69548 0.087872 -0.094 - 59 O 0.509996 0.392393 0.80452 -0.094 - 60 O 0.69548 0.107607 0.990004 -0.094 - 61 O 0.882397 0.990004 0.794525 -0.094 - 62 O 0.617603 0.705475 0.509996 -0.094 - 63 O 0.107607 0.617603 0.412128 -0.094 - 64 O 0.882397 0.392393 0.087872 -0.094 - 65 O 0.794525 0.882397 0.990004 -0.094 - 66 O 0.392393 0.80452 0.509996 -0.094 - 67 O 0.69548 0.087872 0.705475 -0.094 - 68 O 0.80452 0.509996 0.392393 -0.094 - 69 O 0.990004 0.794525 0.882397 -0.094 - 70 O 0.087872 0.705475 0.69548 -0.094 - 71 O 0.990004 0.69548 0.107607 -0.094 - 72 O 0.794525 0.412128 0.80452 -0.094 - 73 O 0.412128 0.80452 0.794525 -0.094 - 74 O 0.705475 0.509996 0.617603 -0.094 - 75 O 0.087872 0.882397 0.392393 -0.094 - 76 O 0.392393 0.087872 0.882397 -0.094 - 77 O 0.107607 0.990004 0.69548 -0.094 - 78 O 0.509996 0.617603 0.705475 -0.094 - 79 O 0.30452 0.912128 0.294525 -0.094","# generated using pymatgen -data_Ca3Si3(NiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.54018042 -_cell_length_b 10.54018042 -_cell_length_c 10.54018042 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Si3(NiO6)2 -_chemical_formula_sum 'Ca12 Si12 Ni8 O48' -_cell_volume 901.40973366 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Ni Ni24 1 0.50000000 0.00000000 0.00000000 1 - Ni Ni25 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni26 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni27 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni28 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni29 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni30 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.58787200 0.89239300 0.38239700 1 - O O33 1 0.38239700 0.58787200 0.89239300 1 - O O34 1 0.29452500 0.30452000 0.91212800 1 - O O35 1 0.49000400 0.60760700 0.19548000 1 - O O36 1 0.30452000 0.89239300 0.00999600 1 - O O37 1 0.11760300 0.00999600 0.20547500 1 - O O38 1 0.38239700 0.29452500 0.49000400 1 - O O39 1 0.89239300 0.38239700 0.58787200 1 - O O40 1 0.19548000 0.20547500 0.58787200 1 - O O41 1 0.49000400 0.38239700 0.29452500 1 - O O42 1 0.89239300 0.00999600 0.30452000 1 - O O43 1 0.60760700 0.91212800 0.11760300 1 - O O44 1 0.91212800 0.11760300 0.60760700 1 - O O45 1 0.29452500 0.49000400 0.38239700 1 - O O46 1 0.58787200 0.19548000 0.20547500 1 - O O47 1 0.20547500 0.58787200 0.19548000 1 - O O48 1 0.00999600 0.30452000 0.89239300 1 - O O49 1 0.91212800 0.29452500 0.30452000 1 - O O50 1 0.00999600 0.20547500 0.11760300 1 - O O51 1 0.80452000 0.79452500 0.41212800 1 - O O52 1 0.19548000 0.49000400 0.60760700 1 - O O53 1 0.60760700 0.19548000 0.49000400 1 - O O54 1 0.20547500 0.11760300 0.00999600 1 - O O55 1 0.11760300 0.60760700 0.91212800 1 - O O56 1 0.41212800 0.10760700 0.61760300 1 - O O57 1 0.61760300 0.41212800 0.10760700 1 - O O58 1 0.70547500 0.69548000 0.08787200 1 - O O59 1 0.50999600 0.39239300 0.80452000 1 - O O60 1 0.69548000 0.10760700 0.99000400 1 - O O61 1 0.88239700 0.99000400 0.79452500 1 - O O62 1 0.61760300 0.70547500 0.50999600 1 - O O63 1 0.10760700 0.61760300 0.41212800 1 - O O64 1 0.88239700 0.39239300 0.08787200 1 - O O65 1 0.79452500 0.88239700 0.99000400 1 - O O66 1 0.39239300 0.80452000 0.50999600 1 - O O67 1 0.69548000 0.08787200 0.70547500 1 - O O68 1 0.80452000 0.50999600 0.39239300 1 - O O69 1 0.99000400 0.79452500 0.88239700 1 - O O70 1 0.08787200 0.70547500 0.69548000 1 - O O71 1 0.99000400 0.69548000 0.10760700 1 - O O72 1 0.79452500 0.41212800 0.80452000 1 - O O73 1 0.41212800 0.80452000 0.79452500 1 - O O74 1 0.70547500 0.50999600 0.61760300 1 - O O75 1 0.08787200 0.88239700 0.39239300 1 - O O76 1 0.39239300 0.08787200 0.88239700 1 - O O77 1 0.10760700 0.99000400 0.69548000 1 - O O78 1 0.50999600 0.61760300 0.70547500 1 - O O79 1 0.30452000 0.91212800 0.29452500 1 -" -Zn3Si3(MoO6)2,mp-1154656,Ia-3d,[],0.14166931906249847,{'tags': []},"Full Formula (Zn12 Si12 Mo8 O48) -Reduced Formula: Zn3Si3(MoO6)2 -abc : 10.492274 10.492274 10.492274 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 0.016 - 1 Zn 0.75 0.125 0.375 0.016 - 2 Zn 0.375 0.125 0.25 0.016 - 3 Zn 0.125 0.375 0.75 0.016 - 4 Zn 0.25 0.875 0.625 0.016 - 5 Zn 0.125 0.25 0.375 0.016 - 6 Zn 0.625 0.25 0.875 0.016 - 7 Zn 0.75 0.625 0.875 0.016 - 8 Zn 0.875 0.75 0.625 0.016 - 9 Zn 0.875 0.625 0.25 0.016 - 10 Zn 0.625 0.875 0.75 0.016 - 11 Zn 0.375 0.75 0.125 0.016 - 12 Si 0.125 0.75 0.875 0.012 - 13 Si 0.875 0.25 0.125 0.012 - 14 Si 0.75 0.375 0.625 0.012 - 15 Si 0.125 0.875 0.25 0.012 - 16 Si 0.25 0.125 0.875 0.012 - 17 Si 0.375 0.625 0.75 0.012 - 18 Si 0.375 0.25 0.625 0.012 - 19 Si 0.875 0.125 0.75 0.012 - 20 Si 0.625 0.375 0.25 0.012 - 21 Si 0.75 0.875 0.125 0.012 - 22 Si 0.25 0.625 0.375 0.012 - 23 Si 0.625 0.75 0.375 0.012 - 24 Mo 0.5 0 0 2.747 - 25 Mo 0.5 0.5 0 2.747 - 26 Mo 0 0.5 0.5 2.747 - 27 Mo 0 0 0.5 2.747 - 28 Mo 0.5 0.5 0.5 2.747 - 29 Mo 0 0.5 0 2.747 - 30 Mo 0.5 0 0.5 2.747 - 31 Mo 0 0 0 2.747 - 32 O 0.592214 0.893817 0.373284 0.01 - 33 O 0.373284 0.592214 0.893817 0.01 - 34 O 0.28107 0.301603 0.907786 0.01 - 35 O 0.479467 0.606183 0.198397 0.01 - 36 O 0.301603 0.893817 0.020533 0.01 - 37 O 0.126716 0.020533 0.21893 0.01 - 38 O 0.373284 0.28107 0.479467 0.01 - 39 O 0.893817 0.373284 0.592214 0.01 - 40 O 0.198397 0.21893 0.592214 0.01 - 41 O 0.479467 0.373284 0.28107 0.01 - 42 O 0.893817 0.020533 0.301603 0.01 - 43 O 0.606183 0.907786 0.126716 0.01 - 44 O 0.907786 0.126716 0.606183 0.01 - 45 O 0.28107 0.479467 0.373284 0.01 - 46 O 0.592214 0.198397 0.21893 0.01 - 47 O 0.21893 0.592214 0.198397 0.01 - 48 O 0.020533 0.301603 0.893817 0.01 - 49 O 0.907786 0.28107 0.301603 0.01 - 50 O 0.020533 0.21893 0.126716 0.01 - 51 O 0.801603 0.78107 0.407786 0.01 - 52 O 0.198397 0.479467 0.606183 0.01 - 53 O 0.606183 0.198397 0.479467 0.01 - 54 O 0.21893 0.126716 0.020533 0.01 - 55 O 0.126716 0.606183 0.907786 0.01 - 56 O 0.407786 0.106183 0.626716 0.01 - 57 O 0.626716 0.407786 0.106183 0.01 - 58 O 0.71893 0.698397 0.092214 0.01 - 59 O 0.520533 0.393817 0.801603 0.01 - 60 O 0.698397 0.106183 0.979467 0.01 - 61 O 0.873284 0.979467 0.78107 0.01 - 62 O 0.626716 0.71893 0.520533 0.01 - 63 O 0.106183 0.626716 0.407786 0.01 - 64 O 0.873284 0.393817 0.092214 0.01 - 65 O 0.78107 0.873284 0.979467 0.01 - 66 O 0.393817 0.801603 0.520533 0.01 - 67 O 0.698397 0.092214 0.71893 0.01 - 68 O 0.801603 0.520533 0.393817 0.01 - 69 O 0.979467 0.78107 0.873284 0.01 - 70 O 0.092214 0.71893 0.698397 0.01 - 71 O 0.979467 0.698397 0.106183 0.01 - 72 O 0.78107 0.407786 0.801603 0.01 - 73 O 0.407786 0.801603 0.78107 0.01 - 74 O 0.71893 0.520533 0.626716 0.01 - 75 O 0.092214 0.873284 0.393817 0.01 - 76 O 0.393817 0.092214 0.873284 0.01 - 77 O 0.106183 0.979467 0.698397 0.01 - 78 O 0.520533 0.626716 0.71893 0.01 - 79 O 0.301603 0.907786 0.28107 0.01","# generated using pymatgen -data_Zn3Si3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.49227362 -_cell_length_b 10.49227362 -_cell_length_c 10.49227362 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Si3(MoO6)2 -_chemical_formula_sum 'Zn12 Si12 Mo8 O48' -_cell_volume 889.17436323 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Mo Mo24 1 0.50000000 0.00000000 0.00000000 1 - Mo Mo25 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo26 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo27 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo28 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo29 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo30 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59221400 0.89381700 0.37328400 1 - O O33 1 0.37328400 0.59221400 0.89381700 1 - O O34 1 0.28107000 0.30160300 0.90778600 1 - O O35 1 0.47946700 0.60618300 0.19839700 1 - O O36 1 0.30160300 0.89381700 0.02053300 1 - O O37 1 0.12671600 0.02053300 0.21893000 1 - O O38 1 0.37328400 0.28107000 0.47946700 1 - O O39 1 0.89381700 0.37328400 0.59221400 1 - O O40 1 0.19839700 0.21893000 0.59221400 1 - O O41 1 0.47946700 0.37328400 0.28107000 1 - O O42 1 0.89381700 0.02053300 0.30160300 1 - O O43 1 0.60618300 0.90778600 0.12671600 1 - O O44 1 0.90778600 0.12671600 0.60618300 1 - O O45 1 0.28107000 0.47946700 0.37328400 1 - O O46 1 0.59221400 0.19839700 0.21893000 1 - O O47 1 0.21893000 0.59221400 0.19839700 1 - O O48 1 0.02053300 0.30160300 0.89381700 1 - O O49 1 0.90778600 0.28107000 0.30160300 1 - O O50 1 0.02053300 0.21893000 0.12671600 1 - O O51 1 0.80160300 0.78107000 0.40778600 1 - O O52 1 0.19839700 0.47946700 0.60618300 1 - O O53 1 0.60618300 0.19839700 0.47946700 1 - O O54 1 0.21893000 0.12671600 0.02053300 1 - O O55 1 0.12671600 0.60618300 0.90778600 1 - O O56 1 0.40778600 0.10618300 0.62671600 1 - O O57 1 0.62671600 0.40778600 0.10618300 1 - O O58 1 0.71893000 0.69839700 0.09221400 1 - O O59 1 0.52053300 0.39381700 0.80160300 1 - O O60 1 0.69839700 0.10618300 0.97946700 1 - O O61 1 0.87328400 0.97946700 0.78107000 1 - O O62 1 0.62671600 0.71893000 0.52053300 1 - O O63 1 0.10618300 0.62671600 0.40778600 1 - O O64 1 0.87328400 0.39381700 0.09221400 1 - O O65 1 0.78107000 0.87328400 0.97946700 1 - O O66 1 0.39381700 0.80160300 0.52053300 1 - O O67 1 0.69839700 0.09221400 0.71893000 1 - O O68 1 0.80160300 0.52053300 0.39381700 1 - O O69 1 0.97946700 0.78107000 0.87328400 1 - O O70 1 0.09221400 0.71893000 0.69839700 1 - O O71 1 0.97946700 0.69839700 0.10618300 1 - O O72 1 0.78107000 0.40778600 0.80160300 1 - O O73 1 0.40778600 0.80160300 0.78107000 1 - O O74 1 0.71893000 0.52053300 0.62671600 1 - O O75 1 0.09221400 0.87328400 0.39381700 1 - O O76 1 0.39381700 0.09221400 0.87328400 1 - O O77 1 0.10618300 0.97946700 0.69839700 1 - O O78 1 0.52053300 0.62671600 0.71893000 1 - O O79 1 0.30160300 0.90778600 0.28107000 1 -" -Y2Si3(SnO4)3,mp-1154662,Ia-3d,[],0.13720020966666713,{'tags': []},"Full Formula (Y8 Si12 Sn12 O48) -Reduced Formula: Y2Si3(SnO4)3 -abc : 11.275885 11.275885 11.275885 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0.5 -0 - 1 Y 0 0 0 -0 - 2 Y 0.5 0 0 -0 - 3 Y 0 0.5 0 -0 - 4 Y 0.5 0.5 0 -0 - 5 Y 0 0.5 0.5 -0 - 6 Y 0.5 0 0.5 -0 - 7 Y 0.5 0.5 0.5 -0 - 8 Si 0.125 0.875 0.25 -0 - 9 Si 0.25 0.125 0.875 -0 - 10 Si 0.75 0.375 0.625 -0 - 11 Si 0.625 0.375 0.25 -0 - 12 Si 0.625 0.75 0.375 -0 - 13 Si 0.375 0.625 0.75 -0 - 14 Si 0.125 0.75 0.875 -0 - 15 Si 0.75 0.875 0.125 -0 - 16 Si 0.875 0.25 0.125 -0 - 17 Si 0.375 0.25 0.625 -0 - 18 Si 0.25 0.625 0.375 -0 - 19 Si 0.875 0.125 0.75 -0 - 20 Sn 0.875 0.625 0.25 -0 - 21 Sn 0.625 0.25 0.875 -0 - 22 Sn 0.875 0.75 0.625 -0 - 23 Sn 0.75 0.625 0.875 -0 - 24 Sn 0.25 0.875 0.625 -0 - 25 Sn 0.625 0.875 0.75 -0 - 26 Sn 0.125 0.375 0.75 -0 - 27 Sn 0.375 0.75 0.125 -0 - 28 Sn 0.125 0.25 0.375 -0 - 29 Sn 0.25 0.375 0.125 -0 - 30 Sn 0.75 0.125 0.375 -0 - 31 Sn 0.375 0.125 0.25 -0 - 32 O 0.498142 0.383375 0.291149 0 - 33 O 0.293007 0.885233 0.001858 0 - 34 O 0.614767 0.907774 0.116625 0 - 35 O 0.592226 0.206993 0.208851 0 - 36 O 0.116625 0.001858 0.208851 0 - 37 O 0.206993 0.208851 0.592226 0 - 38 O 0.206993 0.498142 0.614767 0 - 39 O 0.208851 0.592226 0.206993 0 - 40 O 0.383375 0.592226 0.885233 0 - 41 O 0.907774 0.291149 0.293007 0 - 42 O 0.291149 0.293007 0.907774 0 - 43 O 0.208851 0.116625 0.001858 0 - 44 O 0.498142 0.614767 0.206993 0 - 45 O 0.885233 0.383375 0.592226 0 - 46 O 0.001858 0.208851 0.116625 0 - 47 O 0.614767 0.206993 0.498142 0 - 48 O 0.592226 0.885233 0.383375 0 - 49 O 0.001858 0.293007 0.885233 0 - 50 O 0.907774 0.116625 0.614767 0 - 51 O 0.616625 0.407774 0.114767 0 - 52 O 0.383375 0.291149 0.498142 0 - 53 O 0.291149 0.498142 0.383375 0 - 54 O 0.885233 0.001858 0.293007 0 - 55 O 0.293007 0.907774 0.291149 0 - 56 O 0.501858 0.616625 0.708851 0 - 57 O 0.706993 0.114767 0.998142 0 - 58 O 0.385233 0.092226 0.883375 0 - 59 O 0.407774 0.793007 0.791149 0 - 60 O 0.883375 0.998142 0.791149 0 - 61 O 0.793007 0.791149 0.407774 0 - 62 O 0.793007 0.501858 0.385233 0 - 63 O 0.791149 0.407774 0.793007 0 - 64 O 0.706993 0.092226 0.708851 0 - 65 O 0.114767 0.998142 0.706993 0 - 66 O 0.708851 0.501858 0.616625 0 - 67 O 0.616625 0.708851 0.501858 0 - 68 O 0.883375 0.385233 0.092226 0 - 69 O 0.092226 0.883375 0.385233 0 - 70 O 0.998142 0.706993 0.114767 0 - 71 O 0.407774 0.114767 0.616625 0 - 72 O 0.385233 0.793007 0.501858 0 - 73 O 0.998142 0.791149 0.883375 0 - 74 O 0.114767 0.616625 0.407774 0 - 75 O 0.501858 0.385233 0.793007 0 - 76 O 0.791149 0.883375 0.998142 0 - 77 O 0.708851 0.706993 0.092226 0 - 78 O 0.092226 0.708851 0.706993 0 - 79 O 0.116625 0.614767 0.907774 0","# generated using pymatgen -data_Y2Si3(SnO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.27588458 -_cell_length_b 11.27588458 -_cell_length_c 11.27588458 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Si3(SnO4)3 -_chemical_formula_sum 'Y8 Si12 Sn12 O48' -_cell_volume 1103.64646119 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.50000000 1 - Y Y1 1 0.00000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.00000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.00000000 1 - Y Y4 1 0.50000000 0.50000000 0.00000000 1 - Y Y5 1 0.00000000 0.50000000 0.50000000 1 - Y Y6 1 0.50000000 0.00000000 0.50000000 1 - Y Y7 1 0.50000000 0.50000000 0.50000000 1 - Si Si8 1 0.12500000 0.87500000 0.25000000 1 - Si Si9 1 0.25000000 0.12500000 0.87500000 1 - Si Si10 1 0.75000000 0.37500000 0.62500000 1 - Si Si11 1 0.62500000 0.37500000 0.25000000 1 - Si Si12 1 0.62500000 0.75000000 0.37500000 1 - Si Si13 1 0.37500000 0.62500000 0.75000000 1 - Si Si14 1 0.12500000 0.75000000 0.87500000 1 - Si Si15 1 0.75000000 0.87500000 0.12500000 1 - Si Si16 1 0.87500000 0.25000000 0.12500000 1 - Si Si17 1 0.37500000 0.25000000 0.62500000 1 - Si Si18 1 0.25000000 0.62500000 0.37500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Sn Sn20 1 0.87500000 0.62500000 0.25000000 1 - Sn Sn21 1 0.62500000 0.25000000 0.87500000 1 - Sn Sn22 1 0.87500000 0.75000000 0.62500000 1 - Sn Sn23 1 0.75000000 0.62500000 0.87500000 1 - Sn Sn24 1 0.25000000 0.87500000 0.62500000 1 - Sn Sn25 1 0.62500000 0.87500000 0.75000000 1 - Sn Sn26 1 0.12500000 0.37500000 0.75000000 1 - Sn Sn27 1 0.37500000 0.75000000 0.12500000 1 - Sn Sn28 1 0.12500000 0.25000000 0.37500000 1 - Sn Sn29 1 0.25000000 0.37500000 0.12500000 1 - Sn Sn30 1 0.75000000 0.12500000 0.37500000 1 - Sn Sn31 1 0.37500000 0.12500000 0.25000000 1 - O O32 1 0.49814200 0.38337500 0.29114900 1 - O O33 1 0.29300700 0.88523300 0.00185800 1 - O O34 1 0.61476700 0.90777400 0.11662500 1 - O O35 1 0.59222600 0.20699300 0.20885100 1 - O O36 1 0.11662500 0.00185800 0.20885100 1 - O O37 1 0.20699300 0.20885100 0.59222600 1 - O O38 1 0.20699300 0.49814200 0.61476700 1 - O O39 1 0.20885100 0.59222600 0.20699300 1 - O O40 1 0.38337500 0.59222600 0.88523300 1 - O O41 1 0.90777400 0.29114900 0.29300700 1 - O O42 1 0.29114900 0.29300700 0.90777400 1 - O O43 1 0.20885100 0.11662500 0.00185800 1 - O O44 1 0.49814200 0.61476700 0.20699300 1 - O O45 1 0.88523300 0.38337500 0.59222600 1 - O O46 1 0.00185800 0.20885100 0.11662500 1 - O O47 1 0.61476700 0.20699300 0.49814200 1 - O O48 1 0.59222600 0.88523300 0.38337500 1 - O O49 1 0.00185800 0.29300700 0.88523300 1 - O O50 1 0.90777400 0.11662500 0.61476700 1 - O O51 1 0.61662500 0.40777400 0.11476700 1 - O O52 1 0.38337500 0.29114900 0.49814200 1 - O O53 1 0.29114900 0.49814200 0.38337500 1 - O O54 1 0.88523300 0.00185800 0.29300700 1 - O O55 1 0.29300700 0.90777400 0.29114900 1 - O O56 1 0.50185800 0.61662500 0.70885100 1 - O O57 1 0.70699300 0.11476700 0.99814200 1 - O O58 1 0.38523300 0.09222600 0.88337500 1 - O O59 1 0.40777400 0.79300700 0.79114900 1 - O O60 1 0.88337500 0.99814200 0.79114900 1 - O O61 1 0.79300700 0.79114900 0.40777400 1 - O O62 1 0.79300700 0.50185800 0.38523300 1 - O O63 1 0.79114900 0.40777400 0.79300700 1 - O O64 1 0.70699300 0.09222600 0.70885100 1 - O O65 1 0.11476700 0.99814200 0.70699300 1 - O O66 1 0.70885100 0.50185800 0.61662500 1 - O O67 1 0.61662500 0.70885100 0.50185800 1 - O O68 1 0.88337500 0.38523300 0.09222600 1 - O O69 1 0.09222600 0.88337500 0.38523300 1 - O O70 1 0.99814200 0.70699300 0.11476700 1 - O O71 1 0.40777400 0.11476700 0.61662500 1 - O O72 1 0.38523300 0.79300700 0.50185800 1 - O O73 1 0.99814200 0.79114900 0.88337500 1 - O O74 1 0.11476700 0.61662500 0.40777400 1 - O O75 1 0.50185800 0.38523300 0.79300700 1 - O O76 1 0.79114900 0.88337500 0.99814200 1 - O O77 1 0.70885100 0.70699300 0.09222600 1 - O O78 1 0.09222600 0.70885100 0.70699300 1 - O O79 1 0.11662500 0.61476700 0.90777400 1 -" -Ca3Si3(WO6)2,mp-1154711,Ia-3d,[],0.053517409875000865,{'tags': []},"Full Formula (Ca12 Si12 W8 O48) -Reduced Formula: Ca3Si3(WO6)2 -abc : 10.804961 10.804961 10.804961 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0.001 - 1 Ca 0.75 0.125 0.375 -0.001 - 2 Ca 0.375 0.125 0.25 -0.001 - 3 Ca 0.125 0.375 0.75 -0.001 - 4 Ca 0.25 0.875 0.625 -0.001 - 5 Ca 0.125 0.25 0.375 -0.001 - 6 Ca 0.625 0.25 0.875 -0.001 - 7 Ca 0.75 0.625 0.875 -0.001 - 8 Ca 0.875 0.75 0.625 -0.001 - 9 Ca 0.875 0.625 0.25 -0.001 - 10 Ca 0.625 0.875 0.75 -0.001 - 11 Ca 0.375 0.75 0.125 -0.001 - 12 Si 0.125 0.75 0.875 0.016 - 13 Si 0.875 0.25 0.125 0.016 - 14 Si 0.75 0.375 0.625 0.016 - 15 Si 0.125 0.875 0.25 0.016 - 16 Si 0.25 0.125 0.875 0.016 - 17 Si 0.375 0.625 0.75 0.016 - 18 Si 0.375 0.25 0.625 0.016 - 19 Si 0.875 0.125 0.75 0.016 - 20 Si 0.625 0.375 0.25 0.016 - 21 Si 0.75 0.875 0.125 0.016 - 22 Si 0.25 0.625 0.375 0.016 - 23 Si 0.625 0.75 0.375 0.016 - 24 W 0.5 0 0 2.723 - 25 W 0.5 0.5 0 2.723 - 26 W 0 0.5 0.5 2.723 - 27 W 0 0 0.5 2.723 - 28 W 0.5 0.5 0.5 2.723 - 29 W 0 0.5 0 2.723 - 30 W 0.5 0 0.5 2.723 - 31 W 0 0 0 2.723 - 32 O 0.592105 0.89052 0.379772 0.017 - 33 O 0.379772 0.592105 0.89052 0.017 - 34 O 0.287667 0.298415 0.907895 0.017 - 35 O 0.489252 0.60948 0.201585 0.017 - 36 O 0.298415 0.89052 0.010748 0.018 - 37 O 0.120228 0.010748 0.212333 0.017 - 38 O 0.379772 0.287667 0.489252 0.017 - 39 O 0.89052 0.379772 0.592105 0.017 - 40 O 0.201585 0.212333 0.592105 0.018 - 41 O 0.489252 0.379772 0.287667 0.017 - 42 O 0.89052 0.010748 0.298415 0.018 - 43 O 0.60948 0.907895 0.120228 0.018 - 44 O 0.907895 0.120228 0.60948 0.017 - 45 O 0.287667 0.489252 0.379772 0.017 - 46 O 0.592105 0.201585 0.212333 0.017 - 47 O 0.212333 0.592105 0.201585 0.017 - 48 O 0.010748 0.298415 0.89052 0.017 - 49 O 0.907895 0.287667 0.298415 0.017 - 50 O 0.010748 0.212333 0.120228 0.017 - 51 O 0.798415 0.787667 0.407895 0.018 - 52 O 0.201585 0.489252 0.60948 0.018 - 53 O 0.60948 0.201585 0.489252 0.017 - 54 O 0.212333 0.120228 0.010748 0.017 - 55 O 0.120228 0.60948 0.907895 0.017 - 56 O 0.407895 0.10948 0.620228 0.017 - 57 O 0.620228 0.407895 0.10948 0.017 - 58 O 0.712333 0.701585 0.092105 0.017 - 59 O 0.510748 0.39052 0.798415 0.017 - 60 O 0.701585 0.10948 0.989252 0.018 - 61 O 0.879772 0.989252 0.787667 0.017 - 62 O 0.620228 0.712333 0.510748 0.017 - 63 O 0.10948 0.620228 0.407895 0.018 - 64 O 0.879772 0.39052 0.092105 0.017 - 65 O 0.787667 0.879772 0.989252 0.017 - 66 O 0.39052 0.798415 0.510748 0.018 - 67 O 0.701585 0.092105 0.712333 0.018 - 68 O 0.798415 0.510748 0.39052 0.018 - 69 O 0.989252 0.787667 0.879772 0.017 - 70 O 0.092105 0.712333 0.701585 0.017 - 71 O 0.989252 0.701585 0.10948 0.017 - 72 O 0.787667 0.407895 0.798415 0.017 - 73 O 0.407895 0.798415 0.787667 0.017 - 74 O 0.712333 0.510748 0.620228 0.017 - 75 O 0.092105 0.879772 0.39052 0.017 - 76 O 0.39052 0.092105 0.879772 0.018 - 77 O 0.10948 0.989252 0.701585 0.018 - 78 O 0.510748 0.620228 0.712333 0.017 - 79 O 0.298415 0.907895 0.287667 0.018","# generated using pymatgen -data_Ca3Si3(WO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80496075 -_cell_length_b 10.80496075 -_cell_length_c 10.80496075 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Si3(WO6)2 -_chemical_formula_sum 'Ca12 Si12 W8 O48' -_cell_volume 971.06363473 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - W W24 1 0.50000000 0.00000000 0.00000000 1 - W W25 1 0.50000000 0.50000000 0.00000000 1 - W W26 1 0.00000000 0.50000000 0.50000000 1 - W W27 1 0.00000000 0.00000000 0.50000000 1 - W W28 1 0.50000000 0.50000000 0.50000000 1 - W W29 1 0.00000000 0.50000000 0.00000000 1 - W W30 1 0.50000000 0.00000000 0.50000000 1 - W W31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59210500 0.89052000 0.37977200 1 - O O33 1 0.37977200 0.59210500 0.89052000 1 - O O34 1 0.28766700 0.29841500 0.90789500 1 - O O35 1 0.48925200 0.60948000 0.20158500 1 - O O36 1 0.29841500 0.89052000 0.01074800 1 - O O37 1 0.12022800 0.01074800 0.21233300 1 - O O38 1 0.37977200 0.28766700 0.48925200 1 - O O39 1 0.89052000 0.37977200 0.59210500 1 - O O40 1 0.20158500 0.21233300 0.59210500 1 - O O41 1 0.48925200 0.37977200 0.28766700 1 - O O42 1 0.89052000 0.01074800 0.29841500 1 - O O43 1 0.60948000 0.90789500 0.12022800 1 - O O44 1 0.90789500 0.12022800 0.60948000 1 - O O45 1 0.28766700 0.48925200 0.37977200 1 - O O46 1 0.59210500 0.20158500 0.21233300 1 - O O47 1 0.21233300 0.59210500 0.20158500 1 - O O48 1 0.01074800 0.29841500 0.89052000 1 - O O49 1 0.90789500 0.28766700 0.29841500 1 - O O50 1 0.01074800 0.21233300 0.12022800 1 - O O51 1 0.79841500 0.78766700 0.40789500 1 - O O52 1 0.20158500 0.48925200 0.60948000 1 - O O53 1 0.60948000 0.20158500 0.48925200 1 - O O54 1 0.21233300 0.12022800 0.01074800 1 - O O55 1 0.12022800 0.60948000 0.90789500 1 - O O56 1 0.40789500 0.10948000 0.62022800 1 - O O57 1 0.62022800 0.40789500 0.10948000 1 - O O58 1 0.71233300 0.70158500 0.09210500 1 - O O59 1 0.51074800 0.39052000 0.79841500 1 - O O60 1 0.70158500 0.10948000 0.98925200 1 - O O61 1 0.87977200 0.98925200 0.78766700 1 - O O62 1 0.62022800 0.71233300 0.51074800 1 - O O63 1 0.10948000 0.62022800 0.40789500 1 - O O64 1 0.87977200 0.39052000 0.09210500 1 - O O65 1 0.78766700 0.87977200 0.98925200 1 - O O66 1 0.39052000 0.79841500 0.51074800 1 - O O67 1 0.70158500 0.09210500 0.71233300 1 - O O68 1 0.79841500 0.51074800 0.39052000 1 - O O69 1 0.98925200 0.78766700 0.87977200 1 - O O70 1 0.09210500 0.71233300 0.70158500 1 - O O71 1 0.98925200 0.70158500 0.10948000 1 - O O72 1 0.78766700 0.40789500 0.79841500 1 - O O73 1 0.40789500 0.79841500 0.78766700 1 - O O74 1 0.71233300 0.51074800 0.62022800 1 - O O75 1 0.09210500 0.87977200 0.39052000 1 - O O76 1 0.39052000 0.09210500 0.87977200 1 - O O77 1 0.10948000 0.98925200 0.70158500 1 - O O78 1 0.51074800 0.62022800 0.71233300 1 - O O79 1 0.29841500 0.90789500 0.28766700 1 -" -Mg3Si3(NiO6)2,mp-1154758,Ia-3d,[],0.10595966437499715,{'tags': []},"Full Formula (Mg12 Si12 Ni8 O48) -Reduced Formula: Mg3Si3(NiO6)2 -abc : 10.088612 10.088612 10.088612 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0.001 - 1 Mg 0.75 0.125 0.375 0.001 - 2 Mg 0.375 0.125 0.25 0.001 - 3 Mg 0.125 0.375 0.75 0.001 - 4 Mg 0.25 0.875 0.625 0.001 - 5 Mg 0.125 0.25 0.375 0.001 - 6 Mg 0.625 0.25 0.875 0.001 - 7 Mg 0.75 0.625 0.875 0.001 - 8 Mg 0.875 0.75 0.625 0.001 - 9 Mg 0.875 0.625 0.25 0.001 - 10 Mg 0.625 0.875 0.75 0.001 - 11 Mg 0.375 0.75 0.125 0.001 - 12 Si 0.125 0.75 0.875 0.012 - 13 Si 0.875 0.25 0.125 0.012 - 14 Si 0.75 0.375 0.625 0.012 - 15 Si 0.125 0.875 0.25 0.012 - 16 Si 0.25 0.125 0.875 0.012 - 17 Si 0.375 0.625 0.75 0.012 - 18 Si 0.375 0.25 0.625 0.012 - 19 Si 0.875 0.125 0.75 0.012 - 20 Si 0.625 0.375 0.25 0.012 - 21 Si 0.75 0.875 0.125 0.012 - 22 Si 0.25 0.625 0.375 0.012 - 23 Si 0.625 0.75 0.375 0.012 - 24 Ni 0.5 0 0 1.513 - 25 Ni 0.5 0.5 0 1.513 - 26 Ni 0 0.5 0.5 1.513 - 27 Ni 0 0 0.5 1.513 - 28 Ni 0.5 0.5 0.5 1.513 - 29 Ni 0 0.5 0 1.513 - 30 Ni 0.5 0 0.5 1.513 - 31 Ni 0 0 0 1.513 - 32 O 0.587611 0.897237 0.374643 -0.077 - 33 O 0.374643 0.587611 0.897237 -0.077 - 34 O 0.287032 0.309626 0.912389 -0.077 - 35 O 0.477406 0.602763 0.190374 -0.077 - 36 O 0.309626 0.897237 0.022594 -0.077 - 37 O 0.125357 0.022594 0.212968 -0.077 - 38 O 0.374643 0.287032 0.477406 -0.077 - 39 O 0.897237 0.374643 0.587611 -0.077 - 40 O 0.190374 0.212968 0.587611 -0.077 - 41 O 0.477406 0.374643 0.287032 -0.077 - 42 O 0.897237 0.022594 0.309626 -0.077 - 43 O 0.602763 0.912389 0.125357 -0.077 - 44 O 0.912389 0.125357 0.602763 -0.077 - 45 O 0.287032 0.477406 0.374643 -0.077 - 46 O 0.587611 0.190374 0.212968 -0.077 - 47 O 0.212968 0.587611 0.190374 -0.077 - 48 O 0.022594 0.309626 0.897237 -0.077 - 49 O 0.912389 0.287032 0.309626 -0.077 - 50 O 0.022594 0.212968 0.125357 -0.077 - 51 O 0.809626 0.787032 0.412389 -0.077 - 52 O 0.190374 0.477406 0.602763 -0.077 - 53 O 0.602763 0.190374 0.477406 -0.077 - 54 O 0.212968 0.125357 0.022594 -0.077 - 55 O 0.125357 0.602763 0.912389 -0.077 - 56 O 0.412389 0.102763 0.625357 -0.077 - 57 O 0.625357 0.412389 0.102763 -0.077 - 58 O 0.712968 0.690374 0.087611 -0.077 - 59 O 0.522594 0.397237 0.809626 -0.077 - 60 O 0.690374 0.102763 0.977406 -0.077 - 61 O 0.874643 0.977406 0.787032 -0.077 - 62 O 0.625357 0.712968 0.522594 -0.077 - 63 O 0.102763 0.625357 0.412389 -0.077 - 64 O 0.874643 0.397237 0.087611 -0.077 - 65 O 0.787032 0.874643 0.977406 -0.077 - 66 O 0.397237 0.809626 0.522594 -0.077 - 67 O 0.690374 0.087611 0.712968 -0.077 - 68 O 0.809626 0.522594 0.397237 -0.077 - 69 O 0.977406 0.787032 0.874643 -0.077 - 70 O 0.087611 0.712968 0.690374 -0.077 - 71 O 0.977406 0.690374 0.102763 -0.077 - 72 O 0.787032 0.412389 0.809626 -0.077 - 73 O 0.412389 0.809626 0.787032 -0.077 - 74 O 0.712968 0.522594 0.625357 -0.077 - 75 O 0.087611 0.874643 0.397237 -0.077 - 76 O 0.397237 0.087611 0.874643 -0.077 - 77 O 0.102763 0.977406 0.690374 -0.077 - 78 O 0.522594 0.625357 0.712968 -0.077 - 79 O 0.309626 0.912389 0.287032 -0.077","# generated using pymatgen -data_Mg3Si3(NiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.08861225 -_cell_length_b 10.08861225 -_cell_length_c 10.08861225 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Si3(NiO6)2 -_chemical_formula_sum 'Mg12 Si12 Ni8 O48' -_cell_volume 790.44635499 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Ni Ni24 1 0.50000000 0.00000000 0.00000000 1 - Ni Ni25 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni26 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni27 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni28 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni29 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni30 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.58761100 0.89723700 0.37464300 1 - O O33 1 0.37464300 0.58761100 0.89723700 1 - O O34 1 0.28703200 0.30962600 0.91238900 1 - O O35 1 0.47740600 0.60276300 0.19037400 1 - O O36 1 0.30962600 0.89723700 0.02259400 1 - O O37 1 0.12535700 0.02259400 0.21296800 1 - O O38 1 0.37464300 0.28703200 0.47740600 1 - O O39 1 0.89723700 0.37464300 0.58761100 1 - O O40 1 0.19037400 0.21296800 0.58761100 1 - O O41 1 0.47740600 0.37464300 0.28703200 1 - O O42 1 0.89723700 0.02259400 0.30962600 1 - O O43 1 0.60276300 0.91238900 0.12535700 1 - O O44 1 0.91238900 0.12535700 0.60276300 1 - O O45 1 0.28703200 0.47740600 0.37464300 1 - O O46 1 0.58761100 0.19037400 0.21296800 1 - O O47 1 0.21296800 0.58761100 0.19037400 1 - O O48 1 0.02259400 0.30962600 0.89723700 1 - O O49 1 0.91238900 0.28703200 0.30962600 1 - O O50 1 0.02259400 0.21296800 0.12535700 1 - O O51 1 0.80962600 0.78703200 0.41238900 1 - O O52 1 0.19037400 0.47740600 0.60276300 1 - O O53 1 0.60276300 0.19037400 0.47740600 1 - O O54 1 0.21296800 0.12535700 0.02259400 1 - O O55 1 0.12535700 0.60276300 0.91238900 1 - O O56 1 0.41238900 0.10276300 0.62535700 1 - O O57 1 0.62535700 0.41238900 0.10276300 1 - O O58 1 0.71296800 0.69037400 0.08761100 1 - O O59 1 0.52259400 0.39723700 0.80962600 1 - O O60 1 0.69037400 0.10276300 0.97740600 1 - O O61 1 0.87464300 0.97740600 0.78703200 1 - O O62 1 0.62535700 0.71296800 0.52259400 1 - O O63 1 0.10276300 0.62535700 0.41238900 1 - O O64 1 0.87464300 0.39723700 0.08761100 1 - O O65 1 0.78703200 0.87464300 0.97740600 1 - O O66 1 0.39723700 0.80962600 0.52259400 1 - O O67 1 0.69037400 0.08761100 0.71296800 1 - O O68 1 0.80962600 0.52259400 0.39723700 1 - O O69 1 0.97740600 0.78703200 0.87464300 1 - O O70 1 0.08761100 0.71296800 0.69037400 1 - O O71 1 0.97740600 0.69037400 0.10276300 1 - O O72 1 0.78703200 0.41238900 0.80962600 1 - O O73 1 0.41238900 0.80962600 0.78703200 1 - O O74 1 0.71296800 0.52259400 0.62535700 1 - O O75 1 0.08761100 0.87464300 0.39723700 1 - O O76 1 0.39723700 0.08761100 0.87464300 1 - O O77 1 0.10276300 0.97740600 0.69037400 1 - O O78 1 0.52259400 0.62535700 0.71296800 1 - O O79 1 0.30962600 0.91238900 0.28703200 1 -" -Ca3Si3(AgO6)2,mp-1157153,Ia-3d,[],0.10825221283333697,{'tags': []},"Full Formula (Ca12 Si12 Ag8 O48) -Reduced Formula: Ca3Si3(AgO6)2 -abc : 10.818140 10.818140 10.818140 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0.002 - 1 Ca 0.75 0.125 0.375 -0.002 - 2 Ca 0.375 0.125 0.25 -0.002 - 3 Ca 0.125 0.375 0.75 -0.002 - 4 Ca 0.25 0.875 0.625 -0.002 - 5 Ca 0.125 0.25 0.375 -0.002 - 6 Ca 0.625 0.25 0.875 -0.002 - 7 Ca 0.75 0.625 0.875 -0.002 - 8 Ca 0.875 0.75 0.625 -0.002 - 9 Ca 0.875 0.625 0.25 -0.002 - 10 Ca 0.625 0.875 0.75 -0.002 - 11 Ca 0.375 0.75 0.125 -0.002 - 12 Si 0.125 0.75 0.875 0.003 - 13 Si 0.875 0.25 0.125 0.003 - 14 Si 0.75 0.375 0.625 0.003 - 15 Si 0.125 0.875 0.25 0.003 - 16 Si 0.25 0.125 0.875 0.003 - 17 Si 0.375 0.625 0.75 0.003 - 18 Si 0.375 0.25 0.625 0.003 - 19 Si 0.875 0.125 0.75 0.003 - 20 Si 0.625 0.375 0.25 0.003 - 21 Si 0.75 0.875 0.125 0.003 - 22 Si 0.25 0.625 0.375 0.003 - 23 Si 0.625 0.75 0.375 0.003 - 24 Ag 0.5 0 0 0.7 - 25 Ag 0.5 0.5 0 0.7 - 26 Ag 0 0.5 0.5 0.7 - 27 Ag 0 0 0.5 0.7 - 28 Ag 0.5 0.5 0.5 0.7 - 29 Ag 0 0.5 0 0.7 - 30 Ag 0.5 0 0.5 0.7 - 31 Ag 0 0 0 0.7 - 32 O 0.595789 0.891964 0.376912 0.184 - 33 O 0.376912 0.595789 0.891964 0.184 - 34 O 0.281124 0.296175 0.904211 0.184 - 35 O 0.484949 0.608036 0.203825 0.184 - 36 O 0.296175 0.891964 0.015051 0.184 - 37 O 0.123088 0.015051 0.218876 0.184 - 38 O 0.376912 0.281124 0.484949 0.184 - 39 O 0.891964 0.376912 0.595789 0.184 - 40 O 0.203825 0.218876 0.595789 0.184 - 41 O 0.484949 0.376912 0.281124 0.184 - 42 O 0.891964 0.015051 0.296175 0.184 - 43 O 0.608036 0.904211 0.123088 0.184 - 44 O 0.904211 0.123088 0.608036 0.184 - 45 O 0.281124 0.484949 0.376912 0.184 - 46 O 0.595789 0.203825 0.218876 0.184 - 47 O 0.218876 0.595789 0.203825 0.184 - 48 O 0.015051 0.296175 0.891964 0.184 - 49 O 0.904211 0.281124 0.296175 0.184 - 50 O 0.015051 0.218876 0.123088 0.184 - 51 O 0.796175 0.781124 0.404211 0.184 - 52 O 0.203825 0.484949 0.608036 0.184 - 53 O 0.608036 0.203825 0.484949 0.184 - 54 O 0.218876 0.123088 0.015051 0.184 - 55 O 0.123088 0.608036 0.904211 0.184 - 56 O 0.404211 0.108036 0.623088 0.184 - 57 O 0.623088 0.404211 0.108036 0.184 - 58 O 0.718876 0.703825 0.095789 0.184 - 59 O 0.515051 0.391964 0.796175 0.184 - 60 O 0.703825 0.108036 0.984949 0.184 - 61 O 0.876912 0.984949 0.781124 0.184 - 62 O 0.623088 0.718876 0.515051 0.184 - 63 O 0.108036 0.623088 0.404211 0.184 - 64 O 0.876912 0.391964 0.095789 0.184 - 65 O 0.781124 0.876912 0.984949 0.184 - 66 O 0.391964 0.796175 0.515051 0.184 - 67 O 0.703825 0.095789 0.718876 0.184 - 68 O 0.796175 0.515051 0.391964 0.184 - 69 O 0.984949 0.781124 0.876912 0.184 - 70 O 0.095789 0.718876 0.703825 0.184 - 71 O 0.984949 0.703825 0.108036 0.184 - 72 O 0.781124 0.404211 0.796175 0.184 - 73 O 0.404211 0.796175 0.781124 0.184 - 74 O 0.718876 0.515051 0.623088 0.184 - 75 O 0.095789 0.876912 0.391964 0.184 - 76 O 0.391964 0.095789 0.876912 0.184 - 77 O 0.108036 0.984949 0.703825 0.184 - 78 O 0.515051 0.623088 0.718876 0.184 - 79 O 0.296175 0.904211 0.281124 0.184","# generated using pymatgen -data_Ca3Si3(AgO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.81813993 -_cell_length_b 10.81813993 -_cell_length_c 10.81813993 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Si3(AgO6)2 -_chemical_formula_sum 'Ca12 Si12 Ag8 O48' -_cell_volume 974.62128767 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Ag Ag24 1 0.50000000 0.00000000 0.00000000 1 - Ag Ag25 1 0.50000000 0.50000000 0.00000000 1 - Ag Ag26 1 0.00000000 0.50000000 0.50000000 1 - Ag Ag27 1 0.00000000 0.00000000 0.50000000 1 - Ag Ag28 1 0.50000000 0.50000000 0.50000000 1 - Ag Ag29 1 0.00000000 0.50000000 0.00000000 1 - Ag Ag30 1 0.50000000 0.00000000 0.50000000 1 - Ag Ag31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59578900 0.89196400 0.37691200 1 - O O33 1 0.37691200 0.59578900 0.89196400 1 - O O34 1 0.28112400 0.29617500 0.90421100 1 - O O35 1 0.48494900 0.60803600 0.20382500 1 - O O36 1 0.29617500 0.89196400 0.01505100 1 - O O37 1 0.12308800 0.01505100 0.21887600 1 - O O38 1 0.37691200 0.28112400 0.48494900 1 - O O39 1 0.89196400 0.37691200 0.59578900 1 - O O40 1 0.20382500 0.21887600 0.59578900 1 - O O41 1 0.48494900 0.37691200 0.28112400 1 - O O42 1 0.89196400 0.01505100 0.29617500 1 - O O43 1 0.60803600 0.90421100 0.12308800 1 - O O44 1 0.90421100 0.12308800 0.60803600 1 - O O45 1 0.28112400 0.48494900 0.37691200 1 - O O46 1 0.59578900 0.20382500 0.21887600 1 - O O47 1 0.21887600 0.59578900 0.20382500 1 - O O48 1 0.01505100 0.29617500 0.89196400 1 - O O49 1 0.90421100 0.28112400 0.29617500 1 - O O50 1 0.01505100 0.21887600 0.12308800 1 - O O51 1 0.79617500 0.78112400 0.40421100 1 - O O52 1 0.20382500 0.48494900 0.60803600 1 - O O53 1 0.60803600 0.20382500 0.48494900 1 - O O54 1 0.21887600 0.12308800 0.01505100 1 - O O55 1 0.12308800 0.60803600 0.90421100 1 - O O56 1 0.40421100 0.10803600 0.62308800 1 - O O57 1 0.62308800 0.40421100 0.10803600 1 - O O58 1 0.71887600 0.70382500 0.09578900 1 - O O59 1 0.51505100 0.39196400 0.79617500 1 - O O60 1 0.70382500 0.10803600 0.98494900 1 - O O61 1 0.87691200 0.98494900 0.78112400 1 - O O62 1 0.62308800 0.71887600 0.51505100 1 - O O63 1 0.10803600 0.62308800 0.40421100 1 - O O64 1 0.87691200 0.39196400 0.09578900 1 - O O65 1 0.78112400 0.87691200 0.98494900 1 - O O66 1 0.39196400 0.79617500 0.51505100 1 - O O67 1 0.70382500 0.09578900 0.71887600 1 - O O68 1 0.79617500 0.51505100 0.39196400 1 - O O69 1 0.98494900 0.78112400 0.87691200 1 - O O70 1 0.09578900 0.71887600 0.70382500 1 - O O71 1 0.98494900 0.70382500 0.10803600 1 - O O72 1 0.78112400 0.40421100 0.79617500 1 - O O73 1 0.40421100 0.79617500 0.78112400 1 - O O74 1 0.71887600 0.51505100 0.62308800 1 - O O75 1 0.09578900 0.87691200 0.39196400 1 - O O76 1 0.39196400 0.09578900 0.87691200 1 - O O77 1 0.10803600 0.98494900 0.70382500 1 - O O78 1 0.51505100 0.62308800 0.71887600 1 - O O79 1 0.29617500 0.90421100 0.28112400 1 -" -Zn3Cu2(SiO4)3,mp-1157205,Ia-3d,[],0.1837274546249965,{'tags': []},"Full Formula (Zn12 Cu8 Si12 O48) -Reduced Formula: Zn3Cu2(SiO4)3 -abc : 10.173770 10.173770 10.173770 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.75 0.125 0.375 0 - 1 Zn 0.25 0.375 0.125 0 - 2 Zn 0.125 0.25 0.375 0 - 3 Zn 0.375 0.75 0.125 0 - 4 Zn 0.75 0.625 0.875 0 - 5 Zn 0.125 0.375 0.75 0 - 6 Zn 0.625 0.875 0.75 0 - 7 Zn 0.25 0.875 0.625 0 - 8 Zn 0.875 0.625 0.25 0 - 9 Zn 0.625 0.25 0.875 0 - 10 Zn 0.875 0.75 0.625 0 - 11 Zn 0.375 0.125 0.25 0 - 12 Cu 0 0 0 0.958 - 13 Cu 0.5 0 0 0.958 - 14 Cu 0 0.5 0 0.958 - 15 Cu 0.5 0.5 0 0.958 - 16 Cu 0 0.5 0.5 0.958 - 17 Cu 0.5 0 0.5 0.958 - 18 Cu 0.5 0.5 0.5 0.958 - 19 Cu 0 0 0.5 0.958 - 20 Si 0.125 0.875 0.25 0.004 - 21 Si 0.875 0.125 0.75 0.004 - 22 Si 0.25 0.625 0.375 0.004 - 23 Si 0.375 0.25 0.625 0.004 - 24 Si 0.75 0.875 0.125 0.004 - 25 Si 0.125 0.75 0.875 0.004 - 26 Si 0.375 0.625 0.75 0.004 - 27 Si 0.625 0.75 0.375 0.004 - 28 Si 0.875 0.25 0.125 0.004 - 29 Si 0.25 0.125 0.875 0.004 - 30 Si 0.75 0.375 0.625 0.004 - 31 Si 0.625 0.375 0.25 0.004 - 32 O 0.479974 0.375623 0.290301 0.149 - 33 O 0.310327 0.895649 0.020026 0.149 - 34 O 0.604351 0.914678 0.124377 0.149 - 35 O 0.585322 0.189673 0.209699 0.149 - 36 O 0.124377 0.020026 0.209699 0.149 - 37 O 0.189673 0.209699 0.585322 0.149 - 38 O 0.189673 0.479974 0.604351 0.149 - 39 O 0.209699 0.585322 0.189673 0.149 - 40 O 0.375623 0.585322 0.895649 0.149 - 41 O 0.914678 0.290301 0.310327 0.149 - 42 O 0.290301 0.310327 0.914678 0.149 - 43 O 0.209699 0.124377 0.020026 0.149 - 44 O 0.479974 0.604351 0.189673 0.149 - 45 O 0.895649 0.375623 0.585322 0.149 - 46 O 0.020026 0.209699 0.124377 0.149 - 47 O 0.604351 0.189673 0.479974 0.149 - 48 O 0.585322 0.895649 0.375623 0.149 - 49 O 0.020026 0.310327 0.895649 0.149 - 50 O 0.914678 0.124377 0.604351 0.149 - 51 O 0.624377 0.414678 0.104351 0.149 - 52 O 0.124377 0.604351 0.914678 0.149 - 53 O 0.290301 0.479974 0.375623 0.149 - 54 O 0.895649 0.020026 0.310327 0.149 - 55 O 0.310327 0.914678 0.290301 0.149 - 56 O 0.520026 0.624377 0.709699 0.149 - 57 O 0.689673 0.104351 0.979974 0.149 - 58 O 0.395649 0.085322 0.875623 0.149 - 59 O 0.414678 0.810327 0.790301 0.149 - 60 O 0.875623 0.979974 0.790301 0.149 - 61 O 0.810327 0.790301 0.414678 0.149 - 62 O 0.810327 0.520026 0.395649 0.149 - 63 O 0.790301 0.414678 0.810327 0.149 - 64 O 0.689673 0.085322 0.709699 0.149 - 65 O 0.104351 0.979974 0.689673 0.149 - 66 O 0.709699 0.520026 0.624377 0.149 - 67 O 0.624377 0.709699 0.520026 0.149 - 68 O 0.875623 0.395649 0.085322 0.149 - 69 O 0.085322 0.875623 0.395649 0.149 - 70 O 0.979974 0.689673 0.104351 0.149 - 71 O 0.414678 0.104351 0.624377 0.149 - 72 O 0.395649 0.810327 0.520026 0.149 - 73 O 0.979974 0.790301 0.875623 0.149 - 74 O 0.104351 0.624377 0.414678 0.149 - 75 O 0.520026 0.395649 0.810327 0.149 - 76 O 0.790301 0.875623 0.979974 0.149 - 77 O 0.709699 0.689673 0.085322 0.149 - 78 O 0.085322 0.709699 0.689673 0.149 - 79 O 0.375623 0.290301 0.479974 0.149","# generated using pymatgen -data_Zn3Cu2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.17377026 -_cell_length_b 10.17377026 -_cell_length_c 10.17377026 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Cu2(SiO4)3 -_chemical_formula_sum 'Zn12 Cu8 Si12 O48' -_cell_volume 810.63227060 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn1 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn2 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn3 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn4 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn5 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn6 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn7 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn8 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn9 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn10 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn11 1 0.37500000 0.12500000 0.25000000 1 - Cu Cu12 1 0.00000000 0.00000000 0.00000000 1 - Cu Cu13 1 0.50000000 0.00000000 0.00000000 1 - Cu Cu14 1 0.00000000 0.50000000 0.00000000 1 - Cu Cu15 1 0.50000000 0.50000000 0.00000000 1 - Cu Cu16 1 0.00000000 0.50000000 0.50000000 1 - Cu Cu17 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu18 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu19 1 0.00000000 0.00000000 0.50000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.47997400 0.37562300 0.29030100 1 - O O33 1 0.31032700 0.89564900 0.02002600 1 - O O34 1 0.60435100 0.91467800 0.12437700 1 - O O35 1 0.58532200 0.18967300 0.20969900 1 - O O36 1 0.12437700 0.02002600 0.20969900 1 - O O37 1 0.18967300 0.20969900 0.58532200 1 - O O38 1 0.18967300 0.47997400 0.60435100 1 - O O39 1 0.20969900 0.58532200 0.18967300 1 - O O40 1 0.37562300 0.58532200 0.89564900 1 - O O41 1 0.91467800 0.29030100 0.31032700 1 - O O42 1 0.29030100 0.31032700 0.91467800 1 - O O43 1 0.20969900 0.12437700 0.02002600 1 - O O44 1 0.47997400 0.60435100 0.18967300 1 - O O45 1 0.89564900 0.37562300 0.58532200 1 - O O46 1 0.02002600 0.20969900 0.12437700 1 - O O47 1 0.60435100 0.18967300 0.47997400 1 - O O48 1 0.58532200 0.89564900 0.37562300 1 - O O49 1 0.02002600 0.31032700 0.89564900 1 - O O50 1 0.91467800 0.12437700 0.60435100 1 - O O51 1 0.62437700 0.41467800 0.10435100 1 - O O52 1 0.12437700 0.60435100 0.91467800 1 - O O53 1 0.29030100 0.47997400 0.37562300 1 - O O54 1 0.89564900 0.02002600 0.31032700 1 - O O55 1 0.31032700 0.91467800 0.29030100 1 - O O56 1 0.52002600 0.62437700 0.70969900 1 - O O57 1 0.68967300 0.10435100 0.97997400 1 - O O58 1 0.39564900 0.08532200 0.87562300 1 - O O59 1 0.41467800 0.81032700 0.79030100 1 - O O60 1 0.87562300 0.97997400 0.79030100 1 - O O61 1 0.81032700 0.79030100 0.41467800 1 - O O62 1 0.81032700 0.52002600 0.39564900 1 - O O63 1 0.79030100 0.41467800 0.81032700 1 - O O64 1 0.68967300 0.08532200 0.70969900 1 - O O65 1 0.10435100 0.97997400 0.68967300 1 - O O66 1 0.70969900 0.52002600 0.62437700 1 - O O67 1 0.62437700 0.70969900 0.52002600 1 - O O68 1 0.87562300 0.39564900 0.08532200 1 - O O69 1 0.08532200 0.87562300 0.39564900 1 - O O70 1 0.97997400 0.68967300 0.10435100 1 - O O71 1 0.41467800 0.10435100 0.62437700 1 - O O72 1 0.39564900 0.81032700 0.52002600 1 - O O73 1 0.97997400 0.79030100 0.87562300 1 - O O74 1 0.10435100 0.62437700 0.41467800 1 - O O75 1 0.52002600 0.39564900 0.81032700 1 - O O76 1 0.79030100 0.87562300 0.97997400 1 - O O77 1 0.70969900 0.68967300 0.08532200 1 - O O78 1 0.08532200 0.70969900 0.68967300 1 - O O79 1 0.37562300 0.29030100 0.47997400 1 -" -Y2Si3(WO4)3,mp-1157227,Ia-3d,[],0.6078464569166666,{'tags': []},"Full Formula (Y8 Si12 W12 O48) -Reduced Formula: Y2Si3(WO4)3 -abc : 11.106660 11.106660 11.106660 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0 0.003 - 1 Y 0.5 0 0 0.003 - 2 Y 0.5 0.5 0 0.003 - 3 Y 0 0.5 0.5 0.003 - 4 Y 0 0 0.5 0.003 - 5 Y 0.5 0.5 0.5 0.003 - 6 Y 0 0.5 0 0.003 - 7 Y 0.5 0 0.5 0.003 - 8 Si 0.125 0.75 0.875 0.022 - 9 Si 0.75 0.875 0.125 0.022 - 10 Si 0.25 0.625 0.375 0.022 - 11 Si 0.625 0.75 0.375 0.022 - 12 Si 0.875 0.125 0.75 0.022 - 13 Si 0.375 0.25 0.625 0.022 - 14 Si 0.375 0.625 0.75 0.022 - 15 Si 0.25 0.125 0.875 0.022 - 16 Si 0.625 0.375 0.25 0.022 - 17 Si 0.125 0.875 0.25 0.022 - 18 Si 0.75 0.375 0.625 0.022 - 19 Si 0.875 0.25 0.125 0.022 - 20 W 0.875 0.75 0.625 3.454 - 21 W 0.875 0.625 0.25 3.454 - 22 W 0.625 0.875 0.75 3.454 - 23 W 0.25 0.875 0.625 3.454 - 24 W 0.75 0.625 0.875 3.454 - 25 W 0.625 0.25 0.875 3.454 - 26 W 0.125 0.25 0.375 3.454 - 27 W 0.125 0.375 0.75 3.454 - 28 W 0.375 0.125 0.25 3.454 - 29 W 0.75 0.125 0.375 3.454 - 30 W 0.25 0.375 0.125 3.454 - 31 W 0.375 0.75 0.125 3.454 - 32 O 0.58339 0.880186 0.371703 0.024 - 33 O 0.371703 0.58339 0.880186 0.024 - 34 O 0.288313 0.296796 0.91661 0.024 - 35 O 0.491517 0.619813 0.203204 0.024 - 36 O 0.296796 0.880186 0.008483 0.024 - 37 O 0.128297 0.008483 0.211687 0.024 - 38 O 0.371703 0.288313 0.491517 0.024 - 39 O 0.880186 0.371703 0.58339 0.024 - 40 O 0.203204 0.211687 0.58339 0.024 - 41 O 0.491517 0.371703 0.288313 0.024 - 42 O 0.880186 0.008483 0.296796 0.024 - 43 O 0.619814 0.91661 0.128297 0.024 - 44 O 0.91661 0.128297 0.619814 0.024 - 45 O 0.288313 0.491517 0.371703 0.024 - 46 O 0.58339 0.203204 0.211687 0.024 - 47 O 0.211687 0.58339 0.203204 0.024 - 48 O 0.008483 0.296796 0.880187 0.024 - 49 O 0.91661 0.288313 0.296796 0.024 - 50 O 0.008483 0.211687 0.128297 0.024 - 51 O 0.796796 0.788313 0.41661 0.024 - 52 O 0.296796 0.91661 0.288313 0.024 - 53 O 0.619814 0.203204 0.491517 0.024 - 54 O 0.211687 0.128297 0.008483 0.024 - 55 O 0.128297 0.619813 0.91661 0.024 - 56 O 0.41661 0.119813 0.628297 0.024 - 57 O 0.628297 0.41661 0.119814 0.024 - 58 O 0.711687 0.703204 0.08339 0.024 - 59 O 0.508483 0.380186 0.796796 0.024 - 60 O 0.703204 0.119813 0.991517 0.024 - 61 O 0.871703 0.991517 0.788313 0.024 - 62 O 0.628297 0.711687 0.508483 0.024 - 63 O 0.119814 0.628297 0.41661 0.024 - 64 O 0.871703 0.380186 0.08339 0.024 - 65 O 0.788313 0.871703 0.991517 0.024 - 66 O 0.380186 0.796796 0.508483 0.024 - 67 O 0.703204 0.08339 0.711687 0.024 - 68 O 0.796796 0.508483 0.380186 0.024 - 69 O 0.991517 0.788313 0.871703 0.024 - 70 O 0.08339 0.711687 0.703204 0.024 - 71 O 0.991517 0.703204 0.119814 0.024 - 72 O 0.788313 0.41661 0.796796 0.024 - 73 O 0.41661 0.796796 0.788313 0.024 - 74 O 0.711687 0.508483 0.628297 0.024 - 75 O 0.08339 0.871703 0.380186 0.024 - 76 O 0.380186 0.08339 0.871703 0.024 - 77 O 0.119814 0.991517 0.703204 0.024 - 78 O 0.508483 0.628297 0.711687 0.024 - 79 O 0.203204 0.491517 0.619813 0.024","# generated using pymatgen -data_Y2Si3(WO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.10665976 -_cell_length_b 11.10665976 -_cell_length_c 11.10665976 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Si3(WO4)3 -_chemical_formula_sum 'Y8 Si12 W12 O48' -_cell_volume 1054.69894755 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.00000000 1 - Y Y1 1 0.50000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.50000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.50000000 1 - Y Y4 1 0.00000000 0.00000000 0.50000000 1 - Y Y5 1 0.50000000 0.50000000 0.50000000 1 - Y Y6 1 0.00000000 0.50000000 0.00000000 1 - Y Y7 1 0.50000000 0.00000000 0.50000000 1 - Si Si8 1 0.12500000 0.75000000 0.87500000 1 - Si Si9 1 0.75000000 0.87500000 0.12500000 1 - Si Si10 1 0.25000000 0.62500000 0.37500000 1 - Si Si11 1 0.62500000 0.75000000 0.37500000 1 - Si Si12 1 0.87500000 0.12500000 0.75000000 1 - Si Si13 1 0.37500000 0.25000000 0.62500000 1 - Si Si14 1 0.37500000 0.62500000 0.75000000 1 - Si Si15 1 0.25000000 0.12500000 0.87500000 1 - Si Si16 1 0.62500000 0.37500000 0.25000000 1 - Si Si17 1 0.12500000 0.87500000 0.25000000 1 - Si Si18 1 0.75000000 0.37500000 0.62500000 1 - Si Si19 1 0.87500000 0.25000000 0.12500000 1 - W W20 1 0.87500000 0.75000000 0.62500000 1 - W W21 1 0.87500000 0.62500000 0.25000000 1 - W W22 1 0.62500000 0.87500000 0.75000000 1 - W W23 1 0.25000000 0.87500000 0.62500000 1 - W W24 1 0.75000000 0.62500000 0.87500000 1 - W W25 1 0.62500000 0.25000000 0.87500000 1 - W W26 1 0.12500000 0.25000000 0.37500000 1 - W W27 1 0.12500000 0.37500000 0.75000000 1 - W W28 1 0.37500000 0.12500000 0.25000000 1 - W W29 1 0.75000000 0.12500000 0.37500000 1 - W W30 1 0.25000000 0.37500000 0.12500000 1 - W W31 1 0.37500000 0.75000000 0.12500000 1 - O O32 1 0.58339000 0.88018600 0.37170300 1 - O O33 1 0.37170300 0.58339000 0.88018600 1 - O O34 1 0.28831300 0.29679600 0.91661000 1 - O O35 1 0.49151700 0.61981300 0.20320400 1 - O O36 1 0.29679600 0.88018600 0.00848300 1 - O O37 1 0.12829700 0.00848300 0.21168700 1 - O O38 1 0.37170300 0.28831300 0.49151700 1 - O O39 1 0.88018600 0.37170300 0.58339000 1 - O O40 1 0.20320400 0.21168700 0.58339000 1 - O O41 1 0.49151700 0.37170300 0.28831300 1 - O O42 1 0.88018600 0.00848300 0.29679600 1 - O O43 1 0.61981400 0.91661000 0.12829700 1 - O O44 1 0.91661000 0.12829700 0.61981400 1 - O O45 1 0.28831300 0.49151700 0.37170300 1 - O O46 1 0.58339000 0.20320400 0.21168700 1 - O O47 1 0.21168700 0.58339000 0.20320400 1 - O O48 1 0.00848300 0.29679600 0.88018700 1 - O O49 1 0.91661000 0.28831300 0.29679600 1 - O O50 1 0.00848300 0.21168700 0.12829700 1 - O O51 1 0.79679600 0.78831300 0.41661000 1 - O O52 1 0.29679600 0.91661000 0.28831300 1 - O O53 1 0.61981400 0.20320400 0.49151700 1 - O O54 1 0.21168700 0.12829700 0.00848300 1 - O O55 1 0.12829700 0.61981300 0.91661000 1 - O O56 1 0.41661000 0.11981300 0.62829700 1 - O O57 1 0.62829700 0.41661000 0.11981400 1 - O O58 1 0.71168700 0.70320400 0.08339000 1 - O O59 1 0.50848300 0.38018600 0.79679600 1 - O O60 1 0.70320400 0.11981300 0.99151700 1 - O O61 1 0.87170300 0.99151700 0.78831300 1 - O O62 1 0.62829700 0.71168700 0.50848300 1 - O O63 1 0.11981400 0.62829700 0.41661000 1 - O O64 1 0.87170300 0.38018600 0.08339000 1 - O O65 1 0.78831300 0.87170300 0.99151700 1 - O O66 1 0.38018600 0.79679600 0.50848300 1 - O O67 1 0.70320400 0.08339000 0.71168700 1 - O O68 1 0.79679600 0.50848300 0.38018600 1 - O O69 1 0.99151700 0.78831300 0.87170300 1 - O O70 1 0.08339000 0.71168700 0.70320400 1 - O O71 1 0.99151700 0.70320400 0.11981400 1 - O O72 1 0.78831300 0.41661000 0.79679600 1 - O O73 1 0.41661000 0.79679600 0.78831300 1 - O O74 1 0.71168700 0.50848300 0.62829700 1 - O O75 1 0.08339000 0.87170300 0.38018600 1 - O O76 1 0.38018600 0.08339000 0.87170300 1 - O O77 1 0.11981400 0.99151700 0.70320400 1 - O O78 1 0.50848300 0.62829700 0.71168700 1 - O O79 1 0.20320400 0.49151700 0.61981300 1 -" -Mg3Si3(WO6)2,mp-1157231,Ia-3d,[],0.17065653374999634,{'tags': []},"Full Formula (Mg12 Si12 W8 O48) -Reduced Formula: Mg3Si3(WO6)2 -abc : 10.475786 10.475786 10.475786 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0.002 - 1 Mg 0.75 0.125 0.375 0.002 - 2 Mg 0.375 0.125 0.25 0.002 - 3 Mg 0.125 0.375 0.75 0.002 - 4 Mg 0.25 0.875 0.625 0.002 - 5 Mg 0.125 0.25 0.375 0.002 - 6 Mg 0.625 0.25 0.875 0.002 - 7 Mg 0.75 0.625 0.875 0.002 - 8 Mg 0.875 0.75 0.625 0.002 - 9 Mg 0.875 0.625 0.25 0.002 - 10 Mg 0.625 0.875 0.75 0.002 - 11 Mg 0.375 0.75 0.125 0.002 - 12 Si 0.125 0.75 0.875 0.015 - 13 Si 0.875 0.25 0.125 0.015 - 14 Si 0.75 0.375 0.625 0.015 - 15 Si 0.125 0.875 0.25 0.015 - 16 Si 0.25 0.125 0.875 0.015 - 17 Si 0.375 0.625 0.75 0.015 - 18 Si 0.375 0.25 0.625 0.015 - 19 Si 0.875 0.125 0.75 0.015 - 20 Si 0.625 0.375 0.25 0.015 - 21 Si 0.75 0.875 0.125 0.015 - 22 Si 0.25 0.625 0.375 0.015 - 23 Si 0.625 0.75 0.375 0.015 - 24 W 0.5 0 0 2.749 - 25 W 0.5 0.5 0 2.749 - 26 W 0 0.5 0.5 2.749 - 27 W 0 0 0.5 2.749 - 28 W 0.5 0.5 0.5 2.749 - 29 W 0 0.5 0 2.749 - 30 W 0.5 0 0.5 2.749 - 31 W 0 0 0 2.749 - 32 O 0.59417 0.894752 0.372303 0.016 - 33 O 0.372303 0.59417 0.894752 0.016 - 34 O 0.278133 0.300582 0.90583 0.016 - 35 O 0.477551 0.605248 0.199418 0.016 - 36 O 0.300582 0.894752 0.022449 0.016 - 37 O 0.127697 0.022449 0.221867 0.016 - 38 O 0.372303 0.278133 0.477551 0.016 - 39 O 0.894752 0.372303 0.59417 0.016 - 40 O 0.199418 0.221867 0.59417 0.016 - 41 O 0.477551 0.372303 0.278133 0.016 - 42 O 0.894752 0.022449 0.300582 0.016 - 43 O 0.605248 0.90583 0.127697 0.016 - 44 O 0.90583 0.127697 0.605248 0.016 - 45 O 0.278133 0.477551 0.372303 0.016 - 46 O 0.59417 0.199418 0.221867 0.016 - 47 O 0.221867 0.59417 0.199418 0.016 - 48 O 0.022449 0.300582 0.894752 0.016 - 49 O 0.90583 0.278133 0.300582 0.016 - 50 O 0.022449 0.221867 0.127697 0.016 - 51 O 0.800582 0.778133 0.40583 0.016 - 52 O 0.199418 0.477551 0.605248 0.016 - 53 O 0.605248 0.199418 0.477551 0.016 - 54 O 0.221867 0.127697 0.022449 0.016 - 55 O 0.127697 0.605248 0.90583 0.016 - 56 O 0.40583 0.105248 0.627697 0.016 - 57 O 0.627697 0.40583 0.105248 0.016 - 58 O 0.721867 0.699418 0.09417 0.016 - 59 O 0.522449 0.394752 0.800582 0.016 - 60 O 0.699418 0.105248 0.977551 0.016 - 61 O 0.872303 0.977551 0.778133 0.016 - 62 O 0.627697 0.721867 0.522449 0.016 - 63 O 0.105248 0.627697 0.40583 0.016 - 64 O 0.872303 0.394752 0.09417 0.016 - 65 O 0.778133 0.872303 0.977551 0.016 - 66 O 0.394752 0.800582 0.522449 0.016 - 67 O 0.699418 0.09417 0.721867 0.016 - 68 O 0.800582 0.522449 0.394752 0.016 - 69 O 0.977551 0.778133 0.872303 0.016 - 70 O 0.09417 0.721867 0.699418 0.016 - 71 O 0.977551 0.699418 0.105248 0.016 - 72 O 0.778133 0.40583 0.800582 0.016 - 73 O 0.40583 0.800582 0.778133 0.016 - 74 O 0.721867 0.522449 0.627697 0.016 - 75 O 0.09417 0.872303 0.394752 0.016 - 76 O 0.394752 0.09417 0.872303 0.016 - 77 O 0.105248 0.977551 0.699418 0.016 - 78 O 0.522449 0.627697 0.721867 0.016 - 79 O 0.300582 0.90583 0.278133 0.016","# generated using pymatgen -data_Mg3Si3(WO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.47578623 -_cell_length_b 10.47578623 -_cell_length_c 10.47578623 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Si3(WO6)2 -_chemical_formula_sum 'Mg12 Si12 W8 O48' -_cell_volume 884.98924326 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - W W24 1 0.50000000 0.00000000 0.00000000 1 - W W25 1 0.50000000 0.50000000 0.00000000 1 - W W26 1 0.00000000 0.50000000 0.50000000 1 - W W27 1 0.00000000 0.00000000 0.50000000 1 - W W28 1 0.50000000 0.50000000 0.50000000 1 - W W29 1 0.00000000 0.50000000 0.00000000 1 - W W30 1 0.50000000 0.00000000 0.50000000 1 - W W31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59417000 0.89475200 0.37230300 1 - O O33 1 0.37230300 0.59417000 0.89475200 1 - O O34 1 0.27813300 0.30058200 0.90583000 1 - O O35 1 0.47755100 0.60524800 0.19941800 1 - O O36 1 0.30058200 0.89475200 0.02244900 1 - O O37 1 0.12769700 0.02244900 0.22186700 1 - O O38 1 0.37230300 0.27813300 0.47755100 1 - O O39 1 0.89475200 0.37230300 0.59417000 1 - O O40 1 0.19941800 0.22186700 0.59417000 1 - O O41 1 0.47755100 0.37230300 0.27813300 1 - O O42 1 0.89475200 0.02244900 0.30058200 1 - O O43 1 0.60524800 0.90583000 0.12769700 1 - O O44 1 0.90583000 0.12769700 0.60524800 1 - O O45 1 0.27813300 0.47755100 0.37230300 1 - O O46 1 0.59417000 0.19941800 0.22186700 1 - O O47 1 0.22186700 0.59417000 0.19941800 1 - O O48 1 0.02244900 0.30058200 0.89475200 1 - O O49 1 0.90583000 0.27813300 0.30058200 1 - O O50 1 0.02244900 0.22186700 0.12769700 1 - O O51 1 0.80058200 0.77813300 0.40583000 1 - O O52 1 0.19941800 0.47755100 0.60524800 1 - O O53 1 0.60524800 0.19941800 0.47755100 1 - O O54 1 0.22186700 0.12769700 0.02244900 1 - O O55 1 0.12769700 0.60524800 0.90583000 1 - O O56 1 0.40583000 0.10524800 0.62769700 1 - O O57 1 0.62769700 0.40583000 0.10524800 1 - O O58 1 0.72186700 0.69941800 0.09417000 1 - O O59 1 0.52244900 0.39475200 0.80058200 1 - O O60 1 0.69941800 0.10524800 0.97755100 1 - O O61 1 0.87230300 0.97755100 0.77813300 1 - O O62 1 0.62769700 0.72186700 0.52244900 1 - O O63 1 0.10524800 0.62769700 0.40583000 1 - O O64 1 0.87230300 0.39475200 0.09417000 1 - O O65 1 0.77813300 0.87230300 0.97755100 1 - O O66 1 0.39475200 0.80058200 0.52244900 1 - O O67 1 0.69941800 0.09417000 0.72186700 1 - O O68 1 0.80058200 0.52244900 0.39475200 1 - O O69 1 0.97755100 0.77813300 0.87230300 1 - O O70 1 0.09417000 0.72186700 0.69941800 1 - O O71 1 0.97755100 0.69941800 0.10524800 1 - O O72 1 0.77813300 0.40583000 0.80058200 1 - O O73 1 0.40583000 0.80058200 0.77813300 1 - O O74 1 0.72186700 0.52244900 0.62769700 1 - O O75 1 0.09417000 0.87230300 0.39475200 1 - O O76 1 0.39475200 0.09417000 0.87230300 1 - O O77 1 0.10524800 0.97755100 0.69941800 1 - O O78 1 0.52244900 0.62769700 0.72186700 1 - O O79 1 0.30058200 0.90583000 0.27813300 1 -" -Y2Cr3(SiO4)3,mp-1157313,Ia-3d,[],0.19841963566666543,{'tags': []},"Full Formula (Y8 Cr12 Si12 O48) -Reduced Formula: Y2Cr3(SiO4)3 -abc : 10.799614 10.799614 10.799614 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0 -0.003 - 1 Y 0.5 0 0 -0.003 - 2 Y 0.5 0.5 0 -0.003 - 3 Y 0 0.5 0.5 -0.003 - 4 Y 0 0 0.5 -0.003 - 5 Y 0.5 0.5 0.5 -0.003 - 6 Y 0 0.5 0 -0.003 - 7 Y 0.5 0 0.5 -0.003 - 8 Cr 0.875 0.75 0.625 3.82 - 9 Cr 0.875 0.625 0.25 3.82 - 10 Cr 0.625 0.875 0.75 3.82 - 11 Cr 0.25 0.875 0.625 3.82 - 12 Cr 0.75 0.625 0.875 3.82 - 13 Cr 0.625 0.25 0.875 3.82 - 14 Cr 0.125 0.25 0.375 3.82 - 15 Cr 0.125 0.375 0.75 3.82 - 16 Cr 0.375 0.125 0.25 3.82 - 17 Cr 0.75 0.125 0.375 3.82 - 18 Cr 0.25 0.375 0.125 3.82 - 19 Cr 0.375 0.75 0.125 3.82 - 20 Si 0.125 0.75 0.875 0.009 - 21 Si 0.75 0.875 0.125 0.009 - 22 Si 0.25 0.625 0.375 0.009 - 23 Si 0.625 0.75 0.375 0.009 - 24 Si 0.875 0.125 0.75 0.009 - 25 Si 0.375 0.25 0.625 0.009 - 26 Si 0.375 0.625 0.75 0.009 - 27 Si 0.25 0.125 0.875 0.009 - 28 Si 0.625 0.375 0.25 0.009 - 29 Si 0.125 0.875 0.25 0.009 - 30 Si 0.75 0.375 0.625 0.009 - 31 Si 0.875 0.25 0.125 0.009 - 32 O 0.591336 0.888054 0.370085 -0.001 - 33 O 0.370085 0.591336 0.888054 -0.001 - 34 O 0.278749 0.296719 0.908664 -0.001 - 35 O 0.48203 0.611946 0.203281 -0.001 - 36 O 0.296719 0.888054 0.01797 -0.001 - 37 O 0.129915 0.01797 0.221251 -0.001 - 38 O 0.370085 0.278749 0.48203 -0.001 - 39 O 0.888054 0.370085 0.591336 -0.001 - 40 O 0.203281 0.221251 0.591336 -0.001 - 41 O 0.48203 0.370085 0.278749 -0.001 - 42 O 0.888054 0.01797 0.296719 -0.001 - 43 O 0.611946 0.908664 0.129915 -0.001 - 44 O 0.908664 0.129915 0.611946 -0.001 - 45 O 0.278749 0.48203 0.370085 -0.001 - 46 O 0.591336 0.203281 0.221251 -0.001 - 47 O 0.221251 0.591336 0.203281 -0.001 - 48 O 0.01797 0.296719 0.888054 -0.001 - 49 O 0.908664 0.278749 0.296719 -0.001 - 50 O 0.01797 0.221251 0.129915 -0.001 - 51 O 0.796719 0.778749 0.408664 -0.001 - 52 O 0.296719 0.908664 0.278749 -0.001 - 53 O 0.611946 0.203281 0.48203 -0.001 - 54 O 0.221251 0.129915 0.01797 -0.001 - 55 O 0.129915 0.611946 0.908664 -0.001 - 56 O 0.408664 0.111946 0.629915 -0.001 - 57 O 0.629915 0.408664 0.111946 -0.001 - 58 O 0.721251 0.703281 0.091336 -0.001 - 59 O 0.51797 0.388054 0.796719 -0.001 - 60 O 0.703281 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-_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Cr3(SiO4)3 -_chemical_formula_sum 'Y8 Cr12 Si12 O48' -_cell_volume 969.62275385 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.00000000 1 - Y Y1 1 0.50000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.50000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.50000000 1 - Y Y4 1 0.00000000 0.00000000 0.50000000 1 - Y Y5 1 0.50000000 0.50000000 0.50000000 1 - Y Y6 1 0.00000000 0.50000000 0.00000000 1 - Y Y7 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr8 1 0.87500000 0.75000000 0.62500000 1 - Cr Cr9 1 0.87500000 0.62500000 0.25000000 1 - Cr Cr10 1 0.62500000 0.87500000 0.75000000 1 - Cr Cr11 1 0.25000000 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0.37008500 1 - O O33 1 0.37008500 0.59133600 0.88805400 1 - O O34 1 0.27874900 0.29671900 0.90866400 1 - O O35 1 0.48203000 0.61194600 0.20328100 1 - O O36 1 0.29671900 0.88805400 0.01797000 1 - O O37 1 0.12991500 0.01797000 0.22125100 1 - O O38 1 0.37008500 0.27874900 0.48203000 1 - O O39 1 0.88805400 0.37008500 0.59133600 1 - O O40 1 0.20328100 0.22125100 0.59133600 1 - O O41 1 0.48203000 0.37008500 0.27874900 1 - O O42 1 0.88805400 0.01797000 0.29671900 1 - O O43 1 0.61194600 0.90866400 0.12991500 1 - O O44 1 0.90866400 0.12991500 0.61194600 1 - O O45 1 0.27874900 0.48203000 0.37008500 1 - O O46 1 0.59133600 0.20328100 0.22125100 1 - O O47 1 0.22125100 0.59133600 0.20328100 1 - O O48 1 0.01797000 0.29671900 0.88805400 1 - O O49 1 0.90866400 0.27874900 0.29671900 1 - O O50 1 0.01797000 0.22125100 0.12991500 1 - O O51 1 0.79671900 0.77874900 0.40866400 1 - O O52 1 0.29671900 0.90866400 0.27874900 1 - O O53 1 0.61194600 0.20328100 0.48203000 1 - O O54 1 0.22125100 0.12991500 0.01797000 1 - O O55 1 0.12991500 0.61194600 0.90866400 1 - O O56 1 0.40866400 0.11194600 0.62991500 1 - O O57 1 0.62991500 0.40866400 0.11194600 1 - O O58 1 0.72125100 0.70328100 0.09133600 1 - O O59 1 0.51797000 0.38805400 0.79671900 1 - O O60 1 0.70328100 0.11194600 0.98203000 1 - O O61 1 0.87008500 0.98203000 0.77874900 1 - O O62 1 0.62991500 0.72125100 0.51797000 1 - O O63 1 0.11194600 0.62991500 0.40866400 1 - O O64 1 0.87008500 0.38805400 0.09133600 1 - O O65 1 0.77874900 0.87008500 0.98203000 1 - O O66 1 0.38805400 0.79671900 0.51797000 1 - O O67 1 0.70328100 0.09133600 0.72125100 1 - O O68 1 0.79671900 0.51797000 0.38805400 1 - O O69 1 0.98203000 0.77874900 0.87008500 1 - O O70 1 0.09133600 0.72125100 0.70328100 1 - O O71 1 0.98203000 0.70328100 0.11194600 1 - O O72 1 0.77874900 0.40866400 0.79671900 1 - O O73 1 0.40866400 0.79671900 0.77874900 1 - O O74 1 0.72125100 0.51797000 0.62991500 1 - O O75 1 0.09133600 0.87008500 0.38805400 1 - O O76 1 0.38805400 0.09133600 0.87008500 1 - O O77 1 0.11194600 0.98203000 0.70328100 1 - O O78 1 0.51797000 0.62991500 0.72125100 1 - O O79 1 0.20328100 0.48203000 0.61194600 1 -" -Y2V3(SiO4)3,mp-1157332,Ia-3d,[],0.19465188461553318,{'tags': []},"Full Formula (Y8 V12 Si12 O48) -Reduced Formula: Y2V3(SiO4)3 -abc : 10.788905 10.788905 10.788905 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0.5 0.001 - 1 Y 0 0 0 0.001 - 2 Y 0.5 0 0 0.001 - 3 Y 0 0.5 0 0.001 - 4 Y 0.5 0.5 0 0.001 - 5 Y 0 0.5 0.5 0.001 - 6 Y 0.5 0 0.5 0.001 - 7 Y 0.5 0.5 0.5 0.001 - 8 V 0.875 0.625 0.25 2.736 - 9 V 0.625 0.25 0.875 2.736 - 10 V 0.875 0.75 0.625 2.736 - 11 V 0.75 0.625 0.875 2.736 - 12 V 0.25 0.875 0.625 2.736 - 13 V 0.625 0.875 0.75 2.736 - 14 V 0.125 0.375 0.75 2.736 - 15 V 0.375 0.75 0.125 2.736 - 16 V 0.125 0.25 0.375 2.736 - 17 V 0.25 0.375 0.125 2.736 - 18 V 0.75 0.125 0.375 2.736 - 19 V 0.375 0.125 0.25 2.736 - 20 Si 0.125 0.875 0.25 0.011 - 21 Si 0.25 0.125 0.875 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0.018558 0.295581 0.890078 0.002 - 50 O 0.905503 0.12848 0.609922 0.002 - 51 O 0.62848 0.405503 0.109922 0.002 - 52 O 0.37152 0.277022 0.481442 0.002 - 53 O 0.277022 0.481442 0.37152 0.002 - 54 O 0.890078 0.018558 0.295581 0.002 - 55 O 0.295581 0.905503 0.277022 0.002 - 56 O 0.518558 0.62848 0.722978 0.002 - 57 O 0.704419 0.109922 0.981442 0.002 - 58 O 0.390078 0.094497 0.87152 0.002 - 59 O 0.405503 0.795581 0.777022 0.002 - 60 O 0.87152 0.981442 0.777022 0.002 - 61 O 0.795581 0.777022 0.405503 0.002 - 62 O 0.795581 0.518558 0.390078 0.002 - 63 O 0.777022 0.405503 0.795581 0.002 - 64 O 0.704419 0.094497 0.722978 0.002 - 65 O 0.109922 0.981442 0.704419 0.002 - 66 O 0.722978 0.518558 0.62848 0.002 - 67 O 0.62848 0.722978 0.518558 0.002 - 68 O 0.87152 0.390078 0.094497 0.002 - 69 O 0.094497 0.87152 0.390078 0.002 - 70 O 0.981442 0.704419 0.109922 0.002 - 71 O 0.405503 0.109922 0.62848 0.002 - 72 O 0.390078 0.795581 0.518558 0.002 - 73 O 0.981442 0.777022 0.87152 0.002 - 74 O 0.109922 0.62848 0.405503 0.002 - 75 O 0.518558 0.390078 0.795581 0.002 - 76 O 0.777022 0.87152 0.981442 0.002 - 77 O 0.722978 0.704419 0.094497 0.002 - 78 O 0.094497 0.722978 0.704419 0.002 - 79 O 0.12848 0.609922 0.905503 0.002","# generated using pymatgen -data_Y2V3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.78890464 -_cell_length_b 10.78890464 -_cell_length_c 10.78890464 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2V3(SiO4)3 -_chemical_formula_sum 'Y8 V12 Si12 O48' -_cell_volume 966.74107907 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.50000000 1 - Y Y1 1 0.00000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.00000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.00000000 1 - Y Y4 1 0.50000000 0.50000000 0.00000000 1 - Y Y5 1 0.00000000 0.50000000 0.50000000 1 - Y Y6 1 0.50000000 0.00000000 0.50000000 1 - Y Y7 1 0.50000000 0.50000000 0.50000000 1 - V V8 1 0.87500000 0.62500000 0.25000000 1 - V V9 1 0.62500000 0.25000000 0.87500000 1 - V V10 1 0.87500000 0.75000000 0.62500000 1 - V V11 1 0.75000000 0.62500000 0.87500000 1 - V V12 1 0.25000000 0.87500000 0.62500000 1 - V V13 1 0.62500000 0.87500000 0.75000000 1 - V V14 1 0.12500000 0.37500000 0.75000000 1 - V V15 1 0.37500000 0.75000000 0.12500000 1 - V V16 1 0.12500000 0.25000000 0.37500000 1 - V V17 1 0.25000000 0.37500000 0.12500000 1 - V V18 1 0.75000000 0.12500000 0.37500000 1 - V V19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.25000000 0.12500000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.37500000 0.25000000 0.62500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.48144200 0.37152000 0.27702200 1 - O O33 1 0.29558100 0.89007800 0.01855800 1 - O O34 1 0.60992200 0.90550300 0.12848000 1 - O O35 1 0.59449700 0.20441900 0.22297800 1 - O O36 1 0.12848000 0.01855800 0.22297800 1 - O O37 1 0.20441900 0.22297800 0.59449700 1 - O O38 1 0.20441900 0.48144200 0.60992200 1 - O O39 1 0.22297800 0.59449700 0.20441900 1 - O O40 1 0.37152000 0.59449700 0.89007800 1 - O O41 1 0.90550300 0.27702200 0.29558100 1 - O O42 1 0.27702200 0.29558100 0.90550300 1 - O O43 1 0.22297800 0.12848000 0.01855800 1 - O O44 1 0.48144200 0.60992200 0.20441900 1 - O O45 1 0.89007800 0.37152000 0.59449700 1 - O O46 1 0.01855800 0.22297800 0.12848000 1 - O O47 1 0.60992200 0.20441900 0.48144200 1 - O O48 1 0.59449700 0.89007800 0.37152000 1 - O O49 1 0.01855800 0.29558100 0.89007800 1 - O O50 1 0.90550300 0.12848000 0.60992200 1 - O O51 1 0.62848000 0.40550300 0.10992200 1 - O O52 1 0.37152000 0.27702200 0.48144200 1 - O O53 1 0.27702200 0.48144200 0.37152000 1 - O O54 1 0.89007800 0.01855800 0.29558100 1 - O O55 1 0.29558100 0.90550300 0.27702200 1 - O O56 1 0.51855800 0.62848000 0.72297800 1 - O O57 1 0.70441900 0.10992200 0.98144200 1 - O O58 1 0.39007800 0.09449700 0.87152000 1 - O O59 1 0.40550300 0.79558100 0.77702200 1 - O O60 1 0.87152000 0.98144200 0.77702200 1 - O O61 1 0.79558100 0.77702200 0.40550300 1 - O O62 1 0.79558100 0.51855800 0.39007800 1 - O O63 1 0.77702200 0.40550300 0.79558100 1 - O O64 1 0.70441900 0.09449700 0.72297800 1 - O O65 1 0.10992200 0.98144200 0.70441900 1 - O O66 1 0.72297800 0.51855800 0.62848000 1 - O O67 1 0.62848000 0.72297800 0.51855800 1 - O O68 1 0.87152000 0.39007800 0.09449700 1 - O O69 1 0.09449700 0.87152000 0.39007800 1 - O O70 1 0.98144200 0.70441900 0.10992200 1 - O O71 1 0.40550300 0.10992200 0.62848000 1 - O O72 1 0.39007800 0.79558100 0.51855800 1 - O O73 1 0.98144200 0.77702200 0.87152000 1 - O O74 1 0.10992200 0.62848000 0.40550300 1 - O O75 1 0.51855800 0.39007800 0.79558100 1 - O O76 1 0.77702200 0.87152000 0.98144200 1 - O O77 1 0.72297800 0.70441900 0.09449700 1 - O O78 1 0.09449700 0.72297800 0.70441900 1 - O O79 1 0.12848000 0.60992200 0.90550300 1 -" -Y2Co3(SiO4)3,mp-1157336,Ia-3d,[],0.1867800404166804,{'tags': []},"Full Formula (Y8 Co12 Si12 O48) -Reduced Formula: Y2Co3(SiO4)3 -abc : 10.627684 10.627684 10.627684 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0 -0.003 - 1 Y 0.5 0 0 -0.003 - 2 Y 0.5 0.5 0 -0.003 - 3 Y 0 0.5 0.5 -0.003 - 4 Y 0 0 0.5 -0.003 - 5 Y 0.5 0.5 0.5 -0.003 - 6 Y 0 0.5 0 -0.003 - 7 Y 0.5 0 0.5 -0.003 - 8 Co 0.875 0.75 0.625 2.75 - 9 Co 0.875 0.625 0.25 2.75 - 10 Co 0.625 0.875 0.75 2.75 - 11 Co 0.25 0.875 0.625 2.75 - 12 Co 0.75 0.625 0.875 2.749 - 13 Co 0.625 0.25 0.875 2.75 - 14 Co 0.125 0.25 0.375 2.75 - 15 Co 0.125 0.375 0.75 2.75 - 16 Co 0.375 0.125 0.25 2.75 - 17 Co 0.75 0.125 0.375 2.75 - 18 Co 0.25 0.375 0.125 2.749 - 19 Co 0.375 0.75 0.125 2.75 - 20 Si 0.125 0.75 0.875 0.005 - 21 Si 0.75 0.875 0.125 0.005 - 22 Si 0.25 0.625 0.375 0.005 - 23 Si 0.625 0.75 0.375 0.005 - 24 Si 0.875 0.125 0.75 0.005 - 25 Si 0.375 0.25 0.625 0.005 - 26 Si 0.375 0.625 0.75 0.005 - 27 Si 0.25 0.125 0.875 0.005 - 28 Si 0.625 0.375 0.25 0.005 - 29 Si 0.125 0.875 0.25 0.005 - 30 Si 0.75 0.375 0.625 0.005 - 31 Si 0.875 0.25 0.125 0.005 - 32 O 0.597659 0.893484 0.370389 0.048 - 33 O 0.370389 0.597659 0.893484 0.048 - 34 O 0.27273 0.295825 0.902341 0.048 - 35 O 0.476905 0.606516 0.204175 0.048 - 36 O 0.295825 0.893484 0.023095 0.048 - 37 O 0.129611 0.023095 0.22727 0.048 - 38 O 0.370389 0.27273 0.476905 0.048 - 39 O 0.893484 0.370389 0.597659 0.048 - 40 O 0.204175 0.22727 0.597659 0.048 - 41 O 0.476905 0.370389 0.27273 0.048 - 42 O 0.893484 0.023095 0.295825 0.048 - 43 O 0.606516 0.902341 0.129611 0.048 - 44 O 0.902341 0.129611 0.606516 0.048 - 45 O 0.27273 0.476905 0.370389 0.048 - 46 O 0.597659 0.204175 0.22727 0.048 - 47 O 0.22727 0.597659 0.204175 0.048 - 48 O 0.023095 0.295825 0.893484 0.048 - 49 O 0.902341 0.27273 0.295825 0.048 - 50 O 0.023095 0.22727 0.129611 0.048 - 51 O 0.795825 0.77273 0.402341 0.048 - 52 O 0.295825 0.902341 0.27273 0.048 - 53 O 0.606516 0.204175 0.476905 0.048 - 54 O 0.22727 0.129611 0.023095 0.048 - 55 O 0.129611 0.606516 0.902341 0.048 - 56 O 0.402341 0.106516 0.629611 0.048 - 57 O 0.629611 0.402341 0.106516 0.048 - 58 O 0.72727 0.704175 0.097659 0.048 - 59 O 0.523095 0.393484 0.795825 0.048 - 60 O 0.704175 0.106516 0.976905 0.048 - 61 O 0.870389 0.976905 0.77273 0.048 - 62 O 0.629611 0.72727 0.523095 0.048 - 63 O 0.106516 0.629611 0.402341 0.048 - 64 O 0.870389 0.393484 0.097659 0.048 - 65 O 0.77273 0.870389 0.976905 0.048 - 66 O 0.393484 0.795825 0.523095 0.048 - 67 O 0.704175 0.097659 0.72727 0.048 - 68 O 0.795825 0.523095 0.393484 0.048 - 69 O 0.976905 0.77273 0.870389 0.048 - 70 O 0.097659 0.72727 0.704175 0.048 - 71 O 0.976905 0.704175 0.106516 0.048 - 72 O 0.77273 0.402341 0.795825 0.048 - 73 O 0.402341 0.795825 0.77273 0.048 - 74 O 0.72727 0.523095 0.629611 0.048 - 75 O 0.097659 0.870389 0.393484 0.048 - 76 O 0.393484 0.097659 0.870389 0.048 - 77 O 0.106516 0.976905 0.704175 0.048 - 78 O 0.523095 0.629611 0.72727 0.048 - 79 O 0.204175 0.476905 0.606516 0.048","# generated using pymatgen -data_Y2Co3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.62768362 -_cell_length_b 10.62768362 -_cell_length_c 10.62768362 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Co3(SiO4)3 -_chemical_formula_sum 'Y8 Co12 Si12 O48' -_cell_volume 924.04678680 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.00000000 1 - Y Y1 1 0.50000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.50000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.50000000 1 - Y Y4 1 0.00000000 0.00000000 0.50000000 1 - Y Y5 1 0.50000000 0.50000000 0.50000000 1 - Y Y6 1 0.00000000 0.50000000 0.00000000 1 - Y Y7 1 0.50000000 0.00000000 0.50000000 1 - Co Co8 1 0.87500000 0.75000000 0.62500000 1 - Co Co9 1 0.87500000 0.62500000 0.25000000 1 - Co Co10 1 0.62500000 0.87500000 0.75000000 1 - Co Co11 1 0.25000000 0.87500000 0.62500000 1 - Co Co12 1 0.75000000 0.62500000 0.87500000 1 - Co Co13 1 0.62500000 0.25000000 0.87500000 1 - Co Co14 1 0.12500000 0.25000000 0.37500000 1 - Co Co15 1 0.12500000 0.37500000 0.75000000 1 - Co Co16 1 0.37500000 0.12500000 0.25000000 1 - Co Co17 1 0.75000000 0.12500000 0.37500000 1 - Co Co18 1 0.25000000 0.37500000 0.12500000 1 - Co Co19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.87500000 0.12500000 0.75000000 1 - Si Si25 1 0.37500000 0.25000000 0.62500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.25000000 0.12500000 0.87500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.12500000 0.87500000 0.25000000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.87500000 0.25000000 0.12500000 1 - O O32 1 0.59765900 0.89348400 0.37038900 1 - O O33 1 0.37038900 0.59765900 0.89348400 1 - O O34 1 0.27273000 0.29582500 0.90234100 1 - O O35 1 0.47690500 0.60651600 0.20417500 1 - O O36 1 0.29582500 0.89348400 0.02309500 1 - O O37 1 0.12961100 0.02309500 0.22727000 1 - O O38 1 0.37038900 0.27273000 0.47690500 1 - O O39 1 0.89348400 0.37038900 0.59765900 1 - O O40 1 0.20417500 0.22727000 0.59765900 1 - O O41 1 0.47690500 0.37038900 0.27273000 1 - O O42 1 0.89348400 0.02309500 0.29582500 1 - O O43 1 0.60651600 0.90234100 0.12961100 1 - O O44 1 0.90234100 0.12961100 0.60651600 1 - O O45 1 0.27273000 0.47690500 0.37038900 1 - O O46 1 0.59765900 0.20417500 0.22727000 1 - O O47 1 0.22727000 0.59765900 0.20417500 1 - O O48 1 0.02309500 0.29582500 0.89348400 1 - O O49 1 0.90234100 0.27273000 0.29582500 1 - O O50 1 0.02309500 0.22727000 0.12961100 1 - O O51 1 0.79582500 0.77273000 0.40234100 1 - O O52 1 0.29582500 0.90234100 0.27273000 1 - O O53 1 0.60651600 0.20417500 0.47690500 1 - O O54 1 0.22727000 0.12961100 0.02309500 1 - O O55 1 0.12961100 0.60651600 0.90234100 1 - O O56 1 0.40234100 0.10651600 0.62961100 1 - O O57 1 0.62961100 0.40234100 0.10651600 1 - O O58 1 0.72727000 0.70417500 0.09765900 1 - O O59 1 0.52309500 0.39348400 0.79582500 1 - O O60 1 0.70417500 0.10651600 0.97690500 1 - O O61 1 0.87038900 0.97690500 0.77273000 1 - O O62 1 0.62961100 0.72727000 0.52309500 1 - O O63 1 0.10651600 0.62961100 0.40234100 1 - O O64 1 0.87038900 0.39348400 0.09765900 1 - O O65 1 0.77273000 0.87038900 0.97690500 1 - O O66 1 0.39348400 0.79582500 0.52309500 1 - O O67 1 0.70417500 0.09765900 0.72727000 1 - O O68 1 0.79582500 0.52309500 0.39348400 1 - O O69 1 0.97690500 0.77273000 0.87038900 1 - O O70 1 0.09765900 0.72727000 0.70417500 1 - O O71 1 0.97690500 0.70417500 0.10651600 1 - O O72 1 0.77273000 0.40234100 0.79582500 1 - O O73 1 0.40234100 0.79582500 0.77273000 1 - O O74 1 0.72727000 0.52309500 0.62961100 1 - O O75 1 0.09765900 0.87038900 0.39348400 1 - O O76 1 0.39348400 0.09765900 0.87038900 1 - O O77 1 0.10651600 0.97690500 0.70417500 1 - O O78 1 0.52309500 0.62961100 0.72727000 1 - O O79 1 0.20417500 0.47690500 0.60651600 1 -" -Al2Si3(NiO4)3,mp-1157674,Ia-3d,[],0.10834304250000049,{'tags': []},"Full Formula (Al8 Si12 Ni12 O48) -Reduced Formula: Al2Si3(NiO4)3 -abc : 10.036827 10.036827 10.036827 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0.5 -0 - 1 Al 0 0 0 -0 - 2 Al 0.5 0 0 -0 - 3 Al 0 0.5 0 -0 - 4 Al 0.5 0.5 0 -0 - 5 Al 0 0.5 0.5 -0 - 6 Al 0.5 0 0.5 -0 - 7 Al 0.5 0.5 0.5 -0 - 8 Si 0.125 0.875 0.25 0.001 - 9 Si 0.25 0.125 0.875 0.001 - 10 Si 0.75 0.375 0.625 0.001 - 11 Si 0.625 0.375 0.25 0.001 - 12 Si 0.625 0.75 0.375 0.001 - 13 Si 0.375 0.625 0.75 0.001 - 14 Si 0.125 0.75 0.875 0.001 - 15 Si 0.75 0.875 0.125 0.001 - 16 Si 0.875 0.25 0.125 0.001 - 17 Si 0.375 0.25 0.625 0.001 - 18 Si 0.25 0.625 0.375 0.001 - 19 Si 0.875 0.125 0.75 0.001 - 20 Ni 0.875 0.625 0.25 1.826 - 21 Ni 0.625 0.25 0.875 1.826 - 22 Ni 0.875 0.75 0.625 1.826 - 23 Ni 0.75 0.625 0.875 1.826 - 24 Ni 0.25 0.875 0.625 1.826 - 25 Ni 0.625 0.875 0.75 1.826 - 26 Ni 0.125 0.375 0.75 1.826 - 27 Ni 0.375 0.75 0.125 1.826 - 28 Ni 0.125 0.25 0.375 1.826 - 29 Ni 0.25 0.375 0.125 1.826 - 30 Ni 0.75 0.125 0.375 1.826 - 31 Ni 0.375 0.125 0.25 1.826 - 32 O 0.483791 0.378564 0.298301 0.033 - 33 O 0.31451 0.894773 0.016209 0.033 - 34 O 0.605227 0.919737 0.121436 0.033 - 35 O 0.580263 0.18549 0.201699 0.033 - 36 O 0.121436 0.016209 0.201699 0.033 - 37 O 0.18549 0.201699 0.580263 0.033 - 38 O 0.18549 0.483791 0.605227 0.033 - 39 O 0.201699 0.580263 0.18549 0.033 - 40 O 0.378564 0.580263 0.894773 0.033 - 41 O 0.919737 0.298301 0.31451 0.033 - 42 O 0.298301 0.31451 0.919737 0.033 - 43 O 0.201699 0.121436 0.016209 0.033 - 44 O 0.483791 0.605227 0.18549 0.033 - 45 O 0.894773 0.378564 0.580263 0.033 - 46 O 0.016209 0.201699 0.121436 0.033 - 47 O 0.605227 0.18549 0.483791 0.033 - 48 O 0.580263 0.894773 0.378564 0.033 - 49 O 0.016209 0.31451 0.894773 0.033 - 50 O 0.919737 0.121436 0.605227 0.033 - 51 O 0.621436 0.419737 0.105227 0.033 - 52 O 0.378564 0.298301 0.483791 0.033 - 53 O 0.298301 0.483791 0.378564 0.033 - 54 O 0.894773 0.016209 0.31451 0.033 - 55 O 0.31451 0.919737 0.298301 0.033 - 56 O 0.516209 0.621436 0.701699 0.033 - 57 O 0.68549 0.105227 0.983791 0.033 - 58 O 0.394773 0.080263 0.878564 0.033 - 59 O 0.419737 0.81451 0.798301 0.033 - 60 O 0.878564 0.983791 0.798301 0.033 - 61 O 0.81451 0.798301 0.419737 0.033 - 62 O 0.81451 0.516209 0.394773 0.033 - 63 O 0.798301 0.419737 0.81451 0.033 - 64 O 0.68549 0.080263 0.701699 0.033 - 65 O 0.105227 0.983791 0.68549 0.033 - 66 O 0.701699 0.516209 0.621436 0.033 - 67 O 0.621436 0.701699 0.516209 0.033 - 68 O 0.878564 0.394773 0.080263 0.033 - 69 O 0.080263 0.878564 0.394773 0.033 - 70 O 0.983791 0.68549 0.105227 0.033 - 71 O 0.419737 0.105227 0.621436 0.033 - 72 O 0.394773 0.81451 0.516209 0.033 - 73 O 0.983791 0.798301 0.878564 0.033 - 74 O 0.105227 0.621436 0.419737 0.033 - 75 O 0.516209 0.394773 0.81451 0.033 - 76 O 0.798301 0.878564 0.983791 0.033 - 77 O 0.701699 0.68549 0.080263 0.033 - 78 O 0.080263 0.701699 0.68549 0.033 - 79 O 0.121436 0.605227 0.919737 0.033","# generated using pymatgen -data_Al2Si3(NiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.03682740 -_cell_length_b 10.03682740 -_cell_length_c 10.03682740 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Si3(NiO4)3 -_chemical_formula_sum 'Al8 Si12 Ni12 O48' -_cell_volume 778.33664203 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.50000000 1 - Al Al1 1 0.00000000 0.00000000 0.00000000 1 - Al Al2 1 0.50000000 0.00000000 0.00000000 1 - Al Al3 1 0.00000000 0.50000000 0.00000000 1 - Al Al4 1 0.50000000 0.50000000 0.00000000 1 - Al Al5 1 0.00000000 0.50000000 0.50000000 1 - Al Al6 1 0.50000000 0.00000000 0.50000000 1 - Al Al7 1 0.50000000 0.50000000 0.50000000 1 - Si Si8 1 0.12500000 0.87500000 0.25000000 1 - Si Si9 1 0.25000000 0.12500000 0.87500000 1 - Si Si10 1 0.75000000 0.37500000 0.62500000 1 - Si Si11 1 0.62500000 0.37500000 0.25000000 1 - Si Si12 1 0.62500000 0.75000000 0.37500000 1 - Si Si13 1 0.37500000 0.62500000 0.75000000 1 - Si Si14 1 0.12500000 0.75000000 0.87500000 1 - Si Si15 1 0.75000000 0.87500000 0.12500000 1 - Si Si16 1 0.87500000 0.25000000 0.12500000 1 - Si Si17 1 0.37500000 0.25000000 0.62500000 1 - Si Si18 1 0.25000000 0.62500000 0.37500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Ni Ni20 1 0.87500000 0.62500000 0.25000000 1 - Ni Ni21 1 0.62500000 0.25000000 0.87500000 1 - Ni Ni22 1 0.87500000 0.75000000 0.62500000 1 - Ni Ni23 1 0.75000000 0.62500000 0.87500000 1 - Ni Ni24 1 0.25000000 0.87500000 0.62500000 1 - Ni Ni25 1 0.62500000 0.87500000 0.75000000 1 - Ni Ni26 1 0.12500000 0.37500000 0.75000000 1 - Ni Ni27 1 0.37500000 0.75000000 0.12500000 1 - Ni Ni28 1 0.12500000 0.25000000 0.37500000 1 - Ni Ni29 1 0.25000000 0.37500000 0.12500000 1 - Ni Ni30 1 0.75000000 0.12500000 0.37500000 1 - Ni Ni31 1 0.37500000 0.12500000 0.25000000 1 - O O32 1 0.48379100 0.37856400 0.29830100 1 - O O33 1 0.31451000 0.89477300 0.01620900 1 - O O34 1 0.60522700 0.91973700 0.12143600 1 - O O35 1 0.58026300 0.18549000 0.20169900 1 - O O36 1 0.12143600 0.01620900 0.20169900 1 - O O37 1 0.18549000 0.20169900 0.58026300 1 - O O38 1 0.18549000 0.48379100 0.60522700 1 - O O39 1 0.20169900 0.58026300 0.18549000 1 - O O40 1 0.37856400 0.58026300 0.89477300 1 - O O41 1 0.91973700 0.29830100 0.31451000 1 - O O42 1 0.29830100 0.31451000 0.91973700 1 - O O43 1 0.20169900 0.12143600 0.01620900 1 - O O44 1 0.48379100 0.60522700 0.18549000 1 - O O45 1 0.89477300 0.37856400 0.58026300 1 - O O46 1 0.01620900 0.20169900 0.12143600 1 - O O47 1 0.60522700 0.18549000 0.48379100 1 - O O48 1 0.58026300 0.89477300 0.37856400 1 - O O49 1 0.01620900 0.31451000 0.89477300 1 - O O50 1 0.91973700 0.12143600 0.60522700 1 - O O51 1 0.62143600 0.41973700 0.10522700 1 - O O52 1 0.37856400 0.29830100 0.48379100 1 - O O53 1 0.29830100 0.48379100 0.37856400 1 - O O54 1 0.89477300 0.01620900 0.31451000 1 - O O55 1 0.31451000 0.91973700 0.29830100 1 - O O56 1 0.51620900 0.62143600 0.70169900 1 - O O57 1 0.68549000 0.10522700 0.98379100 1 - O O58 1 0.39477300 0.08026300 0.87856400 1 - O O59 1 0.41973700 0.81451000 0.79830100 1 - O O60 1 0.87856400 0.98379100 0.79830100 1 - O O61 1 0.81451000 0.79830100 0.41973700 1 - O O62 1 0.81451000 0.51620900 0.39477300 1 - O O63 1 0.79830100 0.41973700 0.81451000 1 - O O64 1 0.68549000 0.08026300 0.70169900 1 - O O65 1 0.10522700 0.98379100 0.68549000 1 - O O66 1 0.70169900 0.51620900 0.62143600 1 - O O67 1 0.62143600 0.70169900 0.51620900 1 - O O68 1 0.87856400 0.39477300 0.08026300 1 - O O69 1 0.08026300 0.87856400 0.39477300 1 - O O70 1 0.98379100 0.68549000 0.10522700 1 - O O71 1 0.41973700 0.10522700 0.62143600 1 - O O72 1 0.39477300 0.81451000 0.51620900 1 - O O73 1 0.98379100 0.79830100 0.87856400 1 - O O74 1 0.10522700 0.62143600 0.41973700 1 - O O75 1 0.51620900 0.39477300 0.81451000 1 - O O76 1 0.79830100 0.87856400 0.98379100 1 - O O77 1 0.70169900 0.68549000 0.08026300 1 - O O78 1 0.08026300 0.70169900 0.68549000 1 - O O79 1 0.12143600 0.60522700 0.91973700 1 -" -Zn3Si3(BiO6)2,mp-1157822,Ia-3d,[],0.29231335174999984,{'tags': []},"Full Formula (Zn12 Si12 Bi8 O48) -Reduced Formula: Zn3Si3(BiO6)2 -abc : 10.823575 10.823575 10.823575 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 0 - 1 Zn 0.75 0.125 0.375 0 - 2 Zn 0.375 0.125 0.25 0 - 3 Zn 0.125 0.375 0.75 0 - 4 Zn 0.25 0.875 0.625 0 - 5 Zn 0.125 0.25 0.375 0 - 6 Zn 0.625 0.25 0.875 0 - 7 Zn 0.75 0.625 0.875 0 - 8 Zn 0.875 0.75 0.625 0 - 9 Zn 0.875 0.625 0.25 0 - 10 Zn 0.625 0.875 0.75 0 - 11 Zn 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 0 - 13 Si 0.875 0.25 0.125 0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 0 - 16 Si 0.25 0.125 0.875 0 - 17 Si 0.375 0.625 0.75 0 - 18 Si 0.375 0.25 0.625 0 - 19 Si 0.875 0.125 0.75 0 - 20 Si 0.625 0.375 0.25 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 0 - 24 Bi 0.5 0 0 0 - 25 Bi 0.5 0.5 0 0 - 26 Bi 0 0.5 0.5 0 - 27 Bi 0 0 0.5 0 - 28 Bi 0.5 0.5 0.5 0 - 29 Bi 0 0.5 0 0 - 30 Bi 0.5 0 0.5 0 - 31 Bi 0 0 0 0 - 32 O 0.600617 0.892156 0.367864 -0 - 33 O 0.367864 0.600617 0.892156 -0 - 34 O 0.267248 0.291539 0.899383 -0 - 35 O 0.475709 0.607844 0.208461 -0 - 36 O 0.291539 0.892156 0.024291 -0 - 37 O 0.132136 0.024291 0.232752 -0 - 38 O 0.367864 0.267248 0.475709 -0 - 39 O 0.892156 0.367864 0.600617 -0 - 40 O 0.208461 0.232752 0.600617 -0 - 41 O 0.475709 0.367864 0.267248 -0 - 42 O 0.892156 0.024291 0.291539 -0 - 43 O 0.607844 0.899383 0.132136 -0 - 44 O 0.899383 0.132136 0.607844 -0 - 45 O 0.267248 0.475709 0.367864 -0 - 46 O 0.600617 0.208461 0.232752 -0 - 47 O 0.232752 0.600617 0.208461 -0 - 48 O 0.024291 0.291539 0.892156 -0 - 49 O 0.899383 0.267248 0.291539 -0 - 50 O 0.024291 0.232752 0.132136 -0 - 51 O 0.791539 0.767248 0.399383 -0 - 52 O 0.208461 0.475709 0.607844 -0 - 53 O 0.607844 0.208461 0.475709 -0 - 54 O 0.232752 0.132136 0.024291 -0 - 55 O 0.132136 0.607844 0.899383 -0 - 56 O 0.399383 0.107844 0.632136 -0 - 57 O 0.632136 0.399383 0.107844 -0 - 58 O 0.732752 0.708461 0.100617 -0 - 59 O 0.524291 0.392156 0.791539 -0 - 60 O 0.708461 0.107844 0.975709 -0 - 61 O 0.867864 0.975709 0.767248 -0 - 62 O 0.632136 0.732752 0.524291 -0 - 63 O 0.107844 0.632136 0.399383 -0 - 64 O 0.867864 0.392156 0.100617 -0 - 65 O 0.767248 0.867864 0.975709 -0 - 66 O 0.392156 0.791539 0.524291 -0 - 67 O 0.708461 0.100617 0.732752 -0 - 68 O 0.791539 0.524291 0.392156 -0 - 69 O 0.975709 0.767248 0.867864 -0 - 70 O 0.100617 0.732752 0.708461 -0 - 71 O 0.975709 0.708461 0.107844 -0 - 72 O 0.767248 0.399383 0.791539 -0 - 73 O 0.399383 0.791539 0.767248 -0 - 74 O 0.732752 0.524291 0.632136 -0 - 75 O 0.100617 0.867864 0.392156 -0 - 76 O 0.392156 0.100617 0.867864 -0 - 77 O 0.107844 0.975709 0.708461 -0 - 78 O 0.524291 0.632136 0.732752 -0 - 79 O 0.291539 0.899383 0.267248 -0","# generated using pymatgen -data_Zn3Si3(BiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.82357510 -_cell_length_b 10.82357510 -_cell_length_c 10.82357510 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Si3(BiO6)2 -_chemical_formula_sum 'Zn12 Si12 Bi8 O48' -_cell_volume 976.09101340 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Bi Bi24 1 0.50000000 0.00000000 0.00000000 1 - Bi Bi25 1 0.50000000 0.50000000 0.00000000 1 - Bi Bi26 1 0.00000000 0.50000000 0.50000000 1 - Bi Bi27 1 0.00000000 0.00000000 0.50000000 1 - Bi Bi28 1 0.50000000 0.50000000 0.50000000 1 - Bi Bi29 1 0.00000000 0.50000000 0.00000000 1 - Bi Bi30 1 0.50000000 0.00000000 0.50000000 1 - Bi Bi31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.60061700 0.89215600 0.36786400 1 - O O33 1 0.36786400 0.60061700 0.89215600 1 - O O34 1 0.26724800 0.29153900 0.89938300 1 - O O35 1 0.47570900 0.60784400 0.20846100 1 - O O36 1 0.29153900 0.89215600 0.02429100 1 - O O37 1 0.13213600 0.02429100 0.23275200 1 - O O38 1 0.36786400 0.26724800 0.47570900 1 - O O39 1 0.89215600 0.36786400 0.60061700 1 - O O40 1 0.20846100 0.23275200 0.60061700 1 - O O41 1 0.47570900 0.36786400 0.26724800 1 - O O42 1 0.89215600 0.02429100 0.29153900 1 - O O43 1 0.60784400 0.89938300 0.13213600 1 - O O44 1 0.89938300 0.13213600 0.60784400 1 - O O45 1 0.26724800 0.47570900 0.36786400 1 - O O46 1 0.60061700 0.20846100 0.23275200 1 - O O47 1 0.23275200 0.60061700 0.20846100 1 - O O48 1 0.02429100 0.29153900 0.89215600 1 - O O49 1 0.89938300 0.26724800 0.29153900 1 - O O50 1 0.02429100 0.23275200 0.13213600 1 - O O51 1 0.79153900 0.76724800 0.39938300 1 - O O52 1 0.20846100 0.47570900 0.60784400 1 - O O53 1 0.60784400 0.20846100 0.47570900 1 - O O54 1 0.23275200 0.13213600 0.02429100 1 - O O55 1 0.13213600 0.60784400 0.89938300 1 - O O56 1 0.39938300 0.10784400 0.63213600 1 - O O57 1 0.63213600 0.39938300 0.10784400 1 - O O58 1 0.73275200 0.70846100 0.10061700 1 - O O59 1 0.52429100 0.39215600 0.79153900 1 - O O60 1 0.70846100 0.10784400 0.97570900 1 - O O61 1 0.86786400 0.97570900 0.76724800 1 - O O62 1 0.63213600 0.73275200 0.52429100 1 - O O63 1 0.10784400 0.63213600 0.39938300 1 - O O64 1 0.86786400 0.39215600 0.10061700 1 - O O65 1 0.76724800 0.86786400 0.97570900 1 - O O66 1 0.39215600 0.79153900 0.52429100 1 - O O67 1 0.70846100 0.10061700 0.73275200 1 - O O68 1 0.79153900 0.52429100 0.39215600 1 - O O69 1 0.97570900 0.76724800 0.86786400 1 - O O70 1 0.10061700 0.73275200 0.70846100 1 - O O71 1 0.97570900 0.70846100 0.10784400 1 - O O72 1 0.76724800 0.39938300 0.79153900 1 - O O73 1 0.39938300 0.79153900 0.76724800 1 - O O74 1 0.73275200 0.52429100 0.63213600 1 - O O75 1 0.10061700 0.86786400 0.39215600 1 - O O76 1 0.39215600 0.10061700 0.86786400 1 - O O77 1 0.10784400 0.97570900 0.70846100 1 - O O78 1 0.52429100 0.63213600 0.73275200 1 - O O79 1 0.29153900 0.89938300 0.26724800 1 -" -Y2Ti3(SiO4)3,mp-1163922,Ia-3d,[],0.3256642169702424,{'tags': []},"Full Formula (Y8 Ti12 Si12 O48) -Reduced Formula: Y2Ti3(SiO4)3 -abc : 10.684209 10.684209 10.684209 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0.5 0.038 - 1 Y 0 0 0 0.038 - 2 Y 0.5 0 0 0.038 - 3 Y 0 0.5 0 0.038 - 4 Y 0.5 0.5 0 0.038 - 5 Y 0 0.5 0.5 0.038 - 6 Y 0.5 0 0.5 0.038 - 7 Y 0.5 0.5 0.5 0.038 - 8 Ti 0.875 0.625 0.25 1.65 - 9 Ti 0.625 0.25 0.875 1.65 - 10 Ti 0.875 0.75 0.625 1.65 - 11 Ti 0.75 0.625 0.875 1.647 - 12 Ti 0.25 0.875 0.625 1.65 - 13 Ti 0.625 0.875 0.75 1.65 - 14 Ti 0.125 0.375 0.75 1.65 - 15 Ti 0.375 0.75 0.125 1.65 - 16 Ti 0.125 0.25 0.375 1.65 - 17 Ti 0.25 0.375 0.125 1.647 - 18 Ti 0.75 0.125 0.375 1.65 - 19 Ti 0.375 0.125 0.25 1.65 - 20 Si 0.125 0.875 0.25 0.009 - 21 Si 0.25 0.125 0.875 0.009 - 22 Si 0.75 0.375 0.625 0.009 - 23 Si 0.625 0.375 0.25 0.009 - 24 Si 0.625 0.75 0.375 0.009 - 25 Si 0.375 0.625 0.75 0.009 - 26 Si 0.125 0.75 0.875 0.009 - 27 Si 0.75 0.875 0.125 0.009 - 28 Si 0.875 0.25 0.125 0.009 - 29 Si 0.375 0.25 0.625 0.009 - 30 Si 0.25 0.625 0.375 0.009 - 31 Si 0.875 0.125 0.75 0.009 - 32 O 0.478082 0.371941 0.272631 -0 - 33 O 0.294549 0.893859 0.021918 -0.001 - 34 O 0.606141 0.900689 0.128059 -0.001 - 35 O 0.599311 0.205451 0.227369 -0.001 - 36 O 0.128059 0.021918 0.227369 -0.001 - 37 O 0.205451 0.227369 0.599311 -0.001 - 38 O 0.205451 0.478082 0.606141 -0.001 - 39 O 0.227369 0.599311 0.205451 -0.001 - 40 O 0.371941 0.599311 0.893859 -0.001 - 41 O 0.900689 0.272631 0.294549 -0.001 - 42 O 0.272631 0.294549 0.900689 -0.001 - 43 O 0.227369 0.128059 0.021918 -0.001 - 44 O 0.478082 0.606141 0.205451 -0 - 45 O 0.893859 0.371941 0.599311 -0.001 - 46 O 0.021918 0.227369 0.128059 -0 - 47 O 0.606141 0.205451 0.478082 -0.001 - 48 O 0.599311 0.893859 0.371941 -0.001 - 49 O 0.021918 0.294549 0.893859 -0 - 50 O 0.900689 0.128059 0.606141 -0.001 - 51 O 0.628059 0.400689 0.106141 -0.001 - 52 O 0.371941 0.272631 0.478082 -0.001 - 53 O 0.272631 0.478082 0.371941 -0.001 - 54 O 0.893859 0.021918 0.294549 -0.001 - 55 O 0.294549 0.900689 0.272631 -0.001 - 56 O 0.521918 0.628059 0.727369 -0 - 57 O 0.705451 0.106141 0.978082 -0.001 - 58 O 0.393859 0.099311 0.871941 -0.001 - 59 O 0.400689 0.794549 0.772631 -0.001 - 60 O 0.871941 0.978082 0.772631 -0.001 - 61 O 0.794549 0.772631 0.400689 -0.001 - 62 O 0.794549 0.521918 0.393859 -0.001 - 63 O 0.772631 0.400689 0.794549 -0.001 - 64 O 0.705451 0.099311 0.727369 -0.001 - 65 O 0.106141 0.978082 0.705451 -0.001 - 66 O 0.727369 0.521918 0.628059 -0.001 - 67 O 0.628059 0.727369 0.521918 -0.001 - 68 O 0.871941 0.393859 0.099311 -0.001 - 69 O 0.099311 0.871941 0.393859 -0.001 - 70 O 0.978082 0.705451 0.106141 -0 - 71 O 0.400689 0.106141 0.628059 -0.001 - 72 O 0.393859 0.794549 0.521918 -0.001 - 73 O 0.978082 0.772631 0.871941 -0 - 74 O 0.106141 0.628059 0.400689 -0.001 - 75 O 0.521918 0.393859 0.794549 -0 - 76 O 0.772631 0.871941 0.978082 -0.001 - 77 O 0.727369 0.705451 0.099311 -0.001 - 78 O 0.099311 0.727369 0.705451 -0.001 - 79 O 0.128059 0.606141 0.900689 -0.001","# generated using pymatgen -data_Y2Ti3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.68420910 -_cell_length_b 10.68420910 -_cell_length_c 10.68420910 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Ti3(SiO4)3 -_chemical_formula_sum 'Y8 Ti12 Si12 O48' -_cell_volume 938.86953319 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.50000000 1 - Y Y1 1 0.00000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.00000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.00000000 1 - Y Y4 1 0.50000000 0.50000000 0.00000000 1 - Y Y5 1 0.00000000 0.50000000 0.50000000 1 - Y Y6 1 0.50000000 0.00000000 0.50000000 1 - Y Y7 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti8 1 0.87500000 0.62500000 0.25000000 1 - Ti Ti9 1 0.62500000 0.25000000 0.87500000 1 - Ti Ti10 1 0.87500000 0.75000000 0.62500000 1 - Ti Ti11 1 0.75000000 0.62500000 0.87500000 1 - Ti Ti12 1 0.25000000 0.87500000 0.62500000 1 - Ti Ti13 1 0.62500000 0.87500000 0.75000000 1 - Ti Ti14 1 0.12500000 0.37500000 0.75000000 1 - Ti Ti15 1 0.37500000 0.75000000 0.12500000 1 - Ti Ti16 1 0.12500000 0.25000000 0.37500000 1 - Ti Ti17 1 0.25000000 0.37500000 0.12500000 1 - Ti Ti18 1 0.75000000 0.12500000 0.37500000 1 - Ti Ti19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.25000000 0.12500000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.37500000 0.25000000 0.62500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.47808200 0.37194100 0.27263100 1 - O O33 1 0.29454900 0.89385900 0.02191800 1 - O O34 1 0.60614100 0.90068900 0.12805900 1 - O O35 1 0.59931100 0.20545100 0.22736900 1 - O O36 1 0.12805900 0.02191800 0.22736900 1 - O O37 1 0.20545100 0.22736900 0.59931100 1 - O O38 1 0.20545100 0.47808200 0.60614100 1 - O O39 1 0.22736900 0.59931100 0.20545100 1 - O O40 1 0.37194100 0.59931100 0.89385900 1 - O O41 1 0.90068900 0.27263100 0.29454900 1 - O O42 1 0.27263100 0.29454900 0.90068900 1 - O O43 1 0.22736900 0.12805900 0.02191800 1 - O O44 1 0.47808200 0.60614100 0.20545100 1 - O O45 1 0.89385900 0.37194100 0.59931100 1 - O O46 1 0.02191800 0.22736900 0.12805900 1 - O O47 1 0.60614100 0.20545100 0.47808200 1 - O O48 1 0.59931100 0.89385900 0.37194100 1 - O O49 1 0.02191800 0.29454900 0.89385900 1 - O O50 1 0.90068900 0.12805900 0.60614100 1 - O O51 1 0.62805900 0.40068900 0.10614100 1 - O O52 1 0.37194100 0.27263100 0.47808200 1 - O O53 1 0.27263100 0.47808200 0.37194100 1 - O O54 1 0.89385900 0.02191800 0.29454900 1 - O O55 1 0.29454900 0.90068900 0.27263100 1 - O O56 1 0.52191800 0.62805900 0.72736900 1 - O O57 1 0.70545100 0.10614100 0.97808200 1 - O O58 1 0.39385900 0.09931100 0.87194100 1 - O O59 1 0.40068900 0.79454900 0.77263100 1 - O O60 1 0.87194100 0.97808200 0.77263100 1 - O O61 1 0.79454900 0.77263100 0.40068900 1 - O O62 1 0.79454900 0.52191800 0.39385900 1 - O O63 1 0.77263100 0.40068900 0.79454900 1 - O O64 1 0.70545100 0.09931100 0.72736900 1 - O O65 1 0.10614100 0.97808200 0.70545100 1 - O O66 1 0.72736900 0.52191800 0.62805900 1 - O O67 1 0.62805900 0.72736900 0.52191800 1 - O O68 1 0.87194100 0.39385900 0.09931100 1 - O O69 1 0.09931100 0.87194100 0.39385900 1 - O O70 1 0.97808200 0.70545100 0.10614100 1 - O O71 1 0.40068900 0.10614100 0.62805900 1 - O O72 1 0.39385900 0.79454900 0.52191800 1 - O O73 1 0.97808200 0.77263100 0.87194100 1 - O O74 1 0.10614100 0.62805900 0.40068900 1 - O O75 1 0.52191800 0.39385900 0.79454900 1 - O O76 1 0.77263100 0.87194100 0.97808200 1 - O O77 1 0.72736900 0.70545100 0.09931100 1 - O O78 1 0.09931100 0.72736900 0.70545100 1 - O O79 1 0.12805900 0.60614100 0.90068900 1 -" -Ca3Si3(BiO6)2,mp-1163927,Ia-3d,[],0.06536772037500604,{'tags': []},"Full Formula (Ca12 Si12 Bi8 O48) -Reduced Formula: Ca3Si3(BiO6)2 -abc : 11.119962 11.119962 11.119962 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0 - 1 Ca 0.75 0.125 0.375 -0 - 2 Ca 0.375 0.125 0.25 -0 - 3 Ca 0.125 0.375 0.75 -0 - 4 Ca 0.25 0.875 0.625 -0 - 5 Ca 0.125 0.25 0.375 -0 - 6 Ca 0.625 0.25 0.875 -0 - 7 Ca 0.75 0.625 0.875 -0 - 8 Ca 0.875 0.75 0.625 -0 - 9 Ca 0.875 0.625 0.25 -0 - 10 Ca 0.625 0.875 0.75 -0 - 11 Ca 0.375 0.75 0.125 -0 - 12 Si 0.125 0.75 0.875 0 - 13 Si 0.875 0.25 0.125 0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 0 - 16 Si 0.25 0.125 0.875 0 - 17 Si 0.375 0.625 0.75 0 - 18 Si 0.375 0.25 0.625 0 - 19 Si 0.875 0.125 0.75 0 - 20 Si 0.625 0.375 0.25 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 0 - 24 Bi 0.5 0 0 0 - 25 Bi 0.5 0.5 0 0 - 26 Bi 0 0.5 0.5 0 - 27 Bi 0 0 0.5 0 - 28 Bi 0.5 0.5 0.5 0 - 29 Bi 0 0.5 0 0 - 30 Bi 0.5 0 0.5 0 - 31 Bi 0 0 0 0 - 32 O 0.600148 0.889477 0.373388 -0 - 33 O 0.373388 0.600148 0.889477 -0 - 34 O 0.27324 0.289329 0.899852 -0 - 35 O 0.483911 0.610523 0.210671 -0 - 36 O 0.289329 0.889477 0.016089 -0 - 37 O 0.126612 0.016089 0.22676 -0 - 38 O 0.373388 0.27324 0.483911 -0 - 39 O 0.889477 0.373388 0.600148 -0 - 40 O 0.210671 0.22676 0.600148 -0 - 41 O 0.483911 0.373388 0.27324 -0 - 42 O 0.889477 0.016089 0.289329 -0 - 43 O 0.610523 0.899852 0.126612 -0 - 44 O 0.899852 0.126612 0.610523 -0 - 45 O 0.27324 0.483911 0.373388 -0 - 46 O 0.600148 0.210671 0.22676 -0 - 47 O 0.22676 0.600148 0.210671 -0 - 48 O 0.016089 0.289329 0.889477 -0 - 49 O 0.899852 0.27324 0.289329 -0 - 50 O 0.016089 0.22676 0.126612 -0 - 51 O 0.789329 0.77324 0.399852 -0 - 52 O 0.210671 0.483911 0.610523 -0 - 53 O 0.610523 0.210671 0.483911 -0 - 54 O 0.22676 0.126612 0.016089 -0 - 55 O 0.126612 0.610523 0.899852 -0 - 56 O 0.399852 0.110523 0.626612 -0 - 57 O 0.626612 0.399852 0.110523 -0 - 58 O 0.72676 0.710671 0.100148 -0 - 59 O 0.516089 0.389477 0.789329 -0 - 60 O 0.710671 0.110523 0.983911 -0 - 61 O 0.873388 0.983911 0.77324 -0 - 62 O 0.626612 0.72676 0.516089 -0 - 63 O 0.110523 0.626612 0.399852 -0 - 64 O 0.873388 0.389477 0.100148 -0 - 65 O 0.77324 0.873388 0.983911 -0 - 66 O 0.389477 0.789329 0.516089 -0 - 67 O 0.710671 0.100148 0.72676 -0 - 68 O 0.789329 0.516089 0.389477 -0 - 69 O 0.983911 0.77324 0.873388 -0 - 70 O 0.100148 0.72676 0.710671 -0 - 71 O 0.983911 0.710671 0.110523 -0 - 72 O 0.77324 0.399852 0.789329 -0 - 73 O 0.399852 0.789329 0.77324 -0 - 74 O 0.72676 0.516089 0.626612 -0 - 75 O 0.100148 0.873388 0.389477 -0 - 76 O 0.389477 0.100148 0.873388 -0 - 77 O 0.110523 0.983911 0.710671 -0 - 78 O 0.516089 0.626612 0.72676 -0 - 79 O 0.289329 0.899852 0.27324 -0","# generated using pymatgen -data_Ca3Si3(BiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.11996191 -_cell_length_b 11.11996191 -_cell_length_c 11.11996191 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Si3(BiO6)2 -_chemical_formula_sum 'Ca12 Si12 Bi8 O48' -_cell_volume 1058.49304242 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Bi Bi24 1 0.50000000 0.00000000 0.00000000 1 - Bi Bi25 1 0.50000000 0.50000000 0.00000000 1 - Bi Bi26 1 0.00000000 0.50000000 0.50000000 1 - Bi Bi27 1 0.00000000 0.00000000 0.50000000 1 - Bi Bi28 1 0.50000000 0.50000000 0.50000000 1 - Bi Bi29 1 0.00000000 0.50000000 0.00000000 1 - Bi Bi30 1 0.50000000 0.00000000 0.50000000 1 - Bi Bi31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.60014800 0.88947700 0.37338800 1 - O O33 1 0.37338800 0.60014800 0.88947700 1 - O O34 1 0.27324000 0.28932900 0.89985200 1 - O O35 1 0.48391100 0.61052300 0.21067100 1 - O O36 1 0.28932900 0.88947700 0.01608900 1 - O O37 1 0.12661200 0.01608900 0.22676000 1 - O O38 1 0.37338800 0.27324000 0.48391100 1 - O O39 1 0.88947700 0.37338800 0.60014800 1 - O O40 1 0.21067100 0.22676000 0.60014800 1 - O O41 1 0.48391100 0.37338800 0.27324000 1 - O O42 1 0.88947700 0.01608900 0.28932900 1 - O O43 1 0.61052300 0.89985200 0.12661200 1 - O O44 1 0.89985200 0.12661200 0.61052300 1 - O O45 1 0.27324000 0.48391100 0.37338800 1 - O O46 1 0.60014800 0.21067100 0.22676000 1 - O O47 1 0.22676000 0.60014800 0.21067100 1 - O O48 1 0.01608900 0.28932900 0.88947700 1 - O O49 1 0.89985200 0.27324000 0.28932900 1 - O O50 1 0.01608900 0.22676000 0.12661200 1 - O O51 1 0.78932900 0.77324000 0.39985200 1 - O O52 1 0.21067100 0.48391100 0.61052300 1 - O O53 1 0.61052300 0.21067100 0.48391100 1 - O O54 1 0.22676000 0.12661200 0.01608900 1 - O O55 1 0.12661200 0.61052300 0.89985200 1 - O O56 1 0.39985200 0.11052300 0.62661200 1 - O O57 1 0.62661200 0.39985200 0.11052300 1 - O O58 1 0.72676000 0.71067100 0.10014800 1 - O O59 1 0.51608900 0.38947700 0.78932900 1 - O O60 1 0.71067100 0.11052300 0.98391100 1 - O O61 1 0.87338800 0.98391100 0.77324000 1 - O O62 1 0.62661200 0.72676000 0.51608900 1 - O O63 1 0.11052300 0.62661200 0.39985200 1 - O O64 1 0.87338800 0.38947700 0.10014800 1 - O O65 1 0.77324000 0.87338800 0.98391100 1 - O O66 1 0.38947700 0.78932900 0.51608900 1 - O O67 1 0.71067100 0.10014800 0.72676000 1 - O O68 1 0.78932900 0.51608900 0.38947700 1 - O O69 1 0.98391100 0.77324000 0.87338800 1 - O O70 1 0.10014800 0.72676000 0.71067100 1 - O O71 1 0.98391100 0.71067100 0.11052300 1 - O O72 1 0.77324000 0.39985200 0.78932900 1 - O O73 1 0.39985200 0.78932900 0.77324000 1 - O O74 1 0.72676000 0.51608900 0.62661200 1 - O O75 1 0.10014800 0.87338800 0.38947700 1 - O O76 1 0.38947700 0.10014800 0.87338800 1 - O O77 1 0.11052300 0.98391100 0.71067100 1 - O O78 1 0.51608900 0.62661200 0.72676000 1 - O O79 1 0.28932900 0.89985200 0.27324000 1 -" -Al2Si3(SnO4)3,mp-1163929,Ia-3d,[],0.1735804977500015,{'tags': []},"Full Formula (Al8 Si12 Sn12 O48) -Reduced Formula: Al2Si3(SnO4)3 -abc : 10.667895 10.667895 10.667895 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0 -0 - 1 Al 0.5 0 0 -0 - 2 Al 0.5 0.5 0 -0 - 3 Al 0 0.5 0.5 -0 - 4 Al 0 0 0.5 -0 - 5 Al 0.5 0.5 0.5 -0 - 6 Al 0 0.5 0 -0 - 7 Al 0.5 0 0.5 -0 - 8 Si 0.125 0.75 0.875 -0 - 9 Si 0.75 0.875 0.125 -0 - 10 Si 0.25 0.625 0.375 -0 - 11 Si 0.625 0.75 0.375 -0 - 12 Si 0.875 0.125 0.75 -0 - 13 Si 0.375 0.25 0.625 -0 - 14 Si 0.375 0.625 0.75 -0 - 15 Si 0.25 0.125 0.875 -0 - 16 Si 0.625 0.375 0.25 -0 - 17 Si 0.125 0.875 0.25 -0 - 18 Si 0.75 0.375 0.625 -0 - 19 Si 0.875 0.25 0.125 -0 - 20 Sn 0.875 0.75 0.625 -0 - 21 Sn 0.875 0.625 0.25 -0 - 22 Sn 0.625 0.875 0.75 -0 - 23 Sn 0.25 0.875 0.625 -0 - 24 Sn 0.75 0.625 0.875 -0 - 25 Sn 0.625 0.25 0.875 -0 - 26 Sn 0.125 0.25 0.375 -0 - 27 Sn 0.125 0.375 0.75 -0 - 28 Sn 0.375 0.125 0.25 -0 - 29 Sn 0.75 0.125 0.375 -0 - 30 Sn 0.25 0.375 0.125 -0 - 31 Sn 0.375 0.75 0.125 -0 - 32 O 0.58044 0.888611 0.392868 0 - 33 O 0.392868 0.58044 0.888611 0 - 34 O 0.312428 0.308171 0.91956 0 - 35 O 0.504257 0.611389 0.191829 0 - 36 O 0.308171 0.888611 0.995743 0 - 37 O 0.107132 0.995743 0.187572 0 - 38 O 0.392868 0.312428 0.504257 0 - 39 O 0.888611 0.392868 0.58044 0 - 40 O 0.191829 0.187572 0.58044 0 - 41 O 0.504257 0.392868 0.312428 0 - 42 O 0.888611 0.995743 0.308171 0 - 43 O 0.611389 0.91956 0.107132 0 - 44 O 0.91956 0.107132 0.611389 0 - 45 O 0.312428 0.504257 0.392868 0 - 46 O 0.58044 0.191829 0.187572 0 - 47 O 0.187572 0.58044 0.191829 0 - 48 O 0.995743 0.308171 0.888611 0 - 49 O 0.91956 0.312428 0.308171 0 - 50 O 0.995743 0.187572 0.107132 0 - 51 O 0.808171 0.812428 0.41956 0 - 52 O 0.308171 0.91956 0.312428 0 - 53 O 0.611389 0.191829 0.504257 0 - 54 O 0.187572 0.107132 0.995743 0 - 55 O 0.107132 0.611389 0.91956 0 - 56 O 0.41956 0.111389 0.607132 0 - 57 O 0.607132 0.41956 0.111389 0 - 58 O 0.687572 0.691829 0.08044 0 - 59 O 0.495743 0.388611 0.808171 0 - 60 O 0.691829 0.111389 0.004257 0 - 61 O 0.892868 0.004257 0.812428 0 - 62 O 0.607132 0.687572 0.495743 0 - 63 O 0.111389 0.607132 0.41956 0 - 64 O 0.892868 0.388611 0.08044 0 - 65 O 0.812428 0.892868 0.004257 0 - 66 O 0.388611 0.808171 0.495743 0 - 67 O 0.691829 0.08044 0.687572 0 - 68 O 0.808171 0.495743 0.388611 0 - 69 O 0.004257 0.812428 0.892868 0 - 70 O 0.08044 0.687572 0.691829 0 - 71 O 0.004257 0.691829 0.111389 0 - 72 O 0.812428 0.41956 0.808171 0 - 73 O 0.41956 0.808171 0.812428 0 - 74 O 0.687572 0.495743 0.607132 0 - 75 O 0.08044 0.892868 0.388611 0 - 76 O 0.388611 0.08044 0.892868 0 - 77 O 0.111389 0.004257 0.691829 0 - 78 O 0.495743 0.607132 0.687572 0 - 79 O 0.191829 0.504257 0.611389 0","# generated using pymatgen -data_Al2Si3(SnO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.66789491 -_cell_length_b 10.66789491 -_cell_length_c 10.66789491 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Si3(SnO4)3 -_chemical_formula_sum 'Al8 Si12 Sn12 O48' -_cell_volume 934.57529397 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.00000000 1 - Al Al1 1 0.50000000 0.00000000 0.00000000 1 - Al Al2 1 0.50000000 0.50000000 0.00000000 1 - Al Al3 1 0.00000000 0.50000000 0.50000000 1 - Al Al4 1 0.00000000 0.00000000 0.50000000 1 - Al Al5 1 0.50000000 0.50000000 0.50000000 1 - Al Al6 1 0.00000000 0.50000000 0.00000000 1 - Al Al7 1 0.50000000 0.00000000 0.50000000 1 - Si Si8 1 0.12500000 0.75000000 0.87500000 1 - Si Si9 1 0.75000000 0.87500000 0.12500000 1 - Si Si10 1 0.25000000 0.62500000 0.37500000 1 - Si Si11 1 0.62500000 0.75000000 0.37500000 1 - Si Si12 1 0.87500000 0.12500000 0.75000000 1 - Si Si13 1 0.37500000 0.25000000 0.62500000 1 - Si Si14 1 0.37500000 0.62500000 0.75000000 1 - Si Si15 1 0.25000000 0.12500000 0.87500000 1 - Si Si16 1 0.62500000 0.37500000 0.25000000 1 - Si Si17 1 0.12500000 0.87500000 0.25000000 1 - Si Si18 1 0.75000000 0.37500000 0.62500000 1 - Si Si19 1 0.87500000 0.25000000 0.12500000 1 - Sn Sn20 1 0.87500000 0.75000000 0.62500000 1 - Sn Sn21 1 0.87500000 0.62500000 0.25000000 1 - Sn Sn22 1 0.62500000 0.87500000 0.75000000 1 - Sn Sn23 1 0.25000000 0.87500000 0.62500000 1 - Sn Sn24 1 0.75000000 0.62500000 0.87500000 1 - Sn Sn25 1 0.62500000 0.25000000 0.87500000 1 - Sn Sn26 1 0.12500000 0.25000000 0.37500000 1 - Sn Sn27 1 0.12500000 0.37500000 0.75000000 1 - Sn Sn28 1 0.37500000 0.12500000 0.25000000 1 - Sn Sn29 1 0.75000000 0.12500000 0.37500000 1 - Sn Sn30 1 0.25000000 0.37500000 0.12500000 1 - Sn Sn31 1 0.37500000 0.75000000 0.12500000 1 - O O32 1 0.58044000 0.88861100 0.39286800 1 - O O33 1 0.39286800 0.58044000 0.88861100 1 - O O34 1 0.31242800 0.30817100 0.91956000 1 - O O35 1 0.50425700 0.61138900 0.19182900 1 - O O36 1 0.30817100 0.88861100 0.99574300 1 - O O37 1 0.10713200 0.99574300 0.18757200 1 - O O38 1 0.39286800 0.31242800 0.50425700 1 - O O39 1 0.88861100 0.39286800 0.58044000 1 - O O40 1 0.19182900 0.18757200 0.58044000 1 - O O41 1 0.50425700 0.39286800 0.31242800 1 - O O42 1 0.88861100 0.99574300 0.30817100 1 - O O43 1 0.61138900 0.91956000 0.10713200 1 - O O44 1 0.91956000 0.10713200 0.61138900 1 - O O45 1 0.31242800 0.50425700 0.39286800 1 - O O46 1 0.58044000 0.19182900 0.18757200 1 - O O47 1 0.18757200 0.58044000 0.19182900 1 - O O48 1 0.99574300 0.30817100 0.88861100 1 - O O49 1 0.91956000 0.31242800 0.30817100 1 - O O50 1 0.99574300 0.18757200 0.10713200 1 - O O51 1 0.80817100 0.81242800 0.41956000 1 - O O52 1 0.30817100 0.91956000 0.31242800 1 - O O53 1 0.61138900 0.19182900 0.50425700 1 - O O54 1 0.18757200 0.10713200 0.99574300 1 - O O55 1 0.10713200 0.61138900 0.91956000 1 - O O56 1 0.41956000 0.11138900 0.60713200 1 - O O57 1 0.60713200 0.41956000 0.11138900 1 - O O58 1 0.68757200 0.69182900 0.08044000 1 - O O59 1 0.49574300 0.38861100 0.80817100 1 - O O60 1 0.69182900 0.11138900 0.00425700 1 - O O61 1 0.89286800 0.00425700 0.81242800 1 - O O62 1 0.60713200 0.68757200 0.49574300 1 - O O63 1 0.11138900 0.60713200 0.41956000 1 - O O64 1 0.89286800 0.38861100 0.08044000 1 - O O65 1 0.81242800 0.89286800 0.00425700 1 - O O66 1 0.38861100 0.80817100 0.49574300 1 - O O67 1 0.69182900 0.08044000 0.68757200 1 - O O68 1 0.80817100 0.49574300 0.38861100 1 - O O69 1 0.00425700 0.81242800 0.89286800 1 - O O70 1 0.08044000 0.68757200 0.69182900 1 - O O71 1 0.00425700 0.69182900 0.11138900 1 - O O72 1 0.81242800 0.41956000 0.80817100 1 - O O73 1 0.41956000 0.80817100 0.81242800 1 - O O74 1 0.68757200 0.49574300 0.60713200 1 - O O75 1 0.08044000 0.89286800 0.38861100 1 - O O76 1 0.38861100 0.08044000 0.89286800 1 - O O77 1 0.11138900 0.00425700 0.69182900 1 - O O78 1 0.49574300 0.60713200 0.68757200 1 - O O79 1 0.19182900 0.50425700 0.61138900 1 -" -Ca3Co2(SiO4)3,mp-1163930,Ia-3d,[],0.03056516998610803,{'tags': []},"Full Formula (Ca12 Co8 Si12 O48) -Reduced Formula: Ca3Co2(SiO4)3 -abc : 10.518987 10.518987 10.518987 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0.001 - 1 Ca 0.75 0.125 0.375 0.001 - 2 Ca 0.375 0.125 0.25 0.001 - 3 Ca 0.125 0.375 0.75 0.001 - 4 Ca 0.25 0.875 0.625 0.001 - 5 Ca 0.125 0.25 0.375 0.001 - 6 Ca 0.625 0.25 0.875 0.001 - 7 Ca 0.75 0.625 0.875 0.001 - 8 Ca 0.875 0.75 0.625 0.001 - 9 Ca 0.875 0.625 0.25 0.001 - 10 Ca 0.625 0.875 0.75 0.001 - 11 Ca 0.375 0.75 0.125 0.001 - 12 Co 0.5 0 0 3.127 - 13 Co 0.5 0.5 0 3.13 - 14 Co 0 0.5 0.5 3.128 - 15 Co 0 0 0.5 3.128 - 16 Co 0.5 0.5 0.5 3.13 - 17 Co 0 0.5 0 3.13 - 18 Co 0.5 0 0.5 3.127 - 19 Co 0 0 0 3.13 - 20 Si 0.125 0.75 0.875 0.011 - 21 Si 0.875 0.25 0.125 0.011 - 22 Si 0.75 0.375 0.625 0.011 - 23 Si 0.125 0.875 0.25 0.011 - 24 Si 0.25 0.125 0.875 0.011 - 25 Si 0.375 0.625 0.75 0.011 - 26 Si 0.375 0.25 0.625 0.011 - 27 Si 0.875 0.125 0.75 0.011 - 28 Si 0.625 0.375 0.25 0.011 - 29 Si 0.75 0.875 0.125 0.011 - 30 Si 0.25 0.625 0.375 0.011 - 31 Si 0.625 0.75 0.375 0.011 - 32 O 0.587406 0.893291 0.384051 0.117 - 33 O 0.384051 0.587406 0.893291 0.117 - 34 O 0.296645 0.305884 0.912594 0.118 - 35 O 0.490761 0.606709 0.194116 0.117 - 36 O 0.305884 0.893291 0.009239 0.118 - 37 O 0.115949 0.009239 0.203355 0.117 - 38 O 0.384051 0.296645 0.490761 0.117 - 39 O 0.893291 0.384051 0.587406 0.117 - 40 O 0.194116 0.203355 0.587406 0.118 - 41 O 0.490761 0.384051 0.296645 0.117 - 42 O 0.893291 0.009239 0.305884 0.117 - 43 O 0.606709 0.912594 0.115949 0.117 - 44 O 0.912594 0.115949 0.606709 0.117 - 45 O 0.296645 0.490761 0.384051 0.118 - 46 O 0.587406 0.194116 0.203355 0.117 - 47 O 0.203355 0.587406 0.194116 0.118 - 48 O 0.009239 0.305884 0.893291 0.117 - 49 O 0.912594 0.296645 0.305884 0.117 - 50 O 0.009239 0.203355 0.115949 0.117 - 51 O 0.805884 0.796645 0.412594 0.118 - 52 O 0.194116 0.490761 0.606709 0.118 - 53 O 0.606709 0.194116 0.490761 0.117 - 54 O 0.203355 0.115949 0.009239 0.118 - 55 O 0.115949 0.606709 0.912594 0.117 - 56 O 0.412594 0.106709 0.615949 0.117 - 57 O 0.615949 0.412594 0.106709 0.117 - 58 O 0.703355 0.694116 0.087406 0.118 - 59 O 0.509239 0.393291 0.805884 0.117 - 60 O 0.694116 0.106709 0.990761 0.118 - 61 O 0.884051 0.990761 0.796645 0.117 - 62 O 0.615949 0.703355 0.509239 0.117 - 63 O 0.106709 0.615949 0.412594 0.117 - 64 O 0.884051 0.393291 0.087406 0.117 - 65 O 0.796645 0.884051 0.990761 0.118 - 66 O 0.393291 0.805884 0.509239 0.117 - 67 O 0.694116 0.087406 0.703355 0.118 - 68 O 0.805884 0.509239 0.393291 0.118 - 69 O 0.990761 0.796645 0.884051 0.117 - 70 O 0.087406 0.703355 0.694116 0.117 - 71 O 0.990761 0.694116 0.106709 0.117 - 72 O 0.796645 0.412594 0.805884 0.118 - 73 O 0.412594 0.805884 0.796645 0.117 - 74 O 0.703355 0.509239 0.615949 0.118 - 75 O 0.087406 0.884051 0.393291 0.117 - 76 O 0.393291 0.087406 0.884051 0.117 - 77 O 0.106709 0.990761 0.694116 0.117 - 78 O 0.509239 0.615949 0.703355 0.117 - 79 O 0.305884 0.912594 0.296645 0.118","# generated using pymatgen -data_Ca3Co2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.51898704 -_cell_length_b 10.51898704 -_cell_length_c 10.51898704 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Co2(SiO4)3 -_chemical_formula_sum 'Ca12 Co8 Si12 O48' -_cell_volume 895.98320613 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Co Co12 1 0.50000000 0.00000000 0.00000000 1 - Co Co13 1 0.50000000 0.50000000 0.00000000 1 - Co Co14 1 0.00000000 0.50000000 0.50000000 1 - Co Co15 1 0.00000000 0.00000000 0.50000000 1 - Co Co16 1 0.50000000 0.50000000 0.50000000 1 - Co Co17 1 0.00000000 0.50000000 0.00000000 1 - Co Co18 1 0.50000000 0.00000000 0.50000000 1 - Co Co19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58740600 0.89329100 0.38405100 1 - O O33 1 0.38405100 0.58740600 0.89329100 1 - O O34 1 0.29664500 0.30588400 0.91259400 1 - O O35 1 0.49076100 0.60670900 0.19411600 1 - O O36 1 0.30588400 0.89329100 0.00923900 1 - O O37 1 0.11594900 0.00923900 0.20335500 1 - O O38 1 0.38405100 0.29664500 0.49076100 1 - O O39 1 0.89329100 0.38405100 0.58740600 1 - O O40 1 0.19411600 0.20335500 0.58740600 1 - O O41 1 0.49076100 0.38405100 0.29664500 1 - O O42 1 0.89329100 0.00923900 0.30588400 1 - O O43 1 0.60670900 0.91259400 0.11594900 1 - O O44 1 0.91259400 0.11594900 0.60670900 1 - O O45 1 0.29664500 0.49076100 0.38405100 1 - O O46 1 0.58740600 0.19411600 0.20335500 1 - O O47 1 0.20335500 0.58740600 0.19411600 1 - O O48 1 0.00923900 0.30588400 0.89329100 1 - O O49 1 0.91259400 0.29664500 0.30588400 1 - O O50 1 0.00923900 0.20335500 0.11594900 1 - O O51 1 0.80588400 0.79664500 0.41259400 1 - O O52 1 0.19411600 0.49076100 0.60670900 1 - O O53 1 0.60670900 0.19411600 0.49076100 1 - O O54 1 0.20335500 0.11594900 0.00923900 1 - O O55 1 0.11594900 0.60670900 0.91259400 1 - O O56 1 0.41259400 0.10670900 0.61594900 1 - O O57 1 0.61594900 0.41259400 0.10670900 1 - O O58 1 0.70335500 0.69411600 0.08740600 1 - O O59 1 0.50923900 0.39329100 0.80588400 1 - O O60 1 0.69411600 0.10670900 0.99076100 1 - O O61 1 0.88405100 0.99076100 0.79664500 1 - O O62 1 0.61594900 0.70335500 0.50923900 1 - O O63 1 0.10670900 0.61594900 0.41259400 1 - O O64 1 0.88405100 0.39329100 0.08740600 1 - O O65 1 0.79664500 0.88405100 0.99076100 1 - O O66 1 0.39329100 0.80588400 0.50923900 1 - O O67 1 0.69411600 0.08740600 0.70335500 1 - O O68 1 0.80588400 0.50923900 0.39329100 1 - O O69 1 0.99076100 0.79664500 0.88405100 1 - O O70 1 0.08740600 0.70335500 0.69411600 1 - O O71 1 0.99076100 0.69411600 0.10670900 1 - O O72 1 0.79664500 0.41259400 0.80588400 1 - O O73 1 0.41259400 0.80588400 0.79664500 1 - O O74 1 0.70335500 0.50923900 0.61594900 1 - O O75 1 0.08740600 0.88405100 0.39329100 1 - O O76 1 0.39329100 0.08740600 0.88405100 1 - O O77 1 0.10670900 0.99076100 0.69411600 1 - O O78 1 0.50923900 0.61594900 0.70335500 1 - O O79 1 0.30588400 0.91259400 0.29664500 1 -" -Ca3V2(SiO4)3,mp-1163934,Ia-3d,"[182068, 182067, 182066]",0.0,"{'tags': ['Garnet - (Ca,V,Si)', 'Tricalcium divanadium trisilicate']}","Full Formula (Ca12 V8 Si12 O48) -Reduced Formula: Ca3V2(SiO4)3 -abc : 10.590666 10.590666 10.590666 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.125 0.375 -0 - 2 Ca 0.375 0.125 0.25 0 - 3 Ca 0.125 0.375 0.75 -0 - 4 Ca 0.25 0.875 0.625 -0 - 5 Ca 0.125 0.25 0.375 0 - 6 Ca 0.625 0.25 0.875 -0 - 7 Ca 0.75 0.625 0.875 0 - 8 Ca 0.875 0.75 0.625 0 - 9 Ca 0.875 0.625 0.25 -0 - 10 Ca 0.625 0.875 0.75 0 - 11 Ca 0.375 0.75 0.125 -0 - 12 V 0.5 0 0 1.883 - 13 V 0.5 0.5 0 1.884 - 14 V 0 0.5 0.5 1.884 - 15 V 0 0 0.5 1.885 - 16 V 0.5 0.5 0.5 1.885 - 17 V 0 0.5 0 1.884 - 18 V 0.5 0 0.5 1.884 - 19 V 0 0 0 1.886 - 20 Si 0.125 0.75 0.875 0.006 - 21 Si 0.875 0.25 0.125 0.006 - 22 Si 0.75 0.375 0.625 0.006 - 23 Si 0.125 0.875 0.25 0.006 - 24 Si 0.25 0.125 0.875 0.006 - 25 Si 0.375 0.625 0.75 0.006 - 26 Si 0.375 0.25 0.625 0.006 - 27 Si 0.875 0.125 0.75 0.006 - 28 Si 0.625 0.375 0.25 0.006 - 29 Si 0.75 0.875 0.125 0.006 - 30 Si 0.25 0.625 0.375 0.006 - 31 Si 0.625 0.75 0.375 0.006 - 32 O 0.587818 0.892108 0.383573 -0.008 - 33 O 0.383573 0.587818 0.892108 -0.006 - 34 O 0.295755 0.304291 0.912182 0.005 - 35 O 0.491464 0.607892 0.195709 -0.004 - 36 O 0.304291 0.892108 0.008536 -0.005 - 37 O 0.116427 0.008536 0.204245 0 - 38 O 0.383573 0.295755 0.491464 0.004 - 39 O 0.892108 0.383573 0.587818 -0.008 - 40 O 0.195709 0.204245 0.587818 0.003 - 41 O 0.491464 0.383573 0.295755 -0.008 - 42 O 0.892108 0.008536 0.304291 0.001 - 43 O 0.607892 0.912182 0.116427 -0.004 - 44 O 0.912182 0.116427 0.607892 -0.008 - 45 O 0.295755 0.491464 0.383573 -0.001 - 46 O 0.587818 0.195709 0.204245 0.004 - 47 O 0.204245 0.587818 0.195709 0.004 - 48 O 0.008536 0.304291 0.892108 0 - 49 O 0.912182 0.295755 0.304291 0.002 - 50 O 0.008536 0.204245 0.116427 0.004 - 51 O 0.804291 0.795755 0.412182 0.003 - 52 O 0.195709 0.491464 0.607892 0.001 - 53 O 0.607892 0.195709 0.491464 -0.002 - 54 O 0.204245 0.116427 0.008536 -0.008 - 55 O 0.116427 0.607892 0.912182 -0.009 - 56 O 0.412182 0.107892 0.616427 -0.008 - 57 O 0.616427 0.412182 0.107892 -0.006 - 58 O 0.704245 0.695709 0.087818 0.005 - 59 O 0.508536 0.392108 0.804291 -0.004 - 60 O 0.695709 0.107892 0.991464 -0.005 - 61 O 0.883573 0.991464 0.795755 0 - 62 O 0.616427 0.704245 0.508536 0.004 - 63 O 0.107892 0.616427 0.412182 -0.008 - 64 O 0.883573 0.392108 0.087818 -0.009 - 65 O 0.795755 0.883573 0.991464 -0.008 - 66 O 0.392108 0.804291 0.508536 -0.002 - 67 O 0.695709 0.087818 0.704245 0.005 - 68 O 0.804291 0.508536 0.392108 0.001 - 69 O 0.991464 0.795755 0.883573 0.004 - 70 O 0.087818 0.704245 0.695709 0.002 - 71 O 0.991464 0.695709 0.107892 0 - 72 O 0.795755 0.412182 0.804291 0.004 - 73 O 0.412182 0.804291 0.795755 0.004 - 74 O 0.704245 0.508536 0.616427 -0.001 - 75 O 0.087818 0.883573 0.392108 -0.008 - 76 O 0.392108 0.087818 0.883573 -0.004 - 77 O 0.107892 0.991464 0.695709 0.001 - 78 O 0.508536 0.616427 0.704245 -0.008 - 79 O 0.304291 0.912182 0.295755 0.005","# generated using pymatgen -data_Ca3V2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.59066623 -_cell_length_b 10.59066623 -_cell_length_c 10.59066623 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3V2(SiO4)3 -_chemical_formula_sum 'Ca12 V8 Si12 O48' -_cell_volume 914.42471002 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - V V12 1 0.50000000 0.00000000 0.00000000 1 - V V13 1 0.50000000 0.50000000 0.00000000 1 - V V14 1 0.00000000 0.50000000 0.50000000 1 - V V15 1 0.00000000 0.00000000 0.50000000 1 - V V16 1 0.50000000 0.50000000 0.50000000 1 - V V17 1 0.00000000 0.50000000 0.00000000 1 - V V18 1 0.50000000 0.00000000 0.50000000 1 - V V19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58781800 0.89210800 0.38357300 1 - O O33 1 0.38357300 0.58781800 0.89210800 1 - O O34 1 0.29575500 0.30429100 0.91218200 1 - O O35 1 0.49146400 0.60789200 0.19570900 1 - O O36 1 0.30429100 0.89210800 0.00853600 1 - O O37 1 0.11642700 0.00853600 0.20424500 1 - O O38 1 0.38357300 0.29575500 0.49146400 1 - O O39 1 0.89210800 0.38357300 0.58781800 1 - O O40 1 0.19570900 0.20424500 0.58781800 1 - O O41 1 0.49146400 0.38357300 0.29575500 1 - O O42 1 0.89210800 0.00853600 0.30429100 1 - O O43 1 0.60789200 0.91218200 0.11642700 1 - O O44 1 0.91218200 0.11642700 0.60789200 1 - O O45 1 0.29575500 0.49146400 0.38357300 1 - O O46 1 0.58781800 0.19570900 0.20424500 1 - O O47 1 0.20424500 0.58781800 0.19570900 1 - O O48 1 0.00853600 0.30429100 0.89210800 1 - O O49 1 0.91218200 0.29575500 0.30429100 1 - O O50 1 0.00853600 0.20424500 0.11642700 1 - O O51 1 0.80429100 0.79575500 0.41218200 1 - O O52 1 0.19570900 0.49146400 0.60789200 1 - O O53 1 0.60789200 0.19570900 0.49146400 1 - O O54 1 0.20424500 0.11642700 0.00853600 1 - O O55 1 0.11642700 0.60789200 0.91218200 1 - O O56 1 0.41218200 0.10789200 0.61642700 1 - O O57 1 0.61642700 0.41218200 0.10789200 1 - O O58 1 0.70424500 0.69570900 0.08781800 1 - O O59 1 0.50853600 0.39210800 0.80429100 1 - O O60 1 0.69570900 0.10789200 0.99146400 1 - O O61 1 0.88357300 0.99146400 0.79575500 1 - O O62 1 0.61642700 0.70424500 0.50853600 1 - O O63 1 0.10789200 0.61642700 0.41218200 1 - O O64 1 0.88357300 0.39210800 0.08781800 1 - O O65 1 0.79575500 0.88357300 0.99146400 1 - O O66 1 0.39210800 0.80429100 0.50853600 1 - O O67 1 0.69570900 0.08781800 0.70424500 1 - O O68 1 0.80429100 0.50853600 0.39210800 1 - O O69 1 0.99146400 0.79575500 0.88357300 1 - O O70 1 0.08781800 0.70424500 0.69570900 1 - O O71 1 0.99146400 0.69570900 0.10789200 1 - O O72 1 0.79575500 0.41218200 0.80429100 1 - O O73 1 0.41218200 0.80429100 0.79575500 1 - O O74 1 0.70424500 0.50853600 0.61642700 1 - O O75 1 0.08781800 0.88357300 0.39210800 1 - O O76 1 0.39210800 0.08781800 0.88357300 1 - O O77 1 0.10789200 0.99146400 0.69570900 1 - O O78 1 0.50853600 0.61642700 0.70424500 1 - O O79 1 0.30429100 0.91218200 0.29575500 1 -" -Ca3Cu2(SiO4)3,mp-1163936,Ia-3d,[],0.08913320870833807,{'tags': []},"Full Formula (Ca12 Cu8 Si12 O48) -Reduced Formula: Ca3Cu2(SiO4)3 -abc : 10.528125 10.528125 10.528125 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.75 0.125 0.375 0 - 1 Ca 0.25 0.375 0.125 0 - 2 Ca 0.125 0.25 0.375 0 - 3 Ca 0.375 0.75 0.125 0 - 4 Ca 0.75 0.625 0.875 0 - 5 Ca 0.125 0.375 0.75 0 - 6 Ca 0.625 0.875 0.75 0 - 7 Ca 0.25 0.875 0.625 0 - 8 Ca 0.875 0.625 0.25 0 - 9 Ca 0.625 0.25 0.875 0 - 10 Ca 0.875 0.75 0.625 0 - 11 Ca 0.375 0.125 0.25 0 - 12 Cu 0 0 0 0.933 - 13 Cu 0.5 0 0 0.933 - 14 Cu 0 0.5 0 0.933 - 15 Cu 0.5 0.5 0 0.933 - 16 Cu 0 0.5 0.5 0.933 - 17 Cu 0.5 0 0.5 0.933 - 18 Cu 0.5 0.5 0.5 0.933 - 19 Cu 0 0 0.5 0.933 - 20 Si 0.125 0.875 0.25 0.006 - 21 Si 0.875 0.125 0.75 0.006 - 22 Si 0.25 0.625 0.375 0.006 - 23 Si 0.375 0.25 0.625 0.006 - 24 Si 0.75 0.875 0.125 0.006 - 25 Si 0.125 0.75 0.875 0.006 - 26 Si 0.375 0.625 0.75 0.006 - 27 Si 0.625 0.75 0.375 0.006 - 28 Si 0.875 0.25 0.125 0.006 - 29 Si 0.25 0.125 0.875 0.006 - 30 Si 0.75 0.375 0.625 0.006 - 31 Si 0.625 0.375 0.25 0.006 - 32 O 0.490082 0.383043 0.295605 0.152 - 33 O 0.305523 0.892961 0.009918 0.152 - 34 O 0.607039 0.912563 0.116957 0.152 - 35 O 0.587437 0.194477 0.204395 0.152 - 36 O 0.116957 0.009918 0.204395 0.152 - 37 O 0.194477 0.204394 0.587437 0.152 - 38 O 0.194477 0.490082 0.607039 0.152 - 39 O 0.204394 0.587437 0.194477 0.152 - 40 O 0.383043 0.587437 0.892961 0.152 - 41 O 0.912563 0.295605 0.305523 0.152 - 42 O 0.295605 0.305523 0.912563 0.152 - 43 O 0.204395 0.116957 0.009918 0.152 - 44 O 0.490082 0.607039 0.194477 0.152 - 45 O 0.892961 0.383043 0.587437 0.152 - 46 O 0.009918 0.204395 0.116957 0.152 - 47 O 0.607039 0.194477 0.490082 0.152 - 48 O 0.587437 0.892961 0.383043 0.152 - 49 O 0.009918 0.305523 0.892961 0.152 - 50 O 0.912563 0.116957 0.607039 0.152 - 51 O 0.616957 0.412563 0.107039 0.152 - 52 O 0.116957 0.607039 0.912563 0.152 - 53 O 0.295606 0.490082 0.383043 0.152 - 54 O 0.892961 0.009918 0.305523 0.152 - 55 O 0.305523 0.912563 0.295605 0.152 - 56 O 0.509918 0.616957 0.704395 0.152 - 57 O 0.694477 0.107039 0.990082 0.152 - 58 O 0.392961 0.087437 0.883043 0.152 - 59 O 0.412563 0.805523 0.795605 0.152 - 60 O 0.883043 0.990082 0.795605 0.152 - 61 O 0.805523 0.795605 0.412563 0.152 - 62 O 0.805523 0.509918 0.392961 0.152 - 63 O 0.795605 0.412563 0.805523 0.152 - 64 O 0.694477 0.087437 0.704395 0.152 - 65 O 0.107039 0.990082 0.694477 0.152 - 66 O 0.704395 0.509918 0.616957 0.152 - 67 O 0.616957 0.704395 0.509918 0.152 - 68 O 0.883043 0.392961 0.087437 0.152 - 69 O 0.087437 0.883043 0.392961 0.152 - 70 O 0.990082 0.694477 0.107039 0.152 - 71 O 0.412563 0.107039 0.616957 0.152 - 72 O 0.392961 0.805523 0.509918 0.152 - 73 O 0.990082 0.795605 0.883043 0.152 - 74 O 0.107039 0.616957 0.412563 0.152 - 75 O 0.509918 0.392961 0.805523 0.152 - 76 O 0.795605 0.883043 0.990082 0.152 - 77 O 0.704395 0.694477 0.087437 0.152 - 78 O 0.087437 0.704394 0.694477 0.152 - 79 O 0.383043 0.295605 0.490082 0.152","# generated using pymatgen -data_Ca3Cu2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.52812534 -_cell_length_b 10.52812534 -_cell_length_c 10.52812534 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Cu2(SiO4)3 -_chemical_formula_sum 'Ca12 Cu8 Si12 O48' -_cell_volume 898.32037371 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca1 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca2 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca3 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca4 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca5 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca6 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca7 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca8 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca10 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca11 1 0.37500000 0.12500000 0.25000000 1 - Cu Cu12 1 0.00000000 0.00000000 0.00000000 1 - Cu Cu13 1 0.50000000 0.00000000 0.00000000 1 - Cu Cu14 1 0.00000000 0.50000000 0.00000000 1 - Cu Cu15 1 0.50000000 0.50000000 0.00000000 1 - Cu Cu16 1 0.00000000 0.50000000 0.50000000 1 - Cu Cu17 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu18 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu19 1 0.00000000 0.00000000 0.50000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.49008200 0.38304300 0.29560500 1 - O O33 1 0.30552300 0.89296100 0.00991800 1 - O O34 1 0.60703900 0.91256300 0.11695700 1 - O O35 1 0.58743700 0.19447700 0.20439500 1 - O O36 1 0.11695700 0.00991800 0.20439500 1 - O O37 1 0.19447700 0.20439400 0.58743700 1 - O O38 1 0.19447700 0.49008200 0.60703900 1 - O O39 1 0.20439400 0.58743700 0.19447700 1 - O O40 1 0.38304300 0.58743700 0.89296100 1 - O O41 1 0.91256300 0.29560500 0.30552300 1 - O O42 1 0.29560500 0.30552300 0.91256300 1 - O O43 1 0.20439500 0.11695700 0.00991800 1 - O O44 1 0.49008200 0.60703900 0.19447700 1 - O O45 1 0.89296100 0.38304300 0.58743700 1 - O O46 1 0.00991800 0.20439500 0.11695700 1 - O O47 1 0.60703900 0.19447700 0.49008200 1 - O O48 1 0.58743700 0.89296100 0.38304300 1 - O O49 1 0.00991800 0.30552300 0.89296100 1 - O O50 1 0.91256300 0.11695700 0.60703900 1 - O O51 1 0.61695700 0.41256300 0.10703900 1 - O O52 1 0.11695700 0.60703900 0.91256300 1 - O O53 1 0.29560600 0.49008200 0.38304300 1 - O O54 1 0.89296100 0.00991800 0.30552300 1 - O O55 1 0.30552300 0.91256300 0.29560500 1 - O O56 1 0.50991800 0.61695700 0.70439500 1 - O O57 1 0.69447700 0.10703900 0.99008200 1 - O O58 1 0.39296100 0.08743700 0.88304300 1 - O O59 1 0.41256300 0.80552300 0.79560500 1 - O O60 1 0.88304300 0.99008200 0.79560500 1 - O O61 1 0.80552300 0.79560500 0.41256300 1 - O O62 1 0.80552300 0.50991800 0.39296100 1 - O O63 1 0.79560500 0.41256300 0.80552300 1 - O O64 1 0.69447700 0.08743700 0.70439500 1 - O O65 1 0.10703900 0.99008200 0.69447700 1 - O O66 1 0.70439500 0.50991800 0.61695700 1 - O O67 1 0.61695700 0.70439500 0.50991800 1 - O O68 1 0.88304300 0.39296100 0.08743700 1 - O O69 1 0.08743700 0.88304300 0.39296100 1 - O O70 1 0.99008200 0.69447700 0.10703900 1 - O O71 1 0.41256300 0.10703900 0.61695700 1 - O O72 1 0.39296100 0.80552300 0.50991800 1 - O O73 1 0.99008200 0.79560500 0.88304300 1 - O O74 1 0.10703900 0.61695700 0.41256300 1 - O O75 1 0.50991800 0.39296100 0.80552300 1 - O O76 1 0.79560500 0.88304300 0.99008200 1 - O O77 1 0.70439500 0.69447700 0.08743700 1 - O O78 1 0.08743700 0.70439400 0.69447700 1 - O O79 1 0.38304300 0.29560500 0.49008200 1 -" -Mg3Si3(SbO6)2,mp-1163940,Ia-3d,[],0.2652251153749976,{'tags': []},"Full Formula (Mg12 Si12 Sb8 O48) -Reduced Formula: Mg3Si3(SbO6)2 -abc : 10.679013 10.679013 10.679013 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0 - 1 Mg 0.75 0.125 0.375 0 - 2 Mg 0.375 0.125 0.25 0 - 3 Mg 0.125 0.375 0.75 0 - 4 Mg 0.25 0.875 0.625 0 - 5 Mg 0.125 0.25 0.375 0 - 6 Mg 0.625 0.25 0.875 0 - 7 Mg 0.75 0.625 0.875 0 - 8 Mg 0.875 0.75 0.625 0 - 9 Mg 0.875 0.625 0.25 0 - 10 Mg 0.625 0.875 0.75 0 - 11 Mg 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 0 - 13 Si 0.875 0.25 0.125 0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 0 - 16 Si 0.25 0.125 0.875 0 - 17 Si 0.375 0.625 0.75 0 - 18 Si 0.375 0.25 0.625 0 - 19 Si 0.875 0.125 0.75 0 - 20 Si 0.625 0.375 0.25 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 0 - 24 Sb 0.5 0 0 0 - 25 Sb 0.5 0.5 0 0 - 26 Sb 0 0.5 0.5 0 - 27 Sb 0 0 0.5 0 - 28 Sb 0.5 0.5 0.5 0 - 29 Sb 0 0.5 0 0 - 30 Sb 0.5 0 0.5 0 - 31 Sb 0 0 0 0 - 32 O 0.599498 0.894029 0.369086 -0 - 33 O 0.369086 0.599498 0.894029 -0 - 34 O 0.269588 0.294532 0.900502 -0 - 35 O 0.475056 0.605971 0.205468 -0 - 36 O 0.294532 0.894029 0.024944 -0 - 37 O 0.130915 0.024944 0.230412 -0 - 38 O 0.369086 0.269588 0.475056 -0 - 39 O 0.894029 0.369086 0.599498 -0 - 40 O 0.205468 0.230412 0.599498 -0 - 41 O 0.475056 0.369085 0.269588 -0 - 42 O 0.894029 0.024944 0.294532 -0 - 43 O 0.605971 0.900502 0.130914 -0 - 44 O 0.900502 0.130914 0.605971 -0 - 45 O 0.269588 0.475056 0.369085 -0 - 46 O 0.599498 0.205468 0.230412 -0 - 47 O 0.230412 0.599498 0.205468 -0 - 48 O 0.024944 0.294532 0.894029 -0 - 49 O 0.900502 0.269588 0.294532 -0 - 50 O 0.024944 0.230412 0.130915 -0 - 51 O 0.794532 0.769588 0.400502 -0 - 52 O 0.205468 0.475056 0.605971 -0 - 53 O 0.605971 0.205468 0.475056 -0 - 54 O 0.230412 0.130915 0.024944 -0 - 55 O 0.130915 0.605971 0.900502 -0 - 56 O 0.400502 0.105971 0.630914 -0 - 57 O 0.630914 0.400502 0.105971 -0 - 58 O 0.730412 0.705468 0.099498 -0 - 59 O 0.524944 0.394029 0.794532 -0 - 60 O 0.705468 0.105971 0.975056 -0 - 61 O 0.869086 0.975056 0.769588 -0 - 62 O 0.630914 0.730412 0.524944 -0 - 63 O 0.105971 0.630914 0.400502 -0 - 64 O 0.869085 0.394029 0.099498 -0 - 65 O 0.769588 0.869085 0.975056 -0 - 66 O 0.394029 0.794532 0.524944 -0 - 67 O 0.705468 0.099498 0.730412 -0 - 68 O 0.794532 0.524944 0.394029 -0 - 69 O 0.975056 0.769588 0.869086 -0 - 70 O 0.099498 0.730412 0.705468 -0 - 71 O 0.975056 0.705468 0.105971 -0 - 72 O 0.769588 0.400502 0.794532 -0 - 73 O 0.400502 0.794532 0.769588 -0 - 74 O 0.730412 0.524944 0.630914 -0 - 75 O 0.099498 0.869085 0.394029 -0 - 76 O 0.394029 0.099498 0.869085 -0 - 77 O 0.105971 0.975056 0.705468 -0 - 78 O 0.524944 0.630914 0.730412 -0 - 79 O 0.294532 0.900502 0.269588 -0","# generated using pymatgen -data_Mg3Si3(SbO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.67901295 -_cell_length_b 10.67901295 -_cell_length_c 10.67901295 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Si3(SbO6)2 -_chemical_formula_sum 'Mg12 Si12 Sb8 O48' -_cell_volume 937.50037140 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Sb Sb24 1 0.50000000 0.00000000 0.00000000 1 - Sb Sb25 1 0.50000000 0.50000000 0.00000000 1 - Sb Sb26 1 0.00000000 0.50000000 0.50000000 1 - Sb Sb27 1 0.00000000 0.00000000 0.50000000 1 - Sb Sb28 1 0.50000000 0.50000000 0.50000000 1 - Sb Sb29 1 0.00000000 0.50000000 0.00000000 1 - Sb Sb30 1 0.50000000 0.00000000 0.50000000 1 - Sb Sb31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59949800 0.89402900 0.36908600 1 - O O33 1 0.36908600 0.59949800 0.89402900 1 - O O34 1 0.26958800 0.29453200 0.90050200 1 - O O35 1 0.47505600 0.60597100 0.20546800 1 - O O36 1 0.29453200 0.89402900 0.02494400 1 - O O37 1 0.13091500 0.02494400 0.23041200 1 - O O38 1 0.36908600 0.26958800 0.47505600 1 - O O39 1 0.89402900 0.36908600 0.59949800 1 - O O40 1 0.20546800 0.23041200 0.59949800 1 - O O41 1 0.47505600 0.36908500 0.26958800 1 - O O42 1 0.89402900 0.02494400 0.29453200 1 - O O43 1 0.60597100 0.90050200 0.13091400 1 - O O44 1 0.90050200 0.13091400 0.60597100 1 - O O45 1 0.26958800 0.47505600 0.36908500 1 - O O46 1 0.59949800 0.20546800 0.23041200 1 - O O47 1 0.23041200 0.59949800 0.20546800 1 - O O48 1 0.02494400 0.29453200 0.89402900 1 - O O49 1 0.90050200 0.26958800 0.29453200 1 - O O50 1 0.02494400 0.23041200 0.13091500 1 - O O51 1 0.79453200 0.76958800 0.40050200 1 - O O52 1 0.20546800 0.47505600 0.60597100 1 - O O53 1 0.60597100 0.20546800 0.47505600 1 - O O54 1 0.23041200 0.13091500 0.02494400 1 - O O55 1 0.13091500 0.60597100 0.90050200 1 - O O56 1 0.40050200 0.10597100 0.63091400 1 - O O57 1 0.63091400 0.40050200 0.10597100 1 - O O58 1 0.73041200 0.70546800 0.09949800 1 - O O59 1 0.52494400 0.39402900 0.79453200 1 - O O60 1 0.70546800 0.10597100 0.97505600 1 - O O61 1 0.86908600 0.97505600 0.76958800 1 - O O62 1 0.63091400 0.73041200 0.52494400 1 - O O63 1 0.10597100 0.63091400 0.40050200 1 - O O64 1 0.86908500 0.39402900 0.09949800 1 - O O65 1 0.76958800 0.86908500 0.97505600 1 - O O66 1 0.39402900 0.79453200 0.52494400 1 - O O67 1 0.70546800 0.09949800 0.73041200 1 - O O68 1 0.79453200 0.52494400 0.39402900 1 - O O69 1 0.97505600 0.76958800 0.86908600 1 - O O70 1 0.09949800 0.73041200 0.70546800 1 - O O71 1 0.97505600 0.70546800 0.10597100 1 - O O72 1 0.76958800 0.40050200 0.79453200 1 - O O73 1 0.40050200 0.79453200 0.76958800 1 - O O74 1 0.73041200 0.52494400 0.63091400 1 - O O75 1 0.09949800 0.86908500 0.39402900 1 - O O76 1 0.39402900 0.09949800 0.86908500 1 - O O77 1 0.10597100 0.97505600 0.70546800 1 - O O78 1 0.52494400 0.63091400 0.73041200 1 - O O79 1 0.29453200 0.90050200 0.26958800 1 -" -Al2V3(SiO4)3,mp-1163942,Ia-3d,[],0.09240417306250315,{'tags': []},"Full Formula (Al8 V12 Si12 O48) -Reduced Formula: Al2V3(SiO4)3 -abc : 10.184150 10.184150 10.184150 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0 0.003 - 1 Al 0.5 0 0 0.003 - 2 Al 0.5 0.5 0 0.003 - 3 Al 0 0.5 0.5 0.003 - 4 Al 0 0 0.5 0.003 - 5 Al 0.5 0.5 0.5 0.003 - 6 Al 0 0.5 0 0.003 - 7 Al 0.5 0 0.5 0.003 - 8 V 0.875 0.75 0.625 2.739 - 9 V 0.875 0.625 0.25 2.739 - 10 V 0.625 0.875 0.75 2.739 - 11 V 0.25 0.875 0.625 2.739 - 12 V 0.75 0.625 0.875 2.739 - 13 V 0.625 0.25 0.875 2.739 - 14 V 0.125 0.25 0.375 2.739 - 15 V 0.125 0.375 0.75 2.739 - 16 V 0.375 0.125 0.25 2.739 - 17 V 0.75 0.125 0.375 2.739 - 18 V 0.25 0.375 0.125 2.739 - 19 V 0.375 0.75 0.125 2.739 - 20 Si 0.125 0.75 0.875 0.009 - 21 Si 0.75 0.875 0.125 0.009 - 22 Si 0.25 0.625 0.375 0.009 - 23 Si 0.625 0.75 0.375 0.009 - 24 Si 0.875 0.125 0.75 0.009 - 25 Si 0.375 0.25 0.625 0.009 - 26 Si 0.375 0.625 0.75 0.009 - 27 Si 0.25 0.125 0.875 0.009 - 28 Si 0.625 0.375 0.25 0.009 - 29 Si 0.125 0.875 0.25 0.009 - 30 Si 0.75 0.375 0.625 0.009 - 31 Si 0.875 0.25 0.125 0.009 - 32 O 0.581388 0.894087 0.381758 0.005 - 33 O 0.381758 0.581388 0.894087 0.005 - 34 O 0.300369 0.312699 0.918612 0.005 - 35 O 0.48767 0.605913 0.187301 0.005 - 36 O 0.312699 0.894087 0.01233 0.005 - 37 O 0.118242 0.01233 0.199631 0.005 - 38 O 0.381758 0.300369 0.48767 0.005 - 39 O 0.894087 0.381758 0.581388 0.005 - 40 O 0.187301 0.199631 0.581388 0.005 - 41 O 0.48767 0.381758 0.300369 0.005 - 42 O 0.894087 0.01233 0.312699 0.005 - 43 O 0.605913 0.918612 0.118242 0.005 - 44 O 0.918612 0.118242 0.605913 0.005 - 45 O 0.300369 0.48767 0.381758 0.005 - 46 O 0.581388 0.187301 0.199631 0.005 - 47 O 0.199631 0.581388 0.187301 0.005 - 48 O 0.01233 0.312699 0.894087 0.005 - 49 O 0.918612 0.300369 0.312699 0.005 - 50 O 0.01233 0.199631 0.118242 0.005 - 51 O 0.812699 0.800369 0.418612 0.005 - 52 O 0.312699 0.918612 0.300369 0.005 - 53 O 0.605913 0.187301 0.48767 0.005 - 54 O 0.199631 0.118242 0.01233 0.005 - 55 O 0.118242 0.605913 0.918612 0.005 - 56 O 0.418612 0.105913 0.618242 0.005 - 57 O 0.618242 0.418612 0.105913 0.005 - 58 O 0.699631 0.687301 0.081388 0.005 - 59 O 0.51233 0.394087 0.812699 0.005 - 60 O 0.687301 0.105913 0.98767 0.005 - 61 O 0.881758 0.98767 0.800369 0.005 - 62 O 0.618242 0.699631 0.51233 0.005 - 63 O 0.105913 0.618242 0.418612 0.005 - 64 O 0.881758 0.394087 0.081388 0.005 - 65 O 0.800369 0.881758 0.98767 0.005 - 66 O 0.394087 0.812699 0.51233 0.005 - 67 O 0.687301 0.081388 0.699631 0.005 - 68 O 0.812699 0.51233 0.394087 0.005 - 69 O 0.98767 0.800369 0.881758 0.005 - 70 O 0.081388 0.699631 0.687301 0.005 - 71 O 0.98767 0.687301 0.105913 0.005 - 72 O 0.800369 0.418612 0.812699 0.005 - 73 O 0.418612 0.812699 0.800369 0.005 - 74 O 0.699631 0.51233 0.618242 0.005 - 75 O 0.081388 0.881758 0.394087 0.005 - 76 O 0.394087 0.081388 0.881758 0.005 - 77 O 0.105913 0.98767 0.687301 0.005 - 78 O 0.51233 0.618242 0.699631 0.005 - 79 O 0.187301 0.48767 0.605913 0.005","# generated using pymatgen -data_Al2V3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.18415044 -_cell_length_b 10.18415044 -_cell_length_c 10.18415044 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2V3(SiO4)3 -_chemical_formula_sum 'Al8 V12 Si12 O48' -_cell_volume 813.11603932 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.00000000 1 - Al Al1 1 0.50000000 0.00000000 0.00000000 1 - Al Al2 1 0.50000000 0.50000000 0.00000000 1 - Al Al3 1 0.00000000 0.50000000 0.50000000 1 - Al Al4 1 0.00000000 0.00000000 0.50000000 1 - Al Al5 1 0.50000000 0.50000000 0.50000000 1 - Al Al6 1 0.00000000 0.50000000 0.00000000 1 - Al Al7 1 0.50000000 0.00000000 0.50000000 1 - V V8 1 0.87500000 0.75000000 0.62500000 1 - V V9 1 0.87500000 0.62500000 0.25000000 1 - V V10 1 0.62500000 0.87500000 0.75000000 1 - V V11 1 0.25000000 0.87500000 0.62500000 1 - V V12 1 0.75000000 0.62500000 0.87500000 1 - V V13 1 0.62500000 0.25000000 0.87500000 1 - V V14 1 0.12500000 0.25000000 0.37500000 1 - V V15 1 0.12500000 0.37500000 0.75000000 1 - V V16 1 0.37500000 0.12500000 0.25000000 1 - V V17 1 0.75000000 0.12500000 0.37500000 1 - V V18 1 0.25000000 0.37500000 0.12500000 1 - V V19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.87500000 0.12500000 0.75000000 1 - Si Si25 1 0.37500000 0.25000000 0.62500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.25000000 0.12500000 0.87500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.12500000 0.87500000 0.25000000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.87500000 0.25000000 0.12500000 1 - O O32 1 0.58138800 0.89408700 0.38175800 1 - O O33 1 0.38175800 0.58138800 0.89408700 1 - O O34 1 0.30036900 0.31269900 0.91861200 1 - O O35 1 0.48767000 0.60591300 0.18730100 1 - O O36 1 0.31269900 0.89408700 0.01233000 1 - O O37 1 0.11824200 0.01233000 0.19963100 1 - O O38 1 0.38175800 0.30036900 0.48767000 1 - O O39 1 0.89408700 0.38175800 0.58138800 1 - O O40 1 0.18730100 0.19963100 0.58138800 1 - O O41 1 0.48767000 0.38175800 0.30036900 1 - O O42 1 0.89408700 0.01233000 0.31269900 1 - O O43 1 0.60591300 0.91861200 0.11824200 1 - O O44 1 0.91861200 0.11824200 0.60591300 1 - O O45 1 0.30036900 0.48767000 0.38175800 1 - O O46 1 0.58138800 0.18730100 0.19963100 1 - O O47 1 0.19963100 0.58138800 0.18730100 1 - O O48 1 0.01233000 0.31269900 0.89408700 1 - O O49 1 0.91861200 0.30036900 0.31269900 1 - O O50 1 0.01233000 0.19963100 0.11824200 1 - O O51 1 0.81269900 0.80036900 0.41861200 1 - O O52 1 0.31269900 0.91861200 0.30036900 1 - O O53 1 0.60591300 0.18730100 0.48767000 1 - O O54 1 0.19963100 0.11824200 0.01233000 1 - O O55 1 0.11824200 0.60591300 0.91861200 1 - O O56 1 0.41861200 0.10591300 0.61824200 1 - O O57 1 0.61824200 0.41861200 0.10591300 1 - O O58 1 0.69963100 0.68730100 0.08138800 1 - O O59 1 0.51233000 0.39408700 0.81269900 1 - O O60 1 0.68730100 0.10591300 0.98767000 1 - O O61 1 0.88175800 0.98767000 0.80036900 1 - O O62 1 0.61824200 0.69963100 0.51233000 1 - O O63 1 0.10591300 0.61824200 0.41861200 1 - O O64 1 0.88175800 0.39408700 0.08138800 1 - O O65 1 0.80036900 0.88175800 0.98767000 1 - O O66 1 0.39408700 0.81269900 0.51233000 1 - O O67 1 0.68730100 0.08138800 0.69963100 1 - O O68 1 0.81269900 0.51233000 0.39408700 1 - O O69 1 0.98767000 0.80036900 0.88175800 1 - O O70 1 0.08138800 0.69963100 0.68730100 1 - O O71 1 0.98767000 0.68730100 0.10591300 1 - O O72 1 0.80036900 0.41861200 0.81269900 1 - O O73 1 0.41861200 0.81269900 0.80036900 1 - O O74 1 0.69963100 0.51233000 0.61824200 1 - O O75 1 0.08138800 0.88175800 0.39408700 1 - O O76 1 0.39408700 0.08138800 0.88175800 1 - O O77 1 0.10591300 0.98767000 0.68730100 1 - O O78 1 0.51233000 0.61824200 0.69963100 1 - O O79 1 0.18730100 0.48767000 0.60591300 1 -" -Zn3Si3(WO6)2,mp-1163950,Ia-3d,[],0.22522992824999744,{'tags': []},"Full Formula (Zn12 Si12 W8 O48) -Reduced Formula: Zn3Si3(WO6)2 -abc : 10.511241 10.511241 10.511241 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 0.019 - 1 Zn 0.75 0.125 0.375 0.019 - 2 Zn 0.375 0.125 0.25 0.019 - 3 Zn 0.125 0.375 0.75 0.019 - 4 Zn 0.25 0.875 0.625 0.019 - 5 Zn 0.125 0.25 0.375 0.019 - 6 Zn 0.625 0.25 0.875 0.019 - 7 Zn 0.75 0.625 0.875 0.019 - 8 Zn 0.875 0.75 0.625 0.019 - 9 Zn 0.875 0.625 0.25 0.019 - 10 Zn 0.625 0.875 0.75 0.019 - 11 Zn 0.375 0.75 0.125 0.019 - 12 Si 0.125 0.75 0.875 0.014 - 13 Si 0.875 0.25 0.125 0.014 - 14 Si 0.75 0.375 0.625 0.014 - 15 Si 0.125 0.875 0.25 0.014 - 16 Si 0.25 0.125 0.875 0.014 - 17 Si 0.375 0.625 0.75 0.014 - 18 Si 0.375 0.25 0.625 0.014 - 19 Si 0.875 0.125 0.75 0.014 - 20 Si 0.625 0.375 0.25 0.014 - 21 Si 0.75 0.875 0.125 0.014 - 22 Si 0.25 0.625 0.375 0.014 - 23 Si 0.625 0.75 0.375 0.014 - 24 W 0.5 0 0 2.75 - 25 W 0.5 0.5 0 2.75 - 26 W 0 0.5 0.5 2.75 - 27 W 0 0 0.5 2.75 - 28 W 0.5 0.5 0.5 2.75 - 29 W 0 0.5 0 2.75 - 30 W 0.5 0 0.5 2.75 - 31 W 0 0 0 2.75 - 32 O 0.592717 0.893771 0.373241 0.01 - 33 O 0.373241 0.592717 0.893771 0.01 - 34 O 0.280524 0.301054 0.907283 0.01 - 35 O 0.47947 0.606229 0.198946 0.01 - 36 O 0.301054 0.893771 0.02053 0.01 - 37 O 0.126759 0.02053 0.219476 0.01 - 38 O 0.373241 0.280524 0.47947 0.01 - 39 O 0.893771 0.373241 0.592717 0.01 - 40 O 0.198946 0.219476 0.592717 0.01 - 41 O 0.47947 0.373241 0.280524 0.01 - 42 O 0.893771 0.02053 0.301054 0.01 - 43 O 0.606229 0.907283 0.126759 0.01 - 44 O 0.907283 0.126759 0.606229 0.01 - 45 O 0.280524 0.47947 0.373241 0.01 - 46 O 0.592717 0.198946 0.219476 0.01 - 47 O 0.219476 0.592717 0.198946 0.01 - 48 O 0.02053 0.301054 0.893771 0.01 - 49 O 0.907283 0.280524 0.301054 0.01 - 50 O 0.02053 0.219476 0.126759 0.01 - 51 O 0.801054 0.780524 0.407283 0.01 - 52 O 0.198946 0.47947 0.606229 0.01 - 53 O 0.606229 0.198946 0.47947 0.01 - 54 O 0.219476 0.126759 0.02053 0.01 - 55 O 0.126759 0.606229 0.907283 0.01 - 56 O 0.407283 0.106229 0.626759 0.01 - 57 O 0.626759 0.407283 0.106229 0.01 - 58 O 0.719476 0.698946 0.092717 0.01 - 59 O 0.52053 0.393771 0.801054 0.01 - 60 O 0.698946 0.106229 0.97947 0.01 - 61 O 0.873241 0.97947 0.780524 0.01 - 62 O 0.626759 0.719476 0.52053 0.01 - 63 O 0.106229 0.626759 0.407283 0.01 - 64 O 0.873241 0.393771 0.092717 0.01 - 65 O 0.780524 0.873241 0.97947 0.01 - 66 O 0.393771 0.801054 0.52053 0.01 - 67 O 0.698946 0.092717 0.719476 0.01 - 68 O 0.801054 0.52053 0.393771 0.01 - 69 O 0.97947 0.780524 0.873241 0.01 - 70 O 0.092717 0.719476 0.698946 0.01 - 71 O 0.97947 0.698946 0.106229 0.01 - 72 O 0.780524 0.407283 0.801054 0.01 - 73 O 0.407283 0.801054 0.780524 0.01 - 74 O 0.719476 0.52053 0.626759 0.01 - 75 O 0.092717 0.873241 0.393771 0.01 - 76 O 0.393771 0.092717 0.873241 0.01 - 77 O 0.106229 0.97947 0.698946 0.01 - 78 O 0.52053 0.626759 0.719476 0.01 - 79 O 0.301054 0.907283 0.280524 0.01","# generated using pymatgen -data_Zn3Si3(WO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.51124131 -_cell_length_b 10.51124131 -_cell_length_c 10.51124131 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Si3(WO6)2 -_chemical_formula_sum 'Zn12 Si12 W8 O48' -_cell_volume 894.00537234 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - W W24 1 0.50000000 0.00000000 0.00000000 1 - W W25 1 0.50000000 0.50000000 0.00000000 1 - W W26 1 0.00000000 0.50000000 0.50000000 1 - W W27 1 0.00000000 0.00000000 0.50000000 1 - W W28 1 0.50000000 0.50000000 0.50000000 1 - W W29 1 0.00000000 0.50000000 0.00000000 1 - W W30 1 0.50000000 0.00000000 0.50000000 1 - W W31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59271700 0.89377100 0.37324100 1 - O O33 1 0.37324100 0.59271700 0.89377100 1 - O O34 1 0.28052400 0.30105400 0.90728300 1 - O O35 1 0.47947000 0.60622900 0.19894600 1 - O O36 1 0.30105400 0.89377100 0.02053000 1 - O O37 1 0.12675900 0.02053000 0.21947600 1 - O O38 1 0.37324100 0.28052400 0.47947000 1 - O O39 1 0.89377100 0.37324100 0.59271700 1 - O O40 1 0.19894600 0.21947600 0.59271700 1 - O O41 1 0.47947000 0.37324100 0.28052400 1 - O O42 1 0.89377100 0.02053000 0.30105400 1 - O O43 1 0.60622900 0.90728300 0.12675900 1 - O O44 1 0.90728300 0.12675900 0.60622900 1 - O O45 1 0.28052400 0.47947000 0.37324100 1 - O O46 1 0.59271700 0.19894600 0.21947600 1 - O O47 1 0.21947600 0.59271700 0.19894600 1 - O O48 1 0.02053000 0.30105400 0.89377100 1 - O O49 1 0.90728300 0.28052400 0.30105400 1 - O O50 1 0.02053000 0.21947600 0.12675900 1 - O O51 1 0.80105400 0.78052400 0.40728300 1 - O O52 1 0.19894600 0.47947000 0.60622900 1 - O O53 1 0.60622900 0.19894600 0.47947000 1 - O O54 1 0.21947600 0.12675900 0.02053000 1 - O O55 1 0.12675900 0.60622900 0.90728300 1 - O O56 1 0.40728300 0.10622900 0.62675900 1 - O O57 1 0.62675900 0.40728300 0.10622900 1 - O O58 1 0.71947600 0.69894600 0.09271700 1 - O O59 1 0.52053000 0.39377100 0.80105400 1 - O O60 1 0.69894600 0.10622900 0.97947000 1 - O O61 1 0.87324100 0.97947000 0.78052400 1 - O O62 1 0.62675900 0.71947600 0.52053000 1 - O O63 1 0.10622900 0.62675900 0.40728300 1 - O O64 1 0.87324100 0.39377100 0.09271700 1 - O O65 1 0.78052400 0.87324100 0.97947000 1 - O O66 1 0.39377100 0.80105400 0.52053000 1 - O O67 1 0.69894600 0.09271700 0.71947600 1 - O O68 1 0.80105400 0.52053000 0.39377100 1 - O O69 1 0.97947000 0.78052400 0.87324100 1 - O O70 1 0.09271700 0.71947600 0.69894600 1 - O O71 1 0.97947000 0.69894600 0.10622900 1 - O O72 1 0.78052400 0.40728300 0.80105400 1 - O O73 1 0.40728300 0.80105400 0.78052400 1 - O O74 1 0.71947600 0.52053000 0.62675900 1 - O O75 1 0.09271700 0.87324100 0.39377100 1 - O O76 1 0.39377100 0.09271700 0.87324100 1 - O O77 1 0.10622900 0.97947000 0.69894600 1 - O O78 1 0.52053000 0.62675900 0.71947600 1 - O O79 1 0.30105400 0.90728300 0.28052400 1 -" -Ca3Si3(MoO6)2,mp-1170750,Ia-3d,[],0.0,{'tags': []},"Full Formula (Ca12 Si12 Mo8 O48) -Reduced Formula: Ca3Si3(MoO6)2 -abc : 10.785972 10.785972 10.785972 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.75 0.125 0.375 -0.001 - 1 Ca 0.25 0.375 0.125 -0.001 - 2 Ca 0.125 0.25 0.375 -0.001 - 3 Ca 0.375 0.75 0.125 -0.001 - 4 Ca 0.75 0.625 0.875 -0.001 - 5 Ca 0.125 0.375 0.75 -0.001 - 6 Ca 0.625 0.875 0.75 -0.001 - 7 Ca 0.25 0.875 0.625 -0.001 - 8 Ca 0.875 0.625 0.25 -0.001 - 9 Ca 0.625 0.25 0.875 -0.001 - 10 Ca 0.875 0.75 0.625 -0.001 - 11 Ca 0.375 0.125 0.25 -0.001 - 12 Si 0.125 0.875 0.25 0.013 - 13 Si 0.875 0.125 0.75 0.013 - 14 Si 0.25 0.625 0.375 0.013 - 15 Si 0.375 0.25 0.625 0.013 - 16 Si 0.75 0.875 0.125 0.013 - 17 Si 0.125 0.75 0.875 0.013 - 18 Si 0.375 0.625 0.75 0.013 - 19 Si 0.625 0.75 0.375 0.013 - 20 Si 0.875 0.25 0.125 0.013 - 21 Si 0.25 0.125 0.875 0.013 - 22 Si 0.75 0.375 0.625 0.013 - 23 Si 0.625 0.375 0.25 0.013 - 24 Mo 0 0 0 2.726 - 25 Mo 0.5 0 0 2.726 - 26 Mo 0 0.5 0 2.726 - 27 Mo 0.5 0.5 0 2.726 - 28 Mo 0 0.5 0.5 2.726 - 29 Mo 0.5 0 0.5 2.726 - 30 Mo 0.5 0.5 0.5 2.726 - 31 Mo 0 0 0.5 2.726 - 32 O 0.489537 0.380146 0.288741 0.016 - 33 O 0.299204 0.89061 0.010463 0.016 - 34 O 0.60939 0.908594 0.119854 0.016 - 35 O 0.591406 0.200796 0.211259 0.017 - 36 O 0.119854 0.010463 0.211259 0.016 - 37 O 0.200796 0.211259 0.591406 0.016 - 38 O 0.200796 0.489537 0.60939 0.016 - 39 O 0.211259 0.591406 0.200796 0.016 - 40 O 0.380146 0.591406 0.89061 0.016 - 41 O 0.908594 0.288741 0.299204 0.016 - 42 O 0.288741 0.299204 0.908594 0.016 - 43 O 0.211259 0.119854 0.010463 0.016 - 44 O 0.489537 0.60939 0.200796 0.016 - 45 O 0.89061 0.380146 0.591406 0.016 - 46 O 0.010463 0.211259 0.119854 0.016 - 47 O 0.60939 0.200796 0.489537 0.016 - 48 O 0.591406 0.89061 0.380146 0.016 - 49 O 0.010463 0.299204 0.89061 0.017 - 50 O 0.908594 0.119854 0.60939 0.016 - 51 O 0.619854 0.408594 0.10939 0.016 - 52 O 0.119854 0.60939 0.908594 0.016 - 53 O 0.288741 0.489537 0.380146 0.016 - 54 O 0.89061 0.010463 0.299204 0.016 - 55 O 0.299204 0.908594 0.288741 0.016 - 56 O 0.510463 0.619854 0.711259 0.016 - 57 O 0.700796 0.10939 0.989537 0.016 - 58 O 0.39061 0.091406 0.880146 0.016 - 59 O 0.408594 0.799204 0.788741 0.016 - 60 O 0.880146 0.989537 0.788741 0.016 - 61 O 0.799204 0.788741 0.408594 0.016 - 62 O 0.799204 0.510463 0.39061 0.016 - 63 O 0.788741 0.408594 0.799204 0.016 - 64 O 0.700796 0.091406 0.711259 0.016 - 65 O 0.10939 0.989537 0.700796 0.016 - 66 O 0.711259 0.510463 0.619854 0.016 - 67 O 0.619854 0.711259 0.510463 0.016 - 68 O 0.880146 0.39061 0.091406 0.016 - 69 O 0.091406 0.880146 0.39061 0.016 - 70 O 0.989537 0.700796 0.10939 0.016 - 71 O 0.408594 0.10939 0.619854 0.016 - 72 O 0.39061 0.799204 0.510463 0.016 - 73 O 0.989537 0.788741 0.880146 0.016 - 74 O 0.10939 0.619854 0.408594 0.016 - 75 O 0.510463 0.39061 0.799204 0.016 - 76 O 0.788741 0.880146 0.989537 0.016 - 77 O 0.711259 0.700796 0.091406 0.016 - 78 O 0.091406 0.711259 0.700796 0.016 - 79 O 0.380146 0.288741 0.489537 0.016","# generated using pymatgen -data_Ca3Si3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.78597228 -_cell_length_b 10.78597228 -_cell_length_c 10.78597228 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Si3(MoO6)2 -_chemical_formula_sum 'Ca12 Si12 Mo8 O48' -_cell_volume 965.95302936 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca1 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca2 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca3 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca4 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca5 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca6 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca7 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca8 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca10 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca11 1 0.37500000 0.12500000 0.25000000 1 - Si Si12 1 0.12500000 0.87500000 0.25000000 1 - Si Si13 1 0.87500000 0.12500000 0.75000000 1 - Si Si14 1 0.25000000 0.62500000 0.37500000 1 - Si Si15 1 0.37500000 0.25000000 0.62500000 1 - Si Si16 1 0.75000000 0.87500000 0.12500000 1 - Si Si17 1 0.12500000 0.75000000 0.87500000 1 - Si Si18 1 0.37500000 0.62500000 0.75000000 1 - Si Si19 1 0.62500000 0.75000000 0.37500000 1 - Si Si20 1 0.87500000 0.25000000 0.12500000 1 - Si Si21 1 0.25000000 0.12500000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Mo Mo24 1 0.00000000 0.00000000 0.00000000 1 - Mo Mo25 1 0.50000000 0.00000000 0.00000000 1 - Mo Mo26 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo27 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo28 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo29 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo30 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo31 1 0.00000000 0.00000000 0.50000000 1 - O O32 1 0.48953700 0.38014600 0.28874100 1 - O O33 1 0.29920400 0.89061000 0.01046300 1 - O O34 1 0.60939000 0.90859400 0.11985400 1 - O O35 1 0.59140600 0.20079600 0.21125900 1 - O O36 1 0.11985400 0.01046300 0.21125900 1 - O O37 1 0.20079600 0.21125900 0.59140600 1 - O O38 1 0.20079600 0.48953700 0.60939000 1 - O O39 1 0.21125900 0.59140600 0.20079600 1 - O O40 1 0.38014600 0.59140600 0.89061000 1 - O O41 1 0.90859400 0.28874100 0.29920400 1 - O O42 1 0.28874100 0.29920400 0.90859400 1 - O O43 1 0.21125900 0.11985400 0.01046300 1 - O O44 1 0.48953700 0.60939000 0.20079600 1 - O O45 1 0.89061000 0.38014600 0.59140600 1 - O O46 1 0.01046300 0.21125900 0.11985400 1 - O O47 1 0.60939000 0.20079600 0.48953700 1 - O O48 1 0.59140600 0.89061000 0.38014600 1 - O O49 1 0.01046300 0.29920400 0.89061000 1 - O O50 1 0.90859400 0.11985400 0.60939000 1 - O O51 1 0.61985400 0.40859400 0.10939000 1 - O O52 1 0.11985400 0.60939000 0.90859400 1 - O O53 1 0.28874100 0.48953700 0.38014600 1 - O O54 1 0.89061000 0.01046300 0.29920400 1 - O O55 1 0.29920400 0.90859400 0.28874100 1 - O O56 1 0.51046300 0.61985400 0.71125900 1 - O O57 1 0.70079600 0.10939000 0.98953700 1 - O O58 1 0.39061000 0.09140600 0.88014600 1 - O O59 1 0.40859400 0.79920400 0.78874100 1 - O O60 1 0.88014600 0.98953700 0.78874100 1 - O O61 1 0.79920400 0.78874100 0.40859400 1 - O O62 1 0.79920400 0.51046300 0.39061000 1 - O O63 1 0.78874100 0.40859400 0.79920400 1 - O O64 1 0.70079600 0.09140600 0.71125900 1 - O O65 1 0.10939000 0.98953700 0.70079600 1 - O O66 1 0.71125900 0.51046300 0.61985400 1 - O O67 1 0.61985400 0.71125900 0.51046300 1 - O O68 1 0.88014600 0.39061000 0.09140600 1 - O O69 1 0.09140600 0.88014600 0.39061000 1 - O O70 1 0.98953700 0.70079600 0.10939000 1 - O O71 1 0.40859400 0.10939000 0.61985400 1 - O O72 1 0.39061000 0.79920400 0.51046300 1 - O O73 1 0.98953700 0.78874100 0.88014600 1 - O O74 1 0.10939000 0.61985400 0.40859400 1 - O O75 1 0.51046300 0.39061000 0.79920400 1 - O O76 1 0.78874100 0.88014600 0.98953700 1 - O O77 1 0.71125900 0.70079600 0.09140600 1 - O O78 1 0.09140600 0.71125900 0.70079600 1 - O O79 1 0.38014600 0.28874100 0.48953700 1 -" -Li3La3(MoO6)2,mp-1185315,Ia-3d,[],0.0,{'tags': []},"Full Formula (Li12 La12 Mo8 O48) -Reduced Formula: Li3La3(MoO6)2 -abc : 11.040984 11.040984 11.040984 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.375 0.625 -0 - 1 Li 0.875 0.125 0.75 -0 - 2 Li 0.125 0.75 0.875 -0 - 3 Li 0.625 0.75 0.375 -0 - 4 Li 0.25 0.125 0.875 -0 - 5 Li 0.625 0.375 0.25 -0 - 6 Li 0.375 0.625 0.75 -0 - 7 Li 0.75 0.875 0.125 -0 - 8 Li 0.375 0.25 0.625 -0 - 9 Li 0.875 0.25 0.125 -0 - 10 Li 0.125 0.875 0.25 -0 - 11 Li 0.25 0.625 0.375 -0 - 12 La 0.25 0.375 0.125 -0 - 13 La 0.375 0.125 0.25 -0 - 14 La 0.375 0.75 0.125 -0 - 15 La 0.875 0.75 0.625 -0 - 16 La 0.125 0.375 0.75 -0 - 17 La 0.75 0.125 0.375 -0 - 18 La 0.25 0.875 0.625 -0 - 19 La 0.875 0.625 0.25 -0 - 20 La 0.125 0.25 0.375 -0 - 21 La 0.625 0.25 0.875 -0 - 22 La 0.75 0.625 0.875 -0 - 23 La 0.625 0.875 0.75 -0 - 24 Mo 0 0 0 -0.002 - 25 Mo 0 0.5 0 -0.002 - 26 Mo 0.5 0 0.5 -0.002 - 27 Mo 0.5 0.5 0.5 -0.002 - 28 Mo 0 0.5 0.5 -0.002 - 29 Mo 0 0 0.5 -0.002 - 30 Mo 0.5 0.5 0 -0.002 - 31 Mo 0.5 0 0 -0.002 - 32 O 0.19351 0.580122 0.170878 0.001 - 33 O 0.329122 0.919878 0.30649 0.001 - 34 O 0.69351 0.522631 0.613388 0.001 - 35 O 0.886612 0.977369 0.80649 0.001 - 36 O 0.613388 0.69351 0.522631 0.001 - 37 O 0.977369 0.80649 0.886612 0.001 - 38 O 0.022631 0.329122 0.909243 0.001 - 39 O 0.590757 0.170878 0.477369 0.001 - 40 O 0.19351 0.113388 0.022631 0.001 - 41 O 0.477369 0.386612 0.30649 0.001 - 42 O 0.113388 0.590757 0.919878 0.001 - 43 O 0.580122 0.909243 0.386612 0.001 - 44 O 0.329122 0.909243 0.022631 0.001 - 45 O 0.477369 0.590757 0.170878 0.001 - 46 O 0.919878 0.113388 0.590757 0.001 - 47 O 0.909243 0.386612 0.580122 0.001 - 48 O 0.30649 0.329122 0.919878 0.001 - 49 O 0.580122 0.170878 0.19351 0.001 - 50 O 0.829122 0.80649 0.419878 0.001 - 51 O 0.080122 0.69351 0.670878 0.001 - 52 O 0.829122 0.522631 0.409243 0.001 - 53 O 0.090757 0.977369 0.670878 0.001 - 54 O 0.386612 0.580122 0.909243 0.001 - 55 O 0.590757 0.919878 0.113388 0.001 - 56 O 0.613388 0.419878 0.090757 0.001 - 57 O 0.409243 0.080122 0.886612 0.001 - 58 O 0.170878 0.477369 0.590757 0.001 - 59 O 0.909243 0.022631 0.329122 0.001 - 60 O 0.919878 0.30649 0.329122 0.001 - 61 O 0.170878 0.19351 0.580122 0.001 - 62 O 0.69351 0.670878 0.080122 0.001 - 63 O 0.419878 0.829122 0.80649 0.001 - 64 O 0.080122 0.886612 0.409243 0.001 - 65 O 0.090757 0.613388 0.419878 0.001 - 66 O 0.522631 0.409243 0.829122 0.001 - 67 O 0.670878 0.090757 0.977369 0.001 - 68 O 0.886612 0.409243 0.080122 0.001 - 69 O 0.419878 0.090757 0.613388 0.001 - 70 O 0.522631 0.613388 0.69351 0.001 - 71 O 0.80649 0.886612 0.977369 0.001 - 72 O 0.977369 0.670878 0.090757 0.001 - 73 O 0.409243 0.829122 0.522631 0.001 - 74 O 0.386612 0.30649 0.477369 0.001 - 75 O 0.022631 0.19351 0.113388 0.001 - 76 O 0.113388 0.022631 0.19351 0.001 - 77 O 0.30649 0.477369 0.386612 0.001 - 78 O 0.670878 0.080122 0.69351 0.001 - 79 O 0.80649 0.419878 0.829122 0.001","# generated using pymatgen -data_Li3La3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.04098385 -_cell_length_b 11.04098385 -_cell_length_c 11.04098385 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3La3(MoO6)2 -_chemical_formula_sum 'Li12 La12 Mo8 O48' -_cell_volume 1036.09942706 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.37500000 0.62500000 1 - Li Li1 1 0.87500000 0.12500000 0.75000000 1 - Li Li2 1 0.12500000 0.75000000 0.87500000 1 - Li Li3 1 0.62500000 0.75000000 0.37500000 1 - Li Li4 1 0.25000000 0.12500000 0.87500000 1 - Li Li5 1 0.62500000 0.37500000 0.25000000 1 - Li Li6 1 0.37500000 0.62500000 0.75000000 1 - Li Li7 1 0.75000000 0.87500000 0.12500000 1 - Li Li8 1 0.37500000 0.25000000 0.62500000 1 - Li Li9 1 0.87500000 0.25000000 0.12500000 1 - Li Li10 1 0.12500000 0.87500000 0.25000000 1 - Li Li11 1 0.25000000 0.62500000 0.37500000 1 - La La12 1 0.25000000 0.37500000 0.12500000 1 - La La13 1 0.37500000 0.12500000 0.25000000 1 - La La14 1 0.37500000 0.75000000 0.12500000 1 - La La15 1 0.87500000 0.75000000 0.62500000 1 - La La16 1 0.12500000 0.37500000 0.75000000 1 - La La17 1 0.75000000 0.12500000 0.37500000 1 - La La18 1 0.25000000 0.87500000 0.62500000 1 - La La19 1 0.87500000 0.62500000 0.25000000 1 - La La20 1 0.12500000 0.25000000 0.37500000 1 - La La21 1 0.62500000 0.25000000 0.87500000 1 - La La22 1 0.75000000 0.62500000 0.87500000 1 - La La23 1 0.62500000 0.87500000 0.75000000 1 - Mo Mo24 1 0.00000000 0.00000000 0.00000000 1 - Mo Mo25 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo26 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo27 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo28 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo29 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo30 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.19351000 0.58012200 0.17087800 1 - O O33 1 0.32912200 0.91987800 0.30649000 1 - O O34 1 0.69351000 0.52263100 0.61338800 1 - O O35 1 0.88661200 0.97736900 0.80649000 1 - O O36 1 0.61338800 0.69351000 0.52263100 1 - O O37 1 0.97736900 0.80649000 0.88661200 1 - O O38 1 0.02263100 0.32912200 0.90924300 1 - O O39 1 0.59075700 0.17087800 0.47736900 1 - O O40 1 0.19351000 0.11338800 0.02263100 1 - O O41 1 0.47736900 0.38661200 0.30649000 1 - O O42 1 0.11338800 0.59075700 0.91987800 1 - O O43 1 0.58012200 0.90924300 0.38661200 1 - O O44 1 0.32912200 0.90924300 0.02263100 1 - O O45 1 0.47736900 0.59075700 0.17087800 1 - O O46 1 0.91987800 0.11338800 0.59075700 1 - O O47 1 0.90924300 0.38661200 0.58012200 1 - O O48 1 0.30649000 0.32912200 0.91987800 1 - O O49 1 0.58012200 0.17087800 0.19351000 1 - O O50 1 0.82912200 0.80649000 0.41987800 1 - O O51 1 0.08012200 0.69351000 0.67087800 1 - O O52 1 0.82912200 0.52263100 0.40924300 1 - O O53 1 0.09075700 0.97736900 0.67087800 1 - O O54 1 0.38661200 0.58012200 0.90924300 1 - O O55 1 0.59075700 0.91987800 0.11338800 1 - O O56 1 0.61338800 0.41987800 0.09075700 1 - O O57 1 0.40924300 0.08012200 0.88661200 1 - O O58 1 0.17087800 0.47736900 0.59075700 1 - O O59 1 0.90924300 0.02263100 0.32912200 1 - O O60 1 0.91987800 0.30649000 0.32912200 1 - O O61 1 0.17087800 0.19351000 0.58012200 1 - O O62 1 0.69351000 0.67087800 0.08012200 1 - O O63 1 0.41987800 0.82912200 0.80649000 1 - O O64 1 0.08012200 0.88661200 0.40924300 1 - O O65 1 0.09075700 0.61338800 0.41987800 1 - O O66 1 0.52263100 0.40924300 0.82912200 1 - O O67 1 0.67087800 0.09075700 0.97736900 1 - O O68 1 0.88661200 0.40924300 0.08012200 1 - O O69 1 0.41987800 0.09075700 0.61338800 1 - O O70 1 0.52263100 0.61338800 0.69351000 1 - O O71 1 0.80649000 0.88661200 0.97736900 1 - O O72 1 0.97736900 0.67087800 0.09075700 1 - O O73 1 0.40924300 0.82912200 0.52263100 1 - O O74 1 0.38661200 0.30649000 0.47736900 1 - O O75 1 0.02263100 0.19351000 0.11338800 1 - O O76 1 0.11338800 0.02263100 0.19351000 1 - O O77 1 0.30649000 0.47736900 0.38661200 1 - O O78 1 0.67087800 0.08012200 0.69351000 1 - O O79 1 0.80649000 0.41987800 0.82912200 1 -" -Mn3Fe2(GeO4)3,mp-1201980,Ia-3d,[18111],0.015894075750001235,"{'tags': ['garnet family', 'Trimanganese diiron(III) trigermanium oxide']}","Full Formula (Mn12 Fe8 Ge12 O48) -Reduced Formula: Mn3Fe2(GeO4)3 -abc : 10.605264 10.605264 10.605264 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.125 0.375 0.75 4.68 - 1 Mn 0.375 0.125 0.25 4.68 - 2 Mn 0.375 0.75 0.125 4.68 - 3 Mn 0.125 0.25 0.375 4.68 - 4 Mn 0.75 0.125 0.375 4.68 - 5 Mn 0.25 0.375 0.125 4.68 - 6 Mn 0.875 0.625 0.25 4.68 - 7 Mn 0.625 0.875 0.75 4.68 - 8 Mn 0.625 0.25 0.875 4.68 - 9 Mn 0.875 0.75 0.625 4.68 - 10 Mn 0.25 0.875 0.625 4.68 - 11 Mn 0.75 0.625 0.875 4.68 - 12 Fe 0 0.5 0 4.377 - 13 Fe 0 0 0.5 4.377 - 14 Fe 0.5 0 0 4.377 - 15 Fe 0.5 0.5 0.5 4.377 - 16 Fe 0.5 0.5 0 4.377 - 17 Fe 0.5 0 0.5 4.377 - 18 Fe 0 0.5 0.5 4.377 - 19 Fe 0 0 0 4.377 - 20 Ge 0.375 0.625 0.75 0.034 - 21 Ge 0.125 0.875 0.25 0.034 - 22 Ge 0.625 0.75 0.375 0.034 - 23 Ge 0.875 0.25 0.125 0.034 - 24 Ge 0.75 0.375 0.625 0.034 - 25 Ge 0.25 0.125 0.875 0.034 - 26 Ge 0.625 0.375 0.25 0.034 - 27 Ge 0.875 0.125 0.75 0.034 - 28 Ge 0.375 0.25 0.625 0.034 - 29 Ge 0.125 0.75 0.875 0.034 - 30 Ge 0.25 0.625 0.375 0.034 - 31 Ge 0.75 0.875 0.125 0.034 - 32 O 0.085102 0.876652 0.400847 0.105 - 33 O 0.975805 0.684255 0.099153 0.105 - 34 O 0.524195 0.623348 0.70845 0.105 - 35 O 0.414898 0.815745 0.79155 0.105 - 36 O 0.876652 0.400847 0.085102 0.105 - 37 O 0.684255 0.099153 0.975805 0.105 - 38 O 0.623348 0.70845 0.524195 0.105 - 39 O 0.815745 0.79155 0.414898 0.105 - 40 O 0.400847 0.085102 0.876652 0.105 - 41 O 0.099153 0.975805 0.684255 0.105 - 42 O 0.70845 0.524195 0.623348 0.105 - 43 O 0.79155 0.414898 0.815745 0.105 - 44 O 0.914898 0.123348 0.599153 0.105 - 45 O 0.024195 0.315745 0.900847 0.105 - 46 O 0.475805 0.376652 0.29155 0.105 - 47 O 0.585102 0.184255 0.20845 0.105 - 48 O 0.123348 0.599153 0.914898 0.105 - 49 O 0.315745 0.900847 0.024195 0.105 - 50 O 0.376652 0.29155 0.475805 0.105 - 51 O 0.184255 0.20845 0.585102 0.105 - 52 O 0.599153 0.914898 0.123348 0.105 - 53 O 0.900847 0.024195 0.315745 0.105 - 54 O 0.29155 0.475805 0.376652 0.105 - 55 O 0.20845 0.585102 0.184255 0.105 - 56 O 0.585102 0.900847 0.376652 0.105 - 57 O 0.475805 0.599153 0.184255 0.105 - 58 O 0.024195 0.20845 0.123348 0.105 - 59 O 0.914898 0.29155 0.315745 0.105 - 60 O 0.376652 0.585102 0.900847 0.105 - 61 O 0.184255 0.475805 0.599153 0.105 - 62 O 0.123348 0.024195 0.20845 0.105 - 63 O 0.315745 0.914898 0.29155 0.105 - 64 O 0.900847 0.376652 0.585102 0.105 - 65 O 0.599153 0.184255 0.475805 0.105 - 66 O 0.20845 0.123348 0.024195 0.105 - 67 O 0.29155 0.315745 0.914898 0.105 - 68 O 0.414898 0.099153 0.623348 0.105 - 69 O 0.524195 0.400847 0.815745 0.105 - 70 O 0.975805 0.79155 0.876652 0.105 - 71 O 0.085102 0.70845 0.684255 0.105 - 72 O 0.623348 0.414898 0.099153 0.105 - 73 O 0.815745 0.524195 0.400847 0.105 - 74 O 0.876652 0.975805 0.79155 0.105 - 75 O 0.684255 0.085102 0.70845 0.105 - 76 O 0.099153 0.623348 0.414898 0.105 - 77 O 0.400847 0.815745 0.524195 0.105 - 78 O 0.79155 0.876652 0.975805 0.105 - 79 O 0.70845 0.684255 0.085102 0.105","# generated using pymatgen -data_Mn3Fe2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.60526396 -_cell_length_b 10.60526396 -_cell_length_c 10.60526396 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn3Fe2(GeO4)3 -_chemical_formula_sum 'Mn12 Fe8 Ge12 O48' -_cell_volume 918.21113675 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn1 1 0.37500000 0.12500000 0.25000000 1 - Mn Mn2 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn3 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn4 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn5 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn6 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn7 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn8 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn9 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn10 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn11 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe12 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe13 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe18 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge24 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge27 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge28 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge29 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge30 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge31 1 0.75000000 0.87500000 0.12500000 1 - O O32 1 0.08510200 0.87665200 0.40084700 1 - O O33 1 0.97580500 0.68425500 0.09915300 1 - O O34 1 0.52419500 0.62334800 0.70845000 1 - O O35 1 0.41489800 0.81574500 0.79155000 1 - O O36 1 0.87665200 0.40084700 0.08510200 1 - O O37 1 0.68425500 0.09915300 0.97580500 1 - O O38 1 0.62334800 0.70845000 0.52419500 1 - O O39 1 0.81574500 0.79155000 0.41489800 1 - O O40 1 0.40084700 0.08510200 0.87665200 1 - O O41 1 0.09915300 0.97580500 0.68425500 1 - O O42 1 0.70845000 0.52419500 0.62334800 1 - O O43 1 0.79155000 0.41489800 0.81574500 1 - O O44 1 0.91489800 0.12334800 0.59915300 1 - O O45 1 0.02419500 0.31574500 0.90084700 1 - O O46 1 0.47580500 0.37665200 0.29155000 1 - O O47 1 0.58510200 0.18425500 0.20845000 1 - O O48 1 0.12334800 0.59915300 0.91489800 1 - O O49 1 0.31574500 0.90084700 0.02419500 1 - O O50 1 0.37665200 0.29155000 0.47580500 1 - O O51 1 0.18425500 0.20845000 0.58510200 1 - O O52 1 0.59915300 0.91489800 0.12334800 1 - O O53 1 0.90084700 0.02419500 0.31574500 1 - O O54 1 0.29155000 0.47580500 0.37665200 1 - O O55 1 0.20845000 0.58510200 0.18425500 1 - O O56 1 0.58510200 0.90084700 0.37665200 1 - O O57 1 0.47580500 0.59915300 0.18425500 1 - O O58 1 0.02419500 0.20845000 0.12334800 1 - O O59 1 0.91489800 0.29155000 0.31574500 1 - O O60 1 0.37665200 0.58510200 0.90084700 1 - O O61 1 0.18425500 0.47580500 0.59915300 1 - O O62 1 0.12334800 0.02419500 0.20845000 1 - O O63 1 0.31574500 0.91489800 0.29155000 1 - O O64 1 0.90084700 0.37665200 0.58510200 1 - O O65 1 0.59915300 0.18425500 0.47580500 1 - O O66 1 0.20845000 0.12334800 0.02419500 1 - O O67 1 0.29155000 0.31574500 0.91489800 1 - O O68 1 0.41489800 0.09915300 0.62334800 1 - O O69 1 0.52419500 0.40084700 0.81574500 1 - O O70 1 0.97580500 0.79155000 0.87665200 1 - O O71 1 0.08510200 0.70845000 0.68425500 1 - O O72 1 0.62334800 0.41489800 0.09915300 1 - O O73 1 0.81574500 0.52419500 0.40084700 1 - O O74 1 0.87665200 0.97580500 0.79155000 1 - O O75 1 0.68425500 0.08510200 0.70845000 1 - O O76 1 0.09915300 0.62334800 0.41489800 1 - O O77 1 0.40084700 0.81574500 0.52419500 1 - O O78 1 0.79155000 0.87665200 0.97580500 1 - O O79 1 0.70845000 0.68425500 0.08510200 1 -" -Na3V3Cr2O12,mp-1202673,Ia-3d,[190757],0.0,{'tags': ['Trisodium dichromium trivanadate']},"Full Formula (Na12 V12 Cr8 O48) -Reduced Formula: Na3V3Cr2O12 -abc : 10.806701 10.806701 10.806701 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.125 0.375 0.75 0 - 1 Na 0.375 0.125 0.25 0 - 2 Na 0.375 0.75 0.125 0 - 3 Na 0.125 0.25 0.375 0 - 4 Na 0.75 0.125 0.375 0 - 5 Na 0.25 0.375 0.125 0 - 6 Na 0.875 0.625 0.25 0 - 7 Na 0.625 0.875 0.75 0 - 8 Na 0.625 0.25 0.875 0 - 9 Na 0.875 0.75 0.625 0 - 10 Na 0.25 0.875 0.625 0 - 11 Na 0.75 0.625 0.875 0 - 12 V 0.375 0.625 0.75 0.082 - 13 V 0.125 0.875 0.25 0.082 - 14 V 0.625 0.75 0.375 0.082 - 15 V 0.875 0.25 0.125 0.082 - 16 V 0.75 0.375 0.625 0.082 - 17 V 0.25 0.125 0.875 0.082 - 18 V 0.625 0.375 0.25 0.082 - 19 V 0.875 0.125 0.75 0.082 - 20 V 0.375 0.25 0.625 0.082 - 21 V 0.125 0.75 0.875 0.082 - 22 V 0.25 0.625 0.375 0.082 - 23 V 0.75 0.875 0.125 0.082 - 24 Cr 0 0.5 0 2.904 - 25 Cr 0 0 0.5 2.903 - 26 Cr 0.5 0 0 2.903 - 27 Cr 0.5 0.5 0.5 2.904 - 28 Cr 0.5 0.5 0 2.904 - 29 Cr 0.5 0 0.5 2.903 - 30 Cr 0 0.5 0.5 2.903 - 31 Cr 0 0 0 2.904 - 32 O 0.085423 0.888755 0.396667 -0.018 - 33 O 0.992088 0.688756 0.103333 -0.018 - 34 O 0.507912 0.611245 0.696668 -0.018 - 35 O 0.414577 0.811244 0.803332 -0.018 - 36 O 0.888755 0.396667 0.085423 -0.019 - 37 O 0.688756 0.103333 0.992088 -0.017 - 38 O 0.611245 0.696668 0.507912 -0.019 - 39 O 0.811244 0.803332 0.414577 -0.017 - 40 O 0.396667 0.085423 0.888755 -0.019 - 41 O 0.103333 0.992088 0.688756 -0.019 - 42 O 0.696668 0.507912 0.611245 -0.018 - 43 O 0.803332 0.414577 0.811244 -0.018 - 44 O 0.914577 0.111245 0.603333 -0.018 - 45 O 0.007912 0.311244 0.896667 -0.018 - 46 O 0.492088 0.388755 0.303332 -0.018 - 47 O 0.585423 0.188756 0.196668 -0.018 - 48 O 0.111245 0.603333 0.914577 -0.019 - 49 O 0.311244 0.896667 0.007912 -0.017 - 50 O 0.388755 0.303332 0.492088 -0.019 - 51 O 0.188756 0.196668 0.585423 -0.017 - 52 O 0.603333 0.914577 0.111245 -0.019 - 53 O 0.896667 0.007912 0.311244 -0.019 - 54 O 0.303332 0.492088 0.388755 -0.018 - 55 O 0.196668 0.585423 0.188756 -0.018 - 56 O 0.585423 0.896667 0.388755 -0.018 - 57 O 0.492088 0.603333 0.188756 -0.018 - 58 O 0.007912 0.196668 0.111245 -0.018 - 59 O 0.914577 0.303332 0.311244 -0.018 - 60 O 0.388755 0.585423 0.896667 -0.019 - 61 O 0.188756 0.492088 0.603333 -0.017 - 62 O 0.111245 0.007912 0.196668 -0.019 - 63 O 0.311244 0.914577 0.303332 -0.017 - 64 O 0.896667 0.388755 0.585423 -0.019 - 65 O 0.603333 0.188756 0.492088 -0.019 - 66 O 0.196668 0.111245 0.007912 -0.018 - 67 O 0.303332 0.311244 0.914577 -0.018 - 68 O 0.414577 0.103333 0.611245 -0.018 - 69 O 0.507912 0.396667 0.811244 -0.018 - 70 O 0.992088 0.803332 0.888755 -0.018 - 71 O 0.085423 0.696668 0.688756 -0.018 - 72 O 0.611245 0.414577 0.103333 -0.019 - 73 O 0.811244 0.507912 0.396667 -0.017 - 74 O 0.888755 0.992088 0.803332 -0.019 - 75 O 0.688756 0.085423 0.696668 -0.017 - 76 O 0.103333 0.611245 0.414577 -0.019 - 77 O 0.396667 0.811244 0.507912 -0.019 - 78 O 0.803332 0.888755 0.992088 -0.018 - 79 O 0.696668 0.688756 0.085423 -0.018","# generated using pymatgen -data_Na3V3Cr2O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80670147 -_cell_length_b 10.80670147 -_cell_length_c 10.80670147 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3V3Cr2O12 -_chemical_formula_sum 'Na12 V12 Cr8 O48' -_cell_volume 971.53303400 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.12500000 0.37500000 0.75000000 1 - Na Na1 1 0.37500000 0.12500000 0.25000000 1 - Na Na2 1 0.37500000 0.75000000 0.12500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.75000000 0.12500000 0.37500000 1 - Na Na5 1 0.25000000 0.37500000 0.12500000 1 - Na Na6 1 0.87500000 0.62500000 0.25000000 1 - Na Na7 1 0.62500000 0.87500000 0.75000000 1 - Na Na8 1 0.62500000 0.25000000 0.87500000 1 - Na Na9 1 0.87500000 0.75000000 0.62500000 1 - Na Na10 1 0.25000000 0.87500000 0.62500000 1 - Na Na11 1 0.75000000 0.62500000 0.87500000 1 - V V12 1 0.37500000 0.62500000 0.75000000 1 - V V13 1 0.12500000 0.87500000 0.25000000 1 - V V14 1 0.62500000 0.75000000 0.37500000 1 - V V15 1 0.87500000 0.25000000 0.12500000 1 - V V16 1 0.75000000 0.37500000 0.62500000 1 - V V17 1 0.25000000 0.12500000 0.87500000 1 - V V18 1 0.62500000 0.37500000 0.25000000 1 - V V19 1 0.87500000 0.12500000 0.75000000 1 - V V20 1 0.37500000 0.25000000 0.62500000 1 - V V21 1 0.12500000 0.75000000 0.87500000 1 - V V22 1 0.25000000 0.62500000 0.37500000 1 - V V23 1 0.75000000 0.87500000 0.12500000 1 - Cr Cr24 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr25 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr26 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr27 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr28 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr29 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr30 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.08542300 0.88875500 0.39666700 1 - O O33 1 0.99208800 0.68875600 0.10333300 1 - O O34 1 0.50791200 0.61124500 0.69666800 1 - O O35 1 0.41457700 0.81124400 0.80333200 1 - O O36 1 0.88875500 0.39666700 0.08542300 1 - O O37 1 0.68875600 0.10333300 0.99208800 1 - O O38 1 0.61124500 0.69666800 0.50791200 1 - O O39 1 0.81124400 0.80333200 0.41457700 1 - O O40 1 0.39666700 0.08542300 0.88875500 1 - O O41 1 0.10333300 0.99208800 0.68875600 1 - O O42 1 0.69666800 0.50791200 0.61124500 1 - O O43 1 0.80333200 0.41457700 0.81124400 1 - O O44 1 0.91457700 0.11124500 0.60333300 1 - O O45 1 0.00791200 0.31124400 0.89666700 1 - O O46 1 0.49208800 0.38875500 0.30333200 1 - O O47 1 0.58542300 0.18875600 0.19666800 1 - O O48 1 0.11124500 0.60333300 0.91457700 1 - O O49 1 0.31124400 0.89666700 0.00791200 1 - O O50 1 0.38875500 0.30333200 0.49208800 1 - O O51 1 0.18875600 0.19666800 0.58542300 1 - O O52 1 0.60333300 0.91457700 0.11124500 1 - O O53 1 0.89666700 0.00791200 0.31124400 1 - O O54 1 0.30333200 0.49208800 0.38875500 1 - O O55 1 0.19666800 0.58542300 0.18875600 1 - O O56 1 0.58542300 0.89666700 0.38875500 1 - O O57 1 0.49208800 0.60333300 0.18875600 1 - O O58 1 0.00791200 0.19666800 0.11124500 1 - O O59 1 0.91457700 0.30333200 0.31124400 1 - O O60 1 0.38875500 0.58542300 0.89666700 1 - O O61 1 0.18875600 0.49208800 0.60333300 1 - O O62 1 0.11124500 0.00791200 0.19666800 1 - O O63 1 0.31124400 0.91457700 0.30333200 1 - O O64 1 0.89666700 0.38875500 0.58542300 1 - O O65 1 0.60333300 0.18875600 0.49208800 1 - O O66 1 0.19666800 0.11124500 0.00791200 1 - O O67 1 0.30333200 0.31124400 0.91457700 1 - O O68 1 0.41457700 0.10333300 0.61124500 1 - O O69 1 0.50791200 0.39666700 0.81124400 1 - O O70 1 0.99208800 0.80333200 0.88875500 1 - O O71 1 0.08542300 0.69666800 0.68875600 1 - O O72 1 0.61124500 0.41457700 0.10333300 1 - O O73 1 0.81124400 0.50791200 0.39666700 1 - O O74 1 0.88875500 0.99208800 0.80333200 1 - O O75 1 0.68875600 0.08542300 0.69666800 1 - O O76 1 0.10333300 0.61124500 0.41457700 1 - O O77 1 0.39666700 0.81124400 0.50791200 1 - O O78 1 0.80333200 0.88875500 0.99208800 1 - O O79 1 0.69666800 0.68875600 0.08542300 1 -" -Zn3Cd3(TeO6)2,mp-1207534,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Zn3Cd3Te2O12']}","Full Formula (Zn12 Cd12 Te8 O48) -Reduced Formula: Zn3Cd3(TeO6)2 -abc : 11.020994 11.020994 11.020994 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.625 0.375 0 - 1 Zn 0.75 0.375 0.625 0 - 2 Zn 0.75 0.875 0.125 0 - 3 Zn 0.375 0.25 0.625 0 - 4 Zn 0.625 0.75 0.375 0 - 5 Zn 0.25 0.125 0.875 0 - 6 Zn 0.125 0.75 0.875 0 - 7 Zn 0.875 0.25 0.125 0 - 8 Zn 0.625 0.375 0.25 0 - 9 Zn 0.375 0.625 0.75 0 - 10 Zn 0.875 0.125 0.75 0 - 11 Zn 0.125 0.875 0.25 0 - 12 Cd 0.25 0.375 0.125 0 - 13 Cd 0.75 0.625 0.875 0 - 14 Cd 0.75 0.125 0.375 0 - 15 Cd 0.125 0.25 0.375 0 - 16 Cd 0.375 0.75 0.125 0 - 17 Cd 0.25 0.875 0.625 0 - 18 Cd 0.875 0.75 0.625 0 - 19 Cd 0.625 0.25 0.875 0 - 20 Cd 0.375 0.125 0.25 0 - 21 Cd 0.625 0.875 0.75 0 - 22 Cd 0.125 0.375 0.75 0 - 23 Cd 0.875 0.625 0.25 0 - 24 Te 0 0 0 0 - 25 Te 0.5 0 0.5 0 - 26 Te 0 0.5 0.5 0 - 27 Te 0.5 0 0 0 - 28 Te 0.5 0.5 0 0 - 29 Te 0.5 0.5 0.5 0 - 30 Te 0 0 0.5 0 - 31 Te 0 0.5 0 0 - 32 O 0.476706 0.381055 0.306957 -0 - 33 O 0.523294 0.618945 0.693043 -0 - 34 O 0.574098 0.16975 0.193043 -0 - 35 O 0.925902 0.118945 0.595651 -0 - 36 O 0.306957 0.476706 0.381055 -0 - 37 O 0.33025 0.925902 0.306957 -0 - 38 O 0.425902 0.83025 0.806957 -0 - 39 O 0.074098 0.881055 0.404349 -0 - 40 O 0.693043 0.523294 0.618945 -0 - 41 O 0.66975 0.074098 0.693043 -0 - 42 O 0.023294 0.33025 0.904349 -0 - 43 O 0.193043 0.574098 0.16975 -0 - 44 O 0.118945 0.023294 0.193043 -0 - 45 O 0.976706 0.66975 0.095651 -0 - 46 O 0.806957 0.425902 0.83025 -0 - 47 O 0.881055 0.976706 0.806957 -0 - 48 O 0.595651 0.925902 0.118945 -0 - 49 O 0.16975 0.476706 0.595651 -0 - 50 O 0.404349 0.074098 0.881055 -0 - 51 O 0.83025 0.523294 0.404349 -0 - 52 O 0.904349 0.023294 0.33025 -0 - 53 O 0.381055 0.574098 0.904349 -0 - 54 O 0.095651 0.976706 0.66975 -0 - 55 O 0.618945 0.425902 0.095651 -0 - 56 O 0.381055 0.306957 0.476706 -0 - 57 O 0.574098 0.904349 0.381055 -0 - 58 O 0.618945 0.693043 0.523294 -0 - 59 O 0.425902 0.095651 0.618945 -0 - 60 O 0.118945 0.595651 0.925902 -0 - 61 O 0.023294 0.193043 0.118945 -0 - 62 O 0.881055 0.404349 0.074098 -0 - 63 O 0.976706 0.806957 0.881055 -0 - 64 O 0.33025 0.904349 0.023294 -0 - 65 O 0.925902 0.306957 0.33025 -0 - 66 O 0.66975 0.095651 0.976706 -0 - 67 O 0.074098 0.693043 0.66975 -0 - 68 O 0.16975 0.193043 0.574098 -0 - 69 O 0.476706 0.595651 0.16975 -0 - 70 O 0.83025 0.806957 0.425902 -0 - 71 O 0.523294 0.404349 0.83025 -0 - 72 O 0.306957 0.33025 0.925902 -0 - 73 O 0.693043 0.66975 0.074098 -0 - 74 O 0.193043 0.118945 0.023294 -0 - 75 O 0.806957 0.881055 0.976706 -0 - 76 O 0.904349 0.381055 0.574098 -0 - 77 O 0.095651 0.618945 0.425902 -0 - 78 O 0.595651 0.16975 0.476706 -0 - 79 O 0.404349 0.83025 0.523294 -0","# generated using pymatgen -data_Zn3Cd3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.02099426 -_cell_length_b 11.02099426 -_cell_length_c 11.02099426 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Cd3(TeO6)2 -_chemical_formula_sum 'Zn12 Cd12 Te8 O48' -_cell_volume 1030.48206446 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.62500000 0.37500000 1 - Zn Zn1 1 0.75000000 0.37500000 0.62500000 1 - Zn Zn2 1 0.75000000 0.87500000 0.12500000 1 - Zn Zn3 1 0.37500000 0.25000000 0.62500000 1 - Zn Zn4 1 0.62500000 0.75000000 0.37500000 1 - Zn Zn5 1 0.25000000 0.12500000 0.87500000 1 - Zn Zn6 1 0.12500000 0.75000000 0.87500000 1 - Zn Zn7 1 0.87500000 0.25000000 0.12500000 1 - Zn Zn8 1 0.62500000 0.37500000 0.25000000 1 - Zn Zn9 1 0.37500000 0.62500000 0.75000000 1 - Zn Zn10 1 0.87500000 0.12500000 0.75000000 1 - Zn Zn11 1 0.12500000 0.87500000 0.25000000 1 - Cd Cd12 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd13 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd14 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd15 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd16 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd17 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd18 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd19 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd20 1 0.37500000 0.12500000 0.25000000 1 - Cd Cd21 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd22 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47670600 0.38105500 0.30695700 1 - O O33 1 0.52329400 0.61894500 0.69304300 1 - O O34 1 0.57409800 0.16975000 0.19304300 1 - O O35 1 0.92590200 0.11894500 0.59565100 1 - O O36 1 0.30695700 0.47670600 0.38105500 1 - O O37 1 0.33025000 0.92590200 0.30695700 1 - O O38 1 0.42590200 0.83025000 0.80695700 1 - O O39 1 0.07409800 0.88105500 0.40434900 1 - O O40 1 0.69304300 0.52329400 0.61894500 1 - O O41 1 0.66975000 0.07409800 0.69304300 1 - O O42 1 0.02329400 0.33025000 0.90434900 1 - O O43 1 0.19304300 0.57409800 0.16975000 1 - O O44 1 0.11894500 0.02329400 0.19304300 1 - O O45 1 0.97670600 0.66975000 0.09565100 1 - O O46 1 0.80695700 0.42590200 0.83025000 1 - O O47 1 0.88105500 0.97670600 0.80695700 1 - O O48 1 0.59565100 0.92590200 0.11894500 1 - O O49 1 0.16975000 0.47670600 0.59565100 1 - O O50 1 0.40434900 0.07409800 0.88105500 1 - O O51 1 0.83025000 0.52329400 0.40434900 1 - O O52 1 0.90434900 0.02329400 0.33025000 1 - O O53 1 0.38105500 0.57409800 0.90434900 1 - O O54 1 0.09565100 0.97670600 0.66975000 1 - O O55 1 0.61894500 0.42590200 0.09565100 1 - O O56 1 0.38105500 0.30695700 0.47670600 1 - O O57 1 0.57409800 0.90434900 0.38105500 1 - O O58 1 0.61894500 0.69304300 0.52329400 1 - O O59 1 0.42590200 0.09565100 0.61894500 1 - O O60 1 0.11894500 0.59565100 0.92590200 1 - O O61 1 0.02329400 0.19304300 0.11894500 1 - O O62 1 0.88105500 0.40434900 0.07409800 1 - O O63 1 0.97670600 0.80695700 0.88105500 1 - O O64 1 0.33025000 0.90434900 0.02329400 1 - O O65 1 0.92590200 0.30695700 0.33025000 1 - O O66 1 0.66975000 0.09565100 0.97670600 1 - O O67 1 0.07409800 0.69304300 0.66975000 1 - O O68 1 0.16975000 0.19304300 0.57409800 1 - O O69 1 0.47670600 0.59565100 0.16975000 1 - O O70 1 0.83025000 0.80695700 0.42590200 1 - O O71 1 0.52329400 0.40434900 0.83025000 1 - O O72 1 0.30695700 0.33025000 0.92590200 1 - O O73 1 0.69304300 0.66975000 0.07409800 1 - O O74 1 0.19304300 0.11894500 0.02329400 1 - O O75 1 0.80695700 0.88105500 0.97670600 1 - O O76 1 0.90434900 0.38105500 0.57409800 1 - O O77 1 0.09565100 0.61894500 0.42590200 1 - O O78 1 0.59565100 0.16975000 0.47670600 1 - O O79 1 0.40434900 0.83025000 0.52329400 1 -" -Yb3Sc2Al3O12,mp-1207682,Ia-3d,[],0.04612177893750058,{'tags': []},"Full Formula (Yb12 Sc8 Al12 O48) -Reduced Formula: Yb3Sc2Al3O12 -abc : 10.803852 10.803852 10.803852 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Yb 0.25 0.375 0.125 0.007 - 1 Yb 0.75 0.625 0.875 0.007 - 2 Yb 0.75 0.125 0.375 0.01 - 3 Yb 0.125 0.25 0.375 0.014 - 4 Yb 0.375 0.75 0.125 0.014 - 5 Yb 0.25 0.875 0.625 0.01 - 6 Yb 0.875 0.75 0.625 0.014 - 7 Yb 0.625 0.25 0.875 0.014 - 8 Yb 0.375 0.125 0.25 0.014 - 9 Yb 0.625 0.875 0.75 0.014 - 10 Yb 0.125 0.375 0.75 0.014 - 11 Yb 0.875 0.625 0.25 0.014 - 12 Sc 0 0 0 -0.026 - 13 Sc 0.5 0 0.5 -0.019 - 14 Sc 0 0.5 0.5 -0.019 - 15 Sc 0.5 0 0 -0.019 - 16 Sc 0.5 0.5 0 -0.026 - 17 Sc 0.5 0.5 0.5 -0.026 - 18 Sc 0 0 0.5 -0.019 - 19 Sc 0 0.5 0 -0.026 - 20 Al 0.25 0.625 0.375 -0.007 - 21 Al 0.75 0.375 0.625 -0.007 - 22 Al 0.75 0.875 0.125 -0.007 - 23 Al 0.375 0.25 0.625 -0.008 - 24 Al 0.625 0.75 0.375 -0.008 - 25 Al 0.25 0.125 0.875 -0.007 - 26 Al 0.125 0.75 0.875 -0.008 - 27 Al 0.875 0.25 0.125 -0.008 - 28 Al 0.625 0.375 0.25 -0.008 - 29 Al 0.375 0.625 0.75 -0.008 - 30 Al 0.875 0.125 0.75 -0.008 - 31 Al 0.125 0.875 0.25 -0.008 - 32 O 0.477871 0.37716 0.288878 0.211 - 33 O 0.522129 0.62284 0.711122 0.211 - 34 O 0.588282 0.188993 0.211122 0.238 - 35 O 0.911718 0.12284 0.600711 0.238 - 36 O 0.288878 0.477871 0.37716 0.187 - 37 O 0.311007 0.911718 0.288878 0.239 - 38 O 0.411718 0.811007 0.788878 0.238 - 39 O 0.088282 0.87716 0.399289 0.238 - 40 O 0.711122 0.522129 0.62284 0.187 - 41 O 0.688993 0.088282 0.711122 0.239 - 42 O 0.022129 0.311007 0.899289 0.211 - 43 O 0.211122 0.588282 0.188993 0.187 - 44 O 0.12284 0.022129 0.211122 0.188 - 45 O 0.977871 0.688993 0.100711 0.211 - 46 O 0.788878 0.411718 0.811007 0.187 - 47 O 0.87716 0.977871 0.788878 0.188 - 48 O 0.600711 0.911718 0.12284 0.219 - 49 O 0.188993 0.477871 0.600711 0.239 - 50 O 0.399289 0.088282 0.87716 0.219 - 51 O 0.811007 0.522129 0.399289 0.239 - 52 O 0.899289 0.022129 0.311007 0.219 - 53 O 0.37716 0.588282 0.899289 0.188 - 54 O 0.100711 0.977871 0.688993 0.219 - 55 O 0.62284 0.411718 0.100711 0.188 - 56 O 0.37716 0.288878 0.477871 0.188 - 57 O 0.588282 0.899289 0.37716 0.238 - 58 O 0.62284 0.711122 0.522129 0.188 - 59 O 0.411718 0.100711 0.62284 0.238 - 60 O 0.12284 0.600711 0.911718 0.188 - 61 O 0.022129 0.211122 0.12284 0.211 - 62 O 0.87716 0.399289 0.088282 0.188 - 63 O 0.977871 0.788878 0.87716 0.211 - 64 O 0.311007 0.899289 0.022129 0.239 - 65 O 0.911718 0.288878 0.311007 0.238 - 66 O 0.688993 0.100711 0.977871 0.239 - 67 O 0.088282 0.711122 0.688993 0.238 - 68 O 0.188993 0.211122 0.588282 0.239 - 69 O 0.477871 0.600711 0.188993 0.211 - 70 O 0.811007 0.788878 0.411718 0.239 - 71 O 0.522129 0.399289 0.811007 0.211 - 72 O 0.288878 0.311007 0.911718 0.187 - 73 O 0.711122 0.688993 0.088282 0.187 - 74 O 0.211122 0.12284 0.022129 0.187 - 75 O 0.788878 0.87716 0.977871 0.187 - 76 O 0.899289 0.37716 0.588282 0.219 - 77 O 0.100711 0.62284 0.411718 0.219 - 78 O 0.600711 0.188993 0.477871 0.219 - 79 O 0.399289 0.811007 0.522129 0.219","# generated using pymatgen -data_Yb3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80385224 -_cell_length_b 10.80385224 -_cell_length_c 10.80385224 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Yb3Sc2Al3O12 -_chemical_formula_sum 'Yb12 Sc8 Al12 O48' -_cell_volume 970.76479262 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Yb Yb0 1 0.25000000 0.37500000 0.12500000 1 - Yb Yb1 1 0.75000000 0.62500000 0.87500000 1 - Yb Yb2 1 0.75000000 0.12500000 0.37500000 1 - Yb Yb3 1 0.12500000 0.25000000 0.37500000 1 - Yb Yb4 1 0.37500000 0.75000000 0.12500000 1 - Yb Yb5 1 0.25000000 0.87500000 0.62500000 1 - Yb Yb6 1 0.87500000 0.75000000 0.62500000 1 - Yb Yb7 1 0.62500000 0.25000000 0.87500000 1 - Yb Yb8 1 0.37500000 0.12500000 0.25000000 1 - Yb Yb9 1 0.62500000 0.87500000 0.75000000 1 - Yb Yb10 1 0.12500000 0.37500000 0.75000000 1 - Yb Yb11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Al Al20 1 0.25000000 0.62500000 0.37500000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.37500000 0.25000000 0.62500000 1 - Al Al24 1 0.62500000 0.75000000 0.37500000 1 - Al Al25 1 0.25000000 0.12500000 0.87500000 1 - Al Al26 1 0.12500000 0.75000000 0.87500000 1 - Al Al27 1 0.87500000 0.25000000 0.12500000 1 - Al Al28 1 0.62500000 0.37500000 0.25000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.87500000 0.12500000 0.75000000 1 - Al Al31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47787100 0.37716000 0.28887800 1 - O O33 1 0.52212900 0.62284000 0.71112200 1 - O O34 1 0.58828200 0.18899300 0.21112200 1 - O O35 1 0.91171800 0.12284000 0.60071100 1 - O O36 1 0.28887800 0.47787100 0.37716000 1 - O O37 1 0.31100700 0.91171800 0.28887800 1 - O O38 1 0.41171800 0.81100700 0.78887800 1 - O O39 1 0.08828200 0.87716000 0.39928900 1 - O O40 1 0.71112200 0.52212900 0.62284000 1 - O O41 1 0.68899300 0.08828200 0.71112200 1 - O O42 1 0.02212900 0.31100700 0.89928900 1 - O O43 1 0.21112200 0.58828200 0.18899300 1 - O O44 1 0.12284000 0.02212900 0.21112200 1 - O O45 1 0.97787100 0.68899300 0.10071100 1 - O O46 1 0.78887800 0.41171800 0.81100700 1 - O O47 1 0.87716000 0.97787100 0.78887800 1 - O O48 1 0.60071100 0.91171800 0.12284000 1 - O O49 1 0.18899300 0.47787100 0.60071100 1 - O O50 1 0.39928900 0.08828200 0.87716000 1 - O O51 1 0.81100700 0.52212900 0.39928900 1 - O O52 1 0.89928900 0.02212900 0.31100700 1 - O O53 1 0.37716000 0.58828200 0.89928900 1 - O O54 1 0.10071100 0.97787100 0.68899300 1 - O O55 1 0.62284000 0.41171800 0.10071100 1 - O O56 1 0.37716000 0.28887800 0.47787100 1 - O O57 1 0.58828200 0.89928900 0.37716000 1 - O O58 1 0.62284000 0.71112200 0.52212900 1 - O O59 1 0.41171800 0.10071100 0.62284000 1 - O O60 1 0.12284000 0.60071100 0.91171800 1 - O O61 1 0.02212900 0.21112200 0.12284000 1 - O O62 1 0.87716000 0.39928900 0.08828200 1 - O O63 1 0.97787100 0.78887800 0.87716000 1 - O O64 1 0.31100700 0.89928900 0.02212900 1 - O O65 1 0.91171800 0.28887800 0.31100700 1 - O O66 1 0.68899300 0.10071100 0.97787100 1 - O O67 1 0.08828200 0.71112200 0.68899300 1 - O O68 1 0.18899300 0.21112200 0.58828200 1 - O O69 1 0.47787100 0.60071100 0.18899300 1 - O O70 1 0.81100700 0.78887800 0.41171800 1 - O O71 1 0.52212900 0.39928900 0.81100700 1 - O O72 1 0.28887800 0.31100700 0.91171800 1 - O O73 1 0.71112200 0.68899300 0.08828200 1 - O O74 1 0.21112200 0.12284000 0.02212900 1 - O O75 1 0.78887800 0.87716000 0.97787100 1 - O O76 1 0.89928900 0.37716000 0.58828200 1 - O O77 1 0.10071100 0.62284000 0.41171800 1 - O O78 1 0.60071100 0.18899300 0.47787100 1 - O O79 1 0.39928900 0.81100700 0.52212900 1 -" -Yb3Al3Cr2O12,mp-1207693,Ia-3d,[],0.03191910981249535,"{'tags': ['Yb3Cr2Al3O12', 'garnet family']}","Full Formula (Yb12 Al12 Cr8 O48) -Reduced Formula: Yb3Al3Cr2O12 -abc : 10.522491 10.522491 10.522491 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Yb 0.25 0.375 0.125 -0.018 - 1 Yb 0.75 0.625 0.875 -0.018 - 2 Yb 0.75 0.125 0.375 -0.018 - 3 Yb 0.125 0.25 0.375 -0.018 - 4 Yb 0.375 0.75 0.125 -0.018 - 5 Yb 0.25 0.875 0.625 -0.018 - 6 Yb 0.875 0.75 0.625 -0.018 - 7 Yb 0.625 0.25 0.875 -0.018 - 8 Yb 0.375 0.125 0.25 -0.018 - 9 Yb 0.625 0.875 0.75 -0.018 - 10 Yb 0.125 0.375 0.75 -0.018 - 11 Yb 0.875 0.625 0.25 -0.018 - 12 Al 0.25 0.625 0.375 0.007 - 13 Al 0.75 0.375 0.625 0.007 - 14 Al 0.75 0.875 0.125 0.007 - 15 Al 0.375 0.25 0.625 0.007 - 16 Al 0.625 0.75 0.375 0.007 - 17 Al 0.25 0.125 0.875 0.007 - 18 Al 0.125 0.75 0.875 0.007 - 19 Al 0.875 0.25 0.125 0.007 - 20 Al 0.625 0.375 0.25 0.007 - 21 Al 0.375 0.625 0.75 0.007 - 22 Al 0.875 0.125 0.75 0.007 - 23 Al 0.125 0.875 0.25 0.007 - 24 Cr 0 0 0 2.009 - 25 Cr 0.5 0 0.5 2.009 - 26 Cr 0 0.5 0.5 2.009 - 27 Cr 0.5 0 0 2.009 - 28 Cr 0.5 0.5 0 2.009 - 29 Cr 0.5 0.5 0.5 2.009 - 30 Cr 0 0 0.5 2.009 - 31 Cr 0 0.5 0 2.009 - 32 O 0.483059 0.384327 0.302932 -0.08 - 33 O 0.516941 0.615673 0.697068 -0.08 - 34 O 0.581395 0.180127 0.197068 -0.08 - 35 O 0.918605 0.115673 0.598732 -0.08 - 36 O 0.302932 0.483059 0.384327 -0.08 - 37 O 0.319873 0.918605 0.302932 -0.08 - 38 O 0.418605 0.819873 0.802932 -0.08 - 39 O 0.081395 0.884327 0.401268 -0.08 - 40 O 0.697068 0.516941 0.615673 -0.08 - 41 O 0.680127 0.081395 0.697068 -0.08 - 42 O 0.016941 0.319873 0.901268 -0.08 - 43 O 0.197068 0.581395 0.180127 -0.08 - 44 O 0.115673 0.016941 0.197068 -0.08 - 45 O 0.983059 0.680127 0.098732 -0.08 - 46 O 0.802932 0.418605 0.819873 -0.08 - 47 O 0.884327 0.983059 0.802932 -0.08 - 48 O 0.598732 0.918605 0.115673 -0.08 - 49 O 0.180127 0.483059 0.598732 -0.08 - 50 O 0.401268 0.081395 0.884327 -0.08 - 51 O 0.819873 0.516941 0.401268 -0.08 - 52 O 0.901268 0.016941 0.319873 -0.08 - 53 O 0.384327 0.581395 0.901268 -0.08 - 54 O 0.098732 0.983059 0.680127 -0.08 - 55 O 0.615673 0.418605 0.098732 -0.08 - 56 O 0.384327 0.302932 0.483059 -0.08 - 57 O 0.581395 0.901268 0.384327 -0.08 - 58 O 0.615673 0.697068 0.516941 -0.08 - 59 O 0.418605 0.098732 0.615673 -0.08 - 60 O 0.115673 0.598732 0.918605 -0.08 - 61 O 0.016941 0.197068 0.115673 -0.08 - 62 O 0.884327 0.401268 0.081395 -0.08 - 63 O 0.983059 0.802932 0.884327 -0.08 - 64 O 0.319873 0.901268 0.016941 -0.08 - 65 O 0.918605 0.302932 0.319873 -0.08 - 66 O 0.680127 0.098732 0.983059 -0.08 - 67 O 0.081395 0.697068 0.680127 -0.08 - 68 O 0.180127 0.197068 0.581395 -0.08 - 69 O 0.483059 0.598732 0.180127 -0.08 - 70 O 0.819873 0.802932 0.418605 -0.08 - 71 O 0.516941 0.401268 0.819873 -0.08 - 72 O 0.302932 0.319873 0.918605 -0.08 - 73 O 0.697068 0.680127 0.081395 -0.08 - 74 O 0.197068 0.115673 0.016941 -0.08 - 75 O 0.802932 0.884327 0.983059 -0.08 - 76 O 0.901268 0.384327 0.581395 -0.08 - 77 O 0.098732 0.615673 0.418605 -0.08 - 78 O 0.598732 0.180127 0.483059 -0.08 - 79 O 0.401268 0.819873 0.516941 -0.08","# generated using pymatgen -data_Yb3Al3Cr2O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.52249098 -_cell_length_b 10.52249098 -_cell_length_c 10.52249098 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Yb3Al3Cr2O12 -_chemical_formula_sum 'Yb12 Al12 Cr8 O48' -_cell_volume 896.87887684 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Yb Yb0 1 0.25000000 0.37500000 0.12500000 1 - Yb Yb1 1 0.75000000 0.62500000 0.87500000 1 - Yb Yb2 1 0.75000000 0.12500000 0.37500000 1 - Yb Yb3 1 0.12500000 0.25000000 0.37500000 1 - Yb Yb4 1 0.37500000 0.75000000 0.12500000 1 - Yb Yb5 1 0.25000000 0.87500000 0.62500000 1 - Yb Yb6 1 0.87500000 0.75000000 0.62500000 1 - Yb Yb7 1 0.62500000 0.25000000 0.87500000 1 - Yb Yb8 1 0.37500000 0.12500000 0.25000000 1 - Yb Yb9 1 0.62500000 0.87500000 0.75000000 1 - Yb Yb10 1 0.12500000 0.37500000 0.75000000 1 - Yb Yb11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.25000000 0.62500000 0.37500000 1 - Al Al13 1 0.75000000 0.37500000 0.62500000 1 - Al Al14 1 0.75000000 0.87500000 0.12500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.62500000 0.75000000 0.37500000 1 - Al Al17 1 0.25000000 0.12500000 0.87500000 1 - Al Al18 1 0.12500000 0.75000000 0.87500000 1 - Al Al19 1 0.87500000 0.25000000 0.12500000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.37500000 0.62500000 0.75000000 1 - Al Al22 1 0.87500000 0.12500000 0.75000000 1 - Al Al23 1 0.12500000 0.87500000 0.25000000 1 - Cr Cr24 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr25 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr26 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr27 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr28 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr29 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr30 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.48305900 0.38432700 0.30293200 1 - O O33 1 0.51694100 0.61567300 0.69706800 1 - O O34 1 0.58139500 0.18012700 0.19706800 1 - O O35 1 0.91860500 0.11567300 0.59873200 1 - O O36 1 0.30293200 0.48305900 0.38432700 1 - O O37 1 0.31987300 0.91860500 0.30293200 1 - O O38 1 0.41860500 0.81987300 0.80293200 1 - O O39 1 0.08139500 0.88432700 0.40126800 1 - O O40 1 0.69706800 0.51694100 0.61567300 1 - O O41 1 0.68012700 0.08139500 0.69706800 1 - O O42 1 0.01694100 0.31987300 0.90126800 1 - O O43 1 0.19706800 0.58139500 0.18012700 1 - O O44 1 0.11567300 0.01694100 0.19706800 1 - O O45 1 0.98305900 0.68012700 0.09873200 1 - O O46 1 0.80293200 0.41860500 0.81987300 1 - O O47 1 0.88432700 0.98305900 0.80293200 1 - O O48 1 0.59873200 0.91860500 0.11567300 1 - O O49 1 0.18012700 0.48305900 0.59873200 1 - O O50 1 0.40126800 0.08139500 0.88432700 1 - O O51 1 0.81987300 0.51694100 0.40126800 1 - O O52 1 0.90126800 0.01694100 0.31987300 1 - O O53 1 0.38432700 0.58139500 0.90126800 1 - O O54 1 0.09873200 0.98305900 0.68012700 1 - O O55 1 0.61567300 0.41860500 0.09873200 1 - O O56 1 0.38432700 0.30293200 0.48305900 1 - O O57 1 0.58139500 0.90126800 0.38432700 1 - O O58 1 0.61567300 0.69706800 0.51694100 1 - O O59 1 0.41860500 0.09873200 0.61567300 1 - O O60 1 0.11567300 0.59873200 0.91860500 1 - O O61 1 0.01694100 0.19706800 0.11567300 1 - O O62 1 0.88432700 0.40126800 0.08139500 1 - O O63 1 0.98305900 0.80293200 0.88432700 1 - O O64 1 0.31987300 0.90126800 0.01694100 1 - O O65 1 0.91860500 0.30293200 0.31987300 1 - O O66 1 0.68012700 0.09873200 0.98305900 1 - O O67 1 0.08139500 0.69706800 0.68012700 1 - O O68 1 0.18012700 0.19706800 0.58139500 1 - O O69 1 0.48305900 0.59873200 0.18012700 1 - O O70 1 0.81987300 0.80293200 0.41860500 1 - O O71 1 0.51694100 0.40126800 0.81987300 1 - O O72 1 0.30293200 0.31987300 0.91860500 1 - O O73 1 0.69706800 0.68012700 0.08139500 1 - O O74 1 0.19706800 0.11567300 0.01694100 1 - O O75 1 0.80293200 0.88432700 0.98305900 1 - O O76 1 0.90126800 0.38432700 0.58139500 1 - O O77 1 0.09873200 0.61567300 0.41860500 1 - O O78 1 0.59873200 0.18012700 0.48305900 1 - O O79 1 0.40126800 0.81987300 0.51694100 1 -" -Y3Al3V2O12,mp-1207869,Ia-3d,[],0.04227769527500769,"{'tags': ['garnet family', 'Y3V2Al3O12']}","Full Formula (Y12 Al12 V8 O48) -Reduced Formula: Y3Al3V2O12 -abc : 10.680697 10.680697 10.680697 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.25 0.375 0.125 0.004 - 1 Y 0.75 0.625 0.875 0.004 - 2 Y 0.75 0.125 0.375 0.003 - 3 Y 0.125 0.25 0.375 0.004 - 4 Y 0.375 0.75 0.125 0.004 - 5 Y 0.25 0.875 0.625 0.003 - 6 Y 0.875 0.75 0.625 0.004 - 7 Y 0.625 0.25 0.875 0.004 - 8 Y 0.375 0.125 0.25 0.004 - 9 Y 0.625 0.875 0.75 0.004 - 10 Y 0.125 0.375 0.75 0.004 - 11 Y 0.875 0.625 0.25 0.004 - 12 Al 0.25 0.625 0.375 0.005 - 13 Al 0.75 0.375 0.625 0.005 - 14 Al 0.75 0.875 0.125 0.005 - 15 Al 0.375 0.25 0.625 0.005 - 16 Al 0.625 0.75 0.375 0.005 - 17 Al 0.25 0.125 0.875 0.005 - 18 Al 0.125 0.75 0.875 0.005 - 19 Al 0.875 0.25 0.125 0.005 - 20 Al 0.625 0.375 0.25 0.005 - 21 Al 0.375 0.625 0.75 0.005 - 22 Al 0.875 0.125 0.75 0.005 - 23 Al 0.125 0.875 0.25 0.005 - 24 V 0 0 0 1.957 - 25 V 0.5 0 0.5 1.921 - 26 V 0 0.5 0.5 1.921 - 27 V 0.5 0 0 1.922 - 28 V 0.5 0.5 0 1.957 - 29 V 0.5 0.5 0.5 1.957 - 30 V 0 0 0.5 1.922 - 31 V 0 0.5 0 1.957 - 32 O 0.476268 0.37709 0.290693 -0.015 - 33 O 0.523732 0.62291 0.709307 -0.015 - 34 O 0.586397 0.185575 0.209307 -0.015 - 35 O 0.913603 0.12291 0.599178 -0.015 - 36 O 0.290693 0.476268 0.37709 -0.011 - 37 O 0.314425 0.913603 0.290693 -0.014 - 38 O 0.413603 0.814425 0.790693 -0.015 - 39 O 0.086397 0.87709 0.400822 -0.015 - 40 O 0.709307 0.523732 0.62291 -0.011 - 41 O 0.685575 0.086397 0.709307 -0.014 - 42 O 0.023732 0.314425 0.900822 -0.015 - 43 O 0.209307 0.586397 0.185575 -0.011 - 44 O 0.12291 0.023732 0.209307 -0.013 - 45 O 0.976268 0.685575 0.099178 -0.015 - 46 O 0.790693 0.413603 0.814425 -0.011 - 47 O 0.87709 0.976268 0.790693 -0.013 - 48 O 0.599178 0.913603 0.12291 -0.013 - 49 O 0.185575 0.476268 0.599178 -0.014 - 50 O 0.400822 0.086397 0.87709 -0.013 - 51 O 0.814425 0.523732 0.400822 -0.014 - 52 O 0.900822 0.023732 0.314425 -0.013 - 53 O 0.37709 0.586397 0.900822 -0.013 - 54 O 0.099178 0.976268 0.685575 -0.013 - 55 O 0.62291 0.413603 0.099178 -0.013 - 56 O 0.37709 0.290693 0.476268 -0.013 - 57 O 0.586397 0.900822 0.37709 -0.015 - 58 O 0.62291 0.709307 0.523732 -0.013 - 59 O 0.413603 0.099178 0.62291 -0.015 - 60 O 0.12291 0.599178 0.913603 -0.013 - 61 O 0.023732 0.209307 0.12291 -0.015 - 62 O 0.87709 0.400822 0.086397 -0.013 - 63 O 0.976268 0.790693 0.87709 -0.015 - 64 O 0.314425 0.900822 0.023732 -0.014 - 65 O 0.913603 0.290693 0.314425 -0.015 - 66 O 0.685575 0.099178 0.976268 -0.014 - 67 O 0.086397 0.709307 0.685575 -0.015 - 68 O 0.185575 0.209307 0.586397 -0.014 - 69 O 0.476268 0.599178 0.185575 -0.015 - 70 O 0.814425 0.790693 0.413603 -0.014 - 71 O 0.523732 0.400822 0.814425 -0.015 - 72 O 0.290693 0.314425 0.913603 -0.011 - 73 O 0.709307 0.685575 0.086397 -0.011 - 74 O 0.209307 0.12291 0.023732 -0.011 - 75 O 0.790693 0.87709 0.976268 -0.011 - 76 O 0.900822 0.37709 0.586397 -0.013 - 77 O 0.099178 0.62291 0.413603 -0.013 - 78 O 0.599178 0.185575 0.476268 -0.013 - 79 O 0.400822 0.814425 0.523732 -0.013","# generated using pymatgen -data_Y3Al3V2O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.68069650 -_cell_length_b 10.68069650 -_cell_length_c 10.68069650 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Al3V2O12 -_chemical_formula_sum 'Y12 Al12 V8 O48' -_cell_volume 937.94383395 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.25000000 0.37500000 0.12500000 1 - Y Y1 1 0.75000000 0.62500000 0.87500000 1 - Y Y2 1 0.75000000 0.12500000 0.37500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.37500000 0.75000000 0.12500000 1 - Y Y5 1 0.25000000 0.87500000 0.62500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.62500000 0.25000000 0.87500000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.62500000 0.87500000 0.75000000 1 - Y Y10 1 0.12500000 0.37500000 0.75000000 1 - Y Y11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.25000000 0.62500000 0.37500000 1 - Al Al13 1 0.75000000 0.37500000 0.62500000 1 - Al Al14 1 0.75000000 0.87500000 0.12500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.62500000 0.75000000 0.37500000 1 - Al Al17 1 0.25000000 0.12500000 0.87500000 1 - Al Al18 1 0.12500000 0.75000000 0.87500000 1 - Al Al19 1 0.87500000 0.25000000 0.12500000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.37500000 0.62500000 0.75000000 1 - Al Al22 1 0.87500000 0.12500000 0.75000000 1 - Al Al23 1 0.12500000 0.87500000 0.25000000 1 - V V24 1 0.00000000 0.00000000 0.00000000 1 - V V25 1 0.50000000 0.00000000 0.50000000 1 - V V26 1 0.00000000 0.50000000 0.50000000 1 - V V27 1 0.50000000 0.00000000 0.00000000 1 - V V28 1 0.50000000 0.50000000 0.00000000 1 - V V29 1 0.50000000 0.50000000 0.50000000 1 - V V30 1 0.00000000 0.00000000 0.50000000 1 - V V31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47626800 0.37709000 0.29069300 1 - O O33 1 0.52373200 0.62291000 0.70930700 1 - O O34 1 0.58639700 0.18557500 0.20930700 1 - O O35 1 0.91360300 0.12291000 0.59917800 1 - O O36 1 0.29069300 0.47626800 0.37709000 1 - O O37 1 0.31442500 0.91360300 0.29069300 1 - O O38 1 0.41360300 0.81442500 0.79069300 1 - O O39 1 0.08639700 0.87709000 0.40082200 1 - O O40 1 0.70930700 0.52373200 0.62291000 1 - O O41 1 0.68557500 0.08639700 0.70930700 1 - O O42 1 0.02373200 0.31442500 0.90082200 1 - O O43 1 0.20930700 0.58639700 0.18557500 1 - O O44 1 0.12291000 0.02373200 0.20930700 1 - O O45 1 0.97626800 0.68557500 0.09917800 1 - O O46 1 0.79069300 0.41360300 0.81442500 1 - O O47 1 0.87709000 0.97626800 0.79069300 1 - O O48 1 0.59917800 0.91360300 0.12291000 1 - O O49 1 0.18557500 0.47626800 0.59917800 1 - O O50 1 0.40082200 0.08639700 0.87709000 1 - O O51 1 0.81442500 0.52373200 0.40082200 1 - O O52 1 0.90082200 0.02373200 0.31442500 1 - O O53 1 0.37709000 0.58639700 0.90082200 1 - O O54 1 0.09917800 0.97626800 0.68557500 1 - O O55 1 0.62291000 0.41360300 0.09917800 1 - O O56 1 0.37709000 0.29069300 0.47626800 1 - O O57 1 0.58639700 0.90082200 0.37709000 1 - O O58 1 0.62291000 0.70930700 0.52373200 1 - O O59 1 0.41360300 0.09917800 0.62291000 1 - O O60 1 0.12291000 0.59917800 0.91360300 1 - O O61 1 0.02373200 0.20930700 0.12291000 1 - O O62 1 0.87709000 0.40082200 0.08639700 1 - O O63 1 0.97626800 0.79069300 0.87709000 1 - O O64 1 0.31442500 0.90082200 0.02373200 1 - O O65 1 0.91360300 0.29069300 0.31442500 1 - O O66 1 0.68557500 0.09917800 0.97626800 1 - O O67 1 0.08639700 0.70930700 0.68557500 1 - O O68 1 0.18557500 0.20930700 0.58639700 1 - O O69 1 0.47626800 0.59917800 0.18557500 1 - O O70 1 0.81442500 0.79069300 0.41360300 1 - O O71 1 0.52373200 0.40082200 0.81442500 1 - O O72 1 0.29069300 0.31442500 0.91360300 1 - O O73 1 0.70930700 0.68557500 0.08639700 1 - O O74 1 0.20930700 0.12291000 0.02373200 1 - O O75 1 0.79069300 0.87709000 0.97626800 1 - O O76 1 0.90082200 0.37709000 0.58639700 1 - O O77 1 0.09917800 0.62291000 0.41360300 1 - O O78 1 0.59917800 0.18557500 0.47626800 1 - O O79 1 0.40082200 0.81442500 0.52373200 1 -" -Y2Mg3(SiO4)3,mp-1207890,Ia-3d,[],0.20463127495832723,"{'tags': ['pyrope', 'garnet family']}","Full Formula (Y8 Mg12 Si12 O48) -Reduced Formula: Y2Mg3(SiO4)3 -abc : 10.656618 10.656618 10.656618 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0 -0 - 1 Y 0.5 0 0.5 -0 - 2 Y 0 0.5 0.5 -0 - 3 Y 0.5 0 0 -0 - 4 Y 0.5 0.5 0 -0 - 5 Y 0.5 0.5 0.5 -0 - 6 Y 0 0 0.5 -0 - 7 Y 0 0.5 0 -0 - 8 Mg 0.25 0.375 0.125 -0 - 9 Mg 0.75 0.625 0.875 -0 - 10 Mg 0.75 0.125 0.375 -0 - 11 Mg 0.125 0.25 0.375 -0 - 12 Mg 0.375 0.75 0.125 -0 - 13 Mg 0.25 0.875 0.625 -0 - 14 Mg 0.875 0.75 0.625 -0 - 15 Mg 0.625 0.25 0.875 -0 - 16 Mg 0.375 0.125 0.25 -0 - 17 Mg 0.625 0.875 0.75 -0 - 18 Mg 0.125 0.375 0.75 -0 - 19 Mg 0.875 0.625 0.25 -0 - 20 Si 0.25 0.625 0.375 -0 - 21 Si 0.75 0.375 0.625 -0 - 22 Si 0.75 0.875 0.125 -0 - 23 Si 0.375 0.25 0.625 -0 - 24 Si 0.625 0.75 0.375 -0 - 25 Si 0.25 0.125 0.875 -0 - 26 Si 0.125 0.75 0.875 -0 - 27 Si 0.875 0.25 0.125 -0 - 28 Si 0.625 0.375 0.25 -0 - 29 Si 0.375 0.625 0.75 -0 - 30 Si 0.875 0.125 0.75 -0 - 31 Si 0.125 0.875 0.25 -0 - 32 O 0.477482 0.370638 0.27371 0 - 33 O 0.522518 0.629362 0.72629 0 - 34 O 0.596928 0.203772 0.22629 0 - 35 O 0.903072 0.129362 0.606844 0 - 36 O 0.27371 0.477482 0.370638 0 - 37 O 0.296228 0.903072 0.27371 0 - 38 O 0.403072 0.796228 0.77371 0 - 39 O 0.096928 0.870638 0.393156 0 - 40 O 0.72629 0.522518 0.629362 0 - 41 O 0.703772 0.096928 0.72629 0 - 42 O 0.022518 0.296228 0.893156 0 - 43 O 0.22629 0.596928 0.203772 0 - 44 O 0.129362 0.022518 0.22629 0 - 45 O 0.977482 0.703772 0.106844 0 - 46 O 0.77371 0.403072 0.796228 0 - 47 O 0.870638 0.977482 0.77371 0 - 48 O 0.606844 0.903072 0.129362 0 - 49 O 0.203772 0.477482 0.606844 0 - 50 O 0.393156 0.096928 0.870638 0 - 51 O 0.796228 0.522518 0.393156 0 - 52 O 0.893156 0.022518 0.296228 0 - 53 O 0.370638 0.596928 0.893156 0 - 54 O 0.106844 0.977482 0.703772 0 - 55 O 0.629362 0.403072 0.106844 0 - 56 O 0.370638 0.27371 0.477482 0 - 57 O 0.596928 0.893156 0.370638 0 - 58 O 0.629362 0.72629 0.522518 0 - 59 O 0.403072 0.106844 0.629362 0 - 60 O 0.129362 0.606844 0.903072 0 - 61 O 0.022518 0.22629 0.129362 0 - 62 O 0.870638 0.393156 0.096928 0 - 63 O 0.977482 0.77371 0.870638 0 - 64 O 0.296228 0.893156 0.022518 0 - 65 O 0.903072 0.27371 0.296228 0 - 66 O 0.703772 0.106844 0.977482 0 - 67 O 0.096928 0.72629 0.703772 0 - 68 O 0.203772 0.22629 0.596928 0 - 69 O 0.477482 0.606844 0.203772 0 - 70 O 0.796228 0.77371 0.403072 0 - 71 O 0.522518 0.393156 0.796228 0 - 72 O 0.27371 0.296228 0.903072 0 - 73 O 0.72629 0.703772 0.096928 0 - 74 O 0.22629 0.129362 0.022518 0 - 75 O 0.77371 0.870638 0.977482 0 - 76 O 0.893156 0.370638 0.596928 0 - 77 O 0.106844 0.629362 0.403072 0 - 78 O 0.606844 0.203772 0.477482 0 - 79 O 0.393156 0.796228 0.522518 0","# generated using pymatgen -data_Y2Mg3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.65661753 -_cell_length_b 10.65661753 -_cell_length_c 10.65661753 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Mg3(SiO4)3 -_chemical_formula_sum 'Y8 Mg12 Si12 O48' -_cell_volume 931.61451521 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.00000000 1 - Y Y1 1 0.50000000 0.00000000 0.50000000 1 - Y Y2 1 0.00000000 0.50000000 0.50000000 1 - Y Y3 1 0.50000000 0.00000000 0.00000000 1 - Y Y4 1 0.50000000 0.50000000 0.00000000 1 - Y Y5 1 0.50000000 0.50000000 0.50000000 1 - Y Y6 1 0.00000000 0.00000000 0.50000000 1 - Y Y7 1 0.00000000 0.50000000 0.00000000 1 - Mg Mg8 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg9 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg10 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg12 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg13 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg14 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg15 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg16 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg17 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg18 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg19 1 0.87500000 0.62500000 0.25000000 1 - Si Si20 1 0.25000000 0.62500000 0.37500000 1 - Si Si21 1 0.75000000 0.37500000 0.62500000 1 - Si Si22 1 0.75000000 0.87500000 0.12500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.25000000 0.12500000 0.87500000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.87500000 0.25000000 0.12500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.37500000 0.62500000 0.75000000 1 - Si Si30 1 0.87500000 0.12500000 0.75000000 1 - Si Si31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47748200 0.37063800 0.27371000 1 - O O33 1 0.52251800 0.62936200 0.72629000 1 - O O34 1 0.59692800 0.20377200 0.22629000 1 - O O35 1 0.90307200 0.12936200 0.60684400 1 - O O36 1 0.27371000 0.47748200 0.37063800 1 - O O37 1 0.29622800 0.90307200 0.27371000 1 - O O38 1 0.40307200 0.79622800 0.77371000 1 - O O39 1 0.09692800 0.87063800 0.39315600 1 - O O40 1 0.72629000 0.52251800 0.62936200 1 - O O41 1 0.70377200 0.09692800 0.72629000 1 - O O42 1 0.02251800 0.29622800 0.89315600 1 - O O43 1 0.22629000 0.59692800 0.20377200 1 - O O44 1 0.12936200 0.02251800 0.22629000 1 - O O45 1 0.97748200 0.70377200 0.10684400 1 - O O46 1 0.77371000 0.40307200 0.79622800 1 - O O47 1 0.87063800 0.97748200 0.77371000 1 - O O48 1 0.60684400 0.90307200 0.12936200 1 - O O49 1 0.20377200 0.47748200 0.60684400 1 - O O50 1 0.39315600 0.09692800 0.87063800 1 - O O51 1 0.79622800 0.52251800 0.39315600 1 - O O52 1 0.89315600 0.02251800 0.29622800 1 - O O53 1 0.37063800 0.59692800 0.89315600 1 - O O54 1 0.10684400 0.97748200 0.70377200 1 - O O55 1 0.62936200 0.40307200 0.10684400 1 - O O56 1 0.37063800 0.27371000 0.47748200 1 - O O57 1 0.59692800 0.89315600 0.37063800 1 - O O58 1 0.62936200 0.72629000 0.52251800 1 - O O59 1 0.40307200 0.10684400 0.62936200 1 - O O60 1 0.12936200 0.60684400 0.90307200 1 - O O61 1 0.02251800 0.22629000 0.12936200 1 - O O62 1 0.87063800 0.39315600 0.09692800 1 - O O63 1 0.97748200 0.77371000 0.87063800 1 - O O64 1 0.29622800 0.89315600 0.02251800 1 - O O65 1 0.90307200 0.27371000 0.29622800 1 - O O66 1 0.70377200 0.10684400 0.97748200 1 - O O67 1 0.09692800 0.72629000 0.70377200 1 - O O68 1 0.20377200 0.22629000 0.59692800 1 - O O69 1 0.47748200 0.60684400 0.20377200 1 - O O70 1 0.79622800 0.77371000 0.40307200 1 - O O71 1 0.52251800 0.39315600 0.79622800 1 - O O72 1 0.27371000 0.29622800 0.90307200 1 - O O73 1 0.72629000 0.70377200 0.09692800 1 - O O74 1 0.22629000 0.12936200 0.02251800 1 - O O75 1 0.77371000 0.87063800 0.97748200 1 - O O76 1 0.89315600 0.37063800 0.59692800 1 - O O77 1 0.10684400 0.62936200 0.40307200 1 - O O78 1 0.60684400 0.20377200 0.47748200 1 - O O79 1 0.39315600 0.79622800 0.52251800 1 -" -Y3Al3Cr2O12,mp-1207891,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Y3Cr2Al3O12']}","Full Formula (Y12 Al12 Cr8 O48) -Reduced Formula: Y3Al3Cr2O12 -abc : 10.637730 10.637730 10.637730 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.25 0.375 0.125 0.005 - 1 Y 0.75 0.625 0.875 0.005 - 2 Y 0.75 0.125 0.375 0.005 - 3 Y 0.125 0.25 0.375 0.005 - 4 Y 0.375 0.75 0.125 0.005 - 5 Y 0.25 0.875 0.625 0.005 - 6 Y 0.875 0.75 0.625 0.005 - 7 Y 0.625 0.25 0.875 0.005 - 8 Y 0.375 0.125 0.25 0.005 - 9 Y 0.625 0.875 0.75 0.005 - 10 Y 0.125 0.375 0.75 0.005 - 11 Y 0.875 0.625 0.25 0.005 - 12 Al 0.25 0.625 0.375 0.003 - 13 Al 0.75 0.375 0.625 0.003 - 14 Al 0.75 0.875 0.125 0.003 - 15 Al 0.375 0.25 0.625 0.004 - 16 Al 0.625 0.75 0.375 0.004 - 17 Al 0.25 0.125 0.875 0.003 - 18 Al 0.125 0.75 0.875 0.004 - 19 Al 0.875 0.25 0.125 0.004 - 20 Al 0.625 0.375 0.25 0.004 - 21 Al 0.375 0.625 0.75 0.004 - 22 Al 0.875 0.125 0.75 0.004 - 23 Al 0.125 0.875 0.25 0.004 - 24 Cr 0 0 0 2.945 - 25 Cr 0.5 0 0.5 2.944 - 26 Cr 0 0.5 0.5 2.944 - 27 Cr 0.5 0 0 2.944 - 28 Cr 0.5 0.5 0 2.945 - 29 Cr 0.5 0.5 0.5 2.945 - 30 Cr 0 0 0.5 2.944 - 31 Cr 0 0.5 0 2.945 - 32 O 0.476452 0.377592 0.292214 -0.006 - 33 O 0.523548 0.622408 0.707786 -0.006 - 34 O 0.585378 0.184238 0.207786 -0.006 - 35 O 0.914622 0.122408 0.59886 -0.006 - 36 O 0.292214 0.476452 0.377592 -0.006 - 37 O 0.315762 0.914622 0.292214 -0.005 - 38 O 0.414622 0.815762 0.792214 -0.006 - 39 O 0.085378 0.877592 0.40114 -0.006 - 40 O 0.707786 0.523548 0.622408 -0.006 - 41 O 0.684238 0.085378 0.707786 -0.005 - 42 O 0.023548 0.315762 0.90114 -0.006 - 43 O 0.207786 0.585378 0.184238 -0.006 - 44 O 0.122408 0.023548 0.207786 -0.006 - 45 O 0.976452 0.684238 0.09886 -0.006 - 46 O 0.792214 0.414622 0.815762 -0.006 - 47 O 0.877592 0.976452 0.792214 -0.006 - 48 O 0.59886 0.914622 0.122408 -0.006 - 49 O 0.184238 0.476452 0.59886 -0.005 - 50 O 0.40114 0.085378 0.877592 -0.006 - 51 O 0.815762 0.523548 0.40114 -0.005 - 52 O 0.90114 0.023548 0.315762 -0.006 - 53 O 0.377592 0.585378 0.90114 -0.006 - 54 O 0.09886 0.976452 0.684238 -0.006 - 55 O 0.622408 0.414622 0.09886 -0.006 - 56 O 0.377592 0.292214 0.476452 -0.006 - 57 O 0.585378 0.90114 0.377592 -0.006 - 58 O 0.622408 0.707786 0.523548 -0.006 - 59 O 0.414622 0.09886 0.622408 -0.006 - 60 O 0.122408 0.59886 0.914622 -0.006 - 61 O 0.023548 0.207786 0.122408 -0.006 - 62 O 0.877592 0.40114 0.085378 -0.006 - 63 O 0.976452 0.792214 0.877592 -0.006 - 64 O 0.315762 0.90114 0.023548 -0.005 - 65 O 0.914622 0.292214 0.315762 -0.006 - 66 O 0.684238 0.09886 0.976452 -0.005 - 67 O 0.085378 0.707786 0.684238 -0.006 - 68 O 0.184238 0.207786 0.585378 -0.005 - 69 O 0.476452 0.59886 0.184238 -0.006 - 70 O 0.815762 0.792214 0.414622 -0.005 - 71 O 0.523548 0.40114 0.815762 -0.006 - 72 O 0.292214 0.315762 0.914622 -0.006 - 73 O 0.707786 0.684238 0.085378 -0.006 - 74 O 0.207786 0.122408 0.023548 -0.006 - 75 O 0.792214 0.877592 0.976452 -0.006 - 76 O 0.90114 0.377592 0.585378 -0.006 - 77 O 0.09886 0.622408 0.414622 -0.006 - 78 O 0.59886 0.184238 0.476452 -0.006 - 79 O 0.40114 0.815762 0.523548 -0.006","# generated using pymatgen -data_Y3Al3Cr2O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.63772952 -_cell_length_b 10.63772952 -_cell_length_c 10.63772952 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Al3Cr2O12 -_chemical_formula_sum 'Y12 Al12 Cr8 O48' -_cell_volume 926.66965021 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.25000000 0.37500000 0.12500000 1 - Y Y1 1 0.75000000 0.62500000 0.87500000 1 - Y Y2 1 0.75000000 0.12500000 0.37500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.37500000 0.75000000 0.12500000 1 - Y Y5 1 0.25000000 0.87500000 0.62500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.62500000 0.25000000 0.87500000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.62500000 0.87500000 0.75000000 1 - Y Y10 1 0.12500000 0.37500000 0.75000000 1 - Y Y11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.25000000 0.62500000 0.37500000 1 - Al Al13 1 0.75000000 0.37500000 0.62500000 1 - Al Al14 1 0.75000000 0.87500000 0.12500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.62500000 0.75000000 0.37500000 1 - Al Al17 1 0.25000000 0.12500000 0.87500000 1 - Al Al18 1 0.12500000 0.75000000 0.87500000 1 - Al Al19 1 0.87500000 0.25000000 0.12500000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.37500000 0.62500000 0.75000000 1 - Al Al22 1 0.87500000 0.12500000 0.75000000 1 - Al Al23 1 0.12500000 0.87500000 0.25000000 1 - Cr Cr24 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr25 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr26 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr27 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr28 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr29 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr30 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47645200 0.37759200 0.29221400 1 - O O33 1 0.52354800 0.62240800 0.70778600 1 - O O34 1 0.58537800 0.18423800 0.20778600 1 - O O35 1 0.91462200 0.12240800 0.59886000 1 - O O36 1 0.29221400 0.47645200 0.37759200 1 - O O37 1 0.31576200 0.91462200 0.29221400 1 - O O38 1 0.41462200 0.81576200 0.79221400 1 - O O39 1 0.08537800 0.87759200 0.40114000 1 - O O40 1 0.70778600 0.52354800 0.62240800 1 - O O41 1 0.68423800 0.08537800 0.70778600 1 - O O42 1 0.02354800 0.31576200 0.90114000 1 - O O43 1 0.20778600 0.58537800 0.18423800 1 - O O44 1 0.12240800 0.02354800 0.20778600 1 - O O45 1 0.97645200 0.68423800 0.09886000 1 - O O46 1 0.79221400 0.41462200 0.81576200 1 - O O47 1 0.87759200 0.97645200 0.79221400 1 - O O48 1 0.59886000 0.91462200 0.12240800 1 - O O49 1 0.18423800 0.47645200 0.59886000 1 - O O50 1 0.40114000 0.08537800 0.87759200 1 - O O51 1 0.81576200 0.52354800 0.40114000 1 - O O52 1 0.90114000 0.02354800 0.31576200 1 - O O53 1 0.37759200 0.58537800 0.90114000 1 - O O54 1 0.09886000 0.97645200 0.68423800 1 - O O55 1 0.62240800 0.41462200 0.09886000 1 - O O56 1 0.37759200 0.29221400 0.47645200 1 - O O57 1 0.58537800 0.90114000 0.37759200 1 - O O58 1 0.62240800 0.70778600 0.52354800 1 - O O59 1 0.41462200 0.09886000 0.62240800 1 - O O60 1 0.12240800 0.59886000 0.91462200 1 - O O61 1 0.02354800 0.20778600 0.12240800 1 - O O62 1 0.87759200 0.40114000 0.08537800 1 - O O63 1 0.97645200 0.79221400 0.87759200 1 - O O64 1 0.31576200 0.90114000 0.02354800 1 - O O65 1 0.91462200 0.29221400 0.31576200 1 - O O66 1 0.68423800 0.09886000 0.97645200 1 - O O67 1 0.08537800 0.70778600 0.68423800 1 - O O68 1 0.18423800 0.20778600 0.58537800 1 - O O69 1 0.47645200 0.59886000 0.18423800 1 - O O70 1 0.81576200 0.79221400 0.41462200 1 - O O71 1 0.52354800 0.40114000 0.81576200 1 - O O72 1 0.29221400 0.31576200 0.91462200 1 - O O73 1 0.70778600 0.68423800 0.08537800 1 - O O74 1 0.20778600 0.12240800 0.02354800 1 - O O75 1 0.79221400 0.87759200 0.97645200 1 - O O76 1 0.90114000 0.37759200 0.58537800 1 - O O77 1 0.09886000 0.62240800 0.41462200 1 - O O78 1 0.59886000 0.18423800 0.47645200 1 - O O79 1 0.40114000 0.81576200 0.52354800 1 -" -Yb2Nd3(GaO4)3,mp-1207900,Ia-3d,[],0.023916531625000736,"{'tags': ['Nd3Yb2Ga3O12', 'garnet family', 'Y3Al5O12']}","Full Formula (Yb8 Nd12 Ga12 O48) -Reduced Formula: Yb2Nd3(GaO4)3 -abc : 11.290822 11.290822 11.290822 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Yb 0 0 0 0.021 - 1 Yb 0.5 0 0.5 0.075 - 2 Yb 0 0.5 0.5 0.075 - 3 Yb 0.5 0 0 0.075 - 4 Yb 0.5 0.5 0 0.021 - 5 Yb 0.5 0.5 0.5 0.021 - 6 Yb 0 0 0.5 0.075 - 7 Yb 0 0.5 0 0.021 - 8 Nd 0.25 0.375 0.125 -0.012 - 9 Nd 0.75 0.625 0.875 -0.012 - 10 Nd 0.75 0.125 0.375 -0.012 - 11 Nd 0.125 0.25 0.375 -0.011 - 12 Nd 0.375 0.75 0.125 -0.011 - 13 Nd 0.25 0.875 0.625 -0.012 - 14 Nd 0.875 0.75 0.625 -0.011 - 15 Nd 0.625 0.25 0.875 -0.011 - 16 Nd 0.375 0.125 0.25 -0.011 - 17 Nd 0.625 0.875 0.75 -0.011 - 18 Nd 0.125 0.375 0.75 -0.011 - 19 Nd 0.875 0.625 0.25 -0.011 - 20 Ga 0.25 0.625 0.375 -0.005 - 21 Ga 0.75 0.375 0.625 -0.005 - 22 Ga 0.75 0.875 0.125 -0.005 - 23 Ga 0.375 0.25 0.625 -0.005 - 24 Ga 0.625 0.75 0.375 -0.005 - 25 Ga 0.25 0.125 0.875 -0.005 - 26 Ga 0.125 0.75 0.875 -0.005 - 27 Ga 0.875 0.25 0.125 -0.005 - 28 Ga 0.625 0.375 0.25 -0.005 - 29 Ga 0.375 0.625 0.75 -0.005 - 30 Ga 0.875 0.125 0.75 -0.005 - 31 Ga 0.125 0.875 0.25 -0.005 - 32 O 0.468327 0.370175 0.277281 0.112 - 33 O 0.531673 0.629825 0.722719 0.112 - 34 O 0.592894 0.191046 0.222719 0.178 - 35 O 0.907106 0.129825 0.598152 0.178 - 36 O 0.277281 0.468327 0.370175 0.114 - 37 O 0.308954 0.907106 0.277281 0.18 - 38 O 0.407106 0.808954 0.777281 0.178 - 39 O 0.092894 0.870175 0.401848 0.178 - 40 O 0.722719 0.531673 0.629825 0.114 - 41 O 0.691046 0.092894 0.722719 0.18 - 42 O 0.031673 0.308954 0.901848 0.112 - 43 O 0.222719 0.592894 0.191046 0.114 - 44 O 0.129825 0.031673 0.222719 0.1 - 45 O 0.968327 0.691046 0.098152 0.112 - 46 O 0.777281 0.407106 0.808954 0.114 - 47 O 0.870175 0.968327 0.777281 0.1 - 48 O 0.598152 0.907106 0.129825 0.169 - 49 O 0.191046 0.468327 0.598152 0.18 - 50 O 0.401848 0.092894 0.870175 0.169 - 51 O 0.808954 0.531673 0.401848 0.18 - 52 O 0.901848 0.031673 0.308954 0.169 - 53 O 0.370175 0.592894 0.901848 0.1 - 54 O 0.098152 0.968327 0.691046 0.169 - 55 O 0.629825 0.407106 0.098152 0.1 - 56 O 0.370175 0.277281 0.468327 0.1 - 57 O 0.592894 0.901848 0.370175 0.178 - 58 O 0.629825 0.722719 0.531673 0.1 - 59 O 0.407106 0.098152 0.629825 0.178 - 60 O 0.129825 0.598152 0.907106 0.1 - 61 O 0.031673 0.222719 0.129825 0.112 - 62 O 0.870175 0.401848 0.092894 0.1 - 63 O 0.968327 0.777281 0.870175 0.112 - 64 O 0.308954 0.901848 0.031673 0.18 - 65 O 0.907106 0.277281 0.308954 0.178 - 66 O 0.691046 0.098152 0.968327 0.18 - 67 O 0.092894 0.722719 0.691046 0.178 - 68 O 0.191046 0.222719 0.592894 0.18 - 69 O 0.468327 0.598152 0.191046 0.112 - 70 O 0.808954 0.777281 0.407106 0.18 - 71 O 0.531673 0.401848 0.808954 0.112 - 72 O 0.277281 0.308954 0.907106 0.114 - 73 O 0.722719 0.691046 0.092894 0.114 - 74 O 0.222719 0.129825 0.031673 0.114 - 75 O 0.777281 0.870175 0.968327 0.114 - 76 O 0.901848 0.370175 0.592894 0.169 - 77 O 0.098152 0.629825 0.407106 0.169 - 78 O 0.598152 0.191046 0.468327 0.169 - 79 O 0.401848 0.808954 0.531673 0.169","# generated using pymatgen -data_Yb2Nd3(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.29082179 -_cell_length_b 11.29082179 -_cell_length_c 11.29082179 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Yb2Nd3(GaO4)3 -_chemical_formula_sum 'Yb8 Nd12 Ga12 O48' -_cell_volume 1108.03828761 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Yb Yb0 1 0.00000000 0.00000000 0.00000000 1 - Yb Yb1 1 0.50000000 0.00000000 0.50000000 1 - Yb Yb2 1 0.00000000 0.50000000 0.50000000 1 - Yb Yb3 1 0.50000000 0.00000000 0.00000000 1 - Yb Yb4 1 0.50000000 0.50000000 0.00000000 1 - Yb Yb5 1 0.50000000 0.50000000 0.50000000 1 - Yb Yb6 1 0.00000000 0.00000000 0.50000000 1 - Yb Yb7 1 0.00000000 0.50000000 0.00000000 1 - Nd Nd8 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd9 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd10 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd11 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd12 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd13 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd14 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd15 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd16 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd17 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd18 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd19 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.46832700 0.37017500 0.27728100 1 - O O33 1 0.53167300 0.62982500 0.72271900 1 - O O34 1 0.59289400 0.19104600 0.22271900 1 - O O35 1 0.90710600 0.12982500 0.59815200 1 - O O36 1 0.27728100 0.46832700 0.37017500 1 - O O37 1 0.30895400 0.90710600 0.27728100 1 - O O38 1 0.40710600 0.80895400 0.77728100 1 - O O39 1 0.09289400 0.87017500 0.40184800 1 - O O40 1 0.72271900 0.53167300 0.62982500 1 - O O41 1 0.69104600 0.09289400 0.72271900 1 - O O42 1 0.03167300 0.30895400 0.90184800 1 - O O43 1 0.22271900 0.59289400 0.19104600 1 - O O44 1 0.12982500 0.03167300 0.22271900 1 - O O45 1 0.96832700 0.69104600 0.09815200 1 - O O46 1 0.77728100 0.40710600 0.80895400 1 - O O47 1 0.87017500 0.96832700 0.77728100 1 - O O48 1 0.59815200 0.90710600 0.12982500 1 - O O49 1 0.19104600 0.46832700 0.59815200 1 - O O50 1 0.40184800 0.09289400 0.87017500 1 - O O51 1 0.80895400 0.53167300 0.40184800 1 - O O52 1 0.90184800 0.03167300 0.30895400 1 - O O53 1 0.37017500 0.59289400 0.90184800 1 - O O54 1 0.09815200 0.96832700 0.69104600 1 - O O55 1 0.62982500 0.40710600 0.09815200 1 - O O56 1 0.37017500 0.27728100 0.46832700 1 - O O57 1 0.59289400 0.90184800 0.37017500 1 - O O58 1 0.62982500 0.72271900 0.53167300 1 - O O59 1 0.40710600 0.09815200 0.62982500 1 - O O60 1 0.12982500 0.59815200 0.90710600 1 - O O61 1 0.03167300 0.22271900 0.12982500 1 - O O62 1 0.87017500 0.40184800 0.09289400 1 - O O63 1 0.96832700 0.77728100 0.87017500 1 - O O64 1 0.30895400 0.90184800 0.03167300 1 - O O65 1 0.90710600 0.27728100 0.30895400 1 - O O66 1 0.69104600 0.09815200 0.96832700 1 - O O67 1 0.09289400 0.72271900 0.69104600 1 - O O68 1 0.19104600 0.22271900 0.59289400 1 - O O69 1 0.46832700 0.59815200 0.19104600 1 - O O70 1 0.80895400 0.77728100 0.40710600 1 - O O71 1 0.53167300 0.40184800 0.80895400 1 - O O72 1 0.27728100 0.30895400 0.90710600 1 - O O73 1 0.72271900 0.69104600 0.09289400 1 - O O74 1 0.22271900 0.12982500 0.03167300 1 - O O75 1 0.77728100 0.87017500 0.96832700 1 - O O76 1 0.90184800 0.37017500 0.59289400 1 - O O77 1 0.09815200 0.62982500 0.40710600 1 - O O78 1 0.59815200 0.19104600 0.46832700 1 - O O79 1 0.40184800 0.80895400 0.53167300 1 -" -Y3Mg2(GeO4)3,mp-1207912,Ia-3d,[],0.06903735403125832,{'tags': []},"Full Formula (Y12 Mg8 Ge12 O48) -Reduced Formula: Y3Mg2(GeO4)3 -abc : 10.836869 10.836869 10.836869 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.25 0.375 0.125 0 - 1 Y 0.75 0.625 0.875 0 - 2 Y 0.75 0.125 0.375 0 - 3 Y 0.125 0.25 0.375 0 - 4 Y 0.375 0.75 0.125 0 - 5 Y 0.25 0.875 0.625 0 - 6 Y 0.875 0.75 0.625 0 - 7 Y 0.625 0.25 0.875 0 - 8 Y 0.375 0.125 0.25 0 - 9 Y 0.625 0.875 0.75 0 - 10 Y 0.125 0.375 0.75 0 - 11 Y 0.875 0.625 0.25 0 - 12 Mg 0 0 0 -0 - 13 Mg 0.5 0 0.5 -0 - 14 Mg 0 0.5 0.5 -0 - 15 Mg 0.5 0 0 -0 - 16 Mg 0.5 0.5 0 -0 - 17 Mg 0.5 0.5 0.5 -0 - 18 Mg 0 0 0.5 -0 - 19 Mg 0 0.5 0 -0 - 20 Ge 0.25 0.625 0.375 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.75 0.875 0.125 -0 - 23 Ge 0.375 0.25 0.625 -0 - 24 Ge 0.625 0.75 0.375 -0 - 25 Ge 0.25 0.125 0.875 -0 - 26 Ge 0.125 0.75 0.875 -0 - 27 Ge 0.875 0.25 0.125 -0 - 28 Ge 0.625 0.375 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.875 0.125 0.75 -0 - 31 Ge 0.125 0.875 0.25 -0 - 32 O 0.474385 0.374714 0.287928 -0 - 33 O 0.525615 0.625286 0.712072 -0 - 34 O 0.586786 0.186457 0.212072 -0 - 35 O 0.913214 0.125286 0.599671 -0 - 36 O 0.287928 0.474385 0.374714 -0 - 37 O 0.313543 0.913214 0.287928 -0 - 38 O 0.413214 0.813543 0.787928 -0 - 39 O 0.086786 0.874714 0.400329 -0 - 40 O 0.712072 0.525615 0.625286 -0 - 41 O 0.686457 0.086786 0.712072 -0 - 42 O 0.025615 0.313543 0.900329 -0 - 43 O 0.212072 0.586786 0.186457 -0 - 44 O 0.125286 0.025615 0.212072 -0 - 45 O 0.974385 0.686457 0.099671 -0 - 46 O 0.787928 0.413214 0.813543 -0 - 47 O 0.874714 0.974385 0.787928 -0 - 48 O 0.599671 0.913214 0.125286 -0 - 49 O 0.186457 0.474385 0.599671 -0 - 50 O 0.400329 0.086786 0.874714 -0 - 51 O 0.813543 0.525615 0.400329 -0 - 52 O 0.900329 0.025615 0.313543 -0 - 53 O 0.374714 0.586786 0.900329 -0 - 54 O 0.099671 0.974385 0.686457 -0 - 55 O 0.625286 0.413214 0.099671 -0 - 56 O 0.374714 0.287928 0.474385 -0 - 57 O 0.586786 0.900329 0.374714 -0 - 58 O 0.625286 0.712072 0.525615 -0 - 59 O 0.413214 0.099671 0.625286 -0 - 60 O 0.125286 0.599671 0.913214 -0 - 61 O 0.025615 0.212072 0.125286 -0 - 62 O 0.874714 0.400329 0.086786 -0 - 63 O 0.974385 0.787928 0.874714 -0 - 64 O 0.313543 0.900329 0.025615 -0 - 65 O 0.913214 0.287928 0.313543 -0 - 66 O 0.686457 0.099671 0.974385 -0 - 67 O 0.086786 0.712072 0.686457 -0 - 68 O 0.186457 0.212072 0.586786 -0 - 69 O 0.474385 0.599671 0.186457 -0 - 70 O 0.813543 0.787928 0.413214 -0 - 71 O 0.525615 0.400329 0.813543 -0 - 72 O 0.287928 0.313543 0.913214 -0 - 73 O 0.712072 0.686457 0.086786 -0 - 74 O 0.212072 0.125286 0.025615 -0 - 75 O 0.787928 0.874714 0.974385 -0 - 76 O 0.900329 0.374714 0.586786 -0 - 77 O 0.099671 0.625286 0.413214 -0 - 78 O 0.599671 0.186457 0.474385 -0 - 79 O 0.400329 0.813543 0.525615 -0","# generated using pymatgen -data_Y3Mg2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.83686859 -_cell_length_b 10.83686859 -_cell_length_c 10.83686859 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Mg2(GeO4)3 -_chemical_formula_sum 'Y12 Mg8 Ge12 O48' -_cell_volume 979.69193060 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.25000000 0.37500000 0.12500000 1 - Y Y1 1 0.75000000 0.62500000 0.87500000 1 - Y Y2 1 0.75000000 0.12500000 0.37500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.37500000 0.75000000 0.12500000 1 - Y Y5 1 0.25000000 0.87500000 0.62500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.62500000 0.25000000 0.87500000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.62500000 0.87500000 0.75000000 1 - Y Y10 1 0.12500000 0.37500000 0.75000000 1 - Y Y11 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg12 1 0.00000000 0.00000000 0.00000000 1 - Mg Mg13 1 0.50000000 0.00000000 0.50000000 1 - Mg Mg14 1 0.00000000 0.50000000 0.50000000 1 - Mg Mg15 1 0.50000000 0.00000000 0.00000000 1 - Mg Mg16 1 0.50000000 0.50000000 0.00000000 1 - Mg Mg17 1 0.50000000 0.50000000 0.50000000 1 - Mg Mg18 1 0.00000000 0.00000000 0.50000000 1 - Mg Mg19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47438500 0.37471400 0.28792800 1 - O O33 1 0.52561500 0.62528600 0.71207200 1 - O O34 1 0.58678600 0.18645700 0.21207200 1 - O O35 1 0.91321400 0.12528600 0.59967100 1 - O O36 1 0.28792800 0.47438500 0.37471400 1 - O O37 1 0.31354300 0.91321400 0.28792800 1 - O O38 1 0.41321400 0.81354300 0.78792800 1 - O O39 1 0.08678600 0.87471400 0.40032900 1 - O O40 1 0.71207200 0.52561500 0.62528600 1 - O O41 1 0.68645700 0.08678600 0.71207200 1 - O O42 1 0.02561500 0.31354300 0.90032900 1 - O O43 1 0.21207200 0.58678600 0.18645700 1 - O O44 1 0.12528600 0.02561500 0.21207200 1 - O O45 1 0.97438500 0.68645700 0.09967100 1 - O O46 1 0.78792800 0.41321400 0.81354300 1 - O O47 1 0.87471400 0.97438500 0.78792800 1 - O O48 1 0.59967100 0.91321400 0.12528600 1 - O O49 1 0.18645700 0.47438500 0.59967100 1 - O O50 1 0.40032900 0.08678600 0.87471400 1 - O O51 1 0.81354300 0.52561500 0.40032900 1 - O O52 1 0.90032900 0.02561500 0.31354300 1 - O O53 1 0.37471400 0.58678600 0.90032900 1 - O O54 1 0.09967100 0.97438500 0.68645700 1 - O O55 1 0.62528600 0.41321400 0.09967100 1 - O O56 1 0.37471400 0.28792800 0.47438500 1 - O O57 1 0.58678600 0.90032900 0.37471400 1 - O O58 1 0.62528600 0.71207200 0.52561500 1 - O O59 1 0.41321400 0.09967100 0.62528600 1 - O O60 1 0.12528600 0.59967100 0.91321400 1 - O O61 1 0.02561500 0.21207200 0.12528600 1 - O O62 1 0.87471400 0.40032900 0.08678600 1 - O O63 1 0.97438500 0.78792800 0.87471400 1 - O O64 1 0.31354300 0.90032900 0.02561500 1 - O O65 1 0.91321400 0.28792800 0.31354300 1 - O O66 1 0.68645700 0.09967100 0.97438500 1 - O O67 1 0.08678600 0.71207200 0.68645700 1 - O O68 1 0.18645700 0.21207200 0.58678600 1 - O O69 1 0.47438500 0.59967100 0.18645700 1 - O O70 1 0.81354300 0.78792800 0.41321400 1 - O O71 1 0.52561500 0.40032900 0.81354300 1 - O O72 1 0.28792800 0.31354300 0.91321400 1 - O O73 1 0.71207200 0.68645700 0.08678600 1 - O O74 1 0.21207200 0.12528600 0.02561500 1 - O O75 1 0.78792800 0.87471400 0.97438500 1 - O O76 1 0.90032900 0.37471400 0.58678600 1 - O O77 1 0.09967100 0.62528600 0.41321400 1 - O O78 1 0.59967100 0.18645700 0.47438500 1 - O O79 1 0.40032900 0.81354300 0.52561500 1 -" -Tm3Sc2Al3O12,mp-1207916,Ia-3d,[],0.0038203339624978128,{'tags': []},"Full Formula (Tm12 Sc8 Al12 O48) -Reduced Formula: Tm3Sc2Al3O12 -abc : 10.690225 10.690225 10.690225 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tm 0.25 0.375 0.125 0 - 1 Tm 0.75 0.625 0.875 0 - 2 Tm 0.75 0.125 0.375 0 - 3 Tm 0.125 0.25 0.375 0 - 4 Tm 0.375 0.75 0.125 0 - 5 Tm 0.25 0.875 0.625 0 - 6 Tm 0.875 0.75 0.625 0 - 7 Tm 0.625 0.25 0.875 0 - 8 Tm 0.375 0.125 0.25 0 - 9 Tm 0.625 0.875 0.75 0 - 10 Tm 0.125 0.375 0.75 0 - 11 Tm 0.875 0.625 0.25 0 - 12 Sc 0 0 0 0 - 13 Sc 0.5 0 0.5 0 - 14 Sc 0 0.5 0.5 0 - 15 Sc 0.5 0 0 0 - 16 Sc 0.5 0.5 0 0 - 17 Sc 0.5 0.5 0.5 0 - 18 Sc 0 0 0.5 0 - 19 Sc 0 0.5 0 0 - 20 Al 0.25 0.625 0.375 0 - 21 Al 0.75 0.375 0.625 0 - 22 Al 0.75 0.875 0.125 0 - 23 Al 0.375 0.25 0.625 0 - 24 Al 0.625 0.75 0.375 0 - 25 Al 0.25 0.125 0.875 0 - 26 Al 0.125 0.75 0.875 0 - 27 Al 0.875 0.25 0.125 0 - 28 Al 0.625 0.375 0.25 0 - 29 Al 0.375 0.625 0.75 0 - 30 Al 0.875 0.125 0.75 0 - 31 Al 0.125 0.875 0.25 0 - 32 O 0.471984 0.372732 0.284405 -0 - 33 O 0.528016 0.627268 0.715595 -0 - 34 O 0.588328 0.18758 0.215595 -0 - 35 O 0.911672 0.127268 0.599252 -0 - 36 O 0.284405 0.471984 0.372732 -0 - 37 O 0.31242 0.911672 0.284405 -0 - 38 O 0.411672 0.81242 0.784405 -0 - 39 O 0.088328 0.872732 0.400748 -0 - 40 O 0.715595 0.528016 0.627268 -0 - 41 O 0.68758 0.088328 0.715595 -0 - 42 O 0.028016 0.31242 0.900748 -0 - 43 O 0.215595 0.588328 0.18758 -0 - 44 O 0.127268 0.028016 0.215595 -0 - 45 O 0.971984 0.68758 0.099252 -0 - 46 O 0.784405 0.411672 0.81242 -0 - 47 O 0.872732 0.971984 0.784405 -0 - 48 O 0.599252 0.911672 0.127268 -0 - 49 O 0.18758 0.471984 0.599252 -0 - 50 O 0.400748 0.088328 0.872732 -0 - 51 O 0.81242 0.528016 0.400748 -0 - 52 O 0.900748 0.028016 0.31242 -0 - 53 O 0.372732 0.588328 0.900748 -0 - 54 O 0.099252 0.971984 0.68758 -0 - 55 O 0.627268 0.411672 0.099252 -0 - 56 O 0.372732 0.284405 0.471984 -0 - 57 O 0.588328 0.900748 0.372732 -0 - 58 O 0.627268 0.715595 0.528016 -0 - 59 O 0.411672 0.099252 0.627268 -0 - 60 O 0.127268 0.599252 0.911672 -0 - 61 O 0.028016 0.215595 0.127268 -0 - 62 O 0.872732 0.400748 0.088328 -0 - 63 O 0.971984 0.784405 0.872732 -0 - 64 O 0.31242 0.900748 0.028016 -0 - 65 O 0.911672 0.284405 0.31242 -0 - 66 O 0.68758 0.099252 0.971984 -0 - 67 O 0.088328 0.715595 0.68758 -0 - 68 O 0.18758 0.215595 0.588328 -0 - 69 O 0.471984 0.599252 0.18758 -0 - 70 O 0.81242 0.784405 0.411672 -0 - 71 O 0.528016 0.400748 0.81242 -0 - 72 O 0.284405 0.31242 0.911672 -0 - 73 O 0.715595 0.68758 0.088328 -0 - 74 O 0.215595 0.127268 0.028016 -0 - 75 O 0.784405 0.872732 0.971984 -0 - 76 O 0.900748 0.372732 0.588328 -0 - 77 O 0.099252 0.627268 0.411672 -0 - 78 O 0.599252 0.18758 0.471984 -0 - 79 O 0.400748 0.81242 0.528016 -0","# generated using pymatgen -data_Tm3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.69022451 -_cell_length_b 10.69022451 -_cell_length_c 10.69022451 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tm3Sc2Al3O12 -_chemical_formula_sum 'Tm12 Sc8 Al12 O48' -_cell_volume 940.45623029 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tm Tm0 1 0.25000000 0.37500000 0.12500000 1 - Tm Tm1 1 0.75000000 0.62500000 0.87500000 1 - Tm Tm2 1 0.75000000 0.12500000 0.37500000 1 - Tm Tm3 1 0.12500000 0.25000000 0.37500000 1 - Tm Tm4 1 0.37500000 0.75000000 0.12500000 1 - Tm Tm5 1 0.25000000 0.87500000 0.62500000 1 - Tm Tm6 1 0.87500000 0.75000000 0.62500000 1 - Tm Tm7 1 0.62500000 0.25000000 0.87500000 1 - Tm Tm8 1 0.37500000 0.12500000 0.25000000 1 - Tm Tm9 1 0.62500000 0.87500000 0.75000000 1 - Tm Tm10 1 0.12500000 0.37500000 0.75000000 1 - Tm Tm11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Al Al20 1 0.25000000 0.62500000 0.37500000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.37500000 0.25000000 0.62500000 1 - Al Al24 1 0.62500000 0.75000000 0.37500000 1 - Al Al25 1 0.25000000 0.12500000 0.87500000 1 - Al Al26 1 0.12500000 0.75000000 0.87500000 1 - Al Al27 1 0.87500000 0.25000000 0.12500000 1 - Al Al28 1 0.62500000 0.37500000 0.25000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.87500000 0.12500000 0.75000000 1 - Al Al31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47198400 0.37273200 0.28440500 1 - O O33 1 0.52801600 0.62726800 0.71559500 1 - O O34 1 0.58832800 0.18758000 0.21559500 1 - O O35 1 0.91167200 0.12726800 0.59925200 1 - O O36 1 0.28440500 0.47198400 0.37273200 1 - O O37 1 0.31242000 0.91167200 0.28440500 1 - O O38 1 0.41167200 0.81242000 0.78440500 1 - O O39 1 0.08832800 0.87273200 0.40074800 1 - O O40 1 0.71559500 0.52801600 0.62726800 1 - O O41 1 0.68758000 0.08832800 0.71559500 1 - O O42 1 0.02801600 0.31242000 0.90074800 1 - O O43 1 0.21559500 0.58832800 0.18758000 1 - O O44 1 0.12726800 0.02801600 0.21559500 1 - O O45 1 0.97198400 0.68758000 0.09925200 1 - O O46 1 0.78440500 0.41167200 0.81242000 1 - O O47 1 0.87273200 0.97198400 0.78440500 1 - O O48 1 0.59925200 0.91167200 0.12726800 1 - O O49 1 0.18758000 0.47198400 0.59925200 1 - O O50 1 0.40074800 0.08832800 0.87273200 1 - O O51 1 0.81242000 0.52801600 0.40074800 1 - O O52 1 0.90074800 0.02801600 0.31242000 1 - O O53 1 0.37273200 0.58832800 0.90074800 1 - O O54 1 0.09925200 0.97198400 0.68758000 1 - O O55 1 0.62726800 0.41167200 0.09925200 1 - O O56 1 0.37273200 0.28440500 0.47198400 1 - O O57 1 0.58832800 0.90074800 0.37273200 1 - O O58 1 0.62726800 0.71559500 0.52801600 1 - O O59 1 0.41167200 0.09925200 0.62726800 1 - O O60 1 0.12726800 0.59925200 0.91167200 1 - O O61 1 0.02801600 0.21559500 0.12726800 1 - O O62 1 0.87273200 0.40074800 0.08832800 1 - O O63 1 0.97198400 0.78440500 0.87273200 1 - O O64 1 0.31242000 0.90074800 0.02801600 1 - O O65 1 0.91167200 0.28440500 0.31242000 1 - O O66 1 0.68758000 0.09925200 0.97198400 1 - O O67 1 0.08832800 0.71559500 0.68758000 1 - O O68 1 0.18758000 0.21559500 0.58832800 1 - O O69 1 0.47198400 0.59925200 0.18758000 1 - O O70 1 0.81242000 0.78440500 0.41167200 1 - O O71 1 0.52801600 0.40074800 0.81242000 1 - O O72 1 0.28440500 0.31242000 0.91167200 1 - O O73 1 0.71559500 0.68758000 0.08832800 1 - O O74 1 0.21559500 0.12726800 0.02801600 1 - O O75 1 0.78440500 0.87273200 0.97198400 1 - O O76 1 0.90074800 0.37273200 0.58832800 1 - O O77 1 0.09925200 0.62726800 0.41167200 1 - O O78 1 0.59925200 0.18758000 0.47198400 1 - O O79 1 0.40074800 0.81242000 0.52801600 1 -" -Y3Sc2(GaO4)3,mp-1207933,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Y3Sc2Ga3O12']}","Full Formula (Y12 Sc8 Ga12 O48) -Reduced Formula: Y3Sc2(GaO4)3 -abc : 10.923315 10.923315 10.923315 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.25 0.375 0.125 -0 - 1 Y 0.75 0.625 0.875 -0 - 2 Y 0.75 0.125 0.375 -0 - 3 Y 0.125 0.25 0.375 -0 - 4 Y 0.375 0.75 0.125 -0 - 5 Y 0.25 0.875 0.625 -0 - 6 Y 0.875 0.75 0.625 -0 - 7 Y 0.625 0.25 0.875 -0 - 8 Y 0.375 0.125 0.25 -0 - 9 Y 0.625 0.875 0.75 -0 - 10 Y 0.125 0.375 0.75 -0 - 11 Y 0.875 0.625 0.25 -0 - 12 Sc 0 0 0 -0 - 13 Sc 0.5 0 0.5 -0 - 14 Sc 0 0.5 0.5 -0 - 15 Sc 0.5 0 0 -0 - 16 Sc 0.5 0.5 0 -0 - 17 Sc 0.5 0.5 0.5 -0 - 18 Sc 0 0 0.5 -0 - 19 Sc 0 0.5 0 -0 - 20 Ga 0.25 0.625 0.375 -0 - 21 Ga 0.75 0.375 0.625 -0 - 22 Ga 0.75 0.875 0.125 -0 - 23 Ga 0.375 0.25 0.625 -0 - 24 Ga 0.625 0.75 0.375 -0 - 25 Ga 0.25 0.125 0.875 -0 - 26 Ga 0.125 0.75 0.875 -0 - 27 Ga 0.875 0.25 0.125 -0 - 28 Ga 0.625 0.375 0.25 -0 - 29 Ga 0.375 0.625 0.75 -0 - 30 Ga 0.875 0.125 0.75 -0 - 31 Ga 0.125 0.875 0.25 -0 - 32 O 0.469558 0.37321 0.287269 0 - 33 O 0.530442 0.62679 0.712731 0 - 34 O 0.585941 0.182289 0.212731 0 - 35 O 0.914059 0.12679 0.596348 0 - 36 O 0.287269 0.469558 0.37321 0 - 37 O 0.317711 0.914059 0.287269 0 - 38 O 0.414059 0.817711 0.787269 0 - 39 O 0.085941 0.87321 0.403652 0 - 40 O 0.712731 0.530442 0.62679 0 - 41 O 0.682289 0.085941 0.712731 0 - 42 O 0.030442 0.317711 0.903652 0 - 43 O 0.212731 0.585941 0.182289 0 - 44 O 0.12679 0.030442 0.212731 0 - 45 O 0.969558 0.682289 0.096348 0 - 46 O 0.787269 0.414059 0.817711 0 - 47 O 0.87321 0.969558 0.787269 0 - 48 O 0.596348 0.914059 0.12679 0 - 49 O 0.182289 0.469558 0.596348 0 - 50 O 0.403652 0.085941 0.87321 0 - 51 O 0.817711 0.530442 0.403652 0 - 52 O 0.903652 0.030442 0.317711 0 - 53 O 0.37321 0.585941 0.903652 0 - 54 O 0.096348 0.969558 0.682289 0 - 55 O 0.62679 0.414059 0.096348 0 - 56 O 0.37321 0.287269 0.469558 0 - 57 O 0.585941 0.903652 0.37321 0 - 58 O 0.62679 0.712731 0.530442 0 - 59 O 0.414059 0.096348 0.62679 0 - 60 O 0.12679 0.596348 0.914059 0 - 61 O 0.030442 0.212731 0.12679 0 - 62 O 0.87321 0.403652 0.085941 0 - 63 O 0.969558 0.787269 0.87321 0 - 64 O 0.317711 0.903652 0.030442 0 - 65 O 0.914059 0.287269 0.317711 0 - 66 O 0.682289 0.096348 0.969558 0 - 67 O 0.085941 0.712731 0.682289 0 - 68 O 0.182289 0.212731 0.585941 0 - 69 O 0.469558 0.596348 0.182289 0 - 70 O 0.817711 0.787269 0.414059 0 - 71 O 0.530442 0.403652 0.817711 0 - 72 O 0.287269 0.317711 0.914059 0 - 73 O 0.712731 0.682289 0.085941 0 - 74 O 0.212731 0.12679 0.030442 0 - 75 O 0.787269 0.87321 0.969558 0 - 76 O 0.903652 0.37321 0.585941 0 - 77 O 0.096348 0.62679 0.414059 0 - 78 O 0.596348 0.182289 0.469558 0 - 79 O 0.403652 0.817711 0.530442 0","# generated using pymatgen -data_Y3Sc2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.92331525 -_cell_length_b 10.92331525 -_cell_length_c 10.92331525 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Sc2(GaO4)3 -_chemical_formula_sum 'Y12 Sc8 Ga12 O48' -_cell_volume 1003.32471947 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.25000000 0.37500000 0.12500000 1 - Y Y1 1 0.75000000 0.62500000 0.87500000 1 - Y Y2 1 0.75000000 0.12500000 0.37500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.37500000 0.75000000 0.12500000 1 - Y Y5 1 0.25000000 0.87500000 0.62500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.62500000 0.25000000 0.87500000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.62500000 0.87500000 0.75000000 1 - Y Y10 1 0.12500000 0.37500000 0.75000000 1 - Y Y11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.46955800 0.37321000 0.28726900 1 - O O33 1 0.53044200 0.62679000 0.71273100 1 - O O34 1 0.58594100 0.18228900 0.21273100 1 - O O35 1 0.91405900 0.12679000 0.59634800 1 - O O36 1 0.28726900 0.46955800 0.37321000 1 - O O37 1 0.31771100 0.91405900 0.28726900 1 - O O38 1 0.41405900 0.81771100 0.78726900 1 - O O39 1 0.08594100 0.87321000 0.40365200 1 - O O40 1 0.71273100 0.53044200 0.62679000 1 - O O41 1 0.68228900 0.08594100 0.71273100 1 - O O42 1 0.03044200 0.31771100 0.90365200 1 - O O43 1 0.21273100 0.58594100 0.18228900 1 - O O44 1 0.12679000 0.03044200 0.21273100 1 - O O45 1 0.96955800 0.68228900 0.09634800 1 - O O46 1 0.78726900 0.41405900 0.81771100 1 - O O47 1 0.87321000 0.96955800 0.78726900 1 - O O48 1 0.59634800 0.91405900 0.12679000 1 - O O49 1 0.18228900 0.46955800 0.59634800 1 - O O50 1 0.40365200 0.08594100 0.87321000 1 - O O51 1 0.81771100 0.53044200 0.40365200 1 - O O52 1 0.90365200 0.03044200 0.31771100 1 - O O53 1 0.37321000 0.58594100 0.90365200 1 - O O54 1 0.09634800 0.96955800 0.68228900 1 - O O55 1 0.62679000 0.41405900 0.09634800 1 - O O56 1 0.37321000 0.28726900 0.46955800 1 - O O57 1 0.58594100 0.90365200 0.37321000 1 - O O58 1 0.62679000 0.71273100 0.53044200 1 - O O59 1 0.41405900 0.09634800 0.62679000 1 - O O60 1 0.12679000 0.59634800 0.91405900 1 - O O61 1 0.03044200 0.21273100 0.12679000 1 - O O62 1 0.87321000 0.40365200 0.08594100 1 - O O63 1 0.96955800 0.78726900 0.87321000 1 - O O64 1 0.31771100 0.90365200 0.03044200 1 - O O65 1 0.91405900 0.28726900 0.31771100 1 - O O66 1 0.68228900 0.09634800 0.96955800 1 - O O67 1 0.08594100 0.71273100 0.68228900 1 - O O68 1 0.18228900 0.21273100 0.58594100 1 - O O69 1 0.46955800 0.59634800 0.18228900 1 - O O70 1 0.81771100 0.78726900 0.41405900 1 - O O71 1 0.53044200 0.40365200 0.81771100 1 - O O72 1 0.28726900 0.31771100 0.91405900 1 - O O73 1 0.71273100 0.68228900 0.08594100 1 - O O74 1 0.21273100 0.12679000 0.03044200 1 - O O75 1 0.78726900 0.87321000 0.96955800 1 - O O76 1 0.90365200 0.37321000 0.58594100 1 - O O77 1 0.09634800 0.62679000 0.41405900 1 - O O78 1 0.59634800 0.18228900 0.46955800 1 - O O79 1 0.40365200 0.81771100 0.53044200 1 -" -Y3In2(GaO4)3,mp-1207946,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Y3Ga3In2O12']}","Full Formula (Y12 In8 Ga12 O48) -Reduced Formula: Y3In2(GaO4)3 -abc : 11.025511 11.025511 11.025511 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.25 0.375 0.125 -0 - 1 Y 0.75 0.625 0.875 -0 - 2 Y 0.75 0.125 0.375 -0 - 3 Y 0.125 0.25 0.375 -0 - 4 Y 0.375 0.75 0.125 -0 - 5 Y 0.25 0.875 0.625 -0 - 6 Y 0.875 0.75 0.625 -0 - 7 Y 0.625 0.25 0.875 -0 - 8 Y 0.375 0.125 0.25 -0 - 9 Y 0.625 0.875 0.75 -0 - 10 Y 0.125 0.375 0.75 -0 - 11 Y 0.875 0.625 0.25 -0 - 12 In 0 0 0 0 - 13 In 0.5 0 0.5 0 - 14 In 0 0.5 0.5 -0 - 15 In 0.5 0 0 0 - 16 In 0.5 0.5 0 0 - 17 In 0.5 0.5 0.5 0 - 18 In 0 0 0.5 -0 - 19 In 0 0.5 0 0 - 20 Ga 0.25 0.625 0.375 -0 - 21 Ga 0.75 0.375 0.625 -0 - 22 Ga 0.75 0.875 0.125 -0 - 23 Ga 0.375 0.25 0.625 -0 - 24 Ga 0.625 0.75 0.375 -0 - 25 Ga 0.25 0.125 0.875 -0 - 26 Ga 0.125 0.75 0.875 -0 - 27 Ga 0.875 0.25 0.125 -0 - 28 Ga 0.625 0.375 0.25 -0 - 29 Ga 0.375 0.625 0.75 -0 - 30 Ga 0.875 0.125 0.75 -0 - 31 Ga 0.125 0.875 0.25 -0 - 32 O 0.467163 0.370106 0.281975 0 - 33 O 0.532837 0.629894 0.718025 0 - 34 O 0.588131 0.185188 0.218025 0 - 35 O 0.911869 0.129894 0.597057 0 - 36 O 0.281975 0.467163 0.370106 0 - 37 O 0.314812 0.911869 0.281975 0 - 38 O 0.411869 0.814812 0.781975 0 - 39 O 0.088131 0.870106 0.402943 0 - 40 O 0.718025 0.532837 0.629894 0 - 41 O 0.685188 0.088131 0.718025 0 - 42 O 0.032837 0.314812 0.902943 0 - 43 O 0.218025 0.588131 0.185188 0 - 44 O 0.129894 0.032837 0.218025 0 - 45 O 0.967163 0.685188 0.097057 0 - 46 O 0.781975 0.411869 0.814812 0 - 47 O 0.870106 0.967163 0.781975 0 - 48 O 0.597057 0.911869 0.129894 0 - 49 O 0.185188 0.467163 0.597057 0 - 50 O 0.402943 0.088131 0.870106 0 - 51 O 0.814812 0.532837 0.402943 0 - 52 O 0.902943 0.032837 0.314812 0 - 53 O 0.370106 0.588131 0.902943 0 - 54 O 0.097057 0.967163 0.685188 0 - 55 O 0.629894 0.411869 0.097057 0 - 56 O 0.370106 0.281975 0.467163 0 - 57 O 0.588131 0.902943 0.370106 0 - 58 O 0.629894 0.718025 0.532837 0 - 59 O 0.411869 0.097057 0.629894 0 - 60 O 0.129894 0.597057 0.911869 0 - 61 O 0.032837 0.218025 0.129894 0 - 62 O 0.870106 0.402943 0.088131 0 - 63 O 0.967163 0.781975 0.870106 0 - 64 O 0.314812 0.902943 0.032837 0 - 65 O 0.911869 0.281975 0.314812 0 - 66 O 0.685188 0.097057 0.967163 0 - 67 O 0.088131 0.718025 0.685188 0 - 68 O 0.185188 0.218025 0.588131 0 - 69 O 0.467163 0.597057 0.185188 0 - 70 O 0.814812 0.781975 0.411869 0 - 71 O 0.532837 0.402943 0.814812 0 - 72 O 0.281975 0.314812 0.911869 0 - 73 O 0.718025 0.685188 0.088131 0 - 74 O 0.218025 0.129894 0.032837 0 - 75 O 0.781975 0.870106 0.967163 0 - 76 O 0.902943 0.370106 0.588131 0 - 77 O 0.097057 0.629894 0.411869 0 - 78 O 0.597057 0.185188 0.467163 0 - 79 O 0.402943 0.814812 0.532837 0","# generated using pymatgen -data_Y3In2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.02551144 -_cell_length_b 11.02551144 -_cell_length_c 11.02551144 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3In2(GaO4)3 -_chemical_formula_sum 'Y12 In8 Ga12 O48' -_cell_volume 1031.74967874 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.25000000 0.37500000 0.12500000 1 - Y Y1 1 0.75000000 0.62500000 0.87500000 1 - Y Y2 1 0.75000000 0.12500000 0.37500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.37500000 0.75000000 0.12500000 1 - Y Y5 1 0.25000000 0.87500000 0.62500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.62500000 0.25000000 0.87500000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.62500000 0.87500000 0.75000000 1 - Y Y10 1 0.12500000 0.37500000 0.75000000 1 - Y Y11 1 0.87500000 0.62500000 0.25000000 1 - In In12 1 0.00000000 0.00000000 0.00000000 1 - In In13 1 0.50000000 0.00000000 0.50000000 1 - In In14 1 0.00000000 0.50000000 0.50000000 1 - In In15 1 0.50000000 0.00000000 0.00000000 1 - In In16 1 0.50000000 0.50000000 0.00000000 1 - In In17 1 0.50000000 0.50000000 0.50000000 1 - In In18 1 0.00000000 0.00000000 0.50000000 1 - In In19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.46716300 0.37010600 0.28197500 1 - O O33 1 0.53283700 0.62989400 0.71802500 1 - O O34 1 0.58813100 0.18518800 0.21802500 1 - O O35 1 0.91186900 0.12989400 0.59705700 1 - O O36 1 0.28197500 0.46716300 0.37010600 1 - O O37 1 0.31481200 0.91186900 0.28197500 1 - O O38 1 0.41186900 0.81481200 0.78197500 1 - O O39 1 0.08813100 0.87010600 0.40294300 1 - O O40 1 0.71802500 0.53283700 0.62989400 1 - O O41 1 0.68518800 0.08813100 0.71802500 1 - O O42 1 0.03283700 0.31481200 0.90294300 1 - O O43 1 0.21802500 0.58813100 0.18518800 1 - O O44 1 0.12989400 0.03283700 0.21802500 1 - O O45 1 0.96716300 0.68518800 0.09705700 1 - O O46 1 0.78197500 0.41186900 0.81481200 1 - O O47 1 0.87010600 0.96716300 0.78197500 1 - O O48 1 0.59705700 0.91186900 0.12989400 1 - O O49 1 0.18518800 0.46716300 0.59705700 1 - O O50 1 0.40294300 0.08813100 0.87010600 1 - O O51 1 0.81481200 0.53283700 0.40294300 1 - O O52 1 0.90294300 0.03283700 0.31481200 1 - O O53 1 0.37010600 0.58813100 0.90294300 1 - O O54 1 0.09705700 0.96716300 0.68518800 1 - O O55 1 0.62989400 0.41186900 0.09705700 1 - O O56 1 0.37010600 0.28197500 0.46716300 1 - O O57 1 0.58813100 0.90294300 0.37010600 1 - O O58 1 0.62989400 0.71802500 0.53283700 1 - O O59 1 0.41186900 0.09705700 0.62989400 1 - O O60 1 0.12989400 0.59705700 0.91186900 1 - O O61 1 0.03283700 0.21802500 0.12989400 1 - O O62 1 0.87010600 0.40294300 0.08813100 1 - O O63 1 0.96716300 0.78197500 0.87010600 1 - O O64 1 0.31481200 0.90294300 0.03283700 1 - O O65 1 0.91186900 0.28197500 0.31481200 1 - O O66 1 0.68518800 0.09705700 0.96716300 1 - O O67 1 0.08813100 0.71802500 0.68518800 1 - O O68 1 0.18518800 0.21802500 0.58813100 1 - O O69 1 0.46716300 0.59705700 0.18518800 1 - O O70 1 0.81481200 0.78197500 0.41186900 1 - O O71 1 0.53283700 0.40294300 0.81481200 1 - O O72 1 0.28197500 0.31481200 0.91186900 1 - O O73 1 0.71802500 0.68518800 0.08813100 1 - O O74 1 0.21802500 0.12989400 0.03283700 1 - O O75 1 0.78197500 0.87010600 0.96716300 1 - O O76 1 0.90294300 0.37010600 0.58813100 1 - O O77 1 0.09705700 0.62989400 0.41186900 1 - O O78 1 0.59705700 0.18518800 0.46716300 1 - O O79 1 0.40294300 0.81481200 0.53283700 1 -" -Y3Cr2(GaO4)3,mp-1207967,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Y3Cr2Ga3O12']}","Full Formula (Y12 Cr8 Ga12 O48) -Reduced Formula: Y3Cr2(GaO4)3 -abc : 10.782191 10.782191 10.782191 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.25 0.375 0.125 0.007 - 1 Y 0.75 0.625 0.875 0.007 - 2 Y 0.75 0.125 0.375 0.007 - 3 Y 0.125 0.25 0.375 0.007 - 4 Y 0.375 0.75 0.125 0.007 - 5 Y 0.25 0.875 0.625 0.007 - 6 Y 0.875 0.75 0.625 0.007 - 7 Y 0.625 0.25 0.875 0.007 - 8 Y 0.375 0.125 0.25 0.007 - 9 Y 0.625 0.875 0.75 0.007 - 10 Y 0.125 0.375 0.75 0.007 - 11 Y 0.875 0.625 0.25 0.007 - 12 Cr 0 0 0 2.949 - 13 Cr 0.5 0 0.5 2.948 - 14 Cr 0 0.5 0.5 2.948 - 15 Cr 0.5 0 0 2.948 - 16 Cr 0.5 0.5 0 2.949 - 17 Cr 0.5 0.5 0.5 2.949 - 18 Cr 0 0 0.5 2.948 - 19 Cr 0 0.5 0 2.949 - 20 Ga 0.25 0.625 0.375 0.009 - 21 Ga 0.75 0.375 0.625 0.009 - 22 Ga 0.75 0.875 0.125 0.009 - 23 Ga 0.375 0.25 0.625 0.009 - 24 Ga 0.625 0.75 0.375 0.009 - 25 Ga 0.25 0.125 0.875 0.009 - 26 Ga 0.125 0.75 0.875 0.009 - 27 Ga 0.875 0.25 0.125 0.009 - 28 Ga 0.625 0.375 0.25 0.009 - 29 Ga 0.375 0.625 0.75 0.009 - 30 Ga 0.875 0.125 0.75 0.009 - 31 Ga 0.125 0.875 0.25 0.009 - 32 O 0.471051 0.375882 0.292986 -0.008 - 33 O 0.528949 0.624118 0.707014 -0.008 - 34 O 0.582896 0.178065 0.207014 -0.008 - 35 O 0.917104 0.124118 0.595169 -0.008 - 36 O 0.292986 0.471051 0.375882 -0.008 - 37 O 0.321935 0.917104 0.292986 -0.007 - 38 O 0.417104 0.821935 0.792986 -0.008 - 39 O 0.082896 0.875882 0.404831 -0.008 - 40 O 0.707014 0.528949 0.624118 -0.008 - 41 O 0.678065 0.082896 0.707014 -0.007 - 42 O 0.028949 0.321935 0.904831 -0.008 - 43 O 0.207014 0.582896 0.178065 -0.008 - 44 O 0.124118 0.028949 0.207014 -0.008 - 45 O 0.971051 0.678065 0.095169 -0.008 - 46 O 0.792986 0.417104 0.821935 -0.008 - 47 O 0.875882 0.971051 0.792986 -0.008 - 48 O 0.595169 0.917104 0.124118 -0.008 - 49 O 0.178065 0.471051 0.595169 -0.007 - 50 O 0.404831 0.082896 0.875882 -0.008 - 51 O 0.821935 0.528949 0.404831 -0.007 - 52 O 0.904831 0.028949 0.321935 -0.008 - 53 O 0.375882 0.582896 0.904831 -0.008 - 54 O 0.095169 0.971051 0.678065 -0.008 - 55 O 0.624118 0.417104 0.095169 -0.008 - 56 O 0.375882 0.292986 0.471051 -0.008 - 57 O 0.582896 0.904831 0.375882 -0.008 - 58 O 0.624118 0.707014 0.528949 -0.008 - 59 O 0.417104 0.095169 0.624118 -0.008 - 60 O 0.124118 0.595169 0.917104 -0.008 - 61 O 0.028949 0.207014 0.124118 -0.008 - 62 O 0.875882 0.404831 0.082896 -0.008 - 63 O 0.971051 0.792986 0.875882 -0.008 - 64 O 0.321935 0.904831 0.028949 -0.007 - 65 O 0.917104 0.292986 0.321935 -0.008 - 66 O 0.678065 0.095169 0.971051 -0.007 - 67 O 0.082896 0.707014 0.678065 -0.008 - 68 O 0.178065 0.207014 0.582896 -0.007 - 69 O 0.471051 0.595169 0.178065 -0.008 - 70 O 0.821935 0.792986 0.417104 -0.007 - 71 O 0.528949 0.404831 0.821935 -0.008 - 72 O 0.292986 0.321935 0.917104 -0.008 - 73 O 0.707014 0.678065 0.082896 -0.008 - 74 O 0.207014 0.124118 0.028949 -0.008 - 75 O 0.792986 0.875882 0.971051 -0.008 - 76 O 0.904831 0.375882 0.582896 -0.008 - 77 O 0.095169 0.624118 0.417104 -0.008 - 78 O 0.595169 0.178065 0.471051 -0.008 - 79 O 0.404831 0.821935 0.528949 -0.008","# generated using pymatgen -data_Y3Cr2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.78219121 -_cell_length_b 10.78219121 -_cell_length_c 10.78219121 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Cr2(GaO4)3 -_chemical_formula_sum 'Y12 Cr8 Ga12 O48' -_cell_volume 964.93752902 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.25000000 0.37500000 0.12500000 1 - Y Y1 1 0.75000000 0.62500000 0.87500000 1 - Y Y2 1 0.75000000 0.12500000 0.37500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.37500000 0.75000000 0.12500000 1 - Y Y5 1 0.25000000 0.87500000 0.62500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.62500000 0.25000000 0.87500000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.62500000 0.87500000 0.75000000 1 - Y Y10 1 0.12500000 0.37500000 0.75000000 1 - Y Y11 1 0.87500000 0.62500000 0.25000000 1 - Cr Cr12 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr13 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr16 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr17 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr18 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47105100 0.37588200 0.29298600 1 - O O33 1 0.52894900 0.62411800 0.70701400 1 - O O34 1 0.58289600 0.17806500 0.20701400 1 - O O35 1 0.91710400 0.12411800 0.59516900 1 - O O36 1 0.29298600 0.47105100 0.37588200 1 - O O37 1 0.32193500 0.91710400 0.29298600 1 - O O38 1 0.41710400 0.82193500 0.79298600 1 - O O39 1 0.08289600 0.87588200 0.40483100 1 - O O40 1 0.70701400 0.52894900 0.62411800 1 - O O41 1 0.67806500 0.08289600 0.70701400 1 - O O42 1 0.02894900 0.32193500 0.90483100 1 - O O43 1 0.20701400 0.58289600 0.17806500 1 - O O44 1 0.12411800 0.02894900 0.20701400 1 - O O45 1 0.97105100 0.67806500 0.09516900 1 - O O46 1 0.79298600 0.41710400 0.82193500 1 - O O47 1 0.87588200 0.97105100 0.79298600 1 - O O48 1 0.59516900 0.91710400 0.12411800 1 - O O49 1 0.17806500 0.47105100 0.59516900 1 - O O50 1 0.40483100 0.08289600 0.87588200 1 - O O51 1 0.82193500 0.52894900 0.40483100 1 - O O52 1 0.90483100 0.02894900 0.32193500 1 - O O53 1 0.37588200 0.58289600 0.90483100 1 - O O54 1 0.09516900 0.97105100 0.67806500 1 - O O55 1 0.62411800 0.41710400 0.09516900 1 - O O56 1 0.37588200 0.29298600 0.47105100 1 - O O57 1 0.58289600 0.90483100 0.37588200 1 - O O58 1 0.62411800 0.70701400 0.52894900 1 - O O59 1 0.41710400 0.09516900 0.62411800 1 - O O60 1 0.12411800 0.59516900 0.91710400 1 - O O61 1 0.02894900 0.20701400 0.12411800 1 - O O62 1 0.87588200 0.40483100 0.08289600 1 - O O63 1 0.97105100 0.79298600 0.87588200 1 - O O64 1 0.32193500 0.90483100 0.02894900 1 - O O65 1 0.91710400 0.29298600 0.32193500 1 - O O66 1 0.67806500 0.09516900 0.97105100 1 - O O67 1 0.08289600 0.70701400 0.67806500 1 - O O68 1 0.17806500 0.20701400 0.58289600 1 - O O69 1 0.47105100 0.59516900 0.17806500 1 - O O70 1 0.82193500 0.79298600 0.41710400 1 - O O71 1 0.52894900 0.40483100 0.82193500 1 - O O72 1 0.29298600 0.32193500 0.91710400 1 - O O73 1 0.70701400 0.67806500 0.08289600 1 - O O74 1 0.20701400 0.12411800 0.02894900 1 - O O75 1 0.79298600 0.87588200 0.97105100 1 - O O76 1 0.90483100 0.37588200 0.58289600 1 - O O77 1 0.09516900 0.62411800 0.41710400 1 - O O78 1 0.59516900 0.17806500 0.47105100 1 - O O79 1 0.40483100 0.82193500 0.52894900 1 -" -V2Cd3(GeO4)3,mp-1207985,Ia-3d,[],0.041052070906249405,{'tags': ['garnet family']},"Full Formula (V8 Cd12 Ge12 O48) -Reduced Formula: V2Cd3(GeO4)3 -abc : 10.838580 10.838580 10.838580 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 V 0 0 0 1.979 - 1 V 0.5 0 0.5 1.903 - 2 V 0 0.5 0.5 1.903 - 3 V 0.5 0 0 1.903 - 4 V 0.5 0.5 0 1.979 - 5 V 0.5 0.5 0.5 1.979 - 6 V 0 0 0.5 1.903 - 7 V 0 0.5 0 1.979 - 8 Cd 0.25 0.375 0.125 0.014 - 9 Cd 0.75 0.625 0.875 0.014 - 10 Cd 0.75 0.125 0.375 0.012 - 11 Cd 0.125 0.25 0.375 0.014 - 12 Cd 0.375 0.75 0.125 0.014 - 13 Cd 0.25 0.875 0.625 0.012 - 14 Cd 0.875 0.75 0.625 0.014 - 15 Cd 0.625 0.25 0.875 0.014 - 16 Cd 0.375 0.125 0.25 0.014 - 17 Cd 0.625 0.875 0.75 0.014 - 18 Cd 0.125 0.375 0.75 0.014 - 19 Cd 0.875 0.625 0.25 0.014 - 20 Ge 0.25 0.625 0.375 0.014 - 21 Ge 0.75 0.375 0.625 0.014 - 22 Ge 0.75 0.875 0.125 0.014 - 23 Ge 0.375 0.25 0.625 0.014 - 24 Ge 0.625 0.75 0.375 0.014 - 25 Ge 0.25 0.125 0.875 0.014 - 26 Ge 0.125 0.75 0.875 0.014 - 27 Ge 0.875 0.25 0.125 0.014 - 28 Ge 0.625 0.375 0.25 0.014 - 29 Ge 0.375 0.625 0.75 0.014 - 30 Ge 0.875 0.125 0.75 0.014 - 31 Ge 0.125 0.875 0.25 0.014 - 32 O 0.484225 0.380263 0.299059 -0.021 - 33 O 0.515775 0.619737 0.700941 -0.021 - 34 O 0.581204 0.185166 0.200941 -0.024 - 35 O 0.918796 0.119737 0.603962 -0.024 - 36 O 0.299059 0.484225 0.380263 -0.016 - 37 O 0.314834 0.918796 0.299059 -0.023 - 38 O 0.418796 0.814834 0.799059 -0.024 - 39 O 0.081204 0.880263 0.396038 -0.024 - 40 O 0.700941 0.515775 0.619737 -0.016 - 41 O 0.685166 0.081204 0.700941 -0.023 - 42 O 0.015775 0.314834 0.896038 -0.021 - 43 O 0.200941 0.581204 0.185166 -0.016 - 44 O 0.119737 0.015775 0.200941 -0.02 - 45 O 0.984225 0.685166 0.103962 -0.021 - 46 O 0.799059 0.418796 0.814834 -0.016 - 47 O 0.880263 0.984225 0.799059 -0.02 - 48 O 0.603962 0.918796 0.119737 -0.021 - 49 O 0.185166 0.484225 0.603962 -0.023 - 50 O 0.396038 0.081204 0.880263 -0.021 - 51 O 0.814834 0.515775 0.396038 -0.023 - 52 O 0.896038 0.015775 0.314834 -0.021 - 53 O 0.380263 0.581204 0.896038 -0.02 - 54 O 0.103962 0.984225 0.685166 -0.021 - 55 O 0.619737 0.418796 0.103962 -0.02 - 56 O 0.380263 0.299059 0.484225 -0.02 - 57 O 0.581204 0.896038 0.380263 -0.024 - 58 O 0.619737 0.700941 0.515775 -0.02 - 59 O 0.418796 0.103962 0.619737 -0.024 - 60 O 0.119737 0.603962 0.918796 -0.02 - 61 O 0.015775 0.200941 0.119737 -0.021 - 62 O 0.880263 0.396038 0.081204 -0.02 - 63 O 0.984225 0.799059 0.880263 -0.021 - 64 O 0.314834 0.896038 0.015775 -0.023 - 65 O 0.918796 0.299059 0.314834 -0.024 - 66 O 0.685166 0.103962 0.984225 -0.023 - 67 O 0.081204 0.700941 0.685166 -0.024 - 68 O 0.185166 0.200941 0.581204 -0.023 - 69 O 0.484225 0.603962 0.185166 -0.021 - 70 O 0.814834 0.799059 0.418796 -0.023 - 71 O 0.515775 0.396038 0.814834 -0.021 - 72 O 0.299059 0.314834 0.918796 -0.016 - 73 O 0.700941 0.685166 0.081204 -0.016 - 74 O 0.200941 0.119737 0.015775 -0.016 - 75 O 0.799059 0.880263 0.984225 -0.016 - 76 O 0.896038 0.380263 0.581204 -0.021 - 77 O 0.103962 0.619737 0.418796 -0.021 - 78 O 0.603962 0.185166 0.484225 -0.021 - 79 O 0.396038 0.814834 0.515775 -0.021","# generated using pymatgen -data_V2Cd3(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.83857986 -_cell_length_b 10.83857986 -_cell_length_c 10.83857986 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural V2Cd3(GeO4)3 -_chemical_formula_sum 'V8 Cd12 Ge12 O48' -_cell_volume 980.15611777 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - V V0 1 0.00000000 0.00000000 0.00000000 1 - V V1 1 0.50000000 0.00000000 0.50000000 1 - V V2 1 0.00000000 0.50000000 0.50000000 1 - V V3 1 0.50000000 0.00000000 0.00000000 1 - V V4 1 0.50000000 0.50000000 0.00000000 1 - V V5 1 0.50000000 0.50000000 0.50000000 1 - V V6 1 0.00000000 0.00000000 0.50000000 1 - V V7 1 0.00000000 0.50000000 0.00000000 1 - Cd Cd8 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd9 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd10 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd11 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd12 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd13 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd14 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd15 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd16 1 0.37500000 0.12500000 0.25000000 1 - Cd Cd17 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd18 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd19 1 0.87500000 0.62500000 0.25000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48422500 0.38026300 0.29905900 1 - O O33 1 0.51577500 0.61973700 0.70094100 1 - O O34 1 0.58120400 0.18516600 0.20094100 1 - O O35 1 0.91879600 0.11973700 0.60396200 1 - O O36 1 0.29905900 0.48422500 0.38026300 1 - O O37 1 0.31483400 0.91879600 0.29905900 1 - O O38 1 0.41879600 0.81483400 0.79905900 1 - O O39 1 0.08120400 0.88026300 0.39603800 1 - O O40 1 0.70094100 0.51577500 0.61973700 1 - O O41 1 0.68516600 0.08120400 0.70094100 1 - O O42 1 0.01577500 0.31483400 0.89603800 1 - O O43 1 0.20094100 0.58120400 0.18516600 1 - O O44 1 0.11973700 0.01577500 0.20094100 1 - O O45 1 0.98422500 0.68516600 0.10396200 1 - O O46 1 0.79905900 0.41879600 0.81483400 1 - O O47 1 0.88026300 0.98422500 0.79905900 1 - O O48 1 0.60396200 0.91879600 0.11973700 1 - O O49 1 0.18516600 0.48422500 0.60396200 1 - O O50 1 0.39603800 0.08120400 0.88026300 1 - O O51 1 0.81483400 0.51577500 0.39603800 1 - O O52 1 0.89603800 0.01577500 0.31483400 1 - O O53 1 0.38026300 0.58120400 0.89603800 1 - O O54 1 0.10396200 0.98422500 0.68516600 1 - O O55 1 0.61973700 0.41879600 0.10396200 1 - O O56 1 0.38026300 0.29905900 0.48422500 1 - O O57 1 0.58120400 0.89603800 0.38026300 1 - O O58 1 0.61973700 0.70094100 0.51577500 1 - O O59 1 0.41879600 0.10396200 0.61973700 1 - O O60 1 0.11973700 0.60396200 0.91879600 1 - O O61 1 0.01577500 0.20094100 0.11973700 1 - O O62 1 0.88026300 0.39603800 0.08120400 1 - O O63 1 0.98422500 0.79905900 0.88026300 1 - O O64 1 0.31483400 0.89603800 0.01577500 1 - O O65 1 0.91879600 0.29905900 0.31483400 1 - O O66 1 0.68516600 0.10396200 0.98422500 1 - O O67 1 0.08120400 0.70094100 0.68516600 1 - O O68 1 0.18516600 0.20094100 0.58120400 1 - O O69 1 0.48422500 0.60396200 0.18516600 1 - O O70 1 0.81483400 0.79905900 0.41879600 1 - O O71 1 0.51577500 0.39603800 0.81483400 1 - O O72 1 0.29905900 0.31483400 0.91879600 1 - O O73 1 0.70094100 0.68516600 0.08120400 1 - O O74 1 0.20094100 0.11973700 0.01577500 1 - O O75 1 0.79905900 0.88026300 0.98422500 1 - O O76 1 0.89603800 0.38026300 0.58120400 1 - O O77 1 0.10396200 0.61973700 0.41879600 1 - O O78 1 0.60396200 0.18516600 0.48422500 1 - O O79 1 0.39603800 0.81483400 0.51577500 1 -" -Y3Ga3(FeO6)2,mp-1208208,Ia-3d,[],0.0,"{'tags': ['Y3FeGa4O12', 'garnet family', 'Y3Al5O12']}","Full Formula (Y12 Ga12 Fe8 O48) -Reduced Formula: Y3Ga3(FeO6)2 -abc : 10.805910 10.805910 10.805910 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.25 0.375 0.125 0.01 - 1 Y 0.75 0.625 0.875 0.01 - 2 Y 0.75 0.125 0.375 0.01 - 3 Y 0.125 0.25 0.375 0.01 - 4 Y 0.375 0.75 0.125 0.01 - 5 Y 0.25 0.875 0.625 0.01 - 6 Y 0.875 0.75 0.625 0.01 - 7 Y 0.625 0.25 0.875 0.01 - 8 Y 0.375 0.125 0.25 0.01 - 9 Y 0.625 0.875 0.75 0.01 - 10 Y 0.125 0.375 0.75 0.01 - 11 Y 0.875 0.625 0.25 0.01 - 12 Ga 0.25 0.625 0.375 0.023 - 13 Ga 0.75 0.375 0.625 0.023 - 14 Ga 0.75 0.875 0.125 0.023 - 15 Ga 0.375 0.25 0.625 0.023 - 16 Ga 0.625 0.75 0.375 0.023 - 17 Ga 0.25 0.125 0.875 0.023 - 18 Ga 0.125 0.75 0.875 0.023 - 19 Ga 0.875 0.25 0.125 0.023 - 20 Ga 0.625 0.375 0.25 0.023 - 21 Ga 0.375 0.625 0.75 0.023 - 22 Ga 0.875 0.125 0.75 0.023 - 23 Ga 0.125 0.875 0.25 0.023 - 24 Fe 0 0 0 4.357 - 25 Fe 0.5 0 0.5 4.358 - 26 Fe 0 0.5 0.5 4.358 - 27 Fe 0.5 0 0 4.358 - 28 Fe 0.5 0.5 0 4.357 - 29 Fe 0.5 0.5 0.5 4.357 - 30 Fe 0 0 0.5 4.358 - 31 Fe 0 0.5 0 4.357 - 32 O 0.470996 0.376269 0.291977 0.081 - 33 O 0.529004 0.623731 0.708023 0.081 - 34 O 0.584292 0.179019 0.208023 0.081 - 35 O 0.915708 0.123731 0.594727 0.081 - 36 O 0.291977 0.470996 0.376269 0.082 - 37 O 0.320981 0.915708 0.291977 0.082 - 38 O 0.415708 0.820981 0.791977 0.081 - 39 O 0.084292 0.876269 0.405273 0.081 - 40 O 0.708023 0.529004 0.623731 0.082 - 41 O 0.679019 0.084292 0.708023 0.082 - 42 O 0.029004 0.320981 0.905273 0.081 - 43 O 0.208023 0.584292 0.179019 0.082 - 44 O 0.123731 0.029004 0.208023 0.082 - 45 O 0.970996 0.679019 0.094727 0.081 - 46 O 0.791977 0.415708 0.820981 0.082 - 47 O 0.876269 0.970996 0.791977 0.082 - 48 O 0.594727 0.915708 0.123731 0.082 - 49 O 0.179019 0.470996 0.594727 0.082 - 50 O 0.405273 0.084292 0.876269 0.082 - 51 O 0.820981 0.529004 0.405273 0.082 - 52 O 0.905273 0.029004 0.320981 0.082 - 53 O 0.376269 0.584292 0.905273 0.082 - 54 O 0.094727 0.970996 0.679019 0.082 - 55 O 0.623731 0.415708 0.094727 0.082 - 56 O 0.376269 0.291977 0.470996 0.082 - 57 O 0.584292 0.905273 0.376269 0.081 - 58 O 0.623731 0.708023 0.529004 0.082 - 59 O 0.415708 0.094727 0.623731 0.081 - 60 O 0.123731 0.594727 0.915708 0.082 - 61 O 0.029004 0.208023 0.123731 0.081 - 62 O 0.876269 0.405273 0.084292 0.082 - 63 O 0.970996 0.791977 0.876269 0.081 - 64 O 0.320981 0.905273 0.029004 0.082 - 65 O 0.915708 0.291977 0.320981 0.081 - 66 O 0.679019 0.094727 0.970996 0.082 - 67 O 0.084292 0.708023 0.679019 0.081 - 68 O 0.179019 0.208023 0.584292 0.082 - 69 O 0.470996 0.594727 0.179019 0.081 - 70 O 0.820981 0.791977 0.415708 0.082 - 71 O 0.529004 0.405273 0.820981 0.081 - 72 O 0.291977 0.320981 0.915708 0.082 - 73 O 0.708023 0.679019 0.084292 0.082 - 74 O 0.208023 0.123731 0.029004 0.082 - 75 O 0.791977 0.876269 0.970996 0.082 - 76 O 0.905273 0.376269 0.584292 0.082 - 77 O 0.094727 0.623731 0.415708 0.082 - 78 O 0.594727 0.179019 0.470996 0.082 - 79 O 0.405273 0.820981 0.529004 0.082","# generated using pymatgen -data_Y3Ga3(FeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80590992 -_cell_length_b 10.80590992 -_cell_length_c 10.80590992 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Ga3(FeO6)2 -_chemical_formula_sum 'Y12 Ga12 Fe8 O48' -_cell_volume 971.31956702 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.25000000 0.37500000 0.12500000 1 - Y Y1 1 0.75000000 0.62500000 0.87500000 1 - Y Y2 1 0.75000000 0.12500000 0.37500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.37500000 0.75000000 0.12500000 1 - Y Y5 1 0.25000000 0.87500000 0.62500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.62500000 0.25000000 0.87500000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.62500000 0.87500000 0.75000000 1 - Y Y10 1 0.12500000 0.37500000 0.75000000 1 - Y Y11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga13 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga14 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga17 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga18 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga19 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe24 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe25 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe26 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe27 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe28 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe29 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe30 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47099600 0.37626900 0.29197700 1 - O O33 1 0.52900400 0.62373100 0.70802300 1 - O O34 1 0.58429200 0.17901900 0.20802300 1 - O O35 1 0.91570800 0.12373100 0.59472700 1 - O O36 1 0.29197700 0.47099600 0.37626900 1 - O O37 1 0.32098100 0.91570800 0.29197700 1 - O O38 1 0.41570800 0.82098100 0.79197700 1 - O O39 1 0.08429200 0.87626900 0.40527300 1 - O O40 1 0.70802300 0.52900400 0.62373100 1 - O O41 1 0.67901900 0.08429200 0.70802300 1 - O O42 1 0.02900400 0.32098100 0.90527300 1 - O O43 1 0.20802300 0.58429200 0.17901900 1 - O O44 1 0.12373100 0.02900400 0.20802300 1 - O O45 1 0.97099600 0.67901900 0.09472700 1 - O O46 1 0.79197700 0.41570800 0.82098100 1 - O O47 1 0.87626900 0.97099600 0.79197700 1 - O O48 1 0.59472700 0.91570800 0.12373100 1 - O O49 1 0.17901900 0.47099600 0.59472700 1 - O O50 1 0.40527300 0.08429200 0.87626900 1 - O O51 1 0.82098100 0.52900400 0.40527300 1 - O O52 1 0.90527300 0.02900400 0.32098100 1 - O O53 1 0.37626900 0.58429200 0.90527300 1 - O O54 1 0.09472700 0.97099600 0.67901900 1 - O O55 1 0.62373100 0.41570800 0.09472700 1 - O O56 1 0.37626900 0.29197700 0.47099600 1 - O O57 1 0.58429200 0.90527300 0.37626900 1 - O O58 1 0.62373100 0.70802300 0.52900400 1 - O O59 1 0.41570800 0.09472700 0.62373100 1 - O O60 1 0.12373100 0.59472700 0.91570800 1 - O O61 1 0.02900400 0.20802300 0.12373100 1 - O O62 1 0.87626900 0.40527300 0.08429200 1 - O O63 1 0.97099600 0.79197700 0.87626900 1 - O O64 1 0.32098100 0.90527300 0.02900400 1 - O O65 1 0.91570800 0.29197700 0.32098100 1 - O O66 1 0.67901900 0.09472700 0.97099600 1 - O O67 1 0.08429200 0.70802300 0.67901900 1 - O O68 1 0.17901900 0.20802300 0.58429200 1 - O O69 1 0.47099600 0.59472700 0.17901900 1 - O O70 1 0.82098100 0.79197700 0.41570800 1 - O O71 1 0.52900400 0.40527300 0.82098100 1 - O O72 1 0.29197700 0.32098100 0.91570800 1 - O O73 1 0.70802300 0.67901900 0.08429200 1 - O O74 1 0.20802300 0.12373100 0.02900400 1 - O O75 1 0.79197700 0.87626900 0.97099600 1 - O O76 1 0.90527300 0.37626900 0.58429200 1 - O O77 1 0.09472700 0.62373100 0.41570800 1 - O O78 1 0.59472700 0.17901900 0.47099600 1 - O O79 1 0.40527300 0.82098100 0.52900400 1 -" -Sr3Sc2(GeO4)3,mp-1208829,Ia-3d,[],0.0,{'tags': []},"Full Formula (Sr12 Sc8 Ge12 O48) -Reduced Formula: Sr3Sc2(GeO4)3 -abc : 11.216538 11.216538 11.216538 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sr 0.25 0.375 0.125 0 - 1 Sr 0.75 0.625 0.875 0 - 2 Sr 0.75 0.125 0.375 0 - 3 Sr 0.125 0.25 0.375 0 - 4 Sr 0.375 0.75 0.125 0 - 5 Sr 0.25 0.875 0.625 0 - 6 Sr 0.875 0.75 0.625 0 - 7 Sr 0.625 0.25 0.875 0 - 8 Sr 0.375 0.125 0.25 0 - 9 Sr 0.625 0.875 0.75 0 - 10 Sr 0.125 0.375 0.75 0 - 11 Sr 0.875 0.625 0.25 0 - 12 Sc 0 0 0 0 - 13 Sc 0.5 0 0.5 0 - 14 Sc 0 0.5 0.5 0 - 15 Sc 0.5 0 0 0 - 16 Sc 0.5 0.5 0 0 - 17 Sc 0.5 0.5 0.5 0 - 18 Sc 0 0 0.5 0 - 19 Sc 0 0.5 0 0 - 20 Ge 0.25 0.625 0.375 0 - 21 Ge 0.75 0.375 0.625 0 - 22 Ge 0.75 0.875 0.125 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Ge 0.625 0.75 0.375 0 - 25 Ge 0.25 0.125 0.875 0 - 26 Ge 0.125 0.75 0.875 0 - 27 Ge 0.875 0.25 0.125 0 - 28 Ge 0.625 0.375 0.25 0 - 29 Ge 0.375 0.625 0.75 0 - 30 Ge 0.875 0.125 0.75 0 - 31 Ge 0.125 0.875 0.25 0 - 32 O 0.490914 0.384776 0.299887 -0 - 33 O 0.509086 0.615224 0.700113 -0 - 34 O 0.58489 0.191028 0.200113 -0 - 35 O 0.91511 0.115224 0.606138 0 - 36 O 0.299887 0.490914 0.384776 -0 - 37 O 0.308972 0.91511 0.299887 0 - 38 O 0.41511 0.808972 0.799887 -0 - 39 O 0.08489 0.884776 0.393862 -0 - 40 O 0.700113 0.509086 0.615224 0 - 41 O 0.691028 0.08489 0.700113 0 - 42 O 0.009086 0.308972 0.893862 -0 - 43 O 0.200113 0.58489 0.191028 -0 - 44 O 0.115224 0.009086 0.200113 -0 - 45 O 0.990914 0.691028 0.106138 0 - 46 O 0.799887 0.41511 0.808972 0 - 47 O 0.884776 0.990914 0.799887 -0 - 48 O 0.606138 0.91511 0.115224 -0 - 49 O 0.191028 0.490914 0.606138 -0 - 50 O 0.393862 0.08489 0.884776 0 - 51 O 0.808972 0.509086 0.393862 0 - 52 O 0.893862 0.009086 0.308972 -0 - 53 O 0.384776 0.58489 0.893862 0 - 54 O 0.106138 0.990914 0.691028 0 - 55 O 0.615224 0.41511 0.106138 -0 - 56 O 0.384776 0.299887 0.490914 -0 - 57 O 0.58489 0.893862 0.384776 -0 - 58 O 0.615224 0.700113 0.509086 0 - 59 O 0.41511 0.106138 0.615224 -0 - 60 O 0.115224 0.606138 0.91511 -0 - 61 O 0.009086 0.200113 0.115224 0 - 62 O 0.884776 0.393862 0.08489 0 - 63 O 0.990914 0.799887 0.884776 -0 - 64 O 0.308972 0.893862 0.009086 -0 - 65 O 0.91511 0.299887 0.308972 0 - 66 O 0.691028 0.106138 0.990914 0 - 67 O 0.08489 0.700113 0.691028 0 - 68 O 0.191028 0.200113 0.58489 -0 - 69 O 0.490914 0.606138 0.191028 0 - 70 O 0.808972 0.799887 0.41511 -0 - 71 O 0.509086 0.393862 0.808972 -0 - 72 O 0.299887 0.308972 0.91511 0 - 73 O 0.700113 0.691028 0.08489 0 - 74 O 0.200113 0.115224 0.009086 0 - 75 O 0.799887 0.884776 0.990914 -0 - 76 O 0.893862 0.384776 0.58489 0 - 77 O 0.106138 0.615224 0.41511 -0 - 78 O 0.606138 0.191028 0.490914 0 - 79 O 0.393862 0.808972 0.509086 -0","# generated using pymatgen -data_Sr3Sc2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.21653760 -_cell_length_b 11.21653760 -_cell_length_c 11.21653760 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sr3Sc2(GeO4)3 -_chemical_formula_sum 'Sr12 Sc8 Ge12 O48' -_cell_volume 1086.31195308 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sr Sr0 1 0.25000000 0.37500000 0.12500000 1 - Sr Sr1 1 0.75000000 0.62500000 0.87500000 1 - Sr Sr2 1 0.75000000 0.12500000 0.37500000 1 - Sr Sr3 1 0.12500000 0.25000000 0.37500000 1 - Sr Sr4 1 0.37500000 0.75000000 0.12500000 1 - Sr Sr5 1 0.25000000 0.87500000 0.62500000 1 - Sr Sr6 1 0.87500000 0.75000000 0.62500000 1 - Sr Sr7 1 0.62500000 0.25000000 0.87500000 1 - Sr Sr8 1 0.37500000 0.12500000 0.25000000 1 - Sr Sr9 1 0.62500000 0.87500000 0.75000000 1 - Sr Sr10 1 0.12500000 0.37500000 0.75000000 1 - Sr Sr11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.49091400 0.38477600 0.29988700 1 - O O33 1 0.50908600 0.61522400 0.70011300 1 - O O34 1 0.58489000 0.19102800 0.20011300 1 - O O35 1 0.91511000 0.11522400 0.60613800 1 - O O36 1 0.29988700 0.49091400 0.38477600 1 - O O37 1 0.30897200 0.91511000 0.29988700 1 - O O38 1 0.41511000 0.80897200 0.79988700 1 - O O39 1 0.08489000 0.88477600 0.39386200 1 - O O40 1 0.70011300 0.50908600 0.61522400 1 - O O41 1 0.69102800 0.08489000 0.70011300 1 - O O42 1 0.00908600 0.30897200 0.89386200 1 - O O43 1 0.20011300 0.58489000 0.19102800 1 - O O44 1 0.11522400 0.00908600 0.20011300 1 - O O45 1 0.99091400 0.69102800 0.10613800 1 - O O46 1 0.79988700 0.41511000 0.80897200 1 - O O47 1 0.88477600 0.99091400 0.79988700 1 - O O48 1 0.60613800 0.91511000 0.11522400 1 - O O49 1 0.19102800 0.49091400 0.60613800 1 - O O50 1 0.39386200 0.08489000 0.88477600 1 - O O51 1 0.80897200 0.50908600 0.39386200 1 - O O52 1 0.89386200 0.00908600 0.30897200 1 - O O53 1 0.38477600 0.58489000 0.89386200 1 - O O54 1 0.10613800 0.99091400 0.69102800 1 - O O55 1 0.61522400 0.41511000 0.10613800 1 - O O56 1 0.38477600 0.29988700 0.49091400 1 - O O57 1 0.58489000 0.89386200 0.38477600 1 - O O58 1 0.61522400 0.70011300 0.50908600 1 - O O59 1 0.41511000 0.10613800 0.61522400 1 - O O60 1 0.11522400 0.60613800 0.91511000 1 - O O61 1 0.00908600 0.20011300 0.11522400 1 - O O62 1 0.88477600 0.39386200 0.08489000 1 - O O63 1 0.99091400 0.79988700 0.88477600 1 - O O64 1 0.30897200 0.89386200 0.00908600 1 - O O65 1 0.91511000 0.29988700 0.30897200 1 - O O66 1 0.69102800 0.10613800 0.99091400 1 - O O67 1 0.08489000 0.70011300 0.69102800 1 - O O68 1 0.19102800 0.20011300 0.58489000 1 - O O69 1 0.49091400 0.60613800 0.19102800 1 - O O70 1 0.80897200 0.79988700 0.41511000 1 - O O71 1 0.50908600 0.39386200 0.80897200 1 - O O72 1 0.29988700 0.30897200 0.91511000 1 - O O73 1 0.70011300 0.69102800 0.08489000 1 - O O74 1 0.20011300 0.11522400 0.00908600 1 - O O75 1 0.79988700 0.88477600 0.99091400 1 - O O76 1 0.89386200 0.38477600 0.58489000 1 - O O77 1 0.10613800 0.61522400 0.41511000 1 - O O78 1 0.60613800 0.19102800 0.49091400 1 - O O79 1 0.39386200 0.80897200 0.50908600 1 -" -Sr3Tm2(GeO4)3,mp-1209021,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Sr12 Tm8 Ge12 O48) -Reduced Formula: Sr3Tm2(GeO4)3 -abc : 11.400601 11.400601 11.400601 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sr 0.25 0.375 0.125 -0 - 1 Sr 0.75 0.625 0.875 -0 - 2 Sr 0.75 0.125 0.375 -0 - 3 Sr 0.125 0.25 0.375 -0 - 4 Sr 0.375 0.75 0.125 -0 - 5 Sr 0.25 0.875 0.625 -0 - 6 Sr 0.875 0.75 0.625 -0 - 7 Sr 0.625 0.25 0.875 -0 - 8 Sr 0.375 0.125 0.25 -0 - 9 Sr 0.625 0.875 0.75 -0 - 10 Sr 0.125 0.375 0.75 -0 - 11 Sr 0.875 0.625 0.25 -0 - 12 Tm 0 0 0 -0 - 13 Tm 0.5 0 0.5 -0 - 14 Tm 0 0.5 0.5 -0 - 15 Tm 0.5 0 0 -0 - 16 Tm 0.5 0.5 0 -0 - 17 Tm 0.5 0.5 0.5 -0 - 18 Tm 0 0 0.5 -0 - 19 Tm 0 0.5 0 -0 - 20 Ge 0.25 0.625 0.375 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.75 0.875 0.125 -0 - 23 Ge 0.375 0.25 0.625 -0 - 24 Ge 0.625 0.75 0.375 -0 - 25 Ge 0.25 0.125 0.875 -0 - 26 Ge 0.125 0.75 0.875 -0 - 27 Ge 0.875 0.25 0.125 -0 - 28 Ge 0.625 0.375 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.875 0.125 0.75 -0 - 31 Ge 0.125 0.875 0.25 -0 - 32 O 0.48916 0.381105 0.293216 0 - 33 O 0.51084 0.618895 0.706784 0 - 34 O 0.587889 0.195944 0.206784 0 - 35 O 0.912111 0.118895 0.608055 0 - 36 O 0.293216 0.48916 0.381105 0 - 37 O 0.304056 0.912111 0.293216 0 - 38 O 0.412111 0.804056 0.793216 0 - 39 O 0.087889 0.881105 0.391945 0 - 40 O 0.706784 0.51084 0.618895 0 - 41 O 0.695944 0.087889 0.706784 0 - 42 O 0.01084 0.304056 0.891945 0 - 43 O 0.206784 0.587889 0.195944 0 - 44 O 0.118895 0.01084 0.206784 0 - 45 O 0.98916 0.695944 0.108055 0 - 46 O 0.793216 0.412111 0.804056 0 - 47 O 0.881105 0.98916 0.793216 0 - 48 O 0.608055 0.912111 0.118895 0 - 49 O 0.195944 0.48916 0.608055 0 - 50 O 0.391945 0.087889 0.881105 0 - 51 O 0.804056 0.51084 0.391945 0 - 52 O 0.891945 0.01084 0.304056 0 - 53 O 0.381105 0.587889 0.891945 0 - 54 O 0.108055 0.98916 0.695944 0 - 55 O 0.618895 0.412111 0.108055 0 - 56 O 0.381105 0.293216 0.48916 0 - 57 O 0.587889 0.891945 0.381105 0 - 58 O 0.618895 0.706784 0.51084 0 - 59 O 0.412111 0.108055 0.618895 0 - 60 O 0.118895 0.608055 0.912111 0 - 61 O 0.01084 0.206784 0.118895 0 - 62 O 0.881105 0.391945 0.087889 0 - 63 O 0.98916 0.793216 0.881105 0 - 64 O 0.304056 0.891945 0.01084 0 - 65 O 0.912111 0.293216 0.304056 0 - 66 O 0.695944 0.108055 0.98916 0 - 67 O 0.087889 0.706784 0.695944 0 - 68 O 0.195944 0.206784 0.587889 0 - 69 O 0.48916 0.608055 0.195944 0 - 70 O 0.804056 0.793216 0.412111 0 - 71 O 0.51084 0.391945 0.804056 0 - 72 O 0.293216 0.304056 0.912111 0 - 73 O 0.706784 0.695944 0.087889 0 - 74 O 0.206784 0.118895 0.01084 0 - 75 O 0.793216 0.881105 0.98916 0 - 76 O 0.891945 0.381105 0.587889 0 - 77 O 0.108055 0.618895 0.412111 0 - 78 O 0.608055 0.195944 0.48916 0 - 79 O 0.391945 0.804056 0.51084 0","# generated using pymatgen -data_Sr3Tm2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.40060090 -_cell_length_b 11.40060090 -_cell_length_c 11.40060090 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sr3Tm2(GeO4)3 -_chemical_formula_sum 'Sr12 Tm8 Ge12 O48' -_cell_volume 1140.67346120 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sr Sr0 1 0.25000000 0.37500000 0.12500000 1 - Sr Sr1 1 0.75000000 0.62500000 0.87500000 1 - Sr Sr2 1 0.75000000 0.12500000 0.37500000 1 - Sr Sr3 1 0.12500000 0.25000000 0.37500000 1 - Sr Sr4 1 0.37500000 0.75000000 0.12500000 1 - Sr Sr5 1 0.25000000 0.87500000 0.62500000 1 - Sr Sr6 1 0.87500000 0.75000000 0.62500000 1 - Sr Sr7 1 0.62500000 0.25000000 0.87500000 1 - Sr Sr8 1 0.37500000 0.12500000 0.25000000 1 - Sr Sr9 1 0.62500000 0.87500000 0.75000000 1 - Sr Sr10 1 0.12500000 0.37500000 0.75000000 1 - Sr Sr11 1 0.87500000 0.62500000 0.25000000 1 - Tm Tm12 1 0.00000000 0.00000000 0.00000000 1 - Tm Tm13 1 0.50000000 0.00000000 0.50000000 1 - Tm Tm14 1 0.00000000 0.50000000 0.50000000 1 - Tm Tm15 1 0.50000000 0.00000000 0.00000000 1 - Tm Tm16 1 0.50000000 0.50000000 0.00000000 1 - Tm Tm17 1 0.50000000 0.50000000 0.50000000 1 - Tm Tm18 1 0.00000000 0.00000000 0.50000000 1 - Tm Tm19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48916000 0.38110500 0.29321600 1 - O O33 1 0.51084000 0.61889500 0.70678400 1 - O O34 1 0.58788900 0.19594400 0.20678400 1 - O O35 1 0.91211100 0.11889500 0.60805500 1 - O O36 1 0.29321600 0.48916000 0.38110500 1 - O O37 1 0.30405600 0.91211100 0.29321600 1 - O O38 1 0.41211100 0.80405600 0.79321600 1 - O O39 1 0.08788900 0.88110500 0.39194500 1 - O O40 1 0.70678400 0.51084000 0.61889500 1 - O O41 1 0.69594400 0.08788900 0.70678400 1 - O O42 1 0.01084000 0.30405600 0.89194500 1 - O O43 1 0.20678400 0.58788900 0.19594400 1 - O O44 1 0.11889500 0.01084000 0.20678400 1 - O O45 1 0.98916000 0.69594400 0.10805500 1 - O O46 1 0.79321600 0.41211100 0.80405600 1 - O O47 1 0.88110500 0.98916000 0.79321600 1 - O O48 1 0.60805500 0.91211100 0.11889500 1 - O O49 1 0.19594400 0.48916000 0.60805500 1 - O O50 1 0.39194500 0.08788900 0.88110500 1 - O O51 1 0.80405600 0.51084000 0.39194500 1 - O O52 1 0.89194500 0.01084000 0.30405600 1 - O O53 1 0.38110500 0.58788900 0.89194500 1 - O O54 1 0.10805500 0.98916000 0.69594400 1 - O O55 1 0.61889500 0.41211100 0.10805500 1 - O O56 1 0.38110500 0.29321600 0.48916000 1 - O O57 1 0.58788900 0.89194500 0.38110500 1 - O O58 1 0.61889500 0.70678400 0.51084000 1 - O O59 1 0.41211100 0.10805500 0.61889500 1 - O O60 1 0.11889500 0.60805500 0.91211100 1 - O O61 1 0.01084000 0.20678400 0.11889500 1 - O O62 1 0.88110500 0.39194500 0.08788900 1 - O O63 1 0.98916000 0.79321600 0.88110500 1 - O O64 1 0.30405600 0.89194500 0.01084000 1 - O O65 1 0.91211100 0.29321600 0.30405600 1 - O O66 1 0.69594400 0.10805500 0.98916000 1 - O O67 1 0.08788900 0.70678400 0.69594400 1 - O O68 1 0.19594400 0.20678400 0.58788900 1 - O O69 1 0.48916000 0.60805500 0.19594400 1 - O O70 1 0.80405600 0.79321600 0.41211100 1 - O O71 1 0.51084000 0.39194500 0.80405600 1 - O O72 1 0.29321600 0.30405600 0.91211100 1 - O O73 1 0.70678400 0.69594400 0.08788900 1 - O O74 1 0.20678400 0.11889500 0.01084000 1 - O O75 1 0.79321600 0.88110500 0.98916000 1 - O O76 1 0.89194500 0.38110500 0.58788900 1 - O O77 1 0.10805500 0.61889500 0.41211100 1 - O O78 1 0.60805500 0.19594400 0.48916000 1 - O O79 1 0.39194500 0.80405600 0.51084000 1 -" -Sm3Sc2Al3O12,mp-1209040,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Sc2Sm3Al3O12']}","Full Formula (Sm12 Sc8 Al12 O48) -Reduced Formula: Sm3Sc2Al3O12 -abc : 10.895994 10.895994 10.895994 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sm 0.25 0.375 0.125 -0 - 1 Sm 0.75 0.625 0.875 -0 - 2 Sm 0.75 0.125 0.375 -0 - 3 Sm 0.125 0.25 0.375 -0 - 4 Sm 0.375 0.75 0.125 -0 - 5 Sm 0.25 0.875 0.625 -0 - 6 Sm 0.875 0.75 0.625 -0 - 7 Sm 0.625 0.25 0.875 -0 - 8 Sm 0.375 0.125 0.25 -0 - 9 Sm 0.625 0.875 0.75 -0 - 10 Sm 0.125 0.375 0.75 -0 - 11 Sm 0.875 0.625 0.25 -0 - 12 Sc 0 0 0 0 - 13 Sc 0.5 0 0.5 0 - 14 Sc 0 0.5 0.5 0 - 15 Sc 0.5 0 0 0 - 16 Sc 0.5 0.5 0 0 - 17 Sc 0.5 0.5 0.5 0 - 18 Sc 0 0 0.5 0 - 19 Sc 0 0.5 0 0 - 20 Al 0.25 0.625 0.375 0 - 21 Al 0.75 0.375 0.625 0 - 22 Al 0.75 0.875 0.125 0 - 23 Al 0.375 0.25 0.625 0 - 24 Al 0.625 0.75 0.375 0 - 25 Al 0.25 0.125 0.875 0 - 26 Al 0.125 0.75 0.875 0 - 27 Al 0.875 0.25 0.125 0 - 28 Al 0.625 0.375 0.25 0 - 29 Al 0.375 0.625 0.75 0 - 30 Al 0.875 0.125 0.75 0 - 31 Al 0.125 0.875 0.25 0 - 32 O 0.477987 0.376934 0.28927 0 - 33 O 0.522013 0.623066 0.71073 0 - 34 O 0.587664 0.188718 0.21073 0 - 35 O 0.912336 0.123066 0.601054 0 - 36 O 0.28927 0.477987 0.376934 0 - 37 O 0.311282 0.912336 0.28927 0 - 38 O 0.412336 0.811282 0.78927 0 - 39 O 0.087664 0.876934 0.398946 0 - 40 O 0.71073 0.522013 0.623066 0 - 41 O 0.688718 0.087664 0.71073 0 - 42 O 0.022013 0.311282 0.898946 0 - 43 O 0.210731 0.587664 0.188718 0 - 44 O 0.123066 0.022013 0.21073 0 - 45 O 0.977987 0.688718 0.101054 0 - 46 O 0.78927 0.412336 0.811282 0 - 47 O 0.876934 0.977987 0.78927 0 - 48 O 0.601054 0.912336 0.123066 0 - 49 O 0.188718 0.477987 0.601054 0 - 50 O 0.398946 0.087664 0.876934 0 - 51 O 0.811282 0.522013 0.398946 0 - 52 O 0.898946 0.022013 0.311282 0 - 53 O 0.376934 0.587664 0.898946 0 - 54 O 0.101054 0.977987 0.688718 0 - 55 O 0.623066 0.412336 0.101054 0 - 56 O 0.376934 0.28927 0.477987 0 - 57 O 0.587664 0.898946 0.376934 0 - 58 O 0.623066 0.71073 0.522013 0 - 59 O 0.412336 0.101054 0.623066 0 - 60 O 0.123066 0.601054 0.912336 0 - 61 O 0.022013 0.21073 0.123066 0 - 62 O 0.876934 0.398946 0.087664 0 - 63 O 0.977987 0.789269 0.876934 0 - 64 O 0.311282 0.898946 0.022013 0 - 65 O 0.912336 0.28927 0.311282 0 - 66 O 0.688718 0.101054 0.977987 0 - 67 O 0.087664 0.71073 0.688718 0 - 68 O 0.188718 0.21073 0.587664 0 - 69 O 0.477987 0.601054 0.188718 0 - 70 O 0.811282 0.78927 0.412336 0 - 71 O 0.522013 0.398946 0.811282 0 - 72 O 0.28927 0.311282 0.912336 0 - 73 O 0.71073 0.688718 0.087664 0 - 74 O 0.21073 0.123066 0.022013 0 - 75 O 0.78927 0.876934 0.977987 0 - 76 O 0.898946 0.376934 0.587664 0 - 77 O 0.101054 0.623066 0.412336 0 - 78 O 0.601054 0.188718 0.477987 0 - 79 O 0.398946 0.811282 0.522013 0","# generated using pymatgen -data_Sm3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.89599388 -_cell_length_b 10.89599388 -_cell_length_c 10.89599388 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sm3Sc2Al3O12 -_chemical_formula_sum 'Sm12 Sc8 Al12 O48' -_cell_volume 995.81499412 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sm Sm0 1 0.25000000 0.37500000 0.12500000 1 - Sm Sm1 1 0.75000000 0.62500000 0.87500000 1 - Sm Sm2 1 0.75000000 0.12500000 0.37500000 1 - Sm Sm3 1 0.12500000 0.25000000 0.37500000 1 - Sm Sm4 1 0.37500000 0.75000000 0.12500000 1 - Sm Sm5 1 0.25000000 0.87500000 0.62500000 1 - Sm Sm6 1 0.87500000 0.75000000 0.62500000 1 - Sm Sm7 1 0.62500000 0.25000000 0.87500000 1 - Sm Sm8 1 0.37500000 0.12500000 0.25000000 1 - Sm Sm9 1 0.62500000 0.87500000 0.75000000 1 - Sm Sm10 1 0.12500000 0.37500000 0.75000000 1 - Sm Sm11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Al Al20 1 0.25000000 0.62500000 0.37500000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.37500000 0.25000000 0.62500000 1 - Al Al24 1 0.62500000 0.75000000 0.37500000 1 - Al Al25 1 0.25000000 0.12500000 0.87500000 1 - Al Al26 1 0.12500000 0.75000000 0.87500000 1 - Al Al27 1 0.87500000 0.25000000 0.12500000 1 - Al Al28 1 0.62500000 0.37500000 0.25000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.87500000 0.12500000 0.75000000 1 - Al Al31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47798700 0.37693400 0.28927000 1 - O O33 1 0.52201300 0.62306600 0.71073000 1 - O O34 1 0.58766400 0.18871800 0.21073000 1 - O O35 1 0.91233600 0.12306600 0.60105400 1 - O O36 1 0.28927000 0.47798700 0.37693400 1 - O O37 1 0.31128200 0.91233600 0.28927000 1 - O O38 1 0.41233600 0.81128200 0.78927000 1 - O O39 1 0.08766400 0.87693400 0.39894600 1 - O O40 1 0.71073000 0.52201300 0.62306600 1 - O O41 1 0.68871800 0.08766400 0.71073000 1 - O O42 1 0.02201300 0.31128200 0.89894600 1 - O O43 1 0.21073100 0.58766400 0.18871800 1 - O O44 1 0.12306600 0.02201300 0.21073000 1 - O O45 1 0.97798700 0.68871800 0.10105400 1 - O O46 1 0.78927000 0.41233600 0.81128200 1 - O O47 1 0.87693400 0.97798700 0.78927000 1 - O O48 1 0.60105400 0.91233600 0.12306600 1 - O O49 1 0.18871800 0.47798700 0.60105400 1 - O O50 1 0.39894600 0.08766400 0.87693400 1 - O O51 1 0.81128200 0.52201300 0.39894600 1 - O O52 1 0.89894600 0.02201300 0.31128200 1 - O O53 1 0.37693400 0.58766400 0.89894600 1 - O O54 1 0.10105400 0.97798700 0.68871800 1 - O O55 1 0.62306600 0.41233600 0.10105400 1 - O O56 1 0.37693400 0.28927000 0.47798700 1 - O O57 1 0.58766400 0.89894600 0.37693400 1 - O O58 1 0.62306600 0.71073000 0.52201300 1 - O O59 1 0.41233600 0.10105400 0.62306600 1 - O O60 1 0.12306600 0.60105400 0.91233600 1 - O O61 1 0.02201300 0.21073000 0.12306600 1 - O O62 1 0.87693400 0.39894600 0.08766400 1 - O O63 1 0.97798700 0.78926900 0.87693400 1 - O O64 1 0.31128200 0.89894600 0.02201300 1 - O O65 1 0.91233600 0.28927000 0.31128200 1 - O O66 1 0.68871800 0.10105400 0.97798700 1 - O O67 1 0.08766400 0.71073000 0.68871800 1 - O O68 1 0.18871800 0.21073000 0.58766400 1 - O O69 1 0.47798700 0.60105400 0.18871800 1 - O O70 1 0.81128200 0.78927000 0.41233600 1 - O O71 1 0.52201300 0.39894600 0.81128200 1 - O O72 1 0.28927000 0.31128200 0.91233600 1 - O O73 1 0.71073000 0.68871800 0.08766400 1 - O O74 1 0.21073000 0.12306600 0.02201300 1 - O O75 1 0.78927000 0.87693400 0.97798700 1 - O O76 1 0.89894600 0.37693400 0.58766400 1 - O O77 1 0.10105400 0.62306600 0.41233600 1 - O O78 1 0.60105400 0.18871800 0.47798700 1 - O O79 1 0.39894600 0.81128200 0.52201300 1 -" -Sr3Yb2(GeO4)3,mp-1209062,Ia-3d,[],0.035766539125005714,{'tags': ['garnet family']},"Full Formula (Sr12 Yb8 Ge12 O48) -Reduced Formula: Sr3Yb2(GeO4)3 -abc : 11.487176 11.487176 11.487176 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sr 0.25 0.375 0.125 -0.002 - 1 Sr 0.75 0.625 0.875 -0.002 - 2 Sr 0.75 0.125 0.375 -0.002 - 3 Sr 0.125 0.25 0.375 -0.001 - 4 Sr 0.375 0.75 0.125 -0.001 - 5 Sr 0.25 0.875 0.625 -0.002 - 6 Sr 0.875 0.75 0.625 -0.001 - 7 Sr 0.625 0.25 0.875 -0.001 - 8 Sr 0.375 0.125 0.25 -0.001 - 9 Sr 0.625 0.875 0.75 -0.001 - 10 Sr 0.125 0.375 0.75 -0.001 - 11 Sr 0.875 0.625 0.25 -0.001 - 12 Yb 0 0 0 0.006 - 13 Yb 0.5 0 0.5 0.019 - 14 Yb 0 0.5 0.5 0.019 - 15 Yb 0.5 0 0 0.019 - 16 Yb 0.5 0.5 0 0.006 - 17 Yb 0.5 0.5 0.5 0.006 - 18 Yb 0 0 0.5 0.019 - 19 Yb 0 0.5 0 0.006 - 20 Ge 0.25 0.625 0.375 -0.013 - 21 Ge 0.75 0.375 0.625 -0.013 - 22 Ge 0.75 0.875 0.125 -0.013 - 23 Ge 0.375 0.25 0.625 -0.012 - 24 Ge 0.625 0.75 0.375 -0.012 - 25 Ge 0.25 0.125 0.875 -0.013 - 26 Ge 0.125 0.75 0.875 -0.012 - 27 Ge 0.875 0.25 0.125 -0.012 - 28 Ge 0.625 0.375 0.25 -0.012 - 29 Ge 0.375 0.625 0.75 -0.012 - 30 Ge 0.875 0.125 0.75 -0.012 - 31 Ge 0.125 0.875 0.25 -0.012 - 32 O 0.485418 0.377771 0.285609 0.137 - 33 O 0.514582 0.622229 0.714391 0.137 - 34 O 0.592162 0.199809 0.214391 0.163 - 35 O 0.907838 0.122229 0.607647 0.163 - 36 O 0.285609 0.485418 0.377771 0.107 - 37 O 0.300191 0.907838 0.285609 0.157 - 38 O 0.407838 0.800191 0.785609 0.163 - 39 O 0.092162 0.877771 0.392353 0.163 - 40 O 0.714391 0.514582 0.622229 0.107 - 41 O 0.699809 0.092162 0.714391 0.157 - 42 O 0.014582 0.300191 0.892353 0.137 - 43 O 0.214391 0.592162 0.199809 0.107 - 44 O 0.122229 0.014582 0.214391 0.125 - 45 O 0.985418 0.699809 0.107647 0.137 - 46 O 0.785609 0.407838 0.800191 0.107 - 47 O 0.877771 0.985418 0.785609 0.125 - 48 O 0.607647 0.907838 0.122229 0.153 - 49 O 0.199809 0.485418 0.607647 0.157 - 50 O 0.392353 0.092162 0.877771 0.153 - 51 O 0.800191 0.514582 0.392353 0.157 - 52 O 0.892353 0.014582 0.300191 0.153 - 53 O 0.377771 0.592162 0.892353 0.125 - 54 O 0.107647 0.985418 0.699809 0.153 - 55 O 0.622229 0.407838 0.107647 0.125 - 56 O 0.377771 0.285609 0.485418 0.125 - 57 O 0.592162 0.892353 0.377771 0.163 - 58 O 0.622229 0.714391 0.514582 0.125 - 59 O 0.407838 0.107647 0.622229 0.163 - 60 O 0.122229 0.607647 0.907838 0.125 - 61 O 0.014582 0.214391 0.122229 0.137 - 62 O 0.877771 0.392353 0.092162 0.125 - 63 O 0.985418 0.785609 0.877771 0.137 - 64 O 0.300191 0.892353 0.014582 0.157 - 65 O 0.907838 0.285609 0.300191 0.163 - 66 O 0.699809 0.107647 0.985418 0.157 - 67 O 0.092162 0.714391 0.699809 0.163 - 68 O 0.199809 0.214391 0.592162 0.157 - 69 O 0.485418 0.607647 0.199809 0.137 - 70 O 0.800191 0.785609 0.407838 0.157 - 71 O 0.514582 0.392353 0.800191 0.137 - 72 O 0.285609 0.300191 0.907838 0.107 - 73 O 0.714391 0.699809 0.092162 0.107 - 74 O 0.214391 0.122229 0.014582 0.107 - 75 O 0.785609 0.877771 0.985418 0.107 - 76 O 0.892353 0.377771 0.592162 0.153 - 77 O 0.107647 0.622229 0.407838 0.153 - 78 O 0.607647 0.199809 0.485418 0.153 - 79 O 0.392353 0.800191 0.514582 0.153","# generated using pymatgen -data_Sr3Yb2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.48717573 -_cell_length_b 11.48717573 -_cell_length_c 11.48717573 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sr3Yb2(GeO4)3 -_chemical_formula_sum 'Sr12 Yb8 Ge12 O48' -_cell_volume 1166.85772043 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sr Sr0 1 0.25000000 0.37500000 0.12500000 1 - Sr Sr1 1 0.75000000 0.62500000 0.87500000 1 - Sr Sr2 1 0.75000000 0.12500000 0.37500000 1 - Sr Sr3 1 0.12500000 0.25000000 0.37500000 1 - Sr Sr4 1 0.37500000 0.75000000 0.12500000 1 - Sr Sr5 1 0.25000000 0.87500000 0.62500000 1 - Sr Sr6 1 0.87500000 0.75000000 0.62500000 1 - Sr Sr7 1 0.62500000 0.25000000 0.87500000 1 - Sr Sr8 1 0.37500000 0.12500000 0.25000000 1 - Sr Sr9 1 0.62500000 0.87500000 0.75000000 1 - Sr Sr10 1 0.12500000 0.37500000 0.75000000 1 - Sr Sr11 1 0.87500000 0.62500000 0.25000000 1 - Yb Yb12 1 0.00000000 0.00000000 0.00000000 1 - Yb Yb13 1 0.50000000 0.00000000 0.50000000 1 - Yb Yb14 1 0.00000000 0.50000000 0.50000000 1 - Yb Yb15 1 0.50000000 0.00000000 0.00000000 1 - Yb Yb16 1 0.50000000 0.50000000 0.00000000 1 - Yb Yb17 1 0.50000000 0.50000000 0.50000000 1 - Yb Yb18 1 0.00000000 0.00000000 0.50000000 1 - Yb Yb19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48541800 0.37777100 0.28560900 1 - O O33 1 0.51458200 0.62222900 0.71439100 1 - O O34 1 0.59216200 0.19980900 0.21439100 1 - O O35 1 0.90783800 0.12222900 0.60764700 1 - O O36 1 0.28560900 0.48541800 0.37777100 1 - O O37 1 0.30019100 0.90783800 0.28560900 1 - O O38 1 0.40783800 0.80019100 0.78560900 1 - O O39 1 0.09216200 0.87777100 0.39235300 1 - O O40 1 0.71439100 0.51458200 0.62222900 1 - O O41 1 0.69980900 0.09216200 0.71439100 1 - O O42 1 0.01458200 0.30019100 0.89235300 1 - O O43 1 0.21439100 0.59216200 0.19980900 1 - O O44 1 0.12222900 0.01458200 0.21439100 1 - O O45 1 0.98541800 0.69980900 0.10764700 1 - O O46 1 0.78560900 0.40783800 0.80019100 1 - O O47 1 0.87777100 0.98541800 0.78560900 1 - O O48 1 0.60764700 0.90783800 0.12222900 1 - O O49 1 0.19980900 0.48541800 0.60764700 1 - O O50 1 0.39235300 0.09216200 0.87777100 1 - O O51 1 0.80019100 0.51458200 0.39235300 1 - O O52 1 0.89235300 0.01458200 0.30019100 1 - O O53 1 0.37777100 0.59216200 0.89235300 1 - O O54 1 0.10764700 0.98541800 0.69980900 1 - O O55 1 0.62222900 0.40783800 0.10764700 1 - O O56 1 0.37777100 0.28560900 0.48541800 1 - O O57 1 0.59216200 0.89235300 0.37777100 1 - O O58 1 0.62222900 0.71439100 0.51458200 1 - O O59 1 0.40783800 0.10764700 0.62222900 1 - O O60 1 0.12222900 0.60764700 0.90783800 1 - O O61 1 0.01458200 0.21439100 0.12222900 1 - O O62 1 0.87777100 0.39235300 0.09216200 1 - O O63 1 0.98541800 0.78560900 0.87777100 1 - O O64 1 0.30019100 0.89235300 0.01458200 1 - O O65 1 0.90783800 0.28560900 0.30019100 1 - O O66 1 0.69980900 0.10764700 0.98541800 1 - O O67 1 0.09216200 0.71439100 0.69980900 1 - O O68 1 0.19980900 0.21439100 0.59216200 1 - O O69 1 0.48541800 0.60764700 0.19980900 1 - O O70 1 0.80019100 0.78560900 0.40783800 1 - O O71 1 0.51458200 0.39235300 0.80019100 1 - O O72 1 0.28560900 0.30019100 0.90783800 1 - O O73 1 0.71439100 0.69980900 0.09216200 1 - O O74 1 0.21439100 0.12222900 0.01458200 1 - O O75 1 0.78560900 0.87777100 0.98541800 1 - O O76 1 0.89235300 0.37777100 0.59216200 1 - O O77 1 0.10764700 0.62222900 0.40783800 1 - O O78 1 0.60764700 0.19980900 0.48541800 1 - O O79 1 0.39235300 0.80019100 0.51458200 1 -" -Sr3Er2(GeO4)3,mp-1209197,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Sr12 Er8 Ge12 O48) -Reduced Formula: Sr3Er2(GeO4)3 -abc : 11.438514 11.438514 11.438514 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sr 0.25 0.375 0.125 0 - 1 Sr 0.75 0.625 0.875 0 - 2 Sr 0.75 0.125 0.375 0 - 3 Sr 0.125 0.25 0.375 0 - 4 Sr 0.375 0.75 0.125 0 - 5 Sr 0.25 0.875 0.625 0 - 6 Sr 0.875 0.75 0.625 0 - 7 Sr 0.625 0.25 0.875 0 - 8 Sr 0.375 0.125 0.25 0 - 9 Sr 0.625 0.875 0.75 0 - 10 Sr 0.125 0.375 0.75 0 - 11 Sr 0.875 0.625 0.25 0 - 12 Er 0 0 0 0 - 13 Er 0.5 0 0.5 0 - 14 Er 0 0.5 0.5 0 - 15 Er 0.5 0 0 0 - 16 Er 0.5 0.5 0 0 - 17 Er 0.5 0.5 0.5 0 - 18 Er 0 0 0.5 0 - 19 Er 0 0.5 0 0 - 20 Ge 0.25 0.625 0.375 0 - 21 Ge 0.75 0.375 0.625 0 - 22 Ge 0.75 0.875 0.125 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Ge 0.625 0.75 0.375 0 - 25 Ge 0.25 0.125 0.875 0 - 26 Ge 0.125 0.75 0.875 0 - 27 Ge 0.875 0.25 0.125 0 - 28 Ge 0.625 0.375 0.25 0 - 29 Ge 0.375 0.625 0.75 0 - 30 Ge 0.875 0.125 0.75 0 - 31 Ge 0.125 0.875 0.25 0 - 32 O 0.488699 0.380738 0.29249 -0 - 33 O 0.511301 0.619262 0.70751 -0 - 34 O 0.588247 0.196209 0.20751 -0 - 35 O 0.911753 0.119262 0.607962 -0 - 36 O 0.29249 0.488699 0.380738 -0 - 37 O 0.303791 0.911753 0.29249 -0 - 38 O 0.411753 0.803791 0.79249 -0 - 39 O 0.088247 0.880738 0.392038 -0 - 40 O 0.70751 0.511301 0.619262 -0 - 41 O 0.696209 0.088247 0.70751 -0 - 42 O 0.011301 0.303791 0.892038 -0 - 43 O 0.20751 0.588247 0.196209 -0 - 44 O 0.119262 0.011301 0.20751 -0 - 45 O 0.988699 0.696209 0.107962 -0 - 46 O 0.79249 0.411753 0.803791 -0 - 47 O 0.880738 0.988699 0.79249 -0 - 48 O 0.607962 0.911753 0.119262 -0 - 49 O 0.196209 0.488699 0.607962 -0 - 50 O 0.392038 0.088247 0.880738 -0 - 51 O 0.803791 0.511301 0.392038 -0 - 52 O 0.892038 0.011301 0.303791 -0 - 53 O 0.380738 0.588247 0.892038 -0 - 54 O 0.107962 0.988699 0.696209 -0 - 55 O 0.619262 0.411753 0.107962 -0 - 56 O 0.380738 0.29249 0.488699 -0 - 57 O 0.588247 0.892038 0.380738 -0 - 58 O 0.619262 0.70751 0.511301 -0 - 59 O 0.411753 0.107962 0.619262 -0 - 60 O 0.119262 0.607962 0.911753 -0 - 61 O 0.011301 0.20751 0.119262 -0 - 62 O 0.880738 0.392038 0.088247 -0 - 63 O 0.988699 0.79249 0.880738 -0 - 64 O 0.303791 0.892038 0.011301 -0 - 65 O 0.911753 0.29249 0.303791 -0 - 66 O 0.696209 0.107962 0.988699 -0 - 67 O 0.088247 0.70751 0.696209 -0 - 68 O 0.196209 0.20751 0.588247 -0 - 69 O 0.488699 0.607962 0.196209 -0 - 70 O 0.803791 0.79249 0.411753 -0 - 71 O 0.511301 0.392038 0.803791 -0 - 72 O 0.29249 0.303791 0.911753 -0 - 73 O 0.70751 0.696209 0.088247 -0 - 74 O 0.20751 0.119262 0.011301 -0 - 75 O 0.79249 0.880738 0.988699 -0 - 76 O 0.892038 0.380738 0.588247 -0 - 77 O 0.107962 0.619262 0.411753 -0 - 78 O 0.607962 0.196209 0.488699 -0 - 79 O 0.392038 0.803791 0.511301 -0","# generated using pymatgen -data_Sr3Er2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.43851376 -_cell_length_b 11.43851376 -_cell_length_c 11.43851376 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sr3Er2(GeO4)3 -_chemical_formula_sum 'Sr12 Er8 Ge12 O48' -_cell_volume 1152.09132478 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sr Sr0 1 0.25000000 0.37500000 0.12500000 1 - Sr Sr1 1 0.75000000 0.62500000 0.87500000 1 - Sr Sr2 1 0.75000000 0.12500000 0.37500000 1 - Sr Sr3 1 0.12500000 0.25000000 0.37500000 1 - Sr Sr4 1 0.37500000 0.75000000 0.12500000 1 - Sr Sr5 1 0.25000000 0.87500000 0.62500000 1 - Sr Sr6 1 0.87500000 0.75000000 0.62500000 1 - Sr Sr7 1 0.62500000 0.25000000 0.87500000 1 - Sr Sr8 1 0.37500000 0.12500000 0.25000000 1 - Sr Sr9 1 0.62500000 0.87500000 0.75000000 1 - Sr Sr10 1 0.12500000 0.37500000 0.75000000 1 - Sr Sr11 1 0.87500000 0.62500000 0.25000000 1 - Er Er12 1 0.00000000 0.00000000 0.00000000 1 - Er Er13 1 0.50000000 0.00000000 0.50000000 1 - Er Er14 1 0.00000000 0.50000000 0.50000000 1 - Er Er15 1 0.50000000 0.00000000 0.00000000 1 - Er Er16 1 0.50000000 0.50000000 0.00000000 1 - Er Er17 1 0.50000000 0.50000000 0.50000000 1 - Er Er18 1 0.00000000 0.00000000 0.50000000 1 - Er Er19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48869900 0.38073800 0.29249000 1 - O O33 1 0.51130100 0.61926200 0.70751000 1 - O O34 1 0.58824700 0.19620900 0.20751000 1 - O O35 1 0.91175300 0.11926200 0.60796200 1 - O O36 1 0.29249000 0.48869900 0.38073800 1 - O O37 1 0.30379100 0.91175300 0.29249000 1 - O O38 1 0.41175300 0.80379100 0.79249000 1 - O O39 1 0.08824700 0.88073800 0.39203800 1 - O O40 1 0.70751000 0.51130100 0.61926200 1 - O O41 1 0.69620900 0.08824700 0.70751000 1 - O O42 1 0.01130100 0.30379100 0.89203800 1 - O O43 1 0.20751000 0.58824700 0.19620900 1 - O O44 1 0.11926200 0.01130100 0.20751000 1 - O O45 1 0.98869900 0.69620900 0.10796200 1 - O O46 1 0.79249000 0.41175300 0.80379100 1 - O O47 1 0.88073800 0.98869900 0.79249000 1 - O O48 1 0.60796200 0.91175300 0.11926200 1 - O O49 1 0.19620900 0.48869900 0.60796200 1 - O O50 1 0.39203800 0.08824700 0.88073800 1 - O O51 1 0.80379100 0.51130100 0.39203800 1 - O O52 1 0.89203800 0.01130100 0.30379100 1 - O O53 1 0.38073800 0.58824700 0.89203800 1 - O O54 1 0.10796200 0.98869900 0.69620900 1 - O O55 1 0.61926200 0.41175300 0.10796200 1 - O O56 1 0.38073800 0.29249000 0.48869900 1 - O O57 1 0.58824700 0.89203800 0.38073800 1 - O O58 1 0.61926200 0.70751000 0.51130100 1 - O O59 1 0.41175300 0.10796200 0.61926200 1 - O O60 1 0.11926200 0.60796200 0.91175300 1 - O O61 1 0.01130100 0.20751000 0.11926200 1 - O O62 1 0.88073800 0.39203800 0.08824700 1 - O O63 1 0.98869900 0.79249000 0.88073800 1 - O O64 1 0.30379100 0.89203800 0.01130100 1 - O O65 1 0.91175300 0.29249000 0.30379100 1 - O O66 1 0.69620900 0.10796200 0.98869900 1 - O O67 1 0.08824700 0.70751000 0.69620900 1 - O O68 1 0.19620900 0.20751000 0.58824700 1 - O O69 1 0.48869900 0.60796200 0.19620900 1 - O O70 1 0.80379100 0.79249000 0.41175300 1 - O O71 1 0.51130100 0.39203800 0.80379100 1 - O O72 1 0.29249000 0.30379100 0.91175300 1 - O O73 1 0.70751000 0.69620900 0.08824700 1 - O O74 1 0.20751000 0.11926200 0.01130100 1 - O O75 1 0.79249000 0.88073800 0.98869900 1 - O O76 1 0.89203800 0.38073800 0.58824700 1 - O O77 1 0.10796200 0.61926200 0.41175300 1 - O O78 1 0.60796200 0.19620900 0.48869900 1 - O O79 1 0.39203800 0.80379100 0.51130100 1 -" -Sm3Sc2(FeO4)3,mp-1209643,Ia-3d,[],0.0,"{'tags': ['Sc2Sm3Fe3O12', 'garnet family']}","Full Formula (Sm12 Sc8 Fe12 O48) -Reduced Formula: Sm3Sc2(FeO4)3 -abc : 11.082899 11.082899 11.082899 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sm 0.25 0.375 0.125 0.016 - 1 Sm 0.75 0.625 0.875 0.016 - 2 Sm 0.75 0.125 0.375 0.016 - 3 Sm 0.125 0.25 0.375 0.016 - 4 Sm 0.375 0.75 0.125 0.016 - 5 Sm 0.25 0.875 0.625 0.016 - 6 Sm 0.875 0.75 0.625 0.016 - 7 Sm 0.625 0.25 0.875 0.016 - 8 Sm 0.375 0.125 0.25 0.016 - 9 Sm 0.625 0.875 0.75 0.016 - 10 Sm 0.125 0.375 0.75 0.016 - 11 Sm 0.875 0.625 0.25 0.016 - 12 Sc 0 0 0 0.059 - 13 Sc 0.5 0 0.5 0.059 - 14 Sc 0 0.5 0.5 0.059 - 15 Sc 0.5 0 0 0.059 - 16 Sc 0.5 0.5 0 0.059 - 17 Sc 0.5 0.5 0.5 0.059 - 18 Sc 0 0 0.5 0.059 - 19 Sc 0 0.5 0 0.059 - 20 Fe 0.25 0.625 0.375 4.246 - 21 Fe 0.75 0.375 0.625 4.246 - 22 Fe 0.75 0.875 0.125 4.246 - 23 Fe 0.375 0.25 0.625 4.246 - 24 Fe 0.625 0.75 0.375 4.246 - 25 Fe 0.25 0.125 0.875 4.246 - 26 Fe 0.125 0.75 0.875 4.246 - 27 Fe 0.875 0.25 0.125 4.246 - 28 Fe 0.625 0.375 0.25 4.246 - 29 Fe 0.375 0.625 0.75 4.246 - 30 Fe 0.875 0.125 0.75 4.246 - 31 Fe 0.125 0.875 0.25 4.246 - 32 O 0.470756 0.374665 0.289967 0.136 - 33 O 0.529244 0.625335 0.710033 0.136 - 34 O 0.584698 0.180789 0.210033 0.136 - 35 O 0.915302 0.125335 0.596091 0.136 - 36 O 0.289967 0.470756 0.374665 0.135 - 37 O 0.319211 0.915302 0.289967 0.135 - 38 O 0.415302 0.819211 0.789967 0.136 - 39 O 0.084698 0.874665 0.403909 0.136 - 40 O 0.710033 0.529244 0.625335 0.135 - 41 O 0.680789 0.084698 0.710033 0.135 - 42 O 0.029244 0.319211 0.903909 0.136 - 43 O 0.210033 0.584698 0.180789 0.135 - 44 O 0.125335 0.029244 0.210033 0.136 - 45 O 0.970756 0.680789 0.096091 0.136 - 46 O 0.789967 0.415302 0.819211 0.135 - 47 O 0.874665 0.970756 0.789967 0.136 - 48 O 0.596091 0.915302 0.125335 0.136 - 49 O 0.180789 0.470756 0.596091 0.135 - 50 O 0.403909 0.084698 0.874665 0.136 - 51 O 0.819211 0.529244 0.403909 0.135 - 52 O 0.903909 0.029244 0.319211 0.136 - 53 O 0.374665 0.584698 0.903909 0.136 - 54 O 0.096091 0.970756 0.680789 0.136 - 55 O 0.625335 0.415302 0.096091 0.136 - 56 O 0.374665 0.289967 0.470756 0.136 - 57 O 0.584698 0.903909 0.374665 0.136 - 58 O 0.625335 0.710033 0.529244 0.136 - 59 O 0.415302 0.096091 0.625335 0.136 - 60 O 0.125335 0.596091 0.915302 0.136 - 61 O 0.029244 0.210033 0.125335 0.136 - 62 O 0.874665 0.403909 0.084698 0.136 - 63 O 0.970756 0.789967 0.874665 0.136 - 64 O 0.319211 0.903909 0.029244 0.135 - 65 O 0.915302 0.289967 0.319211 0.136 - 66 O 0.680789 0.096091 0.970756 0.135 - 67 O 0.084698 0.710033 0.680789 0.136 - 68 O 0.180789 0.210033 0.584698 0.135 - 69 O 0.470756 0.596091 0.180789 0.136 - 70 O 0.819211 0.789967 0.415302 0.135 - 71 O 0.529244 0.403909 0.819211 0.136 - 72 O 0.289967 0.319211 0.915302 0.135 - 73 O 0.710033 0.680789 0.084698 0.135 - 74 O 0.210033 0.125335 0.029244 0.135 - 75 O 0.789967 0.874665 0.970756 0.135 - 76 O 0.903909 0.374665 0.584698 0.136 - 77 O 0.096091 0.625335 0.415302 0.136 - 78 O 0.596091 0.180789 0.470756 0.136 - 79 O 0.403909 0.819211 0.529244 0.136","# generated using pymatgen -data_Sm3Sc2(FeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.08289948 -_cell_length_b 11.08289948 -_cell_length_c 11.08289948 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sm3Sc2(FeO4)3 -_chemical_formula_sum 'Sm12 Sc8 Fe12 O48' -_cell_volume 1047.94452361 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sm Sm0 1 0.25000000 0.37500000 0.12500000 1 - Sm Sm1 1 0.75000000 0.62500000 0.87500000 1 - Sm Sm2 1 0.75000000 0.12500000 0.37500000 1 - Sm Sm3 1 0.12500000 0.25000000 0.37500000 1 - Sm Sm4 1 0.37500000 0.75000000 0.12500000 1 - Sm Sm5 1 0.25000000 0.87500000 0.62500000 1 - Sm Sm6 1 0.87500000 0.75000000 0.62500000 1 - Sm Sm7 1 0.62500000 0.25000000 0.87500000 1 - Sm Sm8 1 0.37500000 0.12500000 0.25000000 1 - Sm Sm9 1 0.62500000 0.87500000 0.75000000 1 - Sm Sm10 1 0.12500000 0.37500000 0.75000000 1 - Sm Sm11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe21 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe22 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe23 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe24 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe25 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe26 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe27 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe28 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe29 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe30 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47075600 0.37466500 0.28996700 1 - O O33 1 0.52924400 0.62533500 0.71003300 1 - O O34 1 0.58469800 0.18078900 0.21003300 1 - O O35 1 0.91530200 0.12533500 0.59609100 1 - O O36 1 0.28996700 0.47075600 0.37466500 1 - O O37 1 0.31921100 0.91530200 0.28996700 1 - O O38 1 0.41530200 0.81921100 0.78996700 1 - O O39 1 0.08469800 0.87466500 0.40390900 1 - O O40 1 0.71003300 0.52924400 0.62533500 1 - O O41 1 0.68078900 0.08469800 0.71003300 1 - O O42 1 0.02924400 0.31921100 0.90390900 1 - O O43 1 0.21003300 0.58469800 0.18078900 1 - O O44 1 0.12533500 0.02924400 0.21003300 1 - O O45 1 0.97075600 0.68078900 0.09609100 1 - O O46 1 0.78996700 0.41530200 0.81921100 1 - O O47 1 0.87466500 0.97075600 0.78996700 1 - O O48 1 0.59609100 0.91530200 0.12533500 1 - O O49 1 0.18078900 0.47075600 0.59609100 1 - O O50 1 0.40390900 0.08469800 0.87466500 1 - O O51 1 0.81921100 0.52924400 0.40390900 1 - O O52 1 0.90390900 0.02924400 0.31921100 1 - O O53 1 0.37466500 0.58469800 0.90390900 1 - O O54 1 0.09609100 0.97075600 0.68078900 1 - O O55 1 0.62533500 0.41530200 0.09609100 1 - O O56 1 0.37466500 0.28996700 0.47075600 1 - O O57 1 0.58469800 0.90390900 0.37466500 1 - O O58 1 0.62533500 0.71003300 0.52924400 1 - O O59 1 0.41530200 0.09609100 0.62533500 1 - O O60 1 0.12533500 0.59609100 0.91530200 1 - O O61 1 0.02924400 0.21003300 0.12533500 1 - O O62 1 0.87466500 0.40390900 0.08469800 1 - O O63 1 0.97075600 0.78996700 0.87466500 1 - O O64 1 0.31921100 0.90390900 0.02924400 1 - O O65 1 0.91530200 0.28996700 0.31921100 1 - O O66 1 0.68078900 0.09609100 0.97075600 1 - O O67 1 0.08469800 0.71003300 0.68078900 1 - O O68 1 0.18078900 0.21003300 0.58469800 1 - O O69 1 0.47075600 0.59609100 0.18078900 1 - O O70 1 0.81921100 0.78996700 0.41530200 1 - O O71 1 0.52924400 0.40390900 0.81921100 1 - O O72 1 0.28996700 0.31921100 0.91530200 1 - O O73 1 0.71003300 0.68078900 0.08469800 1 - O O74 1 0.21003300 0.12533500 0.02924400 1 - O O75 1 0.78996700 0.87466500 0.97075600 1 - O O76 1 0.90390900 0.37466500 0.58469800 1 - O O77 1 0.09609100 0.62533500 0.41530200 1 - O O78 1 0.59609100 0.18078900 0.47075600 1 - O O79 1 0.40390900 0.81921100 0.52924400 1 -" -Pr3Sc2(FeO4)3,mp-1209949,Ia-3d,[],0.0,{'tags': []},"Full Formula (Pr12 Sc8 Fe12 O48) -Reduced Formula: Pr3Sc2(FeO4)3 -abc : 11.218855 11.218855 11.218855 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Pr 0.25 0.375 0.125 0.014 - 1 Pr 0.75 0.625 0.875 0.014 - 2 Pr 0.75 0.125 0.375 0.014 - 3 Pr 0.125 0.25 0.375 0.014 - 4 Pr 0.375 0.75 0.125 0.014 - 5 Pr 0.25 0.875 0.625 0.014 - 6 Pr 0.875 0.75 0.625 0.014 - 7 Pr 0.625 0.25 0.875 0.014 - 8 Pr 0.375 0.125 0.25 0.014 - 9 Pr 0.625 0.875 0.75 0.014 - 10 Pr 0.125 0.375 0.75 0.014 - 11 Pr 0.875 0.625 0.25 0.014 - 12 Sc 0 0 0 0.06 - 13 Sc 0.5 0 0.5 0.06 - 14 Sc 0 0.5 0.5 0.06 - 15 Sc 0.5 0 0 0.06 - 16 Sc 0.5 0.5 0 0.06 - 17 Sc 0.5 0.5 0.5 0.06 - 18 Sc 0 0 0.5 0.06 - 19 Sc 0 0.5 0 0.06 - 20 Fe 0.25 0.625 0.375 4.246 - 21 Fe 0.75 0.375 0.625 4.246 - 22 Fe 0.75 0.875 0.125 4.246 - 23 Fe 0.375 0.25 0.625 4.246 - 24 Fe 0.625 0.75 0.375 4.246 - 25 Fe 0.25 0.125 0.875 4.246 - 26 Fe 0.125 0.75 0.875 4.246 - 27 Fe 0.875 0.25 0.125 4.246 - 28 Fe 0.625 0.375 0.25 4.246 - 29 Fe 0.375 0.625 0.75 4.246 - 30 Fe 0.875 0.125 0.75 4.246 - 31 Fe 0.125 0.875 0.25 4.246 - 32 O 0.47414 0.377302 0.292378 0.135 - 33 O 0.52586 0.622698 0.707622 0.135 - 34 O 0.584924 0.181763 0.207622 0.135 - 35 O 0.915076 0.122698 0.596839 0.135 - 36 O 0.292378 0.47414 0.377302 0.135 - 37 O 0.318237 0.915076 0.292378 0.135 - 38 O 0.415076 0.818237 0.792378 0.135 - 39 O 0.084924 0.877302 0.403161 0.135 - 40 O 0.707622 0.52586 0.622698 0.135 - 41 O 0.681763 0.084924 0.707622 0.135 - 42 O 0.02586 0.318237 0.903161 0.135 - 43 O 0.207622 0.584924 0.181763 0.135 - 44 O 0.122698 0.02586 0.207622 0.135 - 45 O 0.97414 0.681763 0.096839 0.135 - 46 O 0.792378 0.415076 0.818237 0.135 - 47 O 0.877302 0.97414 0.792378 0.135 - 48 O 0.596839 0.915076 0.122698 0.135 - 49 O 0.181763 0.47414 0.596839 0.135 - 50 O 0.403161 0.084924 0.877302 0.135 - 51 O 0.818237 0.52586 0.403161 0.135 - 52 O 0.903161 0.02586 0.318237 0.135 - 53 O 0.377302 0.584924 0.903161 0.135 - 54 O 0.096839 0.97414 0.681763 0.135 - 55 O 0.622698 0.415076 0.096839 0.135 - 56 O 0.377302 0.292378 0.47414 0.135 - 57 O 0.584924 0.903161 0.377302 0.135 - 58 O 0.622698 0.707622 0.52586 0.135 - 59 O 0.415076 0.096839 0.622698 0.135 - 60 O 0.122698 0.596839 0.915076 0.135 - 61 O 0.02586 0.207622 0.122698 0.135 - 62 O 0.877302 0.403161 0.084924 0.135 - 63 O 0.97414 0.792378 0.877302 0.135 - 64 O 0.318237 0.903161 0.02586 0.135 - 65 O 0.915076 0.292378 0.318237 0.135 - 66 O 0.681763 0.096839 0.97414 0.135 - 67 O 0.084924 0.707622 0.681763 0.135 - 68 O 0.181763 0.207622 0.584924 0.135 - 69 O 0.47414 0.596839 0.181763 0.135 - 70 O 0.818237 0.792378 0.415076 0.135 - 71 O 0.52586 0.403161 0.818237 0.135 - 72 O 0.292378 0.318237 0.915076 0.135 - 73 O 0.707622 0.681763 0.084924 0.135 - 74 O 0.207622 0.122698 0.02586 0.135 - 75 O 0.792378 0.877302 0.97414 0.135 - 76 O 0.903161 0.377302 0.584924 0.135 - 77 O 0.096839 0.622698 0.415076 0.135 - 78 O 0.596839 0.181763 0.47414 0.135 - 79 O 0.403161 0.818237 0.52586 0.135","# generated using pymatgen -data_Pr3Sc2(FeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.21885508 -_cell_length_b 11.21885508 -_cell_length_c 11.21885508 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Pr3Sc2(FeO4)3 -_chemical_formula_sum 'Pr12 Sc8 Fe12 O48' -_cell_volume 1086.98543116 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Pr Pr0 1 0.25000000 0.37500000 0.12500000 1 - Pr Pr1 1 0.75000000 0.62500000 0.87500000 1 - Pr Pr2 1 0.75000000 0.12500000 0.37500000 1 - Pr Pr3 1 0.12500000 0.25000000 0.37500000 1 - Pr Pr4 1 0.37500000 0.75000000 0.12500000 1 - Pr Pr5 1 0.25000000 0.87500000 0.62500000 1 - Pr Pr6 1 0.87500000 0.75000000 0.62500000 1 - Pr Pr7 1 0.62500000 0.25000000 0.87500000 1 - Pr Pr8 1 0.37500000 0.12500000 0.25000000 1 - Pr Pr9 1 0.62500000 0.87500000 0.75000000 1 - Pr Pr10 1 0.12500000 0.37500000 0.75000000 1 - Pr Pr11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe21 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe22 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe23 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe24 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe25 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe26 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe27 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe28 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe29 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe30 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47414000 0.37730200 0.29237800 1 - O O33 1 0.52586000 0.62269800 0.70762200 1 - O O34 1 0.58492400 0.18176300 0.20762200 1 - O O35 1 0.91507600 0.12269800 0.59683900 1 - O O36 1 0.29237800 0.47414000 0.37730200 1 - O O37 1 0.31823700 0.91507600 0.29237800 1 - O O38 1 0.41507600 0.81823700 0.79237800 1 - O O39 1 0.08492400 0.87730200 0.40316100 1 - O O40 1 0.70762200 0.52586000 0.62269800 1 - O O41 1 0.68176300 0.08492400 0.70762200 1 - O O42 1 0.02586000 0.31823700 0.90316100 1 - O O43 1 0.20762200 0.58492400 0.18176300 1 - O O44 1 0.12269800 0.02586000 0.20762200 1 - O O45 1 0.97414000 0.68176300 0.09683900 1 - O O46 1 0.79237800 0.41507600 0.81823700 1 - O O47 1 0.87730200 0.97414000 0.79237800 1 - O O48 1 0.59683900 0.91507600 0.12269800 1 - O O49 1 0.18176300 0.47414000 0.59683900 1 - O O50 1 0.40316100 0.08492400 0.87730200 1 - O O51 1 0.81823700 0.52586000 0.40316100 1 - O O52 1 0.90316100 0.02586000 0.31823700 1 - O O53 1 0.37730200 0.58492400 0.90316100 1 - O O54 1 0.09683900 0.97414000 0.68176300 1 - O O55 1 0.62269800 0.41507600 0.09683900 1 - O O56 1 0.37730200 0.29237800 0.47414000 1 - O O57 1 0.58492400 0.90316100 0.37730200 1 - O O58 1 0.62269800 0.70762200 0.52586000 1 - O O59 1 0.41507600 0.09683900 0.62269800 1 - O O60 1 0.12269800 0.59683900 0.91507600 1 - O O61 1 0.02586000 0.20762200 0.12269800 1 - O O62 1 0.87730200 0.40316100 0.08492400 1 - O O63 1 0.97414000 0.79237800 0.87730200 1 - O O64 1 0.31823700 0.90316100 0.02586000 1 - O O65 1 0.91507600 0.29237800 0.31823700 1 - O O66 1 0.68176300 0.09683900 0.97414000 1 - O O67 1 0.08492400 0.70762200 0.68176300 1 - O O68 1 0.18176300 0.20762200 0.58492400 1 - O O69 1 0.47414000 0.59683900 0.18176300 1 - O O70 1 0.81823700 0.79237800 0.41507600 1 - O O71 1 0.52586000 0.40316100 0.81823700 1 - O O72 1 0.29237800 0.31823700 0.91507600 1 - O O73 1 0.70762200 0.68176300 0.08492400 1 - O O74 1 0.20762200 0.12269800 0.02586000 1 - O O75 1 0.79237800 0.87730200 0.97414000 1 - O O76 1 0.90316100 0.37730200 0.58492400 1 - O O77 1 0.09683900 0.62269800 0.41507600 1 - O O78 1 0.59683900 0.18176300 0.47414000 1 - O O79 1 0.40316100 0.81823700 0.52586000 1 -" -Nd3Tm2(GaO4)3,mp-1210408,Ia-3d,[],0.0,"{'tags': ['Nd3Tm2Ga3O12', 'garnet family', 'Y3Al5O12']}","Full Formula (Nd12 Tm8 Ga12 O48) -Reduced Formula: Nd3Tm2(GaO4)3 -abc : 11.280578 11.280578 11.280578 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Nd 0.25 0.375 0.125 -0 - 1 Nd 0.75 0.625 0.875 -0 - 2 Nd 0.75 0.125 0.375 -0 - 3 Nd 0.125 0.25 0.375 -0 - 4 Nd 0.375 0.75 0.125 -0 - 5 Nd 0.25 0.875 0.625 -0 - 6 Nd 0.875 0.75 0.625 -0 - 7 Nd 0.625 0.25 0.875 -0 - 8 Nd 0.375 0.125 0.25 -0 - 9 Nd 0.625 0.875 0.75 -0 - 10 Nd 0.125 0.375 0.75 -0 - 11 Nd 0.875 0.625 0.25 -0 - 12 Tm 0 0 0 -0 - 13 Tm 0.5 0 0.5 -0 - 14 Tm 0 0.5 0.5 -0 - 15 Tm 0.5 0 0 0 - 16 Tm 0.5 0.5 0 -0 - 17 Tm 0.5 0.5 0.5 -0 - 18 Tm 0 0 0.5 -0 - 19 Tm 0 0.5 0 0 - 20 Ga 0.25 0.625 0.375 0 - 21 Ga 0.75 0.375 0.625 0 - 22 Ga 0.75 0.875 0.125 0 - 23 Ga 0.375 0.25 0.625 0 - 24 Ga 0.625 0.75 0.375 0 - 25 Ga 0.25 0.125 0.875 0 - 26 Ga 0.125 0.75 0.875 0 - 27 Ga 0.875 0.25 0.125 0 - 28 Ga 0.625 0.375 0.25 0 - 29 Ga 0.375 0.625 0.75 0 - 30 Ga 0.875 0.125 0.75 0 - 31 Ga 0.125 0.875 0.25 0 - 32 O 0.4724 0.37277 0.284917 0 - 33 O 0.5276 0.62723 0.715083 0 - 34 O 0.587853 0.187482 0.215083 0 - 35 O 0.912147 0.12723 0.59963 0 - 36 O 0.284917 0.4724 0.37277 0 - 37 O 0.312518 0.912147 0.284917 0 - 38 O 0.412147 0.812518 0.784917 0 - 39 O 0.087853 0.87277 0.40037 0 - 40 O 0.715083 0.5276 0.62723 0 - 41 O 0.687482 0.087853 0.715083 0 - 42 O 0.0276 0.312518 0.90037 0 - 43 O 0.215083 0.587853 0.187482 0 - 44 O 0.12723 0.0276 0.215083 -0 - 45 O 0.9724 0.687482 0.09963 0 - 46 O 0.784917 0.412147 0.812518 -0 - 47 O 0.87277 0.9724 0.784917 0 - 48 O 0.59963 0.912147 0.12723 0 - 49 O 0.187482 0.4724 0.59963 0 - 50 O 0.40037 0.087853 0.87277 -0 - 51 O 0.812518 0.5276 0.40037 0 - 52 O 0.90037 0.0276 0.312518 0 - 53 O 0.37277 0.587853 0.90037 0 - 54 O 0.09963 0.9724 0.687482 0 - 55 O 0.62723 0.412147 0.09963 0 - 56 O 0.37277 0.284917 0.4724 -0 - 57 O 0.587853 0.90037 0.37277 0 - 58 O 0.62723 0.715083 0.5276 0 - 59 O 0.412147 0.09963 0.62723 0 - 60 O 0.12723 0.59963 0.912147 0 - 61 O 0.0276 0.215083 0.12723 0 - 62 O 0.87277 0.40037 0.087853 0 - 63 O 0.9724 0.784917 0.87277 0 - 64 O 0.312518 0.90037 0.0276 0 - 65 O 0.912147 0.284917 0.312518 0 - 66 O 0.687482 0.09963 0.9724 0 - 67 O 0.087853 0.715083 0.687482 0 - 68 O 0.187482 0.215083 0.587853 0 - 69 O 0.4724 0.59963 0.187482 0 - 70 O 0.812518 0.784917 0.412147 0 - 71 O 0.5276 0.40037 0.812518 0 - 72 O 0.284917 0.312518 0.912147 0 - 73 O 0.715083 0.687482 0.087853 0 - 74 O 0.215083 0.12723 0.0276 -0 - 75 O 0.784917 0.87277 0.9724 0 - 76 O 0.90037 0.37277 0.587853 -0 - 77 O 0.09963 0.62723 0.412147 0 - 78 O 0.59963 0.187482 0.4724 0 - 79 O 0.40037 0.812518 0.5276 0","# generated using pymatgen -data_Nd3Tm2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.28057844 -_cell_length_b 11.28057844 -_cell_length_c 11.28057844 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Nd3Tm2(GaO4)3 -_chemical_formula_sum 'Nd12 Tm8 Ga12 O48' -_cell_volume 1105.02529301 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Nd Nd0 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd1 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd2 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd3 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd4 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd5 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd6 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd7 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd8 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd9 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd10 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd11 1 0.87500000 0.62500000 0.25000000 1 - Tm Tm12 1 0.00000000 0.00000000 0.00000000 1 - Tm Tm13 1 0.50000000 0.00000000 0.50000000 1 - Tm Tm14 1 0.00000000 0.50000000 0.50000000 1 - Tm Tm15 1 0.50000000 0.00000000 0.00000000 1 - Tm Tm16 1 0.50000000 0.50000000 0.00000000 1 - Tm Tm17 1 0.50000000 0.50000000 0.50000000 1 - Tm Tm18 1 0.00000000 0.00000000 0.50000000 1 - Tm Tm19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47240000 0.37277000 0.28491700 1 - O O33 1 0.52760000 0.62723000 0.71508300 1 - O O34 1 0.58785300 0.18748200 0.21508300 1 - O O35 1 0.91214700 0.12723000 0.59963000 1 - O O36 1 0.28491700 0.47240000 0.37277000 1 - O O37 1 0.31251800 0.91214700 0.28491700 1 - O O38 1 0.41214700 0.81251800 0.78491700 1 - O O39 1 0.08785300 0.87277000 0.40037000 1 - O O40 1 0.71508300 0.52760000 0.62723000 1 - O O41 1 0.68748200 0.08785300 0.71508300 1 - O O42 1 0.02760000 0.31251800 0.90037000 1 - O O43 1 0.21508300 0.58785300 0.18748200 1 - O O44 1 0.12723000 0.02760000 0.21508300 1 - O O45 1 0.97240000 0.68748200 0.09963000 1 - O O46 1 0.78491700 0.41214700 0.81251800 1 - O O47 1 0.87277000 0.97240000 0.78491700 1 - O O48 1 0.59963000 0.91214700 0.12723000 1 - O O49 1 0.18748200 0.47240000 0.59963000 1 - O O50 1 0.40037000 0.08785300 0.87277000 1 - O O51 1 0.81251800 0.52760000 0.40037000 1 - O O52 1 0.90037000 0.02760000 0.31251800 1 - O O53 1 0.37277000 0.58785300 0.90037000 1 - O O54 1 0.09963000 0.97240000 0.68748200 1 - O O55 1 0.62723000 0.41214700 0.09963000 1 - O O56 1 0.37277000 0.28491700 0.47240000 1 - O O57 1 0.58785300 0.90037000 0.37277000 1 - O O58 1 0.62723000 0.71508300 0.52760000 1 - O O59 1 0.41214700 0.09963000 0.62723000 1 - O O60 1 0.12723000 0.59963000 0.91214700 1 - O O61 1 0.02760000 0.21508300 0.12723000 1 - O O62 1 0.87277000 0.40037000 0.08785300 1 - O O63 1 0.97240000 0.78491700 0.87277000 1 - O O64 1 0.31251800 0.90037000 0.02760000 1 - O O65 1 0.91214700 0.28491700 0.31251800 1 - O O66 1 0.68748200 0.09963000 0.97240000 1 - O O67 1 0.08785300 0.71508300 0.68748200 1 - O O68 1 0.18748200 0.21508300 0.58785300 1 - O O69 1 0.47240000 0.59963000 0.18748200 1 - O O70 1 0.81251800 0.78491700 0.41214700 1 - O O71 1 0.52760000 0.40037000 0.81251800 1 - O O72 1 0.28491700 0.31251800 0.91214700 1 - O O73 1 0.71508300 0.68748200 0.08785300 1 - O O74 1 0.21508300 0.12723000 0.02760000 1 - O O75 1 0.78491700 0.87277000 0.97240000 1 - O O76 1 0.90037000 0.37277000 0.58785300 1 - O O77 1 0.09963000 0.62723000 0.41214700 1 - O O78 1 0.59963000 0.18748200 0.47240000 1 - O O79 1 0.40037000 0.81251800 0.52760000 1 -" -Nd3Ho2(GaO4)3,mp-1210498,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Nd3Ho2Ga3O12', 'Y3Al5O12']}","Full Formula (Nd12 Ho8 Ga12 O48) -Reduced Formula: Nd3Ho2(GaO4)3 -abc : 11.324275 11.324275 11.324275 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Nd 0.25 0.375 0.125 -0 - 1 Nd 0.75 0.625 0.875 -0 - 2 Nd 0.75 0.125 0.375 -0 - 3 Nd 0.125 0.25 0.375 -0 - 4 Nd 0.375 0.75 0.125 -0 - 5 Nd 0.25 0.875 0.625 -0 - 6 Nd 0.875 0.75 0.625 -0 - 7 Nd 0.625 0.25 0.875 -0 - 8 Nd 0.375 0.125 0.25 -0 - 9 Nd 0.625 0.875 0.75 -0 - 10 Nd 0.125 0.375 0.75 -0 - 11 Nd 0.875 0.625 0.25 -0 - 12 Ho 0 0 0 -0 - 13 Ho 0.5 0 0.5 -0 - 14 Ho 0 0.5 0.5 -0 - 15 Ho 0.5 0 0 -0 - 16 Ho 0.5 0.5 0 -0 - 17 Ho 0.5 0.5 0.5 -0 - 18 Ho 0 0 0.5 -0 - 19 Ho 0 0.5 0 -0 - 20 Ga 0.25 0.625 0.375 0 - 21 Ga 0.75 0.375 0.625 0 - 22 Ga 0.75 0.875 0.125 0 - 23 Ga 0.375 0.25 0.625 0 - 24 Ga 0.625 0.75 0.375 0 - 25 Ga 0.25 0.125 0.875 0 - 26 Ga 0.125 0.75 0.875 0 - 27 Ga 0.875 0.25 0.125 0 - 28 Ga 0.625 0.375 0.25 0 - 29 Ga 0.375 0.625 0.75 0 - 30 Ga 0.875 0.125 0.75 0 - 31 Ga 0.125 0.875 0.25 0 - 32 O 0.471748 0.371822 0.283251 0 - 33 O 0.528252 0.628178 0.716749 0 - 34 O 0.588571 0.188496 0.216749 0 - 35 O 0.911429 0.128178 0.599925 0 - 36 O 0.283251 0.471748 0.371822 0 - 37 O 0.311504 0.911429 0.283251 0 - 38 O 0.411429 0.811504 0.783251 -0 - 39 O 0.088571 0.871822 0.400075 0 - 40 O 0.716749 0.528252 0.628178 0 - 41 O 0.688496 0.088571 0.716749 0 - 42 O 0.028252 0.311504 0.900075 0 - 43 O 0.216749 0.588571 0.188496 0 - 44 O 0.128178 0.028252 0.216749 0 - 45 O 0.971748 0.688496 0.099925 0 - 46 O 0.783251 0.411429 0.811504 0 - 47 O 0.871822 0.971748 0.783251 0 - 48 O 0.599925 0.911429 0.128178 0 - 49 O 0.188496 0.471748 0.599925 0 - 50 O 0.400075 0.088571 0.871822 0 - 51 O 0.811504 0.528252 0.400075 0 - 52 O 0.900075 0.028252 0.311504 0 - 53 O 0.371822 0.588571 0.900075 -0 - 54 O 0.099925 0.971748 0.688496 0 - 55 O 0.628178 0.411429 0.099925 0 - 56 O 0.371822 0.283251 0.471748 0 - 57 O 0.588571 0.900075 0.371822 0 - 58 O 0.628178 0.716749 0.528252 0 - 59 O 0.411429 0.099925 0.628178 0 - 60 O 0.128178 0.599925 0.911429 0 - 61 O 0.028252 0.216749 0.128178 0 - 62 O 0.871822 0.400075 0.088571 0 - 63 O 0.971748 0.783251 0.871822 0 - 64 O 0.311504 0.900075 0.028252 0 - 65 O 0.911429 0.283251 0.311504 0 - 66 O 0.688496 0.099925 0.971748 0 - 67 O 0.088571 0.716749 0.688496 0 - 68 O 0.188496 0.216749 0.588571 0 - 69 O 0.471748 0.599925 0.188496 0 - 70 O 0.811504 0.783251 0.411429 0 - 71 O 0.528252 0.400075 0.811504 0 - 72 O 0.283251 0.311504 0.911429 0 - 73 O 0.716749 0.688496 0.088571 0 - 74 O 0.216749 0.128178 0.028252 0 - 75 O 0.783251 0.871822 0.971748 0 - 76 O 0.900075 0.371822 0.588571 0 - 77 O 0.099925 0.628178 0.411429 0 - 78 O 0.599925 0.188496 0.471748 0 - 79 O 0.400075 0.811504 0.528252 0","# generated using pymatgen -data_Nd3Ho2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.32427462 -_cell_length_b 11.32427462 -_cell_length_c 11.32427462 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Nd3Ho2(GaO4)3 -_chemical_formula_sum 'Nd12 Ho8 Ga12 O48' -_cell_volume 1117.91629692 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Nd Nd0 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd1 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd2 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd3 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd4 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd5 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd6 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd7 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd8 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd9 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd10 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd11 1 0.87500000 0.62500000 0.25000000 1 - Ho Ho12 1 0.00000000 0.00000000 0.00000000 1 - Ho Ho13 1 0.50000000 0.00000000 0.50000000 1 - Ho Ho14 1 0.00000000 0.50000000 0.50000000 1 - Ho Ho15 1 0.50000000 0.00000000 0.00000000 1 - Ho Ho16 1 0.50000000 0.50000000 0.00000000 1 - Ho Ho17 1 0.50000000 0.50000000 0.50000000 1 - Ho Ho18 1 0.00000000 0.00000000 0.50000000 1 - Ho Ho19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47174800 0.37182200 0.28325100 1 - O O33 1 0.52825200 0.62817800 0.71674900 1 - O O34 1 0.58857100 0.18849600 0.21674900 1 - O O35 1 0.91142900 0.12817800 0.59992500 1 - O O36 1 0.28325100 0.47174800 0.37182200 1 - O O37 1 0.31150400 0.91142900 0.28325100 1 - O O38 1 0.41142900 0.81150400 0.78325100 1 - O O39 1 0.08857100 0.87182200 0.40007500 1 - O O40 1 0.71674900 0.52825200 0.62817800 1 - O O41 1 0.68849600 0.08857100 0.71674900 1 - O O42 1 0.02825200 0.31150400 0.90007500 1 - O O43 1 0.21674900 0.58857100 0.18849600 1 - O O44 1 0.12817800 0.02825200 0.21674900 1 - O O45 1 0.97174800 0.68849600 0.09992500 1 - O O46 1 0.78325100 0.41142900 0.81150400 1 - O O47 1 0.87182200 0.97174800 0.78325100 1 - O O48 1 0.59992500 0.91142900 0.12817800 1 - O O49 1 0.18849600 0.47174800 0.59992500 1 - O O50 1 0.40007500 0.08857100 0.87182200 1 - O O51 1 0.81150400 0.52825200 0.40007500 1 - O O52 1 0.90007500 0.02825200 0.31150400 1 - O O53 1 0.37182200 0.58857100 0.90007500 1 - O O54 1 0.09992500 0.97174800 0.68849600 1 - O O55 1 0.62817800 0.41142900 0.09992500 1 - O O56 1 0.37182200 0.28325100 0.47174800 1 - O O57 1 0.58857100 0.90007500 0.37182200 1 - O O58 1 0.62817800 0.71674900 0.52825200 1 - O O59 1 0.41142900 0.09992500 0.62817800 1 - O O60 1 0.12817800 0.59992500 0.91142900 1 - O O61 1 0.02825200 0.21674900 0.12817800 1 - O O62 1 0.87182200 0.40007500 0.08857100 1 - O O63 1 0.97174800 0.78325100 0.87182200 1 - O O64 1 0.31150400 0.90007500 0.02825200 1 - O O65 1 0.91142900 0.28325100 0.31150400 1 - O O66 1 0.68849600 0.09992500 0.97174800 1 - O O67 1 0.08857100 0.71674900 0.68849600 1 - O O68 1 0.18849600 0.21674900 0.58857100 1 - O O69 1 0.47174800 0.59992500 0.18849600 1 - O O70 1 0.81150400 0.78325100 0.41142900 1 - O O71 1 0.52825200 0.40007500 0.81150400 1 - O O72 1 0.28325100 0.31150400 0.91142900 1 - O O73 1 0.71674900 0.68849600 0.08857100 1 - O O74 1 0.21674900 0.12817800 0.02825200 1 - O O75 1 0.78325100 0.87182200 0.97174800 1 - O O76 1 0.90007500 0.37182200 0.58857100 1 - O O77 1 0.09992500 0.62817800 0.41142900 1 - O O78 1 0.59992500 0.18849600 0.47174800 1 - O O79 1 0.40007500 0.81150400 0.52825200 1 -" -Pr3Lu2(GaO4)3,mp-1210514,Ia-3d,[],0.0,"{'tags': ['Pr3Lu2Ga3O12', 'garnet family']}","Full Formula (Pr12 Lu8 Ga12 O48) -Reduced Formula: Pr3Lu2(GaO4)3 -abc : 11.306738 11.306738 11.306738 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Pr 0.25 0.375 0.125 0 - 1 Pr 0.75 0.625 0.875 0 - 2 Pr 0.75 0.125 0.375 0 - 3 Pr 0.125 0.25 0.375 0 - 4 Pr 0.375 0.75 0.125 0 - 5 Pr 0.25 0.875 0.625 0 - 6 Pr 0.875 0.75 0.625 0 - 7 Pr 0.625 0.25 0.875 0 - 8 Pr 0.375 0.125 0.25 0 - 9 Pr 0.625 0.875 0.75 0 - 10 Pr 0.125 0.375 0.75 0 - 11 Pr 0.875 0.625 0.25 0 - 12 Lu 0 0 0 0 - 13 Lu 0.5 0 0.5 0 - 14 Lu 0 0.5 0.5 0 - 15 Lu 0.5 0 0 0 - 16 Lu 0.5 0.5 0 0 - 17 Lu 0.5 0.5 0.5 0 - 18 Lu 0 0 0.5 0 - 19 Lu 0 0.5 0 0 - 20 Ga 0.25 0.625 0.375 0 - 21 Ga 0.75 0.375 0.625 -0 - 22 Ga 0.75 0.875 0.125 0 - 23 Ga 0.375 0.25 0.625 0 - 24 Ga 0.625 0.75 0.375 -0 - 25 Ga 0.25 0.125 0.875 -0 - 26 Ga 0.125 0.75 0.875 0 - 27 Ga 0.875 0.25 0.125 0 - 28 Ga 0.625 0.375 0.25 -0 - 29 Ga 0.375 0.625 0.75 -0 - 30 Ga 0.875 0.125 0.75 -0 - 31 Ga 0.125 0.875 0.25 0 - 32 O 0.474042 0.374984 0.286846 -0 - 33 O 0.525958 0.625016 0.713154 -0 - 34 O 0.588137 0.187195 0.213154 -0 - 35 O 0.911863 0.125016 0.599058 -0 - 36 O 0.286846 0.474042 0.374984 -0 - 37 O 0.312805 0.911863 0.286846 -0 - 38 O 0.411863 0.812805 0.786846 -0 - 39 O 0.088137 0.874984 0.400942 -0 - 40 O 0.713154 0.525958 0.625016 -0 - 41 O 0.687195 0.088137 0.713154 -0 - 42 O 0.025958 0.312805 0.900942 -0 - 43 O 0.213154 0.588137 0.187195 -0 - 44 O 0.125016 0.025958 0.213154 -0 - 45 O 0.974042 0.687195 0.099058 -0 - 46 O 0.786846 0.411863 0.812805 -0 - 47 O 0.874984 0.974042 0.786846 -0 - 48 O 0.599058 0.911863 0.125016 -0 - 49 O 0.187195 0.474042 0.599058 -0 - 50 O 0.400942 0.088137 0.874984 -0 - 51 O 0.812805 0.525958 0.400942 -0 - 52 O 0.900942 0.025958 0.312805 -0 - 53 O 0.374984 0.588137 0.900942 -0 - 54 O 0.099058 0.974042 0.687195 -0 - 55 O 0.625016 0.411863 0.099058 -0 - 56 O 0.374984 0.286846 0.474042 -0 - 57 O 0.588137 0.900942 0.374984 -0 - 58 O 0.625016 0.713154 0.525958 -0 - 59 O 0.411863 0.099058 0.625016 -0 - 60 O 0.125016 0.599058 0.911863 -0 - 61 O 0.025958 0.213154 0.125016 -0 - 62 O 0.874984 0.400942 0.088137 -0 - 63 O 0.974042 0.786846 0.874984 -0 - 64 O 0.312805 0.900942 0.025958 -0 - 65 O 0.911863 0.286846 0.312805 -0 - 66 O 0.687195 0.099058 0.974042 -0 - 67 O 0.088137 0.713154 0.687195 -0 - 68 O 0.187195 0.213154 0.588137 -0 - 69 O 0.474042 0.599058 0.187195 -0 - 70 O 0.812805 0.786846 0.411863 -0 - 71 O 0.525958 0.400942 0.812805 -0 - 72 O 0.286846 0.312805 0.911863 -0 - 73 O 0.713154 0.687195 0.088137 -0 - 74 O 0.213154 0.125016 0.025958 -0 - 75 O 0.786846 0.874984 0.974042 -0 - 76 O 0.900942 0.374984 0.588137 -0 - 77 O 0.099058 0.625016 0.411863 -0 - 78 O 0.599058 0.187195 0.474042 -0 - 79 O 0.400942 0.812805 0.525958 -0","# generated using pymatgen -data_Pr3Lu2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.30673761 -_cell_length_b 11.30673761 -_cell_length_c 11.30673761 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Pr3Lu2(GaO4)3 -_chemical_formula_sum 'Pr12 Lu8 Ga12 O48' -_cell_volume 1112.73064839 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Pr Pr0 1 0.25000000 0.37500000 0.12500000 1 - Pr Pr1 1 0.75000000 0.62500000 0.87500000 1 - Pr Pr2 1 0.75000000 0.12500000 0.37500000 1 - Pr Pr3 1 0.12500000 0.25000000 0.37500000 1 - Pr Pr4 1 0.37500000 0.75000000 0.12500000 1 - Pr Pr5 1 0.25000000 0.87500000 0.62500000 1 - Pr Pr6 1 0.87500000 0.75000000 0.62500000 1 - Pr Pr7 1 0.62500000 0.25000000 0.87500000 1 - Pr Pr8 1 0.37500000 0.12500000 0.25000000 1 - Pr Pr9 1 0.62500000 0.87500000 0.75000000 1 - Pr Pr10 1 0.12500000 0.37500000 0.75000000 1 - Pr Pr11 1 0.87500000 0.62500000 0.25000000 1 - Lu Lu12 1 0.00000000 0.00000000 0.00000000 1 - Lu Lu13 1 0.50000000 0.00000000 0.50000000 1 - Lu Lu14 1 0.00000000 0.50000000 0.50000000 1 - Lu Lu15 1 0.50000000 0.00000000 0.00000000 1 - Lu Lu16 1 0.50000000 0.50000000 0.00000000 1 - Lu Lu17 1 0.50000000 0.50000000 0.50000000 1 - Lu Lu18 1 0.00000000 0.00000000 0.50000000 1 - Lu Lu19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47404200 0.37498400 0.28684600 1 - O O33 1 0.52595800 0.62501600 0.71315400 1 - O O34 1 0.58813700 0.18719500 0.21315400 1 - O O35 1 0.91186300 0.12501600 0.59905800 1 - O O36 1 0.28684600 0.47404200 0.37498400 1 - O O37 1 0.31280500 0.91186300 0.28684600 1 - O O38 1 0.41186300 0.81280500 0.78684600 1 - O O39 1 0.08813700 0.87498400 0.40094200 1 - O O40 1 0.71315400 0.52595800 0.62501600 1 - O O41 1 0.68719500 0.08813700 0.71315400 1 - O O42 1 0.02595800 0.31280500 0.90094200 1 - O O43 1 0.21315400 0.58813700 0.18719500 1 - O O44 1 0.12501600 0.02595800 0.21315400 1 - O O45 1 0.97404200 0.68719500 0.09905800 1 - O O46 1 0.78684600 0.41186300 0.81280500 1 - O O47 1 0.87498400 0.97404200 0.78684600 1 - O O48 1 0.59905800 0.91186300 0.12501600 1 - O O49 1 0.18719500 0.47404200 0.59905800 1 - O O50 1 0.40094200 0.08813700 0.87498400 1 - O O51 1 0.81280500 0.52595800 0.40094200 1 - O O52 1 0.90094200 0.02595800 0.31280500 1 - O O53 1 0.37498400 0.58813700 0.90094200 1 - O O54 1 0.09905800 0.97404200 0.68719500 1 - O O55 1 0.62501600 0.41186300 0.09905800 1 - O O56 1 0.37498400 0.28684600 0.47404200 1 - O O57 1 0.58813700 0.90094200 0.37498400 1 - O O58 1 0.62501600 0.71315400 0.52595800 1 - O O59 1 0.41186300 0.09905800 0.62501600 1 - O O60 1 0.12501600 0.59905800 0.91186300 1 - O O61 1 0.02595800 0.21315400 0.12501600 1 - O O62 1 0.87498400 0.40094200 0.08813700 1 - O O63 1 0.97404200 0.78684600 0.87498400 1 - O O64 1 0.31280500 0.90094200 0.02595800 1 - O O65 1 0.91186300 0.28684600 0.31280500 1 - O O66 1 0.68719500 0.09905800 0.97404200 1 - O O67 1 0.08813700 0.71315400 0.68719500 1 - O O68 1 0.18719500 0.21315400 0.58813700 1 - O O69 1 0.47404200 0.59905800 0.18719500 1 - O O70 1 0.81280500 0.78684600 0.41186300 1 - O O71 1 0.52595800 0.40094200 0.81280500 1 - O O72 1 0.28684600 0.31280500 0.91186300 1 - O O73 1 0.71315400 0.68719500 0.08813700 1 - O O74 1 0.21315400 0.12501600 0.02595800 1 - O O75 1 0.78684600 0.87498400 0.97404200 1 - O O76 1 0.90094200 0.37498400 0.58813700 1 - O O77 1 0.09905800 0.62501600 0.41186300 1 - O O78 1 0.59905800 0.18719500 0.47404200 1 - O O79 1 0.40094200 0.81280500 0.52595800 1 -" -Na3Mg2V3O12,mp-1210549,Ia-3d,[],0.06502529087499997,{'tags': []},"Full Formula (Na12 Mg8 V12 O48) -Reduced Formula: Na3Mg2V3O12 -abc : 10.969164 10.969164 10.969164 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.25 0.375 0.125 -0.001 - 1 Na 0.75 0.625 0.875 -0.001 - 2 Na 0.75 0.125 0.375 -0.001 - 3 Na 0.125 0.25 0.375 -0.001 - 4 Na 0.375 0.75 0.125 -0.001 - 5 Na 0.25 0.875 0.625 -0.001 - 6 Na 0.875 0.75 0.625 -0.001 - 7 Na 0.625 0.25 0.875 -0.001 - 8 Na 0.375 0.125 0.25 -0.001 - 9 Na 0.625 0.875 0.75 -0.001 - 10 Na 0.125 0.375 0.75 -0.001 - 11 Na 0.875 0.625 0.25 -0.001 - 12 Mg 0 0 0 -0.001 - 13 Mg 0.5 0 0.5 -0.001 - 14 Mg 0 0.5 0.5 -0.001 - 15 Mg 0.5 0 0 -0.001 - 16 Mg 0.5 0.5 0 -0.001 - 17 Mg 0.5 0.5 0.5 -0.001 - 18 Mg 0 0 0.5 -0.001 - 19 Mg 0 0.5 0 -0.001 - 20 V 0.25 0.625 0.375 -0.108 - 21 V 0.75 0.375 0.625 -0.108 - 22 V 0.75 0.875 0.125 -0.108 - 23 V 0.375 0.25 0.625 -0.108 - 24 V 0.625 0.75 0.375 -0.108 - 25 V 0.25 0.125 0.875 -0.108 - 26 V 0.125 0.75 0.875 -0.108 - 27 V 0.875 0.25 0.125 -0.108 - 28 V 0.625 0.375 0.25 -0.108 - 29 V 0.375 0.625 0.75 -0.108 - 30 V 0.875 0.125 0.75 -0.108 - 31 V 0.125 0.875 0.25 -0.108 - 32 O 0.491223 0.387599 0.297634 0.161 - 33 O 0.508777 0.612401 0.702366 0.161 - 34 O 0.589965 0.193589 0.202366 0.161 - 35 O 0.910035 0.112401 0.603625 0.161 - 36 O 0.297634 0.491223 0.387599 0.161 - 37 O 0.306411 0.910035 0.297634 0.161 - 38 O 0.410035 0.806411 0.797634 0.161 - 39 O 0.089965 0.887599 0.396375 0.161 - 40 O 0.702366 0.508777 0.612401 0.161 - 41 O 0.693589 0.089965 0.702366 0.161 - 42 O 0.008777 0.306411 0.896375 0.161 - 43 O 0.202366 0.589965 0.193589 0.161 - 44 O 0.112401 0.008777 0.202366 0.161 - 45 O 0.991223 0.693589 0.103625 0.161 - 46 O 0.797634 0.410035 0.806411 0.161 - 47 O 0.887599 0.991223 0.797634 0.161 - 48 O 0.603625 0.910035 0.112401 0.161 - 49 O 0.193589 0.491223 0.603625 0.161 - 50 O 0.396375 0.089965 0.887599 0.161 - 51 O 0.806411 0.508777 0.396375 0.161 - 52 O 0.896375 0.008777 0.306411 0.161 - 53 O 0.387599 0.589965 0.896375 0.161 - 54 O 0.103625 0.991223 0.693589 0.161 - 55 O 0.612401 0.410035 0.103625 0.161 - 56 O 0.387599 0.297634 0.491223 0.161 - 57 O 0.589965 0.896375 0.387599 0.161 - 58 O 0.612401 0.702366 0.508777 0.161 - 59 O 0.410035 0.103625 0.612401 0.161 - 60 O 0.112401 0.603625 0.910035 0.161 - 61 O 0.008777 0.202366 0.112401 0.161 - 62 O 0.887599 0.396375 0.089965 0.161 - 63 O 0.991223 0.797634 0.887599 0.161 - 64 O 0.306411 0.896375 0.008777 0.161 - 65 O 0.910035 0.297634 0.306411 0.161 - 66 O 0.693589 0.103625 0.991223 0.161 - 67 O 0.089965 0.702366 0.693589 0.161 - 68 O 0.193589 0.202366 0.589965 0.161 - 69 O 0.491223 0.603625 0.193589 0.161 - 70 O 0.806411 0.797634 0.410035 0.161 - 71 O 0.508777 0.396375 0.806411 0.161 - 72 O 0.297634 0.306411 0.910035 0.161 - 73 O 0.702366 0.693589 0.089965 0.161 - 74 O 0.202366 0.112401 0.008777 0.161 - 75 O 0.797634 0.887599 0.991223 0.161 - 76 O 0.896375 0.387599 0.589965 0.161 - 77 O 0.103625 0.612401 0.410035 0.161 - 78 O 0.603625 0.193589 0.491223 0.161 - 79 O 0.396375 0.806411 0.508777 0.161","# generated using pymatgen -data_Na3Mg2V3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.96916437 -_cell_length_b 10.96916437 -_cell_length_c 10.96916437 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Mg2V3O12 -_chemical_formula_sum 'Na12 Mg8 V12 O48' -_cell_volume 1016.01177647 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.25000000 0.37500000 0.12500000 1 - Na Na1 1 0.75000000 0.62500000 0.87500000 1 - Na Na2 1 0.75000000 0.12500000 0.37500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.37500000 0.75000000 0.12500000 1 - Na Na5 1 0.25000000 0.87500000 0.62500000 1 - Na Na6 1 0.87500000 0.75000000 0.62500000 1 - Na Na7 1 0.62500000 0.25000000 0.87500000 1 - Na Na8 1 0.37500000 0.12500000 0.25000000 1 - Na Na9 1 0.62500000 0.87500000 0.75000000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg12 1 0.00000000 0.00000000 0.00000000 1 - Mg Mg13 1 0.50000000 0.00000000 0.50000000 1 - Mg Mg14 1 0.00000000 0.50000000 0.50000000 1 - Mg Mg15 1 0.50000000 0.00000000 0.00000000 1 - Mg Mg16 1 0.50000000 0.50000000 0.00000000 1 - Mg Mg17 1 0.50000000 0.50000000 0.50000000 1 - Mg Mg18 1 0.00000000 0.00000000 0.50000000 1 - Mg Mg19 1 0.00000000 0.50000000 0.00000000 1 - V V20 1 0.25000000 0.62500000 0.37500000 1 - V V21 1 0.75000000 0.37500000 0.62500000 1 - V V22 1 0.75000000 0.87500000 0.12500000 1 - V V23 1 0.37500000 0.25000000 0.62500000 1 - V V24 1 0.62500000 0.75000000 0.37500000 1 - V V25 1 0.25000000 0.12500000 0.87500000 1 - V V26 1 0.12500000 0.75000000 0.87500000 1 - V V27 1 0.87500000 0.25000000 0.12500000 1 - V V28 1 0.62500000 0.37500000 0.25000000 1 - V V29 1 0.37500000 0.62500000 0.75000000 1 - V V30 1 0.87500000 0.12500000 0.75000000 1 - V V31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.49122300 0.38759900 0.29763400 1 - O O33 1 0.50877700 0.61240100 0.70236600 1 - O O34 1 0.58996500 0.19358900 0.20236600 1 - O O35 1 0.91003500 0.11240100 0.60362500 1 - O O36 1 0.29763400 0.49122300 0.38759900 1 - O O37 1 0.30641100 0.91003500 0.29763400 1 - O O38 1 0.41003500 0.80641100 0.79763400 1 - O O39 1 0.08996500 0.88759900 0.39637500 1 - O O40 1 0.70236600 0.50877700 0.61240100 1 - O O41 1 0.69358900 0.08996500 0.70236600 1 - O O42 1 0.00877700 0.30641100 0.89637500 1 - O O43 1 0.20236600 0.58996500 0.19358900 1 - O O44 1 0.11240100 0.00877700 0.20236600 1 - O O45 1 0.99122300 0.69358900 0.10362500 1 - O O46 1 0.79763400 0.41003500 0.80641100 1 - O O47 1 0.88759900 0.99122300 0.79763400 1 - O O48 1 0.60362500 0.91003500 0.11240100 1 - O O49 1 0.19358900 0.49122300 0.60362500 1 - O O50 1 0.39637500 0.08996500 0.88759900 1 - O O51 1 0.80641100 0.50877700 0.39637500 1 - O O52 1 0.89637500 0.00877700 0.30641100 1 - O O53 1 0.38759900 0.58996500 0.89637500 1 - O O54 1 0.10362500 0.99122300 0.69358900 1 - O O55 1 0.61240100 0.41003500 0.10362500 1 - O O56 1 0.38759900 0.29763400 0.49122300 1 - O O57 1 0.58996500 0.89637500 0.38759900 1 - O O58 1 0.61240100 0.70236600 0.50877700 1 - O O59 1 0.41003500 0.10362500 0.61240100 1 - O O60 1 0.11240100 0.60362500 0.91003500 1 - O O61 1 0.00877700 0.20236600 0.11240100 1 - O O62 1 0.88759900 0.39637500 0.08996500 1 - O O63 1 0.99122300 0.79763400 0.88759900 1 - O O64 1 0.30641100 0.89637500 0.00877700 1 - O O65 1 0.91003500 0.29763400 0.30641100 1 - O O66 1 0.69358900 0.10362500 0.99122300 1 - O O67 1 0.08996500 0.70236600 0.69358900 1 - O O68 1 0.19358900 0.20236600 0.58996500 1 - O O69 1 0.49122300 0.60362500 0.19358900 1 - O O70 1 0.80641100 0.79763400 0.41003500 1 - O O71 1 0.50877700 0.39637500 0.80641100 1 - O O72 1 0.29763400 0.30641100 0.91003500 1 - O O73 1 0.70236600 0.69358900 0.08996500 1 - O O74 1 0.20236600 0.11240100 0.00877700 1 - O O75 1 0.79763400 0.88759900 0.99122300 1 - O O76 1 0.89637500 0.38759900 0.58996500 1 - O O77 1 0.10362500 0.61240100 0.41003500 1 - O O78 1 0.60362500 0.19358900 0.49122300 1 - O O79 1 0.39637500 0.80641100 0.50877700 1 -" -Nd3Sc2(FeO4)3,mp-1210576,Ia-3d,[],0.0,"{'tags': ['Sc2Nd3Fe3O12', 'garnet family']}","Full Formula (Nd12 Sc8 Fe12 O48) -Reduced Formula: Nd3Sc2(FeO4)3 -abc : 11.158370 11.158370 11.158370 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Nd 0.25 0.375 0.125 0.014 - 1 Nd 0.75 0.625 0.875 0.014 - 2 Nd 0.75 0.125 0.375 0.014 - 3 Nd 0.125 0.25 0.375 0.014 - 4 Nd 0.375 0.75 0.125 0.014 - 5 Nd 0.25 0.875 0.625 0.014 - 6 Nd 0.875 0.75 0.625 0.014 - 7 Nd 0.625 0.25 0.875 0.014 - 8 Nd 0.375 0.125 0.25 0.014 - 9 Nd 0.625 0.875 0.75 0.014 - 10 Nd 0.125 0.375 0.75 0.014 - 11 Nd 0.875 0.625 0.25 0.014 - 12 Sc 0 0 0 0.059 - 13 Sc 0.5 0 0.5 0.06 - 14 Sc 0 0.5 0.5 0.06 - 15 Sc 0.5 0 0 0.06 - 16 Sc 0.5 0.5 0 0.059 - 17 Sc 0.5 0.5 0.5 0.059 - 18 Sc 0 0 0.5 0.06 - 19 Sc 0 0.5 0 0.059 - 20 Fe 0.25 0.625 0.375 4.246 - 21 Fe 0.75 0.375 0.625 4.246 - 22 Fe 0.75 0.875 0.125 4.246 - 23 Fe 0.375 0.25 0.625 4.245 - 24 Fe 0.625 0.75 0.375 4.245 - 25 Fe 0.25 0.125 0.875 4.246 - 26 Fe 0.125 0.75 0.875 4.245 - 27 Fe 0.875 0.25 0.125 4.245 - 28 Fe 0.625 0.375 0.25 4.245 - 29 Fe 0.375 0.625 0.75 4.245 - 30 Fe 0.875 0.125 0.75 4.245 - 31 Fe 0.125 0.875 0.25 4.245 - 32 O 0.473004 0.376036 0.291976 0.136 - 33 O 0.526996 0.623964 0.708024 0.136 - 34 O 0.58406 0.181028 0.208024 0.136 - 35 O 0.91594 0.123964 0.596967 0.136 - 36 O 0.291976 0.473004 0.376036 0.135 - 37 O 0.318972 0.91594 0.291976 0.135 - 38 O 0.41594 0.818972 0.791976 0.136 - 39 O 0.08406 0.876036 0.403033 0.136 - 40 O 0.708024 0.526996 0.623964 0.135 - 41 O 0.681028 0.08406 0.708024 0.135 - 42 O 0.026996 0.318972 0.903033 0.136 - 43 O 0.208024 0.58406 0.181028 0.135 - 44 O 0.123964 0.026996 0.208024 0.136 - 45 O 0.973004 0.681028 0.096967 0.136 - 46 O 0.791976 0.41594 0.818972 0.135 - 47 O 0.876036 0.973004 0.791976 0.136 - 48 O 0.596967 0.91594 0.123964 0.136 - 49 O 0.181028 0.473004 0.596967 0.135 - 50 O 0.403033 0.08406 0.876036 0.136 - 51 O 0.818972 0.526996 0.403033 0.135 - 52 O 0.903033 0.026996 0.318972 0.136 - 53 O 0.376036 0.58406 0.903033 0.136 - 54 O 0.096967 0.973004 0.681028 0.136 - 55 O 0.623964 0.41594 0.096967 0.136 - 56 O 0.376036 0.291976 0.473004 0.136 - 57 O 0.58406 0.903033 0.376036 0.136 - 58 O 0.623964 0.708024 0.526996 0.136 - 59 O 0.41594 0.096967 0.623964 0.136 - 60 O 0.123964 0.596967 0.91594 0.136 - 61 O 0.026996 0.208024 0.123964 0.136 - 62 O 0.876036 0.403033 0.08406 0.136 - 63 O 0.973004 0.791976 0.876036 0.136 - 64 O 0.318972 0.903033 0.026996 0.135 - 65 O 0.91594 0.291976 0.318972 0.136 - 66 O 0.681028 0.096967 0.973004 0.135 - 67 O 0.08406 0.708024 0.681028 0.136 - 68 O 0.181028 0.208024 0.58406 0.135 - 69 O 0.473004 0.596967 0.181028 0.136 - 70 O 0.818972 0.791976 0.41594 0.135 - 71 O 0.526996 0.403033 0.818972 0.136 - 72 O 0.291976 0.318972 0.91594 0.135 - 73 O 0.708024 0.681028 0.08406 0.135 - 74 O 0.208024 0.123964 0.026996 0.135 - 75 O 0.791976 0.876036 0.973004 0.135 - 76 O 0.903033 0.376036 0.58406 0.136 - 77 O 0.096967 0.623964 0.41594 0.136 - 78 O 0.596967 0.181028 0.473004 0.136 - 79 O 0.403033 0.818972 0.526996 0.136","# generated using pymatgen -data_Nd3Sc2(FeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.15837013 -_cell_length_b 11.15837013 -_cell_length_c 11.15837013 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Nd3Sc2(FeO4)3 -_chemical_formula_sum 'Nd12 Sc8 Fe12 O48' -_cell_volume 1069.49903977 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Nd Nd0 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd1 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd2 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd3 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd4 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd5 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd6 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd7 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd8 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd9 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd10 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe21 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe22 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe23 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe24 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe25 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe26 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe27 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe28 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe29 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe30 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47300400 0.37603600 0.29197600 1 - O O33 1 0.52699600 0.62396400 0.70802400 1 - O O34 1 0.58406000 0.18102800 0.20802400 1 - O O35 1 0.91594000 0.12396400 0.59696700 1 - O O36 1 0.29197600 0.47300400 0.37603600 1 - O O37 1 0.31897200 0.91594000 0.29197600 1 - O O38 1 0.41594000 0.81897200 0.79197600 1 - O O39 1 0.08406000 0.87603600 0.40303300 1 - O O40 1 0.70802400 0.52699600 0.62396400 1 - O O41 1 0.68102800 0.08406000 0.70802400 1 - O O42 1 0.02699600 0.31897200 0.90303300 1 - O O43 1 0.20802400 0.58406000 0.18102800 1 - O O44 1 0.12396400 0.02699600 0.20802400 1 - O O45 1 0.97300400 0.68102800 0.09696700 1 - O O46 1 0.79197600 0.41594000 0.81897200 1 - O O47 1 0.87603600 0.97300400 0.79197600 1 - O O48 1 0.59696700 0.91594000 0.12396400 1 - O O49 1 0.18102800 0.47300400 0.59696700 1 - O O50 1 0.40303300 0.08406000 0.87603600 1 - O O51 1 0.81897200 0.52699600 0.40303300 1 - O O52 1 0.90303300 0.02699600 0.31897200 1 - O O53 1 0.37603600 0.58406000 0.90303300 1 - O O54 1 0.09696700 0.97300400 0.68102800 1 - O O55 1 0.62396400 0.41594000 0.09696700 1 - O O56 1 0.37603600 0.29197600 0.47300400 1 - O O57 1 0.58406000 0.90303300 0.37603600 1 - O O58 1 0.62396400 0.70802400 0.52699600 1 - O O59 1 0.41594000 0.09696700 0.62396400 1 - O O60 1 0.12396400 0.59696700 0.91594000 1 - O O61 1 0.02699600 0.20802400 0.12396400 1 - O O62 1 0.87603600 0.40303300 0.08406000 1 - O O63 1 0.97300400 0.79197600 0.87603600 1 - O O64 1 0.31897200 0.90303300 0.02699600 1 - O O65 1 0.91594000 0.29197600 0.31897200 1 - O O66 1 0.68102800 0.09696700 0.97300400 1 - O O67 1 0.08406000 0.70802400 0.68102800 1 - O O68 1 0.18102800 0.20802400 0.58406000 1 - O O69 1 0.47300400 0.59696700 0.18102800 1 - O O70 1 0.81897200 0.79197600 0.41594000 1 - O O71 1 0.52699600 0.40303300 0.81897200 1 - O O72 1 0.29197600 0.31897200 0.91594000 1 - O O73 1 0.70802400 0.68102800 0.08406000 1 - O O74 1 0.20802400 0.12396400 0.02699600 1 - O O75 1 0.79197600 0.87603600 0.97300400 1 - O O76 1 0.90303300 0.37603600 0.58406000 1 - O O77 1 0.09696700 0.62396400 0.41594000 1 - O O78 1 0.59696700 0.18102800 0.47300400 1 - O O79 1 0.40303300 0.81897200 0.52699600 1 -" -Na3Mn2V3O12,mp-1210577,Ia-3d,[],0.03029697371875706,{'tags': ['garnet family']},"Full Formula (Na12 Mn8 V12 O48) -Reduced Formula: Na3Mn2V3O12 -abc : 10.862799 10.862799 10.862799 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.25 0.375 0.125 0 - 1 Na 0.75 0.625 0.875 0 - 2 Na 0.75 0.125 0.375 0 - 3 Na 0.125 0.25 0.375 0 - 4 Na 0.375 0.75 0.125 0 - 5 Na 0.25 0.875 0.625 0 - 6 Na 0.875 0.75 0.625 0 - 7 Na 0.625 0.25 0.875 0 - 8 Na 0.375 0.125 0.25 0 - 9 Na 0.625 0.875 0.75 0 - 10 Na 0.125 0.375 0.75 0 - 11 Na 0.875 0.625 0.25 0 - 12 Mn 0 0 0 3.985 - 13 Mn 0.5 0 0.5 4.008 - 14 Mn 0 0.5 0.5 4.008 - 15 Mn 0.5 0 0 4.008 - 16 Mn 0.5 0.5 0 3.985 - 17 Mn 0.5 0.5 0.5 3.985 - 18 Mn 0 0 0.5 4.008 - 19 Mn 0 0.5 0 3.985 - 20 V 0.25 0.625 0.375 0.215 - 21 V 0.75 0.375 0.625 0.215 - 22 V 0.75 0.875 0.125 0.215 - 23 V 0.375 0.25 0.625 0.206 - 24 V 0.625 0.75 0.375 0.206 - 25 V 0.25 0.125 0.875 0.215 - 26 V 0.125 0.75 0.875 0.206 - 27 V 0.875 0.25 0.125 0.206 - 28 V 0.625 0.375 0.25 0.206 - 29 V 0.375 0.625 0.75 0.206 - 30 V 0.875 0.125 0.75 0.206 - 31 V 0.125 0.875 0.25 0.206 - 32 O 0.491382 0.38971 0.300691 -0.063 - 33 O 0.508618 0.61029 0.699309 -0.063 - 34 O 0.589019 0.190691 0.199309 -0.064 - 35 O 0.910981 0.11029 0.601672 -0.064 - 36 O 0.300691 0.491382 0.38971 -0.063 - 37 O 0.309309 0.910981 0.300691 -0.06 - 38 O 0.410981 0.809309 0.800691 -0.064 - 39 O 0.089019 0.88971 0.398328 -0.064 - 40 O 0.699309 0.508618 0.61029 -0.063 - 41 O 0.690691 0.089019 0.699309 -0.06 - 42 O 0.008618 0.309309 0.898328 -0.063 - 43 O 0.199309 0.589019 0.190691 -0.063 - 44 O 0.11029 0.008618 0.199309 -0.067 - 45 O 0.991382 0.690691 0.101672 -0.063 - 46 O 0.800691 0.410981 0.809309 -0.063 - 47 O 0.88971 0.991382 0.800691 -0.067 - 48 O 0.601672 0.910981 0.11029 -0.064 - 49 O 0.190691 0.491382 0.601672 -0.06 - 50 O 0.398328 0.089019 0.88971 -0.064 - 51 O 0.809309 0.508618 0.398328 -0.06 - 52 O 0.898328 0.008618 0.309309 -0.064 - 53 O 0.38971 0.589019 0.898328 -0.067 - 54 O 0.101672 0.991382 0.690691 -0.064 - 55 O 0.61029 0.410981 0.101672 -0.067 - 56 O 0.38971 0.300691 0.491382 -0.067 - 57 O 0.589019 0.898328 0.38971 -0.064 - 58 O 0.61029 0.699309 0.508618 -0.067 - 59 O 0.410981 0.101672 0.61029 -0.064 - 60 O 0.11029 0.601672 0.910981 -0.067 - 61 O 0.008618 0.199309 0.11029 -0.063 - 62 O 0.88971 0.398328 0.089019 -0.067 - 63 O 0.991382 0.800691 0.88971 -0.063 - 64 O 0.309309 0.898328 0.008618 -0.06 - 65 O 0.910981 0.300691 0.309309 -0.064 - 66 O 0.690691 0.101672 0.991382 -0.06 - 67 O 0.089019 0.699309 0.690691 -0.064 - 68 O 0.190691 0.199309 0.589019 -0.06 - 69 O 0.491382 0.601672 0.190691 -0.063 - 70 O 0.809309 0.800691 0.410981 -0.06 - 71 O 0.508618 0.398328 0.809309 -0.063 - 72 O 0.300691 0.309309 0.910981 -0.063 - 73 O 0.699309 0.690691 0.089019 -0.063 - 74 O 0.199309 0.11029 0.008618 -0.063 - 75 O 0.800691 0.88971 0.991382 -0.063 - 76 O 0.898328 0.38971 0.589019 -0.064 - 77 O 0.101672 0.61029 0.410981 -0.064 - 78 O 0.601672 0.190691 0.491382 -0.064 - 79 O 0.398328 0.809309 0.508618 -0.064","# generated using pymatgen -data_Na3Mn2V3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.86279913 -_cell_length_b 10.86279913 -_cell_length_c 10.86279913 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Mn2V3O12 -_chemical_formula_sum 'Na12 Mn8 V12 O48' -_cell_volume 986.74141226 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.25000000 0.37500000 0.12500000 1 - Na Na1 1 0.75000000 0.62500000 0.87500000 1 - Na Na2 1 0.75000000 0.12500000 0.37500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.37500000 0.75000000 0.12500000 1 - Na Na5 1 0.25000000 0.87500000 0.62500000 1 - Na Na6 1 0.87500000 0.75000000 0.62500000 1 - Na Na7 1 0.62500000 0.25000000 0.87500000 1 - Na Na8 1 0.37500000 0.12500000 0.25000000 1 - Na Na9 1 0.62500000 0.87500000 0.75000000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn12 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn13 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn14 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn15 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn16 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn17 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn18 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn19 1 0.00000000 0.50000000 0.00000000 1 - V V20 1 0.25000000 0.62500000 0.37500000 1 - V V21 1 0.75000000 0.37500000 0.62500000 1 - V V22 1 0.75000000 0.87500000 0.12500000 1 - V V23 1 0.37500000 0.25000000 0.62500000 1 - V V24 1 0.62500000 0.75000000 0.37500000 1 - V V25 1 0.25000000 0.12500000 0.87500000 1 - V V26 1 0.12500000 0.75000000 0.87500000 1 - V V27 1 0.87500000 0.25000000 0.12500000 1 - V V28 1 0.62500000 0.37500000 0.25000000 1 - V V29 1 0.37500000 0.62500000 0.75000000 1 - V V30 1 0.87500000 0.12500000 0.75000000 1 - V V31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.49138200 0.38971000 0.30069100 1 - O O33 1 0.50861800 0.61029000 0.69930900 1 - O O34 1 0.58901900 0.19069100 0.19930900 1 - O O35 1 0.91098100 0.11029000 0.60167200 1 - O O36 1 0.30069100 0.49138200 0.38971000 1 - O O37 1 0.30930900 0.91098100 0.30069100 1 - O O38 1 0.41098100 0.80930900 0.80069100 1 - O O39 1 0.08901900 0.88971000 0.39832800 1 - O O40 1 0.69930900 0.50861800 0.61029000 1 - O O41 1 0.69069100 0.08901900 0.69930900 1 - O O42 1 0.00861800 0.30930900 0.89832800 1 - O O43 1 0.19930900 0.58901900 0.19069100 1 - O O44 1 0.11029000 0.00861800 0.19930900 1 - O O45 1 0.99138200 0.69069100 0.10167200 1 - O O46 1 0.80069100 0.41098100 0.80930900 1 - O O47 1 0.88971000 0.99138200 0.80069100 1 - O O48 1 0.60167200 0.91098100 0.11029000 1 - O O49 1 0.19069100 0.49138200 0.60167200 1 - O O50 1 0.39832800 0.08901900 0.88971000 1 - O O51 1 0.80930900 0.50861800 0.39832800 1 - O O52 1 0.89832800 0.00861800 0.30930900 1 - O O53 1 0.38971000 0.58901900 0.89832800 1 - O O54 1 0.10167200 0.99138200 0.69069100 1 - O O55 1 0.61029000 0.41098100 0.10167200 1 - O O56 1 0.38971000 0.30069100 0.49138200 1 - O O57 1 0.58901900 0.89832800 0.38971000 1 - O O58 1 0.61029000 0.69930900 0.50861800 1 - O O59 1 0.41098100 0.10167200 0.61029000 1 - O O60 1 0.11029000 0.60167200 0.91098100 1 - O O61 1 0.00861800 0.19930900 0.11029000 1 - O O62 1 0.88971000 0.39832800 0.08901900 1 - O O63 1 0.99138200 0.80069100 0.88971000 1 - O O64 1 0.30930900 0.89832800 0.00861800 1 - O O65 1 0.91098100 0.30069100 0.30930900 1 - O O66 1 0.69069100 0.10167200 0.99138200 1 - O O67 1 0.08901900 0.69930900 0.69069100 1 - O O68 1 0.19069100 0.19930900 0.58901900 1 - O O69 1 0.49138200 0.60167200 0.19069100 1 - O O70 1 0.80930900 0.80069100 0.41098100 1 - O O71 1 0.50861800 0.39832800 0.80930900 1 - O O72 1 0.30069100 0.30930900 0.91098100 1 - O O73 1 0.69930900 0.69069100 0.08901900 1 - O O74 1 0.19930900 0.11029000 0.00861800 1 - O O75 1 0.80069100 0.88971000 0.99138200 1 - O O76 1 0.89832800 0.38971000 0.58901900 1 - O O77 1 0.10167200 0.61029000 0.41098100 1 - O O78 1 0.60167200 0.19069100 0.49138200 1 - O O79 1 0.39832800 0.80930900 0.50861800 1 -" -Na3Li3Rh2F12,mp-1210682,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Na3Li3Rh2F12']}","Full Formula (Na12 Li12 Rh8 F48) -Reduced Formula: Na3Li3Rh2F12 -abc : 10.977383 10.977383 10.977383 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.25 0.375 0.125 0 - 1 Na 0.75 0.625 0.875 0 - 2 Na 0.75 0.125 0.375 0 - 3 Na 0.125 0.25 0.375 0 - 4 Na 0.375 0.75 0.125 0 - 5 Na 0.25 0.875 0.625 0 - 6 Na 0.875 0.75 0.625 0 - 7 Na 0.625 0.25 0.875 0 - 8 Na 0.375 0.125 0.25 0 - 9 Na 0.625 0.875 0.75 0 - 10 Na 0.125 0.375 0.75 0 - 11 Na 0.875 0.625 0.25 0 - 12 Li 0.25 0.625 0.375 -0 - 13 Li 0.75 0.375 0.625 -0 - 14 Li 0.75 0.875 0.125 0 - 15 Li 0.375 0.25 0.625 -0 - 16 Li 0.625 0.75 0.375 -0 - 17 Li 0.25 0.125 0.875 -0 - 18 Li 0.125 0.75 0.875 0 - 19 Li 0.875 0.25 0.125 0 - 20 Li 0.625 0.375 0.25 0 - 21 Li 0.375 0.625 0.75 -0 - 22 Li 0.875 0.125 0.75 0 - 23 Li 0.125 0.875 0.25 0 - 24 Rh 0 0 0 0 - 25 Rh 0.5 0 0.5 0 - 26 Rh 0 0.5 0.5 0 - 27 Rh 0.5 0 0 0 - 28 Rh 0.5 0.5 0 0 - 29 Rh 0.5 0.5 0.5 0 - 30 Rh 0 0 0.5 0 - 31 Rh 0 0.5 0 0 - 32 F 0.479098 0.380629 0.302039 0 - 33 F 0.520902 0.619371 0.697961 0 - 34 F 0.57859 0.177059 0.197961 0 - 35 F 0.92141 0.119371 0.598469 0 - 36 F 0.302039 0.479098 0.380629 0 - 37 F 0.322941 0.92141 0.302039 0 - 38 F 0.42141 0.822941 0.802039 0 - 39 F 0.07859 0.880629 0.401531 0 - 40 F 0.697961 0.520902 0.619371 0 - 41 F 0.677059 0.07859 0.697961 0 - 42 F 0.020902 0.322941 0.901531 0 - 43 F 0.197961 0.57859 0.177059 0 - 44 F 0.119371 0.020902 0.197961 0 - 45 F 0.979098 0.677059 0.098469 0 - 46 F 0.802039 0.42141 0.822941 0 - 47 F 0.880629 0.979098 0.802039 0 - 48 F 0.598469 0.92141 0.119371 0 - 49 F 0.177059 0.479098 0.598469 0 - 50 F 0.401531 0.07859 0.880629 0 - 51 F 0.822941 0.520902 0.401531 0 - 52 F 0.901531 0.020902 0.322941 0 - 53 F 0.380629 0.57859 0.901531 0 - 54 F 0.098469 0.979098 0.677059 0 - 55 F 0.619371 0.42141 0.098469 0 - 56 F 0.380629 0.302039 0.479098 0 - 57 F 0.57859 0.901531 0.380629 0 - 58 F 0.619371 0.697961 0.520902 0 - 59 F 0.42141 0.098469 0.619371 0 - 60 F 0.119371 0.598469 0.92141 0 - 61 F 0.020902 0.197961 0.119371 0 - 62 F 0.880629 0.401531 0.07859 0 - 63 F 0.979098 0.802039 0.880629 0 - 64 F 0.322941 0.901531 0.020902 0 - 65 F 0.92141 0.302039 0.322941 0 - 66 F 0.677059 0.098469 0.979098 0 - 67 F 0.07859 0.697961 0.677059 0 - 68 F 0.177059 0.197961 0.57859 0 - 69 F 0.479098 0.598469 0.177059 0 - 70 F 0.822941 0.802039 0.42141 0 - 71 F 0.520902 0.401531 0.822941 0 - 72 F 0.302039 0.322941 0.92141 0 - 73 F 0.697961 0.677059 0.07859 0 - 74 F 0.197961 0.119371 0.020902 0 - 75 F 0.802039 0.880629 0.979098 0 - 76 F 0.901531 0.380629 0.57859 0 - 77 F 0.098469 0.619371 0.42141 0 - 78 F 0.598469 0.177059 0.479098 0 - 79 F 0.401531 0.822941 0.520902 0","# generated using pymatgen -data_Na3Li3Rh2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.97738295 -_cell_length_b 10.97738295 -_cell_length_c 10.97738295 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3Rh2F12 -_chemical_formula_sum 'Na12 Li12 Rh8 F48' -_cell_volume 1018.29721028 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.25000000 0.37500000 0.12500000 1 - Na Na1 1 0.75000000 0.62500000 0.87500000 1 - Na Na2 1 0.75000000 0.12500000 0.37500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.37500000 0.75000000 0.12500000 1 - Na Na5 1 0.25000000 0.87500000 0.62500000 1 - Na Na6 1 0.87500000 0.75000000 0.62500000 1 - Na Na7 1 0.62500000 0.25000000 0.87500000 1 - Na Na8 1 0.37500000 0.12500000 0.25000000 1 - Na Na9 1 0.62500000 0.87500000 0.75000000 1 - Na Na10 1 0.12500000 0.37500000 0.75000000 1 - Na Na11 1 0.87500000 0.62500000 0.25000000 1 - Li Li12 1 0.25000000 0.62500000 0.37500000 1 - Li Li13 1 0.75000000 0.37500000 0.62500000 1 - Li Li14 1 0.75000000 0.87500000 0.12500000 1 - Li Li15 1 0.37500000 0.25000000 0.62500000 1 - Li Li16 1 0.62500000 0.75000000 0.37500000 1 - Li Li17 1 0.25000000 0.12500000 0.87500000 1 - Li Li18 1 0.12500000 0.75000000 0.87500000 1 - Li Li19 1 0.87500000 0.25000000 0.12500000 1 - Li Li20 1 0.62500000 0.37500000 0.25000000 1 - Li Li21 1 0.37500000 0.62500000 0.75000000 1 - Li Li22 1 0.87500000 0.12500000 0.75000000 1 - Li Li23 1 0.12500000 0.87500000 0.25000000 1 - Rh Rh24 1 0.00000000 0.00000000 0.00000000 1 - Rh Rh25 1 0.50000000 0.00000000 0.50000000 1 - Rh Rh26 1 0.00000000 0.50000000 0.50000000 1 - Rh Rh27 1 0.50000000 0.00000000 0.00000000 1 - Rh Rh28 1 0.50000000 0.50000000 0.00000000 1 - Rh Rh29 1 0.50000000 0.50000000 0.50000000 1 - Rh Rh30 1 0.00000000 0.00000000 0.50000000 1 - Rh Rh31 1 0.00000000 0.50000000 0.00000000 1 - F F32 1 0.47909800 0.38062900 0.30203900 1 - F F33 1 0.52090200 0.61937100 0.69796100 1 - F F34 1 0.57859000 0.17705900 0.19796100 1 - F F35 1 0.92141000 0.11937100 0.59846900 1 - F F36 1 0.30203900 0.47909800 0.38062900 1 - F F37 1 0.32294100 0.92141000 0.30203900 1 - F F38 1 0.42141000 0.82294100 0.80203900 1 - F F39 1 0.07859000 0.88062900 0.40153100 1 - F F40 1 0.69796100 0.52090200 0.61937100 1 - F F41 1 0.67705900 0.07859000 0.69796100 1 - F F42 1 0.02090200 0.32294100 0.90153100 1 - F F43 1 0.19796100 0.57859000 0.17705900 1 - F F44 1 0.11937100 0.02090200 0.19796100 1 - F F45 1 0.97909800 0.67705900 0.09846900 1 - F F46 1 0.80203900 0.42141000 0.82294100 1 - F F47 1 0.88062900 0.97909800 0.80203900 1 - F F48 1 0.59846900 0.92141000 0.11937100 1 - F F49 1 0.17705900 0.47909800 0.59846900 1 - F F50 1 0.40153100 0.07859000 0.88062900 1 - F F51 1 0.82294100 0.52090200 0.40153100 1 - F F52 1 0.90153100 0.02090200 0.32294100 1 - F F53 1 0.38062900 0.57859000 0.90153100 1 - F F54 1 0.09846900 0.97909800 0.67705900 1 - F F55 1 0.61937100 0.42141000 0.09846900 1 - F F56 1 0.38062900 0.30203900 0.47909800 1 - F F57 1 0.57859000 0.90153100 0.38062900 1 - F F58 1 0.61937100 0.69796100 0.52090200 1 - F F59 1 0.42141000 0.09846900 0.61937100 1 - F F60 1 0.11937100 0.59846900 0.92141000 1 - F F61 1 0.02090200 0.19796100 0.11937100 1 - F F62 1 0.88062900 0.40153100 0.07859000 1 - F F63 1 0.97909800 0.80203900 0.88062900 1 - F F64 1 0.32294100 0.90153100 0.02090200 1 - F F65 1 0.92141000 0.30203900 0.32294100 1 - F F66 1 0.67705900 0.09846900 0.97909800 1 - F F67 1 0.07859000 0.69796100 0.67705900 1 - F F68 1 0.17705900 0.19796100 0.57859000 1 - F F69 1 0.47909800 0.59846900 0.17705900 1 - F F70 1 0.82294100 0.80203900 0.42141000 1 - F F71 1 0.52090200 0.40153100 0.82294100 1 - F F72 1 0.30203900 0.32294100 0.92141000 1 - F F73 1 0.69796100 0.67705900 0.07859000 1 - F F74 1 0.19796100 0.11937100 0.02090200 1 - F F75 1 0.80203900 0.88062900 0.97909800 1 - F F76 1 0.90153100 0.38062900 0.57859000 1 - F F77 1 0.09846900 0.61937100 0.42141000 1 - F F78 1 0.59846900 0.17705900 0.47909800 1 - F F79 1 0.40153100 0.82294100 0.52090200 1 -" -Nd3Lu2(GaO4)3,mp-1210727,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Nd3Lu2Ga3O12']}","Full Formula (Nd12 Lu8 Ga12 O48) -Reduced Formula: Nd3Lu2(GaO4)3 -abc : 11.260111 11.260111 11.260111 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Nd 0.25 0.375 0.125 0 - 1 Nd 0.75 0.625 0.875 0 - 2 Nd 0.75 0.125 0.375 0 - 3 Nd 0.125 0.25 0.375 0 - 4 Nd 0.375 0.75 0.125 0 - 5 Nd 0.25 0.875 0.625 0 - 6 Nd 0.875 0.75 0.625 0 - 7 Nd 0.625 0.25 0.875 0 - 8 Nd 0.375 0.125 0.25 0 - 9 Nd 0.625 0.875 0.75 0 - 10 Nd 0.125 0.375 0.75 0 - 11 Nd 0.875 0.625 0.25 0 - 12 Lu 0 0 0 0 - 13 Lu 0.5 0 0.5 0 - 14 Lu 0 0.5 0.5 0 - 15 Lu 0.5 0 0 0 - 16 Lu 0.5 0.5 0 0 - 17 Lu 0.5 0.5 0.5 0 - 18 Lu 0 0 0.5 0 - 19 Lu 0 0.5 0 0 - 20 Ga 0.25 0.625 0.375 -0 - 21 Ga 0.75 0.375 0.625 -0 - 22 Ga 0.75 0.875 0.125 -0 - 23 Ga 0.375 0.25 0.625 -0 - 24 Ga 0.625 0.75 0.375 -0 - 25 Ga 0.25 0.125 0.875 -0 - 26 Ga 0.125 0.75 0.875 -0 - 27 Ga 0.875 0.25 0.125 -0 - 28 Ga 0.625 0.375 0.25 -0 - 29 Ga 0.375 0.625 0.75 -0 - 30 Ga 0.875 0.125 0.75 -0 - 31 Ga 0.125 0.875 0.25 -0 - 32 O 0.473133 0.373655 0.286715 -0 - 33 O 0.526867 0.626345 0.713285 -0 - 34 O 0.58694 0.186418 0.213285 -0 - 35 O 0.91306 0.126345 0.599478 -0 - 36 O 0.286715 0.473133 0.373655 -0 - 37 O 0.313582 0.91306 0.286715 -0 - 38 O 0.41306 0.813582 0.786715 -0 - 39 O 0.08694 0.873655 0.400522 -0 - 40 O 0.713285 0.526867 0.626345 -0 - 41 O 0.686418 0.08694 0.713285 -0 - 42 O 0.026867 0.313582 0.900522 -0 - 43 O 0.213285 0.58694 0.186418 -0 - 44 O 0.126345 0.026867 0.213285 -0 - 45 O 0.973133 0.686418 0.099478 -0 - 46 O 0.786715 0.41306 0.813582 -0 - 47 O 0.873655 0.973133 0.786715 -0 - 48 O 0.599478 0.91306 0.126345 -0 - 49 O 0.186418 0.473133 0.599478 -0 - 50 O 0.400522 0.08694 0.873655 -0 - 51 O 0.813582 0.526867 0.400522 -0 - 52 O 0.900522 0.026867 0.313582 -0 - 53 O 0.373655 0.58694 0.900522 -0 - 54 O 0.099478 0.973133 0.686418 -0 - 55 O 0.626345 0.41306 0.099478 -0 - 56 O 0.373655 0.286715 0.473133 -0 - 57 O 0.58694 0.900522 0.373655 -0 - 58 O 0.626345 0.713285 0.526867 -0 - 59 O 0.41306 0.099478 0.626345 -0 - 60 O 0.126345 0.599478 0.91306 -0 - 61 O 0.026867 0.213285 0.126345 -0 - 62 O 0.873655 0.400522 0.08694 -0 - 63 O 0.973133 0.786715 0.873655 -0 - 64 O 0.313582 0.900522 0.026867 -0 - 65 O 0.91306 0.286715 0.313582 -0 - 66 O 0.686418 0.099478 0.973133 -0 - 67 O 0.08694 0.713285 0.686418 -0 - 68 O 0.186418 0.213285 0.58694 -0 - 69 O 0.473133 0.599478 0.186418 -0 - 70 O 0.813582 0.786715 0.41306 -0 - 71 O 0.526867 0.400522 0.813582 -0 - 72 O 0.286715 0.313582 0.91306 -0 - 73 O 0.713285 0.686418 0.08694 -0 - 74 O 0.213285 0.126345 0.026867 -0 - 75 O 0.786715 0.873655 0.973133 -0 - 76 O 0.900522 0.373655 0.58694 -0 - 77 O 0.099478 0.626345 0.41306 -0 - 78 O 0.599478 0.186418 0.473133 -0 - 79 O 0.400522 0.813582 0.526867 -0","# generated using pymatgen -data_Nd3Lu2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.26011080 -_cell_length_b 11.26011080 -_cell_length_c 11.26011080 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Nd3Lu2(GaO4)3 -_chemical_formula_sum 'Nd12 Lu8 Ga12 O48' -_cell_volume 1099.02127843 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Nd Nd0 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd1 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd2 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd3 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd4 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd5 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd6 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd7 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd8 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd9 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd10 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd11 1 0.87500000 0.62500000 0.25000000 1 - Lu Lu12 1 0.00000000 0.00000000 0.00000000 1 - Lu Lu13 1 0.50000000 0.00000000 0.50000000 1 - Lu Lu14 1 0.00000000 0.50000000 0.50000000 1 - Lu Lu15 1 0.50000000 0.00000000 0.00000000 1 - Lu Lu16 1 0.50000000 0.50000000 0.00000000 1 - Lu Lu17 1 0.50000000 0.50000000 0.50000000 1 - Lu Lu18 1 0.00000000 0.00000000 0.50000000 1 - Lu Lu19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47313300 0.37365500 0.28671500 1 - O O33 1 0.52686700 0.62634500 0.71328500 1 - O O34 1 0.58694000 0.18641800 0.21328500 1 - O O35 1 0.91306000 0.12634500 0.59947800 1 - O O36 1 0.28671500 0.47313300 0.37365500 1 - O O37 1 0.31358200 0.91306000 0.28671500 1 - O O38 1 0.41306000 0.81358200 0.78671500 1 - O O39 1 0.08694000 0.87365500 0.40052200 1 - O O40 1 0.71328500 0.52686700 0.62634500 1 - O O41 1 0.68641800 0.08694000 0.71328500 1 - O O42 1 0.02686700 0.31358200 0.90052200 1 - O O43 1 0.21328500 0.58694000 0.18641800 1 - O O44 1 0.12634500 0.02686700 0.21328500 1 - O O45 1 0.97313300 0.68641800 0.09947800 1 - O O46 1 0.78671500 0.41306000 0.81358200 1 - O O47 1 0.87365500 0.97313300 0.78671500 1 - O O48 1 0.59947800 0.91306000 0.12634500 1 - O O49 1 0.18641800 0.47313300 0.59947800 1 - O O50 1 0.40052200 0.08694000 0.87365500 1 - O O51 1 0.81358200 0.52686700 0.40052200 1 - O O52 1 0.90052200 0.02686700 0.31358200 1 - O O53 1 0.37365500 0.58694000 0.90052200 1 - O O54 1 0.09947800 0.97313300 0.68641800 1 - O O55 1 0.62634500 0.41306000 0.09947800 1 - O O56 1 0.37365500 0.28671500 0.47313300 1 - O O57 1 0.58694000 0.90052200 0.37365500 1 - O O58 1 0.62634500 0.71328500 0.52686700 1 - O O59 1 0.41306000 0.09947800 0.62634500 1 - O O60 1 0.12634500 0.59947800 0.91306000 1 - O O61 1 0.02686700 0.21328500 0.12634500 1 - O O62 1 0.87365500 0.40052200 0.08694000 1 - O O63 1 0.97313300 0.78671500 0.87365500 1 - O O64 1 0.31358200 0.90052200 0.02686700 1 - O O65 1 0.91306000 0.28671500 0.31358200 1 - O O66 1 0.68641800 0.09947800 0.97313300 1 - O O67 1 0.08694000 0.71328500 0.68641800 1 - O O68 1 0.18641800 0.21328500 0.58694000 1 - O O69 1 0.47313300 0.59947800 0.18641800 1 - O O70 1 0.81358200 0.78671500 0.41306000 1 - O O71 1 0.52686700 0.40052200 0.81358200 1 - O O72 1 0.28671500 0.31358200 0.91306000 1 - O O73 1 0.71328500 0.68641800 0.08694000 1 - O O74 1 0.21328500 0.12634500 0.02686700 1 - O O75 1 0.78671500 0.87365500 0.97313300 1 - O O76 1 0.90052200 0.37365500 0.58694000 1 - O O77 1 0.09947800 0.62634500 0.41306000 1 - O O78 1 0.59947800 0.18641800 0.47313300 1 - O O79 1 0.40052200 0.81358200 0.52686700 1 -" -Mn2V3(AgO4)3,mp-1210930,Ia-3d,[],0.059302919812497024,{'tags': ['garnet family']},"Full Formula (Mn8 V12 Ag12 O48) -Reduced Formula: Mn2V3(AgO4)3 -abc : 10.995147 10.995147 10.995147 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0 0 0 4.099 - 1 Mn 0.5 0 0.5 4.099 - 2 Mn 0 0.5 0.5 4.099 - 3 Mn 0.5 0 0 4.1 - 4 Mn 0.5 0.5 0 4.099 - 5 Mn 0.5 0.5 0.5 4.099 - 6 Mn 0 0 0.5 4.1 - 7 Mn 0 0.5 0 4.099 - 8 V 0.25 0.625 0.375 0.199 - 9 V 0.75 0.375 0.625 0.199 - 10 V 0.75 0.875 0.125 0.2 - 11 V 0.375 0.25 0.625 0.199 - 12 V 0.625 0.75 0.375 0.199 - 13 V 0.25 0.125 0.875 0.2 - 14 V 0.125 0.75 0.875 0.199 - 15 V 0.875 0.25 0.125 0.199 - 16 V 0.625 0.375 0.25 0.199 - 17 V 0.375 0.625 0.75 0.199 - 18 V 0.875 0.125 0.75 0.199 - 19 V 0.125 0.875 0.25 0.199 - 20 Ag 0.25 0.375 0.125 -0.054 - 21 Ag 0.75 0.625 0.875 -0.054 - 22 Ag 0.75 0.125 0.375 -0.054 - 23 Ag 0.125 0.25 0.375 -0.071 - 24 Ag 0.375 0.75 0.125 -0.071 - 25 Ag 0.25 0.875 0.625 -0.054 - 26 Ag 0.875 0.75 0.625 -0.071 - 27 Ag 0.625 0.25 0.875 -0.071 - 28 Ag 0.375 0.125 0.25 -0.054 - 29 Ag 0.625 0.875 0.75 -0.054 - 30 Ag 0.125 0.375 0.75 -0.054 - 31 Ag 0.875 0.625 0.25 -0.054 - 32 O 0.492907 0.392868 0.300187 -0.081 - 33 O 0.507093 0.607132 0.699813 -0.081 - 34 O 0.592681 0.19272 0.199813 -0.081 - 35 O 0.907319 0.107132 0.600038 -0.081 - 36 O 0.300187 0.492907 0.392868 -0.048 - 37 O 0.30728 0.907319 0.300187 -0.048 - 38 O 0.407319 0.80728 0.800187 -0.081 - 39 O 0.092681 0.892868 0.399962 -0.081 - 40 O 0.699813 0.507093 0.607132 -0.048 - 41 O 0.69272 0.092681 0.699813 -0.048 - 42 O 0.007093 0.30728 0.899962 -0.081 - 43 O 0.199813 0.592681 0.19272 -0.048 - 44 O 0.107132 0.007093 0.199813 -0.048 - 45 O 0.992907 0.69272 0.100038 -0.081 - 46 O 0.800187 0.407319 0.80728 -0.048 - 47 O 0.892868 0.992907 0.800187 -0.048 - 48 O 0.600038 0.907319 0.107132 -0.048 - 49 O 0.19272 0.492907 0.600038 -0.048 - 50 O 0.399962 0.092681 0.892868 -0.048 - 51 O 0.80728 0.507093 0.399962 -0.048 - 52 O 0.899962 0.007093 0.30728 -0.048 - 53 O 0.392868 0.592681 0.899962 -0.048 - 54 O 0.100038 0.992907 0.69272 -0.048 - 55 O 0.607132 0.407319 0.100038 -0.048 - 56 O 0.392868 0.300187 0.492907 -0.068 - 57 O 0.592681 0.899962 0.392868 -0.068 - 58 O 0.607132 0.699813 0.507093 -0.068 - 59 O 0.407319 0.100038 0.607132 -0.068 - 60 O 0.107132 0.600038 0.907319 -0.068 - 61 O 0.007093 0.199813 0.107132 -0.068 - 62 O 0.892868 0.399962 0.092681 -0.068 - 63 O 0.992907 0.800187 0.892868 -0.068 - 64 O 0.30728 0.899962 0.007093 -0.068 - 65 O 0.907319 0.300187 0.30728 -0.067 - 66 O 0.69272 0.100038 0.992907 -0.068 - 67 O 0.092681 0.699813 0.69272 -0.067 - 68 O 0.19272 0.199813 0.592681 -0.067 - 69 O 0.492907 0.600038 0.19272 -0.068 - 70 O 0.80728 0.800187 0.407319 -0.067 - 71 O 0.507093 0.399962 0.80728 -0.068 - 72 O 0.300187 0.30728 0.907319 -0.081 - 73 O 0.699813 0.69272 0.092681 -0.081 - 74 O 0.199813 0.107132 0.007093 -0.081 - 75 O 0.800187 0.892868 0.992907 -0.081 - 76 O 0.899962 0.392868 0.592681 -0.081 - 77 O 0.100038 0.607132 0.407319 -0.081 - 78 O 0.600038 0.19272 0.492907 -0.081 - 79 O 0.399962 0.80728 0.507093 -0.081","# generated using pymatgen -data_Mn2V3(AgO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.99514686 -_cell_length_b 10.99514686 -_cell_length_c 10.99514686 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn2V3(AgO4)3 -_chemical_formula_sum 'Mn8 V12 Ag12 O48' -_cell_volume 1023.24872679 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn1 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn2 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn3 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn4 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn5 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn6 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn7 1 0.00000000 0.50000000 0.00000000 1 - V V8 1 0.25000000 0.62500000 0.37500000 1 - V V9 1 0.75000000 0.37500000 0.62500000 1 - V V10 1 0.75000000 0.87500000 0.12500000 1 - V V11 1 0.37500000 0.25000000 0.62500000 1 - V V12 1 0.62500000 0.75000000 0.37500000 1 - V V13 1 0.25000000 0.12500000 0.87500000 1 - V V14 1 0.12500000 0.75000000 0.87500000 1 - V V15 1 0.87500000 0.25000000 0.12500000 1 - V V16 1 0.62500000 0.37500000 0.25000000 1 - V V17 1 0.37500000 0.62500000 0.75000000 1 - V V18 1 0.87500000 0.12500000 0.75000000 1 - V V19 1 0.12500000 0.87500000 0.25000000 1 - Ag Ag20 1 0.25000000 0.37500000 0.12500000 1 - Ag Ag21 1 0.75000000 0.62500000 0.87500000 1 - Ag Ag22 1 0.75000000 0.12500000 0.37500000 1 - Ag Ag23 1 0.12500000 0.25000000 0.37500000 1 - Ag Ag24 1 0.37500000 0.75000000 0.12500000 1 - Ag Ag25 1 0.25000000 0.87500000 0.62500000 1 - Ag Ag26 1 0.87500000 0.75000000 0.62500000 1 - Ag Ag27 1 0.62500000 0.25000000 0.87500000 1 - Ag Ag28 1 0.37500000 0.12500000 0.25000000 1 - Ag Ag29 1 0.62500000 0.87500000 0.75000000 1 - Ag Ag30 1 0.12500000 0.37500000 0.75000000 1 - Ag Ag31 1 0.87500000 0.62500000 0.25000000 1 - O O32 1 0.49290700 0.39286800 0.30018700 1 - O O33 1 0.50709300 0.60713200 0.69981300 1 - O O34 1 0.59268100 0.19272000 0.19981300 1 - O O35 1 0.90731900 0.10713200 0.60003800 1 - O O36 1 0.30018700 0.49290700 0.39286800 1 - O O37 1 0.30728000 0.90731900 0.30018700 1 - O O38 1 0.40731900 0.80728000 0.80018700 1 - O O39 1 0.09268100 0.89286800 0.39996200 1 - O O40 1 0.69981300 0.50709300 0.60713200 1 - O O41 1 0.69272000 0.09268100 0.69981300 1 - O O42 1 0.00709300 0.30728000 0.89996200 1 - O O43 1 0.19981300 0.59268100 0.19272000 1 - O O44 1 0.10713200 0.00709300 0.19981300 1 - O O45 1 0.99290700 0.69272000 0.10003800 1 - O O46 1 0.80018700 0.40731900 0.80728000 1 - O O47 1 0.89286800 0.99290700 0.80018700 1 - O O48 1 0.60003800 0.90731900 0.10713200 1 - O O49 1 0.19272000 0.49290700 0.60003800 1 - O O50 1 0.39996200 0.09268100 0.89286800 1 - O O51 1 0.80728000 0.50709300 0.39996200 1 - O O52 1 0.89996200 0.00709300 0.30728000 1 - O O53 1 0.39286800 0.59268100 0.89996200 1 - O O54 1 0.10003800 0.99290700 0.69272000 1 - O O55 1 0.60713200 0.40731900 0.10003800 1 - O O56 1 0.39286800 0.30018700 0.49290700 1 - O O57 1 0.59268100 0.89996200 0.39286800 1 - O O58 1 0.60713200 0.69981300 0.50709300 1 - O O59 1 0.40731900 0.10003800 0.60713200 1 - O O60 1 0.10713200 0.60003800 0.90731900 1 - O O61 1 0.00709300 0.19981300 0.10713200 1 - O O62 1 0.89286800 0.39996200 0.09268100 1 - O O63 1 0.99290700 0.80018700 0.89286800 1 - O O64 1 0.30728000 0.89996200 0.00709300 1 - O O65 1 0.90731900 0.30018700 0.30728000 1 - O O66 1 0.69272000 0.10003800 0.99290700 1 - O O67 1 0.09268100 0.69981300 0.69272000 1 - O O68 1 0.19272000 0.19981300 0.59268100 1 - O O69 1 0.49290700 0.60003800 0.19272000 1 - O O70 1 0.80728000 0.80018700 0.40731900 1 - O O71 1 0.50709300 0.39996200 0.80728000 1 - O O72 1 0.30018700 0.30728000 0.90731900 1 - O O73 1 0.69981300 0.69272000 0.09268100 1 - O O74 1 0.19981300 0.10713200 0.00709300 1 - O O75 1 0.80018700 0.89286800 0.99290700 1 - O O76 1 0.89996200 0.39286800 0.59268100 1 - O O77 1 0.10003800 0.60713200 0.40731900 1 - O O78 1 0.60003800 0.19272000 0.49290700 1 - O O79 1 0.39996200 0.80728000 0.50709300 1 -" -Li3Dy3(TeO6)2,mp-1210935,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Dy12 Te8 O48) -Reduced Formula: Li3Dy3(TeO6)2 -abc : 10.746831 10.746831 10.746831 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Dy 0.25 0.375 0.125 -0 - 13 Dy 0.75 0.625 0.875 -0 - 14 Dy 0.75 0.125 0.375 -0 - 15 Dy 0.125 0.25 0.375 -0 - 16 Dy 0.375 0.75 0.125 -0 - 17 Dy 0.25 0.875 0.625 -0 - 18 Dy 0.875 0.75 0.625 -0 - 19 Dy 0.625 0.25 0.875 -0 - 20 Dy 0.375 0.125 0.25 -0 - 21 Dy 0.625 0.875 0.75 -0 - 22 Dy 0.125 0.375 0.75 -0 - 23 Dy 0.875 0.625 0.25 -0 - 24 Te 0 0 0 -0 - 25 Te 0.5 0 0.5 -0 - 26 Te 0 0.5 0.5 -0 - 27 Te 0.5 0 0 -0 - 28 Te 0.5 0.5 0 -0 - 29 Te 0.5 0.5 0.5 -0 - 30 Te 0 0 0.5 -0 - 31 Te 0 0.5 0 -0 - 32 O 0.472566 0.379462 0.300588 0 - 33 O 0.527434 0.620538 0.699412 0 - 34 O 0.578873 0.171977 0.199412 0 - 35 O 0.921127 0.120538 0.593104 0 - 36 O 0.300588 0.472566 0.379462 0 - 37 O 0.328023 0.921127 0.300588 0 - 38 O 0.421127 0.828023 0.800588 0 - 39 O 0.078873 0.879462 0.406896 0 - 40 O 0.699412 0.527434 0.620538 0 - 41 O 0.671977 0.078873 0.699412 0 - 42 O 0.027434 0.328023 0.906896 0 - 43 O 0.199412 0.578873 0.171977 0 - 44 O 0.120538 0.027434 0.199412 0 - 45 O 0.972566 0.671977 0.093104 0 - 46 O 0.800588 0.421127 0.828023 0 - 47 O 0.879462 0.972566 0.800588 0 - 48 O 0.593104 0.921127 0.120538 0 - 49 O 0.171977 0.472566 0.593104 0 - 50 O 0.406896 0.078873 0.879462 0 - 51 O 0.828023 0.527434 0.406896 0 - 52 O 0.906896 0.027434 0.328023 0 - 53 O 0.379462 0.578873 0.906896 0 - 54 O 0.093104 0.972566 0.671977 0 - 55 O 0.620538 0.421127 0.093104 0 - 56 O 0.379462 0.300588 0.472566 0 - 57 O 0.578873 0.906896 0.379462 0 - 58 O 0.620538 0.699412 0.527434 0 - 59 O 0.421127 0.093104 0.620538 0 - 60 O 0.120538 0.593104 0.921127 0 - 61 O 0.027434 0.199412 0.120538 0 - 62 O 0.879462 0.406896 0.078873 0 - 63 O 0.972566 0.800588 0.879462 0 - 64 O 0.328023 0.906896 0.027434 0 - 65 O 0.921127 0.300588 0.328023 0 - 66 O 0.671977 0.093104 0.972566 0 - 67 O 0.078873 0.699412 0.671977 0 - 68 O 0.171977 0.199412 0.578873 0 - 69 O 0.472566 0.593104 0.171977 0 - 70 O 0.828023 0.800588 0.421127 0 - 71 O 0.527434 0.406896 0.828023 0 - 72 O 0.300588 0.328023 0.921127 0 - 73 O 0.699412 0.671977 0.078873 0 - 74 O 0.199412 0.120538 0.027434 0 - 75 O 0.800588 0.879462 0.972566 0 - 76 O 0.906896 0.379462 0.578873 0 - 77 O 0.093104 0.620538 0.421127 0 - 78 O 0.593104 0.171977 0.472566 0 - 79 O 0.406896 0.828023 0.527434 0","# generated using pymatgen -data_Li3Dy3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.74683140 -_cell_length_b 10.74683140 -_cell_length_c 10.74683140 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Dy3(TeO6)2 -_chemical_formula_sum 'Li12 Dy12 Te8 O48' -_cell_volume 955.47519221 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Dy Dy12 1 0.25000000 0.37500000 0.12500000 1 - Dy Dy13 1 0.75000000 0.62500000 0.87500000 1 - Dy Dy14 1 0.75000000 0.12500000 0.37500000 1 - Dy Dy15 1 0.12500000 0.25000000 0.37500000 1 - Dy Dy16 1 0.37500000 0.75000000 0.12500000 1 - Dy Dy17 1 0.25000000 0.87500000 0.62500000 1 - Dy Dy18 1 0.87500000 0.75000000 0.62500000 1 - Dy Dy19 1 0.62500000 0.25000000 0.87500000 1 - Dy Dy20 1 0.37500000 0.12500000 0.25000000 1 - Dy Dy21 1 0.62500000 0.87500000 0.75000000 1 - Dy Dy22 1 0.12500000 0.37500000 0.75000000 1 - Dy Dy23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47256600 0.37946200 0.30058800 1 - O O33 1 0.52743400 0.62053800 0.69941200 1 - O O34 1 0.57887300 0.17197700 0.19941200 1 - O O35 1 0.92112700 0.12053800 0.59310400 1 - O O36 1 0.30058800 0.47256600 0.37946200 1 - O O37 1 0.32802300 0.92112700 0.30058800 1 - O O38 1 0.42112700 0.82802300 0.80058800 1 - O O39 1 0.07887300 0.87946200 0.40689600 1 - O O40 1 0.69941200 0.52743400 0.62053800 1 - O O41 1 0.67197700 0.07887300 0.69941200 1 - O O42 1 0.02743400 0.32802300 0.90689600 1 - O O43 1 0.19941200 0.57887300 0.17197700 1 - O O44 1 0.12053800 0.02743400 0.19941200 1 - O O45 1 0.97256600 0.67197700 0.09310400 1 - O O46 1 0.80058800 0.42112700 0.82802300 1 - O O47 1 0.87946200 0.97256600 0.80058800 1 - O O48 1 0.59310400 0.92112700 0.12053800 1 - O O49 1 0.17197700 0.47256600 0.59310400 1 - O O50 1 0.40689600 0.07887300 0.87946200 1 - O O51 1 0.82802300 0.52743400 0.40689600 1 - O O52 1 0.90689600 0.02743400 0.32802300 1 - O O53 1 0.37946200 0.57887300 0.90689600 1 - O O54 1 0.09310400 0.97256600 0.67197700 1 - O O55 1 0.62053800 0.42112700 0.09310400 1 - O O56 1 0.37946200 0.30058800 0.47256600 1 - O O57 1 0.57887300 0.90689600 0.37946200 1 - O O58 1 0.62053800 0.69941200 0.52743400 1 - O O59 1 0.42112700 0.09310400 0.62053800 1 - O O60 1 0.12053800 0.59310400 0.92112700 1 - O O61 1 0.02743400 0.19941200 0.12053800 1 - O O62 1 0.87946200 0.40689600 0.07887300 1 - O O63 1 0.97256600 0.80058800 0.87946200 1 - O O64 1 0.32802300 0.90689600 0.02743400 1 - O O65 1 0.92112700 0.30058800 0.32802300 1 - O O66 1 0.67197700 0.09310400 0.97256600 1 - O O67 1 0.07887300 0.69941200 0.67197700 1 - O O68 1 0.17197700 0.19941200 0.57887300 1 - O O69 1 0.47256600 0.59310400 0.17197700 1 - O O70 1 0.82802300 0.80058800 0.42112700 1 - O O71 1 0.52743400 0.40689600 0.82802300 1 - O O72 1 0.30058800 0.32802300 0.92112700 1 - O O73 1 0.69941200 0.67197700 0.07887300 1 - O O74 1 0.19941200 0.12053800 0.02743400 1 - O O75 1 0.80058800 0.87946200 0.97256600 1 - O O76 1 0.90689600 0.37946200 0.57887300 1 - O O77 1 0.09310400 0.62053800 0.42112700 1 - O O78 1 0.59310400 0.17197700 0.47256600 1 - O O79 1 0.40689600 0.82802300 0.52743400 1 -" -Li3Er3(TeO6)2,mp-1210989,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Er12 Te8 O48) -Reduced Formula: Li3Er3(TeO6)2 -abc : 10.700542 10.700542 10.700542 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Er 0.25 0.375 0.125 -0.001 - 13 Er 0.75 0.625 0.875 -0.001 - 14 Er 0.75 0.125 0.375 -0.001 - 15 Er 0.125 0.25 0.375 -0.001 - 16 Er 0.375 0.75 0.125 -0.001 - 17 Er 0.25 0.875 0.625 -0.001 - 18 Er 0.875 0.75 0.625 -0.001 - 19 Er 0.625 0.25 0.875 -0.001 - 20 Er 0.375 0.125 0.25 -0.001 - 21 Er 0.625 0.875 0.75 -0.001 - 22 Er 0.125 0.375 0.75 -0.001 - 23 Er 0.875 0.625 0.25 -0.001 - 24 Te 0 0 0 -0 - 25 Te 0.5 0 0.5 -0 - 26 Te 0 0.5 0.5 -0 - 27 Te 0.5 0 0 -0 - 28 Te 0.5 0.5 0 -0 - 29 Te 0.5 0.5 0.5 -0 - 30 Te 0 0 0.5 -0 - 31 Te 0 0.5 0 -0 - 32 O 0.472346 0.379352 0.299929 0.001 - 33 O 0.527654 0.620648 0.700071 0.001 - 34 O 0.579423 0.172417 0.200071 0.001 - 35 O 0.920577 0.120648 0.592994 0.001 - 36 O 0.299929 0.472346 0.379352 0.001 - 37 O 0.327583 0.920577 0.299929 0.001 - 38 O 0.420577 0.827583 0.799929 0.001 - 39 O 0.079423 0.879352 0.407005 0.001 - 40 O 0.700071 0.527654 0.620648 0.001 - 41 O 0.672417 0.079423 0.700071 0.001 - 42 O 0.027654 0.327583 0.907006 0.001 - 43 O 0.200071 0.579423 0.172417 0.001 - 44 O 0.120648 0.027654 0.200071 0.001 - 45 O 0.972346 0.672417 0.092995 0.001 - 46 O 0.799929 0.420577 0.827583 0.001 - 47 O 0.879352 0.972346 0.799929 0.001 - 48 O 0.592994 0.920577 0.120648 0.001 - 49 O 0.172417 0.472346 0.592995 0.001 - 50 O 0.407005 0.079423 0.879352 0.001 - 51 O 0.827583 0.527654 0.407006 0.001 - 52 O 0.907005 0.027654 0.327583 0.001 - 53 O 0.379352 0.579423 0.907006 0.001 - 54 O 0.092994 0.972346 0.672417 0.001 - 55 O 0.620648 0.420577 0.092995 0.001 - 56 O 0.379352 0.299929 0.472346 0.001 - 57 O 0.579423 0.907006 0.379352 0.001 - 58 O 0.620648 0.700071 0.527654 0.001 - 59 O 0.420577 0.092994 0.620648 0.001 - 60 O 0.120648 0.592994 0.920577 0.001 - 61 O 0.027654 0.200071 0.120648 0.001 - 62 O 0.879352 0.407005 0.079423 0.001 - 63 O 0.972346 0.799929 0.879352 0.001 - 64 O 0.327583 0.907005 0.027654 0.001 - 65 O 0.920577 0.299929 0.327583 0.001 - 66 O 0.672417 0.092994 0.972346 0.001 - 67 O 0.079423 0.700071 0.672417 0.001 - 68 O 0.172417 0.200071 0.579423 0.001 - 69 O 0.472346 0.592994 0.172417 0.001 - 70 O 0.827583 0.799929 0.420577 0.001 - 71 O 0.527654 0.407005 0.827583 0.001 - 72 O 0.299929 0.327583 0.920577 0.001 - 73 O 0.700071 0.672417 0.079423 0.001 - 74 O 0.200071 0.120648 0.027654 0.001 - 75 O 0.799929 0.879352 0.972346 0.001 - 76 O 0.907005 0.379352 0.579423 0.001 - 77 O 0.092994 0.620648 0.420577 0.001 - 78 O 0.592995 0.172417 0.472346 0.001 - 79 O 0.407005 0.827583 0.527654 0.001","# generated using pymatgen -data_Li3Er3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.70054234 -_cell_length_b 10.70054234 -_cell_length_c 10.70054234 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Er3(TeO6)2 -_chemical_formula_sum 'Li12 Er12 Te8 O48' -_cell_volume 943.18194464 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Er Er12 1 0.25000000 0.37500000 0.12500000 1 - Er Er13 1 0.75000000 0.62500000 0.87500000 1 - Er Er14 1 0.75000000 0.12500000 0.37500000 1 - Er Er15 1 0.12500000 0.25000000 0.37500000 1 - Er Er16 1 0.37500000 0.75000000 0.12500000 1 - Er Er17 1 0.25000000 0.87500000 0.62500000 1 - Er Er18 1 0.87500000 0.75000000 0.62500000 1 - Er Er19 1 0.62500000 0.25000000 0.87500000 1 - Er Er20 1 0.37500000 0.12500000 0.25000000 1 - Er Er21 1 0.62500000 0.87500000 0.75000000 1 - Er Er22 1 0.12500000 0.37500000 0.75000000 1 - Er Er23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47234600 0.37935200 0.29992900 1 - O O33 1 0.52765400 0.62064800 0.70007100 1 - O O34 1 0.57942300 0.17241700 0.20007100 1 - O O35 1 0.92057700 0.12064800 0.59299400 1 - O O36 1 0.29992900 0.47234600 0.37935200 1 - O O37 1 0.32758300 0.92057700 0.29992900 1 - O O38 1 0.42057700 0.82758300 0.79992900 1 - O O39 1 0.07942300 0.87935200 0.40700500 1 - O O40 1 0.70007100 0.52765400 0.62064800 1 - O O41 1 0.67241700 0.07942300 0.70007100 1 - O O42 1 0.02765400 0.32758300 0.90700600 1 - O O43 1 0.20007100 0.57942300 0.17241700 1 - O O44 1 0.12064800 0.02765400 0.20007100 1 - O O45 1 0.97234600 0.67241700 0.09299500 1 - O O46 1 0.79992900 0.42057700 0.82758300 1 - O O47 1 0.87935200 0.97234600 0.79992900 1 - O O48 1 0.59299400 0.92057700 0.12064800 1 - O O49 1 0.17241700 0.47234600 0.59299500 1 - O O50 1 0.40700500 0.07942300 0.87935200 1 - O O51 1 0.82758300 0.52765400 0.40700600 1 - O O52 1 0.90700500 0.02765400 0.32758300 1 - O O53 1 0.37935200 0.57942300 0.90700600 1 - O O54 1 0.09299400 0.97234600 0.67241700 1 - O O55 1 0.62064800 0.42057700 0.09299500 1 - O O56 1 0.37935200 0.29992900 0.47234600 1 - O O57 1 0.57942300 0.90700600 0.37935200 1 - O O58 1 0.62064800 0.70007100 0.52765400 1 - O O59 1 0.42057700 0.09299400 0.62064800 1 - O O60 1 0.12064800 0.59299400 0.92057700 1 - O O61 1 0.02765400 0.20007100 0.12064800 1 - O O62 1 0.87935200 0.40700500 0.07942300 1 - O O63 1 0.97234600 0.79992900 0.87935200 1 - O O64 1 0.32758300 0.90700500 0.02765400 1 - O O65 1 0.92057700 0.29992900 0.32758300 1 - O O66 1 0.67241700 0.09299400 0.97234600 1 - O O67 1 0.07942300 0.70007100 0.67241700 1 - O O68 1 0.17241700 0.20007100 0.57942300 1 - O O69 1 0.47234600 0.59299400 0.17241700 1 - O O70 1 0.82758300 0.79992900 0.42057700 1 - O O71 1 0.52765400 0.40700500 0.82758300 1 - O O72 1 0.29992900 0.32758300 0.92057700 1 - O O73 1 0.70007100 0.67241700 0.07942300 1 - O O74 1 0.20007100 0.12064800 0.02765400 1 - O O75 1 0.79992900 0.87935200 0.97234600 1 - O O76 1 0.90700500 0.37935200 0.57942300 1 - O O77 1 0.09299400 0.62064800 0.42057700 1 - O O78 1 0.59299500 0.17241700 0.47234600 1 - O O79 1 0.40700500 0.82758300 0.52765400 1 -" -Lu3Mg2(SiO4)3,mp-1211091,Ia-3d,[],0.07317645071876022,{'tags': ['garnet family']},"Full Formula (Lu12 Mg8 Si12 O48) -Reduced Formula: Lu3Mg2(SiO4)3 -abc : 10.443021 10.443021 10.443021 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Lu 0.25 0.375 0.125 0.147 - 1 Lu 0.75 0.625 0.875 0.147 - 2 Lu 0.75 0.125 0.375 0.147 - 3 Lu 0.125 0.25 0.375 0.147 - 4 Lu 0.375 0.75 0.125 0.147 - 5 Lu 0.25 0.875 0.625 0.147 - 6 Lu 0.875 0.75 0.625 0.147 - 7 Lu 0.625 0.25 0.875 0.147 - 8 Lu 0.375 0.125 0.25 0.147 - 9 Lu 0.625 0.875 0.75 0.147 - 10 Lu 0.125 0.375 0.75 0.147 - 11 Lu 0.875 0.625 0.25 0.147 - 12 Mg 0 0 0 -0 - 13 Mg 0.5 0 0.5 -0 - 14 Mg 0 0.5 0.5 -0 - 15 Mg 0.5 0 0 -0 - 16 Mg 0.5 0.5 0 -0 - 17 Mg 0.5 0.5 0.5 -0 - 18 Mg 0 0 0.5 -0 - 19 Mg 0 0.5 0 -0 - 20 Si 0.25 0.625 0.375 0.008 - 21 Si 0.75 0.375 0.625 0.008 - 22 Si 0.75 0.875 0.125 0.008 - 23 Si 0.375 0.25 0.625 0.008 - 24 Si 0.625 0.75 0.375 0.008 - 25 Si 0.25 0.125 0.875 0.008 - 26 Si 0.125 0.75 0.875 0.008 - 27 Si 0.875 0.25 0.125 0.008 - 28 Si 0.625 0.375 0.25 0.008 - 29 Si 0.375 0.625 0.75 0.008 - 30 Si 0.875 0.125 0.75 0.008 - 31 Si 0.125 0.875 0.25 0.008 - 32 O 0.482914 0.378184 0.286446 0.003 - 33 O 0.517086 0.621816 0.713554 0.003 - 34 O 0.591738 0.196468 0.213554 0.003 - 35 O 0.908262 0.121816 0.60473 0.003 - 36 O 0.286446 0.482914 0.378184 0.003 - 37 O 0.303532 0.908262 0.286446 0.003 - 38 O 0.408262 0.803532 0.786446 0.003 - 39 O 0.091738 0.878184 0.39527 0.003 - 40 O 0.713554 0.517086 0.621816 0.003 - 41 O 0.696468 0.091738 0.713554 0.003 - 42 O 0.017086 0.303532 0.89527 0.003 - 43 O 0.213554 0.591738 0.196468 0.003 - 44 O 0.121816 0.017086 0.213554 0.003 - 45 O 0.982914 0.696468 0.10473 0.003 - 46 O 0.786446 0.408262 0.803532 0.003 - 47 O 0.878184 0.982914 0.786446 0.003 - 48 O 0.60473 0.908262 0.121816 0.003 - 49 O 0.196468 0.482914 0.60473 0.003 - 50 O 0.39527 0.091738 0.878184 0.003 - 51 O 0.803532 0.517086 0.39527 0.003 - 52 O 0.89527 0.017086 0.303532 0.003 - 53 O 0.378184 0.591738 0.89527 0.003 - 54 O 0.10473 0.982914 0.696468 0.003 - 55 O 0.621816 0.408262 0.10473 0.003 - 56 O 0.378184 0.286446 0.482914 0.003 - 57 O 0.591738 0.89527 0.378184 0.003 - 58 O 0.621816 0.713554 0.517086 0.003 - 59 O 0.408262 0.10473 0.621816 0.003 - 60 O 0.121816 0.60473 0.908262 0.003 - 61 O 0.017086 0.213554 0.121816 0.003 - 62 O 0.878184 0.39527 0.091738 0.003 - 63 O 0.982914 0.786446 0.878184 0.003 - 64 O 0.303532 0.89527 0.017086 0.003 - 65 O 0.908262 0.286446 0.303532 0.003 - 66 O 0.696468 0.10473 0.982914 0.003 - 67 O 0.091738 0.713554 0.696468 0.003 - 68 O 0.196468 0.213554 0.591738 0.003 - 69 O 0.482914 0.60473 0.196468 0.003 - 70 O 0.803532 0.786446 0.408262 0.003 - 71 O 0.517086 0.39527 0.803532 0.003 - 72 O 0.286446 0.303532 0.908262 0.003 - 73 O 0.713554 0.696468 0.091738 0.003 - 74 O 0.213554 0.121816 0.017086 0.003 - 75 O 0.786446 0.878184 0.982914 0.003 - 76 O 0.89527 0.378184 0.591738 0.003 - 77 O 0.10473 0.621816 0.408262 0.003 - 78 O 0.60473 0.196468 0.482914 0.003 - 79 O 0.39527 0.803532 0.517086 0.003","# generated using pymatgen -data_Lu3Mg2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.44302103 -_cell_length_b 10.44302103 -_cell_length_c 10.44302103 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Lu3Mg2(SiO4)3 -_chemical_formula_sum 'Lu12 Mg8 Si12 O48' -_cell_volume 876.71122356 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Lu Lu0 1 0.25000000 0.37500000 0.12500000 1 - Lu Lu1 1 0.75000000 0.62500000 0.87500000 1 - Lu Lu2 1 0.75000000 0.12500000 0.37500000 1 - Lu Lu3 1 0.12500000 0.25000000 0.37500000 1 - Lu Lu4 1 0.37500000 0.75000000 0.12500000 1 - Lu Lu5 1 0.25000000 0.87500000 0.62500000 1 - Lu Lu6 1 0.87500000 0.75000000 0.62500000 1 - Lu Lu7 1 0.62500000 0.25000000 0.87500000 1 - Lu Lu8 1 0.37500000 0.12500000 0.25000000 1 - Lu Lu9 1 0.62500000 0.87500000 0.75000000 1 - Lu Lu10 1 0.12500000 0.37500000 0.75000000 1 - Lu Lu11 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg12 1 0.00000000 0.00000000 0.00000000 1 - Mg Mg13 1 0.50000000 0.00000000 0.50000000 1 - Mg Mg14 1 0.00000000 0.50000000 0.50000000 1 - Mg Mg15 1 0.50000000 0.00000000 0.00000000 1 - Mg Mg16 1 0.50000000 0.50000000 0.00000000 1 - Mg Mg17 1 0.50000000 0.50000000 0.50000000 1 - Mg Mg18 1 0.00000000 0.00000000 0.50000000 1 - Mg Mg19 1 0.00000000 0.50000000 0.00000000 1 - Si Si20 1 0.25000000 0.62500000 0.37500000 1 - Si Si21 1 0.75000000 0.37500000 0.62500000 1 - Si Si22 1 0.75000000 0.87500000 0.12500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.25000000 0.12500000 0.87500000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.87500000 0.25000000 0.12500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.37500000 0.62500000 0.75000000 1 - Si Si30 1 0.87500000 0.12500000 0.75000000 1 - Si Si31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48291400 0.37818400 0.28644600 1 - O O33 1 0.51708600 0.62181600 0.71355400 1 - O O34 1 0.59173800 0.19646800 0.21355400 1 - O O35 1 0.90826200 0.12181600 0.60473000 1 - O O36 1 0.28644600 0.48291400 0.37818400 1 - O O37 1 0.30353200 0.90826200 0.28644600 1 - O O38 1 0.40826200 0.80353200 0.78644600 1 - O O39 1 0.09173800 0.87818400 0.39527000 1 - O O40 1 0.71355400 0.51708600 0.62181600 1 - O O41 1 0.69646800 0.09173800 0.71355400 1 - O O42 1 0.01708600 0.30353200 0.89527000 1 - O O43 1 0.21355400 0.59173800 0.19646800 1 - O O44 1 0.12181600 0.01708600 0.21355400 1 - O O45 1 0.98291400 0.69646800 0.10473000 1 - O O46 1 0.78644600 0.40826200 0.80353200 1 - O O47 1 0.87818400 0.98291400 0.78644600 1 - O O48 1 0.60473000 0.90826200 0.12181600 1 - O O49 1 0.19646800 0.48291400 0.60473000 1 - O O50 1 0.39527000 0.09173800 0.87818400 1 - O O51 1 0.80353200 0.51708600 0.39527000 1 - O O52 1 0.89527000 0.01708600 0.30353200 1 - O O53 1 0.37818400 0.59173800 0.89527000 1 - O O54 1 0.10473000 0.98291400 0.69646800 1 - O O55 1 0.62181600 0.40826200 0.10473000 1 - O O56 1 0.37818400 0.28644600 0.48291400 1 - O O57 1 0.59173800 0.89527000 0.37818400 1 - O O58 1 0.62181600 0.71355400 0.51708600 1 - O O59 1 0.40826200 0.10473000 0.62181600 1 - O O60 1 0.12181600 0.60473000 0.90826200 1 - O O61 1 0.01708600 0.21355400 0.12181600 1 - O O62 1 0.87818400 0.39527000 0.09173800 1 - O O63 1 0.98291400 0.78644600 0.87818400 1 - O O64 1 0.30353200 0.89527000 0.01708600 1 - O O65 1 0.90826200 0.28644600 0.30353200 1 - O O66 1 0.69646800 0.10473000 0.98291400 1 - O O67 1 0.09173800 0.71355400 0.69646800 1 - O O68 1 0.19646800 0.21355400 0.59173800 1 - O O69 1 0.48291400 0.60473000 0.19646800 1 - O O70 1 0.80353200 0.78644600 0.40826200 1 - O O71 1 0.51708600 0.39527000 0.80353200 1 - O O72 1 0.28644600 0.30353200 0.90826200 1 - O O73 1 0.71355400 0.69646800 0.09173800 1 - O O74 1 0.21355400 0.12181600 0.01708600 1 - O O75 1 0.78644600 0.87818400 0.98291400 1 - O O76 1 0.89527000 0.37818400 0.59173800 1 - O O77 1 0.10473000 0.62181600 0.40826200 1 - O O78 1 0.60473000 0.19646800 0.48291400 1 - O O79 1 0.39527000 0.80353200 0.51708600 1 -" -Li3Eu3(TeO6)2,mp-1211152,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Eu12 Te8 O48) -Reduced Formula: Li3Eu3(TeO6)2 -abc : 11.019477 11.019477 11.019477 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Eu 0.25 0.375 0.125 6.237 - 13 Eu 0.75 0.625 0.875 6.237 - 14 Eu 0.75 0.125 0.375 6.235 - 15 Eu 0.125 0.25 0.375 6.241 - 16 Eu 0.375 0.75 0.125 6.241 - 17 Eu 0.25 0.875 0.625 6.235 - 18 Eu 0.875 0.75 0.625 6.241 - 19 Eu 0.625 0.25 0.875 6.241 - 20 Eu 0.375 0.125 0.25 6.241 - 21 Eu 0.625 0.875 0.75 6.241 - 22 Eu 0.125 0.375 0.75 6.241 - 23 Eu 0.875 0.625 0.25 6.241 - 24 Te 0 0 0 0.009 - 25 Te 0.5 0 0.5 0.01 - 26 Te 0 0.5 0.5 0.01 - 27 Te 0.5 0 0 0.01 - 28 Te 0.5 0.5 0 0.009 - 29 Te 0.5 0.5 0.5 0.009 - 30 Te 0 0 0.5 0.01 - 31 Te 0 0.5 0 0.009 - 32 O 0.47613 0.384177 0.305153 -0.067 - 33 O 0.52387 0.615823 0.694847 -0.067 - 34 O 0.579024 0.170977 0.194847 -0.067 - 35 O 0.920976 0.115823 0.591953 -0.067 - 36 O 0.305153 0.47613 0.384177 -0.075 - 37 O 0.329023 0.920976 0.305153 -0.066 - 38 O 0.420976 0.829023 0.805153 -0.067 - 39 O 0.079024 0.884177 0.408047 -0.067 - 40 O 0.694847 0.52387 0.615823 -0.075 - 41 O 0.670977 0.079024 0.694847 -0.066 - 42 O 0.02387 0.329023 0.908047 -0.067 - 43 O 0.194847 0.579024 0.170977 -0.075 - 44 O 0.115823 0.02387 0.194847 -0.07 - 45 O 0.97613 0.670977 0.091953 -0.067 - 46 O 0.805153 0.420976 0.829023 -0.075 - 47 O 0.884177 0.97613 0.805153 -0.07 - 48 O 0.591953 0.920976 0.115823 -0.068 - 49 O 0.170977 0.47613 0.591953 -0.066 - 50 O 0.408047 0.079024 0.884177 -0.068 - 51 O 0.829023 0.52387 0.408047 -0.066 - 52 O 0.908047 0.02387 0.329023 -0.068 - 53 O 0.384177 0.579024 0.908047 -0.07 - 54 O 0.091953 0.97613 0.670977 -0.068 - 55 O 0.615823 0.420976 0.091953 -0.07 - 56 O 0.384177 0.305153 0.47613 -0.07 - 57 O 0.579024 0.908047 0.384177 -0.067 - 58 O 0.615823 0.694847 0.52387 -0.07 - 59 O 0.420976 0.091953 0.615823 -0.067 - 60 O 0.115823 0.591953 0.920976 -0.07 - 61 O 0.02387 0.194847 0.115823 -0.067 - 62 O 0.884177 0.408047 0.079024 -0.07 - 63 O 0.97613 0.805153 0.884177 -0.067 - 64 O 0.329023 0.908047 0.02387 -0.066 - 65 O 0.920976 0.305153 0.329023 -0.067 - 66 O 0.670977 0.091953 0.97613 -0.066 - 67 O 0.079024 0.694847 0.670977 -0.067 - 68 O 0.170977 0.194847 0.579024 -0.066 - 69 O 0.47613 0.591953 0.170977 -0.067 - 70 O 0.829023 0.805153 0.420976 -0.066 - 71 O 0.52387 0.408047 0.829023 -0.067 - 72 O 0.305153 0.329023 0.920976 -0.075 - 73 O 0.694847 0.670977 0.079024 -0.075 - 74 O 0.194847 0.115823 0.02387 -0.075 - 75 O 0.805153 0.884177 0.97613 -0.075 - 76 O 0.908047 0.384177 0.579024 -0.068 - 77 O 0.091953 0.615823 0.420976 -0.068 - 78 O 0.591953 0.170977 0.47613 -0.068 - 79 O 0.408047 0.829023 0.52387 -0.068","# generated using pymatgen -data_Li3Eu3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.01947698 -_cell_length_b 11.01947698 -_cell_length_c 11.01947698 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Eu3(TeO6)2 -_chemical_formula_sum 'Li12 Eu12 Te8 O48' -_cell_volume 1030.05651910 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Eu Eu12 1 0.25000000 0.37500000 0.12500000 1 - Eu Eu13 1 0.75000000 0.62500000 0.87500000 1 - Eu Eu14 1 0.75000000 0.12500000 0.37500000 1 - Eu Eu15 1 0.12500000 0.25000000 0.37500000 1 - Eu Eu16 1 0.37500000 0.75000000 0.12500000 1 - Eu Eu17 1 0.25000000 0.87500000 0.62500000 1 - Eu Eu18 1 0.87500000 0.75000000 0.62500000 1 - Eu Eu19 1 0.62500000 0.25000000 0.87500000 1 - Eu Eu20 1 0.37500000 0.12500000 0.25000000 1 - Eu Eu21 1 0.62500000 0.87500000 0.75000000 1 - Eu Eu22 1 0.12500000 0.37500000 0.75000000 1 - Eu Eu23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47613000 0.38417700 0.30515300 1 - O O33 1 0.52387000 0.61582300 0.69484700 1 - O O34 1 0.57902400 0.17097700 0.19484700 1 - O O35 1 0.92097600 0.11582300 0.59195300 1 - O O36 1 0.30515300 0.47613000 0.38417700 1 - O O37 1 0.32902300 0.92097600 0.30515300 1 - O O38 1 0.42097600 0.82902300 0.80515300 1 - O O39 1 0.07902400 0.88417700 0.40804700 1 - O O40 1 0.69484700 0.52387000 0.61582300 1 - O O41 1 0.67097700 0.07902400 0.69484700 1 - O O42 1 0.02387000 0.32902300 0.90804700 1 - O O43 1 0.19484700 0.57902400 0.17097700 1 - O O44 1 0.11582300 0.02387000 0.19484700 1 - O O45 1 0.97613000 0.67097700 0.09195300 1 - O O46 1 0.80515300 0.42097600 0.82902300 1 - O O47 1 0.88417700 0.97613000 0.80515300 1 - O O48 1 0.59195300 0.92097600 0.11582300 1 - O O49 1 0.17097700 0.47613000 0.59195300 1 - O O50 1 0.40804700 0.07902400 0.88417700 1 - O O51 1 0.82902300 0.52387000 0.40804700 1 - O O52 1 0.90804700 0.02387000 0.32902300 1 - O O53 1 0.38417700 0.57902400 0.90804700 1 - O O54 1 0.09195300 0.97613000 0.67097700 1 - O O55 1 0.61582300 0.42097600 0.09195300 1 - O O56 1 0.38417700 0.30515300 0.47613000 1 - O O57 1 0.57902400 0.90804700 0.38417700 1 - O O58 1 0.61582300 0.69484700 0.52387000 1 - O O59 1 0.42097600 0.09195300 0.61582300 1 - O O60 1 0.11582300 0.59195300 0.92097600 1 - O O61 1 0.02387000 0.19484700 0.11582300 1 - O O62 1 0.88417700 0.40804700 0.07902400 1 - O O63 1 0.97613000 0.80515300 0.88417700 1 - O O64 1 0.32902300 0.90804700 0.02387000 1 - O O65 1 0.92097600 0.30515300 0.32902300 1 - O O66 1 0.67097700 0.09195300 0.97613000 1 - O O67 1 0.07902400 0.69484700 0.67097700 1 - O O68 1 0.17097700 0.19484700 0.57902400 1 - O O69 1 0.47613000 0.59195300 0.17097700 1 - O O70 1 0.82902300 0.80515300 0.42097600 1 - O O71 1 0.52387000 0.40804700 0.82902300 1 - O O72 1 0.30515300 0.32902300 0.92097600 1 - O O73 1 0.69484700 0.67097700 0.07902400 1 - O O74 1 0.19484700 0.11582300 0.02387000 1 - O O75 1 0.80515300 0.88417700 0.97613000 1 - O O76 1 0.90804700 0.38417700 0.57902400 1 - O O77 1 0.09195300 0.61582300 0.42097600 1 - O O78 1 0.59195300 0.17097700 0.47613000 1 - O O79 1 0.40804700 0.82902300 0.52387000 1 -" -Li3Tb3(TeO6)2,mp-1211213,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Tb12 Te8 O48) -Reduced Formula: Li3Tb3(TeO6)2 -abc : 10.784942 10.784942 10.784942 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Tb 0.25 0.375 0.125 -0 - 13 Tb 0.75 0.625 0.875 -0 - 14 Tb 0.75 0.125 0.375 -0 - 15 Tb 0.125 0.25 0.375 -0 - 16 Tb 0.375 0.75 0.125 -0 - 17 Tb 0.25 0.875 0.625 -0 - 18 Tb 0.875 0.75 0.625 -0 - 19 Tb 0.625 0.25 0.875 -0 - 20 Tb 0.375 0.125 0.25 -0 - 21 Tb 0.625 0.875 0.75 -0 - 22 Tb 0.125 0.375 0.75 -0 - 23 Tb 0.875 0.625 0.25 -0 - 24 Te 0 0 0 -0 - 25 Te 0.5 0 0.5 -0 - 26 Te 0 0.5 0.5 -0 - 27 Te 0.5 0 0 -0 - 28 Te 0.5 0.5 0 -0 - 29 Te 0.5 0.5 0.5 -0 - 30 Te 0 0 0.5 -0 - 31 Te 0 0.5 0 -0 - 32 O 0.472944 0.379783 0.301269 0 - 33 O 0.527056 0.620217 0.698731 0 - 34 O 0.578515 0.171676 0.198731 0 - 35 O 0.921485 0.120217 0.593161 0 - 36 O 0.301269 0.472944 0.379783 0 - 37 O 0.328324 0.921485 0.301269 0 - 38 O 0.421485 0.828324 0.801269 0 - 39 O 0.078515 0.879783 0.406839 0 - 40 O 0.698731 0.527056 0.620217 0 - 41 O 0.671676 0.078515 0.698731 0 - 42 O 0.027056 0.328324 0.906839 0 - 43 O 0.198731 0.578515 0.171676 0 - 44 O 0.120217 0.027056 0.198731 0 - 45 O 0.972944 0.671676 0.093161 0 - 46 O 0.801269 0.421485 0.828324 0 - 47 O 0.879783 0.972944 0.801269 0 - 48 O 0.593161 0.921485 0.120217 0 - 49 O 0.171676 0.472944 0.593161 0 - 50 O 0.406839 0.078515 0.879783 0 - 51 O 0.828324 0.527056 0.406839 0 - 52 O 0.906839 0.027056 0.328324 0 - 53 O 0.379783 0.578515 0.906839 0 - 54 O 0.093161 0.972944 0.671676 0 - 55 O 0.620217 0.421485 0.093161 0 - 56 O 0.379783 0.301269 0.472944 0 - 57 O 0.578515 0.906839 0.379783 0 - 58 O 0.620217 0.698731 0.527056 0 - 59 O 0.421485 0.093161 0.620217 0 - 60 O 0.120217 0.593161 0.921485 0 - 61 O 0.027056 0.198731 0.120217 0 - 62 O 0.879783 0.406839 0.078515 0 - 63 O 0.972944 0.801269 0.879783 0 - 64 O 0.328324 0.906839 0.027056 0 - 65 O 0.921485 0.301269 0.328324 0 - 66 O 0.671676 0.093161 0.972944 0 - 67 O 0.078515 0.698731 0.671676 0 - 68 O 0.171676 0.198731 0.578515 0 - 69 O 0.472944 0.593161 0.171676 0 - 70 O 0.828324 0.801269 0.421485 0 - 71 O 0.527056 0.406839 0.828324 0 - 72 O 0.301269 0.328324 0.921485 0 - 73 O 0.698731 0.671676 0.078515 0 - 74 O 0.198731 0.120217 0.027056 0 - 75 O 0.801269 0.879783 0.972944 0 - 76 O 0.906839 0.379783 0.578515 0 - 77 O 0.093161 0.620217 0.421485 0 - 78 O 0.593161 0.171676 0.472944 0 - 79 O 0.406839 0.828324 0.527056 0","# generated using pymatgen -data_Li3Tb3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.78494171 -_cell_length_b 10.78494171 -_cell_length_c 10.78494171 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Tb3(TeO6)2 -_chemical_formula_sum 'Li12 Tb12 Te8 O48' -_cell_volume 965.67617329 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Tb Tb12 1 0.25000000 0.37500000 0.12500000 1 - Tb Tb13 1 0.75000000 0.62500000 0.87500000 1 - Tb Tb14 1 0.75000000 0.12500000 0.37500000 1 - Tb Tb15 1 0.12500000 0.25000000 0.37500000 1 - Tb Tb16 1 0.37500000 0.75000000 0.12500000 1 - Tb Tb17 1 0.25000000 0.87500000 0.62500000 1 - Tb Tb18 1 0.87500000 0.75000000 0.62500000 1 - Tb Tb19 1 0.62500000 0.25000000 0.87500000 1 - Tb Tb20 1 0.37500000 0.12500000 0.25000000 1 - Tb Tb21 1 0.62500000 0.87500000 0.75000000 1 - Tb Tb22 1 0.12500000 0.37500000 0.75000000 1 - Tb Tb23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47294400 0.37978300 0.30126900 1 - O O33 1 0.52705600 0.62021700 0.69873100 1 - O O34 1 0.57851500 0.17167600 0.19873100 1 - O O35 1 0.92148500 0.12021700 0.59316100 1 - O O36 1 0.30126900 0.47294400 0.37978300 1 - O O37 1 0.32832400 0.92148500 0.30126900 1 - O O38 1 0.42148500 0.82832400 0.80126900 1 - O O39 1 0.07851500 0.87978300 0.40683900 1 - O O40 1 0.69873100 0.52705600 0.62021700 1 - O O41 1 0.67167600 0.07851500 0.69873100 1 - O O42 1 0.02705600 0.32832400 0.90683900 1 - O O43 1 0.19873100 0.57851500 0.17167600 1 - O O44 1 0.12021700 0.02705600 0.19873100 1 - O O45 1 0.97294400 0.67167600 0.09316100 1 - O O46 1 0.80126900 0.42148500 0.82832400 1 - O O47 1 0.87978300 0.97294400 0.80126900 1 - O O48 1 0.59316100 0.92148500 0.12021700 1 - O O49 1 0.17167600 0.47294400 0.59316100 1 - O O50 1 0.40683900 0.07851500 0.87978300 1 - O O51 1 0.82832400 0.52705600 0.40683900 1 - O O52 1 0.90683900 0.02705600 0.32832400 1 - O O53 1 0.37978300 0.57851500 0.90683900 1 - O O54 1 0.09316100 0.97294400 0.67167600 1 - O O55 1 0.62021700 0.42148500 0.09316100 1 - O O56 1 0.37978300 0.30126900 0.47294400 1 - O O57 1 0.57851500 0.90683900 0.37978300 1 - O O58 1 0.62021700 0.69873100 0.52705600 1 - O O59 1 0.42148500 0.09316100 0.62021700 1 - O O60 1 0.12021700 0.59316100 0.92148500 1 - O O61 1 0.02705600 0.19873100 0.12021700 1 - O O62 1 0.87978300 0.40683900 0.07851500 1 - O O63 1 0.97294400 0.80126900 0.87978300 1 - O O64 1 0.32832400 0.90683900 0.02705600 1 - O O65 1 0.92148500 0.30126900 0.32832400 1 - O O66 1 0.67167600 0.09316100 0.97294400 1 - O O67 1 0.07851500 0.69873100 0.67167600 1 - O O68 1 0.17167600 0.19873100 0.57851500 1 - O O69 1 0.47294400 0.59316100 0.17167600 1 - O O70 1 0.82832400 0.80126900 0.42148500 1 - O O71 1 0.52705600 0.40683900 0.82832400 1 - O O72 1 0.30126900 0.32832400 0.92148500 1 - O O73 1 0.69873100 0.67167600 0.07851500 1 - O O74 1 0.19873100 0.12021700 0.02705600 1 - O O75 1 0.80126900 0.87978300 0.97294400 1 - O O76 1 0.90683900 0.37978300 0.57851500 1 - O O77 1 0.09316100 0.62021700 0.42148500 1 - O O78 1 0.59316100 0.17167600 0.47294400 1 - O O79 1 0.40683900 0.82832400 0.52705600 1 -" -Li3Yb3(TeO6)2,mp-1211223,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Yb12 Te8 O48) -Reduced Formula: Li3Yb3(TeO6)2 -abc : 10.830581 10.830581 10.830581 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 0.001 - 1 Li 0.75 0.375 0.625 0.001 - 2 Li 0.75 0.875 0.125 0.001 - 3 Li 0.375 0.25 0.625 0.002 - 4 Li 0.625 0.75 0.375 0.002 - 5 Li 0.25 0.125 0.875 0.001 - 6 Li 0.125 0.75 0.875 0.002 - 7 Li 0.875 0.25 0.125 0.002 - 8 Li 0.625 0.375 0.25 0.002 - 9 Li 0.375 0.625 0.75 0.002 - 10 Li 0.875 0.125 0.75 0.002 - 11 Li 0.125 0.875 0.25 0.002 - 12 Yb 0.25 0.375 0.125 0.013 - 13 Yb 0.75 0.625 0.875 0.013 - 14 Yb 0.75 0.125 0.375 0.001 - 15 Yb 0.125 0.25 0.375 0.004 - 16 Yb 0.375 0.75 0.125 0.004 - 17 Yb 0.25 0.875 0.625 0.001 - 18 Yb 0.875 0.75 0.625 0.004 - 19 Yb 0.625 0.25 0.875 0.004 - 20 Yb 0.375 0.125 0.25 0.004 - 21 Yb 0.625 0.875 0.75 0.004 - 22 Yb 0.125 0.375 0.75 0.004 - 23 Yb 0.875 0.625 0.25 0.004 - 24 Te 0 0 0 -0.027 - 25 Te 0.5 0 0.5 -0.027 - 26 Te 0 0.5 0.5 -0.027 - 27 Te 0.5 0 0 -0.027 - 28 Te 0.5 0.5 0 -0.027 - 29 Te 0.5 0.5 0.5 -0.027 - 30 Te 0 0 0.5 -0.027 - 31 Te 0 0.5 0 -0.027 - 32 O 0.474064 0.383927 0.303343 0.199 - 33 O 0.525936 0.616073 0.696657 0.199 - 34 O 0.580584 0.170721 0.196657 0.224 - 35 O 0.919416 0.116073 0.590137 0.224 - 36 O 0.303343 0.474064 0.383927 0.21 - 37 O 0.329279 0.919416 0.303343 0.232 - 38 O 0.419416 0.829279 0.803343 0.224 - 39 O 0.080584 0.883927 0.409863 0.224 - 40 O 0.696657 0.525936 0.616073 0.21 - 41 O 0.670721 0.080584 0.696657 0.232 - 42 O 0.025936 0.329279 0.909863 0.199 - 43 O 0.196657 0.580584 0.170721 0.21 - 44 O 0.116073 0.025936 0.196657 0.193 - 45 O 0.974064 0.670721 0.090137 0.199 - 46 O 0.803343 0.419416 0.829279 0.21 - 47 O 0.883927 0.974064 0.803343 0.193 - 48 O 0.590137 0.919416 0.116073 0.209 - 49 O 0.170721 0.474064 0.590137 0.232 - 50 O 0.409863 0.080584 0.883927 0.209 - 51 O 0.829279 0.525936 0.409863 0.232 - 52 O 0.909863 0.025936 0.329279 0.209 - 53 O 0.383927 0.580584 0.909863 0.193 - 54 O 0.090137 0.974064 0.670721 0.209 - 55 O 0.616073 0.419416 0.090137 0.193 - 56 O 0.383927 0.303343 0.474064 0.193 - 57 O 0.580584 0.909863 0.383927 0.224 - 58 O 0.616073 0.696657 0.525936 0.193 - 59 O 0.419416 0.090137 0.616073 0.224 - 60 O 0.116073 0.590137 0.919416 0.193 - 61 O 0.025936 0.196657 0.116073 0.199 - 62 O 0.883927 0.409863 0.080584 0.193 - 63 O 0.974064 0.803343 0.883927 0.199 - 64 O 0.329279 0.909863 0.025936 0.232 - 65 O 0.919416 0.303343 0.329279 0.224 - 66 O 0.670721 0.090137 0.974064 0.232 - 67 O 0.080584 0.696657 0.670721 0.224 - 68 O 0.170721 0.196657 0.580584 0.232 - 69 O 0.474064 0.590137 0.170721 0.199 - 70 O 0.829279 0.803343 0.419416 0.232 - 71 O 0.525936 0.409863 0.829279 0.199 - 72 O 0.303343 0.329279 0.919416 0.21 - 73 O 0.696657 0.670721 0.080584 0.21 - 74 O 0.196657 0.116073 0.025936 0.21 - 75 O 0.803343 0.883927 0.974064 0.21 - 76 O 0.909863 0.383927 0.580584 0.209 - 77 O 0.090137 0.616073 0.419416 0.209 - 78 O 0.590137 0.170721 0.474064 0.209 - 79 O 0.409863 0.829279 0.525936 0.209","# generated using pymatgen -data_Li3Yb3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.83058125 -_cell_length_b 10.83058125 -_cell_length_c 10.83058125 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Yb3(TeO6)2 -_chemical_formula_sum 'Li12 Yb12 Te8 O48' -_cell_volume 977.98772403 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Yb Yb12 1 0.25000000 0.37500000 0.12500000 1 - Yb Yb13 1 0.75000000 0.62500000 0.87500000 1 - Yb Yb14 1 0.75000000 0.12500000 0.37500000 1 - Yb Yb15 1 0.12500000 0.25000000 0.37500000 1 - Yb Yb16 1 0.37500000 0.75000000 0.12500000 1 - Yb Yb17 1 0.25000000 0.87500000 0.62500000 1 - Yb Yb18 1 0.87500000 0.75000000 0.62500000 1 - Yb Yb19 1 0.62500000 0.25000000 0.87500000 1 - Yb Yb20 1 0.37500000 0.12500000 0.25000000 1 - Yb Yb21 1 0.62500000 0.87500000 0.75000000 1 - Yb Yb22 1 0.12500000 0.37500000 0.75000000 1 - Yb Yb23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47406400 0.38392700 0.30334300 1 - O O33 1 0.52593600 0.61607300 0.69665700 1 - O O34 1 0.58058400 0.17072100 0.19665700 1 - O O35 1 0.91941600 0.11607300 0.59013700 1 - O O36 1 0.30334300 0.47406400 0.38392700 1 - O O37 1 0.32927900 0.91941600 0.30334300 1 - O O38 1 0.41941600 0.82927900 0.80334300 1 - O O39 1 0.08058400 0.88392700 0.40986300 1 - O O40 1 0.69665700 0.52593600 0.61607300 1 - O O41 1 0.67072100 0.08058400 0.69665700 1 - O O42 1 0.02593600 0.32927900 0.90986300 1 - O O43 1 0.19665700 0.58058400 0.17072100 1 - O O44 1 0.11607300 0.02593600 0.19665700 1 - O O45 1 0.97406400 0.67072100 0.09013700 1 - O O46 1 0.80334300 0.41941600 0.82927900 1 - O O47 1 0.88392700 0.97406400 0.80334300 1 - O O48 1 0.59013700 0.91941600 0.11607300 1 - O O49 1 0.17072100 0.47406400 0.59013700 1 - O O50 1 0.40986300 0.08058400 0.88392700 1 - O O51 1 0.82927900 0.52593600 0.40986300 1 - O O52 1 0.90986300 0.02593600 0.32927900 1 - O O53 1 0.38392700 0.58058400 0.90986300 1 - O O54 1 0.09013700 0.97406400 0.67072100 1 - O O55 1 0.61607300 0.41941600 0.09013700 1 - O O56 1 0.38392700 0.30334300 0.47406400 1 - O O57 1 0.58058400 0.90986300 0.38392700 1 - O O58 1 0.61607300 0.69665700 0.52593600 1 - O O59 1 0.41941600 0.09013700 0.61607300 1 - O O60 1 0.11607300 0.59013700 0.91941600 1 - O O61 1 0.02593600 0.19665700 0.11607300 1 - O O62 1 0.88392700 0.40986300 0.08058400 1 - O O63 1 0.97406400 0.80334300 0.88392700 1 - O O64 1 0.32927900 0.90986300 0.02593600 1 - O O65 1 0.91941600 0.30334300 0.32927900 1 - O O66 1 0.67072100 0.09013700 0.97406400 1 - O O67 1 0.08058400 0.69665700 0.67072100 1 - O O68 1 0.17072100 0.19665700 0.58058400 1 - O O69 1 0.47406400 0.59013700 0.17072100 1 - O O70 1 0.82927900 0.80334300 0.41941600 1 - O O71 1 0.52593600 0.40986300 0.82927900 1 - O O72 1 0.30334300 0.32927900 0.91941600 1 - O O73 1 0.69665700 0.67072100 0.08058400 1 - O O74 1 0.19665700 0.11607300 0.02593600 1 - O O75 1 0.80334300 0.88392700 0.97406400 1 - O O76 1 0.90986300 0.38392700 0.58058400 1 - O O77 1 0.09013700 0.61607300 0.41941600 1 - O O78 1 0.59013700 0.17072100 0.47406400 1 - O O79 1 0.40986300 0.82927900 0.52593600 1 -" -Li3Y3(TeO6)2,mp-1211226,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Y12 Te8 O48) -Reduced Formula: Li3Y3(TeO6)2 -abc : 10.765761 10.765761 10.765761 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 0 - 1 Li 0.75 0.375 0.625 0 - 2 Li 0.75 0.875 0.125 0 - 3 Li 0.375 0.25 0.625 0 - 4 Li 0.625 0.75 0.375 0 - 5 Li 0.25 0.125 0.875 0 - 6 Li 0.125 0.75 0.875 0 - 7 Li 0.875 0.25 0.125 0 - 8 Li 0.625 0.375 0.25 0 - 9 Li 0.375 0.625 0.75 0 - 10 Li 0.875 0.125 0.75 0 - 11 Li 0.125 0.875 0.25 0 - 12 Y 0.25 0.375 0.125 0 - 13 Y 0.75 0.625 0.875 0 - 14 Y 0.75 0.125 0.375 0 - 15 Y 0.125 0.25 0.375 0 - 16 Y 0.375 0.75 0.125 0 - 17 Y 0.25 0.875 0.625 0 - 18 Y 0.875 0.75 0.625 0 - 19 Y 0.625 0.25 0.875 0 - 20 Y 0.375 0.125 0.25 0 - 21 Y 0.625 0.875 0.75 0 - 22 Y 0.125 0.375 0.75 0 - 23 Y 0.875 0.625 0.25 0 - 24 Te 0 0 0 0 - 25 Te 0.5 0 0.5 0 - 26 Te 0 0.5 0.5 0 - 27 Te 0.5 0 0 0 - 28 Te 0.5 0.5 0 0 - 29 Te 0.5 0.5 0.5 0 - 30 Te 0 0 0.5 0 - 31 Te 0 0.5 0 0 - 32 O 0.472773 0.379958 0.301075 -0 - 33 O 0.527227 0.620042 0.698925 -0 - 34 O 0.578883 0.171698 0.198925 -0 - 35 O 0.921117 0.120042 0.592815 -0 - 36 O 0.301075 0.472773 0.379958 -0 - 37 O 0.328302 0.921117 0.301075 -0 - 38 O 0.421117 0.828302 0.801075 -0 - 39 O 0.078883 0.879958 0.407185 -0 - 40 O 0.698925 0.527227 0.620042 -0 - 41 O 0.671698 0.078883 0.698925 -0 - 42 O 0.027227 0.328302 0.907185 -0 - 43 O 0.198925 0.578883 0.171698 -0 - 44 O 0.120042 0.027227 0.198925 -0 - 45 O 0.972773 0.671698 0.092815 -0 - 46 O 0.801075 0.421117 0.828302 -0 - 47 O 0.879958 0.972773 0.801075 -0 - 48 O 0.592815 0.921117 0.120042 -0 - 49 O 0.171698 0.472773 0.592815 -0 - 50 O 0.407185 0.078883 0.879958 -0 - 51 O 0.828302 0.527227 0.407185 -0 - 52 O 0.907185 0.027227 0.328302 -0 - 53 O 0.379958 0.578883 0.907185 -0 - 54 O 0.092815 0.972773 0.671698 -0 - 55 O 0.620042 0.421117 0.092815 -0 - 56 O 0.379958 0.301075 0.472773 -0 - 57 O 0.578883 0.907185 0.379958 -0 - 58 O 0.620042 0.698925 0.527227 -0 - 59 O 0.421117 0.092815 0.620042 -0 - 60 O 0.120042 0.592815 0.921117 -0 - 61 O 0.027227 0.198925 0.120042 -0 - 62 O 0.879958 0.407185 0.078883 -0 - 63 O 0.972773 0.801075 0.879958 -0 - 64 O 0.328302 0.907185 0.027227 -0 - 65 O 0.921117 0.301075 0.328302 -0 - 66 O 0.671698 0.092815 0.972773 -0 - 67 O 0.078883 0.698925 0.671698 -0 - 68 O 0.171698 0.198925 0.578883 -0 - 69 O 0.472773 0.592815 0.171698 -0 - 70 O 0.828302 0.801075 0.421117 -0 - 71 O 0.527227 0.407185 0.828302 -0 - 72 O 0.301075 0.328302 0.921117 -0 - 73 O 0.698925 0.671698 0.078883 -0 - 74 O 0.198925 0.120042 0.027227 -0 - 75 O 0.801075 0.879958 0.972773 -0 - 76 O 0.907185 0.379958 0.578883 -0 - 77 O 0.092815 0.620042 0.421117 -0 - 78 O 0.592815 0.171698 0.472773 -0 - 79 O 0.407185 0.828302 0.527227 -0","# generated using pymatgen -data_Li3Y3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.76576098 -_cell_length_b 10.76576098 -_cell_length_c 10.76576098 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Y3(TeO6)2 -_chemical_formula_sum 'Li12 Y12 Te8 O48' -_cell_volume 960.53304325 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Y Y12 1 0.25000000 0.37500000 0.12500000 1 - Y Y13 1 0.75000000 0.62500000 0.87500000 1 - Y Y14 1 0.75000000 0.12500000 0.37500000 1 - Y Y15 1 0.12500000 0.25000000 0.37500000 1 - Y Y16 1 0.37500000 0.75000000 0.12500000 1 - Y Y17 1 0.25000000 0.87500000 0.62500000 1 - Y Y18 1 0.87500000 0.75000000 0.62500000 1 - Y Y19 1 0.62500000 0.25000000 0.87500000 1 - Y Y20 1 0.37500000 0.12500000 0.25000000 1 - Y Y21 1 0.62500000 0.87500000 0.75000000 1 - Y Y22 1 0.12500000 0.37500000 0.75000000 1 - Y Y23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47277300 0.37995800 0.30107500 1 - O O33 1 0.52722700 0.62004200 0.69892500 1 - O O34 1 0.57888300 0.17169800 0.19892500 1 - O O35 1 0.92111700 0.12004200 0.59281500 1 - O O36 1 0.30107500 0.47277300 0.37995800 1 - O O37 1 0.32830200 0.92111700 0.30107500 1 - O O38 1 0.42111700 0.82830200 0.80107500 1 - O O39 1 0.07888300 0.87995800 0.40718500 1 - O O40 1 0.69892500 0.52722700 0.62004200 1 - O O41 1 0.67169800 0.07888300 0.69892500 1 - O O42 1 0.02722700 0.32830200 0.90718500 1 - O O43 1 0.19892500 0.57888300 0.17169800 1 - O O44 1 0.12004200 0.02722700 0.19892500 1 - O O45 1 0.97277300 0.67169800 0.09281500 1 - O O46 1 0.80107500 0.42111700 0.82830200 1 - O O47 1 0.87995800 0.97277300 0.80107500 1 - O O48 1 0.59281500 0.92111700 0.12004200 1 - O O49 1 0.17169800 0.47277300 0.59281500 1 - O O50 1 0.40718500 0.07888300 0.87995800 1 - O O51 1 0.82830200 0.52722700 0.40718500 1 - O O52 1 0.90718500 0.02722700 0.32830200 1 - O O53 1 0.37995800 0.57888300 0.90718500 1 - O O54 1 0.09281500 0.97277300 0.67169800 1 - O O55 1 0.62004200 0.42111700 0.09281500 1 - O O56 1 0.37995800 0.30107500 0.47277300 1 - O O57 1 0.57888300 0.90718500 0.37995800 1 - O O58 1 0.62004200 0.69892500 0.52722700 1 - O O59 1 0.42111700 0.09281500 0.62004200 1 - O O60 1 0.12004200 0.59281500 0.92111700 1 - O O61 1 0.02722700 0.19892500 0.12004200 1 - O O62 1 0.87995800 0.40718500 0.07888300 1 - O O63 1 0.97277300 0.80107500 0.87995800 1 - O O64 1 0.32830200 0.90718500 0.02722700 1 - O O65 1 0.92111700 0.30107500 0.32830200 1 - O O66 1 0.67169800 0.09281500 0.97277300 1 - O O67 1 0.07888300 0.69892500 0.67169800 1 - O O68 1 0.17169800 0.19892500 0.57888300 1 - O O69 1 0.47277300 0.59281500 0.17169800 1 - O O70 1 0.82830200 0.80107500 0.42111700 1 - O O71 1 0.52722700 0.40718500 0.82830200 1 - O O72 1 0.30107500 0.32830200 0.92111700 1 - O O73 1 0.69892500 0.67169800 0.07888300 1 - O O74 1 0.19892500 0.12004200 0.02722700 1 - O O75 1 0.80107500 0.87995800 0.97277300 1 - O O76 1 0.90718500 0.37995800 0.57888300 1 - O O77 1 0.09281500 0.62004200 0.42111700 1 - O O78 1 0.59281500 0.17169800 0.47277300 1 - O O79 1 0.40718500 0.82830200 0.52722700 1 -" -Li3Tm3(TeO6)2,mp-1211248,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Tm12 Te8 O48) -Reduced Formula: Li3Tm3(TeO6)2 -abc : 10.659247 10.659247 10.659247 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Tm 0.25 0.375 0.125 -0.001 - 13 Tm 0.75 0.625 0.875 -0.001 - 14 Tm 0.75 0.125 0.375 -0.001 - 15 Tm 0.125 0.25 0.375 -0.001 - 16 Tm 0.375 0.75 0.125 -0.001 - 17 Tm 0.25 0.875 0.625 -0.001 - 18 Tm 0.875 0.75 0.625 -0.001 - 19 Tm 0.625 0.25 0.875 -0.001 - 20 Tm 0.375 0.125 0.25 -0.001 - 21 Tm 0.625 0.875 0.75 -0.001 - 22 Tm 0.125 0.375 0.75 -0.001 - 23 Tm 0.875 0.625 0.25 -0.001 - 24 Te 0 0 0 -0 - 25 Te 0.5 0 0.5 -0 - 26 Te 0 0.5 0.5 -0 - 27 Te 0.5 0 0 -0 - 28 Te 0.5 0.5 0 -0 - 29 Te 0.5 0.5 0.5 -0 - 30 Te 0 0 0.5 -0 - 31 Te 0 0.5 0 -0 - 32 O 0.471049 0.377219 0.299016 0 - 33 O 0.528951 0.622781 0.700984 0 - 34 O 0.578203 0.172033 0.200984 0 - 35 O 0.921797 0.122781 0.59383 0 - 36 O 0.299016 0.471049 0.377219 0 - 37 O 0.327967 0.921797 0.299016 0 - 38 O 0.421797 0.827967 0.799016 0 - 39 O 0.078203 0.877219 0.40617 0 - 40 O 0.700984 0.528951 0.622781 0 - 41 O 0.672033 0.078203 0.700984 0 - 42 O 0.028951 0.327967 0.90617 0 - 43 O 0.200984 0.578203 0.172033 0 - 44 O 0.122781 0.028951 0.200984 0 - 45 O 0.971049 0.672033 0.09383 0 - 46 O 0.799016 0.421797 0.827967 0 - 47 O 0.877219 0.971049 0.799016 0 - 48 O 0.59383 0.921797 0.122781 0 - 49 O 0.172033 0.471049 0.59383 0 - 50 O 0.40617 0.078203 0.877219 0 - 51 O 0.827967 0.528951 0.40617 0 - 52 O 0.90617 0.028951 0.327967 0 - 53 O 0.377219 0.578203 0.90617 0.001 - 54 O 0.09383 0.971049 0.672033 0 - 55 O 0.622781 0.421797 0.09383 0.001 - 56 O 0.377219 0.299016 0.471049 0.001 - 57 O 0.578203 0.90617 0.377219 0 - 58 O 0.622781 0.700984 0.528951 0.001 - 59 O 0.421797 0.09383 0.622781 0 - 60 O 0.122781 0.59383 0.921797 0.001 - 61 O 0.028951 0.200984 0.122781 0 - 62 O 0.877219 0.40617 0.078203 0.001 - 63 O 0.971049 0.799016 0.877219 0 - 64 O 0.327967 0.90617 0.028951 0 - 65 O 0.921797 0.299016 0.327967 0 - 66 O 0.672033 0.09383 0.971049 0 - 67 O 0.078203 0.700984 0.672033 0 - 68 O 0.172033 0.200984 0.578203 0 - 69 O 0.471049 0.59383 0.172033 0 - 70 O 0.827967 0.799016 0.421797 0 - 71 O 0.528951 0.40617 0.827967 0 - 72 O 0.299016 0.327967 0.921797 0 - 73 O 0.700984 0.672033 0.078203 0 - 74 O 0.200984 0.122781 0.028951 0 - 75 O 0.799016 0.877219 0.971049 0 - 76 O 0.90617 0.377219 0.578203 0 - 77 O 0.09383 0.622781 0.421797 0 - 78 O 0.59383 0.172033 0.471049 0 - 79 O 0.40617 0.827967 0.528951 0","# generated using pymatgen -data_Li3Tm3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.65924678 -_cell_length_b 10.65924678 -_cell_length_c 10.65924678 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Tm3(TeO6)2 -_chemical_formula_sum 'Li12 Tm12 Te8 O48' -_cell_volume 932.30424291 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Tm Tm12 1 0.25000000 0.37500000 0.12500000 1 - Tm Tm13 1 0.75000000 0.62500000 0.87500000 1 - Tm Tm14 1 0.75000000 0.12500000 0.37500000 1 - Tm Tm15 1 0.12500000 0.25000000 0.37500000 1 - Tm Tm16 1 0.37500000 0.75000000 0.12500000 1 - Tm Tm17 1 0.25000000 0.87500000 0.62500000 1 - Tm Tm18 1 0.87500000 0.75000000 0.62500000 1 - Tm Tm19 1 0.62500000 0.25000000 0.87500000 1 - Tm Tm20 1 0.37500000 0.12500000 0.25000000 1 - Tm Tm21 1 0.62500000 0.87500000 0.75000000 1 - Tm Tm22 1 0.12500000 0.37500000 0.75000000 1 - Tm Tm23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47104900 0.37721900 0.29901600 1 - O O33 1 0.52895100 0.62278100 0.70098400 1 - O O34 1 0.57820300 0.17203300 0.20098400 1 - O O35 1 0.92179700 0.12278100 0.59383000 1 - O O36 1 0.29901600 0.47104900 0.37721900 1 - O O37 1 0.32796700 0.92179700 0.29901600 1 - O O38 1 0.42179700 0.82796700 0.79901600 1 - O O39 1 0.07820300 0.87721900 0.40617000 1 - O O40 1 0.70098400 0.52895100 0.62278100 1 - O O41 1 0.67203300 0.07820300 0.70098400 1 - O O42 1 0.02895100 0.32796700 0.90617000 1 - O O43 1 0.20098400 0.57820300 0.17203300 1 - O O44 1 0.12278100 0.02895100 0.20098400 1 - O O45 1 0.97104900 0.67203300 0.09383000 1 - O O46 1 0.79901600 0.42179700 0.82796700 1 - O O47 1 0.87721900 0.97104900 0.79901600 1 - O O48 1 0.59383000 0.92179700 0.12278100 1 - O O49 1 0.17203300 0.47104900 0.59383000 1 - O O50 1 0.40617000 0.07820300 0.87721900 1 - O O51 1 0.82796700 0.52895100 0.40617000 1 - O O52 1 0.90617000 0.02895100 0.32796700 1 - O O53 1 0.37721900 0.57820300 0.90617000 1 - O O54 1 0.09383000 0.97104900 0.67203300 1 - O O55 1 0.62278100 0.42179700 0.09383000 1 - O O56 1 0.37721900 0.29901600 0.47104900 1 - O O57 1 0.57820300 0.90617000 0.37721900 1 - O O58 1 0.62278100 0.70098400 0.52895100 1 - O O59 1 0.42179700 0.09383000 0.62278100 1 - O O60 1 0.12278100 0.59383000 0.92179700 1 - O O61 1 0.02895100 0.20098400 0.12278100 1 - O O62 1 0.87721900 0.40617000 0.07820300 1 - O O63 1 0.97104900 0.79901600 0.87721900 1 - O O64 1 0.32796700 0.90617000 0.02895100 1 - O O65 1 0.92179700 0.29901600 0.32796700 1 - O O66 1 0.67203300 0.09383000 0.97104900 1 - O O67 1 0.07820300 0.70098400 0.67203300 1 - O O68 1 0.17203300 0.20098400 0.57820300 1 - O O69 1 0.47104900 0.59383000 0.17203300 1 - O O70 1 0.82796700 0.79901600 0.42179700 1 - O O71 1 0.52895100 0.40617000 0.82796700 1 - O O72 1 0.29901600 0.32796700 0.92179700 1 - O O73 1 0.70098400 0.67203300 0.07820300 1 - O O74 1 0.20098400 0.12278100 0.02895100 1 - O O75 1 0.79901600 0.87721900 0.97104900 1 - O O76 1 0.90617000 0.37721900 0.57820300 1 - O O77 1 0.09383000 0.62278100 0.42179700 1 - O O78 1 0.59383000 0.17203300 0.47104900 1 - O O79 1 0.40617000 0.82796700 0.52895100 1 -" -Li3Sm3(TeO6)2,mp-1211256,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Sm12 Te8 O48) -Reduced Formula: Li3Sm3(TeO6)2 -abc : 10.914657 10.914657 10.914657 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Sm 0.25 0.375 0.125 -0 - 13 Sm 0.75 0.625 0.875 -0 - 14 Sm 0.75 0.125 0.375 -0 - 15 Sm 0.125 0.25 0.375 -0 - 16 Sm 0.375 0.75 0.125 -0 - 17 Sm 0.25 0.875 0.625 -0 - 18 Sm 0.875 0.75 0.625 -0 - 19 Sm 0.625 0.25 0.875 -0 - 20 Sm 0.375 0.125 0.25 -0 - 21 Sm 0.625 0.875 0.75 -0 - 22 Sm 0.125 0.375 0.75 -0 - 23 Sm 0.875 0.625 0.25 -0 - 24 Te 0 0 0 -0 - 25 Te 0.5 0 0.5 -0 - 26 Te 0 0.5 0.5 -0 - 27 Te 0.5 0 0 -0 - 28 Te 0.5 0.5 0 -0 - 29 Te 0.5 0.5 0.5 -0 - 30 Te 0 0 0.5 -0 - 31 Te 0 0.5 0 -0 - 32 O 0.475382 0.382135 0.304172 0 - 33 O 0.524618 0.617865 0.695828 0 - 34 O 0.577962 0.17121 0.195828 0 - 35 O 0.922038 0.117865 0.593247 0 - 36 O 0.304172 0.475382 0.382135 0 - 37 O 0.32879 0.922038 0.304172 0 - 38 O 0.422038 0.82879 0.804172 0 - 39 O 0.077962 0.882135 0.406753 0 - 40 O 0.695828 0.524618 0.617865 0 - 41 O 0.67121 0.077962 0.695828 0 - 42 O 0.024618 0.32879 0.906753 0 - 43 O 0.195828 0.577962 0.17121 0 - 44 O 0.117865 0.024618 0.195828 0 - 45 O 0.975382 0.67121 0.093247 0 - 46 O 0.804172 0.422038 0.82879 0 - 47 O 0.882135 0.975382 0.804172 0 - 48 O 0.593247 0.922038 0.117865 0 - 49 O 0.17121 0.475382 0.593247 0 - 50 O 0.406753 0.077962 0.882135 0 - 51 O 0.82879 0.524618 0.406753 0 - 52 O 0.906753 0.024618 0.32879 0 - 53 O 0.382135 0.577962 0.906753 0 - 54 O 0.093247 0.975382 0.67121 0 - 55 O 0.617865 0.422038 0.093247 0 - 56 O 0.382135 0.304172 0.475382 0 - 57 O 0.577962 0.906753 0.382135 0 - 58 O 0.617865 0.695828 0.524618 0 - 59 O 0.422038 0.093247 0.617865 0 - 60 O 0.117865 0.593247 0.922038 0 - 61 O 0.024618 0.195828 0.117865 0 - 62 O 0.882135 0.406753 0.077962 0 - 63 O 0.975382 0.804172 0.882135 0 - 64 O 0.32879 0.906753 0.024618 0 - 65 O 0.922038 0.304172 0.32879 0 - 66 O 0.67121 0.093247 0.975382 0 - 67 O 0.077962 0.695828 0.67121 0 - 68 O 0.17121 0.195828 0.577962 0 - 69 O 0.475382 0.593247 0.17121 0 - 70 O 0.82879 0.804172 0.422038 0 - 71 O 0.524618 0.406753 0.82879 0 - 72 O 0.304172 0.32879 0.922038 0 - 73 O 0.695828 0.67121 0.077962 0 - 74 O 0.195828 0.117865 0.024618 0 - 75 O 0.804172 0.882135 0.975382 0 - 76 O 0.906753 0.382135 0.577962 0 - 77 O 0.093247 0.617865 0.422038 0 - 78 O 0.593247 0.17121 0.475382 0 - 79 O 0.406753 0.82879 0.524618 0","# generated using pymatgen -data_Li3Sm3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.91465673 -_cell_length_b 10.91465673 -_cell_length_c 10.91465673 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Sm3(TeO6)2 -_chemical_formula_sum 'Li12 Sm12 Te8 O48' -_cell_volume 1000.94071114 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Sm Sm12 1 0.25000000 0.37500000 0.12500000 1 - Sm Sm13 1 0.75000000 0.62500000 0.87500000 1 - Sm Sm14 1 0.75000000 0.12500000 0.37500000 1 - Sm Sm15 1 0.12500000 0.25000000 0.37500000 1 - Sm Sm16 1 0.37500000 0.75000000 0.12500000 1 - Sm Sm17 1 0.25000000 0.87500000 0.62500000 1 - Sm Sm18 1 0.87500000 0.75000000 0.62500000 1 - Sm Sm19 1 0.62500000 0.25000000 0.87500000 1 - Sm Sm20 1 0.37500000 0.12500000 0.25000000 1 - Sm Sm21 1 0.62500000 0.87500000 0.75000000 1 - Sm Sm22 1 0.12500000 0.37500000 0.75000000 1 - Sm Sm23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47538200 0.38213500 0.30417200 1 - O O33 1 0.52461800 0.61786500 0.69582800 1 - O O34 1 0.57796200 0.17121000 0.19582800 1 - O O35 1 0.92203800 0.11786500 0.59324700 1 - O O36 1 0.30417200 0.47538200 0.38213500 1 - O O37 1 0.32879000 0.92203800 0.30417200 1 - O O38 1 0.42203800 0.82879000 0.80417200 1 - O O39 1 0.07796200 0.88213500 0.40675300 1 - O O40 1 0.69582800 0.52461800 0.61786500 1 - O O41 1 0.67121000 0.07796200 0.69582800 1 - O O42 1 0.02461800 0.32879000 0.90675300 1 - O O43 1 0.19582800 0.57796200 0.17121000 1 - O O44 1 0.11786500 0.02461800 0.19582800 1 - O O45 1 0.97538200 0.67121000 0.09324700 1 - O O46 1 0.80417200 0.42203800 0.82879000 1 - O O47 1 0.88213500 0.97538200 0.80417200 1 - O O48 1 0.59324700 0.92203800 0.11786500 1 - O O49 1 0.17121000 0.47538200 0.59324700 1 - O O50 1 0.40675300 0.07796200 0.88213500 1 - O O51 1 0.82879000 0.52461800 0.40675300 1 - O O52 1 0.90675300 0.02461800 0.32879000 1 - O O53 1 0.38213500 0.57796200 0.90675300 1 - O O54 1 0.09324700 0.97538200 0.67121000 1 - O O55 1 0.61786500 0.42203800 0.09324700 1 - O O56 1 0.38213500 0.30417200 0.47538200 1 - O O57 1 0.57796200 0.90675300 0.38213500 1 - O O58 1 0.61786500 0.69582800 0.52461800 1 - O O59 1 0.42203800 0.09324700 0.61786500 1 - O O60 1 0.11786500 0.59324700 0.92203800 1 - O O61 1 0.02461800 0.19582800 0.11786500 1 - O O62 1 0.88213500 0.40675300 0.07796200 1 - O O63 1 0.97538200 0.80417200 0.88213500 1 - O O64 1 0.32879000 0.90675300 0.02461800 1 - O O65 1 0.92203800 0.30417200 0.32879000 1 - O O66 1 0.67121000 0.09324700 0.97538200 1 - O O67 1 0.07796200 0.69582800 0.67121000 1 - O O68 1 0.17121000 0.19582800 0.57796200 1 - O O69 1 0.47538200 0.59324700 0.17121000 1 - O O70 1 0.82879000 0.80417200 0.42203800 1 - O O71 1 0.52461800 0.40675300 0.82879000 1 - O O72 1 0.30417200 0.32879000 0.92203800 1 - O O73 1 0.69582800 0.67121000 0.07796200 1 - O O74 1 0.19582800 0.11786500 0.02461800 1 - O O75 1 0.80417200 0.88213500 0.97538200 1 - O O76 1 0.90675300 0.38213500 0.57796200 1 - O O77 1 0.09324700 0.61786500 0.42203800 1 - O O78 1 0.59324700 0.17121000 0.47538200 1 - O O79 1 0.40675300 0.82879000 0.52461800 1 -" -Li3Pr3(TeO6)2,mp-1211386,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Pr12 Te8 O48) -Reduced Formula: Li3Pr3(TeO6)2 -abc : 11.060752 11.060752 11.060752 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Pr 0.25 0.375 0.125 -0 - 13 Pr 0.75 0.625 0.875 -0 - 14 Pr 0.75 0.125 0.375 0 - 15 Pr 0.125 0.25 0.375 -0 - 16 Pr 0.375 0.75 0.125 -0 - 17 Pr 0.25 0.875 0.625 0 - 18 Pr 0.875 0.75 0.625 -0 - 19 Pr 0.625 0.25 0.875 -0 - 20 Pr 0.375 0.125 0.25 -0 - 21 Pr 0.625 0.875 0.75 -0 - 22 Pr 0.125 0.375 0.75 -0 - 23 Pr 0.875 0.625 0.25 -0 - 24 Te 0 0 0 0 - 25 Te 0.5 0 0.5 0 - 26 Te 0 0.5 0.5 0 - 27 Te 0.5 0 0 0 - 28 Te 0.5 0.5 0 0 - 29 Te 0.5 0.5 0.5 0 - 30 Te 0 0 0.5 0 - 31 Te 0 0.5 0 0 - 32 O 0.477697 0.384544 0.307774 -0 - 33 O 0.522303 0.615456 0.692226 -0 - 34 O 0.57677 0.169923 0.192226 -0 - 35 O 0.92323 0.115456 0.593153 -0 - 36 O 0.307774 0.477697 0.384544 -0 - 37 O 0.330077 0.92323 0.307774 -0 - 38 O 0.42323 0.830077 0.807774 -0 - 39 O 0.07677 0.884544 0.406847 -0 - 40 O 0.692226 0.522303 0.615456 -0 - 41 O 0.669923 0.07677 0.692226 -0 - 42 O 0.022303 0.330077 0.906847 -0 - 43 O 0.192226 0.57677 0.169923 -0 - 44 O 0.115456 0.022303 0.192226 -0 - 45 O 0.977697 0.669923 0.093153 -0 - 46 O 0.807774 0.42323 0.830077 -0 - 47 O 0.884544 0.977697 0.807774 -0 - 48 O 0.593153 0.92323 0.115456 -0 - 49 O 0.169923 0.477697 0.593153 -0 - 50 O 0.406847 0.07677 0.884544 -0 - 51 O 0.830077 0.522303 0.406847 -0 - 52 O 0.906847 0.022303 0.330077 -0 - 53 O 0.384544 0.57677 0.906847 -0 - 54 O 0.093153 0.977697 0.669923 -0 - 55 O 0.615456 0.42323 0.093153 -0 - 56 O 0.384544 0.307774 0.477697 -0 - 57 O 0.57677 0.906847 0.384544 -0 - 58 O 0.615456 0.692226 0.522303 -0 - 59 O 0.42323 0.093153 0.615456 -0 - 60 O 0.115456 0.593153 0.92323 -0 - 61 O 0.022303 0.192226 0.115456 -0 - 62 O 0.884544 0.406847 0.07677 -0 - 63 O 0.977697 0.807774 0.884544 -0 - 64 O 0.330077 0.906847 0.022303 -0 - 65 O 0.92323 0.307774 0.330077 -0 - 66 O 0.669923 0.093153 0.977697 -0 - 67 O 0.07677 0.692226 0.669923 -0 - 68 O 0.169923 0.192226 0.57677 -0 - 69 O 0.477697 0.593153 0.169923 -0 - 70 O 0.830077 0.807774 0.42323 -0 - 71 O 0.522303 0.406847 0.830077 -0 - 72 O 0.307774 0.330077 0.92323 -0 - 73 O 0.692226 0.669923 0.07677 -0 - 74 O 0.192226 0.115456 0.022303 -0 - 75 O 0.807774 0.884544 0.977697 -0 - 76 O 0.906847 0.384544 0.57677 -0 - 77 O 0.093153 0.615456 0.42323 -0 - 78 O 0.593153 0.169923 0.477697 -0 - 79 O 0.406847 0.830077 0.522303 -0","# generated using pymatgen -data_Li3Pr3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.06075175 -_cell_length_b 11.06075175 -_cell_length_c 11.06075175 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Pr3(TeO6)2 -_chemical_formula_sum 'Li12 Pr12 Te8 O48' -_cell_volume 1041.67452744 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Pr Pr12 1 0.25000000 0.37500000 0.12500000 1 - Pr Pr13 1 0.75000000 0.62500000 0.87500000 1 - Pr Pr14 1 0.75000000 0.12500000 0.37500000 1 - Pr Pr15 1 0.12500000 0.25000000 0.37500000 1 - Pr Pr16 1 0.37500000 0.75000000 0.12500000 1 - Pr Pr17 1 0.25000000 0.87500000 0.62500000 1 - Pr Pr18 1 0.87500000 0.75000000 0.62500000 1 - Pr Pr19 1 0.62500000 0.25000000 0.87500000 1 - Pr Pr20 1 0.37500000 0.12500000 0.25000000 1 - Pr Pr21 1 0.62500000 0.87500000 0.75000000 1 - Pr Pr22 1 0.12500000 0.37500000 0.75000000 1 - Pr Pr23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47769700 0.38454400 0.30777400 1 - O O33 1 0.52230300 0.61545600 0.69222600 1 - O O34 1 0.57677000 0.16992300 0.19222600 1 - O O35 1 0.92323000 0.11545600 0.59315300 1 - O O36 1 0.30777400 0.47769700 0.38454400 1 - O O37 1 0.33007700 0.92323000 0.30777400 1 - O O38 1 0.42323000 0.83007700 0.80777400 1 - O O39 1 0.07677000 0.88454400 0.40684700 1 - O O40 1 0.69222600 0.52230300 0.61545600 1 - O O41 1 0.66992300 0.07677000 0.69222600 1 - O O42 1 0.02230300 0.33007700 0.90684700 1 - O O43 1 0.19222600 0.57677000 0.16992300 1 - O O44 1 0.11545600 0.02230300 0.19222600 1 - O O45 1 0.97769700 0.66992300 0.09315300 1 - O O46 1 0.80777400 0.42323000 0.83007700 1 - O O47 1 0.88454400 0.97769700 0.80777400 1 - O O48 1 0.59315300 0.92323000 0.11545600 1 - O O49 1 0.16992300 0.47769700 0.59315300 1 - O O50 1 0.40684700 0.07677000 0.88454400 1 - O O51 1 0.83007700 0.52230300 0.40684700 1 - O O52 1 0.90684700 0.02230300 0.33007700 1 - O O53 1 0.38454400 0.57677000 0.90684700 1 - O O54 1 0.09315300 0.97769700 0.66992300 1 - O O55 1 0.61545600 0.42323000 0.09315300 1 - O O56 1 0.38454400 0.30777400 0.47769700 1 - O O57 1 0.57677000 0.90684700 0.38454400 1 - O O58 1 0.61545600 0.69222600 0.52230300 1 - O O59 1 0.42323000 0.09315300 0.61545600 1 - O O60 1 0.11545600 0.59315300 0.92323000 1 - O O61 1 0.02230300 0.19222600 0.11545600 1 - O O62 1 0.88454400 0.40684700 0.07677000 1 - O O63 1 0.97769700 0.80777400 0.88454400 1 - O O64 1 0.33007700 0.90684700 0.02230300 1 - O O65 1 0.92323000 0.30777400 0.33007700 1 - O O66 1 0.66992300 0.09315300 0.97769700 1 - O O67 1 0.07677000 0.69222600 0.66992300 1 - O O68 1 0.16992300 0.19222600 0.57677000 1 - O O69 1 0.47769700 0.59315300 0.16992300 1 - O O70 1 0.83007700 0.80777400 0.42323000 1 - O O71 1 0.52230300 0.40684700 0.83007700 1 - O O72 1 0.30777400 0.33007700 0.92323000 1 - O O73 1 0.69222600 0.66992300 0.07677000 1 - O O74 1 0.19222600 0.11545600 0.02230300 1 - O O75 1 0.80777400 0.88454400 0.97769700 1 - O O76 1 0.90684700 0.38454400 0.57677000 1 - O O77 1 0.09315300 0.61545600 0.42323000 1 - O O78 1 0.59315300 0.16992300 0.47769700 1 - O O79 1 0.40684700 0.83007700 0.52230300 1 -" -Mn3Al2(GeO4)3,mp-1211470,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Mn12 Al8 Ge12 O48) -Reduced Formula: Mn3Al2(GeO4)3 -abc : 10.429184 10.429184 10.429184 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.25 0.375 0.125 4.669 - 1 Mn 0.75 0.625 0.875 4.669 - 2 Mn 0.75 0.125 0.375 4.669 - 3 Mn 0.125 0.25 0.375 4.669 - 4 Mn 0.375 0.75 0.125 4.669 - 5 Mn 0.25 0.875 0.625 4.669 - 6 Mn 0.875 0.75 0.625 4.669 - 7 Mn 0.625 0.25 0.875 4.669 - 8 Mn 0.375 0.125 0.25 4.669 - 9 Mn 0.625 0.875 0.75 4.669 - 10 Mn 0.125 0.375 0.75 4.669 - 11 Mn 0.875 0.625 0.25 4.669 - 12 Al 0 0 0 0.003 - 13 Al 0.5 0 0.5 0.003 - 14 Al 0 0.5 0.5 0.003 - 15 Al 0.5 0 0 0.003 - 16 Al 0.5 0.5 0 0.003 - 17 Al 0.5 0.5 0.5 0.003 - 18 Al 0 0 0.5 0.003 - 19 Al 0 0.5 0 0.003 - 20 Ge 0.25 0.625 0.375 0.009 - 21 Ge 0.75 0.375 0.625 0.009 - 22 Ge 0.75 0.875 0.125 0.009 - 23 Ge 0.375 0.25 0.625 0.009 - 24 Ge 0.625 0.75 0.375 0.009 - 25 Ge 0.25 0.125 0.875 0.009 - 26 Ge 0.125 0.75 0.875 0.009 - 27 Ge 0.875 0.25 0.125 0.009 - 28 Ge 0.625 0.375 0.25 0.009 - 29 Ge 0.375 0.625 0.75 0.009 - 30 Ge 0.875 0.125 0.75 0.009 - 31 Ge 0.125 0.875 0.25 0.009 - 32 O 0.480225 0.379548 0.302127 0.028 - 33 O 0.519775 0.620452 0.697873 0.028 - 34 O 0.57742 0.178098 0.197873 0.028 - 35 O 0.92258 0.120452 0.600678 0.028 - 36 O 0.302127 0.480225 0.379548 0.028 - 37 O 0.321902 0.92258 0.302127 0.028 - 38 O 0.42258 0.821902 0.802127 0.028 - 39 O 0.07742 0.879548 0.399322 0.028 - 40 O 0.697873 0.519775 0.620452 0.028 - 41 O 0.678098 0.07742 0.697873 0.028 - 42 O 0.019775 0.321902 0.899322 0.028 - 43 O 0.197873 0.57742 0.178098 0.028 - 44 O 0.120452 0.019775 0.197873 0.028 - 45 O 0.980225 0.678098 0.100678 0.028 - 46 O 0.802127 0.42258 0.821902 0.028 - 47 O 0.879548 0.980225 0.802127 0.028 - 48 O 0.600678 0.92258 0.120452 0.028 - 49 O 0.178098 0.480225 0.600678 0.028 - 50 O 0.399322 0.07742 0.879548 0.028 - 51 O 0.821902 0.519775 0.399322 0.028 - 52 O 0.899322 0.019775 0.321902 0.028 - 53 O 0.379548 0.57742 0.899322 0.028 - 54 O 0.100678 0.980225 0.678098 0.028 - 55 O 0.620452 0.42258 0.100678 0.028 - 56 O 0.379548 0.302127 0.480225 0.028 - 57 O 0.57742 0.899322 0.379548 0.028 - 58 O 0.620452 0.697873 0.519775 0.028 - 59 O 0.42258 0.100678 0.620452 0.028 - 60 O 0.120452 0.600678 0.92258 0.028 - 61 O 0.019775 0.197873 0.120452 0.028 - 62 O 0.879548 0.399322 0.07742 0.028 - 63 O 0.980225 0.802127 0.879548 0.028 - 64 O 0.321902 0.899322 0.019775 0.028 - 65 O 0.92258 0.302127 0.321902 0.028 - 66 O 0.678098 0.100678 0.980225 0.028 - 67 O 0.07742 0.697873 0.678098 0.028 - 68 O 0.178098 0.197873 0.57742 0.028 - 69 O 0.480225 0.600678 0.178098 0.028 - 70 O 0.821902 0.802127 0.42258 0.028 - 71 O 0.519775 0.399322 0.821902 0.028 - 72 O 0.302127 0.321902 0.92258 0.028 - 73 O 0.697873 0.678098 0.07742 0.028 - 74 O 0.197873 0.120452 0.019775 0.028 - 75 O 0.802127 0.879548 0.980225 0.028 - 76 O 0.899322 0.379548 0.57742 0.028 - 77 O 0.100678 0.620452 0.42258 0.028 - 78 O 0.600678 0.178098 0.480225 0.028 - 79 O 0.399322 0.821902 0.519775 0.028","# generated using pymatgen -data_Mn3Al2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.42918367 -_cell_length_b 10.42918367 -_cell_length_c 10.42918367 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn3Al2(GeO4)3 -_chemical_formula_sum 'Mn12 Al8 Ge12 O48' -_cell_volume 873.23082376 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn1 1 0.75000000 0.62500000 0.87500000 1 - Mn Mn2 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn3 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn4 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn5 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn6 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn7 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn8 1 0.37500000 0.12500000 0.25000000 1 - Mn Mn9 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn10 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.00000000 0.00000000 0.00000000 1 - Al Al13 1 0.50000000 0.00000000 0.50000000 1 - Al Al14 1 0.00000000 0.50000000 0.50000000 1 - Al Al15 1 0.50000000 0.00000000 0.00000000 1 - Al Al16 1 0.50000000 0.50000000 0.00000000 1 - Al Al17 1 0.50000000 0.50000000 0.50000000 1 - Al Al18 1 0.00000000 0.00000000 0.50000000 1 - Al Al19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48022500 0.37954800 0.30212700 1 - O O33 1 0.51977500 0.62045200 0.69787300 1 - O O34 1 0.57742000 0.17809800 0.19787300 1 - O O35 1 0.92258000 0.12045200 0.60067800 1 - O O36 1 0.30212700 0.48022500 0.37954800 1 - O O37 1 0.32190200 0.92258000 0.30212700 1 - O O38 1 0.42258000 0.82190200 0.80212700 1 - O O39 1 0.07742000 0.87954800 0.39932200 1 - O O40 1 0.69787300 0.51977500 0.62045200 1 - O O41 1 0.67809800 0.07742000 0.69787300 1 - O O42 1 0.01977500 0.32190200 0.89932200 1 - O O43 1 0.19787300 0.57742000 0.17809800 1 - O O44 1 0.12045200 0.01977500 0.19787300 1 - O O45 1 0.98022500 0.67809800 0.10067800 1 - O O46 1 0.80212700 0.42258000 0.82190200 1 - O O47 1 0.87954800 0.98022500 0.80212700 1 - O O48 1 0.60067800 0.92258000 0.12045200 1 - O O49 1 0.17809800 0.48022500 0.60067800 1 - O O50 1 0.39932200 0.07742000 0.87954800 1 - O O51 1 0.82190200 0.51977500 0.39932200 1 - O O52 1 0.89932200 0.01977500 0.32190200 1 - O O53 1 0.37954800 0.57742000 0.89932200 1 - O O54 1 0.10067800 0.98022500 0.67809800 1 - O O55 1 0.62045200 0.42258000 0.10067800 1 - O O56 1 0.37954800 0.30212700 0.48022500 1 - O O57 1 0.57742000 0.89932200 0.37954800 1 - O O58 1 0.62045200 0.69787300 0.51977500 1 - O O59 1 0.42258000 0.10067800 0.62045200 1 - O O60 1 0.12045200 0.60067800 0.92258000 1 - O O61 1 0.01977500 0.19787300 0.12045200 1 - O O62 1 0.87954800 0.39932200 0.07742000 1 - O O63 1 0.98022500 0.80212700 0.87954800 1 - O O64 1 0.32190200 0.89932200 0.01977500 1 - O O65 1 0.92258000 0.30212700 0.32190200 1 - O O66 1 0.67809800 0.10067800 0.98022500 1 - O O67 1 0.07742000 0.69787300 0.67809800 1 - O O68 1 0.17809800 0.19787300 0.57742000 1 - O O69 1 0.48022500 0.60067800 0.17809800 1 - O O70 1 0.82190200 0.80212700 0.42258000 1 - O O71 1 0.51977500 0.39932200 0.82190200 1 - O O72 1 0.30212700 0.32190200 0.92258000 1 - O O73 1 0.69787300 0.67809800 0.07742000 1 - O O74 1 0.19787300 0.12045200 0.01977500 1 - O O75 1 0.80212700 0.87954800 0.98022500 1 - O O76 1 0.89932200 0.37954800 0.57742000 1 - O O77 1 0.10067800 0.62045200 0.42258000 1 - O O78 1 0.60067800 0.17809800 0.48022500 1 - O O79 1 0.39932200 0.82190200 0.51977500 1 -" -Li3Ho3(TeO6)2,mp-1211542,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Ho12 Te8 O48) -Reduced Formula: Li3Ho3(TeO6)2 -abc : 10.720416 10.720416 10.720416 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 -0 - 12 Ho 0.25 0.375 0.125 -0 - 13 Ho 0.75 0.625 0.875 -0 - 14 Ho 0.75 0.125 0.375 -0.001 - 15 Ho 0.125 0.25 0.375 -0.001 - 16 Ho 0.375 0.75 0.125 -0.001 - 17 Ho 0.25 0.875 0.625 -0.001 - 18 Ho 0.875 0.75 0.625 -0.001 - 19 Ho 0.625 0.25 0.875 -0.001 - 20 Ho 0.375 0.125 0.25 -0.001 - 21 Ho 0.625 0.875 0.75 -0.001 - 22 Ho 0.125 0.375 0.75 -0.001 - 23 Ho 0.875 0.625 0.25 -0.001 - 24 Te 0 0 0 0 - 25 Te 0.5 0 0.5 0 - 26 Te 0 0.5 0.5 0 - 27 Te 0.5 0 0 0 - 28 Te 0.5 0.5 0 0 - 29 Te 0.5 0.5 0.5 0 - 30 Te 0 0 0.5 0 - 31 Te 0 0.5 0 0 - 32 O 0.472406 0.379313 0.300211 0.001 - 33 O 0.527594 0.620687 0.699789 0.001 - 34 O 0.579102 0.172194 0.199789 0.001 - 35 O 0.920898 0.120687 0.593092 0.001 - 36 O 0.300211 0.472406 0.379313 0.001 - 37 O 0.327806 0.920898 0.300211 0.001 - 38 O 0.420898 0.827806 0.800211 0.001 - 39 O 0.079102 0.879313 0.406908 0.001 - 40 O 0.699789 0.527594 0.620687 0.001 - 41 O 0.672194 0.079102 0.699789 0.001 - 42 O 0.027594 0.327806 0.906908 0.001 - 43 O 0.199789 0.579102 0.172194 0.001 - 44 O 0.120687 0.027594 0.199789 0.001 - 45 O 0.972406 0.672194 0.093092 0.001 - 46 O 0.800211 0.420898 0.827806 0.001 - 47 O 0.879313 0.972406 0.800211 0.001 - 48 O 0.593092 0.920898 0.120687 0.001 - 49 O 0.172194 0.472406 0.593092 0.001 - 50 O 0.406908 0.079102 0.879313 0.001 - 51 O 0.827806 0.527594 0.406908 0.001 - 52 O 0.906908 0.027594 0.327806 0.001 - 53 O 0.379313 0.579102 0.906908 0.001 - 54 O 0.093092 0.972406 0.672194 0.001 - 55 O 0.620687 0.420898 0.093092 0.001 - 56 O 0.379313 0.300211 0.472406 0.001 - 57 O 0.579102 0.906908 0.379313 0.001 - 58 O 0.620687 0.699789 0.527594 0.001 - 59 O 0.420898 0.093092 0.620687 0.001 - 60 O 0.120687 0.593092 0.920898 0.001 - 61 O 0.027594 0.199789 0.120687 0.001 - 62 O 0.879313 0.406908 0.079102 0.001 - 63 O 0.972406 0.800211 0.879313 0.001 - 64 O 0.327806 0.906908 0.027594 0.001 - 65 O 0.920898 0.300211 0.327806 0.001 - 66 O 0.672194 0.093092 0.972406 0.001 - 67 O 0.079102 0.699789 0.672194 0.001 - 68 O 0.172194 0.199789 0.579102 0.001 - 69 O 0.472406 0.593092 0.172194 0.001 - 70 O 0.827806 0.800211 0.420898 0.001 - 71 O 0.527594 0.406908 0.827806 0.001 - 72 O 0.300211 0.327806 0.920898 0.001 - 73 O 0.699789 0.672194 0.079102 0.001 - 74 O 0.199789 0.120687 0.027594 0.001 - 75 O 0.800211 0.879313 0.972406 0.001 - 76 O 0.906908 0.379313 0.579102 0.001 - 77 O 0.093092 0.620687 0.420898 0.001 - 78 O 0.593092 0.172194 0.472406 0.001 - 79 O 0.406908 0.827806 0.527594 0.001","# generated using pymatgen -data_Li3Ho3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.72041589 -_cell_length_b 10.72041589 -_cell_length_c 10.72041589 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Ho3(TeO6)2 -_chemical_formula_sum 'Li12 Ho12 Te8 O48' -_cell_volume 948.44687655 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Ho Ho12 1 0.25000000 0.37500000 0.12500000 1 - Ho Ho13 1 0.75000000 0.62500000 0.87500000 1 - Ho Ho14 1 0.75000000 0.12500000 0.37500000 1 - Ho Ho15 1 0.12500000 0.25000000 0.37500000 1 - Ho Ho16 1 0.37500000 0.75000000 0.12500000 1 - Ho Ho17 1 0.25000000 0.87500000 0.62500000 1 - Ho Ho18 1 0.87500000 0.75000000 0.62500000 1 - Ho Ho19 1 0.62500000 0.25000000 0.87500000 1 - Ho Ho20 1 0.37500000 0.12500000 0.25000000 1 - Ho Ho21 1 0.62500000 0.87500000 0.75000000 1 - Ho Ho22 1 0.12500000 0.37500000 0.75000000 1 - Ho Ho23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47240600 0.37931300 0.30021100 1 - O O33 1 0.52759400 0.62068700 0.69978900 1 - O O34 1 0.57910200 0.17219400 0.19978900 1 - O O35 1 0.92089800 0.12068700 0.59309200 1 - O O36 1 0.30021100 0.47240600 0.37931300 1 - O O37 1 0.32780600 0.92089800 0.30021100 1 - O O38 1 0.42089800 0.82780600 0.80021100 1 - O O39 1 0.07910200 0.87931300 0.40690800 1 - O O40 1 0.69978900 0.52759400 0.62068700 1 - O O41 1 0.67219400 0.07910200 0.69978900 1 - O O42 1 0.02759400 0.32780600 0.90690800 1 - O O43 1 0.19978900 0.57910200 0.17219400 1 - O O44 1 0.12068700 0.02759400 0.19978900 1 - O O45 1 0.97240600 0.67219400 0.09309200 1 - O O46 1 0.80021100 0.42089800 0.82780600 1 - O O47 1 0.87931300 0.97240600 0.80021100 1 - O O48 1 0.59309200 0.92089800 0.12068700 1 - O O49 1 0.17219400 0.47240600 0.59309200 1 - O O50 1 0.40690800 0.07910200 0.87931300 1 - O O51 1 0.82780600 0.52759400 0.40690800 1 - O O52 1 0.90690800 0.02759400 0.32780600 1 - O O53 1 0.37931300 0.57910200 0.90690800 1 - O O54 1 0.09309200 0.97240600 0.67219400 1 - O O55 1 0.62068700 0.42089800 0.09309200 1 - O O56 1 0.37931300 0.30021100 0.47240600 1 - O O57 1 0.57910200 0.90690800 0.37931300 1 - O O58 1 0.62068700 0.69978900 0.52759400 1 - O O59 1 0.42089800 0.09309200 0.62068700 1 - O O60 1 0.12068700 0.59309200 0.92089800 1 - O O61 1 0.02759400 0.19978900 0.12068700 1 - O O62 1 0.87931300 0.40690800 0.07910200 1 - O O63 1 0.97240600 0.80021100 0.87931300 1 - O O64 1 0.32780600 0.90690800 0.02759400 1 - O O65 1 0.92089800 0.30021100 0.32780600 1 - O O66 1 0.67219400 0.09309200 0.97240600 1 - O O67 1 0.07910200 0.69978900 0.67219400 1 - O O68 1 0.17219400 0.19978900 0.57910200 1 - O O69 1 0.47240600 0.59309200 0.17219400 1 - O O70 1 0.82780600 0.80021100 0.42089800 1 - O O71 1 0.52759400 0.40690800 0.82780600 1 - O O72 1 0.30021100 0.32780600 0.92089800 1 - O O73 1 0.69978900 0.67219400 0.07910200 1 - O O74 1 0.19978900 0.12068700 0.02759400 1 - O O75 1 0.80021100 0.87931300 0.97240600 1 - O O76 1 0.90690800 0.37931300 0.57910200 1 - O O77 1 0.09309200 0.62068700 0.42089800 1 - O O78 1 0.59309200 0.17219400 0.47240600 1 - O O79 1 0.40690800 0.82780600 0.52759400 1 -" -Mn3Ga2(GeO4)3,mp-1211638,Ia-3d,[],0.013618521250000626,{'tags': ['garnet family']},"Full Formula (Mn12 Ga8 Ge12 O48) -Reduced Formula: Mn3Ga2(GeO4)3 -abc : 10.559697 10.559697 10.559697 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.25 0.375 0.125 4.672 - 1 Mn 0.75 0.625 0.875 4.672 - 2 Mn 0.75 0.125 0.375 4.672 - 3 Mn 0.125 0.25 0.375 4.672 - 4 Mn 0.375 0.75 0.125 4.672 - 5 Mn 0.25 0.875 0.625 4.672 - 6 Mn 0.875 0.75 0.625 4.672 - 7 Mn 0.625 0.25 0.875 4.672 - 8 Mn 0.375 0.125 0.25 4.672 - 9 Mn 0.625 0.875 0.75 4.672 - 10 Mn 0.125 0.375 0.75 4.672 - 11 Mn 0.875 0.625 0.25 4.672 - 12 Ga 0 0 0 0.005 - 13 Ga 0.5 0 0.5 0.005 - 14 Ga 0 0.5 0.5 0.005 - 15 Ga 0.5 0 0 0.005 - 16 Ga 0.5 0.5 0 0.005 - 17 Ga 0.5 0.5 0.5 0.005 - 18 Ga 0 0 0.5 0.005 - 19 Ga 0 0.5 0 0.005 - 20 Ge 0.25 0.625 0.375 0.01 - 21 Ge 0.75 0.375 0.625 0.01 - 22 Ge 0.75 0.875 0.125 0.01 - 23 Ge 0.375 0.25 0.625 0.01 - 24 Ge 0.625 0.75 0.375 0.01 - 25 Ge 0.25 0.125 0.875 0.01 - 26 Ge 0.125 0.75 0.875 0.01 - 27 Ge 0.875 0.25 0.125 0.01 - 28 Ge 0.625 0.375 0.25 0.01 - 29 Ge 0.375 0.625 0.75 0.01 - 30 Ge 0.875 0.125 0.75 0.01 - 31 Ge 0.125 0.875 0.25 0.01 - 32 O 0.477724 0.375822 0.296081 0.026 - 33 O 0.522276 0.624178 0.703919 0.026 - 34 O 0.579741 0.181643 0.203919 0.026 - 35 O 0.920259 0.124178 0.601901 0.026 - 36 O 0.296081 0.477724 0.375822 0.026 - 37 O 0.318357 0.920259 0.296081 0.026 - 38 O 0.420259 0.818357 0.796081 0.026 - 39 O 0.079741 0.875822 0.398099 0.026 - 40 O 0.703919 0.522276 0.624178 0.026 - 41 O 0.681643 0.079741 0.703919 0.026 - 42 O 0.022276 0.318357 0.898099 0.026 - 43 O 0.203919 0.579741 0.181643 0.026 - 44 O 0.124178 0.022276 0.203919 0.026 - 45 O 0.977724 0.681643 0.101901 0.026 - 46 O 0.796081 0.420259 0.818357 0.026 - 47 O 0.875822 0.977724 0.796081 0.026 - 48 O 0.601901 0.920259 0.124178 0.026 - 49 O 0.181643 0.477724 0.601901 0.026 - 50 O 0.398099 0.079741 0.875822 0.026 - 51 O 0.818357 0.522276 0.398099 0.026 - 52 O 0.898099 0.022276 0.318357 0.026 - 53 O 0.375822 0.579741 0.898099 0.026 - 54 O 0.101901 0.977724 0.681643 0.026 - 55 O 0.624178 0.420259 0.101901 0.026 - 56 O 0.375822 0.296081 0.477724 0.026 - 57 O 0.579741 0.898099 0.375822 0.026 - 58 O 0.624178 0.703919 0.522276 0.026 - 59 O 0.420259 0.101901 0.624178 0.026 - 60 O 0.124178 0.601901 0.920259 0.026 - 61 O 0.022276 0.203919 0.124178 0.026 - 62 O 0.875822 0.398099 0.079741 0.026 - 63 O 0.977724 0.796081 0.875822 0.026 - 64 O 0.318357 0.898099 0.022276 0.026 - 65 O 0.920259 0.296081 0.318357 0.026 - 66 O 0.681643 0.101901 0.977724 0.026 - 67 O 0.079741 0.703919 0.681643 0.026 - 68 O 0.181643 0.203919 0.579741 0.026 - 69 O 0.477724 0.601901 0.181643 0.026 - 70 O 0.818357 0.796081 0.420259 0.026 - 71 O 0.522276 0.398099 0.818357 0.026 - 72 O 0.296081 0.318357 0.920259 0.026 - 73 O 0.703919 0.681643 0.079741 0.026 - 74 O 0.203919 0.124178 0.022276 0.026 - 75 O 0.796081 0.875822 0.977724 0.026 - 76 O 0.898099 0.375822 0.579741 0.026 - 77 O 0.101901 0.624178 0.420259 0.026 - 78 O 0.601901 0.181643 0.477724 0.026 - 79 O 0.398099 0.818357 0.522276 0.026","# generated using pymatgen -data_Mn3Ga2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.55969716 -_cell_length_b 10.55969716 -_cell_length_c 10.55969716 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn3Ga2(GeO4)3 -_chemical_formula_sum 'Mn12 Ga8 Ge12 O48' -_cell_volume 906.42630316 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn1 1 0.75000000 0.62500000 0.87500000 1 - Mn Mn2 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn3 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn4 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn5 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn6 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn7 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn8 1 0.37500000 0.12500000 0.25000000 1 - Mn Mn9 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn10 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga13 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga14 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga15 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga16 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga18 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47772400 0.37582200 0.29608100 1 - O O33 1 0.52227600 0.62417800 0.70391900 1 - O O34 1 0.57974100 0.18164300 0.20391900 1 - O O35 1 0.92025900 0.12417800 0.60190100 1 - O O36 1 0.29608100 0.47772400 0.37582200 1 - O O37 1 0.31835700 0.92025900 0.29608100 1 - O O38 1 0.42025900 0.81835700 0.79608100 1 - O O39 1 0.07974100 0.87582200 0.39809900 1 - O O40 1 0.70391900 0.52227600 0.62417800 1 - O O41 1 0.68164300 0.07974100 0.70391900 1 - O O42 1 0.02227600 0.31835700 0.89809900 1 - O O43 1 0.20391900 0.57974100 0.18164300 1 - O O44 1 0.12417800 0.02227600 0.20391900 1 - O O45 1 0.97772400 0.68164300 0.10190100 1 - O O46 1 0.79608100 0.42025900 0.81835700 1 - O O47 1 0.87582200 0.97772400 0.79608100 1 - O O48 1 0.60190100 0.92025900 0.12417800 1 - O O49 1 0.18164300 0.47772400 0.60190100 1 - O O50 1 0.39809900 0.07974100 0.87582200 1 - O O51 1 0.81835700 0.52227600 0.39809900 1 - O O52 1 0.89809900 0.02227600 0.31835700 1 - O O53 1 0.37582200 0.57974100 0.89809900 1 - O O54 1 0.10190100 0.97772400 0.68164300 1 - O O55 1 0.62417800 0.42025900 0.10190100 1 - O O56 1 0.37582200 0.29608100 0.47772400 1 - O O57 1 0.57974100 0.89809900 0.37582200 1 - O O58 1 0.62417800 0.70391900 0.52227600 1 - O O59 1 0.42025900 0.10190100 0.62417800 1 - O O60 1 0.12417800 0.60190100 0.92025900 1 - O O61 1 0.02227600 0.20391900 0.12417800 1 - O O62 1 0.87582200 0.39809900 0.07974100 1 - O O63 1 0.97772400 0.79608100 0.87582200 1 - O O64 1 0.31835700 0.89809900 0.02227600 1 - O O65 1 0.92025900 0.29608100 0.31835700 1 - O O66 1 0.68164300 0.10190100 0.97772400 1 - O O67 1 0.07974100 0.70391900 0.68164300 1 - O O68 1 0.18164300 0.20391900 0.57974100 1 - O O69 1 0.47772400 0.60190100 0.18164300 1 - O O70 1 0.81835700 0.79608100 0.42025900 1 - O O71 1 0.52227600 0.39809900 0.81835700 1 - O O72 1 0.29608100 0.31835700 0.92025900 1 - O O73 1 0.70391900 0.68164300 0.07974100 1 - O O74 1 0.20391900 0.12417800 0.02227600 1 - O O75 1 0.79608100 0.87582200 0.97772400 1 - O O76 1 0.89809900 0.37582200 0.57974100 1 - O O77 1 0.10190100 0.62417800 0.42025900 1 - O O78 1 0.60190100 0.18164300 0.47772400 1 - O O79 1 0.39809900 0.81835700 0.52227600 1 -" -Li3Lu3(TeO6)2,mp-1211646,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Lu12 Te8 O48) -Reduced Formula: Li3Lu3(TeO6)2 -abc : 10.605695 10.605695 10.605695 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 -0 - 1 Li 0.75 0.375 0.625 -0 - 2 Li 0.75 0.875 0.125 -0 - 3 Li 0.375 0.25 0.625 0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.125 0.875 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.875 0.25 0.125 -0 - 8 Li 0.625 0.375 0.25 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.875 0.125 0.75 -0 - 11 Li 0.125 0.875 0.25 0 - 12 Lu 0.25 0.375 0.125 0 - 13 Lu 0.75 0.625 0.875 0 - 14 Lu 0.75 0.125 0.375 0 - 15 Lu 0.125 0.25 0.375 0 - 16 Lu 0.375 0.75 0.125 0 - 17 Lu 0.25 0.875 0.625 0 - 18 Lu 0.875 0.75 0.625 -0 - 19 Lu 0.625 0.25 0.875 0 - 20 Lu 0.375 0.125 0.25 0 - 21 Lu 0.625 0.875 0.75 0 - 22 Lu 0.125 0.375 0.75 -0 - 23 Lu 0.875 0.625 0.25 -0 - 24 Te 0 0 0 -0 - 25 Te 0.5 0 0.5 -0 - 26 Te 0 0.5 0.5 -0 - 27 Te 0.5 0 0 -0 - 28 Te 0.5 0.5 0 -0 - 29 Te 0.5 0.5 0.5 -0 - 30 Te 0 0 0.5 -0 - 31 Te 0 0.5 0 -0 - 32 O 0.469905 0.377258 0.297453 -0 - 33 O 0.530095 0.622742 0.702547 -0 - 34 O 0.579806 0.172452 0.202547 0 - 35 O 0.920194 0.122742 0.592646 0 - 36 O 0.297453 0.469905 0.377258 -0 - 37 O 0.327548 0.920194 0.297453 -0 - 38 O 0.420194 0.827548 0.797453 0 - 39 O 0.079806 0.877258 0.407354 -0 - 40 O 0.702547 0.530095 0.622742 -0 - 41 O 0.672452 0.079806 0.702547 0 - 42 O 0.030095 0.327548 0.907354 0 - 43 O 0.202547 0.579806 0.172452 -0 - 44 O 0.122742 0.030095 0.202547 -0 - 45 O 0.969905 0.672452 0.092646 0 - 46 O 0.797453 0.420194 0.827548 -0 - 47 O 0.877258 0.969905 0.797453 0 - 48 O 0.592646 0.920194 0.122742 -0 - 49 O 0.172452 0.469905 0.592646 -0 - 50 O 0.407354 0.079806 0.877258 -0 - 51 O 0.827548 0.530095 0.407354 -0 - 52 O 0.907354 0.030095 0.327548 0 - 53 O 0.377258 0.579806 0.907354 -0 - 54 O 0.092646 0.969905 0.672452 -0 - 55 O 0.622742 0.420194 0.092646 -0 - 56 O 0.377258 0.297453 0.469905 0 - 57 O 0.579806 0.907354 0.377258 0 - 58 O 0.622742 0.702547 0.530095 0 - 59 O 0.420194 0.092646 0.622742 -0 - 60 O 0.122742 0.592646 0.920194 -0 - 61 O 0.030095 0.202547 0.122742 -0 - 62 O 0.877258 0.407354 0.079806 -0 - 63 O 0.969905 0.797453 0.877258 -0 - 64 O 0.327548 0.907354 0.030095 -0 - 65 O 0.920194 0.297453 0.327548 -0 - 66 O 0.672452 0.092646 0.969905 0 - 67 O 0.079806 0.702547 0.672452 -0 - 68 O 0.172452 0.202547 0.579806 -0 - 69 O 0.469905 0.592646 0.172452 -0 - 70 O 0.827548 0.797453 0.420194 0 - 71 O 0.530095 0.407354 0.827548 -0 - 72 O 0.297453 0.327548 0.920194 -0 - 73 O 0.702547 0.672452 0.079806 -0 - 74 O 0.202547 0.122742 0.030095 -0 - 75 O 0.797453 0.877258 0.969905 -0 - 76 O 0.907354 0.377258 0.579806 -0 - 77 O 0.092646 0.622742 0.420194 -0 - 78 O 0.592646 0.172452 0.469905 -0 - 79 O 0.407354 0.827548 0.530095 0","# generated using pymatgen -data_Li3Lu3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.60569524 -_cell_length_b 10.60569524 -_cell_length_c 10.60569524 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Lu3(TeO6)2 -_chemical_formula_sum 'Li12 Lu12 Te8 O48' -_cell_volume 918.32316304 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Lu Lu12 1 0.25000000 0.37500000 0.12500000 1 - Lu Lu13 1 0.75000000 0.62500000 0.87500000 1 - Lu Lu14 1 0.75000000 0.12500000 0.37500000 1 - Lu Lu15 1 0.12500000 0.25000000 0.37500000 1 - Lu Lu16 1 0.37500000 0.75000000 0.12500000 1 - Lu Lu17 1 0.25000000 0.87500000 0.62500000 1 - Lu Lu18 1 0.87500000 0.75000000 0.62500000 1 - Lu Lu19 1 0.62500000 0.25000000 0.87500000 1 - Lu Lu20 1 0.37500000 0.12500000 0.25000000 1 - Lu Lu21 1 0.62500000 0.87500000 0.75000000 1 - Lu Lu22 1 0.12500000 0.37500000 0.75000000 1 - Lu Lu23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.46990500 0.37725800 0.29745300 1 - O O33 1 0.53009500 0.62274200 0.70254700 1 - O O34 1 0.57980600 0.17245200 0.20254700 1 - O O35 1 0.92019400 0.12274200 0.59264600 1 - O O36 1 0.29745300 0.46990500 0.37725800 1 - O O37 1 0.32754800 0.92019400 0.29745300 1 - O O38 1 0.42019400 0.82754800 0.79745300 1 - O O39 1 0.07980600 0.87725800 0.40735400 1 - O O40 1 0.70254700 0.53009500 0.62274200 1 - O O41 1 0.67245200 0.07980600 0.70254700 1 - O O42 1 0.03009500 0.32754800 0.90735400 1 - O O43 1 0.20254700 0.57980600 0.17245200 1 - O O44 1 0.12274200 0.03009500 0.20254700 1 - O O45 1 0.96990500 0.67245200 0.09264600 1 - O O46 1 0.79745300 0.42019400 0.82754800 1 - O O47 1 0.87725800 0.96990500 0.79745300 1 - O O48 1 0.59264600 0.92019400 0.12274200 1 - O O49 1 0.17245200 0.46990500 0.59264600 1 - O O50 1 0.40735400 0.07980600 0.87725800 1 - O O51 1 0.82754800 0.53009500 0.40735400 1 - O O52 1 0.90735400 0.03009500 0.32754800 1 - O O53 1 0.37725800 0.57980600 0.90735400 1 - O O54 1 0.09264600 0.96990500 0.67245200 1 - O O55 1 0.62274200 0.42019400 0.09264600 1 - O O56 1 0.37725800 0.29745300 0.46990500 1 - O O57 1 0.57980600 0.90735400 0.37725800 1 - O O58 1 0.62274200 0.70254700 0.53009500 1 - O O59 1 0.42019400 0.09264600 0.62274200 1 - O O60 1 0.12274200 0.59264600 0.92019400 1 - O O61 1 0.03009500 0.20254700 0.12274200 1 - O O62 1 0.87725800 0.40735400 0.07980600 1 - O O63 1 0.96990500 0.79745300 0.87725800 1 - O O64 1 0.32754800 0.90735400 0.03009500 1 - O O65 1 0.92019400 0.29745300 0.32754800 1 - O O66 1 0.67245200 0.09264600 0.96990500 1 - O O67 1 0.07980600 0.70254700 0.67245200 1 - O O68 1 0.17245200 0.20254700 0.57980600 1 - O O69 1 0.46990500 0.59264600 0.17245200 1 - O O70 1 0.82754800 0.79745300 0.42019400 1 - O O71 1 0.53009500 0.40735400 0.82754800 1 - O O72 1 0.29745300 0.32754800 0.92019400 1 - O O73 1 0.70254700 0.67245200 0.07980600 1 - O O74 1 0.20254700 0.12274200 0.03009500 1 - O O75 1 0.79745300 0.87725800 0.96990500 1 - O O76 1 0.90735400 0.37725800 0.57980600 1 - O O77 1 0.09264600 0.62274200 0.42019400 1 - O O78 1 0.59264600 0.17245200 0.46990500 1 - O O79 1 0.40735400 0.82754800 0.53009500 1 -" -La3Sc2(GaO4)3,mp-1211869,Ia-3d,[],0.0,"{'tags': ['garnet family', 'La3Sc2Ga3O12']}","Full Formula (La12 Sc8 Ga12 O48) -Reduced Formula: La3Sc2(GaO4)3 -abc : 11.241779 11.241779 11.241779 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.25 0.375 0.125 0 - 1 La 0.75 0.625 0.875 0 - 2 La 0.75 0.125 0.375 0 - 3 La 0.125 0.25 0.375 0 - 4 La 0.375 0.75 0.125 0 - 5 La 0.25 0.875 0.625 0 - 6 La 0.875 0.75 0.625 0 - 7 La 0.625 0.25 0.875 0 - 8 La 0.375 0.125 0.25 0 - 9 La 0.625 0.875 0.75 0 - 10 La 0.125 0.375 0.75 0 - 11 La 0.875 0.625 0.25 0 - 12 Sc 0 0 0 -0 - 13 Sc 0.5 0 0.5 -0 - 14 Sc 0 0.5 0.5 -0 - 15 Sc 0.5 0 0 -0 - 16 Sc 0.5 0.5 0 -0 - 17 Sc 0.5 0.5 0.5 -0 - 18 Sc 0 0 0.5 -0 - 19 Sc 0 0.5 0 -0 - 20 Ga 0.25 0.625 0.375 0 - 21 Ga 0.75 0.375 0.625 0 - 22 Ga 0.75 0.875 0.125 0 - 23 Ga 0.375 0.25 0.625 0 - 24 Ga 0.625 0.75 0.375 0 - 25 Ga 0.25 0.125 0.875 0 - 26 Ga 0.125 0.75 0.875 0 - 27 Ga 0.875 0.25 0.125 0 - 28 Ga 0.625 0.375 0.25 0 - 29 Ga 0.375 0.625 0.75 0 - 30 Ga 0.875 0.125 0.75 0 - 31 Ga 0.125 0.875 0.25 0 - 32 O 0.477838 0.378009 0.29453 -0 - 33 O 0.522162 0.621991 0.70547 -0 - 34 O 0.583479 0.183308 0.20547 -0 - 35 O 0.916521 0.121991 0.59983 -0 - 36 O 0.29453 0.477838 0.378009 -0 - 37 O 0.316692 0.916521 0.29453 -0 - 38 O 0.416521 0.816692 0.79453 -0 - 39 O 0.083479 0.878009 0.40017 0 - 40 O 0.70547 0.522162 0.621991 -0 - 41 O 0.683308 0.083479 0.70547 -0 - 42 O 0.022162 0.316692 0.90017 -0 - 43 O 0.20547 0.583479 0.183308 -0 - 44 O 0.121991 0.022162 0.20547 0 - 45 O 0.977838 0.683308 0.09983 0 - 46 O 0.79453 0.416521 0.816692 0 - 47 O 0.878009 0.977838 0.79453 -0 - 48 O 0.59983 0.916521 0.121991 -0 - 49 O 0.183308 0.477838 0.59983 0 - 50 O 0.40017 0.083479 0.878009 -0 - 51 O 0.816692 0.522162 0.40017 -0 - 52 O 0.90017 0.022162 0.316692 -0 - 53 O 0.378009 0.583479 0.90017 -0 - 54 O 0.09983 0.977838 0.683308 -0 - 55 O 0.621991 0.416521 0.09983 -0 - 56 O 0.378009 0.29453 0.477838 -0 - 57 O 0.583479 0.90017 0.378009 -0 - 58 O 0.621991 0.70547 0.522162 -0 - 59 O 0.416521 0.09983 0.621991 0 - 60 O 0.121991 0.59983 0.916521 0 - 61 O 0.022162 0.20547 0.121991 -0 - 62 O 0.878009 0.40017 0.083479 -0 - 63 O 0.977838 0.79453 0.878009 -0 - 64 O 0.316692 0.90017 0.022162 -0 - 65 O 0.916521 0.29453 0.316692 -0 - 66 O 0.683308 0.09983 0.977838 0 - 67 O 0.083479 0.70547 0.683308 -0 - 68 O 0.183308 0.20547 0.583479 -0 - 69 O 0.477838 0.59983 0.183308 -0 - 70 O 0.816692 0.79453 0.416521 -0 - 71 O 0.522162 0.40017 0.816692 -0 - 72 O 0.29453 0.316692 0.916521 -0 - 73 O 0.70547 0.683308 0.083479 0 - 74 O 0.20547 0.121991 0.022162 -0 - 75 O 0.79453 0.878009 0.977838 -0 - 76 O 0.90017 0.378009 0.583479 -0 - 77 O 0.09983 0.621991 0.416521 0 - 78 O 0.59983 0.183308 0.477838 -0 - 79 O 0.40017 0.816692 0.522162 -0","# generated using pymatgen -data_La3Sc2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.24177877 -_cell_length_b 11.24177877 -_cell_length_c 11.24177877 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3Sc2(GaO4)3 -_chemical_formula_sum 'La12 Sc8 Ga12 O48' -_cell_volume 1093.66222725 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.25000000 0.37500000 0.12500000 1 - La La1 1 0.75000000 0.62500000 0.87500000 1 - La La2 1 0.75000000 0.12500000 0.37500000 1 - La La3 1 0.12500000 0.25000000 0.37500000 1 - La La4 1 0.37500000 0.75000000 0.12500000 1 - La La5 1 0.25000000 0.87500000 0.62500000 1 - La La6 1 0.87500000 0.75000000 0.62500000 1 - La La7 1 0.62500000 0.25000000 0.87500000 1 - La La8 1 0.37500000 0.12500000 0.25000000 1 - La La9 1 0.62500000 0.87500000 0.75000000 1 - La La10 1 0.12500000 0.37500000 0.75000000 1 - La La11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47783800 0.37800900 0.29453000 1 - O O33 1 0.52216200 0.62199100 0.70547000 1 - O O34 1 0.58347900 0.18330800 0.20547000 1 - O O35 1 0.91652100 0.12199100 0.59983000 1 - O O36 1 0.29453000 0.47783800 0.37800900 1 - O O37 1 0.31669200 0.91652100 0.29453000 1 - O O38 1 0.41652100 0.81669200 0.79453000 1 - O O39 1 0.08347900 0.87800900 0.40017000 1 - O O40 1 0.70547000 0.52216200 0.62199100 1 - O O41 1 0.68330800 0.08347900 0.70547000 1 - O O42 1 0.02216200 0.31669200 0.90017000 1 - O O43 1 0.20547000 0.58347900 0.18330800 1 - O O44 1 0.12199100 0.02216200 0.20547000 1 - O O45 1 0.97783800 0.68330800 0.09983000 1 - O O46 1 0.79453000 0.41652100 0.81669200 1 - O O47 1 0.87800900 0.97783800 0.79453000 1 - O O48 1 0.59983000 0.91652100 0.12199100 1 - O O49 1 0.18330800 0.47783800 0.59983000 1 - O O50 1 0.40017000 0.08347900 0.87800900 1 - O O51 1 0.81669200 0.52216200 0.40017000 1 - O O52 1 0.90017000 0.02216200 0.31669200 1 - O O53 1 0.37800900 0.58347900 0.90017000 1 - O O54 1 0.09983000 0.97783800 0.68330800 1 - O O55 1 0.62199100 0.41652100 0.09983000 1 - O O56 1 0.37800900 0.29453000 0.47783800 1 - O O57 1 0.58347900 0.90017000 0.37800900 1 - O O58 1 0.62199100 0.70547000 0.52216200 1 - O O59 1 0.41652100 0.09983000 0.62199100 1 - O O60 1 0.12199100 0.59983000 0.91652100 1 - O O61 1 0.02216200 0.20547000 0.12199100 1 - O O62 1 0.87800900 0.40017000 0.08347900 1 - O O63 1 0.97783800 0.79453000 0.87800900 1 - O O64 1 0.31669200 0.90017000 0.02216200 1 - O O65 1 0.91652100 0.29453000 0.31669200 1 - O O66 1 0.68330800 0.09983000 0.97783800 1 - O O67 1 0.08347900 0.70547000 0.68330800 1 - O O68 1 0.18330800 0.20547000 0.58347900 1 - O O69 1 0.47783800 0.59983000 0.18330800 1 - O O70 1 0.81669200 0.79453000 0.41652100 1 - O O71 1 0.52216200 0.40017000 0.81669200 1 - O O72 1 0.29453000 0.31669200 0.91652100 1 - O O73 1 0.70547000 0.68330800 0.08347900 1 - O O74 1 0.20547000 0.12199100 0.02216200 1 - O O75 1 0.79453000 0.87800900 0.97783800 1 - O O76 1 0.90017000 0.37800900 0.58347900 1 - O O77 1 0.09983000 0.62199100 0.41652100 1 - O O78 1 0.59983000 0.18330800 0.47783800 1 - O O79 1 0.40017000 0.81669200 0.52216200 1 -" -La3In2(GaO4)3,mp-1211871,Ia-3d,[],0.0,"{'tags': ['garnet family', 'La3Ga3In2O12']}","Full Formula (La12 In8 Ga12 O48) -Reduced Formula: La3In2(GaO4)3 -abc : 11.333655 11.333655 11.333655 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.25 0.375 0.125 0 - 1 La 0.75 0.625 0.875 0 - 2 La 0.75 0.125 0.375 0 - 3 La 0.125 0.25 0.375 0 - 4 La 0.375 0.75 0.125 0 - 5 La 0.25 0.875 0.625 0 - 6 La 0.875 0.75 0.625 0 - 7 La 0.625 0.25 0.875 0 - 8 La 0.375 0.125 0.25 0 - 9 La 0.625 0.875 0.75 0 - 10 La 0.125 0.375 0.75 0 - 11 La 0.875 0.625 0.25 0 - 12 In 0 0 0 -0 - 13 In 0.5 0 0.5 -0 - 14 In 0 0.5 0.5 -0 - 15 In 0.5 0 0 -0 - 16 In 0.5 0.5 0 -0 - 17 In 0.5 0.5 0.5 -0 - 18 In 0 0 0.5 -0 - 19 In 0 0.5 0 -0 - 20 Ga 0.25 0.625 0.375 0 - 21 Ga 0.75 0.375 0.625 0 - 22 Ga 0.75 0.875 0.125 0 - 23 Ga 0.375 0.25 0.625 0 - 24 Ga 0.625 0.75 0.375 -0 - 25 Ga 0.25 0.125 0.875 -0 - 26 Ga 0.125 0.75 0.875 0 - 27 Ga 0.875 0.25 0.125 0 - 28 Ga 0.625 0.375 0.25 -0 - 29 Ga 0.375 0.625 0.75 -0 - 30 Ga 0.875 0.125 0.75 0 - 31 Ga 0.125 0.875 0.25 0 - 32 O 0.47511 0.374976 0.2884 -0 - 33 O 0.52489 0.625024 0.7116 -0 - 34 O 0.586576 0.18671 0.2116 -0 - 35 O 0.913424 0.125024 0.600133 -0 - 36 O 0.2884 0.47511 0.374976 -0 - 37 O 0.31329 0.913424 0.2884 -0 - 38 O 0.413424 0.81329 0.7884 -0 - 39 O 0.086576 0.874976 0.399867 -0 - 40 O 0.7116 0.52489 0.625024 -0 - 41 O 0.68671 0.086576 0.7116 -0 - 42 O 0.02489 0.31329 0.899867 -0 - 43 O 0.2116 0.586576 0.18671 -0 - 44 O 0.125024 0.02489 0.2116 -0 - 45 O 0.97511 0.68671 0.100133 -0 - 46 O 0.7884 0.413424 0.81329 -0 - 47 O 0.874976 0.97511 0.7884 -0 - 48 O 0.600133 0.913424 0.125024 -0 - 49 O 0.18671 0.47511 0.600133 0 - 50 O 0.399867 0.086576 0.874976 -0 - 51 O 0.81329 0.52489 0.399867 -0 - 52 O 0.899867 0.02489 0.31329 -0 - 53 O 0.374976 0.586576 0.899867 -0 - 54 O 0.100133 0.97511 0.68671 -0 - 55 O 0.625024 0.413424 0.100133 -0 - 56 O 0.374976 0.2884 0.47511 -0 - 57 O 0.586576 0.899867 0.374976 -0 - 58 O 0.625024 0.7116 0.52489 -0 - 59 O 0.413424 0.100133 0.625024 -0 - 60 O 0.125024 0.600133 0.913424 -0 - 61 O 0.02489 0.2116 0.125024 -0 - 62 O 0.874976 0.399867 0.086576 -0 - 63 O 0.97511 0.7884 0.874976 -0 - 64 O 0.31329 0.899867 0.02489 -0 - 65 O 0.913424 0.2884 0.31329 -0 - 66 O 0.68671 0.100133 0.97511 -0 - 67 O 0.086576 0.7116 0.68671 -0 - 68 O 0.18671 0.2116 0.586576 -0 - 69 O 0.47511 0.600133 0.18671 -0 - 70 O 0.81329 0.7884 0.413424 -0 - 71 O 0.52489 0.399867 0.81329 -0 - 72 O 0.2884 0.31329 0.913424 -0 - 73 O 0.7116 0.68671 0.086576 -0 - 74 O 0.2116 0.125024 0.02489 -0 - 75 O 0.7884 0.874976 0.97511 -0 - 76 O 0.899867 0.374976 0.586576 0 - 77 O 0.100133 0.625024 0.413424 -0 - 78 O 0.600133 0.18671 0.47511 -0 - 79 O 0.399867 0.81329 0.52489 -0","# generated using pymatgen -data_La3In2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.33365541 -_cell_length_b 11.33365541 -_cell_length_c 11.33365541 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3In2(GaO4)3 -_chemical_formula_sum 'La12 In8 Ga12 O48' -_cell_volume 1120.69677287 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.25000000 0.37500000 0.12500000 1 - La La1 1 0.75000000 0.62500000 0.87500000 1 - La La2 1 0.75000000 0.12500000 0.37500000 1 - La La3 1 0.12500000 0.25000000 0.37500000 1 - La La4 1 0.37500000 0.75000000 0.12500000 1 - La La5 1 0.25000000 0.87500000 0.62500000 1 - La La6 1 0.87500000 0.75000000 0.62500000 1 - La La7 1 0.62500000 0.25000000 0.87500000 1 - La La8 1 0.37500000 0.12500000 0.25000000 1 - La La9 1 0.62500000 0.87500000 0.75000000 1 - La La10 1 0.12500000 0.37500000 0.75000000 1 - La La11 1 0.87500000 0.62500000 0.25000000 1 - In In12 1 0.00000000 0.00000000 0.00000000 1 - In In13 1 0.50000000 0.00000000 0.50000000 1 - In In14 1 0.00000000 0.50000000 0.50000000 1 - In In15 1 0.50000000 0.00000000 0.00000000 1 - In In16 1 0.50000000 0.50000000 0.00000000 1 - In In17 1 0.50000000 0.50000000 0.50000000 1 - In In18 1 0.00000000 0.00000000 0.50000000 1 - In In19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47511000 0.37497600 0.28840000 1 - O O33 1 0.52489000 0.62502400 0.71160000 1 - O O34 1 0.58657600 0.18671000 0.21160000 1 - O O35 1 0.91342400 0.12502400 0.60013300 1 - O O36 1 0.28840000 0.47511000 0.37497600 1 - O O37 1 0.31329000 0.91342400 0.28840000 1 - O O38 1 0.41342400 0.81329000 0.78840000 1 - O O39 1 0.08657600 0.87497600 0.39986700 1 - O O40 1 0.71160000 0.52489000 0.62502400 1 - O O41 1 0.68671000 0.08657600 0.71160000 1 - O O42 1 0.02489000 0.31329000 0.89986700 1 - O O43 1 0.21160000 0.58657600 0.18671000 1 - O O44 1 0.12502400 0.02489000 0.21160000 1 - O O45 1 0.97511000 0.68671000 0.10013300 1 - O O46 1 0.78840000 0.41342400 0.81329000 1 - O O47 1 0.87497600 0.97511000 0.78840000 1 - O O48 1 0.60013300 0.91342400 0.12502400 1 - O O49 1 0.18671000 0.47511000 0.60013300 1 - O O50 1 0.39986700 0.08657600 0.87497600 1 - O O51 1 0.81329000 0.52489000 0.39986700 1 - O O52 1 0.89986700 0.02489000 0.31329000 1 - O O53 1 0.37497600 0.58657600 0.89986700 1 - O O54 1 0.10013300 0.97511000 0.68671000 1 - O O55 1 0.62502400 0.41342400 0.10013300 1 - O O56 1 0.37497600 0.28840000 0.47511000 1 - O O57 1 0.58657600 0.89986700 0.37497600 1 - O O58 1 0.62502400 0.71160000 0.52489000 1 - O O59 1 0.41342400 0.10013300 0.62502400 1 - O O60 1 0.12502400 0.60013300 0.91342400 1 - O O61 1 0.02489000 0.21160000 0.12502400 1 - O O62 1 0.87497600 0.39986700 0.08657600 1 - O O63 1 0.97511000 0.78840000 0.87497600 1 - O O64 1 0.31329000 0.89986700 0.02489000 1 - O O65 1 0.91342400 0.28840000 0.31329000 1 - O O66 1 0.68671000 0.10013300 0.97511000 1 - O O67 1 0.08657600 0.71160000 0.68671000 1 - O O68 1 0.18671000 0.21160000 0.58657600 1 - O O69 1 0.47511000 0.60013300 0.18671000 1 - O O70 1 0.81329000 0.78840000 0.41342400 1 - O O71 1 0.52489000 0.39986700 0.81329000 1 - O O72 1 0.28840000 0.31329000 0.91342400 1 - O O73 1 0.71160000 0.68671000 0.08657600 1 - O O74 1 0.21160000 0.12502400 0.02489000 1 - O O75 1 0.78840000 0.87497600 0.97511000 1 - O O76 1 0.89986700 0.37497600 0.58657600 1 - O O77 1 0.10013300 0.62502400 0.41342400 1 - O O78 1 0.60013300 0.18671000 0.47511000 1 - O O79 1 0.39986700 0.81329000 0.52489000 1 -" -K3Cr2(AsO4)3,mp-1211915,Ia-3d,[],0.06160269181250033,{'tags': []},"Full Formula (K12 Cr8 As12 O48) -Reduced Formula: K3Cr2(AsO4)3 -abc : 11.095497 11.095497 11.095497 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 K 0.25 0.375 0.125 -0 - 1 K 0.75 0.625 0.875 -0 - 2 K 0.75 0.125 0.375 -0 - 3 K 0.125 0.25 0.375 -0 - 4 K 0.375 0.75 0.125 -0 - 5 K 0.25 0.875 0.625 -0 - 6 K 0.875 0.75 0.625 -0 - 7 K 0.625 0.25 0.875 -0 - 8 K 0.375 0.125 0.25 -0 - 9 K 0.625 0.875 0.75 -0 - 10 K 0.125 0.375 0.75 -0 - 11 K 0.875 0.625 0.25 -0 - 12 Cr 0 0 0 2.959 - 13 Cr 0.5 0 0.5 2.957 - 14 Cr 0 0.5 0.5 2.957 - 15 Cr 0.5 0 0 2.957 - 16 Cr 0.5 0.5 0 2.959 - 17 Cr 0.5 0.5 0.5 2.959 - 18 Cr 0 0 0.5 2.957 - 19 Cr 0 0.5 0 2.959 - 20 As 0.25 0.625 0.375 0.008 - 21 As 0.75 0.375 0.625 0.008 - 22 As 0.75 0.875 0.125 0.008 - 23 As 0.375 0.25 0.625 0.009 - 24 As 0.625 0.75 0.375 0.009 - 25 As 0.25 0.125 0.875 0.008 - 26 As 0.125 0.75 0.875 0.009 - 27 As 0.875 0.25 0.125 0.009 - 28 As 0.625 0.375 0.25 0.009 - 29 As 0.375 0.625 0.75 0.009 - 30 As 0.875 0.125 0.75 0.009 - 31 As 0.125 0.875 0.25 0.009 - 32 O 0.502412 0.395581 0.30788 -0.013 - 33 O 0.497588 0.604419 0.69212 -0.013 - 34 O 0.587701 0.194532 0.19212 -0.013 - 35 O 0.912299 0.104419 0.606831 -0.013 - 36 O 0.30788 0.502412 0.395581 -0.012 - 37 O 0.305468 0.912299 0.30788 -0.01 - 38 O 0.412299 0.805468 0.80788 -0.013 - 39 O 0.087701 0.895581 0.393169 -0.013 - 40 O 0.69212 0.497588 0.604419 -0.012 - 41 O 0.694532 0.087701 0.69212 -0.01 - 42 O 0.997588 0.305468 0.893169 -0.013 - 43 O 0.19212 0.587701 0.194532 -0.012 - 44 O 0.104419 0.997588 0.19212 -0.013 - 45 O 0.002412 0.694532 0.106831 -0.013 - 46 O 0.80788 0.412299 0.805468 -0.012 - 47 O 0.895581 0.002412 0.80788 -0.013 - 48 O 0.606831 0.912299 0.104419 -0.012 - 49 O 0.194532 0.502412 0.606831 -0.01 - 50 O 0.393169 0.087701 0.895581 -0.012 - 51 O 0.805468 0.497588 0.393169 -0.01 - 52 O 0.893169 0.997588 0.305468 -0.012 - 53 O 0.395581 0.587701 0.893169 -0.013 - 54 O 0.106831 0.002412 0.694532 -0.012 - 55 O 0.604419 0.412299 0.106831 -0.013 - 56 O 0.395581 0.30788 0.502412 -0.013 - 57 O 0.587701 0.893169 0.395581 -0.013 - 58 O 0.604419 0.69212 0.497588 -0.013 - 59 O 0.412299 0.106831 0.604419 -0.013 - 60 O 0.104419 0.606831 0.912299 -0.013 - 61 O 0.997588 0.19212 0.104419 -0.013 - 62 O 0.895581 0.393169 0.087701 -0.013 - 63 O 0.002412 0.80788 0.895581 -0.013 - 64 O 0.305468 0.893169 0.997588 -0.01 - 65 O 0.912299 0.30788 0.305468 -0.013 - 66 O 0.694532 0.106831 0.002412 -0.01 - 67 O 0.087701 0.69212 0.694532 -0.013 - 68 O 0.194532 0.19212 0.587701 -0.01 - 69 O 0.502412 0.606831 0.194532 -0.013 - 70 O 0.805468 0.80788 0.412299 -0.01 - 71 O 0.497588 0.393169 0.805468 -0.013 - 72 O 0.30788 0.305468 0.912299 -0.012 - 73 O 0.69212 0.694532 0.087701 -0.012 - 74 O 0.19212 0.104419 0.997588 -0.012 - 75 O 0.80788 0.895581 0.002412 -0.012 - 76 O 0.893169 0.395581 0.587701 -0.012 - 77 O 0.106831 0.604419 0.412299 -0.012 - 78 O 0.606831 0.194532 0.502412 -0.012 - 79 O 0.393169 0.805468 0.497588 -0.012","# generated using pymatgen -data_K3Cr2(AsO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.09549669 -_cell_length_b 11.09549669 -_cell_length_c 11.09549669 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural K3Cr2(AsO4)3 -_chemical_formula_sum 'K12 Cr8 As12 O48' -_cell_volume 1051.52197637 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - K K0 1 0.25000000 0.37500000 0.12500000 1 - K K1 1 0.75000000 0.62500000 0.87500000 1 - K K2 1 0.75000000 0.12500000 0.37500000 1 - K K3 1 0.12500000 0.25000000 0.37500000 1 - K K4 1 0.37500000 0.75000000 0.12500000 1 - K K5 1 0.25000000 0.87500000 0.62500000 1 - K K6 1 0.87500000 0.75000000 0.62500000 1 - K K7 1 0.62500000 0.25000000 0.87500000 1 - K K8 1 0.37500000 0.12500000 0.25000000 1 - K K9 1 0.62500000 0.87500000 0.75000000 1 - K K10 1 0.12500000 0.37500000 0.75000000 1 - K K11 1 0.87500000 0.62500000 0.25000000 1 - Cr Cr12 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr13 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr16 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr17 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr18 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.50000000 0.00000000 1 - As As20 1 0.25000000 0.62500000 0.37500000 1 - As As21 1 0.75000000 0.37500000 0.62500000 1 - As As22 1 0.75000000 0.87500000 0.12500000 1 - As As23 1 0.37500000 0.25000000 0.62500000 1 - As As24 1 0.62500000 0.75000000 0.37500000 1 - As As25 1 0.25000000 0.12500000 0.87500000 1 - As As26 1 0.12500000 0.75000000 0.87500000 1 - As As27 1 0.87500000 0.25000000 0.12500000 1 - As As28 1 0.62500000 0.37500000 0.25000000 1 - As As29 1 0.37500000 0.62500000 0.75000000 1 - As As30 1 0.87500000 0.12500000 0.75000000 1 - As As31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.50241200 0.39558100 0.30788000 1 - O O33 1 0.49758800 0.60441900 0.69212000 1 - O O34 1 0.58770100 0.19453200 0.19212000 1 - O O35 1 0.91229900 0.10441900 0.60683100 1 - O O36 1 0.30788000 0.50241200 0.39558100 1 - O O37 1 0.30546800 0.91229900 0.30788000 1 - O O38 1 0.41229900 0.80546800 0.80788000 1 - O O39 1 0.08770100 0.89558100 0.39316900 1 - O O40 1 0.69212000 0.49758800 0.60441900 1 - O O41 1 0.69453200 0.08770100 0.69212000 1 - O O42 1 0.99758800 0.30546800 0.89316900 1 - O O43 1 0.19212000 0.58770100 0.19453200 1 - O O44 1 0.10441900 0.99758800 0.19212000 1 - O O45 1 0.00241200 0.69453200 0.10683100 1 - O O46 1 0.80788000 0.41229900 0.80546800 1 - O O47 1 0.89558100 0.00241200 0.80788000 1 - O O48 1 0.60683100 0.91229900 0.10441900 1 - O O49 1 0.19453200 0.50241200 0.60683100 1 - O O50 1 0.39316900 0.08770100 0.89558100 1 - O O51 1 0.80546800 0.49758800 0.39316900 1 - O O52 1 0.89316900 0.99758800 0.30546800 1 - O O53 1 0.39558100 0.58770100 0.89316900 1 - O O54 1 0.10683100 0.00241200 0.69453200 1 - O O55 1 0.60441900 0.41229900 0.10683100 1 - O O56 1 0.39558100 0.30788000 0.50241200 1 - O O57 1 0.58770100 0.89316900 0.39558100 1 - O O58 1 0.60441900 0.69212000 0.49758800 1 - O O59 1 0.41229900 0.10683100 0.60441900 1 - O O60 1 0.10441900 0.60683100 0.91229900 1 - O O61 1 0.99758800 0.19212000 0.10441900 1 - O O62 1 0.89558100 0.39316900 0.08770100 1 - O O63 1 0.00241200 0.80788000 0.89558100 1 - O O64 1 0.30546800 0.89316900 0.99758800 1 - O O65 1 0.91229900 0.30788000 0.30546800 1 - O O66 1 0.69453200 0.10683100 0.00241200 1 - O O67 1 0.08770100 0.69212000 0.69453200 1 - O O68 1 0.19453200 0.19212000 0.58770100 1 - O O69 1 0.50241200 0.60683100 0.19453200 1 - O O70 1 0.80546800 0.80788000 0.41229900 1 - O O71 1 0.49758800 0.39316900 0.80546800 1 - O O72 1 0.30788000 0.30546800 0.91229900 1 - O O73 1 0.69212000 0.69453200 0.08770100 1 - O O74 1 0.19212000 0.10441900 0.99758800 1 - O O75 1 0.80788000 0.89558100 0.00241200 1 - O O76 1 0.89316900 0.39558100 0.58770100 1 - O O77 1 0.10683100 0.60441900 0.41229900 1 - O O78 1 0.60683100 0.19453200 0.50241200 1 - O O79 1 0.39316900 0.80546800 0.49758800 1 -" -La3Yb2(GaO4)3,mp-1211944,Ia-3d,[],0.02192342398214464,{'tags': []},"Full Formula (La12 Yb8 Ga12 O48) -Reduced Formula: La3Yb2(GaO4)3 -abc : 11.427664 11.427664 11.427664 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.25 0.375 0.125 0.001 - 1 La 0.75 0.625 0.875 0.001 - 2 La 0.75 0.125 0.375 -0.007 - 3 La 0.125 0.25 0.375 -0.002 - 4 La 0.375 0.75 0.125 -0.002 - 5 La 0.25 0.875 0.625 -0.007 - 6 La 0.875 0.75 0.625 -0.002 - 7 La 0.625 0.25 0.875 -0.002 - 8 La 0.375 0.125 0.25 -0.002 - 9 La 0.625 0.875 0.75 -0.002 - 10 La 0.125 0.375 0.75 -0.002 - 11 La 0.875 0.625 0.25 -0.002 - 12 Yb 0 0 0 0.007 - 13 Yb 0.5 0 0.5 0.05 - 14 Yb 0 0.5 0.5 0.05 - 15 Yb 0.5 0 0 0.05 - 16 Yb 0.5 0.5 0 0.007 - 17 Yb 0.5 0.5 0.5 0.007 - 18 Yb 0 0 0.5 0.05 - 19 Yb 0 0.5 0 0.007 - 20 Ga 0.25 0.625 0.375 -0.005 - 21 Ga 0.75 0.375 0.625 -0.005 - 22 Ga 0.75 0.875 0.125 -0.005 - 23 Ga 0.375 0.25 0.625 -0.005 - 24 Ga 0.625 0.75 0.375 -0.005 - 25 Ga 0.25 0.125 0.875 -0.005 - 26 Ga 0.125 0.75 0.875 -0.005 - 27 Ga 0.875 0.25 0.125 -0.005 - 28 Ga 0.625 0.375 0.25 -0.005 - 29 Ga 0.375 0.625 0.75 -0.005 - 30 Ga 0.875 0.125 0.75 -0.005 - 31 Ga 0.125 0.875 0.25 -0.005 - 32 O 0.471401 0.371671 0.279845 0.124 - 33 O 0.528599 0.628329 0.720155 0.124 - 34 O 0.591826 0.191556 0.220155 0.164 - 35 O 0.908174 0.128329 0.59973 0.164 - 36 O 0.279845 0.471401 0.371671 0.123 - 37 O 0.308444 0.908174 0.279845 0.183 - 38 O 0.408174 0.808444 0.779845 0.164 - 39 O 0.091826 0.871671 0.40027 0.164 - 40 O 0.720155 0.528599 0.628329 0.123 - 41 O 0.691556 0.091826 0.720155 0.183 - 42 O 0.028599 0.308444 0.90027 0.124 - 43 O 0.220155 0.591826 0.191556 0.123 - 44 O 0.128329 0.028599 0.220155 0.096 - 45 O 0.971401 0.691556 0.09973 0.124 - 46 O 0.779845 0.408174 0.808444 0.123 - 47 O 0.871671 0.971401 0.779845 0.096 - 48 O 0.59973 0.908174 0.128329 0.154 - 49 O 0.191556 0.471401 0.59973 0.183 - 50 O 0.40027 0.091826 0.871671 0.154 - 51 O 0.808444 0.528599 0.40027 0.183 - 52 O 0.90027 0.028599 0.308444 0.154 - 53 O 0.371671 0.591826 0.90027 0.096 - 54 O 0.09973 0.971401 0.691556 0.154 - 55 O 0.628329 0.408174 0.09973 0.096 - 56 O 0.371671 0.279845 0.471401 0.096 - 57 O 0.591826 0.90027 0.371671 0.164 - 58 O 0.628329 0.720155 0.528599 0.096 - 59 O 0.408174 0.09973 0.628329 0.164 - 60 O 0.128329 0.59973 0.908174 0.096 - 61 O 0.028599 0.220155 0.128329 0.124 - 62 O 0.871671 0.40027 0.091826 0.096 - 63 O 0.971401 0.779845 0.871671 0.124 - 64 O 0.308444 0.90027 0.028599 0.183 - 65 O 0.908174 0.279845 0.308444 0.164 - 66 O 0.691556 0.09973 0.971401 0.183 - 67 O 0.091826 0.720155 0.691556 0.164 - 68 O 0.191556 0.220155 0.591826 0.183 - 69 O 0.471401 0.59973 0.191556 0.124 - 70 O 0.808444 0.779845 0.408174 0.183 - 71 O 0.528599 0.40027 0.808444 0.124 - 72 O 0.279845 0.308444 0.908174 0.123 - 73 O 0.720155 0.691556 0.091826 0.123 - 74 O 0.220155 0.128329 0.028599 0.123 - 75 O 0.779845 0.871671 0.971401 0.123 - 76 O 0.90027 0.371671 0.591826 0.154 - 77 O 0.09973 0.628329 0.408174 0.154 - 78 O 0.59973 0.191556 0.471401 0.154 - 79 O 0.40027 0.808444 0.528599 0.154","# generated using pymatgen -data_La3Yb2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.42766420 -_cell_length_b 11.42766420 -_cell_length_c 11.42766420 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3Yb2(GaO4)3 -_chemical_formula_sum 'La12 Yb8 Ga12 O48' -_cell_volume 1148.81611638 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.25000000 0.37500000 0.12500000 1 - La La1 1 0.75000000 0.62500000 0.87500000 1 - La La2 1 0.75000000 0.12500000 0.37500000 1 - La La3 1 0.12500000 0.25000000 0.37500000 1 - La La4 1 0.37500000 0.75000000 0.12500000 1 - La La5 1 0.25000000 0.87500000 0.62500000 1 - La La6 1 0.87500000 0.75000000 0.62500000 1 - La La7 1 0.62500000 0.25000000 0.87500000 1 - La La8 1 0.37500000 0.12500000 0.25000000 1 - La La9 1 0.62500000 0.87500000 0.75000000 1 - La La10 1 0.12500000 0.37500000 0.75000000 1 - La La11 1 0.87500000 0.62500000 0.25000000 1 - Yb Yb12 1 0.00000000 0.00000000 0.00000000 1 - Yb Yb13 1 0.50000000 0.00000000 0.50000000 1 - Yb Yb14 1 0.00000000 0.50000000 0.50000000 1 - Yb Yb15 1 0.50000000 0.00000000 0.00000000 1 - Yb Yb16 1 0.50000000 0.50000000 0.00000000 1 - Yb Yb17 1 0.50000000 0.50000000 0.50000000 1 - Yb Yb18 1 0.00000000 0.00000000 0.50000000 1 - Yb Yb19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47140100 0.37167100 0.27984500 1 - O O33 1 0.52859900 0.62832900 0.72015500 1 - O O34 1 0.59182600 0.19155600 0.22015500 1 - O O35 1 0.90817400 0.12832900 0.59973000 1 - O O36 1 0.27984500 0.47140100 0.37167100 1 - O O37 1 0.30844400 0.90817400 0.27984500 1 - O O38 1 0.40817400 0.80844400 0.77984500 1 - O O39 1 0.09182600 0.87167100 0.40027000 1 - O O40 1 0.72015500 0.52859900 0.62832900 1 - O O41 1 0.69155600 0.09182600 0.72015500 1 - O O42 1 0.02859900 0.30844400 0.90027000 1 - O O43 1 0.22015500 0.59182600 0.19155600 1 - O O44 1 0.12832900 0.02859900 0.22015500 1 - O O45 1 0.97140100 0.69155600 0.09973000 1 - O O46 1 0.77984500 0.40817400 0.80844400 1 - O O47 1 0.87167100 0.97140100 0.77984500 1 - O O48 1 0.59973000 0.90817400 0.12832900 1 - O O49 1 0.19155600 0.47140100 0.59973000 1 - O O50 1 0.40027000 0.09182600 0.87167100 1 - O O51 1 0.80844400 0.52859900 0.40027000 1 - O O52 1 0.90027000 0.02859900 0.30844400 1 - O O53 1 0.37167100 0.59182600 0.90027000 1 - O O54 1 0.09973000 0.97140100 0.69155600 1 - O O55 1 0.62832900 0.40817400 0.09973000 1 - O O56 1 0.37167100 0.27984500 0.47140100 1 - O O57 1 0.59182600 0.90027000 0.37167100 1 - O O58 1 0.62832900 0.72015500 0.52859900 1 - O O59 1 0.40817400 0.09973000 0.62832900 1 - O O60 1 0.12832900 0.59973000 0.90817400 1 - O O61 1 0.02859900 0.22015500 0.12832900 1 - O O62 1 0.87167100 0.40027000 0.09182600 1 - O O63 1 0.97140100 0.77984500 0.87167100 1 - O O64 1 0.30844400 0.90027000 0.02859900 1 - O O65 1 0.90817400 0.27984500 0.30844400 1 - O O66 1 0.69155600 0.09973000 0.97140100 1 - O O67 1 0.09182600 0.72015500 0.69155600 1 - O O68 1 0.19155600 0.22015500 0.59182600 1 - O O69 1 0.47140100 0.59973000 0.19155600 1 - O O70 1 0.80844400 0.77984500 0.40817400 1 - O O71 1 0.52859900 0.40027000 0.80844400 1 - O O72 1 0.27984500 0.30844400 0.90817400 1 - O O73 1 0.72015500 0.69155600 0.09182600 1 - O O74 1 0.22015500 0.12832900 0.02859900 1 - O O75 1 0.77984500 0.87167100 0.97140100 1 - O O76 1 0.90027000 0.37167100 0.59182600 1 - O O77 1 0.09973000 0.62832900 0.40817400 1 - O O78 1 0.59973000 0.19155600 0.47140100 1 - O O79 1 0.40027000 0.80844400 0.52859900 1 -" -La3Tm2(GaO4)3,mp-1212025,Ia-3d,[],0.0,{'tags': []},"Full Formula (La12 Tm8 Ga12 O48) -Reduced Formula: La3Tm2(GaO4)3 -abc : 11.403776 11.403776 11.403776 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.25 0.375 0.125 -0 - 1 La 0.75 0.625 0.875 -0 - 2 La 0.75 0.125 0.375 -0 - 3 La 0.125 0.25 0.375 -0 - 4 La 0.375 0.75 0.125 -0 - 5 La 0.25 0.875 0.625 -0 - 6 La 0.875 0.75 0.625 -0 - 7 La 0.625 0.25 0.875 -0 - 8 La 0.375 0.125 0.25 -0 - 9 La 0.625 0.875 0.75 -0 - 10 La 0.125 0.375 0.75 -0 - 11 La 0.875 0.625 0.25 -0 - 12 Tm 0 0 0 0 - 13 Tm 0.5 0 0.5 0 - 14 Tm 0 0.5 0.5 0 - 15 Tm 0.5 0 0 0 - 16 Tm 0.5 0.5 0 0 - 17 Tm 0.5 0.5 0.5 0 - 18 Tm 0 0 0.5 0 - 19 Tm 0 0.5 0 0 - 20 Ga 0.25 0.625 0.375 -0 - 21 Ga 0.75 0.375 0.625 0 - 22 Ga 0.75 0.875 0.125 0 - 23 Ga 0.375 0.25 0.625 0 - 24 Ga 0.625 0.75 0.375 -0 - 25 Ga 0.25 0.125 0.875 0 - 26 Ga 0.125 0.75 0.875 0 - 27 Ga 0.875 0.25 0.125 0 - 28 Ga 0.625 0.375 0.25 0 - 29 Ga 0.375 0.625 0.75 0 - 30 Ga 0.875 0.125 0.75 0 - 31 Ga 0.125 0.875 0.25 0 - 32 O 0.47557 0.37399 0.28815 -0 - 33 O 0.52443 0.62601 0.71185 -0 - 34 O 0.58584 0.187421 0.21185 -0 - 35 O 0.91416 0.12601 0.601581 -0 - 36 O 0.28815 0.47557 0.37399 -0 - 37 O 0.312579 0.91416 0.28815 -0 - 38 O 0.41416 0.812579 0.78815 -0 - 39 O 0.08584 0.87399 0.398419 -0 - 40 O 0.71185 0.52443 0.62601 -0 - 41 O 0.687421 0.08584 0.71185 -0 - 42 O 0.02443 0.312579 0.898419 -0 - 43 O 0.21185 0.58584 0.187421 -0 - 44 O 0.12601 0.02443 0.21185 -0 - 45 O 0.97557 0.687421 0.101581 -0 - 46 O 0.78815 0.41416 0.812579 -0 - 47 O 0.87399 0.97557 0.78815 -0 - 48 O 0.601581 0.91416 0.12601 -0 - 49 O 0.187421 0.47557 0.601581 -0 - 50 O 0.398419 0.08584 0.87399 -0 - 51 O 0.812579 0.52443 0.398419 -0 - 52 O 0.898419 0.02443 0.312579 -0 - 53 O 0.37399 0.58584 0.898419 -0 - 54 O 0.101581 0.97557 0.687421 -0 - 55 O 0.62601 0.41416 0.101581 -0 - 56 O 0.37399 0.28815 0.47557 -0 - 57 O 0.58584 0.898419 0.37399 -0 - 58 O 0.62601 0.71185 0.52443 -0 - 59 O 0.41416 0.101581 0.62601 -0 - 60 O 0.12601 0.601581 0.91416 -0 - 61 O 0.02443 0.21185 0.12601 -0 - 62 O 0.87399 0.398419 0.08584 -0 - 63 O 0.97557 0.78815 0.87399 -0 - 64 O 0.312579 0.898419 0.02443 -0 - 65 O 0.91416 0.28815 0.312579 -0 - 66 O 0.687421 0.101581 0.97557 -0 - 67 O 0.08584 0.71185 0.687421 -0 - 68 O 0.187421 0.21185 0.58584 -0 - 69 O 0.47557 0.601581 0.187421 -0 - 70 O 0.812579 0.78815 0.41416 -0 - 71 O 0.52443 0.398419 0.812579 -0 - 72 O 0.28815 0.312579 0.91416 -0 - 73 O 0.71185 0.687421 0.08584 -0 - 74 O 0.21185 0.12601 0.02443 -0 - 75 O 0.78815 0.87399 0.97557 -0 - 76 O 0.898419 0.37399 0.58584 -0 - 77 O 0.101581 0.62601 0.41416 -0 - 78 O 0.601581 0.187421 0.47557 -0 - 79 O 0.398419 0.812579 0.52443 -0","# generated using pymatgen -data_La3Tm2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.40377575 -_cell_length_b 11.40377575 -_cell_length_c 11.40377575 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3Tm2(GaO4)3 -_chemical_formula_sum 'La12 Tm8 Ga12 O48' -_cell_volume 1141.62669378 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.25000000 0.37500000 0.12500000 1 - La La1 1 0.75000000 0.62500000 0.87500000 1 - La La2 1 0.75000000 0.12500000 0.37500000 1 - La La3 1 0.12500000 0.25000000 0.37500000 1 - La La4 1 0.37500000 0.75000000 0.12500000 1 - La La5 1 0.25000000 0.87500000 0.62500000 1 - La La6 1 0.87500000 0.75000000 0.62500000 1 - La La7 1 0.62500000 0.25000000 0.87500000 1 - La La8 1 0.37500000 0.12500000 0.25000000 1 - La La9 1 0.62500000 0.87500000 0.75000000 1 - La La10 1 0.12500000 0.37500000 0.75000000 1 - La La11 1 0.87500000 0.62500000 0.25000000 1 - Tm Tm12 1 0.00000000 0.00000000 0.00000000 1 - Tm Tm13 1 0.50000000 0.00000000 0.50000000 1 - Tm Tm14 1 0.00000000 0.50000000 0.50000000 1 - Tm Tm15 1 0.50000000 0.00000000 0.00000000 1 - Tm Tm16 1 0.50000000 0.50000000 0.00000000 1 - Tm Tm17 1 0.50000000 0.50000000 0.50000000 1 - Tm Tm18 1 0.00000000 0.00000000 0.50000000 1 - Tm Tm19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47557000 0.37399000 0.28815000 1 - O O33 1 0.52443000 0.62601000 0.71185000 1 - O O34 1 0.58584000 0.18742100 0.21185000 1 - O O35 1 0.91416000 0.12601000 0.60158100 1 - O O36 1 0.28815000 0.47557000 0.37399000 1 - O O37 1 0.31257900 0.91416000 0.28815000 1 - O O38 1 0.41416000 0.81257900 0.78815000 1 - O O39 1 0.08584000 0.87399000 0.39841900 1 - O O40 1 0.71185000 0.52443000 0.62601000 1 - O O41 1 0.68742100 0.08584000 0.71185000 1 - O O42 1 0.02443000 0.31257900 0.89841900 1 - O O43 1 0.21185000 0.58584000 0.18742100 1 - O O44 1 0.12601000 0.02443000 0.21185000 1 - O O45 1 0.97557000 0.68742100 0.10158100 1 - O O46 1 0.78815000 0.41416000 0.81257900 1 - O O47 1 0.87399000 0.97557000 0.78815000 1 - O O48 1 0.60158100 0.91416000 0.12601000 1 - O O49 1 0.18742100 0.47557000 0.60158100 1 - O O50 1 0.39841900 0.08584000 0.87399000 1 - O O51 1 0.81257900 0.52443000 0.39841900 1 - O O52 1 0.89841900 0.02443000 0.31257900 1 - O O53 1 0.37399000 0.58584000 0.89841900 1 - O O54 1 0.10158100 0.97557000 0.68742100 1 - O O55 1 0.62601000 0.41416000 0.10158100 1 - O O56 1 0.37399000 0.28815000 0.47557000 1 - O O57 1 0.58584000 0.89841900 0.37399000 1 - O O58 1 0.62601000 0.71185000 0.52443000 1 - O O59 1 0.41416000 0.10158100 0.62601000 1 - O O60 1 0.12601000 0.60158100 0.91416000 1 - O O61 1 0.02443000 0.21185000 0.12601000 1 - O O62 1 0.87399000 0.39841900 0.08584000 1 - O O63 1 0.97557000 0.78815000 0.87399000 1 - O O64 1 0.31257900 0.89841900 0.02443000 1 - O O65 1 0.91416000 0.28815000 0.31257900 1 - O O66 1 0.68742100 0.10158100 0.97557000 1 - O O67 1 0.08584000 0.71185000 0.68742100 1 - O O68 1 0.18742100 0.21185000 0.58584000 1 - O O69 1 0.47557000 0.60158100 0.18742100 1 - O O70 1 0.81257900 0.78815000 0.41416000 1 - O O71 1 0.52443000 0.39841900 0.81257900 1 - O O72 1 0.28815000 0.31257900 0.91416000 1 - O O73 1 0.71185000 0.68742100 0.08584000 1 - O O74 1 0.21185000 0.12601000 0.02443000 1 - O O75 1 0.78815000 0.87399000 0.97557000 1 - O O76 1 0.89841900 0.37399000 0.58584000 1 - O O77 1 0.10158100 0.62601000 0.41416000 1 - O O78 1 0.60158100 0.18742100 0.47557000 1 - O O79 1 0.39841900 0.81257900 0.52443000 1 -" -Mn2Cd3(GeO4)3,mp-1212395,Ia-3d,[],0.043602613718755734,{'tags': ['garnet family']},"Full Formula (Mn8 Cd12 Ge12 O48) -Reduced Formula: Mn2Cd3(GeO4)3 -abc : 10.852445 10.852445 10.852445 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0 0 0 4.07 - 1 Mn 0.5 0 0.5 4.062 - 2 Mn 0 0.5 0.5 4.062 - 3 Mn 0.5 0 0 4.062 - 4 Mn 0.5 0.5 0 4.07 - 5 Mn 0.5 0.5 0.5 4.07 - 6 Mn 0 0 0.5 4.062 - 7 Mn 0 0.5 0 4.07 - 8 Cd 0.25 0.375 0.125 0.009 - 9 Cd 0.75 0.625 0.875 0.009 - 10 Cd 0.75 0.125 0.375 0.009 - 11 Cd 0.125 0.25 0.375 0.008 - 12 Cd 0.375 0.75 0.125 0.008 - 13 Cd 0.25 0.875 0.625 0.009 - 14 Cd 0.875 0.75 0.625 0.008 - 15 Cd 0.625 0.25 0.875 0.008 - 16 Cd 0.375 0.125 0.25 0.008 - 17 Cd 0.625 0.875 0.75 0.008 - 18 Cd 0.125 0.375 0.75 0.008 - 19 Cd 0.875 0.625 0.25 0.008 - 20 Ge 0.25 0.625 0.375 0.024 - 21 Ge 0.75 0.375 0.625 0.024 - 22 Ge 0.75 0.875 0.125 0.024 - 23 Ge 0.375 0.25 0.625 0.022 - 24 Ge 0.625 0.75 0.375 0.022 - 25 Ge 0.25 0.125 0.875 0.024 - 26 Ge 0.125 0.75 0.875 0.022 - 27 Ge 0.875 0.25 0.125 0.022 - 28 Ge 0.625 0.375 0.25 0.022 - 29 Ge 0.375 0.625 0.75 0.022 - 30 Ge 0.875 0.125 0.75 0.022 - 31 Ge 0.125 0.875 0.25 0.022 - 32 O 0.483055 0.378757 0.297928 -0.037 - 33 O 0.516945 0.621243 0.702072 -0.037 - 34 O 0.580829 0.185127 0.202072 -0.042 - 35 O 0.919171 0.121243 0.604298 -0.042 - 36 O 0.297928 0.483055 0.378757 -0.024 - 37 O 0.314873 0.919171 0.297928 -0.042 - 38 O 0.419171 0.814873 0.797928 -0.042 - 39 O 0.080829 0.878757 0.395702 -0.042 - 40 O 0.702072 0.516945 0.621243 -0.024 - 41 O 0.685127 0.080829 0.702072 -0.042 - 42 O 0.016945 0.314873 0.895702 -0.037 - 43 O 0.202072 0.580829 0.185127 -0.024 - 44 O 0.121243 0.016945 0.202072 -0.04 - 45 O 0.983055 0.685127 0.104298 -0.037 - 46 O 0.797928 0.419171 0.814873 -0.024 - 47 O 0.878757 0.983055 0.797928 -0.04 - 48 O 0.604298 0.919171 0.121243 -0.038 - 49 O 0.185127 0.483055 0.604298 -0.042 - 50 O 0.395702 0.080829 0.878757 -0.038 - 51 O 0.814873 0.516945 0.395702 -0.042 - 52 O 0.895702 0.016945 0.314873 -0.038 - 53 O 0.378757 0.580829 0.895702 -0.04 - 54 O 0.104298 0.983055 0.685127 -0.038 - 55 O 0.621243 0.419171 0.104298 -0.04 - 56 O 0.378757 0.297928 0.483055 -0.04 - 57 O 0.580829 0.895702 0.378757 -0.042 - 58 O 0.621243 0.702072 0.516945 -0.04 - 59 O 0.419171 0.104298 0.621243 -0.042 - 60 O 0.121243 0.604298 0.919171 -0.04 - 61 O 0.016945 0.202072 0.121243 -0.037 - 62 O 0.878757 0.395702 0.080829 -0.04 - 63 O 0.983055 0.797928 0.878757 -0.037 - 64 O 0.314873 0.895702 0.016945 -0.042 - 65 O 0.919171 0.297928 0.314873 -0.042 - 66 O 0.685127 0.104298 0.983055 -0.042 - 67 O 0.080829 0.702072 0.685127 -0.042 - 68 O 0.185127 0.202072 0.580829 -0.042 - 69 O 0.483055 0.604298 0.185127 -0.037 - 70 O 0.814873 0.797928 0.419171 -0.042 - 71 O 0.516945 0.395702 0.814873 -0.037 - 72 O 0.297928 0.314873 0.919171 -0.024 - 73 O 0.702072 0.685127 0.080829 -0.024 - 74 O 0.202072 0.121243 0.016945 -0.024 - 75 O 0.797928 0.878757 0.983055 -0.024 - 76 O 0.895702 0.378757 0.580829 -0.038 - 77 O 0.104298 0.621243 0.419171 -0.038 - 78 O 0.604298 0.185127 0.483055 -0.038 - 79 O 0.395702 0.814873 0.516945 -0.038","# generated using pymatgen -data_Mn2Cd3(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.85244493 -_cell_length_b 10.85244493 -_cell_length_c 10.85244493 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn2Cd3(GeO4)3 -_chemical_formula_sum 'Mn8 Cd12 Ge12 O48' -_cell_volume 983.92247524 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn1 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn2 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn3 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn4 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn5 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn6 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn7 1 0.00000000 0.50000000 0.00000000 1 - Cd Cd8 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd9 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd10 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd11 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd12 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd13 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd14 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd15 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd16 1 0.37500000 0.12500000 0.25000000 1 - Cd Cd17 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd18 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd19 1 0.87500000 0.62500000 0.25000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48305500 0.37875700 0.29792800 1 - O O33 1 0.51694500 0.62124300 0.70207200 1 - O O34 1 0.58082900 0.18512700 0.20207200 1 - O O35 1 0.91917100 0.12124300 0.60429800 1 - O O36 1 0.29792800 0.48305500 0.37875700 1 - O O37 1 0.31487300 0.91917100 0.29792800 1 - O O38 1 0.41917100 0.81487300 0.79792800 1 - O O39 1 0.08082900 0.87875700 0.39570200 1 - O O40 1 0.70207200 0.51694500 0.62124300 1 - O O41 1 0.68512700 0.08082900 0.70207200 1 - O O42 1 0.01694500 0.31487300 0.89570200 1 - O O43 1 0.20207200 0.58082900 0.18512700 1 - O O44 1 0.12124300 0.01694500 0.20207200 1 - O O45 1 0.98305500 0.68512700 0.10429800 1 - O O46 1 0.79792800 0.41917100 0.81487300 1 - O O47 1 0.87875700 0.98305500 0.79792800 1 - O O48 1 0.60429800 0.91917100 0.12124300 1 - O O49 1 0.18512700 0.48305500 0.60429800 1 - O O50 1 0.39570200 0.08082900 0.87875700 1 - O O51 1 0.81487300 0.51694500 0.39570200 1 - O O52 1 0.89570200 0.01694500 0.31487300 1 - O O53 1 0.37875700 0.58082900 0.89570200 1 - O O54 1 0.10429800 0.98305500 0.68512700 1 - O O55 1 0.62124300 0.41917100 0.10429800 1 - O O56 1 0.37875700 0.29792800 0.48305500 1 - O O57 1 0.58082900 0.89570200 0.37875700 1 - O O58 1 0.62124300 0.70207200 0.51694500 1 - O O59 1 0.41917100 0.10429800 0.62124300 1 - O O60 1 0.12124300 0.60429800 0.91917100 1 - O O61 1 0.01694500 0.20207200 0.12124300 1 - O O62 1 0.87875700 0.39570200 0.08082900 1 - O O63 1 0.98305500 0.79792800 0.87875700 1 - O O64 1 0.31487300 0.89570200 0.01694500 1 - O O65 1 0.91917100 0.29792800 0.31487300 1 - O O66 1 0.68512700 0.10429800 0.98305500 1 - O O67 1 0.08082900 0.70207200 0.68512700 1 - O O68 1 0.18512700 0.20207200 0.58082900 1 - O O69 1 0.48305500 0.60429800 0.18512700 1 - O O70 1 0.81487300 0.79792800 0.41917100 1 - O O71 1 0.51694500 0.39570200 0.81487300 1 - O O72 1 0.29792800 0.31487300 0.91917100 1 - O O73 1 0.70207200 0.68512700 0.08082900 1 - O O74 1 0.20207200 0.12124300 0.01694500 1 - O O75 1 0.79792800 0.87875700 0.98305500 1 - O O76 1 0.89570200 0.37875700 0.58082900 1 - O O77 1 0.10429800 0.62124300 0.41917100 1 - O O78 1 0.60429800 0.18512700 0.48305500 1 - O O79 1 0.39570200 0.81487300 0.51694500 1 -" -Ho3Sc2Al3O12,mp-1212436,Ia-3d,[],0.0,{'tags': []},"Full Formula (Ho12 Sc8 Al12 O48) -Reduced Formula: Ho3Sc2Al3O12 -abc : 10.772592 10.772592 10.772592 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ho 0.25 0.375 0.125 0 - 1 Ho 0.75 0.625 0.875 0 - 2 Ho 0.75 0.125 0.375 0 - 3 Ho 0.125 0.25 0.375 0 - 4 Ho 0.375 0.75 0.125 0 - 5 Ho 0.25 0.875 0.625 0 - 6 Ho 0.875 0.75 0.625 0 - 7 Ho 0.625 0.25 0.875 0 - 8 Ho 0.375 0.125 0.25 0 - 9 Ho 0.625 0.875 0.75 0 - 10 Ho 0.125 0.375 0.75 0 - 11 Ho 0.875 0.625 0.25 0 - 12 Sc 0 0 0 0 - 13 Sc 0.5 0 0.5 0 - 14 Sc 0 0.5 0.5 0 - 15 Sc 0.5 0 0 0 - 16 Sc 0.5 0.5 0 0 - 17 Sc 0.5 0.5 0.5 0 - 18 Sc 0 0 0.5 0 - 19 Sc 0 0.5 0 0 - 20 Al 0.25 0.625 0.375 0 - 21 Al 0.75 0.375 0.625 0 - 22 Al 0.75 0.875 0.125 0 - 23 Al 0.375 0.25 0.625 0 - 24 Al 0.625 0.75 0.375 0 - 25 Al 0.25 0.125 0.875 0 - 26 Al 0.125 0.75 0.875 0 - 27 Al 0.875 0.25 0.125 0 - 28 Al 0.625 0.375 0.25 0 - 29 Al 0.375 0.625 0.75 0 - 30 Al 0.875 0.125 0.75 0 - 31 Al 0.125 0.875 0.25 0 - 32 O 0.474271 0.373788 0.286443 -0 - 33 O 0.525729 0.626212 0.713557 -0 - 34 O 0.587345 0.187827 0.213557 -0 - 35 O 0.912655 0.126212 0.600483 -0 - 36 O 0.286443 0.474271 0.373788 -0 - 37 O 0.312173 0.912655 0.286443 -0 - 38 O 0.412655 0.812173 0.786443 -0 - 39 O 0.087345 0.873788 0.399517 -0 - 40 O 0.713557 0.525729 0.626212 -0 - 41 O 0.687827 0.087345 0.713557 -0 - 42 O 0.025729 0.312173 0.899517 -0 - 43 O 0.213557 0.587345 0.187827 -0 - 44 O 0.126212 0.025729 0.213557 -0 - 45 O 0.974271 0.687827 0.100483 -0 - 46 O 0.786443 0.412655 0.812173 -0 - 47 O 0.873788 0.974271 0.786443 -0 - 48 O 0.600483 0.912655 0.126212 -0 - 49 O 0.187827 0.474271 0.600483 -0 - 50 O 0.399517 0.087345 0.873788 -0 - 51 O 0.812173 0.525729 0.399517 -0 - 52 O 0.899517 0.025729 0.312173 -0 - 53 O 0.373788 0.587345 0.899517 -0 - 54 O 0.100483 0.974271 0.687827 -0 - 55 O 0.626212 0.412655 0.100483 -0 - 56 O 0.373788 0.286443 0.474271 -0 - 57 O 0.587345 0.899517 0.373788 -0 - 58 O 0.626212 0.713557 0.525729 -0 - 59 O 0.412655 0.100483 0.626212 -0 - 60 O 0.126212 0.600483 0.912655 -0 - 61 O 0.025729 0.213557 0.126212 -0 - 62 O 0.873788 0.399517 0.087345 -0 - 63 O 0.974271 0.786443 0.873788 -0 - 64 O 0.312173 0.899517 0.025729 -0 - 65 O 0.912655 0.286443 0.312173 -0 - 66 O 0.687827 0.100483 0.974271 -0 - 67 O 0.087345 0.713557 0.687827 -0 - 68 O 0.187827 0.213557 0.587345 -0 - 69 O 0.474271 0.600483 0.187827 -0 - 70 O 0.812173 0.786443 0.412655 -0 - 71 O 0.525729 0.399517 0.812173 -0 - 72 O 0.286443 0.312173 0.912655 -0 - 73 O 0.713557 0.687827 0.087345 -0 - 74 O 0.213557 0.126212 0.025729 -0 - 75 O 0.786443 0.873788 0.974271 -0 - 76 O 0.899517 0.373788 0.587345 -0 - 77 O 0.100483 0.626212 0.412655 -0 - 78 O 0.600483 0.187827 0.474271 -0 - 79 O 0.399517 0.812173 0.525729 -0","# generated using pymatgen -data_Ho3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.77259219 -_cell_length_b 10.77259219 -_cell_length_c 10.77259219 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ho3Sc2Al3O12 -_chemical_formula_sum 'Ho12 Sc8 Al12 O48' -_cell_volume 962.36266750 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ho Ho0 1 0.25000000 0.37500000 0.12500000 1 - Ho Ho1 1 0.75000000 0.62500000 0.87500000 1 - Ho Ho2 1 0.75000000 0.12500000 0.37500000 1 - Ho Ho3 1 0.12500000 0.25000000 0.37500000 1 - Ho Ho4 1 0.37500000 0.75000000 0.12500000 1 - Ho Ho5 1 0.25000000 0.87500000 0.62500000 1 - Ho Ho6 1 0.87500000 0.75000000 0.62500000 1 - Ho Ho7 1 0.62500000 0.25000000 0.87500000 1 - Ho Ho8 1 0.37500000 0.12500000 0.25000000 1 - Ho Ho9 1 0.62500000 0.87500000 0.75000000 1 - Ho Ho10 1 0.12500000 0.37500000 0.75000000 1 - Ho Ho11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Al Al20 1 0.25000000 0.62500000 0.37500000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.37500000 0.25000000 0.62500000 1 - Al Al24 1 0.62500000 0.75000000 0.37500000 1 - Al Al25 1 0.25000000 0.12500000 0.87500000 1 - Al Al26 1 0.12500000 0.75000000 0.87500000 1 - Al Al27 1 0.87500000 0.25000000 0.12500000 1 - Al Al28 1 0.62500000 0.37500000 0.25000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.87500000 0.12500000 0.75000000 1 - Al Al31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47427100 0.37378800 0.28644300 1 - O O33 1 0.52572900 0.62621200 0.71355700 1 - O O34 1 0.58734500 0.18782700 0.21355700 1 - O O35 1 0.91265500 0.12621200 0.60048300 1 - O O36 1 0.28644300 0.47427100 0.37378800 1 - O O37 1 0.31217300 0.91265500 0.28644300 1 - O O38 1 0.41265500 0.81217300 0.78644300 1 - O O39 1 0.08734500 0.87378800 0.39951700 1 - O O40 1 0.71355700 0.52572900 0.62621200 1 - O O41 1 0.68782700 0.08734500 0.71355700 1 - O O42 1 0.02572900 0.31217300 0.89951700 1 - O O43 1 0.21355700 0.58734500 0.18782700 1 - O O44 1 0.12621200 0.02572900 0.21355700 1 - O O45 1 0.97427100 0.68782700 0.10048300 1 - O O46 1 0.78644300 0.41265500 0.81217300 1 - O O47 1 0.87378800 0.97427100 0.78644300 1 - O O48 1 0.60048300 0.91265500 0.12621200 1 - O O49 1 0.18782700 0.47427100 0.60048300 1 - O O50 1 0.39951700 0.08734500 0.87378800 1 - O O51 1 0.81217300 0.52572900 0.39951700 1 - O O52 1 0.89951700 0.02572900 0.31217300 1 - O O53 1 0.37378800 0.58734500 0.89951700 1 - O O54 1 0.10048300 0.97427100 0.68782700 1 - O O55 1 0.62621200 0.41265500 0.10048300 1 - O O56 1 0.37378800 0.28644300 0.47427100 1 - O O57 1 0.58734500 0.89951700 0.37378800 1 - O O58 1 0.62621200 0.71355700 0.52572900 1 - O O59 1 0.41265500 0.10048300 0.62621200 1 - O O60 1 0.12621200 0.60048300 0.91265500 1 - O O61 1 0.02572900 0.21355700 0.12621200 1 - O O62 1 0.87378800 0.39951700 0.08734500 1 - O O63 1 0.97427100 0.78644300 0.87378800 1 - O O64 1 0.31217300 0.89951700 0.02572900 1 - O O65 1 0.91265500 0.28644300 0.31217300 1 - O O66 1 0.68782700 0.10048300 0.97427100 1 - O O67 1 0.08734500 0.71355700 0.68782700 1 - O O68 1 0.18782700 0.21355700 0.58734500 1 - O O69 1 0.47427100 0.60048300 0.18782700 1 - O O70 1 0.81217300 0.78644300 0.41265500 1 - O O71 1 0.52572900 0.39951700 0.81217300 1 - O O72 1 0.28644300 0.31217300 0.91265500 1 - O O73 1 0.71355700 0.68782700 0.08734500 1 - O O74 1 0.21355700 0.12621200 0.02572900 1 - O O75 1 0.78644300 0.87378800 0.97427100 1 - O O76 1 0.89951700 0.37378800 0.58734500 1 - O O77 1 0.10048300 0.62621200 0.41265500 1 - O O78 1 0.60048300 0.18782700 0.47427100 1 - O O79 1 0.39951700 0.81217300 0.52572900 1 -" -La3Lu2(GaO4)3,mp-1212454,Ia-3d,[],0.0,"{'tags': ['garnet family', 'La3Lu2Ga3O12']}","Full Formula (La12 Lu8 Ga12 O48) -Reduced Formula: La3Lu2(GaO4)3 -abc : 11.330527 11.330527 11.330527 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.25 0.375 0.125 -0 - 1 La 0.75 0.625 0.875 -0 - 2 La 0.75 0.125 0.375 -0 - 3 La 0.125 0.25 0.375 -0 - 4 La 0.375 0.75 0.125 -0 - 5 La 0.25 0.875 0.625 -0 - 6 La 0.875 0.75 0.625 -0 - 7 La 0.625 0.25 0.875 -0 - 8 La 0.375 0.125 0.25 -0 - 9 La 0.625 0.875 0.75 -0 - 10 La 0.125 0.375 0.75 -0 - 11 La 0.875 0.625 0.25 -0 - 12 Lu 0 0 0 -0 - 13 Lu 0.5 0 0.5 -0 - 14 Lu 0 0.5 0.5 -0 - 15 Lu 0.5 0 0 -0 - 16 Lu 0.5 0.5 0 -0 - 17 Lu 0.5 0.5 0.5 -0 - 18 Lu 0 0 0.5 -0 - 19 Lu 0 0.5 0 -0 - 20 Ga 0.25 0.625 0.375 0 - 21 Ga 0.75 0.375 0.625 -0 - 22 Ga 0.75 0.875 0.125 0 - 23 Ga 0.375 0.25 0.625 0 - 24 Ga 0.625 0.75 0.375 -0 - 25 Ga 0.25 0.125 0.875 -0 - 26 Ga 0.125 0.75 0.875 0 - 27 Ga 0.875 0.25 0.125 0 - 28 Ga 0.625 0.375 0.25 -0 - 29 Ga 0.375 0.625 0.75 -0 - 30 Ga 0.875 0.125 0.75 -0 - 31 Ga 0.125 0.875 0.25 0 - 32 O 0.476054 0.374843 0.289927 0 - 33 O 0.523946 0.625157 0.710073 0 - 34 O 0.584916 0.186127 0.210073 0 - 35 O 0.915084 0.125157 0.601211 0 - 36 O 0.289927 0.476054 0.374843 0 - 37 O 0.313873 0.915084 0.289927 0 - 38 O 0.415084 0.813873 0.789927 0 - 39 O 0.084916 0.874843 0.398789 0 - 40 O 0.710073 0.523946 0.625157 0 - 41 O 0.686127 0.084916 0.710073 0 - 42 O 0.023946 0.313873 0.898789 0 - 43 O 0.210073 0.584916 0.186127 0 - 44 O 0.125157 0.023946 0.210073 0 - 45 O 0.976054 0.686127 0.101211 0 - 46 O 0.789927 0.415084 0.813873 0 - 47 O 0.874843 0.976054 0.789927 0 - 48 O 0.601211 0.915084 0.125157 0 - 49 O 0.186127 0.476054 0.601211 0 - 50 O 0.398789 0.084916 0.874843 0 - 51 O 0.813873 0.523946 0.398789 0 - 52 O 0.898789 0.023946 0.313873 0 - 53 O 0.374843 0.584916 0.898789 0 - 54 O 0.101211 0.976054 0.686127 0 - 55 O 0.625157 0.415084 0.101211 0 - 56 O 0.374843 0.289927 0.476054 0 - 57 O 0.584916 0.898789 0.374843 0 - 58 O 0.625157 0.710073 0.523946 0 - 59 O 0.415084 0.101211 0.625157 0 - 60 O 0.125157 0.601211 0.915084 0 - 61 O 0.023946 0.210073 0.125157 0 - 62 O 0.874843 0.398789 0.084916 0 - 63 O 0.976054 0.789927 0.874843 0 - 64 O 0.313873 0.898789 0.023946 0 - 65 O 0.915084 0.289927 0.313873 0 - 66 O 0.686127 0.101211 0.976054 0 - 67 O 0.084916 0.710073 0.686127 0 - 68 O 0.186127 0.210073 0.584916 0 - 69 O 0.476054 0.601211 0.186127 0 - 70 O 0.813873 0.789927 0.415084 0 - 71 O 0.523946 0.398789 0.813873 0 - 72 O 0.289927 0.313873 0.915084 0 - 73 O 0.710073 0.686127 0.084916 0 - 74 O 0.210073 0.125157 0.023946 0 - 75 O 0.789927 0.874843 0.976054 0 - 76 O 0.898789 0.374843 0.584916 0 - 77 O 0.101211 0.625157 0.415084 0 - 78 O 0.601211 0.186127 0.476054 0 - 79 O 0.398789 0.813873 0.523946 0","# generated using pymatgen -data_La3Lu2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.33052732 -_cell_length_b 11.33052732 -_cell_length_c 11.33052732 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3Lu2(GaO4)3 -_chemical_formula_sum 'La12 Lu8 Ga12 O48' -_cell_volume 1119.76909355 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.25000000 0.37500000 0.12500000 1 - La La1 1 0.75000000 0.62500000 0.87500000 1 - La La2 1 0.75000000 0.12500000 0.37500000 1 - La La3 1 0.12500000 0.25000000 0.37500000 1 - La La4 1 0.37500000 0.75000000 0.12500000 1 - La La5 1 0.25000000 0.87500000 0.62500000 1 - La La6 1 0.87500000 0.75000000 0.62500000 1 - La La7 1 0.62500000 0.25000000 0.87500000 1 - La La8 1 0.37500000 0.12500000 0.25000000 1 - La La9 1 0.62500000 0.87500000 0.75000000 1 - La La10 1 0.12500000 0.37500000 0.75000000 1 - La La11 1 0.87500000 0.62500000 0.25000000 1 - Lu Lu12 1 0.00000000 0.00000000 0.00000000 1 - Lu Lu13 1 0.50000000 0.00000000 0.50000000 1 - Lu Lu14 1 0.00000000 0.50000000 0.50000000 1 - Lu Lu15 1 0.50000000 0.00000000 0.00000000 1 - Lu Lu16 1 0.50000000 0.50000000 0.00000000 1 - Lu Lu17 1 0.50000000 0.50000000 0.50000000 1 - Lu Lu18 1 0.00000000 0.00000000 0.50000000 1 - Lu Lu19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47605400 0.37484300 0.28992700 1 - O O33 1 0.52394600 0.62515700 0.71007300 1 - O O34 1 0.58491600 0.18612700 0.21007300 1 - O O35 1 0.91508400 0.12515700 0.60121100 1 - O O36 1 0.28992700 0.47605400 0.37484300 1 - O O37 1 0.31387300 0.91508400 0.28992700 1 - O O38 1 0.41508400 0.81387300 0.78992700 1 - O O39 1 0.08491600 0.87484300 0.39878900 1 - O O40 1 0.71007300 0.52394600 0.62515700 1 - O O41 1 0.68612700 0.08491600 0.71007300 1 - O O42 1 0.02394600 0.31387300 0.89878900 1 - O O43 1 0.21007300 0.58491600 0.18612700 1 - O O44 1 0.12515700 0.02394600 0.21007300 1 - O O45 1 0.97605400 0.68612700 0.10121100 1 - O O46 1 0.78992700 0.41508400 0.81387300 1 - O O47 1 0.87484300 0.97605400 0.78992700 1 - O O48 1 0.60121100 0.91508400 0.12515700 1 - O O49 1 0.18612700 0.47605400 0.60121100 1 - O O50 1 0.39878900 0.08491600 0.87484300 1 - O O51 1 0.81387300 0.52394600 0.39878900 1 - O O52 1 0.89878900 0.02394600 0.31387300 1 - O O53 1 0.37484300 0.58491600 0.89878900 1 - O O54 1 0.10121100 0.97605400 0.68612700 1 - O O55 1 0.62515700 0.41508400 0.10121100 1 - O O56 1 0.37484300 0.28992700 0.47605400 1 - O O57 1 0.58491600 0.89878900 0.37484300 1 - O O58 1 0.62515700 0.71007300 0.52394600 1 - O O59 1 0.41508400 0.10121100 0.62515700 1 - O O60 1 0.12515700 0.60121100 0.91508400 1 - O O61 1 0.02394600 0.21007300 0.12515700 1 - O O62 1 0.87484300 0.39878900 0.08491600 1 - O O63 1 0.97605400 0.78992700 0.87484300 1 - O O64 1 0.31387300 0.89878900 0.02394600 1 - O O65 1 0.91508400 0.28992700 0.31387300 1 - O O66 1 0.68612700 0.10121100 0.97605400 1 - O O67 1 0.08491600 0.71007300 0.68612700 1 - O O68 1 0.18612700 0.21007300 0.58491600 1 - O O69 1 0.47605400 0.60121100 0.18612700 1 - O O70 1 0.81387300 0.78992700 0.41508400 1 - O O71 1 0.52394600 0.39878900 0.81387300 1 - O O72 1 0.28992700 0.31387300 0.91508400 1 - O O73 1 0.71007300 0.68612700 0.08491600 1 - O O74 1 0.21007300 0.12515700 0.02394600 1 - O O75 1 0.78992700 0.87484300 0.97605400 1 - O O76 1 0.89878900 0.37484300 0.58491600 1 - O O77 1 0.10121100 0.62515700 0.41508400 1 - O O78 1 0.60121100 0.18612700 0.47605400 1 - O O79 1 0.39878900 0.81387300 0.52394600 1 -" -Li3Gd3(TeO6)2,mp-1212457,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Li12 Gd12 Te8 O48) -Reduced Formula: Li3Gd3(TeO6)2 -abc : 10.841893 10.841893 10.841893 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.625 0.375 0 - 1 Li 0.75 0.375 0.625 0 - 2 Li 0.75 0.875 0.125 0 - 3 Li 0.375 0.25 0.625 0 - 4 Li 0.625 0.75 0.375 0 - 5 Li 0.25 0.125 0.875 0 - 6 Li 0.125 0.75 0.875 0 - 7 Li 0.875 0.25 0.125 0 - 8 Li 0.625 0.375 0.25 0 - 9 Li 0.375 0.625 0.75 0 - 10 Li 0.875 0.125 0.75 0 - 11 Li 0.125 0.875 0.25 0 - 12 Gd 0.25 0.375 0.125 6.888 - 13 Gd 0.75 0.625 0.875 6.888 - 14 Gd 0.75 0.125 0.375 6.887 - 15 Gd 0.125 0.25 0.375 6.887 - 16 Gd 0.375 0.75 0.125 6.887 - 17 Gd 0.25 0.875 0.625 6.887 - 18 Gd 0.875 0.75 0.625 6.887 - 19 Gd 0.625 0.25 0.875 6.887 - 20 Gd 0.375 0.125 0.25 6.887 - 21 Gd 0.625 0.875 0.75 6.887 - 22 Gd 0.125 0.375 0.75 6.887 - 23 Gd 0.875 0.625 0.25 6.887 - 24 Te 0 0 0 0.004 - 25 Te 0.5 0 0.5 0.004 - 26 Te 0 0.5 0.5 0.004 - 27 Te 0.5 0 0 0.004 - 28 Te 0.5 0.5 0 0.004 - 29 Te 0.5 0.5 0.5 0.004 - 30 Te 0 0 0.5 0.004 - 31 Te 0 0.5 0 0.004 - 32 O 0.473987 0.381237 0.30255 0.001 - 33 O 0.526013 0.618763 0.69745 0.001 - 34 O 0.578687 0.171437 0.19745 0.001 - 35 O 0.921313 0.118763 0.59275 0.001 - 36 O 0.30255 0.473987 0.381237 0.001 - 37 O 0.328563 0.921313 0.30255 0.001 - 38 O 0.421313 0.828563 0.80255 0.001 - 39 O 0.078687 0.881237 0.40725 0.001 - 40 O 0.69745 0.526013 0.618763 0.001 - 41 O 0.671437 0.078687 0.69745 0.001 - 42 O 0.026013 0.328563 0.90725 0.001 - 43 O 0.19745 0.578687 0.171437 0.001 - 44 O 0.118763 0.026013 0.19745 0.001 - 45 O 0.973987 0.671437 0.09275 0.001 - 46 O 0.80255 0.421313 0.828563 0.001 - 47 O 0.881237 0.973987 0.80255 0.001 - 48 O 0.59275 0.921313 0.118763 0.001 - 49 O 0.171437 0.473987 0.59275 0.001 - 50 O 0.40725 0.078687 0.881237 0.001 - 51 O 0.828563 0.526013 0.40725 0.001 - 52 O 0.90725 0.026013 0.328563 0.001 - 53 O 0.381237 0.578687 0.90725 0.001 - 54 O 0.09275 0.973987 0.671437 0.001 - 55 O 0.618763 0.421313 0.09275 0.001 - 56 O 0.381237 0.30255 0.473987 0.001 - 57 O 0.578687 0.90725 0.381237 0.001 - 58 O 0.618763 0.69745 0.526013 0.001 - 59 O 0.421313 0.09275 0.618763 0.001 - 60 O 0.118763 0.59275 0.921313 0.001 - 61 O 0.026013 0.19745 0.118763 0.001 - 62 O 0.881237 0.40725 0.078687 0.001 - 63 O 0.973987 0.80255 0.881237 0.001 - 64 O 0.328563 0.90725 0.026013 0.001 - 65 O 0.921313 0.30255 0.328563 0.001 - 66 O 0.671437 0.09275 0.973987 0.001 - 67 O 0.078687 0.69745 0.671437 0.001 - 68 O 0.171437 0.19745 0.578687 0.001 - 69 O 0.473987 0.59275 0.171437 0.001 - 70 O 0.828563 0.80255 0.421313 0.001 - 71 O 0.526013 0.40725 0.828563 0.001 - 72 O 0.30255 0.328563 0.921313 0.001 - 73 O 0.69745 0.671437 0.078687 0.001 - 74 O 0.19745 0.118763 0.026013 0.001 - 75 O 0.80255 0.881237 0.973987 0.001 - 76 O 0.90725 0.381237 0.578687 0.001 - 77 O 0.09275 0.618763 0.421313 0.001 - 78 O 0.59275 0.171437 0.473987 0.001 - 79 O 0.40725 0.828563 0.526013 0.001","# generated using pymatgen -data_Li3Gd3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.84189327 -_cell_length_b 10.84189327 -_cell_length_c 10.84189327 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Gd3(TeO6)2 -_chemical_formula_sum 'Li12 Gd12 Te8 O48' -_cell_volume 981.05530987 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.62500000 0.37500000 1 - Li Li1 1 0.75000000 0.37500000 0.62500000 1 - Li Li2 1 0.75000000 0.87500000 0.12500000 1 - Li Li3 1 0.37500000 0.25000000 0.62500000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.12500000 0.87500000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.87500000 0.25000000 0.12500000 1 - Li Li8 1 0.62500000 0.37500000 0.25000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.87500000 0.12500000 0.75000000 1 - Li Li11 1 0.12500000 0.87500000 0.25000000 1 - Gd Gd12 1 0.25000000 0.37500000 0.12500000 1 - Gd Gd13 1 0.75000000 0.62500000 0.87500000 1 - Gd Gd14 1 0.75000000 0.12500000 0.37500000 1 - Gd Gd15 1 0.12500000 0.25000000 0.37500000 1 - Gd Gd16 1 0.37500000 0.75000000 0.12500000 1 - Gd Gd17 1 0.25000000 0.87500000 0.62500000 1 - Gd Gd18 1 0.87500000 0.75000000 0.62500000 1 - Gd Gd19 1 0.62500000 0.25000000 0.87500000 1 - Gd Gd20 1 0.37500000 0.12500000 0.25000000 1 - Gd Gd21 1 0.62500000 0.87500000 0.75000000 1 - Gd Gd22 1 0.12500000 0.37500000 0.75000000 1 - Gd Gd23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.00000000 0.00000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.50000000 0.50000000 0.50000000 1 - Te Te30 1 0.00000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47398700 0.38123700 0.30255000 1 - O O33 1 0.52601300 0.61876300 0.69745000 1 - O O34 1 0.57868700 0.17143700 0.19745000 1 - O O35 1 0.92131300 0.11876300 0.59275000 1 - O O36 1 0.30255000 0.47398700 0.38123700 1 - O O37 1 0.32856300 0.92131300 0.30255000 1 - O O38 1 0.42131300 0.82856300 0.80255000 1 - O O39 1 0.07868700 0.88123700 0.40725000 1 - O O40 1 0.69745000 0.52601300 0.61876300 1 - O O41 1 0.67143700 0.07868700 0.69745000 1 - O O42 1 0.02601300 0.32856300 0.90725000 1 - O O43 1 0.19745000 0.57868700 0.17143700 1 - O O44 1 0.11876300 0.02601300 0.19745000 1 - O O45 1 0.97398700 0.67143700 0.09275000 1 - O O46 1 0.80255000 0.42131300 0.82856300 1 - O O47 1 0.88123700 0.97398700 0.80255000 1 - O O48 1 0.59275000 0.92131300 0.11876300 1 - O O49 1 0.17143700 0.47398700 0.59275000 1 - O O50 1 0.40725000 0.07868700 0.88123700 1 - O O51 1 0.82856300 0.52601300 0.40725000 1 - O O52 1 0.90725000 0.02601300 0.32856300 1 - O O53 1 0.38123700 0.57868700 0.90725000 1 - O O54 1 0.09275000 0.97398700 0.67143700 1 - O O55 1 0.61876300 0.42131300 0.09275000 1 - O O56 1 0.38123700 0.30255000 0.47398700 1 - O O57 1 0.57868700 0.90725000 0.38123700 1 - O O58 1 0.61876300 0.69745000 0.52601300 1 - O O59 1 0.42131300 0.09275000 0.61876300 1 - O O60 1 0.11876300 0.59275000 0.92131300 1 - O O61 1 0.02601300 0.19745000 0.11876300 1 - O O62 1 0.88123700 0.40725000 0.07868700 1 - O O63 1 0.97398700 0.80255000 0.88123700 1 - O O64 1 0.32856300 0.90725000 0.02601300 1 - O O65 1 0.92131300 0.30255000 0.32856300 1 - O O66 1 0.67143700 0.09275000 0.97398700 1 - O O67 1 0.07868700 0.69745000 0.67143700 1 - O O68 1 0.17143700 0.19745000 0.57868700 1 - O O69 1 0.47398700 0.59275000 0.17143700 1 - O O70 1 0.82856300 0.80255000 0.42131300 1 - O O71 1 0.52601300 0.40725000 0.82856300 1 - O O72 1 0.30255000 0.32856300 0.92131300 1 - O O73 1 0.69745000 0.67143700 0.07868700 1 - O O74 1 0.19745000 0.11876300 0.02601300 1 - O O75 1 0.80255000 0.88123700 0.97398700 1 - O O76 1 0.90725000 0.38123700 0.57868700 1 - O O77 1 0.09275000 0.61876300 0.42131300 1 - O O78 1 0.59275000 0.17143700 0.47398700 1 - O O79 1 0.40725000 0.82856300 0.52601300 1 -" -Gd3Sc2Al3O12,mp-1213017,Ia-3d,[],0.0,{'tags': []},"Full Formula (Gd12 Sc8 Al12 O48) -Reduced Formula: Gd3Sc2Al3O12 -abc : 10.847827 10.847827 10.847827 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Gd 0.25 0.375 0.125 6.885 - 1 Gd 0.75 0.625 0.875 6.885 - 2 Gd 0.75 0.125 0.375 6.883 - 3 Gd 0.125 0.25 0.375 6.884 - 4 Gd 0.375 0.75 0.125 6.884 - 5 Gd 0.25 0.875 0.625 6.883 - 6 Gd 0.875 0.75 0.625 6.884 - 7 Gd 0.625 0.25 0.875 6.884 - 8 Gd 0.375 0.125 0.25 6.884 - 9 Gd 0.625 0.875 0.75 6.884 - 10 Gd 0.125 0.375 0.75 6.884 - 11 Gd 0.875 0.625 0.25 6.884 - 12 Sc 0 0 0 0.001 - 13 Sc 0.5 0 0.5 0.002 - 14 Sc 0 0.5 0.5 0.002 - 15 Sc 0.5 0 0 0.002 - 16 Sc 0.5 0.5 0 0.001 - 17 Sc 0.5 0.5 0.5 0.001 - 18 Sc 0 0 0.5 0.002 - 19 Sc 0 0.5 0 0.001 - 20 Al 0.25 0.625 0.375 0.001 - 21 Al 0.75 0.375 0.625 0.001 - 22 Al 0.75 0.875 0.125 0.001 - 23 Al 0.375 0.25 0.625 0.001 - 24 Al 0.625 0.75 0.375 0.001 - 25 Al 0.25 0.125 0.875 0.001 - 26 Al 0.125 0.75 0.875 0.001 - 27 Al 0.875 0.25 0.125 0.001 - 28 Al 0.625 0.375 0.25 0.001 - 29 Al 0.375 0.625 0.75 0.001 - 30 Al 0.875 0.125 0.75 0.001 - 31 Al 0.125 0.875 0.25 0.001 - 32 O 0.476694 0.375823 0.288186 0.001 - 33 O 0.523306 0.624177 0.711814 0.001 - 34 O 0.587637 0.188509 0.211814 0.002 - 35 O 0.912363 0.124177 0.600871 0.002 - 36 O 0.288186 0.476694 0.375823 0.001 - 37 O 0.311491 0.912363 0.288186 0.001 - 38 O 0.412363 0.811491 0.788186 0.002 - 39 O 0.087637 0.875823 0.399129 0.002 - 40 O 0.711814 0.523306 0.624177 0.001 - 41 O 0.688509 0.087637 0.711814 0.001 - 42 O 0.023306 0.311491 0.899129 0.001 - 43 O 0.211814 0.587637 0.188509 0.001 - 44 O 0.124177 0.023306 0.211814 0.002 - 45 O 0.976694 0.688509 0.100871 0.001 - 46 O 0.788186 0.412363 0.811491 0.001 - 47 O 0.875823 0.976694 0.788186 0.002 - 48 O 0.600871 0.912363 0.124177 0.002 - 49 O 0.188509 0.476694 0.600871 0.001 - 50 O 0.399129 0.087637 0.875823 0.002 - 51 O 0.811491 0.523306 0.399129 0.001 - 52 O 0.899129 0.023306 0.311491 0.002 - 53 O 0.375823 0.587637 0.899129 0.002 - 54 O 0.100871 0.976694 0.688509 0.002 - 55 O 0.624177 0.412363 0.100871 0.002 - 56 O 0.375823 0.288186 0.476694 0.002 - 57 O 0.587637 0.899129 0.375823 0.002 - 58 O 0.624177 0.711814 0.523306 0.002 - 59 O 0.412363 0.100871 0.624177 0.002 - 60 O 0.124177 0.600871 0.912363 0.002 - 61 O 0.023306 0.211814 0.124177 0.001 - 62 O 0.875823 0.399129 0.087637 0.002 - 63 O 0.976694 0.788186 0.875823 0.001 - 64 O 0.311491 0.899129 0.023306 0.001 - 65 O 0.912363 0.288186 0.311491 0.002 - 66 O 0.688509 0.100871 0.976694 0.001 - 67 O 0.087637 0.711814 0.688509 0.002 - 68 O 0.188509 0.211814 0.587637 0.001 - 69 O 0.476694 0.600871 0.188509 0.001 - 70 O 0.811491 0.788186 0.412363 0.001 - 71 O 0.523306 0.399129 0.811491 0.001 - 72 O 0.288186 0.311491 0.912363 0.001 - 73 O 0.711814 0.688509 0.087637 0.001 - 74 O 0.211814 0.124177 0.023306 0.001 - 75 O 0.788186 0.875823 0.976694 0.001 - 76 O 0.899129 0.375823 0.587637 0.002 - 77 O 0.100871 0.624177 0.412363 0.002 - 78 O 0.600871 0.188509 0.476694 0.002 - 79 O 0.399129 0.811491 0.523306 0.002","# generated using pymatgen -data_Gd3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.84782728 -_cell_length_b 10.84782728 -_cell_length_c 10.84782728 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Gd3Sc2Al3O12 -_chemical_formula_sum 'Gd12 Sc8 Al12 O48' -_cell_volume 982.66705098 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Gd Gd0 1 0.25000000 0.37500000 0.12500000 1 - Gd Gd1 1 0.75000000 0.62500000 0.87500000 1 - Gd Gd2 1 0.75000000 0.12500000 0.37500000 1 - Gd Gd3 1 0.12500000 0.25000000 0.37500000 1 - Gd Gd4 1 0.37500000 0.75000000 0.12500000 1 - Gd Gd5 1 0.25000000 0.87500000 0.62500000 1 - Gd Gd6 1 0.87500000 0.75000000 0.62500000 1 - Gd Gd7 1 0.62500000 0.25000000 0.87500000 1 - Gd Gd8 1 0.37500000 0.12500000 0.25000000 1 - Gd Gd9 1 0.62500000 0.87500000 0.75000000 1 - Gd Gd10 1 0.12500000 0.37500000 0.75000000 1 - Gd Gd11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Al Al20 1 0.25000000 0.62500000 0.37500000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.37500000 0.25000000 0.62500000 1 - Al Al24 1 0.62500000 0.75000000 0.37500000 1 - Al Al25 1 0.25000000 0.12500000 0.87500000 1 - Al Al26 1 0.12500000 0.75000000 0.87500000 1 - Al Al27 1 0.87500000 0.25000000 0.12500000 1 - Al Al28 1 0.62500000 0.37500000 0.25000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.87500000 0.12500000 0.75000000 1 - Al Al31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47669400 0.37582300 0.28818600 1 - O O33 1 0.52330600 0.62417700 0.71181400 1 - O O34 1 0.58763700 0.18850900 0.21181400 1 - O O35 1 0.91236300 0.12417700 0.60087100 1 - O O36 1 0.28818600 0.47669400 0.37582300 1 - O O37 1 0.31149100 0.91236300 0.28818600 1 - O O38 1 0.41236300 0.81149100 0.78818600 1 - O O39 1 0.08763700 0.87582300 0.39912900 1 - O O40 1 0.71181400 0.52330600 0.62417700 1 - O O41 1 0.68850900 0.08763700 0.71181400 1 - O O42 1 0.02330600 0.31149100 0.89912900 1 - O O43 1 0.21181400 0.58763700 0.18850900 1 - O O44 1 0.12417700 0.02330600 0.21181400 1 - O O45 1 0.97669400 0.68850900 0.10087100 1 - O O46 1 0.78818600 0.41236300 0.81149100 1 - O O47 1 0.87582300 0.97669400 0.78818600 1 - O O48 1 0.60087100 0.91236300 0.12417700 1 - O O49 1 0.18850900 0.47669400 0.60087100 1 - O O50 1 0.39912900 0.08763700 0.87582300 1 - O O51 1 0.81149100 0.52330600 0.39912900 1 - O O52 1 0.89912900 0.02330600 0.31149100 1 - O O53 1 0.37582300 0.58763700 0.89912900 1 - O O54 1 0.10087100 0.97669400 0.68850900 1 - O O55 1 0.62417700 0.41236300 0.10087100 1 - O O56 1 0.37582300 0.28818600 0.47669400 1 - O O57 1 0.58763700 0.89912900 0.37582300 1 - O O58 1 0.62417700 0.71181400 0.52330600 1 - O O59 1 0.41236300 0.10087100 0.62417700 1 - O O60 1 0.12417700 0.60087100 0.91236300 1 - O O61 1 0.02330600 0.21181400 0.12417700 1 - O O62 1 0.87582300 0.39912900 0.08763700 1 - O O63 1 0.97669400 0.78818600 0.87582300 1 - O O64 1 0.31149100 0.89912900 0.02330600 1 - O O65 1 0.91236300 0.28818600 0.31149100 1 - O O66 1 0.68850900 0.10087100 0.97669400 1 - O O67 1 0.08763700 0.71181400 0.68850900 1 - O O68 1 0.18850900 0.21181400 0.58763700 1 - O O69 1 0.47669400 0.60087100 0.18850900 1 - O O70 1 0.81149100 0.78818600 0.41236300 1 - O O71 1 0.52330600 0.39912900 0.81149100 1 - O O72 1 0.28818600 0.31149100 0.91236300 1 - O O73 1 0.71181400 0.68850900 0.08763700 1 - O O74 1 0.21181400 0.12417700 0.02330600 1 - O O75 1 0.78818600 0.87582300 0.97669400 1 - O O76 1 0.89912900 0.37582300 0.58763700 1 - O O77 1 0.10087100 0.62417700 0.41236300 1 - O O78 1 0.60087100 0.18850900 0.47669400 1 - O O79 1 0.39912900 0.81149100 0.52330600 1 -" -Dy3Sc2Al3O12,mp-1213138,Ia-3d,[],0.0,{'tags': []},"Full Formula (Dy12 Sc8 Al12 O48) -Reduced Formula: Dy3Sc2Al3O12 -abc : 10.775078 10.775078 10.775078 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Dy 0.25 0.375 0.125 0 - 1 Dy 0.75 0.625 0.875 0 - 2 Dy 0.75 0.125 0.375 0 - 3 Dy 0.125 0.25 0.375 0 - 4 Dy 0.375 0.75 0.125 0 - 5 Dy 0.25 0.875 0.625 0 - 6 Dy 0.875 0.75 0.625 0 - 7 Dy 0.625 0.25 0.875 0 - 8 Dy 0.375 0.125 0.25 0 - 9 Dy 0.625 0.875 0.75 0 - 10 Dy 0.125 0.375 0.75 0 - 11 Dy 0.875 0.625 0.25 0 - 12 Sc 0 0 0 0 - 13 Sc 0.5 0 0.5 0 - 14 Sc 0 0.5 0.5 0 - 15 Sc 0.5 0 0 0 - 16 Sc 0.5 0.5 0 0 - 17 Sc 0.5 0.5 0.5 0 - 18 Sc 0 0 0.5 0 - 19 Sc 0 0.5 0 0 - 20 Al 0.25 0.625 0.375 0 - 21 Al 0.75 0.375 0.625 0 - 22 Al 0.75 0.875 0.125 0 - 23 Al 0.375 0.25 0.625 0 - 24 Al 0.625 0.75 0.375 0 - 25 Al 0.25 0.125 0.875 0 - 26 Al 0.125 0.75 0.875 0 - 27 Al 0.875 0.25 0.125 0 - 28 Al 0.625 0.375 0.25 0 - 29 Al 0.375 0.625 0.75 0 - 30 Al 0.875 0.125 0.75 0 - 31 Al 0.125 0.875 0.25 0 - 32 O 0.474613 0.374439 0.286669 -0 - 33 O 0.525387 0.625561 0.713331 -0 - 34 O 0.58777 0.187943 0.213331 -0 - 35 O 0.91223 0.125561 0.600173 -0 - 36 O 0.286669 0.474613 0.374439 -0 - 37 O 0.312057 0.91223 0.286669 -0 - 38 O 0.41223 0.812057 0.786669 -0 - 39 O 0.08777 0.874439 0.399827 -0 - 40 O 0.713331 0.525387 0.625561 -0 - 41 O 0.687943 0.08777 0.713331 -0 - 42 O 0.025387 0.312057 0.899827 -0 - 43 O 0.213331 0.58777 0.187943 -0 - 44 O 0.125561 0.025387 0.213331 -0 - 45 O 0.974613 0.687943 0.100173 -0 - 46 O 0.786669 0.41223 0.812057 -0 - 47 O 0.874439 0.974613 0.786669 -0 - 48 O 0.600173 0.91223 0.125561 -0 - 49 O 0.187943 0.474613 0.600173 -0 - 50 O 0.399827 0.08777 0.874439 -0 - 51 O 0.812057 0.525387 0.399827 -0 - 52 O 0.899827 0.025387 0.312057 -0 - 53 O 0.374439 0.58777 0.899827 -0 - 54 O 0.100173 0.974613 0.687943 -0 - 55 O 0.625561 0.41223 0.100173 -0 - 56 O 0.374439 0.286669 0.474613 -0 - 57 O 0.58777 0.899827 0.374439 -0 - 58 O 0.625561 0.713331 0.525387 -0 - 59 O 0.41223 0.100173 0.625561 -0 - 60 O 0.125561 0.600173 0.91223 -0 - 61 O 0.025387 0.213331 0.125561 -0 - 62 O 0.874439 0.399827 0.08777 -0 - 63 O 0.974613 0.786669 0.874439 -0 - 64 O 0.312057 0.899827 0.025387 -0 - 65 O 0.91223 0.286669 0.312057 -0 - 66 O 0.687943 0.100173 0.974613 -0 - 67 O 0.08777 0.713331 0.687943 -0 - 68 O 0.187943 0.213331 0.58777 -0 - 69 O 0.474613 0.600173 0.187943 -0 - 70 O 0.812057 0.786669 0.41223 -0 - 71 O 0.525387 0.399827 0.812057 -0 - 72 O 0.286669 0.312057 0.91223 -0 - 73 O 0.713331 0.687943 0.08777 -0 - 74 O 0.213331 0.125561 0.025387 -0 - 75 O 0.786669 0.874439 0.974613 -0 - 76 O 0.899827 0.374439 0.58777 -0 - 77 O 0.100173 0.625561 0.41223 -0 - 78 O 0.600173 0.187943 0.474613 -0 - 79 O 0.399827 0.812057 0.525387 -0","# generated using pymatgen -data_Dy3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.77507768 -_cell_length_b 10.77507768 -_cell_length_c 10.77507768 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Dy3Sc2Al3O12 -_chemical_formula_sum 'Dy12 Sc8 Al12 O48' -_cell_volume 963.02894099 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Dy Dy0 1 0.25000000 0.37500000 0.12500000 1 - Dy Dy1 1 0.75000000 0.62500000 0.87500000 1 - Dy Dy2 1 0.75000000 0.12500000 0.37500000 1 - Dy Dy3 1 0.12500000 0.25000000 0.37500000 1 - Dy Dy4 1 0.37500000 0.75000000 0.12500000 1 - Dy Dy5 1 0.25000000 0.87500000 0.62500000 1 - Dy Dy6 1 0.87500000 0.75000000 0.62500000 1 - Dy Dy7 1 0.62500000 0.25000000 0.87500000 1 - Dy Dy8 1 0.37500000 0.12500000 0.25000000 1 - Dy Dy9 1 0.62500000 0.87500000 0.75000000 1 - Dy Dy10 1 0.12500000 0.37500000 0.75000000 1 - Dy Dy11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Al Al20 1 0.25000000 0.62500000 0.37500000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.37500000 0.25000000 0.62500000 1 - Al Al24 1 0.62500000 0.75000000 0.37500000 1 - Al Al25 1 0.25000000 0.12500000 0.87500000 1 - Al Al26 1 0.12500000 0.75000000 0.87500000 1 - Al Al27 1 0.87500000 0.25000000 0.12500000 1 - Al Al28 1 0.62500000 0.37500000 0.25000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.87500000 0.12500000 0.75000000 1 - Al Al31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47461300 0.37443900 0.28666900 1 - O O33 1 0.52538700 0.62556100 0.71333100 1 - O O34 1 0.58777000 0.18794300 0.21333100 1 - O O35 1 0.91223000 0.12556100 0.60017300 1 - O O36 1 0.28666900 0.47461300 0.37443900 1 - O O37 1 0.31205700 0.91223000 0.28666900 1 - O O38 1 0.41223000 0.81205700 0.78666900 1 - O O39 1 0.08777000 0.87443900 0.39982700 1 - O O40 1 0.71333100 0.52538700 0.62556100 1 - O O41 1 0.68794300 0.08777000 0.71333100 1 - O O42 1 0.02538700 0.31205700 0.89982700 1 - O O43 1 0.21333100 0.58777000 0.18794300 1 - O O44 1 0.12556100 0.02538700 0.21333100 1 - O O45 1 0.97461300 0.68794300 0.10017300 1 - O O46 1 0.78666900 0.41223000 0.81205700 1 - O O47 1 0.87443900 0.97461300 0.78666900 1 - O O48 1 0.60017300 0.91223000 0.12556100 1 - O O49 1 0.18794300 0.47461300 0.60017300 1 - O O50 1 0.39982700 0.08777000 0.87443900 1 - O O51 1 0.81205700 0.52538700 0.39982700 1 - O O52 1 0.89982700 0.02538700 0.31205700 1 - O O53 1 0.37443900 0.58777000 0.89982700 1 - O O54 1 0.10017300 0.97461300 0.68794300 1 - O O55 1 0.62556100 0.41223000 0.10017300 1 - O O56 1 0.37443900 0.28666900 0.47461300 1 - O O57 1 0.58777000 0.89982700 0.37443900 1 - O O58 1 0.62556100 0.71333100 0.52538700 1 - O O59 1 0.41223000 0.10017300 0.62556100 1 - O O60 1 0.12556100 0.60017300 0.91223000 1 - O O61 1 0.02538700 0.21333100 0.12556100 1 - O O62 1 0.87443900 0.39982700 0.08777000 1 - O O63 1 0.97461300 0.78666900 0.87443900 1 - O O64 1 0.31205700 0.89982700 0.02538700 1 - O O65 1 0.91223000 0.28666900 0.31205700 1 - O O66 1 0.68794300 0.10017300 0.97461300 1 - O O67 1 0.08777000 0.71333100 0.68794300 1 - O O68 1 0.18794300 0.21333100 0.58777000 1 - O O69 1 0.47461300 0.60017300 0.18794300 1 - O O70 1 0.81205700 0.78666900 0.41223000 1 - O O71 1 0.52538700 0.39982700 0.81205700 1 - O O72 1 0.28666900 0.31205700 0.91223000 1 - O O73 1 0.71333100 0.68794300 0.08777000 1 - O O74 1 0.21333100 0.12556100 0.02538700 1 - O O75 1 0.78666900 0.87443900 0.97461300 1 - O O76 1 0.89982700 0.37443900 0.58777000 1 - O O77 1 0.10017300 0.62556100 0.41223000 1 - O O78 1 0.60017300 0.18794300 0.47461300 1 - O O79 1 0.39982700 0.81205700 0.52538700 1 -" -Er3Al3Cr2O12,mp-1213214,Ia-3d,[],0.0,"{'tags': ['Er3Cr2Al3O12', 'garnet family']}","Full Formula (Er12 Al12 Cr8 O48) -Reduced Formula: Er3Al3Cr2O12 -abc : 10.594962 10.594962 10.594962 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Er 0.25 0.375 0.125 -0.01 - 1 Er 0.75 0.625 0.875 -0.01 - 2 Er 0.75 0.125 0.375 -0.01 - 3 Er 0.125 0.25 0.375 -0.01 - 4 Er 0.375 0.75 0.125 -0.01 - 5 Er 0.25 0.875 0.625 -0.01 - 6 Er 0.875 0.75 0.625 -0.01 - 7 Er 0.625 0.25 0.875 -0.01 - 8 Er 0.375 0.125 0.25 -0.01 - 9 Er 0.625 0.875 0.75 -0.01 - 10 Er 0.125 0.375 0.75 -0.01 - 11 Er 0.875 0.625 0.25 -0.01 - 12 Al 0.25 0.625 0.375 -0.004 - 13 Al 0.75 0.375 0.625 -0.004 - 14 Al 0.75 0.875 0.125 -0.004 - 15 Al 0.375 0.25 0.625 -0.004 - 16 Al 0.625 0.75 0.375 -0.004 - 17 Al 0.25 0.125 0.875 -0.004 - 18 Al 0.125 0.75 0.875 -0.004 - 19 Al 0.875 0.25 0.125 -0.004 - 20 Al 0.625 0.375 0.25 -0.004 - 21 Al 0.375 0.625 0.75 -0.004 - 22 Al 0.875 0.125 0.75 -0.004 - 23 Al 0.125 0.875 0.25 -0.004 - 24 Cr 0 0 0 -2.941 - 25 Cr 0.5 0 0.5 -2.94 - 26 Cr 0 0.5 0.5 -2.94 - 27 Cr 0.5 0 0 -2.94 - 28 Cr 0.5 0.5 0 -2.941 - 29 Cr 0.5 0.5 0.5 -2.941 - 30 Cr 0 0 0.5 -2.94 - 31 Cr 0 0.5 0 -2.941 - 32 O 0.474945 0.375974 0.291333 0.006 - 33 O 0.525055 0.624026 0.708667 0.006 - 34 O 0.584642 0.183613 0.208667 0.006 - 35 O 0.915358 0.124026 0.598971 0.006 - 36 O 0.291333 0.474945 0.375974 0.006 - 37 O 0.316387 0.915358 0.291333 0.006 - 38 O 0.415358 0.816387 0.791333 0.006 - 39 O 0.084642 0.875974 0.401029 0.006 - 40 O 0.708667 0.525055 0.624026 0.006 - 41 O 0.683613 0.084642 0.708667 0.006 - 42 O 0.025055 0.316387 0.901029 0.006 - 43 O 0.208667 0.584642 0.183613 0.006 - 44 O 0.124026 0.025055 0.208667 0.006 - 45 O 0.974945 0.683613 0.098971 0.006 - 46 O 0.791333 0.415358 0.816387 0.006 - 47 O 0.875974 0.974945 0.791333 0.006 - 48 O 0.598971 0.915358 0.124026 0.006 - 49 O 0.183613 0.474945 0.598971 0.006 - 50 O 0.401029 0.084642 0.875974 0.006 - 51 O 0.816387 0.525055 0.401029 0.006 - 52 O 0.901029 0.025055 0.316387 0.006 - 53 O 0.375974 0.584642 0.901029 0.006 - 54 O 0.098971 0.974945 0.683613 0.006 - 55 O 0.624026 0.415358 0.098971 0.006 - 56 O 0.375974 0.291333 0.474945 0.006 - 57 O 0.584642 0.901029 0.375974 0.006 - 58 O 0.624026 0.708667 0.525055 0.006 - 59 O 0.415358 0.098971 0.624026 0.006 - 60 O 0.124026 0.598971 0.915358 0.006 - 61 O 0.025055 0.208667 0.124026 0.006 - 62 O 0.875974 0.401029 0.084642 0.006 - 63 O 0.974945 0.791333 0.875974 0.006 - 64 O 0.316387 0.901029 0.025055 0.006 - 65 O 0.915358 0.291333 0.316387 0.006 - 66 O 0.683613 0.098971 0.974945 0.006 - 67 O 0.084642 0.708667 0.683613 0.006 - 68 O 0.183613 0.208667 0.584642 0.006 - 69 O 0.474945 0.598971 0.183613 0.006 - 70 O 0.816387 0.791333 0.415358 0.006 - 71 O 0.525055 0.401029 0.816387 0.006 - 72 O 0.291333 0.316387 0.915358 0.006 - 73 O 0.708667 0.683613 0.084642 0.006 - 74 O 0.208667 0.124026 0.025055 0.006 - 75 O 0.791333 0.875974 0.974945 0.006 - 76 O 0.901029 0.375974 0.584642 0.006 - 77 O 0.098971 0.624026 0.415358 0.006 - 78 O 0.598971 0.183613 0.474945 0.006 - 79 O 0.401029 0.816387 0.525055 0.006","# generated using pymatgen -data_Er3Al3Cr2O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.59496172 -_cell_length_b 10.59496172 -_cell_length_c 10.59496172 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Er3Al3Cr2O12 -_chemical_formula_sum 'Er12 Al12 Cr8 O48' -_cell_volume 915.53781050 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Er Er0 1 0.25000000 0.37500000 0.12500000 1 - Er Er1 1 0.75000000 0.62500000 0.87500000 1 - Er Er2 1 0.75000000 0.12500000 0.37500000 1 - Er Er3 1 0.12500000 0.25000000 0.37500000 1 - Er Er4 1 0.37500000 0.75000000 0.12500000 1 - Er Er5 1 0.25000000 0.87500000 0.62500000 1 - Er Er6 1 0.87500000 0.75000000 0.62500000 1 - Er Er7 1 0.62500000 0.25000000 0.87500000 1 - Er Er8 1 0.37500000 0.12500000 0.25000000 1 - Er Er9 1 0.62500000 0.87500000 0.75000000 1 - Er Er10 1 0.12500000 0.37500000 0.75000000 1 - Er Er11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.25000000 0.62500000 0.37500000 1 - Al Al13 1 0.75000000 0.37500000 0.62500000 1 - Al Al14 1 0.75000000 0.87500000 0.12500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.62500000 0.75000000 0.37500000 1 - Al Al17 1 0.25000000 0.12500000 0.87500000 1 - Al Al18 1 0.12500000 0.75000000 0.87500000 1 - Al Al19 1 0.87500000 0.25000000 0.12500000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.37500000 0.62500000 0.75000000 1 - Al Al22 1 0.87500000 0.12500000 0.75000000 1 - Al Al23 1 0.12500000 0.87500000 0.25000000 1 - Cr Cr24 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr25 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr26 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr27 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr28 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr29 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr30 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47494500 0.37597400 0.29133300 1 - O O33 1 0.52505500 0.62402600 0.70866700 1 - O O34 1 0.58464200 0.18361300 0.20866700 1 - O O35 1 0.91535800 0.12402600 0.59897100 1 - O O36 1 0.29133300 0.47494500 0.37597400 1 - O O37 1 0.31638700 0.91535800 0.29133300 1 - O O38 1 0.41535800 0.81638700 0.79133300 1 - O O39 1 0.08464200 0.87597400 0.40102900 1 - O O40 1 0.70866700 0.52505500 0.62402600 1 - O O41 1 0.68361300 0.08464200 0.70866700 1 - O O42 1 0.02505500 0.31638700 0.90102900 1 - O O43 1 0.20866700 0.58464200 0.18361300 1 - O O44 1 0.12402600 0.02505500 0.20866700 1 - O O45 1 0.97494500 0.68361300 0.09897100 1 - O O46 1 0.79133300 0.41535800 0.81638700 1 - O O47 1 0.87597400 0.97494500 0.79133300 1 - O O48 1 0.59897100 0.91535800 0.12402600 1 - O O49 1 0.18361300 0.47494500 0.59897100 1 - O O50 1 0.40102900 0.08464200 0.87597400 1 - O O51 1 0.81638700 0.52505500 0.40102900 1 - O O52 1 0.90102900 0.02505500 0.31638700 1 - O O53 1 0.37597400 0.58464200 0.90102900 1 - O O54 1 0.09897100 0.97494500 0.68361300 1 - O O55 1 0.62402600 0.41535800 0.09897100 1 - O O56 1 0.37597400 0.29133300 0.47494500 1 - O O57 1 0.58464200 0.90102900 0.37597400 1 - O O58 1 0.62402600 0.70866700 0.52505500 1 - O O59 1 0.41535800 0.09897100 0.62402600 1 - O O60 1 0.12402600 0.59897100 0.91535800 1 - O O61 1 0.02505500 0.20866700 0.12402600 1 - O O62 1 0.87597400 0.40102900 0.08464200 1 - O O63 1 0.97494500 0.79133300 0.87597400 1 - O O64 1 0.31638700 0.90102900 0.02505500 1 - O O65 1 0.91535800 0.29133300 0.31638700 1 - O O66 1 0.68361300 0.09897100 0.97494500 1 - O O67 1 0.08464200 0.70866700 0.68361300 1 - O O68 1 0.18361300 0.20866700 0.58464200 1 - O O69 1 0.47494500 0.59897100 0.18361300 1 - O O70 1 0.81638700 0.79133300 0.41535800 1 - O O71 1 0.52505500 0.40102900 0.81638700 1 - O O72 1 0.29133300 0.31638700 0.91535800 1 - O O73 1 0.70866700 0.68361300 0.08464200 1 - O O74 1 0.20866700 0.12402600 0.02505500 1 - O O75 1 0.79133300 0.87597400 0.97494500 1 - O O76 1 0.90102900 0.37597400 0.58464200 1 - O O77 1 0.09897100 0.62402600 0.41535800 1 - O O78 1 0.59897100 0.18361300 0.47494500 1 - O O79 1 0.40102900 0.81638700 0.52505500 1 -" -Er3Sc2Al3O12,mp-1213255,Ia-3d,[],0.0,{'tags': []},"Full Formula (Er12 Sc8 Al12 O48) -Reduced Formula: Er3Sc2Al3O12 -abc : 10.724211 10.724211 10.724211 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Er 0.25 0.375 0.125 -0 - 1 Er 0.75 0.625 0.875 -0 - 2 Er 0.75 0.125 0.375 -0 - 3 Er 0.125 0.25 0.375 -0 - 4 Er 0.375 0.75 0.125 -0 - 5 Er 0.25 0.875 0.625 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0.599496 0.187845 0 - 70 O 0.812155 0.78537 0.411651 0 - 71 O 0.526785 0.400504 0.812155 0 - 72 O 0.28537 0.312155 0.911651 0 - 73 O 0.71463 0.687845 0.088349 0 - 74 O 0.21463 0.126281 0.026785 0 - 75 O 0.78537 0.873719 0.973215 0 - 76 O 0.900504 0.373719 0.588349 0 - 77 O 0.099496 0.626281 0.411651 0 - 78 O 0.599496 0.187845 0.473215 0 - 79 O 0.400504 0.812155 0.526785 0","# generated using pymatgen -data_Er3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.72421081 -_cell_length_b 10.72421081 -_cell_length_c 10.72421081 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Er3Sc2Al3O12 -_chemical_formula_sum 'Er12 Sc8 Al12 O48' -_cell_volume 949.45445615 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - 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0.71463000 1 - O O42 1 0.02678500 0.31215500 0.90050400 1 - O O43 1 0.21463000 0.58834900 0.18784500 1 - O O44 1 0.12628100 0.02678500 0.21463000 1 - O O45 1 0.97321500 0.68784500 0.09949600 1 - O O46 1 0.78537000 0.41165100 0.81215500 1 - O O47 1 0.87371900 0.97321500 0.78537000 1 - O O48 1 0.59949600 0.91165100 0.12628100 1 - O O49 1 0.18784500 0.47321500 0.59949600 1 - O O50 1 0.40050400 0.08834900 0.87371900 1 - O O51 1 0.81215500 0.52678500 0.40050400 1 - O O52 1 0.90050400 0.02678500 0.31215500 1 - O O53 1 0.37371900 0.58834900 0.90050400 1 - O O54 1 0.09949600 0.97321500 0.68784500 1 - O O55 1 0.62628100 0.41165100 0.09949600 1 - O O56 1 0.37371900 0.28537000 0.47321500 1 - O O57 1 0.58834900 0.90050400 0.37371900 1 - O O58 1 0.62628100 0.71463000 0.52678500 1 - O O59 1 0.41165100 0.09949600 0.62628100 1 - O O60 1 0.12628200 0.59949600 0.91165100 1 - O O61 1 0.02678500 0.21463000 0.12628100 1 - O O62 1 0.87371900 0.40050400 0.08834900 1 - O O63 1 0.97321500 0.78537000 0.87371800 1 - O O64 1 0.31215500 0.90050400 0.02678500 1 - O O65 1 0.91165100 0.28537000 0.31215500 1 - O O66 1 0.68784500 0.09949600 0.97321500 1 - O O67 1 0.08834900 0.71463000 0.68784500 1 - O O68 1 0.18784500 0.21463000 0.58834900 1 - O O69 1 0.47321500 0.59949600 0.18784500 1 - O O70 1 0.81215500 0.78537000 0.41165100 1 - O O71 1 0.52678500 0.40050400 0.81215500 1 - O O72 1 0.28537000 0.31215500 0.91165100 1 - O O73 1 0.71463000 0.68784500 0.08834900 1 - O O74 1 0.21463000 0.12628100 0.02678500 1 - O O75 1 0.78537000 0.87371900 0.97321500 1 - O O76 1 0.90050400 0.37371900 0.58834900 1 - O O77 1 0.09949600 0.62628100 0.41165100 1 - O O78 1 0.59949600 0.18784500 0.47321500 1 - O O79 1 0.40050400 0.81215500 0.52678500 1 -" -Eu3Sc2Al3O12,mp-1213328,Ia-3d,[],0.0,"{'tags': ['Sc2Eu3Al3O12', 'garnet family']}","Full Formula (Eu12 Sc8 Al12 O48) -Reduced Formula: Eu3Sc2Al3O12 -abc : 10.920118 10.920118 10.920118 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Eu 0.25 0.375 0.125 6.2 - 1 Eu 0.75 0.625 0.875 6.2 - 2 Eu 0.75 0.125 0.375 6.2 - 3 Eu 0.125 0.25 0.375 6.203 - 4 Eu 0.375 0.75 0.125 6.203 - 5 Eu 0.25 0.875 0.625 6.2 - 6 Eu 0.875 0.75 0.625 6.203 - 7 Eu 0.625 0.25 0.875 6.203 - 8 Eu 0.375 0.125 0.25 6.203 - 9 Eu 0.625 0.875 0.75 6.203 - 10 Eu 0.125 0.375 0.75 6.203 - 11 Eu 0.875 0.625 0.25 6.203 - 12 Sc 0 0 0 0.003 - 13 Sc 0.5 0 0.5 0.002 - 14 Sc 0 0.5 0.5 0.002 - 15 Sc 0.5 0 0 0.002 - 16 Sc 0.5 0.5 0 0.003 - 17 Sc 0.5 0.5 0.5 0.003 - 18 Sc 0 0 0.5 0.002 - 19 Sc 0 0.5 0 0.003 - 20 Al 0.25 0.625 0.375 0.001 - 21 Al 0.75 0.375 0.625 0.001 - 22 Al 0.75 0.875 0.125 0.001 - 23 Al 0.375 0.25 0.625 0.001 - 24 Al 0.625 0.75 0.375 0.001 - 25 Al 0.25 0.125 0.875 0.001 - 26 Al 0.125 0.75 0.875 0.001 - 27 Al 0.875 0.25 0.125 0.001 - 28 Al 0.625 0.375 0.25 0.001 - 29 Al 0.375 0.625 0.75 0.001 - 30 Al 0.875 0.125 0.75 0.001 - 31 Al 0.125 0.875 0.25 0.001 - 32 O 0.47937 0.375983 0.290953 -0.06 - 33 O 0.52063 0.624017 0.709047 -0.06 - 34 O 0.58503 0.188417 0.209047 -0.058 - 35 O 0.91497 0.124017 0.603386 -0.058 - 36 O 0.290953 0.47937 0.375983 -0.06 - 37 O 0.311583 0.91497 0.290953 -0.059 - 38 O 0.41497 0.811583 0.790953 -0.058 - 39 O 0.08503 0.875983 0.396614 -0.058 - 40 O 0.709047 0.52063 0.624017 -0.06 - 41 O 0.688417 0.08503 0.709047 -0.059 - 42 O 0.02063 0.311583 0.896614 -0.06 - 43 O 0.209047 0.58503 0.188417 -0.06 - 44 O 0.124017 0.02063 0.209047 -0.059 - 45 O 0.97937 0.688417 0.103386 -0.06 - 46 O 0.790953 0.41497 0.811583 -0.06 - 47 O 0.875983 0.97937 0.790953 -0.059 - 48 O 0.603386 0.91497 0.124017 -0.058 - 49 O 0.188417 0.47937 0.603386 -0.059 - 50 O 0.396614 0.08503 0.875983 -0.058 - 51 O 0.811583 0.52063 0.396614 -0.059 - 52 O 0.896614 0.02063 0.311583 -0.058 - 53 O 0.375983 0.58503 0.896614 -0.059 - 54 O 0.103386 0.97937 0.688417 -0.058 - 55 O 0.624017 0.41497 0.103386 -0.059 - 56 O 0.375983 0.290953 0.47937 -0.059 - 57 O 0.58503 0.896614 0.375983 -0.058 - 58 O 0.624017 0.709047 0.52063 -0.059 - 59 O 0.41497 0.103386 0.624017 -0.058 - 60 O 0.124017 0.603386 0.91497 -0.059 - 61 O 0.02063 0.209047 0.124017 -0.06 - 62 O 0.875983 0.396614 0.08503 -0.059 - 63 O 0.97937 0.790953 0.875983 -0.06 - 64 O 0.311583 0.896614 0.02063 -0.059 - 65 O 0.91497 0.290953 0.311583 -0.058 - 66 O 0.688417 0.103386 0.97937 -0.059 - 67 O 0.08503 0.709047 0.688417 -0.058 - 68 O 0.188417 0.209047 0.58503 -0.059 - 69 O 0.47937 0.603386 0.188417 -0.06 - 70 O 0.811583 0.790953 0.41497 -0.059 - 71 O 0.52063 0.396614 0.811583 -0.06 - 72 O 0.290953 0.311583 0.91497 -0.06 - 73 O 0.709047 0.688417 0.08503 -0.06 - 74 O 0.209047 0.124017 0.02063 -0.06 - 75 O 0.790953 0.875983 0.97937 -0.06 - 76 O 0.896614 0.375983 0.58503 -0.058 - 77 O 0.103386 0.624017 0.41497 -0.058 - 78 O 0.603386 0.188417 0.47937 -0.058 - 79 O 0.396614 0.811583 0.52063 -0.058","# generated using pymatgen -data_Eu3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.92011788 -_cell_length_b 10.92011788 -_cell_length_c 10.92011788 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Eu3Sc2Al3O12 -_chemical_formula_sum 'Eu12 Sc8 Al12 O48' -_cell_volume 1002.44392720 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Eu Eu0 1 0.25000000 0.37500000 0.12500000 1 - Eu Eu1 1 0.75000000 0.62500000 0.87500000 1 - Eu Eu2 1 0.75000000 0.12500000 0.37500000 1 - Eu Eu3 1 0.12500000 0.25000000 0.37500000 1 - Eu Eu4 1 0.37500000 0.75000000 0.12500000 1 - Eu Eu5 1 0.25000000 0.87500000 0.62500000 1 - Eu Eu6 1 0.87500000 0.75000000 0.62500000 1 - Eu Eu7 1 0.62500000 0.25000000 0.87500000 1 - Eu Eu8 1 0.37500000 0.12500000 0.25000000 1 - Eu Eu9 1 0.62500000 0.87500000 0.75000000 1 - Eu Eu10 1 0.12500000 0.37500000 0.75000000 1 - Eu Eu11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Al Al20 1 0.25000000 0.62500000 0.37500000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.37500000 0.25000000 0.62500000 1 - Al Al24 1 0.62500000 0.75000000 0.37500000 1 - Al Al25 1 0.25000000 0.12500000 0.87500000 1 - Al Al26 1 0.12500000 0.75000000 0.87500000 1 - Al Al27 1 0.87500000 0.25000000 0.12500000 1 - Al Al28 1 0.62500000 0.37500000 0.25000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.87500000 0.12500000 0.75000000 1 - Al Al31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47937000 0.37598300 0.29095300 1 - O O33 1 0.52063000 0.62401700 0.70904700 1 - O O34 1 0.58503000 0.18841700 0.20904700 1 - O O35 1 0.91497000 0.12401700 0.60338600 1 - O O36 1 0.29095300 0.47937000 0.37598300 1 - O O37 1 0.31158300 0.91497000 0.29095300 1 - O O38 1 0.41497000 0.81158300 0.79095300 1 - O O39 1 0.08503000 0.87598300 0.39661400 1 - O O40 1 0.70904700 0.52063000 0.62401700 1 - O O41 1 0.68841700 0.08503000 0.70904700 1 - O O42 1 0.02063000 0.31158300 0.89661400 1 - O O43 1 0.20904700 0.58503000 0.18841700 1 - O O44 1 0.12401700 0.02063000 0.20904700 1 - O O45 1 0.97937000 0.68841700 0.10338600 1 - O O46 1 0.79095300 0.41497000 0.81158300 1 - O O47 1 0.87598300 0.97937000 0.79095300 1 - O O48 1 0.60338600 0.91497000 0.12401700 1 - O O49 1 0.18841700 0.47937000 0.60338600 1 - O O50 1 0.39661400 0.08503000 0.87598300 1 - O O51 1 0.81158300 0.52063000 0.39661400 1 - O O52 1 0.89661400 0.02063000 0.31158300 1 - O O53 1 0.37598300 0.58503000 0.89661400 1 - O O54 1 0.10338600 0.97937000 0.68841700 1 - O O55 1 0.62401700 0.41497000 0.10338600 1 - O O56 1 0.37598300 0.29095300 0.47937000 1 - O O57 1 0.58503000 0.89661400 0.37598300 1 - O O58 1 0.62401700 0.70904700 0.52063000 1 - O O59 1 0.41497000 0.10338600 0.62401700 1 - O O60 1 0.12401700 0.60338600 0.91497000 1 - O O61 1 0.02063000 0.20904700 0.12401700 1 - O O62 1 0.87598300 0.39661400 0.08503000 1 - O O63 1 0.97937000 0.79095300 0.87598300 1 - O O64 1 0.31158300 0.89661400 0.02063000 1 - O O65 1 0.91497000 0.29095300 0.31158300 1 - O O66 1 0.68841700 0.10338600 0.97937000 1 - O O67 1 0.08503000 0.70904700 0.68841700 1 - O O68 1 0.18841700 0.20904700 0.58503000 1 - O O69 1 0.47937000 0.60338600 0.18841700 1 - O O70 1 0.81158300 0.79095300 0.41497000 1 - O O71 1 0.52063000 0.39661400 0.81158300 1 - O O72 1 0.29095300 0.31158300 0.91497000 1 - O O73 1 0.70904700 0.68841700 0.08503000 1 - O O74 1 0.20904700 0.12401700 0.02063000 1 - O O75 1 0.79095300 0.87598300 0.97937000 1 - O O76 1 0.89661400 0.37598300 0.58503000 1 - O O77 1 0.10338600 0.62401700 0.41497000 1 - O O78 1 0.60338600 0.18841700 0.47937000 1 - O O79 1 0.39661400 0.81158300 0.52063000 1 -" -Gd3Lu2(GaO4)3,mp-1213450,Ia-3d,[],0.0,"{'tags': ['garnet family', 'Gd3Lu2Ga3O12']}","Full Formula (Gd12 Lu8 Ga12 O48) -Reduced Formula: Gd3Lu2(GaO4)3 -abc : 11.139089 11.139089 11.139089 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Gd 0.25 0.375 0.125 6.885 - 1 Gd 0.75 0.625 0.875 6.885 - 2 Gd 0.75 0.125 0.375 6.883 - 3 Gd 0.125 0.25 0.375 6.884 - 4 Gd 0.375 0.75 0.125 6.884 - 5 Gd 0.25 0.875 0.625 6.883 - 6 Gd 0.875 0.75 0.625 6.884 - 7 Gd 0.625 0.25 0.875 6.884 - 8 Gd 0.375 0.125 0.25 6.884 - 9 Gd 0.625 0.875 0.75 6.884 - 10 Gd 0.125 0.375 0.75 6.884 - 11 Gd 0.875 0.625 0.25 6.884 - 12 Lu 0 0 0 0.001 - 13 Lu 0.5 0 0.5 0.001 - 14 Lu 0 0.5 0.5 0.001 - 15 Lu 0.5 0 0 0.001 - 16 Lu 0.5 0.5 0 0.001 - 17 Lu 0.5 0.5 0.5 0.001 - 18 Lu 0 0 0.5 0.001 - 19 Lu 0 0.5 0 0.001 - 20 Ga 0.25 0.625 0.375 0.002 - 21 Ga 0.75 0.375 0.625 0.002 - 22 Ga 0.75 0.875 0.125 0.002 - 23 Ga 0.375 0.25 0.625 0.002 - 24 Ga 0.625 0.75 0.375 0.002 - 25 Ga 0.25 0.125 0.875 0.002 - 26 Ga 0.125 0.75 0.875 0.002 - 27 Ga 0.875 0.25 0.125 0.002 - 28 Ga 0.625 0.375 0.25 0.002 - 29 Ga 0.375 0.625 0.75 0.002 - 30 Ga 0.875 0.125 0.75 0.002 - 31 Ga 0.125 0.875 0.25 0.002 - 32 O 0.469693 0.371049 0.283936 0.002 - 33 O 0.530307 0.628951 0.716064 0.002 - 34 O 0.587113 0.185757 0.216064 0.003 - 35 O 0.912887 0.128951 0.598644 0.002 - 36 O 0.283936 0.469693 0.371049 0.002 - 37 O 0.314243 0.912887 0.283936 0.002 - 38 O 0.412887 0.814243 0.783936 0.002 - 39 O 0.087113 0.871049 0.401356 0.002 - 40 O 0.716064 0.530307 0.628951 0.002 - 41 O 0.685757 0.087113 0.716064 0.002 - 42 O 0.030307 0.314243 0.901356 0.002 - 43 O 0.216064 0.587113 0.185757 0.002 - 44 O 0.128951 0.030307 0.216064 0.002 - 45 O 0.969693 0.685757 0.098644 0.002 - 46 O 0.783936 0.412887 0.814243 0.002 - 47 O 0.871049 0.969693 0.783936 0.002 - 48 O 0.598644 0.912887 0.128951 0.002 - 49 O 0.185757 0.469693 0.598644 0.002 - 50 O 0.401356 0.087113 0.871049 0.002 - 51 O 0.814243 0.530307 0.401356 0.002 - 52 O 0.901356 0.030307 0.314243 0.002 - 53 O 0.371049 0.587113 0.901356 0.002 - 54 O 0.098644 0.969693 0.685757 0.002 - 55 O 0.628951 0.412887 0.098644 0.002 - 56 O 0.371049 0.283936 0.469693 0.002 - 57 O 0.587113 0.901356 0.371049 0.002 - 58 O 0.628951 0.716064 0.530307 0.002 - 59 O 0.412887 0.098644 0.628951 0.002 - 60 O 0.128951 0.598644 0.912887 0.002 - 61 O 0.030307 0.216064 0.128951 0.002 - 62 O 0.871049 0.401356 0.087113 0.002 - 63 O 0.969693 0.783936 0.871049 0.002 - 64 O 0.314243 0.901356 0.030307 0.002 - 65 O 0.912887 0.283936 0.314243 0.002 - 66 O 0.685757 0.098644 0.969693 0.002 - 67 O 0.087113 0.716064 0.685757 0.002 - 68 O 0.185757 0.216064 0.587113 0.002 - 69 O 0.469693 0.598644 0.185757 0.002 - 70 O 0.814243 0.783936 0.412887 0.002 - 71 O 0.530307 0.401356 0.814243 0.002 - 72 O 0.283936 0.314243 0.912887 0.002 - 73 O 0.716064 0.685757 0.087113 0.002 - 74 O 0.216064 0.128951 0.030307 0.002 - 75 O 0.783936 0.871049 0.969693 0.002 - 76 O 0.901356 0.371049 0.587113 0.002 - 77 O 0.098644 0.628951 0.412887 0.002 - 78 O 0.598644 0.185757 0.469693 0.002 - 79 O 0.401356 0.814243 0.530307 0.003","# generated using pymatgen -data_Gd3Lu2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.13908894 -_cell_length_b 11.13908894 -_cell_length_c 11.13908894 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Gd3Lu2(GaO4)3 -_chemical_formula_sum 'Gd12 Lu8 Ga12 O48' -_cell_volume 1063.96446757 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Gd Gd0 1 0.25000000 0.37500000 0.12500000 1 - Gd Gd1 1 0.75000000 0.62500000 0.87500000 1 - Gd Gd2 1 0.75000000 0.12500000 0.37500000 1 - Gd Gd3 1 0.12500000 0.25000000 0.37500000 1 - Gd Gd4 1 0.37500000 0.75000000 0.12500000 1 - Gd Gd5 1 0.25000000 0.87500000 0.62500000 1 - Gd Gd6 1 0.87500000 0.75000000 0.62500000 1 - Gd Gd7 1 0.62500000 0.25000000 0.87500000 1 - Gd Gd8 1 0.37500000 0.12500000 0.25000000 1 - Gd Gd9 1 0.62500000 0.87500000 0.75000000 1 - Gd Gd10 1 0.12500000 0.37500000 0.75000000 1 - Gd Gd11 1 0.87500000 0.62500000 0.25000000 1 - Lu Lu12 1 0.00000000 0.00000000 0.00000000 1 - Lu Lu13 1 0.50000000 0.00000000 0.50000000 1 - Lu Lu14 1 0.00000000 0.50000000 0.50000000 1 - Lu Lu15 1 0.50000000 0.00000000 0.00000000 1 - Lu Lu16 1 0.50000000 0.50000000 0.00000000 1 - Lu Lu17 1 0.50000000 0.50000000 0.50000000 1 - Lu Lu18 1 0.00000000 0.00000000 0.50000000 1 - Lu Lu19 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga23 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga24 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga27 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga28 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.46969300 0.37104900 0.28393600 1 - O O33 1 0.53030700 0.62895100 0.71606400 1 - O O34 1 0.58711300 0.18575700 0.21606400 1 - O O35 1 0.91288700 0.12895100 0.59864400 1 - O O36 1 0.28393600 0.46969300 0.37104900 1 - O O37 1 0.31424300 0.91288700 0.28393600 1 - O O38 1 0.41288700 0.81424300 0.78393600 1 - O O39 1 0.08711300 0.87104900 0.40135600 1 - O O40 1 0.71606400 0.53030700 0.62895100 1 - O O41 1 0.68575700 0.08711300 0.71606400 1 - O O42 1 0.03030700 0.31424300 0.90135600 1 - O O43 1 0.21606400 0.58711300 0.18575700 1 - O O44 1 0.12895100 0.03030700 0.21606400 1 - O O45 1 0.96969300 0.68575700 0.09864400 1 - O O46 1 0.78393600 0.41288700 0.81424300 1 - O O47 1 0.87104900 0.96969300 0.78393600 1 - O O48 1 0.59864400 0.91288700 0.12895100 1 - O O49 1 0.18575700 0.46969300 0.59864400 1 - O O50 1 0.40135600 0.08711300 0.87104900 1 - O O51 1 0.81424300 0.53030700 0.40135600 1 - O O52 1 0.90135600 0.03030700 0.31424300 1 - O O53 1 0.37104900 0.58711300 0.90135600 1 - O O54 1 0.09864400 0.96969300 0.68575700 1 - O O55 1 0.62895100 0.41288700 0.09864400 1 - O O56 1 0.37104900 0.28393600 0.46969300 1 - O O57 1 0.58711300 0.90135600 0.37104900 1 - O O58 1 0.62895100 0.71606400 0.53030700 1 - O O59 1 0.41288700 0.09864400 0.62895100 1 - O O60 1 0.12895100 0.59864400 0.91288700 1 - O O61 1 0.03030700 0.21606400 0.12895100 1 - O O62 1 0.87104900 0.40135600 0.08711300 1 - O O63 1 0.96969300 0.78393600 0.87104900 1 - O O64 1 0.31424300 0.90135600 0.03030700 1 - O O65 1 0.91288700 0.28393600 0.31424300 1 - O O66 1 0.68575700 0.09864400 0.96969300 1 - O O67 1 0.08711300 0.71606400 0.68575700 1 - O O68 1 0.18575700 0.21606400 0.58711300 1 - O O69 1 0.46969300 0.59864400 0.18575700 1 - O O70 1 0.81424300 0.78393600 0.41288700 1 - O O71 1 0.53030700 0.40135600 0.81424300 1 - O O72 1 0.28393600 0.31424300 0.91288700 1 - O O73 1 0.71606400 0.68575700 0.08711300 1 - O O74 1 0.21606400 0.12895100 0.03030700 1 - O O75 1 0.78393600 0.87104900 0.96969300 1 - O O76 1 0.90135600 0.37104900 0.58711300 1 - O O77 1 0.09864400 0.62895100 0.41288700 1 - O O78 1 0.59864400 0.18575700 0.46969300 1 - O O79 1 0.40135600 0.81424300 0.53030700 1 -" -Eu3Sc2(FeO4)3,mp-1213528,Ia-3d,[],0.0,"{'tags': ['Sc2Eu3Fe3O12', 'garnet family']}","Full Formula (Eu12 Sc8 Fe12 O48) -Reduced Formula: Eu3Sc2(FeO4)3 -abc : 11.102835 11.102835 11.102835 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Eu 0.25 0.375 0.125 6.232 - 1 Eu 0.75 0.625 0.875 6.232 - 2 Eu 0.75 0.125 0.375 6.259 - 3 Eu 0.125 0.25 0.375 6.27 - 4 Eu 0.375 0.75 0.125 6.27 - 5 Eu 0.25 0.875 0.625 6.259 - 6 Eu 0.875 0.75 0.625 6.27 - 7 Eu 0.625 0.25 0.875 6.27 - 8 Eu 0.375 0.125 0.25 6.27 - 9 Eu 0.625 0.875 0.75 6.27 - 10 Eu 0.125 0.375 0.75 6.27 - 11 Eu 0.875 0.625 0.25 6.27 - 12 Sc 0 0 0 0.066 - 13 Sc 0.5 0 0.5 0.067 - 14 Sc 0 0.5 0.5 0.067 - 15 Sc 0.5 0 0 0.067 - 16 Sc 0.5 0.5 0 0.066 - 17 Sc 0.5 0.5 0.5 0.066 - 18 Sc 0 0 0.5 0.067 - 19 Sc 0 0.5 0 0.066 - 20 Fe 0.25 0.625 0.375 4.215 - 21 Fe 0.75 0.375 0.625 4.215 - 22 Fe 0.75 0.875 0.125 4.215 - 23 Fe 0.375 0.25 0.625 4.215 - 24 Fe 0.625 0.75 0.375 4.215 - 25 Fe 0.25 0.125 0.875 4.215 - 26 Fe 0.125 0.75 0.875 4.215 - 27 Fe 0.875 0.25 0.125 4.215 - 28 Fe 0.625 0.375 0.25 4.215 - 29 Fe 0.375 0.625 0.75 4.215 - 30 Fe 0.875 0.125 0.75 4.215 - 31 Fe 0.125 0.875 0.25 4.215 - 32 O 0.472083 0.376553 0.28923 0.072 - 33 O 0.527917 0.623447 0.71077 0.072 - 34 O 0.587323 0.182853 0.21077 0.073 - 35 O 0.912677 0.123447 0.59553 0.073 - 36 O 0.28923 0.472083 0.376553 0.069 - 37 O 0.317147 0.912677 0.28923 0.074 - 38 O 0.412677 0.817147 0.78923 0.073 - 39 O 0.087323 0.876553 0.40447 0.073 - 40 O 0.71077 0.527917 0.623447 0.069 - 41 O 0.682853 0.087323 0.71077 0.074 - 42 O 0.027917 0.317147 0.90447 0.072 - 43 O 0.21077 0.587323 0.182853 0.069 - 44 O 0.123447 0.027917 0.21077 0.071 - 45 O 0.972083 0.682853 0.09553 0.072 - 46 O 0.78923 0.412677 0.817147 0.069 - 47 O 0.876553 0.972083 0.78923 0.071 - 48 O 0.59553 0.912677 0.123447 0.074 - 49 O 0.182853 0.472083 0.59553 0.074 - 50 O 0.40447 0.087323 0.876553 0.074 - 51 O 0.817147 0.527917 0.40447 0.074 - 52 O 0.90447 0.027917 0.317147 0.074 - 53 O 0.376553 0.587323 0.90447 0.071 - 54 O 0.09553 0.972083 0.682853 0.074 - 55 O 0.623447 0.412677 0.09553 0.071 - 56 O 0.376553 0.28923 0.472083 0.071 - 57 O 0.587323 0.90447 0.376553 0.073 - 58 O 0.623447 0.71077 0.527917 0.071 - 59 O 0.412677 0.09553 0.623447 0.073 - 60 O 0.123447 0.59553 0.912677 0.071 - 61 O 0.027917 0.21077 0.123447 0.072 - 62 O 0.876553 0.40447 0.087323 0.071 - 63 O 0.972083 0.78923 0.876553 0.072 - 64 O 0.317147 0.90447 0.027917 0.074 - 65 O 0.912677 0.28923 0.317147 0.073 - 66 O 0.682853 0.09553 0.972083 0.074 - 67 O 0.087323 0.71077 0.682853 0.073 - 68 O 0.182853 0.21077 0.587323 0.074 - 69 O 0.472083 0.59553 0.182853 0.072 - 70 O 0.817147 0.78923 0.412677 0.074 - 71 O 0.527917 0.40447 0.817147 0.072 - 72 O 0.28923 0.317147 0.912677 0.069 - 73 O 0.71077 0.682853 0.087323 0.069 - 74 O 0.21077 0.123447 0.027917 0.069 - 75 O 0.78923 0.876553 0.972083 0.069 - 76 O 0.90447 0.376553 0.587323 0.074 - 77 O 0.09553 0.623447 0.412677 0.074 - 78 O 0.59553 0.182853 0.472083 0.074 - 79 O 0.40447 0.817147 0.527917 0.074","# generated using pymatgen -data_Eu3Sc2(FeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.10283539 -_cell_length_b 11.10283539 -_cell_length_c 11.10283539 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Eu3Sc2(FeO4)3 -_chemical_formula_sum 'Eu12 Sc8 Fe12 O48' -_cell_volume 1053.60982576 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Eu Eu0 1 0.25000000 0.37500000 0.12500000 1 - Eu Eu1 1 0.75000000 0.62500000 0.87500000 1 - Eu Eu2 1 0.75000000 0.12500000 0.37500000 1 - Eu Eu3 1 0.12500000 0.25000000 0.37500000 1 - Eu Eu4 1 0.37500000 0.75000000 0.12500000 1 - Eu Eu5 1 0.25000000 0.87500000 0.62500000 1 - Eu Eu6 1 0.87500000 0.75000000 0.62500000 1 - Eu Eu7 1 0.62500000 0.25000000 0.87500000 1 - Eu Eu8 1 0.37500000 0.12500000 0.25000000 1 - Eu Eu9 1 0.62500000 0.87500000 0.75000000 1 - Eu Eu10 1 0.12500000 0.37500000 0.75000000 1 - Eu Eu11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe21 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe22 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe23 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe24 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe25 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe26 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe27 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe28 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe29 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe30 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47208300 0.37655300 0.28923000 1 - O O33 1 0.52791700 0.62344700 0.71077000 1 - O O34 1 0.58732300 0.18285300 0.21077000 1 - O O35 1 0.91267700 0.12344700 0.59553000 1 - O O36 1 0.28923000 0.47208300 0.37655300 1 - O O37 1 0.31714700 0.91267700 0.28923000 1 - O O38 1 0.41267700 0.81714700 0.78923000 1 - O O39 1 0.08732300 0.87655300 0.40447000 1 - O O40 1 0.71077000 0.52791700 0.62344700 1 - O O41 1 0.68285300 0.08732300 0.71077000 1 - O O42 1 0.02791700 0.31714700 0.90447000 1 - O O43 1 0.21077000 0.58732300 0.18285300 1 - O O44 1 0.12344700 0.02791700 0.21077000 1 - O O45 1 0.97208300 0.68285300 0.09553000 1 - O O46 1 0.78923000 0.41267700 0.81714700 1 - O O47 1 0.87655300 0.97208300 0.78923000 1 - O O48 1 0.59553000 0.91267700 0.12344700 1 - O O49 1 0.18285300 0.47208300 0.59553000 1 - O O50 1 0.40447000 0.08732300 0.87655300 1 - O O51 1 0.81714700 0.52791700 0.40447000 1 - O O52 1 0.90447000 0.02791700 0.31714700 1 - O O53 1 0.37655300 0.58732300 0.90447000 1 - O O54 1 0.09553000 0.97208300 0.68285300 1 - O O55 1 0.62344700 0.41267700 0.09553000 1 - O O56 1 0.37655300 0.28923000 0.47208300 1 - O O57 1 0.58732300 0.90447000 0.37655300 1 - O O58 1 0.62344700 0.71077000 0.52791700 1 - O O59 1 0.41267700 0.09553000 0.62344700 1 - O O60 1 0.12344700 0.59553000 0.91267700 1 - O O61 1 0.02791700 0.21077000 0.12344700 1 - O O62 1 0.87655300 0.40447000 0.08732300 1 - O O63 1 0.97208300 0.78923000 0.87655300 1 - O O64 1 0.31714700 0.90447000 0.02791700 1 - O O65 1 0.91267700 0.28923000 0.31714700 1 - O O66 1 0.68285300 0.09553000 0.97208300 1 - O O67 1 0.08732300 0.71077000 0.68285300 1 - O O68 1 0.18285300 0.21077000 0.58732300 1 - O O69 1 0.47208300 0.59553000 0.18285300 1 - O O70 1 0.81714700 0.78923000 0.41267700 1 - O O71 1 0.52791700 0.40447000 0.81714700 1 - O O72 1 0.28923000 0.31714700 0.91267700 1 - O O73 1 0.71077000 0.68285300 0.08732300 1 - O O74 1 0.21077000 0.12344700 0.02791700 1 - O O75 1 0.78923000 0.87655300 0.97208300 1 - O O76 1 0.90447000 0.37655300 0.58732300 1 - O O77 1 0.09553000 0.62344700 0.41267700 1 - O O78 1 0.59553000 0.18285300 0.47208300 1 - O O79 1 0.40447000 0.81714700 0.52791700 1 -" -Cd3Ga2(GeO4)3,mp-1213979,Ia-3d,[],0.0077527888749981955,{'tags': ['garnet family']},"Full Formula (Cd12 Ga8 Ge12 O48) -Reduced Formula: Cd3Ga2(GeO4)3 -abc : 10.753902 10.753902 10.753902 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Cd 0.25 0.375 0.125 -0 - 1 Cd 0.75 0.625 0.875 -0 - 2 Cd 0.75 0.125 0.375 -0 - 3 Cd 0.125 0.25 0.375 -0 - 4 Cd 0.375 0.75 0.125 -0 - 5 Cd 0.25 0.875 0.625 -0 - 6 Cd 0.875 0.75 0.625 -0 - 7 Cd 0.625 0.25 0.875 -0 - 8 Cd 0.375 0.125 0.25 -0 - 9 Cd 0.625 0.875 0.75 -0 - 10 Cd 0.125 0.375 0.75 -0 - 11 Cd 0.875 0.625 0.25 -0 - 12 Ga 0 0 0 -0 - 13 Ga 0.5 0 0.5 -0 - 14 Ga 0 0.5 0.5 -0 - 15 Ga 0.5 0 0 -0 - 16 Ga 0.5 0.5 0 -0 - 17 Ga 0.5 0.5 0.5 -0 - 18 Ga 0 0 0.5 -0 - 19 Ga 0 0.5 0 -0 - 20 Ge 0.25 0.625 0.375 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.75 0.875 0.125 -0 - 23 Ge 0.375 0.25 0.625 -0 - 24 Ge 0.625 0.75 0.375 -0 - 25 Ge 0.25 0.125 0.875 -0 - 26 Ge 0.125 0.75 0.875 -0 - 27 Ge 0.875 0.25 0.125 -0 - 28 Ge 0.625 0.375 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.875 0.125 0.75 -0 - 31 Ge 0.125 0.875 0.25 -0 - 32 O 0.483818 0.381044 0.30058 0.001 - 33 O 0.516182 0.618956 0.69942 0.001 - 34 O 0.580464 0.183238 0.19942 0.001 - 35 O 0.919536 0.118956 0.602774 0.001 - 36 O 0.30058 0.483818 0.381044 0.001 - 37 O 0.316762 0.919536 0.30058 0.001 - 38 O 0.419536 0.816762 0.80058 0.001 - 39 O 0.080464 0.881044 0.397226 0.001 - 40 O 0.69942 0.516182 0.618956 0.001 - 41 O 0.683238 0.080464 0.69942 0.001 - 42 O 0.016182 0.316762 0.897226 0.001 - 43 O 0.19942 0.580464 0.183238 0.001 - 44 O 0.118956 0.016182 0.19942 0.001 - 45 O 0.983818 0.683238 0.102774 0.001 - 46 O 0.80058 0.419536 0.816762 0.001 - 47 O 0.881044 0.983818 0.80058 0.001 - 48 O 0.602774 0.919536 0.118956 0.001 - 49 O 0.183238 0.483818 0.602774 0.001 - 50 O 0.397226 0.080464 0.881044 0.001 - 51 O 0.816762 0.516182 0.397226 0.001 - 52 O 0.897226 0.016182 0.316762 0.001 - 53 O 0.381044 0.580464 0.897226 0.001 - 54 O 0.102774 0.983818 0.683238 0.001 - 55 O 0.618956 0.419536 0.102774 0.001 - 56 O 0.381044 0.30058 0.483818 0.001 - 57 O 0.580464 0.897226 0.381044 0.001 - 58 O 0.618956 0.69942 0.516182 0.001 - 59 O 0.419536 0.102774 0.618956 0.001 - 60 O 0.118956 0.602774 0.919536 0.001 - 61 O 0.016182 0.19942 0.118956 0.001 - 62 O 0.881044 0.397226 0.080464 0.001 - 63 O 0.983818 0.80058 0.881044 0.001 - 64 O 0.316762 0.897226 0.016182 0.001 - 65 O 0.919536 0.30058 0.316762 0.001 - 66 O 0.683238 0.102774 0.983818 0.001 - 67 O 0.080464 0.69942 0.683238 0.001 - 68 O 0.183238 0.19942 0.580464 0.001 - 69 O 0.483818 0.602774 0.183238 0.001 - 70 O 0.816762 0.80058 0.419536 0.001 - 71 O 0.516182 0.397226 0.816762 0.001 - 72 O 0.30058 0.316762 0.919536 0.001 - 73 O 0.69942 0.683238 0.080464 0.001 - 74 O 0.19942 0.118956 0.016182 0.001 - 75 O 0.80058 0.881044 0.983818 0.001 - 76 O 0.897226 0.381044 0.580464 0.001 - 77 O 0.102774 0.618956 0.419536 0.001 - 78 O 0.602774 0.183238 0.483818 0.001 - 79 O 0.397226 0.816762 0.516182 0.001","# generated using pymatgen -data_Cd3Ga2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.75390163 -_cell_length_b 10.75390163 -_cell_length_c 10.75390163 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Cd3Ga2(GeO4)3 -_chemical_formula_sum 'Cd12 Ga8 Ge12 O48' -_cell_volume 957.36222545 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Cd Cd0 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd1 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd2 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd3 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd4 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd5 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd6 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd7 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd8 1 0.37500000 0.12500000 0.25000000 1 - Cd Cd9 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd10 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga13 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga14 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga15 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga16 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga18 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48381800 0.38104400 0.30058000 1 - O O33 1 0.51618200 0.61895600 0.69942000 1 - O O34 1 0.58046400 0.18323800 0.19942000 1 - O O35 1 0.91953600 0.11895600 0.60277400 1 - O O36 1 0.30058000 0.48381800 0.38104400 1 - O O37 1 0.31676200 0.91953600 0.30058000 1 - O O38 1 0.41953600 0.81676200 0.80058000 1 - O O39 1 0.08046400 0.88104400 0.39722600 1 - O O40 1 0.69942000 0.51618200 0.61895600 1 - O O41 1 0.68323800 0.08046400 0.69942000 1 - O O42 1 0.01618200 0.31676200 0.89722600 1 - O O43 1 0.19942000 0.58046400 0.18323800 1 - O O44 1 0.11895600 0.01618200 0.19942000 1 - O O45 1 0.98381800 0.68323800 0.10277400 1 - O O46 1 0.80058000 0.41953600 0.81676200 1 - O O47 1 0.88104400 0.98381800 0.80058000 1 - O O48 1 0.60277400 0.91953600 0.11895600 1 - O O49 1 0.18323800 0.48381800 0.60277400 1 - O O50 1 0.39722600 0.08046400 0.88104400 1 - O O51 1 0.81676200 0.51618200 0.39722600 1 - O O52 1 0.89722600 0.01618200 0.31676200 1 - O O53 1 0.38104400 0.58046400 0.89722600 1 - O O54 1 0.10277400 0.98381800 0.68323800 1 - O O55 1 0.61895600 0.41953600 0.10277400 1 - O O56 1 0.38104400 0.30058000 0.48381800 1 - O O57 1 0.58046400 0.89722600 0.38104400 1 - O O58 1 0.61895600 0.69942000 0.51618200 1 - O O59 1 0.41953600 0.10277400 0.61895600 1 - O O60 1 0.11895600 0.60277400 0.91953600 1 - O O61 1 0.01618200 0.19942000 0.11895600 1 - O O62 1 0.88104400 0.39722600 0.08046400 1 - O O63 1 0.98381800 0.80058000 0.88104400 1 - O O64 1 0.31676200 0.89722600 0.01618200 1 - O O65 1 0.91953600 0.30058000 0.31676200 1 - O O66 1 0.68323800 0.10277400 0.98381800 1 - O O67 1 0.08046400 0.69942000 0.68323800 1 - O O68 1 0.18323800 0.19942000 0.58046400 1 - O O69 1 0.48381800 0.60277400 0.18323800 1 - O O70 1 0.81676200 0.80058000 0.41953600 1 - O O71 1 0.51618200 0.39722600 0.81676200 1 - O O72 1 0.30058000 0.31676200 0.91953600 1 - O O73 1 0.69942000 0.68323800 0.08046400 1 - O O74 1 0.19942000 0.11895600 0.01618200 1 - O O75 1 0.80058000 0.88104400 0.98381800 1 - O O76 1 0.89722600 0.38104400 0.58046400 1 - O O77 1 0.10277400 0.61895600 0.41953600 1 - O O78 1 0.60277400 0.18323800 0.48381800 1 - O O79 1 0.39722600 0.81676200 0.51618200 1 -" -Ca3Mg2(AsO4)3,mp-1214140,Ia-3d,[],0.042789674067862826,"{'tags': ['berzeliite', 'garnet family']}","Full Formula (Ca12 Mg8 As12 O48) -Reduced Formula: Ca3Mg2(AsO4)3 -abc : 10.914432 10.914432 10.914432 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0 - 1 Ca 0.75 0.625 0.875 -0 - 2 Ca 0.75 0.125 0.375 -0 - 3 Ca 0.125 0.25 0.375 -0 - 4 Ca 0.375 0.75 0.125 -0 - 5 Ca 0.25 0.875 0.625 -0 - 6 Ca 0.875 0.75 0.625 -0 - 7 Ca 0.625 0.25 0.875 -0 - 8 Ca 0.375 0.125 0.25 -0 - 9 Ca 0.625 0.875 0.75 -0 - 10 Ca 0.125 0.375 0.75 -0 - 11 Ca 0.875 0.625 0.25 -0 - 12 Mg 0 0 0 -0 - 13 Mg 0.5 0 0.5 -0 - 14 Mg 0 0.5 0.5 -0 - 15 Mg 0.5 0 0 -0 - 16 Mg 0.5 0.5 0 -0 - 17 Mg 0.5 0.5 0.5 -0 - 18 Mg 0 0 0.5 -0 - 19 Mg 0 0.5 0 -0 - 20 As 0.25 0.625 0.375 -0 - 21 As 0.75 0.375 0.625 -0 - 22 As 0.75 0.875 0.125 -0 - 23 As 0.375 0.25 0.625 -0 - 24 As 0.625 0.75 0.375 -0 - 25 As 0.25 0.125 0.875 -0 - 26 As 0.125 0.75 0.875 -0 - 27 As 0.875 0.25 0.125 -0 - 28 As 0.625 0.375 0.25 -0 - 29 As 0.375 0.625 0.75 -0 - 30 As 0.875 0.125 0.75 -0 - 31 As 0.125 0.875 0.25 -0 - 32 O 0.482822 0.379156 0.291921 -0 - 33 O 0.517178 0.620844 0.708079 -0 - 34 O 0.587235 0.190901 0.208079 -0 - 35 O 0.912765 0.120844 0.603666 -0 - 36 O 0.291921 0.482822 0.379156 -0 - 37 O 0.309099 0.912765 0.291921 -0 - 38 O 0.412765 0.809099 0.791921 -0 - 39 O 0.087235 0.879156 0.396334 -0 - 40 O 0.708079 0.517178 0.620844 -0 - 41 O 0.690901 0.087235 0.708079 -0 - 42 O 0.017178 0.309099 0.896334 -0 - 43 O 0.208079 0.587235 0.190901 -0 - 44 O 0.120844 0.017178 0.208079 -0 - 45 O 0.982822 0.690901 0.103666 -0 - 46 O 0.791921 0.412765 0.809099 -0 - 47 O 0.879156 0.982822 0.791921 -0 - 48 O 0.603666 0.912765 0.120844 -0 - 49 O 0.190901 0.482822 0.603666 -0 - 50 O 0.396334 0.087235 0.879156 -0 - 51 O 0.809099 0.517178 0.396334 -0 - 52 O 0.896334 0.017178 0.309099 -0 - 53 O 0.379156 0.587235 0.896334 -0 - 54 O 0.103666 0.982822 0.690901 -0 - 55 O 0.620844 0.412765 0.103666 -0 - 56 O 0.379156 0.291921 0.482822 -0 - 57 O 0.587235 0.896334 0.379156 -0 - 58 O 0.620844 0.708079 0.517178 -0 - 59 O 0.412765 0.103666 0.620844 -0 - 60 O 0.120844 0.603666 0.912765 -0 - 61 O 0.017178 0.208079 0.120844 -0 - 62 O 0.879156 0.396334 0.087235 -0 - 63 O 0.982822 0.791921 0.879156 -0 - 64 O 0.309099 0.896334 0.017178 -0 - 65 O 0.912765 0.291921 0.309099 -0 - 66 O 0.690901 0.103666 0.982822 -0 - 67 O 0.087235 0.708079 0.690901 -0 - 68 O 0.190901 0.208079 0.587235 -0 - 69 O 0.482822 0.603666 0.190901 -0 - 70 O 0.809099 0.791921 0.412765 -0 - 71 O 0.517178 0.396334 0.809099 -0 - 72 O 0.291921 0.309099 0.912765 -0 - 73 O 0.708079 0.690901 0.087235 -0 - 74 O 0.208079 0.120844 0.017178 -0 - 75 O 0.791921 0.879156 0.982822 -0 - 76 O 0.896334 0.379156 0.587235 -0 - 77 O 0.103666 0.620844 0.412765 -0 - 78 O 0.603666 0.190901 0.482822 -0 - 79 O 0.396334 0.809099 0.517178 -0","# generated using pymatgen -data_Ca3Mg2(AsO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.91443156 -_cell_length_b 10.91443156 -_cell_length_c 10.91443156 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Mg2(AsO4)3 -_chemical_formula_sum 'Ca12 Mg8 As12 O48' -_cell_volume 1000.87876496 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg12 1 0.00000000 0.00000000 0.00000000 1 - Mg Mg13 1 0.50000000 0.00000000 0.50000000 1 - Mg Mg14 1 0.00000000 0.50000000 0.50000000 1 - Mg Mg15 1 0.50000000 0.00000000 0.00000000 1 - Mg Mg16 1 0.50000000 0.50000000 0.00000000 1 - Mg Mg17 1 0.50000000 0.50000000 0.50000000 1 - Mg Mg18 1 0.00000000 0.00000000 0.50000000 1 - Mg Mg19 1 0.00000000 0.50000000 0.00000000 1 - As As20 1 0.25000000 0.62500000 0.37500000 1 - As As21 1 0.75000000 0.37500000 0.62500000 1 - As As22 1 0.75000000 0.87500000 0.12500000 1 - As As23 1 0.37500000 0.25000000 0.62500000 1 - As As24 1 0.62500000 0.75000000 0.37500000 1 - As As25 1 0.25000000 0.12500000 0.87500000 1 - As As26 1 0.12500000 0.75000000 0.87500000 1 - As As27 1 0.87500000 0.25000000 0.12500000 1 - As As28 1 0.62500000 0.37500000 0.25000000 1 - As As29 1 0.37500000 0.62500000 0.75000000 1 - As As30 1 0.87500000 0.12500000 0.75000000 1 - As As31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48282200 0.37915600 0.29192100 1 - O O33 1 0.51717800 0.62084400 0.70807900 1 - O O34 1 0.58723500 0.19090100 0.20807900 1 - O O35 1 0.91276500 0.12084400 0.60366600 1 - O O36 1 0.29192100 0.48282200 0.37915600 1 - O O37 1 0.30909900 0.91276500 0.29192100 1 - O O38 1 0.41276500 0.80909900 0.79192100 1 - O O39 1 0.08723500 0.87915600 0.39633400 1 - O O40 1 0.70807900 0.51717800 0.62084400 1 - O O41 1 0.69090100 0.08723500 0.70807900 1 - O O42 1 0.01717800 0.30909900 0.89633400 1 - O O43 1 0.20807900 0.58723500 0.19090100 1 - O O44 1 0.12084400 0.01717800 0.20807900 1 - O O45 1 0.98282200 0.69090100 0.10366600 1 - O O46 1 0.79192100 0.41276500 0.80909900 1 - O O47 1 0.87915600 0.98282200 0.79192100 1 - O O48 1 0.60366600 0.91276500 0.12084400 1 - O O49 1 0.19090100 0.48282200 0.60366600 1 - O O50 1 0.39633400 0.08723500 0.87915600 1 - O O51 1 0.80909900 0.51717800 0.39633400 1 - O O52 1 0.89633400 0.01717800 0.30909900 1 - O O53 1 0.37915600 0.58723500 0.89633400 1 - O O54 1 0.10366600 0.98282200 0.69090100 1 - O O55 1 0.62084400 0.41276500 0.10366600 1 - O O56 1 0.37915600 0.29192100 0.48282200 1 - O O57 1 0.58723500 0.89633400 0.37915600 1 - O O58 1 0.62084400 0.70807900 0.51717800 1 - O O59 1 0.41276500 0.10366600 0.62084400 1 - O O60 1 0.12084400 0.60366600 0.91276500 1 - O O61 1 0.01717800 0.20807900 0.12084400 1 - O O62 1 0.87915600 0.39633400 0.08723500 1 - O O63 1 0.98282200 0.79192100 0.87915600 1 - O O64 1 0.30909900 0.89633400 0.01717800 1 - O O65 1 0.91276500 0.29192100 0.30909900 1 - O O66 1 0.69090100 0.10366600 0.98282200 1 - O O67 1 0.08723500 0.70807900 0.69090100 1 - O O68 1 0.19090100 0.20807900 0.58723500 1 - O O69 1 0.48282200 0.60366600 0.19090100 1 - O O70 1 0.80909900 0.79192100 0.41276500 1 - O O71 1 0.51717800 0.39633400 0.80909900 1 - O O72 1 0.29192100 0.30909900 0.91276500 1 - O O73 1 0.70807900 0.69090100 0.08723500 1 - O O74 1 0.20807900 0.12084400 0.01717800 1 - O O75 1 0.79192100 0.87915600 0.98282200 1 - O O76 1 0.89633400 0.37915600 0.58723500 1 - O O77 1 0.10366600 0.62084400 0.41276500 1 - O O78 1 0.60366600 0.19090100 0.48282200 1 - O O79 1 0.39633400 0.80909900 0.51717800 1 -" -Ca3V3(CoO6)2,mp-1214146,Ia-3d,[],0.05768066654911319,{'tags': ['garnet family']},"Full Formula (Ca12 V12 Co8 O48) -Reduced Formula: Ca3V3(CoO6)2 -abc : 10.895078 10.895078 10.895078 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.75 0.125 0.375 0 - 3 Ca 0.125 0.25 0.375 0 - 4 Ca 0.375 0.75 0.125 0 - 5 Ca 0.25 0.875 0.625 0 - 6 Ca 0.875 0.75 0.625 0 - 7 Ca 0.625 0.25 0.875 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.625 0.875 0.75 0 - 10 Ca 0.125 0.375 0.75 0 - 11 Ca 0.875 0.625 0.25 0 - 12 V 0.25 0.625 0.375 -0.006 - 13 V 0.75 0.375 0.625 -0.006 - 14 V 0.75 0.875 0.125 -0.006 - 15 V 0.375 0.25 0.625 -0.002 - 16 V 0.625 0.75 0.375 -0.002 - 17 V 0.25 0.125 0.875 -0.006 - 18 V 0.125 0.75 0.875 -0.002 - 19 V 0.875 0.25 0.125 -0.002 - 20 V 0.625 0.375 0.25 -0.002 - 21 V 0.375 0.625 0.75 -0.002 - 22 V 0.875 0.125 0.75 -0.002 - 23 V 0.125 0.875 0.25 -0.002 - 24 Co 0 0 0 2.411 - 25 Co 0.5 0 0.5 2.384 - 26 Co 0 0.5 0.5 2.384 - 27 Co 0.5 0 0 2.384 - 28 Co 0.5 0.5 0 2.411 - 29 Co 0.5 0.5 0.5 2.411 - 30 Co 0 0 0.5 2.384 - 31 Co 0 0.5 0 2.411 - 32 O 0.482687 0.379719 0.290848 0.018 - 33 O 0.517313 0.620281 0.709152 0.018 - 34 O 0.588871 0.191839 0.209152 0.018 - 35 O 0.911129 0.120281 0.602968 0.018 - 36 O 0.290848 0.482687 0.379719 0.016 - 37 O 0.308161 0.911129 0.290848 0.015 - 38 O 0.411129 0.808161 0.790848 0.018 - 39 O 0.088871 0.879719 0.397032 0.018 - 40 O 0.709152 0.517313 0.620281 0.016 - 41 O 0.691839 0.088871 0.709152 0.015 - 42 O 0.017313 0.308161 0.897032 0.018 - 43 O 0.209152 0.588871 0.191839 0.016 - 44 O 0.120281 0.017313 0.209152 0.017 - 45 O 0.982687 0.691839 0.102968 0.018 - 46 O 0.790848 0.411129 0.808161 0.016 - 47 O 0.879719 0.982687 0.790848 0.017 - 48 O 0.602968 0.911129 0.120281 0.015 - 49 O 0.191839 0.482687 0.602968 0.015 - 50 O 0.397032 0.088871 0.879719 0.015 - 51 O 0.808161 0.517313 0.397032 0.015 - 52 O 0.897032 0.017313 0.308161 0.015 - 53 O 0.379719 0.588871 0.897032 0.017 - 54 O 0.102968 0.982687 0.691839 0.015 - 55 O 0.620281 0.411129 0.102968 0.017 - 56 O 0.379719 0.290848 0.482687 0.017 - 57 O 0.588871 0.897032 0.379719 0.018 - 58 O 0.620281 0.709152 0.517313 0.017 - 59 O 0.411129 0.102968 0.620281 0.018 - 60 O 0.120281 0.602968 0.911129 0.017 - 61 O 0.017313 0.209152 0.120281 0.018 - 62 O 0.879719 0.397032 0.088871 0.017 - 63 O 0.982687 0.790848 0.879719 0.018 - 64 O 0.308161 0.897032 0.017313 0.015 - 65 O 0.911129 0.290848 0.308161 0.018 - 66 O 0.691839 0.102968 0.982687 0.015 - 67 O 0.088871 0.709152 0.691839 0.018 - 68 O 0.191839 0.209152 0.588871 0.015 - 69 O 0.482687 0.602968 0.191839 0.018 - 70 O 0.808161 0.790848 0.411129 0.015 - 71 O 0.517313 0.397032 0.808161 0.018 - 72 O 0.290848 0.308161 0.911129 0.016 - 73 O 0.709152 0.691839 0.088871 0.016 - 74 O 0.209152 0.120281 0.017313 0.016 - 75 O 0.790848 0.879719 0.982687 0.016 - 76 O 0.897032 0.379719 0.588871 0.015 - 77 O 0.102968 0.620281 0.411129 0.015 - 78 O 0.602968 0.191839 0.482687 0.015 - 79 O 0.397032 0.808161 0.517313 0.015","# generated using pymatgen -data_Ca3V3(CoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.89507763 -_cell_length_b 10.89507763 -_cell_length_c 10.89507763 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3V3(CoO6)2 -_chemical_formula_sum 'Ca12 V12 Co8 O48' -_cell_volume 995.56379805 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - V V12 1 0.25000000 0.62500000 0.37500000 1 - V V13 1 0.75000000 0.37500000 0.62500000 1 - V V14 1 0.75000000 0.87500000 0.12500000 1 - V V15 1 0.37500000 0.25000000 0.62500000 1 - V V16 1 0.62500000 0.75000000 0.37500000 1 - V V17 1 0.25000000 0.12500000 0.87500000 1 - V V18 1 0.12500000 0.75000000 0.87500000 1 - V V19 1 0.87500000 0.25000000 0.12500000 1 - V V20 1 0.62500000 0.37500000 0.25000000 1 - V V21 1 0.37500000 0.62500000 0.75000000 1 - V V22 1 0.87500000 0.12500000 0.75000000 1 - V V23 1 0.12500000 0.87500000 0.25000000 1 - Co Co24 1 0.00000000 0.00000000 0.00000000 1 - Co Co25 1 0.50000000 0.00000000 0.50000000 1 - Co Co26 1 0.00000000 0.50000000 0.50000000 1 - Co Co27 1 0.50000000 0.00000000 0.00000000 1 - Co Co28 1 0.50000000 0.50000000 0.00000000 1 - Co Co29 1 0.50000000 0.50000000 0.50000000 1 - Co Co30 1 0.00000000 0.00000000 0.50000000 1 - Co Co31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.48268700 0.37971900 0.29084800 1 - O O33 1 0.51731300 0.62028100 0.70915200 1 - O O34 1 0.58887100 0.19183900 0.20915200 1 - O O35 1 0.91112900 0.12028100 0.60296800 1 - O O36 1 0.29084800 0.48268700 0.37971900 1 - O O37 1 0.30816100 0.91112900 0.29084800 1 - O O38 1 0.41112900 0.80816100 0.79084800 1 - O O39 1 0.08887100 0.87971900 0.39703200 1 - O O40 1 0.70915200 0.51731300 0.62028100 1 - O O41 1 0.69183900 0.08887100 0.70915200 1 - O O42 1 0.01731300 0.30816100 0.89703200 1 - O O43 1 0.20915200 0.58887100 0.19183900 1 - O O44 1 0.12028100 0.01731300 0.20915200 1 - O O45 1 0.98268700 0.69183900 0.10296800 1 - O O46 1 0.79084800 0.41112900 0.80816100 1 - O O47 1 0.87971900 0.98268700 0.79084800 1 - O O48 1 0.60296800 0.91112900 0.12028100 1 - O O49 1 0.19183900 0.48268700 0.60296800 1 - O O50 1 0.39703200 0.08887100 0.87971900 1 - O O51 1 0.80816100 0.51731300 0.39703200 1 - O O52 1 0.89703200 0.01731300 0.30816100 1 - O O53 1 0.37971900 0.58887100 0.89703200 1 - O O54 1 0.10296800 0.98268700 0.69183900 1 - O O55 1 0.62028100 0.41112900 0.10296800 1 - O O56 1 0.37971900 0.29084800 0.48268700 1 - O O57 1 0.58887100 0.89703200 0.37971900 1 - O O58 1 0.62028100 0.70915200 0.51731300 1 - O O59 1 0.41112900 0.10296800 0.62028100 1 - O O60 1 0.12028100 0.60296800 0.91112900 1 - O O61 1 0.01731300 0.20915200 0.12028100 1 - O O62 1 0.87971900 0.39703200 0.08887100 1 - O O63 1 0.98268700 0.79084800 0.87971900 1 - O O64 1 0.30816100 0.89703200 0.01731300 1 - O O65 1 0.91112900 0.29084800 0.30816100 1 - O O66 1 0.69183900 0.10296800 0.98268700 1 - O O67 1 0.08887100 0.70915200 0.69183900 1 - O O68 1 0.19183900 0.20915200 0.58887100 1 - O O69 1 0.48268700 0.60296800 0.19183900 1 - O O70 1 0.80816100 0.79084800 0.41112900 1 - O O71 1 0.51731300 0.39703200 0.80816100 1 - O O72 1 0.29084800 0.30816100 0.91112900 1 - O O73 1 0.70915200 0.69183900 0.08887100 1 - O O74 1 0.20915200 0.12028100 0.01731300 1 - O O75 1 0.79084800 0.87971900 0.98268700 1 - O O76 1 0.89703200 0.37971900 0.58887100 1 - O O77 1 0.10296800 0.62028100 0.41112900 1 - O O78 1 0.60296800 0.19183900 0.48268700 1 - O O79 1 0.39703200 0.80816100 0.51731300 1 -" -Ca3Ga3(SnO6)2,mp-1214159,Ia-3d,[],0.0,"{'tags': ['Ca3Ga2Sn3O12', 'garnet family']}","Full Formula (Ca12 Ga12 Sn8 O48) -Reduced Formula: Ca3Ga3(SnO6)2 -abc : 11.060960 11.060960 11.060960 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0.001 - 1 Ca 0.75 0.625 0.875 -0.001 - 2 Ca 0.75 0.125 0.375 -0.001 - 3 Ca 0.125 0.25 0.375 -0.001 - 4 Ca 0.375 0.75 0.125 -0.001 - 5 Ca 0.25 0.875 0.625 -0.001 - 6 Ca 0.875 0.75 0.625 -0.001 - 7 Ca 0.625 0.25 0.875 -0.001 - 8 Ca 0.375 0.125 0.25 -0.001 - 9 Ca 0.625 0.875 0.75 -0.001 - 10 Ca 0.125 0.375 0.75 -0.001 - 11 Ca 0.875 0.625 0.25 -0.001 - 12 Ga 0.25 0.625 0.375 -0.004 - 13 Ga 0.75 0.375 0.625 -0.004 - 14 Ga 0.75 0.875 0.125 -0.004 - 15 Ga 0.375 0.25 0.625 -0.002 - 16 Ga 0.625 0.75 0.375 -0.002 - 17 Ga 0.25 0.125 0.875 -0.004 - 18 Ga 0.125 0.75 0.875 -0.002 - 19 Ga 0.875 0.25 0.125 -0.002 - 20 Ga 0.625 0.375 0.25 -0.002 - 21 Ga 0.375 0.625 0.75 -0.002 - 22 Ga 0.875 0.125 0.75 -0.002 - 23 Ga 0.125 0.875 0.25 -0.002 - 24 Sn 0 0 0 -0.007 - 25 Sn 0.5 0 0.5 0 - 26 Sn 0 0.5 0.5 0 - 27 Sn 0.5 0 0 0 - 28 Sn 0.5 0.5 0 -0.007 - 29 Sn 0.5 0.5 0.5 -0.007 - 30 Sn 0 0 0.5 0 - 31 Sn 0 0.5 0 -0.007 - 32 O 0.477089 0.377437 0.295625 0.067 - 33 O 0.522911 0.622563 0.704375 0.067 - 34 O 0.581812 0.181464 0.204375 0.076 - 35 O 0.918188 0.122563 0.599652 0.076 - 36 O 0.295625 0.477089 0.377437 0.053 - 37 O 0.318536 0.918188 0.295625 0.096 - 38 O 0.418188 0.818536 0.795625 0.076 - 39 O 0.081812 0.877437 0.400348 0.076 - 40 O 0.704375 0.522911 0.622563 0.053 - 41 O 0.681464 0.081812 0.704375 0.096 - 42 O 0.022911 0.318536 0.900348 0.067 - 43 O 0.204375 0.581812 0.181464 0.053 - 44 O 0.122563 0.022911 0.204375 0.053 - 45 O 0.977089 0.681464 0.099652 0.067 - 46 O 0.795625 0.418188 0.818536 0.053 - 47 O 0.877437 0.977089 0.795625 0.053 - 48 O 0.599652 0.918188 0.122563 0.062 - 49 O 0.181464 0.477089 0.599652 0.096 - 50 O 0.400348 0.081812 0.877437 0.062 - 51 O 0.818536 0.522911 0.400348 0.096 - 52 O 0.900348 0.022911 0.318536 0.062 - 53 O 0.377437 0.581812 0.900348 0.053 - 54 O 0.099652 0.977089 0.681464 0.062 - 55 O 0.622563 0.418188 0.099652 0.053 - 56 O 0.377437 0.295625 0.477089 0.053 - 57 O 0.581812 0.900348 0.377437 0.076 - 58 O 0.622563 0.704375 0.522911 0.053 - 59 O 0.418188 0.099652 0.622563 0.076 - 60 O 0.122563 0.599652 0.918188 0.053 - 61 O 0.022911 0.204375 0.122563 0.067 - 62 O 0.877437 0.400348 0.081812 0.053 - 63 O 0.977089 0.795625 0.877437 0.067 - 64 O 0.318536 0.900348 0.022911 0.096 - 65 O 0.918188 0.295625 0.318536 0.076 - 66 O 0.681464 0.099652 0.977089 0.096 - 67 O 0.081812 0.704375 0.681464 0.076 - 68 O 0.181464 0.204375 0.581812 0.096 - 69 O 0.477089 0.599652 0.181464 0.067 - 70 O 0.818536 0.795625 0.418188 0.096 - 71 O 0.522911 0.400348 0.818536 0.067 - 72 O 0.295625 0.318536 0.918188 0.053 - 73 O 0.704375 0.681464 0.081812 0.053 - 74 O 0.204375 0.122563 0.022911 0.053 - 75 O 0.795625 0.877437 0.977089 0.053 - 76 O 0.900348 0.377437 0.581812 0.062 - 77 O 0.099652 0.622563 0.418188 0.062 - 78 O 0.599652 0.181464 0.477089 0.062 - 79 O 0.400348 0.818536 0.522911 0.062","# generated using pymatgen -data_Ca3Ga3(SnO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.06095960 -_cell_length_b 11.06095960 -_cell_length_c 11.06095960 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ga3(SnO6)2 -_chemical_formula_sum 'Ca12 Ga12 Sn8 O48' -_cell_volume 1041.73325185 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga13 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga14 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga17 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga18 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga19 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Sn Sn24 1 0.00000000 0.00000000 0.00000000 1 - Sn Sn25 1 0.50000000 0.00000000 0.50000000 1 - Sn Sn26 1 0.00000000 0.50000000 0.50000000 1 - Sn Sn27 1 0.50000000 0.00000000 0.00000000 1 - Sn Sn28 1 0.50000000 0.50000000 0.00000000 1 - Sn Sn29 1 0.50000000 0.50000000 0.50000000 1 - Sn Sn30 1 0.00000000 0.00000000 0.50000000 1 - Sn Sn31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47708900 0.37743700 0.29562500 1 - O O33 1 0.52291100 0.62256300 0.70437500 1 - O O34 1 0.58181200 0.18146400 0.20437500 1 - O O35 1 0.91818800 0.12256300 0.59965200 1 - O O36 1 0.29562500 0.47708900 0.37743700 1 - O O37 1 0.31853600 0.91818800 0.29562500 1 - O O38 1 0.41818800 0.81853600 0.79562500 1 - O O39 1 0.08181200 0.87743700 0.40034800 1 - O O40 1 0.70437500 0.52291100 0.62256300 1 - O O41 1 0.68146400 0.08181200 0.70437500 1 - O O42 1 0.02291100 0.31853600 0.90034800 1 - O O43 1 0.20437500 0.58181200 0.18146400 1 - O O44 1 0.12256300 0.02291100 0.20437500 1 - O O45 1 0.97708900 0.68146400 0.09965200 1 - O O46 1 0.79562500 0.41818800 0.81853600 1 - O O47 1 0.87743700 0.97708900 0.79562500 1 - O O48 1 0.59965200 0.91818800 0.12256300 1 - O O49 1 0.18146400 0.47708900 0.59965200 1 - O O50 1 0.40034800 0.08181200 0.87743700 1 - O O51 1 0.81853600 0.52291100 0.40034800 1 - O O52 1 0.90034800 0.02291100 0.31853600 1 - O O53 1 0.37743700 0.58181200 0.90034800 1 - O O54 1 0.09965200 0.97708900 0.68146400 1 - O O55 1 0.62256300 0.41818800 0.09965200 1 - O O56 1 0.37743700 0.29562500 0.47708900 1 - O O57 1 0.58181200 0.90034800 0.37743700 1 - O O58 1 0.62256300 0.70437500 0.52291100 1 - O O59 1 0.41818800 0.09965200 0.62256300 1 - O O60 1 0.12256300 0.59965200 0.91818800 1 - O O61 1 0.02291100 0.20437500 0.12256300 1 - O O62 1 0.87743700 0.40034800 0.08181200 1 - O O63 1 0.97708900 0.79562500 0.87743700 1 - O O64 1 0.31853600 0.90034800 0.02291100 1 - O O65 1 0.91818800 0.29562500 0.31853600 1 - O O66 1 0.68146400 0.09965200 0.97708900 1 - O O67 1 0.08181200 0.70437500 0.68146400 1 - O O68 1 0.18146400 0.20437500 0.58181200 1 - O O69 1 0.47708900 0.59965200 0.18146400 1 - O O70 1 0.81853600 0.79562500 0.41818800 1 - O O71 1 0.52291100 0.40034800 0.81853600 1 - O O72 1 0.29562500 0.31853600 0.91818800 1 - O O73 1 0.70437500 0.68146400 0.08181200 1 - O O74 1 0.20437500 0.12256300 0.02291100 1 - O O75 1 0.79562500 0.87743700 0.97708900 1 - O O76 1 0.90034800 0.37743700 0.58181200 1 - O O77 1 0.09965200 0.62256300 0.41818800 1 - O O78 1 0.59965200 0.18146400 0.47708900 1 - O O79 1 0.40034800 0.81853600 0.52291100 1 -" -Ca3V3(NiO6)2,mp-1214162,Ia-3d,[],0.01650998405359161,{'tags': ['garnet family']},"Full Formula (Ca12 V12 Ni8 O48) -Reduced Formula: Ca3V3(NiO6)2 -abc : 10.866568 10.866568 10.866568 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0.002 - 1 Ca 0.75 0.625 0.875 0.002 - 2 Ca 0.75 0.125 0.375 0.002 - 3 Ca 0.125 0.25 0.375 0.002 - 4 Ca 0.375 0.75 0.125 0.002 - 5 Ca 0.25 0.875 0.625 0.002 - 6 Ca 0.875 0.75 0.625 0.002 - 7 Ca 0.625 0.25 0.875 0.002 - 8 Ca 0.375 0.125 0.25 0.002 - 9 Ca 0.625 0.875 0.75 0.002 - 10 Ca 0.125 0.375 0.75 0.002 - 11 Ca 0.875 0.625 0.25 0.002 - 12 V 0.25 0.625 0.375 0.467 - 13 V 0.75 0.375 0.625 0.467 - 14 V 0.75 0.875 0.125 0.467 - 15 V 0.375 0.25 0.625 0.474 - 16 V 0.625 0.75 0.375 0.474 - 17 V 0.25 0.125 0.875 0.467 - 18 V 0.125 0.75 0.875 0.474 - 19 V 0.875 0.25 0.125 0.474 - 20 V 0.625 0.375 0.25 0.474 - 21 V 0.375 0.625 0.75 0.474 - 22 V 0.875 0.125 0.75 0.474 - 23 V 0.125 0.875 0.25 0.474 - 24 Ni 0 0 0 1.787 - 25 Ni 0.5 0 0.5 1.786 - 26 Ni 0 0.5 0.5 1.786 - 27 Ni 0.5 0 0 1.786 - 28 Ni 0.5 0.5 0 1.787 - 29 Ni 0.5 0.5 0.5 1.787 - 30 Ni 0 0 0.5 1.786 - 31 Ni 0 0.5 0 1.787 - 32 O 0.482523 0.380389 0.293124 -0.004 - 33 O 0.517477 0.619611 0.706876 -0.004 - 34 O 0.587265 0.189399 0.206876 -0.006 - 35 O 0.912735 0.119611 0.602134 -0.006 - 36 O 0.293124 0.482523 0.380389 -0.005 - 37 O 0.310601 0.912735 0.293124 -0.007 - 38 O 0.412735 0.810601 0.793124 -0.006 - 39 O 0.087265 0.880389 0.397866 -0.006 - 40 O 0.706876 0.517477 0.619611 -0.005 - 41 O 0.689399 0.087265 0.706876 -0.007 - 42 O 0.017477 0.310601 0.897866 -0.004 - 43 O 0.206876 0.587265 0.189399 -0.005 - 44 O 0.119611 0.017477 0.206876 -0.004 - 45 O 0.982523 0.689399 0.102134 -0.004 - 46 O 0.793124 0.412735 0.810601 -0.005 - 47 O 0.880389 0.982523 0.793124 -0.004 - 48 O 0.602134 0.912735 0.119611 -0.006 - 49 O 0.189399 0.482523 0.602134 -0.007 - 50 O 0.397866 0.087265 0.880389 -0.006 - 51 O 0.810601 0.517477 0.397866 -0.007 - 52 O 0.897866 0.017477 0.310601 -0.006 - 53 O 0.380389 0.587265 0.897866 -0.004 - 54 O 0.102134 0.982523 0.689399 -0.006 - 55 O 0.619611 0.412735 0.102134 -0.004 - 56 O 0.380389 0.293124 0.482523 -0.004 - 57 O 0.587265 0.897866 0.380389 -0.006 - 58 O 0.619611 0.706876 0.517477 -0.004 - 59 O 0.412735 0.102134 0.619611 -0.006 - 60 O 0.119611 0.602134 0.912735 -0.004 - 61 O 0.017477 0.206876 0.119611 -0.004 - 62 O 0.880389 0.397866 0.087265 -0.004 - 63 O 0.982523 0.793124 0.880389 -0.004 - 64 O 0.310601 0.897866 0.017477 -0.007 - 65 O 0.912735 0.293124 0.310601 -0.006 - 66 O 0.689399 0.102134 0.982523 -0.007 - 67 O 0.087265 0.706876 0.689399 -0.006 - 68 O 0.189399 0.206876 0.587265 -0.007 - 69 O 0.482523 0.602134 0.189399 -0.004 - 70 O 0.810601 0.793124 0.412735 -0.007 - 71 O 0.517477 0.397866 0.810601 -0.004 - 72 O 0.293124 0.310601 0.912735 -0.005 - 73 O 0.706876 0.689399 0.087265 -0.005 - 74 O 0.206876 0.119611 0.017477 -0.005 - 75 O 0.793124 0.880389 0.982523 -0.005 - 76 O 0.897866 0.380389 0.587265 -0.006 - 77 O 0.102134 0.619611 0.412735 -0.006 - 78 O 0.602134 0.189399 0.482523 -0.006 - 79 O 0.397866 0.810601 0.517477 -0.006","# generated using pymatgen -data_Ca3V3(NiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.86656807 -_cell_length_b 10.86656807 -_cell_length_c 10.86656807 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3V3(NiO6)2 -_chemical_formula_sum 'Ca12 V12 Ni8 O48' -_cell_volume 987.76884417 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - V V12 1 0.25000000 0.62500000 0.37500000 1 - V V13 1 0.75000000 0.37500000 0.62500000 1 - V V14 1 0.75000000 0.87500000 0.12500000 1 - V V15 1 0.37500000 0.25000000 0.62500000 1 - V V16 1 0.62500000 0.75000000 0.37500000 1 - V V17 1 0.25000000 0.12500000 0.87500000 1 - V V18 1 0.12500000 0.75000000 0.87500000 1 - V V19 1 0.87500000 0.25000000 0.12500000 1 - V V20 1 0.62500000 0.37500000 0.25000000 1 - V V21 1 0.37500000 0.62500000 0.75000000 1 - V V22 1 0.87500000 0.12500000 0.75000000 1 - V V23 1 0.12500000 0.87500000 0.25000000 1 - Ni Ni24 1 0.00000000 0.00000000 0.00000000 1 - Ni Ni25 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni26 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni27 1 0.50000000 0.00000000 0.00000000 1 - Ni Ni28 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni29 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni30 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.48252300 0.38038900 0.29312400 1 - O O33 1 0.51747700 0.61961100 0.70687600 1 - O O34 1 0.58726500 0.18939900 0.20687600 1 - O O35 1 0.91273500 0.11961100 0.60213400 1 - O O36 1 0.29312400 0.48252300 0.38038900 1 - O O37 1 0.31060100 0.91273500 0.29312400 1 - O O38 1 0.41273500 0.81060100 0.79312400 1 - O O39 1 0.08726500 0.88038900 0.39786600 1 - O O40 1 0.70687600 0.51747700 0.61961100 1 - O O41 1 0.68939900 0.08726500 0.70687600 1 - O O42 1 0.01747700 0.31060100 0.89786600 1 - O O43 1 0.20687600 0.58726500 0.18939900 1 - O O44 1 0.11961100 0.01747700 0.20687600 1 - O O45 1 0.98252300 0.68939900 0.10213400 1 - O O46 1 0.79312400 0.41273500 0.81060100 1 - O O47 1 0.88038900 0.98252300 0.79312400 1 - O O48 1 0.60213400 0.91273500 0.11961100 1 - O O49 1 0.18939900 0.48252300 0.60213400 1 - O O50 1 0.39786600 0.08726500 0.88038900 1 - O O51 1 0.81060100 0.51747700 0.39786600 1 - O O52 1 0.89786600 0.01747700 0.31060100 1 - O O53 1 0.38038900 0.58726500 0.89786600 1 - O O54 1 0.10213400 0.98252300 0.68939900 1 - O O55 1 0.61961100 0.41273500 0.10213400 1 - O O56 1 0.38038900 0.29312400 0.48252300 1 - O O57 1 0.58726500 0.89786600 0.38038900 1 - O O58 1 0.61961100 0.70687600 0.51747700 1 - O O59 1 0.41273500 0.10213400 0.61961100 1 - O O60 1 0.11961100 0.60213400 0.91273500 1 - O O61 1 0.01747700 0.20687600 0.11961100 1 - O O62 1 0.88038900 0.39786600 0.08726500 1 - O O63 1 0.98252300 0.79312400 0.88038900 1 - O O64 1 0.31060100 0.89786600 0.01747700 1 - O O65 1 0.91273500 0.29312400 0.31060100 1 - O O66 1 0.68939900 0.10213400 0.98252300 1 - O O67 1 0.08726500 0.70687600 0.68939900 1 - O O68 1 0.18939900 0.20687600 0.58726500 1 - O O69 1 0.48252300 0.60213400 0.18939900 1 - O O70 1 0.81060100 0.79312400 0.41273500 1 - O O71 1 0.51747700 0.39786600 0.81060100 1 - O O72 1 0.29312400 0.31060100 0.91273500 1 - O O73 1 0.70687600 0.68939900 0.08726500 1 - O O74 1 0.20687600 0.11961100 0.01747700 1 - O O75 1 0.79312400 0.88038900 0.98252300 1 - O O76 1 0.89786600 0.38038900 0.58726500 1 - O O77 1 0.10213400 0.61961100 0.41273500 1 - O O78 1 0.60213400 0.18939900 0.48252300 1 - O O79 1 0.39786600 0.81060100 0.51747700 1 -" -Ca3V3(CuO6)2,mp-1214197,Ia-3d,[],0.028659311500002005,{'tags': ['garnet family']},"Full Formula (Ca12 V12 Cu8 O48) -Reduced Formula: Ca3V3(CuO6)2 -abc : 10.880341 10.880341 10.880341 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.75 0.125 0.375 -0.001 - 3 Ca 0.125 0.25 0.375 -0 - 4 Ca 0.375 0.75 0.125 -0 - 5 Ca 0.25 0.875 0.625 -0.001 - 6 Ca 0.875 0.75 0.625 -0 - 7 Ca 0.625 0.25 0.875 -0 - 8 Ca 0.375 0.125 0.25 -0 - 9 Ca 0.625 0.875 0.75 -0 - 10 Ca 0.125 0.375 0.75 -0 - 11 Ca 0.875 0.625 0.25 -0 - 12 V 0.25 0.625 0.375 -0.042 - 13 V 0.75 0.375 0.625 -0.042 - 14 V 0.75 0.875 0.125 -0.042 - 15 V 0.375 0.25 0.625 -0.04 - 16 V 0.625 0.75 0.375 -0.04 - 17 V 0.25 0.125 0.875 -0.042 - 18 V 0.125 0.75 0.875 -0.04 - 19 V 0.875 0.25 0.125 -0.04 - 20 V 0.625 0.375 0.25 -0.04 - 21 V 0.375 0.625 0.75 -0.04 - 22 V 0.875 0.125 0.75 -0.04 - 23 V 0.125 0.875 0.25 -0.04 - 24 Cu 0 0 0 0.429 - 25 Cu 0.5 0 0.5 0.343 - 26 Cu 0 0.5 0.5 0.343 - 27 Cu 0.5 0 0 0.343 - 28 Cu 0.5 0.5 0 0.429 - 29 Cu 0.5 0.5 0.5 0.429 - 30 Cu 0 0 0.5 0.343 - 31 Cu 0 0.5 0 0.429 - 32 O 0.481191 0.379281 0.288086 0.028 - 33 O 0.518809 0.620719 0.711914 0.028 - 34 O 0.591195 0.193105 0.211914 0.027 - 35 O 0.908805 0.120719 0.60191 0.027 - 36 O 0.288086 0.481191 0.379281 0.024 - 37 O 0.306895 0.908805 0.288086 0.019 - 38 O 0.408805 0.806895 0.788086 0.027 - 39 O 0.091195 0.879281 0.39809 0.027 - 40 O 0.711914 0.518809 0.620719 0.024 - 41 O 0.693105 0.091195 0.711914 0.019 - 42 O 0.018809 0.306895 0.89809 0.028 - 43 O 0.211914 0.591195 0.193105 0.024 - 44 O 0.120719 0.018809 0.211914 0.036 - 45 O 0.981191 0.693105 0.10191 0.028 - 46 O 0.788086 0.408805 0.806895 0.024 - 47 O 0.879281 0.981191 0.788086 0.036 - 48 O 0.60191 0.908805 0.120719 0.028 - 49 O 0.193105 0.481191 0.60191 0.019 - 50 O 0.39809 0.091195 0.879281 0.028 - 51 O 0.806895 0.518809 0.39809 0.019 - 52 O 0.89809 0.018809 0.306895 0.028 - 53 O 0.379281 0.591195 0.89809 0.036 - 54 O 0.10191 0.981191 0.693105 0.028 - 55 O 0.620719 0.408805 0.10191 0.036 - 56 O 0.379281 0.288086 0.481191 0.036 - 57 O 0.591195 0.89809 0.379281 0.027 - 58 O 0.620719 0.711914 0.518809 0.036 - 59 O 0.408805 0.10191 0.620719 0.027 - 60 O 0.120719 0.60191 0.908805 0.036 - 61 O 0.018809 0.211914 0.120719 0.028 - 62 O 0.879281 0.39809 0.091195 0.036 - 63 O 0.981191 0.788086 0.879281 0.028 - 64 O 0.306895 0.89809 0.018809 0.019 - 65 O 0.908805 0.288086 0.306895 0.027 - 66 O 0.693105 0.10191 0.981191 0.019 - 67 O 0.091195 0.711914 0.693105 0.027 - 68 O 0.193105 0.211914 0.591195 0.019 - 69 O 0.481191 0.60191 0.193105 0.028 - 70 O 0.806895 0.788086 0.408805 0.019 - 71 O 0.518809 0.39809 0.806895 0.028 - 72 O 0.288086 0.306895 0.908805 0.024 - 73 O 0.711914 0.693105 0.091195 0.024 - 74 O 0.211914 0.120719 0.018809 0.024 - 75 O 0.788086 0.879281 0.981191 0.024 - 76 O 0.89809 0.379281 0.591195 0.028 - 77 O 0.10191 0.620719 0.408805 0.028 - 78 O 0.60191 0.193105 0.481191 0.028 - 79 O 0.39809 0.806895 0.518809 0.028","# generated using pymatgen -data_Ca3V3(CuO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.88034134 -_cell_length_b 10.88034134 -_cell_length_c 10.88034134 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3V3(CuO6)2 -_chemical_formula_sum 'Ca12 V12 Cu8 O48' -_cell_volume 991.52956868 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - V V12 1 0.25000000 0.62500000 0.37500000 1 - V V13 1 0.75000000 0.37500000 0.62500000 1 - V V14 1 0.75000000 0.87500000 0.12500000 1 - V V15 1 0.37500000 0.25000000 0.62500000 1 - V V16 1 0.62500000 0.75000000 0.37500000 1 - V V17 1 0.25000000 0.12500000 0.87500000 1 - V V18 1 0.12500000 0.75000000 0.87500000 1 - V V19 1 0.87500000 0.25000000 0.12500000 1 - V V20 1 0.62500000 0.37500000 0.25000000 1 - V V21 1 0.37500000 0.62500000 0.75000000 1 - V V22 1 0.87500000 0.12500000 0.75000000 1 - V V23 1 0.12500000 0.87500000 0.25000000 1 - Cu Cu24 1 0.00000000 0.00000000 0.00000000 1 - Cu Cu25 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu26 1 0.00000000 0.50000000 0.50000000 1 - Cu Cu27 1 0.50000000 0.00000000 0.00000000 1 - Cu Cu28 1 0.50000000 0.50000000 0.00000000 1 - Cu Cu29 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu30 1 0.00000000 0.00000000 0.50000000 1 - Cu Cu31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.48119100 0.37928100 0.28808600 1 - O O33 1 0.51880900 0.62071900 0.71191400 1 - O O34 1 0.59119500 0.19310500 0.21191400 1 - O O35 1 0.90880500 0.12071900 0.60191000 1 - O O36 1 0.28808600 0.48119100 0.37928100 1 - O O37 1 0.30689500 0.90880500 0.28808600 1 - O O38 1 0.40880500 0.80689500 0.78808600 1 - O O39 1 0.09119500 0.87928100 0.39809000 1 - O O40 1 0.71191400 0.51880900 0.62071900 1 - O O41 1 0.69310500 0.09119500 0.71191400 1 - O O42 1 0.01880900 0.30689500 0.89809000 1 - O O43 1 0.21191400 0.59119500 0.19310500 1 - O O44 1 0.12071900 0.01880900 0.21191400 1 - O O45 1 0.98119100 0.69310500 0.10191000 1 - O O46 1 0.78808600 0.40880500 0.80689500 1 - O O47 1 0.87928100 0.98119100 0.78808600 1 - O O48 1 0.60191000 0.90880500 0.12071900 1 - O O49 1 0.19310500 0.48119100 0.60191000 1 - O O50 1 0.39809000 0.09119500 0.87928100 1 - O O51 1 0.80689500 0.51880900 0.39809000 1 - O O52 1 0.89809000 0.01880900 0.30689500 1 - O O53 1 0.37928100 0.59119500 0.89809000 1 - O O54 1 0.10191000 0.98119100 0.69310500 1 - O O55 1 0.62071900 0.40880500 0.10191000 1 - O O56 1 0.37928100 0.28808600 0.48119100 1 - O O57 1 0.59119500 0.89809000 0.37928100 1 - O O58 1 0.62071900 0.71191400 0.51880900 1 - O O59 1 0.40880500 0.10191000 0.62071900 1 - O O60 1 0.12071900 0.60191000 0.90880500 1 - O O61 1 0.01880900 0.21191400 0.12071900 1 - O O62 1 0.87928100 0.39809000 0.09119500 1 - O O63 1 0.98119100 0.78808600 0.87928100 1 - O O64 1 0.30689500 0.89809000 0.01880900 1 - O O65 1 0.90880500 0.28808600 0.30689500 1 - O O66 1 0.69310500 0.10191000 0.98119100 1 - O O67 1 0.09119500 0.71191400 0.69310500 1 - O O68 1 0.19310500 0.21191400 0.59119500 1 - O O69 1 0.48119100 0.60191000 0.19310500 1 - O O70 1 0.80689500 0.78808600 0.40880500 1 - O O71 1 0.51880900 0.39809000 0.80689500 1 - O O72 1 0.28808600 0.30689500 0.90880500 1 - O O73 1 0.71191400 0.69310500 0.09119500 1 - O O74 1 0.21191400 0.12071900 0.01880900 1 - O O75 1 0.78808600 0.87928100 0.98119100 1 - O O76 1 0.89809000 0.37928100 0.59119500 1 - O O77 1 0.10191000 0.62071900 0.40880500 1 - O O78 1 0.60191000 0.19310500 0.48119100 1 - O O79 1 0.39809000 0.80689500 0.51880900 1 -" -Ca3Y2(SiO4)3,mp-1214208,Ia-3d,[],0.0255135295416693,{'tags': []},"Full Formula (Ca12 Y8 Si12 O48) -Reduced Formula: Ca3Y2(SiO4)3 -abc : 10.990437 10.990437 10.990437 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0 - 1 Ca 0.75 0.625 0.875 -0 - 2 Ca 0.75 0.125 0.375 -0 - 3 Ca 0.125 0.25 0.375 -0 - 4 Ca 0.375 0.75 0.125 -0 - 5 Ca 0.25 0.875 0.625 -0 - 6 Ca 0.875 0.75 0.625 -0 - 7 Ca 0.625 0.25 0.875 -0 - 8 Ca 0.375 0.125 0.25 -0 - 9 Ca 0.625 0.875 0.75 -0 - 10 Ca 0.125 0.375 0.75 -0 - 11 Ca 0.875 0.625 0.25 -0 - 12 Y 0 0 0 0 - 13 Y 0.5 0 0.5 0 - 14 Y 0 0.5 0.5 0 - 15 Y 0.5 0 0 0 - 16 Y 0.5 0.5 0 0 - 17 Y 0.5 0.5 0.5 0 - 18 Y 0 0 0.5 0 - 19 Y 0 0.5 0 0 - 20 Si 0.25 0.625 0.375 0 - 21 Si 0.75 0.375 0.625 0 - 22 Si 0.75 0.875 0.125 0 - 23 Si 0.375 0.25 0.625 0 - 24 Si 0.625 0.75 0.375 0 - 25 Si 0.25 0.125 0.875 0 - 26 Si 0.125 0.75 0.875 0 - 27 Si 0.875 0.25 0.125 0 - 28 Si 0.625 0.375 0.25 0 - 29 Si 0.375 0.625 0.75 0 - 30 Si 0.875 0.125 0.75 0 - 31 Si 0.125 0.875 0.25 0 - 32 O 0.487967 0.37727 0.282523 -0 - 33 O 0.512033 0.62273 0.717477 -0 - 34 O 0.594747 0.205444 0.217477 -0 - 35 O 0.905253 0.12273 0.610697 -0 - 36 O 0.282523 0.487967 0.37727 -0 - 37 O 0.294556 0.905253 0.282523 -0 - 38 O 0.405253 0.794556 0.782523 -0 - 39 O 0.094747 0.87727 0.389303 -0 - 40 O 0.717477 0.512033 0.62273 -0 - 41 O 0.705444 0.094747 0.717477 -0 - 42 O 0.012033 0.294556 0.889303 -0 - 43 O 0.217477 0.594747 0.205444 -0 - 44 O 0.12273 0.012033 0.217477 -0 - 45 O 0.987967 0.705444 0.110697 -0 - 46 O 0.782523 0.405253 0.794556 -0 - 47 O 0.87727 0.987967 0.782523 -0 - 48 O 0.610697 0.905253 0.12273 -0 - 49 O 0.205444 0.487967 0.610697 -0 - 50 O 0.389303 0.094747 0.87727 -0 - 51 O 0.794556 0.512033 0.389303 -0 - 52 O 0.889303 0.012033 0.294556 -0 - 53 O 0.37727 0.594747 0.889303 -0 - 54 O 0.110697 0.987967 0.705444 -0 - 55 O 0.62273 0.405253 0.110697 -0 - 56 O 0.37727 0.282523 0.487967 -0 - 57 O 0.594747 0.889303 0.37727 -0 - 58 O 0.62273 0.717477 0.512033 -0 - 59 O 0.405253 0.110697 0.62273 -0 - 60 O 0.12273 0.610697 0.905253 -0 - 61 O 0.012033 0.217477 0.12273 -0 - 62 O 0.87727 0.389303 0.094747 -0 - 63 O 0.987967 0.782523 0.87727 -0 - 64 O 0.294556 0.889303 0.012033 -0 - 65 O 0.905253 0.282523 0.294556 -0 - 66 O 0.705444 0.110697 0.987967 -0 - 67 O 0.094747 0.717477 0.705444 -0 - 68 O 0.205444 0.217477 0.594747 -0 - 69 O 0.487967 0.610697 0.205444 -0 - 70 O 0.794556 0.782523 0.405253 -0 - 71 O 0.512033 0.389303 0.794556 -0 - 72 O 0.282523 0.294556 0.905253 -0 - 73 O 0.717477 0.705444 0.094747 -0 - 74 O 0.217477 0.12273 0.012033 -0 - 75 O 0.782523 0.87727 0.987967 -0 - 76 O 0.889303 0.37727 0.594747 -0 - 77 O 0.110697 0.62273 0.405253 -0 - 78 O 0.610697 0.205444 0.487967 -0 - 79 O 0.389303 0.794556 0.512033 -0","# generated using pymatgen -data_Ca3Y2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.99043741 -_cell_length_b 10.99043741 -_cell_length_c 10.99043741 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Y2(SiO4)3 -_chemical_formula_sum 'Ca12 Y8 Si12 O48' -_cell_volume 1021.93445485 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Y Y12 1 0.00000000 0.00000000 0.00000000 1 - Y Y13 1 0.50000000 0.00000000 0.50000000 1 - Y Y14 1 0.00000000 0.50000000 0.50000000 1 - Y Y15 1 0.50000000 0.00000000 0.00000000 1 - Y Y16 1 0.50000000 0.50000000 0.00000000 1 - Y Y17 1 0.50000000 0.50000000 0.50000000 1 - Y Y18 1 0.00000000 0.00000000 0.50000000 1 - Y Y19 1 0.00000000 0.50000000 0.00000000 1 - Si Si20 1 0.25000000 0.62500000 0.37500000 1 - Si Si21 1 0.75000000 0.37500000 0.62500000 1 - Si Si22 1 0.75000000 0.87500000 0.12500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.25000000 0.12500000 0.87500000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.87500000 0.25000000 0.12500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.37500000 0.62500000 0.75000000 1 - Si Si30 1 0.87500000 0.12500000 0.75000000 1 - Si Si31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48796700 0.37727000 0.28252300 1 - O O33 1 0.51203300 0.62273000 0.71747700 1 - O O34 1 0.59474700 0.20544400 0.21747700 1 - O O35 1 0.90525300 0.12273000 0.61069700 1 - O O36 1 0.28252300 0.48796700 0.37727000 1 - O O37 1 0.29455600 0.90525300 0.28252300 1 - O O38 1 0.40525300 0.79455600 0.78252300 1 - O O39 1 0.09474700 0.87727000 0.38930300 1 - O O40 1 0.71747700 0.51203300 0.62273000 1 - O O41 1 0.70544400 0.09474700 0.71747700 1 - O O42 1 0.01203300 0.29455600 0.88930300 1 - O O43 1 0.21747700 0.59474700 0.20544400 1 - O O44 1 0.12273000 0.01203300 0.21747700 1 - O O45 1 0.98796700 0.70544400 0.11069700 1 - O O46 1 0.78252300 0.40525300 0.79455600 1 - O O47 1 0.87727000 0.98796700 0.78252300 1 - O O48 1 0.61069700 0.90525300 0.12273000 1 - O O49 1 0.20544400 0.48796700 0.61069700 1 - O O50 1 0.38930300 0.09474700 0.87727000 1 - O O51 1 0.79455600 0.51203300 0.38930300 1 - O O52 1 0.88930300 0.01203300 0.29455600 1 - O O53 1 0.37727000 0.59474700 0.88930300 1 - O O54 1 0.11069700 0.98796700 0.70544400 1 - O O55 1 0.62273000 0.40525300 0.11069700 1 - O O56 1 0.37727000 0.28252300 0.48796700 1 - O O57 1 0.59474700 0.88930300 0.37727000 1 - O O58 1 0.62273000 0.71747700 0.51203300 1 - O O59 1 0.40525300 0.11069700 0.62273000 1 - O O60 1 0.12273000 0.61069700 0.90525300 1 - O O61 1 0.01203300 0.21747700 0.12273000 1 - O O62 1 0.87727000 0.38930300 0.09474700 1 - O O63 1 0.98796700 0.78252300 0.87727000 1 - O O64 1 0.29455600 0.88930300 0.01203300 1 - O O65 1 0.90525300 0.28252300 0.29455600 1 - O O66 1 0.70544400 0.11069700 0.98796700 1 - O O67 1 0.09474700 0.71747700 0.70544400 1 - O O68 1 0.20544400 0.21747700 0.59474700 1 - O O69 1 0.48796700 0.61069700 0.20544400 1 - O O70 1 0.79455600 0.78252300 0.40525300 1 - O O71 1 0.51203300 0.38930300 0.79455600 1 - O O72 1 0.28252300 0.29455600 0.90525300 1 - O O73 1 0.71747700 0.70544400 0.09474700 1 - O O74 1 0.21747700 0.12273000 0.01203300 1 - O O75 1 0.78252300 0.87727000 0.98796700 1 - O O76 1 0.88930300 0.37727000 0.59474700 1 - O O77 1 0.11069700 0.62273000 0.40525300 1 - O O78 1 0.61069700 0.20544400 0.48796700 1 - O O79 1 0.38930300 0.79455600 0.51203300 1 -" -Ca3Al2(GeO4)3,mp-1214222,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Ca12 Al8 Ge12 O48) -Reduced Formula: Ca3Al2(GeO4)3 -abc : 10.608077 10.608077 10.608077 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0 - 1 Ca 0.75 0.625 0.875 -0 - 2 Ca 0.75 0.125 0.375 -0 - 3 Ca 0.125 0.25 0.375 -0 - 4 Ca 0.375 0.75 0.125 -0 - 5 Ca 0.25 0.875 0.625 -0 - 6 Ca 0.875 0.75 0.625 -0 - 7 Ca 0.625 0.25 0.875 -0 - 8 Ca 0.375 0.125 0.25 -0 - 9 Ca 0.625 0.875 0.75 -0 - 10 Ca 0.125 0.375 0.75 -0 - 11 Ca 0.875 0.625 0.25 -0 - 12 Al 0 0 0 -0 - 13 Al 0.5 0 0.5 -0 - 14 Al 0 0.5 0.5 -0 - 15 Al 0.5 0 0 -0 - 16 Al 0.5 0.5 0 -0 - 17 Al 0.5 0.5 0.5 -0 - 18 Al 0 0 0.5 -0 - 19 Al 0 0.5 0 -0 - 20 Ge 0.25 0.625 0.375 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.75 0.875 0.125 -0 - 23 Ge 0.375 0.25 0.625 -0 - 24 Ge 0.625 0.75 0.375 -0 - 25 Ge 0.25 0.125 0.875 -0 - 26 Ge 0.125 0.75 0.875 -0 - 27 Ge 0.875 0.25 0.125 -0 - 28 Ge 0.625 0.375 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.875 0.125 0.75 -0 - 31 Ge 0.125 0.875 0.25 -0 - 32 O 0.485204 0.384575 0.305141 0 - 33 O 0.514796 0.615425 0.694859 0 - 34 O 0.579434 0.180063 0.194859 0 - 35 O 0.920566 0.115425 0.600629 0 - 36 O 0.305141 0.485204 0.384575 0 - 37 O 0.319937 0.920566 0.305141 0 - 38 O 0.420566 0.819937 0.805141 0 - 39 O 0.079434 0.884575 0.399371 0 - 40 O 0.694859 0.514796 0.615425 0 - 41 O 0.680063 0.079434 0.694859 0 - 42 O 0.014796 0.319937 0.899371 0 - 43 O 0.194859 0.579434 0.180063 0 - 44 O 0.115425 0.014796 0.194859 0 - 45 O 0.985204 0.680063 0.100629 0 - 46 O 0.805141 0.420566 0.819937 0 - 47 O 0.884575 0.985204 0.805141 0 - 48 O 0.600629 0.920566 0.115425 0 - 49 O 0.180063 0.485204 0.600629 0 - 50 O 0.399371 0.079434 0.884575 0 - 51 O 0.819937 0.514796 0.399371 0 - 52 O 0.899371 0.014796 0.319937 0 - 53 O 0.384575 0.579434 0.899371 0 - 54 O 0.100629 0.985204 0.680063 0 - 55 O 0.615425 0.420566 0.100629 0 - 56 O 0.384575 0.305141 0.485204 0 - 57 O 0.579434 0.899371 0.384575 0 - 58 O 0.615425 0.694859 0.514796 0 - 59 O 0.420566 0.100629 0.615425 0 - 60 O 0.115425 0.600629 0.920566 0 - 61 O 0.014796 0.194859 0.115425 0 - 62 O 0.884575 0.399371 0.079434 0 - 63 O 0.985204 0.805141 0.884575 0 - 64 O 0.319937 0.899371 0.014796 0 - 65 O 0.920566 0.305141 0.319937 0 - 66 O 0.680063 0.100629 0.985204 0 - 67 O 0.079434 0.694859 0.680063 0 - 68 O 0.180063 0.194859 0.579434 0 - 69 O 0.485204 0.600629 0.180063 0 - 70 O 0.819937 0.805141 0.420566 0 - 71 O 0.514796 0.399371 0.819937 0 - 72 O 0.305141 0.319937 0.920566 0 - 73 O 0.694859 0.680063 0.079434 0 - 74 O 0.194859 0.115425 0.014796 0 - 75 O 0.805141 0.884575 0.985204 0 - 76 O 0.899371 0.384575 0.579434 0 - 77 O 0.100629 0.615425 0.420566 0 - 78 O 0.600629 0.180063 0.485204 0 - 79 O 0.399371 0.819937 0.514796 0","# generated using pymatgen -data_Ca3Al2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.60807681 -_cell_length_b 10.60807681 -_cell_length_c 10.60807681 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Al2(GeO4)3 -_chemical_formula_sum 'Ca12 Al8 Ge12 O48' -_cell_volume 918.94194621 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.00000000 0.00000000 0.00000000 1 - Al Al13 1 0.50000000 0.00000000 0.50000000 1 - Al Al14 1 0.00000000 0.50000000 0.50000000 1 - Al Al15 1 0.50000000 0.00000000 0.00000000 1 - Al Al16 1 0.50000000 0.50000000 0.00000000 1 - Al Al17 1 0.50000000 0.50000000 0.50000000 1 - Al Al18 1 0.00000000 0.00000000 0.50000000 1 - Al Al19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48520400 0.38457500 0.30514100 1 - O O33 1 0.51479600 0.61542500 0.69485900 1 - O O34 1 0.57943400 0.18006300 0.19485900 1 - O O35 1 0.92056600 0.11542500 0.60062900 1 - O O36 1 0.30514100 0.48520400 0.38457500 1 - O O37 1 0.31993700 0.92056600 0.30514100 1 - O O38 1 0.42056600 0.81993700 0.80514100 1 - O O39 1 0.07943400 0.88457500 0.39937100 1 - O O40 1 0.69485900 0.51479600 0.61542500 1 - O O41 1 0.68006300 0.07943400 0.69485900 1 - O O42 1 0.01479600 0.31993700 0.89937100 1 - O O43 1 0.19485900 0.57943400 0.18006300 1 - O O44 1 0.11542500 0.01479600 0.19485900 1 - O O45 1 0.98520400 0.68006300 0.10062900 1 - O O46 1 0.80514100 0.42056600 0.81993700 1 - O O47 1 0.88457500 0.98520400 0.80514100 1 - O O48 1 0.60062900 0.92056600 0.11542500 1 - O O49 1 0.18006300 0.48520400 0.60062900 1 - O O50 1 0.39937100 0.07943400 0.88457500 1 - O O51 1 0.81993700 0.51479600 0.39937100 1 - O O52 1 0.89937100 0.01479600 0.31993700 1 - O O53 1 0.38457500 0.57943400 0.89937100 1 - O O54 1 0.10062900 0.98520400 0.68006300 1 - O O55 1 0.61542500 0.42056600 0.10062900 1 - O O56 1 0.38457500 0.30514100 0.48520400 1 - O O57 1 0.57943400 0.89937100 0.38457500 1 - O O58 1 0.61542500 0.69485900 0.51479600 1 - O O59 1 0.42056600 0.10062900 0.61542500 1 - O O60 1 0.11542500 0.60062900 0.92056600 1 - O O61 1 0.01479600 0.19485900 0.11542500 1 - O O62 1 0.88457500 0.39937100 0.07943400 1 - O O63 1 0.98520400 0.80514100 0.88457500 1 - O O64 1 0.31993700 0.89937100 0.01479600 1 - O O65 1 0.92056600 0.30514100 0.31993700 1 - O O66 1 0.68006300 0.10062900 0.98520400 1 - O O67 1 0.07943400 0.69485900 0.68006300 1 - O O68 1 0.18006300 0.19485900 0.57943400 1 - O O69 1 0.48520400 0.60062900 0.18006300 1 - O O70 1 0.81993700 0.80514100 0.42056600 1 - O O71 1 0.51479600 0.39937100 0.81993700 1 - O O72 1 0.30514100 0.31993700 0.92056600 1 - O O73 1 0.69485900 0.68006300 0.07943400 1 - O O74 1 0.19485900 0.11542500 0.01479600 1 - O O75 1 0.80514100 0.88457500 0.98520400 1 - O O76 1 0.89937100 0.38457500 0.57943400 1 - O O77 1 0.10062900 0.61542500 0.42056600 1 - O O78 1 0.60062900 0.18006300 0.48520400 1 - O O79 1 0.39937100 0.81993700 0.51479600 1 -" -Ca3Fe3(SbO6)2,mp-1214233,Ia-3d,[],0.010347790625003128,"{'tags': ['garnet family', 'Ca3Fe3Sb2O12']}","Full Formula (Ca12 Fe12 Sb8 O48) -Reduced Formula: Ca3Fe3(SbO6)2 -abc : 11.091206 11.091206 11.091206 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0.002 - 1 Ca 0.75 0.625 0.875 0.002 - 2 Ca 0.75 0.125 0.375 0.002 - 3 Ca 0.125 0.25 0.375 0.002 - 4 Ca 0.375 0.75 0.125 0.002 - 5 Ca 0.25 0.875 0.625 0.002 - 6 Ca 0.875 0.75 0.625 0.002 - 7 Ca 0.625 0.25 0.875 0.002 - 8 Ca 0.375 0.125 0.25 0.002 - 9 Ca 0.625 0.875 0.75 0.003 - 10 Ca 0.125 0.375 0.75 0.002 - 11 Ca 0.875 0.625 0.25 0.002 - 12 Fe 0.25 0.625 0.375 4.092 - 13 Fe 0.75 0.375 0.625 4.044 - 14 Fe 0.75 0.875 0.125 4.143 - 15 Fe 0.375 0.25 0.625 4.171 - 16 Fe 0.625 0.75 0.375 4.171 - 17 Fe 0.25 0.125 0.875 4.134 - 18 Fe 0.125 0.75 0.875 4.15 - 19 Fe 0.875 0.25 0.125 4.166 - 20 Fe 0.625 0.375 0.25 4.148 - 21 Fe 0.375 0.625 0.75 4.114 - 22 Fe 0.875 0.125 0.75 4.169 - 23 Fe 0.125 0.875 0.25 4.15 - 24 Sb 0 0 0 0.003 - 25 Sb 0.5 0 0.5 0.007 - 26 Sb 0 0.5 0.5 0.009 - 27 Sb 0.5 0 0 0.005 - 28 Sb 0.5 0.5 0 0.005 - 29 Sb 0.5 0.5 0.5 0.009 - 30 Sb 0 0 0.5 0.002 - 31 Sb 0 0.5 0 0.008 - 32 O 0.476787 0.380415 0.301655 0.097 - 33 O 0.523213 0.619585 0.698345 0.096 - 34 O 0.57876 0.175133 0.198345 0.097 - 35 O 0.92124 0.119585 0.596373 0.1 - 36 O 0.301655 0.476787 0.380415 0.087 - 37 O 0.324867 0.92124 0.301655 0.1 - 38 O 0.42124 0.824867 0.801655 0.095 - 39 O 0.07876 0.880415 0.403627 0.099 - 40 O 0.698345 0.523213 0.619585 0.092 - 41 O 0.675133 0.07876 0.698345 0.101 - 42 O 0.023213 0.324867 0.903627 0.102 - 43 O 0.198345 0.57876 0.175133 0.086 - 44 O 0.119585 0.023213 0.198345 0.099 - 45 O 0.976787 0.675133 0.096373 0.101 - 46 O 0.801655 0.42124 0.824867 0.092 - 47 O 0.880415 0.976787 0.801655 0.101 - 48 O 0.596373 0.92124 0.119585 0.099 - 49 O 0.175133 0.476787 0.596373 0.097 - 50 O 0.403627 0.07876 0.880415 0.099 - 51 O 0.824867 0.523213 0.403627 0.098 - 52 O 0.903627 0.023213 0.324867 0.099 - 53 O 0.380415 0.57876 0.903627 0.096 - 54 O 0.096373 0.976787 0.675133 0.099 - 55 O 0.619585 0.42124 0.096373 0.097 - 56 O 0.380415 0.301655 0.476787 0.102 - 57 O 0.57876 0.903627 0.380415 0.1 - 58 O 0.619585 0.698345 0.523213 0.101 - 59 O 0.42124 0.096373 0.619585 0.102 - 60 O 0.119585 0.596373 0.92124 0.1 - 61 O 0.023213 0.198345 0.119585 0.098 - 62 O 0.880415 0.403627 0.07876 0.1 - 63 O 0.976787 0.801655 0.880415 0.098 - 64 O 0.324867 0.903627 0.023213 0.099 - 65 O 0.92124 0.301655 0.324867 0.1 - 66 O 0.675133 0.096373 0.976787 0.099 - 67 O 0.07876 0.698345 0.675133 0.1 - 68 O 0.175133 0.198345 0.57876 0.1 - 69 O 0.476787 0.596373 0.175133 0.1 - 70 O 0.824867 0.801655 0.42124 0.099 - 71 O 0.523213 0.403627 0.824867 0.101 - 72 O 0.301655 0.324867 0.92124 0.099 - 73 O 0.698345 0.675133 0.07876 0.1 - 74 O 0.198345 0.119585 0.023213 0.099 - 75 O 0.801655 0.880415 0.976787 0.099 - 76 O 0.903627 0.380415 0.57876 0.093 - 77 O 0.096373 0.619585 0.42124 0.087 - 78 O 0.596373 0.175133 0.476787 0.092 - 79 O 0.403627 0.824867 0.523213 0.087","# generated using pymatgen -data_Ca3Fe3(SbO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.09120640 -_cell_length_b 11.09120640 -_cell_length_c 11.09120640 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Fe3(SbO6)2 -_chemical_formula_sum 'Ca12 Fe12 Sb8 O48' -_cell_volume 1050.30267362 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe12 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe13 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe14 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe15 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe16 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe17 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe18 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe19 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe20 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe21 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe22 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe23 1 0.12500000 0.87500000 0.25000000 1 - Sb Sb24 1 0.00000000 0.00000000 0.00000000 1 - Sb Sb25 1 0.50000000 0.00000000 0.50000000 1 - Sb Sb26 1 0.00000000 0.50000000 0.50000000 1 - Sb Sb27 1 0.50000000 0.00000000 0.00000000 1 - Sb Sb28 1 0.50000000 0.50000000 0.00000000 1 - Sb Sb29 1 0.50000000 0.50000000 0.50000000 1 - Sb Sb30 1 0.00000000 0.00000000 0.50000000 1 - Sb Sb31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47678700 0.38041500 0.30165500 1 - O O33 1 0.52321300 0.61958500 0.69834500 1 - O O34 1 0.57876000 0.17513300 0.19834500 1 - O O35 1 0.92124000 0.11958500 0.59637300 1 - O O36 1 0.30165500 0.47678700 0.38041500 1 - O O37 1 0.32486700 0.92124000 0.30165500 1 - O O38 1 0.42124000 0.82486700 0.80165500 1 - O O39 1 0.07876000 0.88041500 0.40362700 1 - O O40 1 0.69834500 0.52321300 0.61958500 1 - O O41 1 0.67513300 0.07876000 0.69834500 1 - O O42 1 0.02321300 0.32486700 0.90362700 1 - O O43 1 0.19834500 0.57876000 0.17513300 1 - O O44 1 0.11958500 0.02321300 0.19834500 1 - O O45 1 0.97678700 0.67513300 0.09637300 1 - O O46 1 0.80165500 0.42124000 0.82486700 1 - O O47 1 0.88041500 0.97678700 0.80165500 1 - O O48 1 0.59637300 0.92124000 0.11958500 1 - O O49 1 0.17513300 0.47678700 0.59637300 1 - O O50 1 0.40362700 0.07876000 0.88041500 1 - O O51 1 0.82486700 0.52321300 0.40362700 1 - O O52 1 0.90362700 0.02321300 0.32486700 1 - O O53 1 0.38041500 0.57876000 0.90362700 1 - O O54 1 0.09637300 0.97678700 0.67513300 1 - O O55 1 0.61958500 0.42124000 0.09637300 1 - O O56 1 0.38041500 0.30165500 0.47678700 1 - O O57 1 0.57876000 0.90362700 0.38041500 1 - O O58 1 0.61958500 0.69834500 0.52321300 1 - O O59 1 0.42124000 0.09637300 0.61958500 1 - O O60 1 0.11958500 0.59637300 0.92124000 1 - O O61 1 0.02321300 0.19834500 0.11958500 1 - O O62 1 0.88041500 0.40362700 0.07876000 1 - O O63 1 0.97678700 0.80165500 0.88041500 1 - O O64 1 0.32486700 0.90362700 0.02321300 1 - O O65 1 0.92124000 0.30165500 0.32486700 1 - O O66 1 0.67513300 0.09637300 0.97678700 1 - O O67 1 0.07876000 0.69834500 0.67513300 1 - O O68 1 0.17513300 0.19834500 0.57876000 1 - O O69 1 0.47678700 0.59637300 0.17513300 1 - O O70 1 0.82486700 0.80165500 0.42124000 1 - O O71 1 0.52321300 0.40362700 0.82486700 1 - O O72 1 0.30165500 0.32486700 0.92124000 1 - O O73 1 0.69834500 0.67513300 0.07876000 1 - O O74 1 0.19834500 0.11958500 0.02321300 1 - O O75 1 0.80165500 0.88041500 0.97678700 1 - O O76 1 0.90362700 0.38041500 0.57876000 1 - O O77 1 0.09637300 0.61958500 0.42124000 1 - O O78 1 0.59637300 0.17513300 0.47678700 1 - O O79 1 0.40362700 0.82486700 0.52321300 1 -" -Ca3In2(GeO4)3,mp-1214247,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Ca12 In8 Ge12 O48) -Reduced Formula: Ca3In2(GeO4)3 -abc : 11.047017 11.047017 11.047017 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0 - 1 Ca 0.75 0.625 0.875 -0 - 2 Ca 0.75 0.125 0.375 -0 - 3 Ca 0.125 0.25 0.375 -0 - 4 Ca 0.375 0.75 0.125 -0 - 5 Ca 0.25 0.875 0.625 -0 - 6 Ca 0.875 0.75 0.625 -0 - 7 Ca 0.625 0.25 0.875 -0 - 8 Ca 0.375 0.125 0.25 -0 - 9 Ca 0.625 0.875 0.75 -0 - 10 Ca 0.125 0.375 0.75 -0 - 11 Ca 0.875 0.625 0.25 -0 - 12 In 0 0 0 -0 - 13 In 0.5 0 0.5 -0 - 14 In 0 0.5 0.5 -0 - 15 In 0.5 0 0 -0 - 16 In 0.5 0.5 0 -0 - 17 In 0.5 0.5 0.5 -0 - 18 In 0 0 0.5 -0 - 19 In 0 0.5 0 -0 - 20 Ge 0.25 0.625 0.375 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.75 0.875 0.125 -0 - 23 Ge 0.375 0.25 0.625 -0 - 24 Ge 0.625 0.75 0.375 -0 - 25 Ge 0.25 0.125 0.875 -0 - 26 Ge 0.125 0.75 0.875 -0 - 27 Ge 0.875 0.25 0.125 -0 - 28 Ge 0.625 0.375 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.875 0.125 0.75 -0 - 31 Ge 0.125 0.875 0.25 -0 - 32 O 0.479582 0.375872 0.287522 0 - 33 O 0.520418 0.624128 0.712478 0 - 34 O 0.58835 0.19206 0.212478 0 - 35 O 0.91165 0.124128 0.60371 0 - 36 O 0.287522 0.479582 0.375872 0 - 37 O 0.30794 0.91165 0.287522 0 - 38 O 0.41165 0.80794 0.787522 0 - 39 O 0.08835 0.875872 0.39629 0 - 40 O 0.712478 0.520418 0.624128 0 - 41 O 0.69206 0.08835 0.712478 0 - 42 O 0.020418 0.30794 0.89629 0 - 43 O 0.212478 0.58835 0.19206 0 - 44 O 0.124128 0.020418 0.212478 0 - 45 O 0.979582 0.69206 0.10371 0 - 46 O 0.787522 0.41165 0.80794 0 - 47 O 0.875872 0.979582 0.787522 0 - 48 O 0.60371 0.91165 0.124128 0 - 49 O 0.19206 0.479582 0.60371 0 - 50 O 0.39629 0.08835 0.875872 0 - 51 O 0.80794 0.520418 0.39629 0 - 52 O 0.89629 0.020418 0.30794 0 - 53 O 0.375872 0.58835 0.89629 0 - 54 O 0.10371 0.979582 0.69206 0 - 55 O 0.624128 0.41165 0.10371 0 - 56 O 0.375872 0.287522 0.479582 0 - 57 O 0.58835 0.89629 0.375872 0 - 58 O 0.624128 0.712478 0.520418 0 - 59 O 0.41165 0.10371 0.624128 0 - 60 O 0.124128 0.60371 0.91165 0 - 61 O 0.020418 0.212478 0.124128 0 - 62 O 0.875872 0.39629 0.08835 0 - 63 O 0.979582 0.787522 0.875872 0 - 64 O 0.30794 0.89629 0.020418 0 - 65 O 0.91165 0.287522 0.30794 0 - 66 O 0.69206 0.10371 0.979582 0 - 67 O 0.08835 0.712478 0.69206 0 - 68 O 0.19206 0.212478 0.58835 0 - 69 O 0.479582 0.60371 0.19206 0 - 70 O 0.80794 0.787522 0.41165 0 - 71 O 0.520418 0.39629 0.80794 0 - 72 O 0.287522 0.30794 0.91165 0 - 73 O 0.712478 0.69206 0.08835 0 - 74 O 0.212478 0.124128 0.020418 0 - 75 O 0.787522 0.875872 0.979582 0 - 76 O 0.89629 0.375872 0.58835 0 - 77 O 0.10371 0.624128 0.41165 0 - 78 O 0.60371 0.19206 0.479582 0 - 79 O 0.39629 0.80794 0.520418 0","# generated using pymatgen -data_Ca3In2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.04701659 -_cell_length_b 11.04701659 -_cell_length_c 11.04701659 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3In2(GeO4)3 -_chemical_formula_sum 'Ca12 In8 Ge12 O48' -_cell_volume 1037.79871232 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - In In12 1 0.00000000 0.00000000 0.00000000 1 - In In13 1 0.50000000 0.00000000 0.50000000 1 - In In14 1 0.00000000 0.50000000 0.50000000 1 - In In15 1 0.50000000 0.00000000 0.00000000 1 - In In16 1 0.50000000 0.50000000 0.00000000 1 - In In17 1 0.50000000 0.50000000 0.50000000 1 - In In18 1 0.00000000 0.00000000 0.50000000 1 - In In19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47958200 0.37587200 0.28752200 1 - O O33 1 0.52041800 0.62412800 0.71247800 1 - O O34 1 0.58835000 0.19206000 0.21247800 1 - O O35 1 0.91165000 0.12412800 0.60371000 1 - O O36 1 0.28752200 0.47958200 0.37587200 1 - O O37 1 0.30794000 0.91165000 0.28752200 1 - O O38 1 0.41165000 0.80794000 0.78752200 1 - O O39 1 0.08835000 0.87587200 0.39629000 1 - O O40 1 0.71247800 0.52041800 0.62412800 1 - O O41 1 0.69206000 0.08835000 0.71247800 1 - O O42 1 0.02041800 0.30794000 0.89629000 1 - O O43 1 0.21247800 0.58835000 0.19206000 1 - O O44 1 0.12412800 0.02041800 0.21247800 1 - O O45 1 0.97958200 0.69206000 0.10371000 1 - O O46 1 0.78752200 0.41165000 0.80794000 1 - O O47 1 0.87587200 0.97958200 0.78752200 1 - O O48 1 0.60371000 0.91165000 0.12412800 1 - O O49 1 0.19206000 0.47958200 0.60371000 1 - O O50 1 0.39629000 0.08835000 0.87587200 1 - O O51 1 0.80794000 0.52041800 0.39629000 1 - O O52 1 0.89629000 0.02041800 0.30794000 1 - O O53 1 0.37587200 0.58835000 0.89629000 1 - O O54 1 0.10371000 0.97958200 0.69206000 1 - O O55 1 0.62412800 0.41165000 0.10371000 1 - O O56 1 0.37587200 0.28752200 0.47958200 1 - O O57 1 0.58835000 0.89629000 0.37587200 1 - O O58 1 0.62412800 0.71247800 0.52041800 1 - O O59 1 0.41165000 0.10371000 0.62412800 1 - O O60 1 0.12412800 0.60371000 0.91165000 1 - O O61 1 0.02041800 0.21247800 0.12412800 1 - O O62 1 0.87587200 0.39629000 0.08835000 1 - O O63 1 0.97958200 0.78752200 0.87587200 1 - O O64 1 0.30794000 0.89629000 0.02041800 1 - O O65 1 0.91165000 0.28752200 0.30794000 1 - O O66 1 0.69206000 0.10371000 0.97958200 1 - O O67 1 0.08835000 0.71247800 0.69206000 1 - O O68 1 0.19206000 0.21247800 0.58835000 1 - O O69 1 0.47958200 0.60371000 0.19206000 1 - O O70 1 0.80794000 0.78752200 0.41165000 1 - O O71 1 0.52041800 0.39629000 0.80794000 1 - O O72 1 0.28752200 0.30794000 0.91165000 1 - O O73 1 0.71247800 0.69206000 0.08835000 1 - O O74 1 0.21247800 0.12412800 0.02041800 1 - O O75 1 0.78752200 0.87587200 0.97958200 1 - O O76 1 0.89629000 0.37587200 0.58835000 1 - O O77 1 0.10371000 0.62412800 0.41165000 1 - O O78 1 0.60371000 0.19206000 0.47958200 1 - O O79 1 0.39629000 0.80794000 0.52041800 1 -" -Ca3Ti3Cr2O12,mp-1214263,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Ca12 Ti12 Cr8 O48) -Reduced Formula: Ca3Ti3Cr2O12 -abc : 10.931082 10.931082 10.931082 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0.002 - 1 Ca 0.75 0.625 0.875 0.002 - 2 Ca 0.75 0.125 0.375 0.002 - 3 Ca 0.125 0.25 0.375 0.002 - 4 Ca 0.375 0.75 0.125 0.002 - 5 Ca 0.25 0.875 0.625 0.002 - 6 Ca 0.875 0.75 0.625 0.002 - 7 Ca 0.625 0.25 0.875 0.002 - 8 Ca 0.375 0.125 0.25 0.002 - 9 Ca 0.625 0.875 0.75 0.002 - 10 Ca 0.125 0.375 0.75 0.002 - 11 Ca 0.875 0.625 0.25 0.002 - 12 Ti 0.25 0.625 0.375 0.034 - 13 Ti 0.75 0.375 0.625 0.034 - 14 Ti 0.75 0.875 0.125 0.034 - 15 Ti 0.375 0.25 0.625 0.034 - 16 Ti 0.625 0.75 0.375 0.034 - 17 Ti 0.25 0.125 0.875 0.034 - 18 Ti 0.125 0.75 0.875 0.034 - 19 Ti 0.875 0.25 0.125 0.034 - 20 Ti 0.625 0.375 0.25 0.034 - 21 Ti 0.375 0.625 0.75 0.034 - 22 Ti 0.875 0.125 0.75 0.034 - 23 Ti 0.125 0.875 0.25 0.034 - 24 Cr 0 0 0 2.927 - 25 Cr 0.5 0 0.5 2.927 - 26 Cr 0 0.5 0.5 2.927 - 27 Cr 0.5 0 0 2.927 - 28 Cr 0.5 0.5 0 2.927 - 29 Cr 0.5 0.5 0.5 2.927 - 30 Cr 0 0 0.5 2.927 - 31 Cr 0 0.5 0 2.927 - 32 O 0.482276 0.381349 0.301011 -0.011 - 33 O 0.517724 0.618651 0.698989 -0.011 - 34 O 0.580338 0.181265 0.198989 -0.011 - 35 O 0.919662 0.118651 0.600927 -0.011 - 36 O 0.301011 0.482276 0.381349 -0.011 - 37 O 0.318735 0.919662 0.301011 -0.01 - 38 O 0.419662 0.818735 0.801011 -0.011 - 39 O 0.080338 0.881349 0.399073 -0.011 - 40 O 0.698989 0.517724 0.618651 -0.011 - 41 O 0.681265 0.080338 0.698989 -0.01 - 42 O 0.017724 0.318735 0.899073 -0.011 - 43 O 0.198989 0.580338 0.181265 -0.011 - 44 O 0.118651 0.017724 0.198989 -0.011 - 45 O 0.982276 0.681265 0.100927 -0.011 - 46 O 0.801011 0.419662 0.818735 -0.011 - 47 O 0.881349 0.982276 0.801011 -0.011 - 48 O 0.600927 0.919662 0.118651 -0.011 - 49 O 0.181265 0.482276 0.600927 -0.01 - 50 O 0.399073 0.080338 0.881349 -0.011 - 51 O 0.818735 0.517724 0.399073 -0.01 - 52 O 0.899073 0.017724 0.318735 -0.011 - 53 O 0.381349 0.580338 0.899073 -0.011 - 54 O 0.100927 0.982276 0.681265 -0.011 - 55 O 0.618651 0.419662 0.100927 -0.011 - 56 O 0.381349 0.301011 0.482276 -0.011 - 57 O 0.580338 0.899073 0.381349 -0.011 - 58 O 0.618651 0.698989 0.517724 -0.011 - 59 O 0.419662 0.100927 0.618651 -0.011 - 60 O 0.118651 0.600927 0.919662 -0.011 - 61 O 0.017724 0.198989 0.118651 -0.011 - 62 O 0.881349 0.399073 0.080338 -0.011 - 63 O 0.982276 0.801011 0.881349 -0.011 - 64 O 0.318735 0.899073 0.017724 -0.01 - 65 O 0.919662 0.301011 0.318735 -0.011 - 66 O 0.681265 0.100927 0.982276 -0.01 - 67 O 0.080338 0.698989 0.681265 -0.011 - 68 O 0.181265 0.198989 0.580338 -0.01 - 69 O 0.482276 0.600927 0.181265 -0.011 - 70 O 0.818735 0.801011 0.419662 -0.01 - 71 O 0.517724 0.399073 0.818735 -0.011 - 72 O 0.301011 0.318735 0.919662 -0.011 - 73 O 0.698989 0.681265 0.080338 -0.011 - 74 O 0.198989 0.118651 0.017724 -0.011 - 75 O 0.801011 0.881349 0.982276 -0.011 - 76 O 0.899073 0.381349 0.580338 -0.011 - 77 O 0.100927 0.618651 0.419662 -0.011 - 78 O 0.600927 0.181265 0.482276 -0.011 - 79 O 0.399073 0.818735 0.517724 -0.011","# generated using pymatgen -data_Ca3Ti3Cr2O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.93108177 -_cell_length_b 10.93108177 -_cell_length_c 10.93108177 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ti3Cr2O12 -_chemical_formula_sum 'Ca12 Ti12 Cr8 O48' -_cell_volume 1005.46634374 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Ti Ti12 1 0.25000000 0.62500000 0.37500000 1 - Ti Ti13 1 0.75000000 0.37500000 0.62500000 1 - Ti Ti14 1 0.75000000 0.87500000 0.12500000 1 - Ti Ti15 1 0.37500000 0.25000000 0.62500000 1 - Ti Ti16 1 0.62500000 0.75000000 0.37500000 1 - Ti Ti17 1 0.25000000 0.12500000 0.87500000 1 - Ti Ti18 1 0.12500000 0.75000000 0.87500000 1 - Ti Ti19 1 0.87500000 0.25000000 0.12500000 1 - Ti Ti20 1 0.62500000 0.37500000 0.25000000 1 - Ti Ti21 1 0.37500000 0.62500000 0.75000000 1 - Ti Ti22 1 0.87500000 0.12500000 0.75000000 1 - Ti Ti23 1 0.12500000 0.87500000 0.25000000 1 - Cr Cr24 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr25 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr26 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr27 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr28 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr29 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr30 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.48227600 0.38134900 0.30101100 1 - O O33 1 0.51772400 0.61865100 0.69898900 1 - O O34 1 0.58033800 0.18126500 0.19898900 1 - O O35 1 0.91966200 0.11865100 0.60092700 1 - O O36 1 0.30101100 0.48227600 0.38134900 1 - O O37 1 0.31873500 0.91966200 0.30101100 1 - O O38 1 0.41966200 0.81873500 0.80101100 1 - O O39 1 0.08033800 0.88134900 0.39907300 1 - O O40 1 0.69898900 0.51772400 0.61865100 1 - O O41 1 0.68126500 0.08033800 0.69898900 1 - O O42 1 0.01772400 0.31873500 0.89907300 1 - O O43 1 0.19898900 0.58033800 0.18126500 1 - O O44 1 0.11865100 0.01772400 0.19898900 1 - O O45 1 0.98227600 0.68126500 0.10092700 1 - O O46 1 0.80101100 0.41966200 0.81873500 1 - O O47 1 0.88134900 0.98227600 0.80101100 1 - O O48 1 0.60092700 0.91966200 0.11865100 1 - O O49 1 0.18126500 0.48227600 0.60092700 1 - O O50 1 0.39907300 0.08033800 0.88134900 1 - O O51 1 0.81873500 0.51772400 0.39907300 1 - O O52 1 0.89907300 0.01772400 0.31873500 1 - O O53 1 0.38134900 0.58033800 0.89907300 1 - O O54 1 0.10092700 0.98227600 0.68126500 1 - O O55 1 0.61865100 0.41966200 0.10092700 1 - O O56 1 0.38134900 0.30101100 0.48227600 1 - O O57 1 0.58033800 0.89907300 0.38134900 1 - O O58 1 0.61865100 0.69898900 0.51772400 1 - O O59 1 0.41966200 0.10092700 0.61865100 1 - O O60 1 0.11865100 0.60092700 0.91966200 1 - O O61 1 0.01772400 0.19898900 0.11865100 1 - O O62 1 0.88134900 0.39907300 0.08033800 1 - O O63 1 0.98227600 0.80101100 0.88134900 1 - O O64 1 0.31873500 0.89907300 0.01772400 1 - O O65 1 0.91966200 0.30101100 0.31873500 1 - O O66 1 0.68126500 0.10092700 0.98227600 1 - O O67 1 0.08033800 0.69898900 0.68126500 1 - O O68 1 0.18126500 0.19898900 0.58033800 1 - O O69 1 0.48227600 0.60092700 0.18126500 1 - O O70 1 0.81873500 0.80101100 0.41966200 1 - O O71 1 0.51772400 0.39907300 0.81873500 1 - O O72 1 0.30101100 0.31873500 0.91966200 1 - O O73 1 0.69898900 0.68126500 0.08033800 1 - O O74 1 0.19898900 0.11865100 0.01772400 1 - O O75 1 0.80101100 0.88134900 0.98227600 1 - O O76 1 0.89907300 0.38134900 0.58033800 1 - O O77 1 0.10092700 0.61865100 0.41966200 1 - O O78 1 0.60092700 0.18126500 0.48227600 1 - O O79 1 0.39907300 0.81873500 0.51772400 1 -" -Ca3Ge3(RhO6)2,mp-1214274,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Ca12 Ge12 Rh8 O48) -Reduced Formula: Ca3Ge3(RhO6)2 -abc : 10.839749 10.839749 10.839749 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.75 0.125 0.375 0 - 3 Ca 0.125 0.25 0.375 0 - 4 Ca 0.375 0.75 0.125 0 - 5 Ca 0.25 0.875 0.625 0 - 6 Ca 0.875 0.75 0.625 0 - 7 Ca 0.625 0.25 0.875 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.625 0.875 0.75 0 - 10 Ca 0.125 0.375 0.75 0 - 11 Ca 0.875 0.625 0.25 0 - 12 Ge 0.25 0.625 0.375 0 - 13 Ge 0.75 0.375 0.625 0 - 14 Ge 0.75 0.875 0.125 0 - 15 Ge 0.375 0.25 0.625 0 - 16 Ge 0.625 0.75 0.375 0 - 17 Ge 0.25 0.125 0.875 0 - 18 Ge 0.125 0.75 0.875 0 - 19 Ge 0.875 0.25 0.125 0 - 20 Ge 0.625 0.375 0.25 0 - 21 Ge 0.375 0.625 0.75 0 - 22 Ge 0.875 0.125 0.75 0 - 23 Ge 0.125 0.875 0.25 0 - 24 Rh 0 0 0 -0 - 25 Rh 0.5 0 0.5 -0 - 26 Rh 0 0.5 0.5 -0 - 27 Rh 0.5 0 0 -0 - 28 Rh 0.5 0.5 0 -0 - 29 Rh 0.5 0.5 0.5 -0 - 30 Rh 0 0 0.5 -0 - 31 Rh 0 0.5 0 -0 - 32 O 0.480268 0.379353 0.293315 -0 - 33 O 0.519732 0.620647 0.706685 -0 - 34 O 0.586038 0.186953 0.206685 -0 - 35 O 0.913962 0.120647 0.600914 -0 - 36 O 0.293315 0.480268 0.379353 -0 - 37 O 0.313047 0.913962 0.293315 -0 - 38 O 0.413962 0.813047 0.793315 -0 - 39 O 0.086038 0.879353 0.399086 -0 - 40 O 0.706685 0.519732 0.620647 -0 - 41 O 0.686953 0.086038 0.706685 -0 - 42 O 0.019732 0.313047 0.899086 -0 - 43 O 0.206685 0.586038 0.186953 -0 - 44 O 0.120647 0.019732 0.206685 -0 - 45 O 0.980268 0.686953 0.100914 -0 - 46 O 0.793315 0.413962 0.813047 -0 - 47 O 0.879353 0.980268 0.793315 -0 - 48 O 0.600914 0.913962 0.120647 -0 - 49 O 0.186953 0.480268 0.600914 -0 - 50 O 0.399086 0.086038 0.879353 -0 - 51 O 0.813047 0.519732 0.399086 -0 - 52 O 0.899086 0.019732 0.313047 -0 - 53 O 0.379353 0.586038 0.899086 -0 - 54 O 0.100914 0.980268 0.686953 -0 - 55 O 0.620647 0.413962 0.100914 -0 - 56 O 0.379353 0.293315 0.480268 -0 - 57 O 0.586038 0.899086 0.379353 -0 - 58 O 0.620647 0.706685 0.519732 -0 - 59 O 0.413962 0.100914 0.620647 -0 - 60 O 0.120647 0.600914 0.913962 -0 - 61 O 0.019732 0.206685 0.120647 -0 - 62 O 0.879353 0.399086 0.086038 -0 - 63 O 0.980268 0.793315 0.879353 -0 - 64 O 0.313047 0.899086 0.019732 -0 - 65 O 0.913962 0.293315 0.313047 -0 - 66 O 0.686953 0.100914 0.980268 -0 - 67 O 0.086038 0.706685 0.686953 -0 - 68 O 0.186953 0.206685 0.586038 -0 - 69 O 0.480268 0.600914 0.186953 -0 - 70 O 0.813047 0.793315 0.413962 -0 - 71 O 0.519732 0.399086 0.813047 -0 - 72 O 0.293315 0.313047 0.913962 -0 - 73 O 0.706685 0.686953 0.086038 -0 - 74 O 0.206685 0.120647 0.019732 -0 - 75 O 0.793315 0.879353 0.980268 -0 - 76 O 0.899086 0.379353 0.586038 -0 - 77 O 0.100914 0.620647 0.413962 -0 - 78 O 0.600914 0.186953 0.480268 -0 - 79 O 0.399086 0.813047 0.519732 -0","# generated using pymatgen -data_Ca3Ge3(RhO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.83974899 -_cell_length_b 10.83974899 -_cell_length_c 10.83974899 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ge3(RhO6)2 -_chemical_formula_sum 'Ca12 Ge12 Rh8 O48' -_cell_volume 980.47333398 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Ge Ge12 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge13 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge14 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge15 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge16 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge17 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge18 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge19 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge20 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge23 1 0.12500000 0.87500000 0.25000000 1 - Rh Rh24 1 0.00000000 0.00000000 0.00000000 1 - Rh Rh25 1 0.50000000 0.00000000 0.50000000 1 - Rh Rh26 1 0.00000000 0.50000000 0.50000000 1 - Rh Rh27 1 0.50000000 0.00000000 0.00000000 1 - Rh Rh28 1 0.50000000 0.50000000 0.00000000 1 - Rh Rh29 1 0.50000000 0.50000000 0.50000000 1 - Rh Rh30 1 0.00000000 0.00000000 0.50000000 1 - Rh Rh31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.48026800 0.37935300 0.29331500 1 - O O33 1 0.51973200 0.62064700 0.70668500 1 - O O34 1 0.58603800 0.18695300 0.20668500 1 - O O35 1 0.91396200 0.12064700 0.60091400 1 - O O36 1 0.29331500 0.48026800 0.37935300 1 - O O37 1 0.31304700 0.91396200 0.29331500 1 - O O38 1 0.41396200 0.81304700 0.79331500 1 - O O39 1 0.08603800 0.87935300 0.39908600 1 - O O40 1 0.70668500 0.51973200 0.62064700 1 - O O41 1 0.68695300 0.08603800 0.70668500 1 - O O42 1 0.01973200 0.31304700 0.89908600 1 - O O43 1 0.20668500 0.58603800 0.18695300 1 - O O44 1 0.12064700 0.01973200 0.20668500 1 - O O45 1 0.98026800 0.68695300 0.10091400 1 - O O46 1 0.79331500 0.41396200 0.81304700 1 - O O47 1 0.87935300 0.98026800 0.79331500 1 - O O48 1 0.60091400 0.91396200 0.12064700 1 - O O49 1 0.18695300 0.48026800 0.60091400 1 - O O50 1 0.39908600 0.08603800 0.87935300 1 - O O51 1 0.81304700 0.51973200 0.39908600 1 - O O52 1 0.89908600 0.01973200 0.31304700 1 - O O53 1 0.37935300 0.58603800 0.89908600 1 - O O54 1 0.10091400 0.98026800 0.68695300 1 - O O55 1 0.62064700 0.41396200 0.10091400 1 - O O56 1 0.37935300 0.29331500 0.48026800 1 - O O57 1 0.58603800 0.89908600 0.37935300 1 - O O58 1 0.62064700 0.70668500 0.51973200 1 - O O59 1 0.41396200 0.10091400 0.62064700 1 - O O60 1 0.12064700 0.60091400 0.91396200 1 - O O61 1 0.01973200 0.20668500 0.12064700 1 - O O62 1 0.87935300 0.39908600 0.08603800 1 - O O63 1 0.98026800 0.79331500 0.87935300 1 - O O64 1 0.31304700 0.89908600 0.01973200 1 - O O65 1 0.91396200 0.29331500 0.31304700 1 - O O66 1 0.68695300 0.10091400 0.98026800 1 - O O67 1 0.08603800 0.70668500 0.68695300 1 - O O68 1 0.18695300 0.20668500 0.58603800 1 - O O69 1 0.48026800 0.60091400 0.18695300 1 - O O70 1 0.81304700 0.79331500 0.41396200 1 - O O71 1 0.51973200 0.39908600 0.81304700 1 - O O72 1 0.29331500 0.31304700 0.91396200 1 - O O73 1 0.70668500 0.68695300 0.08603800 1 - O O74 1 0.20668500 0.12064700 0.01973200 1 - O O75 1 0.79331500 0.87935300 0.98026800 1 - O O76 1 0.89908600 0.37935300 0.58603800 1 - O O77 1 0.10091400 0.62064700 0.41396200 1 - O O78 1 0.60091400 0.18695300 0.48026800 1 - O O79 1 0.39908600 0.81304700 0.51973200 1 -" -Ca3Yb2(GeO4)3,mp-1214302,Ia-3d,[],0.012398311125005002,{'tags': ['garnet family']},"Full Formula (Ca12 Yb8 Ge12 O48) -Reduced Formula: Ca3Yb2(GeO4)3 -abc : 11.168123 11.168123 11.168123 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0.004 - 1 Ca 0.75 0.625 0.875 -0.004 - 2 Ca 0.75 0.125 0.375 -0.004 - 3 Ca 0.125 0.25 0.375 -0.004 - 4 Ca 0.375 0.75 0.125 -0.004 - 5 Ca 0.25 0.875 0.625 -0.004 - 6 Ca 0.875 0.75 0.625 -0.004 - 7 Ca 0.625 0.25 0.875 -0.004 - 8 Ca 0.375 0.125 0.25 -0.004 - 9 Ca 0.625 0.875 0.75 -0.004 - 10 Ca 0.125 0.375 0.75 -0.004 - 11 Ca 0.875 0.625 0.25 -0.004 - 12 Yb 0 0 0 0.036 - 13 Yb 0.5 0 0.5 0.036 - 14 Yb 0 0.5 0.5 0.036 - 15 Yb 0.5 0 0 0.036 - 16 Yb 0.5 0.5 0 0.036 - 17 Yb 0.5 0.5 0.5 0.036 - 18 Yb 0 0 0.5 0.036 - 19 Yb 0 0.5 0 0.036 - 20 Ge 0.25 0.625 0.375 -0.01 - 21 Ge 0.75 0.375 0.625 -0.01 - 22 Ge 0.75 0.875 0.125 -0.01 - 23 Ge 0.375 0.25 0.625 -0.01 - 24 Ge 0.625 0.75 0.375 -0.01 - 25 Ge 0.25 0.125 0.875 -0.01 - 26 Ge 0.125 0.75 0.875 -0.01 - 27 Ge 0.875 0.25 0.125 -0.01 - 28 Ge 0.625 0.375 0.25 -0.01 - 29 Ge 0.375 0.625 0.75 -0.01 - 30 Ge 0.875 0.125 0.75 -0.01 - 31 Ge 0.125 0.875 0.25 -0.01 - 32 O 0.476344 0.37309 0.278342 0.141 - 33 O 0.523656 0.62691 0.721658 0.141 - 34 O 0.594747 0.198002 0.221658 0.141 - 35 O 0.905253 0.12691 0.603255 0.141 - 36 O 0.278342 0.476344 0.37309 0.142 - 37 O 0.301998 0.905252 0.278342 0.141 - 38 O 0.405253 0.801998 0.778342 0.141 - 39 O 0.094747 0.87309 0.396745 0.141 - 40 O 0.721658 0.523656 0.62691 0.141 - 41 O 0.698002 0.094747 0.721658 0.141 - 42 O 0.023656 0.301998 0.896745 0.141 - 43 O 0.221658 0.594747 0.198002 0.141 - 44 O 0.12691 0.023656 0.221658 0.141 - 45 O 0.976344 0.698002 0.103255 0.141 - 46 O 0.778342 0.405253 0.801998 0.141 - 47 O 0.87309 0.976344 0.778342 0.141 - 48 O 0.603255 0.905253 0.12691 0.141 - 49 O 0.198002 0.476344 0.603255 0.141 - 50 O 0.396745 0.094747 0.87309 0.141 - 51 O 0.801998 0.523656 0.396745 0.141 - 52 O 0.896745 0.023656 0.301998 0.142 - 53 O 0.37309 0.594747 0.896745 0.141 - 54 O 0.103255 0.976344 0.698002 0.141 - 55 O 0.62691 0.405252 0.103255 0.141 - 56 O 0.37309 0.278342 0.476344 0.141 - 57 O 0.594747 0.896745 0.37309 0.141 - 58 O 0.62691 0.721658 0.523656 0.141 - 59 O 0.405252 0.103255 0.62691 0.141 - 60 O 0.12691 0.603255 0.905253 0.142 - 61 O 0.023656 0.221658 0.12691 0.142 - 62 O 0.87309 0.396745 0.094747 0.141 - 63 O 0.976344 0.778342 0.87309 0.141 - 64 O 0.301998 0.896745 0.023656 0.142 - 65 O 0.905253 0.278342 0.301998 0.142 - 66 O 0.698002 0.103255 0.976344 0.141 - 67 O 0.094747 0.721658 0.698002 0.141 - 68 O 0.198002 0.221658 0.594747 0.141 - 69 O 0.476344 0.603255 0.198002 0.141 - 70 O 0.801998 0.778342 0.405253 0.141 - 71 O 0.523656 0.396745 0.801998 0.141 - 72 O 0.278342 0.301998 0.905253 0.141 - 73 O 0.721658 0.698002 0.094747 0.141 - 74 O 0.221658 0.12691 0.023656 0.142 - 75 O 0.778342 0.87309 0.976344 0.141 - 76 O 0.896745 0.37309 0.594747 0.142 - 77 O 0.103255 0.62691 0.405253 0.141 - 78 O 0.603255 0.198002 0.476344 0.141 - 79 O 0.396745 0.801998 0.523656 0.141","# generated using pymatgen -data_Ca3Yb2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.16812331 -_cell_length_b 11.16812331 -_cell_length_c 11.16812331 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Yb2(GeO4)3 -_chemical_formula_sum 'Ca12 Yb8 Ge12 O48' -_cell_volume 1072.30593752 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Yb Yb12 1 0.00000000 0.00000000 0.00000000 1 - Yb Yb13 1 0.50000000 0.00000000 0.50000000 1 - Yb Yb14 1 0.00000000 0.50000000 0.50000000 1 - Yb Yb15 1 0.50000000 0.00000000 0.00000000 1 - Yb Yb16 1 0.50000000 0.50000000 0.00000000 1 - Yb Yb17 1 0.50000000 0.50000000 0.50000000 1 - Yb Yb18 1 0.00000000 0.00000000 0.50000000 1 - Yb Yb19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47634400 0.37309000 0.27834200 1 - O O33 1 0.52365600 0.62691000 0.72165800 1 - O O34 1 0.59474700 0.19800200 0.22165800 1 - O O35 1 0.90525300 0.12691000 0.60325500 1 - O O36 1 0.27834200 0.47634400 0.37309000 1 - O O37 1 0.30199800 0.90525200 0.27834200 1 - O O38 1 0.40525300 0.80199800 0.77834200 1 - O O39 1 0.09474700 0.87309000 0.39674500 1 - O O40 1 0.72165800 0.52365600 0.62691000 1 - O O41 1 0.69800200 0.09474700 0.72165800 1 - O O42 1 0.02365600 0.30199800 0.89674500 1 - O O43 1 0.22165800 0.59474700 0.19800200 1 - O O44 1 0.12691000 0.02365600 0.22165800 1 - O O45 1 0.97634400 0.69800200 0.10325500 1 - O O46 1 0.77834200 0.40525300 0.80199800 1 - O O47 1 0.87309000 0.97634400 0.77834200 1 - O O48 1 0.60325500 0.90525300 0.12691000 1 - O O49 1 0.19800200 0.47634400 0.60325500 1 - O O50 1 0.39674500 0.09474700 0.87309000 1 - O O51 1 0.80199800 0.52365600 0.39674500 1 - O O52 1 0.89674500 0.02365600 0.30199800 1 - O O53 1 0.37309000 0.59474700 0.89674500 1 - O O54 1 0.10325500 0.97634400 0.69800200 1 - O O55 1 0.62691000 0.40525200 0.10325500 1 - O O56 1 0.37309000 0.27834200 0.47634400 1 - O O57 1 0.59474700 0.89674500 0.37309000 1 - O O58 1 0.62691000 0.72165800 0.52365600 1 - O O59 1 0.40525200 0.10325500 0.62691000 1 - O O60 1 0.12691000 0.60325500 0.90525300 1 - O O61 1 0.02365600 0.22165800 0.12691000 1 - O O62 1 0.87309000 0.39674500 0.09474700 1 - O O63 1 0.97634400 0.77834200 0.87309000 1 - O O64 1 0.30199800 0.89674500 0.02365600 1 - O O65 1 0.90525300 0.27834200 0.30199800 1 - O O66 1 0.69800200 0.10325500 0.97634400 1 - O O67 1 0.09474700 0.72165800 0.69800200 1 - O O68 1 0.19800200 0.22165800 0.59474700 1 - O O69 1 0.47634400 0.60325500 0.19800200 1 - O O70 1 0.80199800 0.77834200 0.40525300 1 - O O71 1 0.52365600 0.39674500 0.80199800 1 - O O72 1 0.27834200 0.30199800 0.90525300 1 - O O73 1 0.72165800 0.69800200 0.09474700 1 - O O74 1 0.22165800 0.12691000 0.02365600 1 - O O75 1 0.77834200 0.87309000 0.97634400 1 - O O76 1 0.89674500 0.37309000 0.59474700 1 - O O77 1 0.10325500 0.62691000 0.40525300 1 - O O78 1 0.60325500 0.19800200 0.47634400 1 - O O79 1 0.39674500 0.80199800 0.52365600 1 -" -Ca3Tm2(GeO4)3,mp-1214304,Ia-3d,[],0.0,{'tags': []},"Full Formula (Ca12 Tm8 Ge12 O48) -Reduced Formula: Ca3Tm2(GeO4)3 -abc : 11.159638 11.159638 11.159638 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 -0 - 1 Ca 0.75 0.625 0.875 -0 - 2 Ca 0.75 0.125 0.375 -0 - 3 Ca 0.125 0.25 0.375 -0 - 4 Ca 0.375 0.75 0.125 -0 - 5 Ca 0.25 0.875 0.625 -0 - 6 Ca 0.875 0.75 0.625 -0 - 7 Ca 0.625 0.25 0.875 -0 - 8 Ca 0.375 0.125 0.25 -0 - 9 Ca 0.625 0.875 0.75 -0 - 10 Ca 0.125 0.375 0.75 -0 - 11 Ca 0.875 0.625 0.25 -0 - 12 Tm 0 0 0 -0.001 - 13 Tm 0.5 0 0.5 -0.001 - 14 Tm 0 0.5 0.5 -0.001 - 15 Tm 0.5 0 0 -0.001 - 16 Tm 0.5 0.5 0 -0.001 - 17 Tm 0.5 0.5 0.5 -0.001 - 18 Tm 0 0 0.5 -0.001 - 19 Tm 0 0.5 0 -0.001 - 20 Ge 0.25 0.625 0.375 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.75 0.875 0.125 -0 - 23 Ge 0.375 0.25 0.625 -0 - 24 Ge 0.625 0.75 0.375 -0 - 25 Ge 0.25 0.125 0.875 -0 - 26 Ge 0.125 0.75 0.875 -0 - 27 Ge 0.875 0.25 0.125 -0 - 28 Ge 0.625 0.375 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.875 0.125 0.75 -0 - 31 Ge 0.125 0.875 0.25 -0 - 32 O 0.480789 0.375908 0.286594 0 - 33 O 0.519211 0.624092 0.713406 0 - 34 O 0.589314 0.194195 0.213406 0 - 35 O 0.910686 0.124092 0.604881 0 - 36 O 0.286594 0.480789 0.375908 0 - 37 O 0.305805 0.910686 0.286594 0 - 38 O 0.410686 0.805805 0.786594 0 - 39 O 0.089314 0.875908 0.395119 0 - 40 O 0.713406 0.519211 0.624092 0 - 41 O 0.694195 0.089314 0.713406 0 - 42 O 0.019211 0.305805 0.895119 0 - 43 O 0.213406 0.589314 0.194195 0 - 44 O 0.124092 0.019211 0.213406 0 - 45 O 0.980789 0.694195 0.104881 0 - 46 O 0.786594 0.410686 0.805805 0 - 47 O 0.875908 0.980789 0.786594 0 - 48 O 0.604881 0.910686 0.124092 0 - 49 O 0.194195 0.480789 0.604881 0 - 50 O 0.395119 0.089314 0.875908 0 - 51 O 0.805805 0.519211 0.395119 0 - 52 O 0.895119 0.019211 0.305805 0 - 53 O 0.375908 0.589314 0.895119 0 - 54 O 0.104881 0.980789 0.694195 0 - 55 O 0.624092 0.410686 0.104881 0 - 56 O 0.375908 0.286594 0.480789 0 - 57 O 0.589314 0.895119 0.375908 0 - 58 O 0.624092 0.713406 0.519211 0 - 59 O 0.410686 0.104881 0.624092 0 - 60 O 0.124092 0.604881 0.910686 0 - 61 O 0.019211 0.213406 0.124092 0 - 62 O 0.875908 0.395119 0.089314 0 - 63 O 0.980789 0.786594 0.875908 0 - 64 O 0.305805 0.895119 0.019211 0 - 65 O 0.910686 0.286594 0.305805 0 - 66 O 0.694195 0.104881 0.980789 0 - 67 O 0.089314 0.713406 0.694195 0 - 68 O 0.194195 0.213406 0.589314 0 - 69 O 0.480789 0.604881 0.194195 0 - 70 O 0.805805 0.786594 0.410686 0 - 71 O 0.519211 0.395119 0.805805 0 - 72 O 0.286594 0.305805 0.910686 0 - 73 O 0.713406 0.694195 0.089314 0 - 74 O 0.213406 0.124092 0.019211 0 - 75 O 0.786594 0.875908 0.980789 0 - 76 O 0.895119 0.375908 0.589314 0 - 77 O 0.104881 0.624092 0.410686 0 - 78 O 0.604881 0.194195 0.480789 0 - 79 O 0.395119 0.805805 0.519211 0","# generated using pymatgen -data_Ca3Tm2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.15963799 -_cell_length_b 11.15963799 -_cell_length_c 11.15963799 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Tm2(GeO4)3 -_chemical_formula_sum 'Ca12 Tm8 Ge12 O48' -_cell_volume 1069.86364420 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Tm Tm12 1 0.00000000 0.00000000 0.00000000 1 - Tm Tm13 1 0.50000000 0.00000000 0.50000000 1 - Tm Tm14 1 0.00000000 0.50000000 0.50000000 1 - Tm Tm15 1 0.50000000 0.00000000 0.00000000 1 - Tm Tm16 1 0.50000000 0.50000000 0.00000000 1 - Tm Tm17 1 0.50000000 0.50000000 0.50000000 1 - Tm Tm18 1 0.00000000 0.00000000 0.50000000 1 - Tm Tm19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48078900 0.37590800 0.28659400 1 - O O33 1 0.51921100 0.62409200 0.71340600 1 - O O34 1 0.58931400 0.19419500 0.21340600 1 - O O35 1 0.91068600 0.12409200 0.60488100 1 - O O36 1 0.28659400 0.48078900 0.37590800 1 - O O37 1 0.30580500 0.91068600 0.28659400 1 - O O38 1 0.41068600 0.80580500 0.78659400 1 - O O39 1 0.08931400 0.87590800 0.39511900 1 - O O40 1 0.71340600 0.51921100 0.62409200 1 - O O41 1 0.69419500 0.08931400 0.71340600 1 - O O42 1 0.01921100 0.30580500 0.89511900 1 - O O43 1 0.21340600 0.58931400 0.19419500 1 - O O44 1 0.12409200 0.01921100 0.21340600 1 - O O45 1 0.98078900 0.69419500 0.10488100 1 - O O46 1 0.78659400 0.41068600 0.80580500 1 - O O47 1 0.87590800 0.98078900 0.78659400 1 - O O48 1 0.60488100 0.91068600 0.12409200 1 - O O49 1 0.19419500 0.48078900 0.60488100 1 - O O50 1 0.39511900 0.08931400 0.87590800 1 - O O51 1 0.80580500 0.51921100 0.39511900 1 - O O52 1 0.89511900 0.01921100 0.30580500 1 - O O53 1 0.37590800 0.58931400 0.89511900 1 - O O54 1 0.10488100 0.98078900 0.69419500 1 - O O55 1 0.62409200 0.41068600 0.10488100 1 - O O56 1 0.37590800 0.28659400 0.48078900 1 - O O57 1 0.58931400 0.89511900 0.37590800 1 - O O58 1 0.62409200 0.71340600 0.51921100 1 - O O59 1 0.41068600 0.10488100 0.62409200 1 - O O60 1 0.12409200 0.60488100 0.91068600 1 - O O61 1 0.01921100 0.21340600 0.12409200 1 - O O62 1 0.87590800 0.39511900 0.08931400 1 - O O63 1 0.98078900 0.78659400 0.87590800 1 - O O64 1 0.30580500 0.89511900 0.01921100 1 - O O65 1 0.91068600 0.28659400 0.30580500 1 - O O66 1 0.69419500 0.10488100 0.98078900 1 - O O67 1 0.08931400 0.71340600 0.69419500 1 - O O68 1 0.19419500 0.21340600 0.58931400 1 - O O69 1 0.48078900 0.60488100 0.19419500 1 - O O70 1 0.80580500 0.78659400 0.41068600 1 - O O71 1 0.51921100 0.39511900 0.80580500 1 - O O72 1 0.28659400 0.30580500 0.91068600 1 - O O73 1 0.71340600 0.69419500 0.08931400 1 - O O74 1 0.21340600 0.12409200 0.01921100 1 - O O75 1 0.78659400 0.87590800 0.98078900 1 - O O76 1 0.89511900 0.37590800 0.58931400 1 - O O77 1 0.10488100 0.62409200 0.41068600 1 - O O78 1 0.60488100 0.19419500 0.48078900 1 - O O79 1 0.39511900 0.80580500 0.51921100 1 -" -Ca3Ga2(SnO4)3,mp-1214317,Ia-3d,[],0.10601735824996972,"{'tags': ['Ca3Ga2Sn3O12', 'garnet family']}","Full Formula (Ca12 Ga8 Sn12 O48) -Reduced Formula: Ca3Ga2(SnO4)3 -abc : 11.191485 11.191485 11.191485 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.75 0.125 0.375 0 - 3 Ca 0.125 0.25 0.375 0 - 4 Ca 0.375 0.75 0.125 0 - 5 Ca 0.25 0.875 0.625 0 - 6 Ca 0.875 0.75 0.625 0 - 7 Ca 0.625 0.25 0.875 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.625 0.875 0.75 0 - 10 Ca 0.125 0.375 0.75 0 - 11 Ca 0.875 0.625 0.25 0 - 12 Ga 0 0 0 0 - 13 Ga 0.5 0 0.5 0 - 14 Ga 0 0.5 0.5 0 - 15 Ga 0.5 0 0 0 - 16 Ga 0.5 0.5 0 0 - 17 Ga 0.5 0.5 0.5 0 - 18 Ga 0 0 0.5 0 - 19 Ga 0 0.5 0 0 - 20 Sn 0.25 0.625 0.375 0 - 21 Sn 0.75 0.375 0.625 0 - 22 Sn 0.75 0.875 0.125 0 - 23 Sn 0.375 0.25 0.625 0 - 24 Sn 0.625 0.75 0.375 0 - 25 Sn 0.25 0.125 0.875 0 - 26 Sn 0.125 0.75 0.875 0 - 27 Sn 0.875 0.25 0.125 0 - 28 Sn 0.625 0.375 0.25 0 - 29 Sn 0.375 0.625 0.75 0 - 30 Sn 0.875 0.125 0.75 0 - 31 Sn 0.125 0.875 0.25 0 - 32 O 0.473887 0.378744 0.302838 -0 - 33 O 0.526113 0.621256 0.697162 -0 - 34 O 0.575906 0.17105 0.197162 -0 - 35 O 0.924094 0.121256 0.595143 -0 - 36 O 0.302838 0.473887 0.378744 -0 - 37 O 0.32895 0.924094 0.302838 -0 - 38 O 0.424094 0.82895 0.802838 -0 - 39 O 0.075906 0.878744 0.404857 -0 - 40 O 0.697162 0.526113 0.621256 -0 - 41 O 0.67105 0.075906 0.697162 -0 - 42 O 0.026113 0.32895 0.904857 -0 - 43 O 0.197162 0.575906 0.17105 -0 - 44 O 0.121256 0.026113 0.197162 -0 - 45 O 0.973887 0.67105 0.095143 -0 - 46 O 0.802838 0.424094 0.82895 -0 - 47 O 0.878744 0.973887 0.802838 -0 - 48 O 0.595143 0.924094 0.121256 -0 - 49 O 0.17105 0.473887 0.595143 -0 - 50 O 0.404857 0.075906 0.878744 -0 - 51 O 0.82895 0.526113 0.404857 -0 - 52 O 0.904857 0.026113 0.32895 -0 - 53 O 0.378744 0.575906 0.904857 -0 - 54 O 0.095143 0.973887 0.67105 -0 - 55 O 0.621256 0.424094 0.095143 -0 - 56 O 0.378744 0.302838 0.473887 -0 - 57 O 0.575906 0.904857 0.378744 -0 - 58 O 0.621256 0.697162 0.526113 -0 - 59 O 0.424094 0.095143 0.621256 -0 - 60 O 0.121256 0.595143 0.924094 -0 - 61 O 0.026113 0.197162 0.121256 -0 - 62 O 0.878744 0.404857 0.075906 -0 - 63 O 0.973887 0.802838 0.878744 -0 - 64 O 0.32895 0.904857 0.026113 -0 - 65 O 0.924094 0.302838 0.32895 -0 - 66 O 0.67105 0.095143 0.973887 -0 - 67 O 0.075906 0.697162 0.67105 -0 - 68 O 0.17105 0.197162 0.575906 -0 - 69 O 0.473887 0.595143 0.17105 -0 - 70 O 0.82895 0.802838 0.424094 -0 - 71 O 0.526113 0.404857 0.82895 -0 - 72 O 0.302838 0.32895 0.924094 -0 - 73 O 0.697162 0.67105 0.075906 -0 - 74 O 0.197162 0.121256 0.026113 -0 - 75 O 0.802838 0.878744 0.973887 -0 - 76 O 0.904857 0.378744 0.575906 -0 - 77 O 0.095143 0.621256 0.424094 -0 - 78 O 0.595143 0.17105 0.473887 -0 - 79 O 0.404857 0.82895 0.526113 -0","# generated using pymatgen -data_Ca3Ga2(SnO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.19148521 -_cell_length_b 11.19148521 -_cell_length_c 11.19148521 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ga2(SnO4)3 -_chemical_formula_sum 'Ca12 Ga8 Sn12 O48' -_cell_volume 1079.04929381 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga13 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga14 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga15 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga16 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga18 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga19 1 0.00000000 0.50000000 0.00000000 1 - Sn Sn20 1 0.25000000 0.62500000 0.37500000 1 - Sn Sn21 1 0.75000000 0.37500000 0.62500000 1 - Sn Sn22 1 0.75000000 0.87500000 0.12500000 1 - Sn Sn23 1 0.37500000 0.25000000 0.62500000 1 - Sn Sn24 1 0.62500000 0.75000000 0.37500000 1 - Sn Sn25 1 0.25000000 0.12500000 0.87500000 1 - Sn Sn26 1 0.12500000 0.75000000 0.87500000 1 - Sn Sn27 1 0.87500000 0.25000000 0.12500000 1 - Sn Sn28 1 0.62500000 0.37500000 0.25000000 1 - Sn Sn29 1 0.37500000 0.62500000 0.75000000 1 - Sn Sn30 1 0.87500000 0.12500000 0.75000000 1 - Sn Sn31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.47388700 0.37874400 0.30283800 1 - O O33 1 0.52611300 0.62125600 0.69716200 1 - O O34 1 0.57590600 0.17105000 0.19716200 1 - O O35 1 0.92409400 0.12125600 0.59514300 1 - O O36 1 0.30283800 0.47388700 0.37874400 1 - O O37 1 0.32895000 0.92409400 0.30283800 1 - O O38 1 0.42409400 0.82895000 0.80283800 1 - O O39 1 0.07590600 0.87874400 0.40485700 1 - O O40 1 0.69716200 0.52611300 0.62125600 1 - O O41 1 0.67105000 0.07590600 0.69716200 1 - O O42 1 0.02611300 0.32895000 0.90485700 1 - O O43 1 0.19716200 0.57590600 0.17105000 1 - O O44 1 0.12125600 0.02611300 0.19716200 1 - O O45 1 0.97388700 0.67105000 0.09514300 1 - O O46 1 0.80283800 0.42409400 0.82895000 1 - O O47 1 0.87874400 0.97388700 0.80283800 1 - O O48 1 0.59514300 0.92409400 0.12125600 1 - O O49 1 0.17105000 0.47388700 0.59514300 1 - O O50 1 0.40485700 0.07590600 0.87874400 1 - O O51 1 0.82895000 0.52611300 0.40485700 1 - O O52 1 0.90485700 0.02611300 0.32895000 1 - O O53 1 0.37874400 0.57590600 0.90485700 1 - O O54 1 0.09514300 0.97388700 0.67105000 1 - O O55 1 0.62125600 0.42409400 0.09514300 1 - O O56 1 0.37874400 0.30283800 0.47388700 1 - O O57 1 0.57590600 0.90485700 0.37874400 1 - O O58 1 0.62125600 0.69716200 0.52611300 1 - O O59 1 0.42409400 0.09514300 0.62125600 1 - O O60 1 0.12125600 0.59514300 0.92409400 1 - O O61 1 0.02611300 0.19716200 0.12125600 1 - O O62 1 0.87874400 0.40485700 0.07590600 1 - O O63 1 0.97388700 0.80283800 0.87874400 1 - O O64 1 0.32895000 0.90485700 0.02611300 1 - O O65 1 0.92409400 0.30283800 0.32895000 1 - O O66 1 0.67105000 0.09514300 0.97388700 1 - O O67 1 0.07590600 0.69716200 0.67105000 1 - O O68 1 0.17105000 0.19716200 0.57590600 1 - O O69 1 0.47388700 0.59514300 0.17105000 1 - O O70 1 0.82895000 0.80283800 0.42409400 1 - O O71 1 0.52611300 0.40485700 0.82895000 1 - O O72 1 0.30283800 0.32895000 0.92409400 1 - O O73 1 0.69716200 0.67105000 0.07590600 1 - O O74 1 0.19716200 0.12125600 0.02611300 1 - O O75 1 0.80283800 0.87874400 0.97388700 1 - O O76 1 0.90485700 0.37874400 0.57590600 1 - O O77 1 0.09514300 0.62125600 0.42409400 1 - O O78 1 0.59514300 0.17105000 0.47388700 1 - O O79 1 0.40485700 0.82895000 0.52611300 1 -" -Ca3Lu2(GeO4)3,mp-1214423,Ia-3d,[],0.0,{'tags': []},"Full Formula (Ca12 Lu8 Ge12 O48) -Reduced Formula: Ca3Lu2(GeO4)3 -abc : 11.140014 11.140014 11.140014 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.75 0.125 0.375 0 - 3 Ca 0.125 0.25 0.375 0 - 4 Ca 0.375 0.75 0.125 0 - 5 Ca 0.25 0.875 0.625 0 - 6 Ca 0.875 0.75 0.625 0 - 7 Ca 0.625 0.25 0.875 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.625 0.875 0.75 0 - 10 Ca 0.125 0.375 0.75 0 - 11 Ca 0.875 0.625 0.25 0 - 12 Lu 0 0 0 0.001 - 13 Lu 0.5 0 0.5 0.001 - 14 Lu 0 0.5 0.5 0.001 - 15 Lu 0.5 0 0 0.001 - 16 Lu 0.5 0.5 0 0.001 - 17 Lu 0.5 0.5 0.5 0.001 - 18 Lu 0 0 0.5 0.001 - 19 Lu 0 0.5 0 0.001 - 20 Ge 0.25 0.625 0.375 0 - 21 Ge 0.75 0.375 0.625 0 - 22 Ge 0.75 0.875 0.125 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Ge 0.625 0.75 0.375 0 - 25 Ge 0.25 0.125 0.875 0 - 26 Ge 0.125 0.75 0.875 0 - 27 Ge 0.875 0.25 0.125 0 - 28 Ge 0.625 0.375 0.25 0 - 29 Ge 0.375 0.625 0.75 0 - 30 Ge 0.875 0.125 0.75 0 - 31 Ge 0.125 0.875 0.25 0 - 32 O 0.481898 0.37626 0.289065 -0.001 - 33 O 0.518102 0.62374 0.710935 -0.001 - 34 O 0.587195 0.192833 0.210935 -0.001 - 35 O 0.912805 0.12374 0.605638 -0.001 - 36 O 0.289065 0.481898 0.37626 -0.001 - 37 O 0.307167 0.912805 0.289065 -0.001 - 38 O 0.412805 0.807167 0.789065 -0.001 - 39 O 0.087195 0.87626 0.394362 -0.001 - 40 O 0.710935 0.518102 0.62374 -0.001 - 41 O 0.692833 0.087195 0.710935 -0.001 - 42 O 0.018102 0.307167 0.894362 -0.001 - 43 O 0.210935 0.587195 0.192833 -0.001 - 44 O 0.12374 0.018102 0.210935 -0.001 - 45 O 0.981898 0.692833 0.105638 -0.001 - 46 O 0.789065 0.412805 0.807167 -0.001 - 47 O 0.87626 0.981898 0.789065 -0.001 - 48 O 0.605638 0.912805 0.12374 -0.001 - 49 O 0.192833 0.481898 0.605638 -0.001 - 50 O 0.394362 0.087195 0.87626 -0.001 - 51 O 0.807167 0.518102 0.394362 -0.001 - 52 O 0.894362 0.018102 0.307167 -0.001 - 53 O 0.37626 0.587195 0.894362 -0.001 - 54 O 0.105638 0.981898 0.692833 -0.001 - 55 O 0.62374 0.412805 0.105638 -0.001 - 56 O 0.37626 0.289065 0.481898 -0.001 - 57 O 0.587195 0.894362 0.37626 -0.001 - 58 O 0.62374 0.710935 0.518102 -0.001 - 59 O 0.412805 0.105638 0.62374 -0.001 - 60 O 0.12374 0.605638 0.912805 -0.001 - 61 O 0.018102 0.210935 0.12374 -0.001 - 62 O 0.87626 0.394362 0.087195 -0.001 - 63 O 0.981898 0.789065 0.87626 -0.001 - 64 O 0.307167 0.894362 0.018102 -0.001 - 65 O 0.912805 0.289065 0.307167 -0.001 - 66 O 0.692833 0.105638 0.981898 -0.001 - 67 O 0.087195 0.710935 0.692833 -0.001 - 68 O 0.192833 0.210935 0.587195 -0.001 - 69 O 0.481898 0.605638 0.192833 -0.001 - 70 O 0.807167 0.789065 0.412805 -0.001 - 71 O 0.518102 0.394362 0.807167 -0.001 - 72 O 0.289065 0.307167 0.912805 -0.001 - 73 O 0.710935 0.692833 0.087195 -0.001 - 74 O 0.210935 0.12374 0.018102 -0.001 - 75 O 0.789065 0.87626 0.981898 -0.001 - 76 O 0.894362 0.37626 0.587195 -0.001 - 77 O 0.105638 0.62374 0.412805 -0.001 - 78 O 0.605638 0.192833 0.481898 -0.001 - 79 O 0.394362 0.807167 0.518102 -0.001","# generated using pymatgen -data_Ca3Lu2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.14001386 -_cell_length_b 11.14001386 -_cell_length_c 11.14001386 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Lu2(GeO4)3 -_chemical_formula_sum 'Ca12 Lu8 Ge12 O48' -_cell_volume 1064.22952297 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca6 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca7 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Lu Lu12 1 0.00000000 0.00000000 0.00000000 1 - Lu Lu13 1 0.50000000 0.00000000 0.50000000 1 - Lu Lu14 1 0.00000000 0.50000000 0.50000000 1 - Lu Lu15 1 0.50000000 0.00000000 0.00000000 1 - Lu Lu16 1 0.50000000 0.50000000 0.00000000 1 - Lu Lu17 1 0.50000000 0.50000000 0.50000000 1 - Lu Lu18 1 0.00000000 0.00000000 0.50000000 1 - Lu Lu19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48189800 0.37626000 0.28906500 1 - O O33 1 0.51810200 0.62374000 0.71093500 1 - O O34 1 0.58719500 0.19283300 0.21093500 1 - O O35 1 0.91280500 0.12374000 0.60563800 1 - O O36 1 0.28906500 0.48189800 0.37626000 1 - O O37 1 0.30716700 0.91280500 0.28906500 1 - O O38 1 0.41280500 0.80716700 0.78906500 1 - O O39 1 0.08719500 0.87626000 0.39436200 1 - O O40 1 0.71093500 0.51810200 0.62374000 1 - O O41 1 0.69283300 0.08719500 0.71093500 1 - O O42 1 0.01810200 0.30716700 0.89436200 1 - O O43 1 0.21093500 0.58719500 0.19283300 1 - O O44 1 0.12374000 0.01810200 0.21093500 1 - O O45 1 0.98189800 0.69283300 0.10563800 1 - O O46 1 0.78906500 0.41280500 0.80716700 1 - O O47 1 0.87626000 0.98189800 0.78906500 1 - O O48 1 0.60563800 0.91280500 0.12374000 1 - O O49 1 0.19283300 0.48189800 0.60563800 1 - O O50 1 0.39436200 0.08719500 0.87626000 1 - O O51 1 0.80716700 0.51810200 0.39436200 1 - O O52 1 0.89436200 0.01810200 0.30716700 1 - O O53 1 0.37626000 0.58719500 0.89436200 1 - O O54 1 0.10563800 0.98189800 0.69283300 1 - O O55 1 0.62374000 0.41280500 0.10563800 1 - O O56 1 0.37626000 0.28906500 0.48189800 1 - O O57 1 0.58719500 0.89436200 0.37626000 1 - O O58 1 0.62374000 0.71093500 0.51810200 1 - O O59 1 0.41280500 0.10563800 0.62374000 1 - O O60 1 0.12374000 0.60563800 0.91280500 1 - O O61 1 0.01810200 0.21093500 0.12374000 1 - O O62 1 0.87626000 0.39436200 0.08719500 1 - O O63 1 0.98189800 0.78906500 0.87626000 1 - O O64 1 0.30716700 0.89436200 0.01810200 1 - O O65 1 0.91280500 0.28906500 0.30716700 1 - O O66 1 0.69283300 0.10563800 0.98189800 1 - O O67 1 0.08719500 0.71093500 0.69283300 1 - O O68 1 0.19283300 0.21093500 0.58719500 1 - O O69 1 0.48189800 0.60563800 0.19283300 1 - O O70 1 0.80716700 0.78906500 0.41280500 1 - O O71 1 0.51810200 0.39436200 0.80716700 1 - O O72 1 0.28906500 0.30716700 0.91280500 1 - O O73 1 0.71093500 0.69283300 0.08719500 1 - O O74 1 0.21093500 0.12374000 0.01810200 1 - O O75 1 0.78906500 0.87626000 0.98189800 1 - O O76 1 0.89436200 0.37626000 0.58719500 1 - O O77 1 0.10563800 0.62374000 0.41280500 1 - O O78 1 0.60563800 0.19283300 0.48189800 1 - O O79 1 0.39436200 0.80716700 0.51810200 1 -" -Al2Cd3(GeO4)3,mp-1214967,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Al8 Cd12 Ge12 O48) -Reduced Formula: Al2Cd3(GeO4)3 -abc : 10.610465 10.610465 10.610465 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0 0 - 1 Al 0.5 0 0.5 0 - 2 Al 0 0.5 0.5 0 - 3 Al 0.5 0 0 0 - 4 Al 0.5 0.5 0 0 - 5 Al 0.5 0.5 0.5 0 - 6 Al 0 0 0.5 0 - 7 Al 0 0.5 0 0 - 8 Cd 0.25 0.375 0.125 0 - 9 Cd 0.75 0.625 0.875 0 - 10 Cd 0.75 0.125 0.375 0 - 11 Cd 0.125 0.25 0.375 0 - 12 Cd 0.375 0.75 0.125 0 - 13 Cd 0.25 0.875 0.625 0 - 14 Cd 0.875 0.75 0.625 0 - 15 Cd 0.625 0.25 0.875 0 - 16 Cd 0.375 0.125 0.25 0 - 17 Cd 0.625 0.875 0.75 0 - 18 Cd 0.125 0.375 0.75 0 - 19 Cd 0.875 0.625 0.25 0 - 20 Ge 0.25 0.625 0.375 0 - 21 Ge 0.75 0.375 0.625 0 - 22 Ge 0.75 0.875 0.125 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Ge 0.625 0.75 0.375 0 - 25 Ge 0.25 0.125 0.875 0 - 26 Ge 0.125 0.75 0.875 0 - 27 Ge 0.875 0.25 0.125 0 - 28 Ge 0.625 0.375 0.25 0 - 29 Ge 0.375 0.625 0.75 0 - 30 Ge 0.875 0.125 0.75 0 - 31 Ge 0.125 0.875 0.25 0 - 32 O 0.48588 0.384237 0.305902 -0 - 33 O 0.51412 0.615763 0.694098 -0 - 34 O 0.578336 0.179978 0.194098 -0 - 35 O 0.921664 0.115763 0.601642 -0 - 36 O 0.305902 0.48588 0.384237 -0 - 37 O 0.320022 0.921664 0.305902 -0 - 38 O 0.421664 0.820022 0.805902 -0 - 39 O 0.078336 0.884237 0.398358 -0 - 40 O 0.694098 0.51412 0.615763 -0 - 41 O 0.679978 0.078336 0.694098 -0 - 42 O 0.01412 0.320022 0.898358 -0 - 43 O 0.194098 0.578336 0.179978 -0 - 44 O 0.115763 0.01412 0.194098 -0 - 45 O 0.98588 0.679978 0.101642 -0 - 46 O 0.805902 0.421664 0.820022 -0 - 47 O 0.884237 0.98588 0.805902 -0 - 48 O 0.601642 0.921664 0.115763 -0 - 49 O 0.179978 0.48588 0.601642 -0 - 50 O 0.398358 0.078336 0.884237 -0 - 51 O 0.820022 0.51412 0.398358 -0 - 52 O 0.898358 0.01412 0.320022 -0 - 53 O 0.384237 0.578336 0.898358 -0 - 54 O 0.101642 0.98588 0.679978 -0 - 55 O 0.615763 0.421664 0.101642 -0 - 56 O 0.384237 0.305902 0.48588 -0 - 57 O 0.578336 0.898358 0.384237 -0 - 58 O 0.615763 0.694098 0.51412 -0 - 59 O 0.421664 0.101642 0.615763 -0 - 60 O 0.115763 0.601642 0.921664 -0 - 61 O 0.01412 0.194098 0.115763 -0 - 62 O 0.884237 0.398358 0.078336 -0 - 63 O 0.98588 0.805902 0.884237 -0 - 64 O 0.320022 0.898358 0.01412 -0 - 65 O 0.921664 0.305902 0.320022 -0 - 66 O 0.679978 0.101642 0.98588 -0 - 67 O 0.078336 0.694098 0.679978 -0 - 68 O 0.179978 0.194098 0.578336 -0 - 69 O 0.48588 0.601642 0.179978 -0 - 70 O 0.820022 0.805902 0.421664 -0 - 71 O 0.51412 0.398358 0.820022 -0 - 72 O 0.305902 0.320022 0.921664 -0 - 73 O 0.694098 0.679978 0.078336 -0 - 74 O 0.194098 0.115763 0.01412 -0 - 75 O 0.805902 0.884237 0.98588 -0 - 76 O 0.898358 0.384237 0.578336 -0 - 77 O 0.101642 0.615763 0.421664 -0 - 78 O 0.601642 0.179978 0.48588 -0 - 79 O 0.398358 0.820022 0.51412 -0","# generated using pymatgen -data_Al2Cd3(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.61046530 -_cell_length_b 10.61046530 -_cell_length_c 10.61046530 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Cd3(GeO4)3 -_chemical_formula_sum 'Al8 Cd12 Ge12 O48' -_cell_volume 919.56280860 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.00000000 1 - Al Al1 1 0.50000000 0.00000000 0.50000000 1 - Al Al2 1 0.00000000 0.50000000 0.50000000 1 - Al Al3 1 0.50000000 0.00000000 0.00000000 1 - Al Al4 1 0.50000000 0.50000000 0.00000000 1 - Al Al5 1 0.50000000 0.50000000 0.50000000 1 - Al Al6 1 0.00000000 0.00000000 0.50000000 1 - Al Al7 1 0.00000000 0.50000000 0.00000000 1 - Cd Cd8 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd9 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd10 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd11 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd12 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd13 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd14 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd15 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd16 1 0.37500000 0.12500000 0.25000000 1 - Cd Cd17 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd18 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd19 1 0.87500000 0.62500000 0.25000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48588000 0.38423700 0.30590200 1 - O O33 1 0.51412000 0.61576300 0.69409800 1 - O O34 1 0.57833600 0.17997800 0.19409800 1 - O O35 1 0.92166400 0.11576300 0.60164200 1 - O O36 1 0.30590200 0.48588000 0.38423700 1 - O O37 1 0.32002200 0.92166400 0.30590200 1 - O O38 1 0.42166400 0.82002200 0.80590200 1 - O O39 1 0.07833600 0.88423700 0.39835800 1 - O O40 1 0.69409800 0.51412000 0.61576300 1 - O O41 1 0.67997800 0.07833600 0.69409800 1 - O O42 1 0.01412000 0.32002200 0.89835800 1 - O O43 1 0.19409800 0.57833600 0.17997800 1 - O O44 1 0.11576300 0.01412000 0.19409800 1 - O O45 1 0.98588000 0.67997800 0.10164200 1 - O O46 1 0.80590200 0.42166400 0.82002200 1 - O O47 1 0.88423700 0.98588000 0.80590200 1 - O O48 1 0.60164200 0.92166400 0.11576300 1 - O O49 1 0.17997800 0.48588000 0.60164200 1 - O O50 1 0.39835800 0.07833600 0.88423700 1 - O O51 1 0.82002200 0.51412000 0.39835800 1 - O O52 1 0.89835800 0.01412000 0.32002200 1 - O O53 1 0.38423700 0.57833600 0.89835800 1 - O O54 1 0.10164200 0.98588000 0.67997800 1 - O O55 1 0.61576300 0.42166400 0.10164200 1 - O O56 1 0.38423700 0.30590200 0.48588000 1 - O O57 1 0.57833600 0.89835800 0.38423700 1 - O O58 1 0.61576300 0.69409800 0.51412000 1 - O O59 1 0.42166400 0.10164200 0.61576300 1 - O O60 1 0.11576300 0.60164200 0.92166400 1 - O O61 1 0.01412000 0.19409800 0.11576300 1 - O O62 1 0.88423700 0.39835800 0.07833600 1 - O O63 1 0.98588000 0.80590200 0.88423700 1 - O O64 1 0.32002200 0.89835800 0.01412000 1 - O O65 1 0.92166400 0.30590200 0.32002200 1 - O O66 1 0.67997800 0.10164200 0.98588000 1 - O O67 1 0.07833600 0.69409800 0.67997800 1 - O O68 1 0.17997800 0.19409800 0.57833600 1 - O O69 1 0.48588000 0.60164200 0.17997800 1 - O O70 1 0.82002200 0.80590200 0.42166400 1 - O O71 1 0.51412000 0.39835800 0.82002200 1 - O O72 1 0.30590200 0.32002200 0.92166400 1 - O O73 1 0.69409800 0.67997800 0.07833600 1 - O O74 1 0.19409800 0.11576300 0.01412000 1 - O O75 1 0.80590200 0.88423700 0.98588000 1 - O O76 1 0.89835800 0.38423700 0.57833600 1 - O O77 1 0.10164200 0.61576300 0.42166400 1 - O O78 1 0.60164200 0.17997800 0.48588000 1 - O O79 1 0.39835800 0.82002200 0.51412000 1 -" -Cd3Fe2(GeO4)3,mp-1215138,Ia-3d,[],0.0013426380937389126,{'tags': ['garnet family']},"Full Formula (Cd12 Fe8 Ge12 O48) -Reduced Formula: Cd3Fe2(GeO4)3 -abc : 10.827460 10.827460 10.827460 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Cd 0.25 0.375 0.125 0.006 - 1 Cd 0.75 0.625 0.875 0.006 - 2 Cd 0.75 0.125 0.375 0.006 - 3 Cd 0.125 0.25 0.375 0.006 - 4 Cd 0.375 0.75 0.125 0.006 - 5 Cd 0.25 0.875 0.625 0.006 - 6 Cd 0.875 0.75 0.625 0.006 - 7 Cd 0.625 0.25 0.875 0.006 - 8 Cd 0.375 0.125 0.25 0.006 - 9 Cd 0.625 0.875 0.75 0.006 - 10 Cd 0.125 0.375 0.75 0.006 - 11 Cd 0.875 0.625 0.25 0.006 - 12 Fe 0 0 0 4.369 - 13 Fe 0.5 0 0.5 4.37 - 14 Fe 0 0.5 0.5 4.37 - 15 Fe 0.5 0 0 4.37 - 16 Fe 0.5 0.5 0 4.369 - 17 Fe 0.5 0.5 0.5 4.369 - 18 Fe 0 0 0.5 4.37 - 19 Fe 0 0.5 0 4.369 - 20 Ge 0.25 0.625 0.375 0.027 - 21 Ge 0.75 0.375 0.625 0.027 - 22 Ge 0.75 0.875 0.125 0.027 - 23 Ge 0.375 0.25 0.625 0.027 - 24 Ge 0.625 0.75 0.375 0.027 - 25 Ge 0.25 0.125 0.875 0.027 - 26 Ge 0.125 0.75 0.875 0.027 - 27 Ge 0.875 0.25 0.125 0.027 - 28 Ge 0.625 0.375 0.25 0.027 - 29 Ge 0.375 0.625 0.75 0.027 - 30 Ge 0.875 0.125 0.75 0.027 - 31 Ge 0.125 0.875 0.25 0.027 - 32 O 0.484159 0.379824 0.299606 0.078 - 33 O 0.515841 0.620176 0.700394 0.078 - 34 O 0.580218 0.184553 0.200394 0.078 - 35 O 0.919782 0.120176 0.604335 0.078 - 36 O 0.299606 0.484159 0.379824 0.08 - 37 O 0.315447 0.919782 0.299606 0.08 - 38 O 0.419782 0.815447 0.799606 0.078 - 39 O 0.080218 0.879824 0.395665 0.078 - 40 O 0.700394 0.515841 0.620176 0.08 - 41 O 0.684553 0.080218 0.700394 0.08 - 42 O 0.015841 0.315447 0.895665 0.078 - 43 O 0.200394 0.580218 0.184553 0.08 - 44 O 0.120176 0.015841 0.200394 0.079 - 45 O 0.984159 0.684553 0.104335 0.078 - 46 O 0.799606 0.419782 0.815447 0.08 - 47 O 0.879824 0.984159 0.799606 0.079 - 48 O 0.604335 0.919782 0.120176 0.079 - 49 O 0.184553 0.484159 0.604335 0.08 - 50 O 0.395665 0.080218 0.879824 0.079 - 51 O 0.815447 0.515841 0.395665 0.08 - 52 O 0.895665 0.015841 0.315447 0.079 - 53 O 0.379824 0.580218 0.895665 0.079 - 54 O 0.104335 0.984159 0.684553 0.079 - 55 O 0.620176 0.419782 0.104335 0.079 - 56 O 0.379824 0.299606 0.484159 0.079 - 57 O 0.580218 0.895665 0.379824 0.078 - 58 O 0.620176 0.700394 0.515841 0.079 - 59 O 0.419782 0.104335 0.620176 0.078 - 60 O 0.120176 0.604335 0.919782 0.079 - 61 O 0.015841 0.200394 0.120176 0.078 - 62 O 0.879824 0.395665 0.080218 0.079 - 63 O 0.984159 0.799606 0.879824 0.078 - 64 O 0.315447 0.895665 0.015841 0.08 - 65 O 0.919782 0.299606 0.315447 0.078 - 66 O 0.684553 0.104335 0.984159 0.08 - 67 O 0.080218 0.700394 0.684553 0.078 - 68 O 0.184553 0.200394 0.580218 0.08 - 69 O 0.484159 0.604335 0.184553 0.078 - 70 O 0.815447 0.799606 0.419782 0.08 - 71 O 0.515841 0.395665 0.815447 0.078 - 72 O 0.299606 0.315447 0.919782 0.08 - 73 O 0.700394 0.684553 0.080218 0.08 - 74 O 0.200394 0.120176 0.015841 0.08 - 75 O 0.799606 0.879824 0.984159 0.08 - 76 O 0.895665 0.379824 0.580218 0.079 - 77 O 0.104335 0.620176 0.419782 0.079 - 78 O 0.604335 0.184553 0.484159 0.079 - 79 O 0.395665 0.815447 0.515841 0.079","# generated using pymatgen -data_Cd3Fe2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.82746009 -_cell_length_b 10.82746009 -_cell_length_c 10.82746009 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Cd3Fe2(GeO4)3 -_chemical_formula_sum 'Cd12 Fe8 Ge12 O48' -_cell_volume 977.14245852 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Cd Cd0 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd1 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd2 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd3 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd4 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd5 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd6 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd7 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd8 1 0.37500000 0.12500000 0.25000000 1 - Cd Cd9 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd10 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd11 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe12 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe18 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge28 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.48415900 0.37982400 0.29960600 1 - O O33 1 0.51584100 0.62017600 0.70039400 1 - O O34 1 0.58021800 0.18455300 0.20039400 1 - O O35 1 0.91978200 0.12017600 0.60433500 1 - O O36 1 0.29960600 0.48415900 0.37982400 1 - O O37 1 0.31544700 0.91978200 0.29960600 1 - O O38 1 0.41978200 0.81544700 0.79960600 1 - O O39 1 0.08021800 0.87982400 0.39566500 1 - O O40 1 0.70039400 0.51584100 0.62017600 1 - O O41 1 0.68455300 0.08021800 0.70039400 1 - O O42 1 0.01584100 0.31544700 0.89566500 1 - O O43 1 0.20039400 0.58021800 0.18455300 1 - O O44 1 0.12017600 0.01584100 0.20039400 1 - O O45 1 0.98415900 0.68455300 0.10433500 1 - O O46 1 0.79960600 0.41978200 0.81544700 1 - O O47 1 0.87982400 0.98415900 0.79960600 1 - O O48 1 0.60433500 0.91978200 0.12017600 1 - O O49 1 0.18455300 0.48415900 0.60433500 1 - O O50 1 0.39566500 0.08021800 0.87982400 1 - O O51 1 0.81544700 0.51584100 0.39566500 1 - O O52 1 0.89566500 0.01584100 0.31544700 1 - O O53 1 0.37982400 0.58021800 0.89566500 1 - O O54 1 0.10433500 0.98415900 0.68455300 1 - O O55 1 0.62017600 0.41978200 0.10433500 1 - O O56 1 0.37982400 0.29960600 0.48415900 1 - O O57 1 0.58021800 0.89566500 0.37982400 1 - O O58 1 0.62017600 0.70039400 0.51584100 1 - O O59 1 0.41978200 0.10433500 0.62017600 1 - O O60 1 0.12017600 0.60433500 0.91978200 1 - O O61 1 0.01584100 0.20039400 0.12017600 1 - O O62 1 0.87982400 0.39566500 0.08021800 1 - O O63 1 0.98415900 0.79960600 0.87982400 1 - O O64 1 0.31544700 0.89566500 0.01584100 1 - O O65 1 0.91978200 0.29960600 0.31544700 1 - O O66 1 0.68455300 0.10433500 0.98415900 1 - O O67 1 0.08021800 0.70039400 0.68455300 1 - O O68 1 0.18455300 0.20039400 0.58021800 1 - O O69 1 0.48415900 0.60433500 0.18455300 1 - O O70 1 0.81544700 0.79960600 0.41978200 1 - O O71 1 0.51584100 0.39566500 0.81544700 1 - O O72 1 0.29960600 0.31544700 0.91978200 1 - O O73 1 0.70039400 0.68455300 0.08021800 1 - O O74 1 0.20039400 0.12017600 0.01584100 1 - O O75 1 0.79960600 0.87982400 0.98415900 1 - O O76 1 0.89566500 0.37982400 0.58021800 1 - O O77 1 0.10433500 0.62017600 0.41978200 1 - O O78 1 0.60433500 0.18455300 0.48415900 1 - O O79 1 0.39566500 0.81544700 0.51584100 1 -" -Mn2Fe3(SiO4)3,mp-1249697,I4_1/acd,[],0.10413126937499406,{'tags': []},"Full Formula (Mn8 Fe12 Si12 O48) -Reduced Formula: Mn2Fe3(SiO4)3 -abc : 10.301577 10.301578 10.301578 -angles: 111.544513 108.444620 108.444629 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0 0 0.5 3.878 - 1 Mn 0.5 0.5 0.5 3.878 - 2 Mn 0 0 0 3.878 - 3 Mn 0.5 0 0 3.878 - 4 Mn 0.5 0 0.5 3.878 - 5 Mn 0 0.5 0.5 3.878 - 6 Mn 0.5 0.5 0 3.878 - 7 Mn 0 0.5 0 3.878 - 8 Fe 0.371734 0.121734 0.25 3.792 - 9 Fe 0.371734 0.75 0.121734 3.792 - 10 Fe 0.628266 0.25 0.878266 3.792 - 11 Fe 0.128266 0.378266 0.75 3.792 - 12 Fe 0.25 0.875 0.625 3.786 - 13 Fe 0.871734 0.75 0.621734 3.792 - 14 Fe 0.871734 0.621734 0.25 3.792 - 15 Fe 0.628266 0.878266 0.75 3.792 - 16 Fe 0.75 0.125 0.375 3.786 - 17 Fe 0.75 0.625 0.875 3.786 - 18 Fe 0.25 0.375 0.125 3.786 - 19 Fe 0.128266 0.25 0.378266 3.792 - 20 Si 0.125645 0.875645 0.25 0.015 - 21 Si 0.874355 0.124355 0.75 0.015 - 22 Si 0.625645 0.75 0.375645 0.015 - 23 Si 0.75 0.375 0.625 0.016 - 24 Si 0.25 0.625 0.375 0.016 - 25 Si 0.374355 0.624355 0.75 0.015 - 26 Si 0.75 0.875 0.125 0.016 - 27 Si 0.374355 0.25 0.624355 0.015 - 28 Si 0.874355 0.25 0.124355 0.015 - 29 Si 0.25 0.125 0.875 0.016 - 30 Si 0.625645 0.375645 0.25 0.015 - 31 Si 0.125645 0.75 0.875645 0.015 - 32 O 0.621614 0.40692 0.103368 0.048 - 33 O 0.803552 0.518246 0.396632 0.048 - 34 O 0.41544 0.10467 0.61906 -0.009 - 35 O 0.58456 0.89533 0.38094 -0.009 - 36 O 0.378386 0.285305 0.481754 0.048 - 37 O 0.378386 0.59308 0.896632 0.048 - 38 O 0.196448 0.214695 0.59308 0.048 - 39 O 0.894614 0.022294 0.306757 0.045 - 40 O 0.284463 0.477706 0.37232 0.045 - 41 O 0.98561 0.68923 0.10467 -0.009 - 42 O 0.48561 0.38094 0.296379 -0.009 - 43 O 0.215537 0.12768 0.022294 0.045 - 44 O 0.01439 0.203621 0.11906 -0.009 - 45 O 0.08456 0.88094 0.39533 -0.009 - 46 O 0.91544 0.296379 0.31077 -0.009 - 47 O 0.784463 0.412144 0.806757 0.045 - 48 O 0.878386 0.396632 0.09308 0.048 - 49 O 0.284463 0.306757 0.912144 0.045 - 50 O 0.621614 0.714695 0.518246 0.048 - 51 O 0.303552 0.896632 0.018246 0.048 - 52 O 0.105386 0.62768 0.412144 0.045 - 53 O 0.303552 0.90692 0.285305 0.048 - 54 O 0.121614 0.018246 0.214695 0.048 - 55 O 0.784463 0.87232 0.977706 0.045 - 56 O 0.605386 0.193243 0.477706 0.045 - 57 O 0.41544 0.81077 0.796379 -0.009 - 58 O 0.51439 0.61906 0.703621 -0.009 - 59 O 0.51439 0.39533 0.81077 -0.009 - 60 O 0.696448 0.09308 0.714695 0.048 - 61 O 0.08456 0.703621 0.68923 -0.009 - 62 O 0.394614 0.806757 0.522294 0.045 - 63 O 0.878386 0.981754 0.785305 0.048 - 64 O 0.696448 0.103368 0.981754 0.048 - 65 O 0.803552 0.785305 0.40692 0.048 - 66 O 0.715537 0.522294 0.62768 0.045 - 67 O 0.196448 0.481754 0.603368 0.048 - 68 O 0.48561 0.60467 0.18923 -0.009 - 69 O 0.894614 0.37232 0.587856 0.045 - 70 O 0.58456 0.18923 0.203621 -0.009 - 71 O 0.215537 0.587856 0.193243 0.045 - 72 O 0.98561 0.796379 0.88094 -0.009 - 73 O 0.91544 0.11906 0.60467 -0.009 - 74 O 0.715537 0.693243 0.087856 0.045 - 75 O 0.121614 0.603368 0.90692 0.048 - 76 O 0.605386 0.912144 0.12768 0.045 - 77 O 0.01439 0.31077 0.89533 -0.009 - 78 O 0.394614 0.087856 0.87232 0.045 - 79 O 0.105386 0.977706 0.693243 0.045","# generated using pymatgen -data_Mn2Fe3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.30157690 -_cell_length_b 10.30157806 -_cell_length_c 10.30157809 -_cell_angle_alpha 111.54451316 -_cell_angle_beta 108.44462035 -_cell_angle_gamma 108.44462863 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn2Fe3(SiO4)3 -_chemical_formula_sum 'Mn8 Fe12 Si12 O48' -_cell_volume 840.73849868 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn1 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn2 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn3 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn4 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn5 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn6 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn7 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe8 1 0.37173400 0.12173400 0.25000000 1 - Fe Fe9 1 0.37173400 0.75000000 0.12173400 1 - Fe Fe10 1 0.62826600 0.25000000 0.87826600 1 - Fe Fe11 1 0.12826600 0.37826600 0.75000000 1 - Fe Fe12 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe13 1 0.87173400 0.75000000 0.62173400 1 - Fe Fe14 1 0.87173400 0.62173400 0.25000000 1 - Fe Fe15 1 0.62826600 0.87826600 0.75000000 1 - Fe Fe16 1 0.75000000 0.12500000 0.37500000 1 - Fe Fe17 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe18 1 0.25000000 0.37500000 0.12500000 1 - Fe Fe19 1 0.12826600 0.25000000 0.37826600 1 - Si Si20 1 0.12564500 0.87564500 0.25000000 1 - Si Si21 1 0.87435500 0.12435500 0.75000000 1 - Si Si22 1 0.62564500 0.75000000 0.37564500 1 - Si Si23 1 0.75000000 0.37500000 0.62500000 1 - Si Si24 1 0.25000000 0.62500000 0.37500000 1 - Si Si25 1 0.37435500 0.62435500 0.75000000 1 - Si Si26 1 0.75000000 0.87500000 0.12500000 1 - Si Si27 1 0.37435500 0.25000000 0.62435500 1 - Si Si28 1 0.87435500 0.25000000 0.12435500 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.62564500 0.37564500 0.25000000 1 - Si Si31 1 0.12564500 0.75000000 0.87564500 1 - O O32 1 0.62161400 0.40692000 0.10336800 1 - O O33 1 0.80355200 0.51824600 0.39663200 1 - O O34 1 0.41544000 0.10467000 0.61906000 1 - O O35 1 0.58456000 0.89533000 0.38094000 1 - O O36 1 0.37838600 0.28530500 0.48175400 1 - O O37 1 0.37838600 0.59308000 0.89663200 1 - O O38 1 0.19644800 0.21469500 0.59308000 1 - O O39 1 0.89461400 0.02229400 0.30675700 1 - O O40 1 0.28446300 0.47770600 0.37232000 1 - O O41 1 0.98561000 0.68923000 0.10467000 1 - O O42 1 0.48561000 0.38094000 0.29637900 1 - O O43 1 0.21553700 0.12768000 0.02229400 1 - O O44 1 0.01439000 0.20362100 0.11906000 1 - O O45 1 0.08456000 0.88094000 0.39533000 1 - O O46 1 0.91544000 0.29637900 0.31077000 1 - O O47 1 0.78446300 0.41214400 0.80675700 1 - O O48 1 0.87838600 0.39663200 0.09308000 1 - O O49 1 0.28446300 0.30675700 0.91214400 1 - O O50 1 0.62161400 0.71469500 0.51824600 1 - O O51 1 0.30355200 0.89663200 0.01824600 1 - O O52 1 0.10538600 0.62768000 0.41214400 1 - O O53 1 0.30355200 0.90692000 0.28530500 1 - O O54 1 0.12161400 0.01824600 0.21469500 1 - O O55 1 0.78446300 0.87232000 0.97770600 1 - O O56 1 0.60538600 0.19324300 0.47770600 1 - O O57 1 0.41544000 0.81077000 0.79637900 1 - O O58 1 0.51439000 0.61906000 0.70362100 1 - O O59 1 0.51439000 0.39533000 0.81077000 1 - O O60 1 0.69644800 0.09308000 0.71469500 1 - O O61 1 0.08456000 0.70362100 0.68923000 1 - O O62 1 0.39461400 0.80675700 0.52229400 1 - O O63 1 0.87838600 0.98175400 0.78530500 1 - O O64 1 0.69644800 0.10336800 0.98175400 1 - O O65 1 0.80355200 0.78530500 0.40692000 1 - O O66 1 0.71553700 0.52229400 0.62768000 1 - O O67 1 0.19644800 0.48175400 0.60336800 1 - O O68 1 0.48561000 0.60467000 0.18923000 1 - O O69 1 0.89461400 0.37232000 0.58785600 1 - O O70 1 0.58456000 0.18923000 0.20362100 1 - O O71 1 0.21553700 0.58785600 0.19324300 1 - O O72 1 0.98561000 0.79637900 0.88094000 1 - O O73 1 0.91544000 0.11906000 0.60467000 1 - O O74 1 0.71553700 0.69324300 0.08785600 1 - O O75 1 0.12161400 0.60336800 0.90692000 1 - O O76 1 0.60538600 0.91214400 0.12768000 1 - O O77 1 0.01439000 0.31077000 0.89533000 1 - O O78 1 0.39461400 0.08785600 0.87232000 1 - O O79 1 0.10538600 0.97770600 0.69324300 1 -" -V2Zn3(SiO4)3,mp-1251134,Ia-3d,[],0.1734235050833366,{'tags': []},"Full Formula (V8 Zn12 Si12 O48) -Reduced Formula: V2Zn3(SiO4)3 -abc : 10.309379 10.309379 10.309379 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 V 0.5 0 0 1.906 - 1 V 0.5 0.5 0 1.966 - 2 V 0 0.5 0.5 1.942 - 3 V 0 0 0.5 1.942 - 4 V 0.5 0.5 0.5 1.966 - 5 V 0 0.5 0 1.966 - 6 V 0.5 0 0.5 1.906 - 7 V 0 0 0 1.966 - 8 Zn 0.25 0.375 0.125 0.015 - 9 Zn 0.75 0.125 0.375 0.016 - 10 Zn 0.375 0.125 0.25 0.016 - 11 Zn 0.125 0.375 0.75 0.016 - 12 Zn 0.25 0.875 0.625 0.016 - 13 Zn 0.125 0.25 0.375 0.016 - 14 Zn 0.625 0.25 0.875 0.016 - 15 Zn 0.75 0.625 0.875 0.015 - 16 Zn 0.875 0.75 0.625 0.016 - 17 Zn 0.875 0.625 0.25 0.016 - 18 Zn 0.625 0.875 0.75 0.016 - 19 Zn 0.375 0.75 0.125 0.016 - 20 Si 0.125 0.75 0.875 0.008 - 21 Si 0.875 0.25 0.125 0.008 - 22 Si 0.75 0.375 0.625 0.008 - 23 Si 0.125 0.875 0.25 0.008 - 24 Si 0.25 0.125 0.875 0.008 - 25 Si 0.375 0.625 0.75 0.008 - 26 Si 0.375 0.25 0.625 0.008 - 27 Si 0.875 0.125 0.75 0.008 - 28 Si 0.625 0.375 0.25 0.008 - 29 Si 0.75 0.875 0.125 0.008 - 30 Si 0.25 0.625 0.375 0.008 - 31 Si 0.625 0.75 0.375 0.008 - 32 O 0.585853 0.89381 0.376356 -0.021 - 33 O 0.376356 0.585853 0.89381 -0.018 - 34 O 0.290503 0.307957 0.914147 -0.018 - 35 O 0.482546 0.60619 0.192043 -0.019 - 36 O 0.307957 0.89381 0.017454 -0.021 - 37 O 0.123644 0.017454 0.209497 -0.019 - 38 O 0.376356 0.290503 0.482546 -0.018 - 39 O 0.89381 0.376356 0.585853 -0.02 - 40 O 0.192043 0.209497 0.585853 -0.02 - 41 O 0.482546 0.376356 0.290503 -0.019 - 42 O 0.89381 0.017454 0.307957 -0.02 - 43 O 0.60619 0.914147 0.123644 -0.021 - 44 O 0.914147 0.123644 0.60619 -0.019 - 45 O 0.290503 0.482546 0.376356 -0.018 - 46 O 0.585853 0.192043 0.209497 -0.021 - 47 O 0.209497 0.585853 0.192043 -0.018 - 48 O 0.017454 0.307957 0.89381 -0.019 - 49 O 0.914147 0.290503 0.307957 -0.019 - 50 O 0.017454 0.209497 0.123644 -0.019 - 51 O 0.807957 0.790503 0.414147 -0.02 - 52 O 0.192043 0.482546 0.60619 -0.02 - 53 O 0.60619 0.192043 0.482546 -0.021 - 54 O 0.209497 0.123644 0.017454 -0.018 - 55 O 0.123644 0.60619 0.914147 -0.019 - 56 O 0.414147 0.10619 0.623644 -0.021 - 57 O 0.623644 0.414147 0.10619 -0.018 - 58 O 0.709497 0.692043 0.085853 -0.018 - 59 O 0.517454 0.39381 0.807957 -0.019 - 60 O 0.692043 0.10619 0.982546 -0.021 - 61 O 0.876356 0.982546 0.790503 -0.019 - 62 O 0.623644 0.709497 0.517454 -0.018 - 63 O 0.10619 0.623644 0.414147 -0.02 - 64 O 0.876356 0.39381 0.085853 -0.019 - 65 O 0.790503 0.876356 0.982546 -0.018 - 66 O 0.39381 0.807957 0.517454 -0.021 - 67 O 0.692043 0.085853 0.709497 -0.021 - 68 O 0.807957 0.517454 0.39381 -0.02 - 69 O 0.982546 0.790503 0.876356 -0.019 - 70 O 0.085853 0.709497 0.692043 -0.019 - 71 O 0.982546 0.692043 0.10619 -0.019 - 72 O 0.790503 0.414147 0.807957 -0.018 - 73 O 0.414147 0.807957 0.790503 -0.021 - 74 O 0.709497 0.517454 0.623644 -0.018 - 75 O 0.085853 0.876356 0.39381 -0.019 - 76 O 0.39381 0.085853 0.876356 -0.021 - 77 O 0.10619 0.982546 0.692043 -0.02 - 78 O 0.517454 0.623644 0.709497 -0.019 - 79 O 0.307957 0.914147 0.290503 -0.021","# generated using pymatgen -data_V2Zn3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.30937945 -_cell_length_b 10.30937945 -_cell_length_c 10.30937945 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural V2Zn3(SiO4)3 -_chemical_formula_sum 'V8 Zn12 Si12 O48' -_cell_volume 843.48173594 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - V V0 1 0.50000000 0.00000000 0.00000000 1 - V V1 1 0.50000000 0.50000000 0.00000000 1 - V V2 1 0.00000000 0.50000000 0.50000000 1 - V V3 1 0.00000000 0.00000000 0.50000000 1 - V V4 1 0.50000000 0.50000000 0.50000000 1 - V V5 1 0.00000000 0.50000000 0.00000000 1 - V V6 1 0.50000000 0.00000000 0.50000000 1 - V V7 1 0.00000000 0.00000000 0.00000000 1 - Zn Zn8 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn9 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn10 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn11 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn12 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn13 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn14 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn15 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn16 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn17 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn18 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58585300 0.89381000 0.37635600 1 - O O33 1 0.37635600 0.58585300 0.89381000 1 - O O34 1 0.29050300 0.30795700 0.91414700 1 - O O35 1 0.48254600 0.60619000 0.19204300 1 - O O36 1 0.30795700 0.89381000 0.01745400 1 - O O37 1 0.12364400 0.01745400 0.20949700 1 - O O38 1 0.37635600 0.29050300 0.48254600 1 - O O39 1 0.89381000 0.37635600 0.58585300 1 - O O40 1 0.19204300 0.20949700 0.58585300 1 - O O41 1 0.48254600 0.37635600 0.29050300 1 - O O42 1 0.89381000 0.01745400 0.30795700 1 - O O43 1 0.60619000 0.91414700 0.12364400 1 - O O44 1 0.91414700 0.12364400 0.60619000 1 - O O45 1 0.29050300 0.48254600 0.37635600 1 - O O46 1 0.58585300 0.19204300 0.20949700 1 - O O47 1 0.20949700 0.58585300 0.19204300 1 - O O48 1 0.01745400 0.30795700 0.89381000 1 - O O49 1 0.91414700 0.29050300 0.30795700 1 - O O50 1 0.01745400 0.20949700 0.12364400 1 - O O51 1 0.80795700 0.79050300 0.41414700 1 - O O52 1 0.19204300 0.48254600 0.60619000 1 - O O53 1 0.60619000 0.19204300 0.48254600 1 - O O54 1 0.20949700 0.12364400 0.01745400 1 - O O55 1 0.12364400 0.60619000 0.91414700 1 - O O56 1 0.41414700 0.10619000 0.62364400 1 - O O57 1 0.62364400 0.41414700 0.10619000 1 - O O58 1 0.70949700 0.69204300 0.08585300 1 - O O59 1 0.51745400 0.39381000 0.80795700 1 - O O60 1 0.69204300 0.10619000 0.98254600 1 - O O61 1 0.87635600 0.98254600 0.79050300 1 - O O62 1 0.62364400 0.70949700 0.51745400 1 - O O63 1 0.10619000 0.62364400 0.41414700 1 - O O64 1 0.87635600 0.39381000 0.08585300 1 - O O65 1 0.79050300 0.87635600 0.98254600 1 - O O66 1 0.39381000 0.80795700 0.51745400 1 - O O67 1 0.69204300 0.08585300 0.70949700 1 - O O68 1 0.80795700 0.51745400 0.39381000 1 - O O69 1 0.98254600 0.79050300 0.87635600 1 - O O70 1 0.08585300 0.70949700 0.69204300 1 - O O71 1 0.98254600 0.69204300 0.10619000 1 - O O72 1 0.79050300 0.41414700 0.80795700 1 - O O73 1 0.41414700 0.80795700 0.79050300 1 - O O74 1 0.70949700 0.51745400 0.62364400 1 - O O75 1 0.08585300 0.87635600 0.39381000 1 - O O76 1 0.39381000 0.08585300 0.87635600 1 - O O77 1 0.10619000 0.98254600 0.69204300 1 - O O78 1 0.51745400 0.62364400 0.70949700 1 - O O79 1 0.30795700 0.91414700 0.29050300 1 -" -Zn3Cr2(SiO4)3,mp-1253507,Ia-3d,[],0.1322353585000009,{'tags': []},"Full Formula (Zn12 Cr8 Si12 O48) -Reduced Formula: Zn3Cr2(SiO4)3 -abc : 10.237972 10.237972 10.237972 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 0.011 - 1 Zn 0.75 0.125 0.375 0.011 - 2 Zn 0.375 0.125 0.25 0.011 - 3 Zn 0.125 0.375 0.75 0.011 - 4 Zn 0.25 0.875 0.625 0.011 - 5 Zn 0.125 0.25 0.375 0.011 - 6 Zn 0.625 0.25 0.875 0.011 - 7 Zn 0.75 0.625 0.875 0.011 - 8 Zn 0.875 0.75 0.625 0.011 - 9 Zn 0.875 0.625 0.25 0.011 - 10 Zn 0.625 0.875 0.75 0.011 - 11 Zn 0.375 0.75 0.125 0.011 - 12 Cr 0.5 0 0 2.938 - 13 Cr 0.5 0.5 0 2.938 - 14 Cr 0 0.5 0.5 2.938 - 15 Cr 0 0 0.5 2.938 - 16 Cr 0.5 0.5 0.5 2.938 - 17 Cr 0 0.5 0 2.938 - 18 Cr 0.5 0 0.5 2.938 - 19 Cr 0 0 0 2.938 - 20 Si 0.125 0.75 0.875 0.006 - 21 Si 0.875 0.25 0.125 0.006 - 22 Si 0.75 0.375 0.625 0.006 - 23 Si 0.125 0.875 0.25 0.006 - 24 Si 0.25 0.125 0.875 0.006 - 25 Si 0.375 0.625 0.75 0.006 - 26 Si 0.375 0.25 0.625 0.006 - 27 Si 0.875 0.125 0.75 0.006 - 28 Si 0.625 0.375 0.25 0.006 - 29 Si 0.75 0.875 0.125 0.006 - 30 Si 0.25 0.625 0.375 0.006 - 31 Si 0.625 0.75 0.375 0.006 - 32 O 0.585085 0.89445 0.376573 -0.009 - 33 O 0.376573 0.585085 0.89445 -0.009 - 34 O 0.291489 0.309365 0.914915 -0.009 - 35 O 0.482124 0.60555 0.190635 -0.009 - 36 O 0.309365 0.89445 0.017876 -0.009 - 37 O 0.123427 0.017876 0.208511 -0.009 - 38 O 0.376573 0.291489 0.482124 -0.009 - 39 O 0.89445 0.376573 0.585085 -0.009 - 40 O 0.190635 0.208511 0.585085 -0.009 - 41 O 0.482124 0.376573 0.291489 -0.009 - 42 O 0.89445 0.017876 0.309365 -0.009 - 43 O 0.60555 0.914915 0.123427 -0.009 - 44 O 0.914915 0.123427 0.60555 -0.009 - 45 O 0.291489 0.482124 0.376573 -0.009 - 46 O 0.585085 0.190635 0.208511 -0.009 - 47 O 0.208511 0.585085 0.190635 -0.009 - 48 O 0.017876 0.309365 0.89445 -0.009 - 49 O 0.914915 0.291489 0.309365 -0.009 - 50 O 0.017876 0.208511 0.123427 -0.009 - 51 O 0.809365 0.791489 0.414915 -0.009 - 52 O 0.190635 0.482124 0.60555 -0.009 - 53 O 0.60555 0.190635 0.482124 -0.009 - 54 O 0.208511 0.123427 0.017876 -0.009 - 55 O 0.123427 0.60555 0.914915 -0.009 - 56 O 0.414915 0.10555 0.623427 -0.009 - 57 O 0.623427 0.414915 0.10555 -0.009 - 58 O 0.708511 0.690635 0.085085 -0.009 - 59 O 0.517876 0.39445 0.809365 -0.009 - 60 O 0.690635 0.10555 0.982124 -0.009 - 61 O 0.876573 0.982124 0.791489 -0.009 - 62 O 0.623427 0.708511 0.517876 -0.009 - 63 O 0.10555 0.623427 0.414915 -0.009 - 64 O 0.876573 0.39445 0.085085 -0.009 - 65 O 0.791489 0.876573 0.982124 -0.009 - 66 O 0.39445 0.809365 0.517876 -0.009 - 67 O 0.690635 0.085085 0.708511 -0.009 - 68 O 0.809365 0.517876 0.39445 -0.009 - 69 O 0.982124 0.791489 0.876573 -0.009 - 70 O 0.085085 0.708511 0.690635 -0.009 - 71 O 0.982124 0.690635 0.10555 -0.009 - 72 O 0.791489 0.414915 0.809365 -0.009 - 73 O 0.414915 0.809365 0.791489 -0.009 - 74 O 0.708511 0.517876 0.623427 -0.009 - 75 O 0.085085 0.876573 0.39445 -0.009 - 76 O 0.39445 0.085085 0.876573 -0.009 - 77 O 0.10555 0.982124 0.690635 -0.009 - 78 O 0.517876 0.623427 0.708511 -0.009 - 79 O 0.309365 0.914915 0.291489 -0.009","# generated using pymatgen -data_Zn3Cr2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.23797219 -_cell_length_b 10.23797219 -_cell_length_c 10.23797219 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Cr2(SiO4)3 -_chemical_formula_sum 'Zn12 Cr8 Si12 O48' -_cell_volume 826.07588787 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Cr Cr12 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr13 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr16 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr18 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58508500 0.89445000 0.37657300 1 - O O33 1 0.37657300 0.58508500 0.89445000 1 - O O34 1 0.29148900 0.30936500 0.91491500 1 - O O35 1 0.48212400 0.60555000 0.19063500 1 - O O36 1 0.30936500 0.89445000 0.01787600 1 - O O37 1 0.12342700 0.01787600 0.20851100 1 - O O38 1 0.37657300 0.29148900 0.48212400 1 - O O39 1 0.89445000 0.37657300 0.58508500 1 - O O40 1 0.19063500 0.20851100 0.58508500 1 - O O41 1 0.48212400 0.37657300 0.29148900 1 - O O42 1 0.89445000 0.01787600 0.30936500 1 - O O43 1 0.60555000 0.91491500 0.12342700 1 - O O44 1 0.91491500 0.12342700 0.60555000 1 - O O45 1 0.29148900 0.48212400 0.37657300 1 - O O46 1 0.58508500 0.19063500 0.20851100 1 - O O47 1 0.20851100 0.58508500 0.19063500 1 - O O48 1 0.01787600 0.30936500 0.89445000 1 - O O49 1 0.91491500 0.29148900 0.30936500 1 - O O50 1 0.01787600 0.20851100 0.12342700 1 - O O51 1 0.80936500 0.79148900 0.41491500 1 - O O52 1 0.19063500 0.48212400 0.60555000 1 - O O53 1 0.60555000 0.19063500 0.48212400 1 - O O54 1 0.20851100 0.12342700 0.01787600 1 - O O55 1 0.12342700 0.60555000 0.91491500 1 - O O56 1 0.41491500 0.10555000 0.62342700 1 - O O57 1 0.62342700 0.41491500 0.10555000 1 - O O58 1 0.70851100 0.69063500 0.08508500 1 - O O59 1 0.51787600 0.39445000 0.80936500 1 - O O60 1 0.69063500 0.10555000 0.98212400 1 - O O61 1 0.87657300 0.98212400 0.79148900 1 - O O62 1 0.62342700 0.70851100 0.51787600 1 - O O63 1 0.10555000 0.62342700 0.41491500 1 - O O64 1 0.87657300 0.39445000 0.08508500 1 - O O65 1 0.79148900 0.87657300 0.98212400 1 - O O66 1 0.39445000 0.80936500 0.51787600 1 - O O67 1 0.69063500 0.08508500 0.70851100 1 - O O68 1 0.80936500 0.51787600 0.39445000 1 - O O69 1 0.98212400 0.79148900 0.87657300 1 - O O70 1 0.08508500 0.70851100 0.69063500 1 - O O71 1 0.98212400 0.69063500 0.10555000 1 - O O72 1 0.79148900 0.41491500 0.80936500 1 - O O73 1 0.41491500 0.80936500 0.79148900 1 - O O74 1 0.70851100 0.51787600 0.62342700 1 - O O75 1 0.08508500 0.87657300 0.39445000 1 - O O76 1 0.39445000 0.08508500 0.87657300 1 - O O77 1 0.10555000 0.98212400 0.69063500 1 - O O78 1 0.51787600 0.62342700 0.70851100 1 - O O79 1 0.30936500 0.91491500 0.29148900 1 -" -Ti2Zn3(SiO4)3,mp-1254352,Ia-3d,[],0.21692253712500964,{'tags': []},"Full Formula (Ti8 Zn12 Si12 O48) -Reduced Formula: Ti2Zn3(SiO4)3 -abc : 10.363369 10.363369 10.363369 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ti 0.5 0 0 0.741 - 1 Ti 0.5 0.5 0 0.78 - 2 Ti 0 0.5 0.5 0.783 - 3 Ti 0 0 0.5 0.783 - 4 Ti 0.5 0.5 0.5 0.78 - 5 Ti 0 0.5 0 0.78 - 6 Ti 0.5 0 0.5 0.741 - 7 Ti 0 0 0 0.78 - 8 Zn 0.25 0.375 0.125 0.024 - 9 Zn 0.75 0.125 0.375 0.028 - 10 Zn 0.375 0.125 0.25 0.03 - 11 Zn 0.125 0.375 0.75 0.03 - 12 Zn 0.25 0.875 0.625 0.028 - 13 Zn 0.125 0.25 0.375 0.03 - 14 Zn 0.625 0.25 0.875 0.03 - 15 Zn 0.75 0.625 0.875 0.024 - 16 Zn 0.875 0.75 0.625 0.03 - 17 Zn 0.875 0.625 0.25 0.03 - 18 Zn 0.625 0.875 0.75 0.03 - 19 Zn 0.375 0.75 0.125 0.03 - 20 Si 0.125 0.75 0.875 0.006 - 21 Si 0.875 0.25 0.125 0.006 - 22 Si 0.75 0.375 0.625 0.007 - 23 Si 0.125 0.875 0.25 0.006 - 24 Si 0.25 0.125 0.875 0.007 - 25 Si 0.375 0.625 0.75 0.006 - 26 Si 0.375 0.25 0.625 0.006 - 27 Si 0.875 0.125 0.75 0.006 - 28 Si 0.625 0.375 0.25 0.006 - 29 Si 0.75 0.875 0.125 0.007 - 30 Si 0.25 0.625 0.375 0.007 - 31 Si 0.625 0.75 0.375 0.006 - 32 O 0.585156 0.892821 0.377369 -0.007 - 33 O 0.377369 0.585156 0.892821 -0.004 - 34 O 0.292213 0.307665 0.914844 -0.005 - 35 O 0.484548 0.607179 0.192335 -0.005 - 36 O 0.307665 0.892821 0.015452 -0.007 - 37 O 0.122631 0.015452 0.207787 -0.004 - 38 O 0.377369 0.292213 0.484548 -0.004 - 39 O 0.892821 0.377369 0.585156 -0.006 - 40 O 0.192335 0.207787 0.585156 -0.006 - 41 O 0.484548 0.377369 0.292213 -0.005 - 42 O 0.892821 0.015452 0.307665 -0.006 - 43 O 0.607179 0.914844 0.122631 -0.007 - 44 O 0.914844 0.122631 0.607179 -0.006 - 45 O 0.292213 0.484548 0.377369 -0.005 - 46 O 0.585156 0.192335 0.207787 -0.007 - 47 O 0.207787 0.585156 0.192335 -0.005 - 48 O 0.015452 0.307665 0.892821 -0.005 - 49 O 0.914844 0.292213 0.307665 -0.006 - 50 O 0.015452 0.207787 0.122631 -0.005 - 51 O 0.807665 0.792213 0.414844 -0.006 - 52 O 0.192335 0.484548 0.607179 -0.006 - 53 O 0.607179 0.192335 0.484548 -0.007 - 54 O 0.207787 0.122631 0.015452 -0.005 - 55 O 0.122631 0.607179 0.914844 -0.004 - 56 O 0.414844 0.107179 0.622631 -0.007 - 57 O 0.622631 0.414844 0.107179 -0.004 - 58 O 0.707787 0.692335 0.085156 -0.005 - 59 O 0.515452 0.392821 0.807665 -0.005 - 60 O 0.692335 0.107179 0.984548 -0.007 - 61 O 0.877369 0.984548 0.792213 -0.004 - 62 O 0.622631 0.707787 0.515452 -0.004 - 63 O 0.107179 0.622631 0.414844 -0.006 - 64 O 0.877369 0.392821 0.085156 -0.004 - 65 O 0.792213 0.877369 0.984548 -0.005 - 66 O 0.392821 0.807665 0.515452 -0.007 - 67 O 0.692335 0.085156 0.707787 -0.007 - 68 O 0.807665 0.515452 0.392821 -0.006 - 69 O 0.984548 0.792213 0.877369 -0.005 - 70 O 0.085156 0.707787 0.692335 -0.006 - 71 O 0.984548 0.692335 0.107179 -0.005 - 72 O 0.792213 0.414844 0.807665 -0.005 - 73 O 0.414844 0.807665 0.792213 -0.007 - 74 O 0.707787 0.515452 0.622631 -0.005 - 75 O 0.085156 0.877369 0.392821 -0.006 - 76 O 0.392821 0.085156 0.877369 -0.007 - 77 O 0.107179 0.984548 0.692335 -0.006 - 78 O 0.515452 0.622631 0.707787 -0.005 - 79 O 0.307665 0.914844 0.292213 -0.007","# generated using pymatgen -data_Ti2Zn3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.36336920 -_cell_length_b 10.36336920 -_cell_length_c 10.36336920 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ti2Zn3(SiO4)3 -_chemical_formula_sum 'Ti8 Zn12 Si12 O48' -_cell_volume 856.80308386 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ti Ti0 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti1 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti2 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti3 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti4 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti5 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti6 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti7 1 0.00000000 0.00000000 0.00000000 1 - Zn Zn8 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn9 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn10 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn11 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn12 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn13 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn14 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn15 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn16 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn17 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn18 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58515600 0.89282100 0.37736900 1 - O O33 1 0.37736900 0.58515600 0.89282100 1 - O O34 1 0.29221300 0.30766500 0.91484400 1 - O O35 1 0.48454800 0.60717900 0.19233500 1 - O O36 1 0.30766500 0.89282100 0.01545200 1 - O O37 1 0.12263100 0.01545200 0.20778700 1 - O O38 1 0.37736900 0.29221300 0.48454800 1 - O O39 1 0.89282100 0.37736900 0.58515600 1 - O O40 1 0.19233500 0.20778700 0.58515600 1 - O O41 1 0.48454800 0.37736900 0.29221300 1 - O O42 1 0.89282100 0.01545200 0.30766500 1 - O O43 1 0.60717900 0.91484400 0.12263100 1 - O O44 1 0.91484400 0.12263100 0.60717900 1 - O O45 1 0.29221300 0.48454800 0.37736900 1 - O O46 1 0.58515600 0.19233500 0.20778700 1 - O O47 1 0.20778700 0.58515600 0.19233500 1 - O O48 1 0.01545200 0.30766500 0.89282100 1 - O O49 1 0.91484400 0.29221300 0.30766500 1 - O O50 1 0.01545200 0.20778700 0.12263100 1 - O O51 1 0.80766500 0.79221300 0.41484400 1 - O O52 1 0.19233500 0.48454800 0.60717900 1 - O O53 1 0.60717900 0.19233500 0.48454800 1 - O O54 1 0.20778700 0.12263100 0.01545200 1 - O O55 1 0.12263100 0.60717900 0.91484400 1 - O O56 1 0.41484400 0.10717900 0.62263100 1 - O O57 1 0.62263100 0.41484400 0.10717900 1 - O O58 1 0.70778700 0.69233500 0.08515600 1 - O O59 1 0.51545200 0.39282100 0.80766500 1 - O O60 1 0.69233500 0.10717900 0.98454800 1 - O O61 1 0.87736900 0.98454800 0.79221300 1 - O O62 1 0.62263100 0.70778700 0.51545200 1 - O O63 1 0.10717900 0.62263100 0.41484400 1 - O O64 1 0.87736900 0.39282100 0.08515600 1 - O O65 1 0.79221300 0.87736900 0.98454800 1 - O O66 1 0.39282100 0.80766500 0.51545200 1 - O O67 1 0.69233500 0.08515600 0.70778700 1 - O O68 1 0.80766500 0.51545200 0.39282100 1 - O O69 1 0.98454800 0.79221300 0.87736900 1 - O O70 1 0.08515600 0.70778700 0.69233500 1 - O O71 1 0.98454800 0.69233500 0.10717900 1 - O O72 1 0.79221300 0.41484400 0.80766500 1 - O O73 1 0.41484400 0.80766500 0.79221300 1 - O O74 1 0.70778700 0.51545200 0.62263100 1 - O O75 1 0.08515600 0.87736900 0.39282100 1 - O O76 1 0.39282100 0.08515600 0.87736900 1 - O O77 1 0.10717900 0.98454800 0.69233500 1 - O O78 1 0.51545200 0.62263100 0.70778700 1 - O O79 1 0.30766500 0.91484400 0.29221300 1 -" -Zn3Si3(NiO6)2,mp-1257835,Ia-3d,[],0.16572840449999582,{'tags': []},"Full Formula (Zn12 Si12 Ni8 O48) -Reduced Formula: Zn3Si3(NiO6)2 -abc : 10.161842 10.161842 10.161842 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 -0.005 - 1 Zn 0.75 0.125 0.375 -0.005 - 2 Zn 0.375 0.125 0.25 -0.005 - 3 Zn 0.125 0.375 0.75 -0.005 - 4 Zn 0.25 0.875 0.625 -0.005 - 5 Zn 0.125 0.25 0.375 -0.005 - 6 Zn 0.625 0.25 0.875 -0.005 - 7 Zn 0.75 0.625 0.875 -0.005 - 8 Zn 0.875 0.75 0.625 -0.005 - 9 Zn 0.875 0.625 0.25 -0.005 - 10 Zn 0.625 0.875 0.75 -0.005 - 11 Zn 0.375 0.75 0.125 -0.005 - 12 Si 0.125 0.75 0.875 0.013 - 13 Si 0.875 0.25 0.125 0.013 - 14 Si 0.75 0.375 0.625 0.013 - 15 Si 0.125 0.875 0.25 0.013 - 16 Si 0.25 0.125 0.875 0.013 - 17 Si 0.375 0.625 0.75 0.013 - 18 Si 0.375 0.25 0.625 0.013 - 19 Si 0.875 0.125 0.75 0.013 - 20 Si 0.625 0.375 0.25 0.013 - 21 Si 0.75 0.875 0.125 0.013 - 22 Si 0.25 0.625 0.375 0.013 - 23 Si 0.625 0.75 0.375 0.013 - 24 Ni 0.5 0 0 1.54 - 25 Ni 0.5 0.5 0 1.54 - 26 Ni 0 0.5 0.5 1.54 - 27 Ni 0 0 0.5 1.54 - 28 Ni 0.5 0.5 0.5 1.54 - 29 Ni 0 0.5 0 1.54 - 30 Ni 0.5 0 0.5 1.54 - 31 Ni 0 0 0 1.54 - 32 O 0.584887 0.895125 0.375134 -0.081 - 33 O 0.375134 0.584887 0.895125 -0.081 - 34 O 0.290247 0.310238 0.915113 -0.081 - 35 O 0.480009 0.604875 0.189762 -0.081 - 36 O 0.310238 0.895125 0.019991 -0.081 - 37 O 0.124866 0.019991 0.209753 -0.081 - 38 O 0.375134 0.290247 0.480009 -0.081 - 39 O 0.895125 0.375134 0.584887 -0.081 - 40 O 0.189762 0.209753 0.584887 -0.081 - 41 O 0.480009 0.375134 0.290247 -0.081 - 42 O 0.895125 0.019991 0.310238 -0.081 - 43 O 0.604875 0.915113 0.124866 -0.081 - 44 O 0.915113 0.124866 0.604875 -0.081 - 45 O 0.290247 0.480009 0.375134 -0.081 - 46 O 0.584887 0.189762 0.209753 -0.081 - 47 O 0.209753 0.584887 0.189762 -0.081 - 48 O 0.019991 0.310238 0.895125 -0.081 - 49 O 0.915113 0.290247 0.310238 -0.081 - 50 O 0.019991 0.209753 0.124866 -0.081 - 51 O 0.810238 0.790247 0.415113 -0.081 - 52 O 0.189762 0.480009 0.604875 -0.081 - 53 O 0.604875 0.189762 0.480009 -0.081 - 54 O 0.209753 0.124866 0.019991 -0.081 - 55 O 0.124866 0.604875 0.915113 -0.081 - 56 O 0.415113 0.104875 0.624866 -0.081 - 57 O 0.624866 0.415113 0.104875 -0.081 - 58 O 0.709753 0.689762 0.084887 -0.081 - 59 O 0.519991 0.395125 0.810238 -0.081 - 60 O 0.689762 0.104875 0.980009 -0.081 - 61 O 0.875134 0.980009 0.790247 -0.081 - 62 O 0.624866 0.709753 0.519991 -0.081 - 63 O 0.104875 0.624866 0.415113 -0.081 - 64 O 0.875134 0.395125 0.084887 -0.081 - 65 O 0.790247 0.875134 0.980009 -0.081 - 66 O 0.395125 0.810238 0.519991 -0.081 - 67 O 0.689762 0.084887 0.709753 -0.081 - 68 O 0.810238 0.519991 0.395125 -0.081 - 69 O 0.980009 0.790247 0.875134 -0.081 - 70 O 0.084887 0.709753 0.689762 -0.081 - 71 O 0.980009 0.689762 0.104875 -0.081 - 72 O 0.790247 0.415113 0.810238 -0.081 - 73 O 0.415113 0.810238 0.790247 -0.081 - 74 O 0.709753 0.519991 0.624866 -0.081 - 75 O 0.084887 0.875134 0.395125 -0.081 - 76 O 0.395125 0.084887 0.875134 -0.081 - 77 O 0.104875 0.980009 0.689762 -0.081 - 78 O 0.519991 0.624866 0.709753 -0.081 - 79 O 0.310238 0.915113 0.290247 -0.081","# generated using pymatgen -data_Zn3Si3(NiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.16184163 -_cell_length_b 10.16184163 -_cell_length_c 10.16184163 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Si3(NiO6)2 -_chemical_formula_sum 'Zn12 Si12 Ni8 O48' -_cell_volume 807.78424019 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Ni Ni24 1 0.50000000 0.00000000 0.00000000 1 - Ni Ni25 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni26 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni27 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni28 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni29 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni30 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.58488700 0.89512500 0.37513400 1 - O O33 1 0.37513400 0.58488700 0.89512500 1 - O O34 1 0.29024700 0.31023800 0.91511300 1 - O O35 1 0.48000900 0.60487500 0.18976200 1 - O O36 1 0.31023800 0.89512500 0.01999100 1 - O O37 1 0.12486600 0.01999100 0.20975300 1 - O O38 1 0.37513400 0.29024700 0.48000900 1 - O O39 1 0.89512500 0.37513400 0.58488700 1 - O O40 1 0.18976200 0.20975300 0.58488700 1 - O O41 1 0.48000900 0.37513400 0.29024700 1 - O O42 1 0.89512500 0.01999100 0.31023800 1 - O O43 1 0.60487500 0.91511300 0.12486600 1 - O O44 1 0.91511300 0.12486600 0.60487500 1 - O O45 1 0.29024700 0.48000900 0.37513400 1 - O O46 1 0.58488700 0.18976200 0.20975300 1 - O O47 1 0.20975300 0.58488700 0.18976200 1 - O O48 1 0.01999100 0.31023800 0.89512500 1 - O O49 1 0.91511300 0.29024700 0.31023800 1 - O O50 1 0.01999100 0.20975300 0.12486600 1 - O O51 1 0.81023800 0.79024700 0.41511300 1 - O O52 1 0.18976200 0.48000900 0.60487500 1 - O O53 1 0.60487500 0.18976200 0.48000900 1 - O O54 1 0.20975300 0.12486600 0.01999100 1 - O O55 1 0.12486600 0.60487500 0.91511300 1 - O O56 1 0.41511300 0.10487500 0.62486600 1 - O O57 1 0.62486600 0.41511300 0.10487500 1 - O O58 1 0.70975300 0.68976200 0.08488700 1 - O O59 1 0.51999100 0.39512500 0.81023800 1 - O O60 1 0.68976200 0.10487500 0.98000900 1 - O O61 1 0.87513400 0.98000900 0.79024700 1 - O O62 1 0.62486600 0.70975300 0.51999100 1 - O O63 1 0.10487500 0.62486600 0.41511300 1 - O O64 1 0.87513400 0.39512500 0.08488700 1 - O O65 1 0.79024700 0.87513400 0.98000900 1 - O O66 1 0.39512500 0.81023800 0.51999100 1 - O O67 1 0.68976200 0.08488700 0.70975300 1 - O O68 1 0.81023800 0.51999100 0.39512500 1 - O O69 1 0.98000900 0.79024700 0.87513400 1 - O O70 1 0.08488700 0.70975300 0.68976200 1 - O O71 1 0.98000900 0.68976200 0.10487500 1 - O O72 1 0.79024700 0.41511300 0.81023800 1 - O O73 1 0.41511300 0.81023800 0.79024700 1 - O O74 1 0.70975300 0.51999100 0.62486600 1 - O O75 1 0.08488700 0.87513400 0.39512500 1 - O O76 1 0.39512500 0.08488700 0.87513400 1 - O O77 1 0.10487500 0.98000900 0.68976200 1 - O O78 1 0.51999100 0.62486600 0.70975300 1 - O O79 1 0.31023800 0.91511300 0.29024700 1 -" -Mg3Mn2(SiO4)3,mp-1258129,I4_1/acd,[],0.08597777114582694,{'tags': []},"Full Formula (Mg12 Mn8 Si12 O48) -Reduced Formula: Mg3Mn2(SiO4)3 -abc : 10.234578 10.234579 10.234577 -angles: 106.323327 111.067726 111.067732 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.377628 0.75 0.127628 0.003 - 1 Mg 0.122372 0.25 0.372372 0.003 - 2 Mg 0.377628 0.127628 0.25 0.003 - 3 Mg 0.122372 0.372372 0.75 0.003 - 4 Mg 0.877628 0.75 0.627628 0.003 - 5 Mg 0.75 0.125 0.375 0.001 - 6 Mg 0.75 0.625 0.875 0.001 - 7 Mg 0.622372 0.25 0.872372 0.003 - 8 Mg 0.25 0.875 0.625 0.001 - 9 Mg 0.877628 0.627628 0.25 0.003 - 10 Mg 0.622372 0.872372 0.75 0.003 - 11 Mg 0.25 0.375 0.125 0.001 - 12 Mn 0 0 0 3.853 - 13 Mn 0 0.5 0 3.853 - 14 Mn 0 0 0.5 3.853 - 15 Mn 0 0.5 0.5 3.853 - 16 Mn 0.5 0 0.5 3.853 - 17 Mn 0.5 0.5 0 3.853 - 18 Mn 0.5 0.5 0.5 3.853 - 19 Mn 0.5 0 0 3.853 - 20 Si 0.25 0.125 0.875 0.009 - 21 Si 0.75 0.875 0.125 0.009 - 22 Si 0.377086 0.25 0.627086 0.011 - 23 Si 0.622914 0.372914 0.25 0.011 - 24 Si 0.122914 0.75 0.872914 0.011 - 25 Si 0.877086 0.127086 0.75 0.011 - 26 Si 0.75 0.375 0.625 0.009 - 27 Si 0.377086 0.627086 0.75 0.011 - 28 Si 0.122914 0.872914 0.25 0.011 - 29 Si 0.877086 0.25 0.127086 0.011 - 30 Si 0.622914 0.75 0.372914 0.011 - 31 Si 0.25 0.625 0.375 0.009 - 32 O 0.293122 0.485665 0.384186 -0.017 - 33 O 0.028435 0.30404 0.896492 0.04 - 34 O 0.126156 0.605679 0.917091 -0.019 - 35 O 0.206878 0.591063 0.192543 -0.017 - 36 O 0.206878 0.115814 0.014335 -0.017 - 37 O 0.592452 0.19596 0.224396 0.04 - 38 O 0.601479 0.192543 0.485665 -0.017 - 39 O 0.188587 0.209064 0.582909 -0.019 - 40 O 0.898521 0.384186 0.591063 -0.017 - 41 O 0.311413 0.917091 0.290936 -0.019 - 42 O 0.907548 0.275604 0.30404 0.04 - 43 O 0.028435 0.224396 0.131943 0.04 - 44 O 0.188587 0.479523 0.605679 -0.019 - 45 O 0.592452 0.896492 0.368057 0.04 - 46 O 0.126156 0.020477 0.209064 -0.019 - 47 O 0.471565 0.603508 0.19596 0.04 - 48 O 0.373844 0.582909 0.894321 -0.019 - 49 O 0.898521 0.014335 0.307457 -0.017 - 50 O 0.601479 0.908937 0.115814 -0.017 - 51 O 0.101479 0.615814 0.408937 -0.017 - 52 O 0.907548 0.131943 0.603508 0.04 - 53 O 0.373844 0.290936 0.479523 -0.019 - 54 O 0.311413 0.894321 0.020477 -0.019 - 55 O 0.293122 0.307457 0.908937 -0.017 - 56 O 0.706878 0.514335 0.615814 -0.017 - 57 O 0.971565 0.69596 0.103508 0.04 - 58 O 0.873844 0.394321 0.082909 -0.019 - 59 O 0.793122 0.408937 0.807457 -0.017 - 60 O 0.793122 0.884186 0.985665 -0.017 - 61 O 0.407548 0.80404 0.775604 0.04 - 62 O 0.398521 0.807457 0.514335 -0.017 - 63 O 0.811413 0.790936 0.417091 -0.019 - 64 O 0.706878 0.692543 0.091063 -0.017 - 65 O 0.688587 0.105679 0.979523 -0.019 - 66 O 0.626156 0.709064 0.520477 -0.019 - 67 O 0.528435 0.631943 0.724396 0.04 - 68 O 0.092452 0.868057 0.396492 0.04 - 69 O 0.398521 0.091063 0.884186 -0.017 - 70 O 0.101479 0.985665 0.692543 -0.017 - 71 O 0.626156 0.417091 0.105679 -0.019 - 72 O 0.528435 0.396492 0.80404 0.04 - 73 O 0.873844 0.979523 0.790936 -0.019 - 74 O 0.407548 0.103508 0.631943 0.04 - 75 O 0.811413 0.520477 0.394321 -0.019 - 76 O 0.971565 0.775604 0.868057 0.04 - 77 O 0.092452 0.724396 0.69596 0.04 - 78 O 0.688587 0.082909 0.709064 -0.019 - 79 O 0.471565 0.368057 0.275604 0.04","# generated using pymatgen -data_Mg3Mn2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.23457813 -_cell_length_b 10.23457850 -_cell_length_c 10.23457742 -_cell_angle_alpha 106.32332702 -_cell_angle_beta 111.06772585 -_cell_angle_gamma 111.06773174 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Mn2(SiO4)3 -_chemical_formula_sum 'Mg12 Mn8 Si12 O48' -_cell_volume 823.39935804 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.37762800 0.75000000 0.12762800 1 - Mg Mg1 1 0.12237200 0.25000000 0.37237200 1 - Mg Mg2 1 0.37762800 0.12762800 0.25000000 1 - Mg Mg3 1 0.12237200 0.37237200 0.75000000 1 - Mg Mg4 1 0.87762800 0.75000000 0.62762800 1 - Mg Mg5 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg6 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg7 1 0.62237200 0.25000000 0.87237200 1 - Mg Mg8 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg9 1 0.87762800 0.62762800 0.25000000 1 - Mg Mg10 1 0.62237200 0.87237200 0.75000000 1 - Mg Mg11 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn12 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn13 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn14 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn15 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn16 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn17 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn18 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn19 1 0.50000000 0.00000000 0.00000000 1 - Si Si20 1 0.25000000 0.12500000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.37708600 0.25000000 0.62708600 1 - Si Si23 1 0.62291400 0.37291400 0.25000000 1 - Si Si24 1 0.12291400 0.75000000 0.87291400 1 - Si Si25 1 0.87708600 0.12708600 0.75000000 1 - Si Si26 1 0.75000000 0.37500000 0.62500000 1 - Si Si27 1 0.37708600 0.62708600 0.75000000 1 - Si Si28 1 0.12291400 0.87291400 0.25000000 1 - Si Si29 1 0.87708600 0.25000000 0.12708600 1 - Si Si30 1 0.62291400 0.75000000 0.37291400 1 - Si Si31 1 0.25000000 0.62500000 0.37500000 1 - O O32 1 0.29312200 0.48566500 0.38418600 1 - O O33 1 0.02843500 0.30404000 0.89649200 1 - O O34 1 0.12615600 0.60567900 0.91709100 1 - O O35 1 0.20687800 0.59106300 0.19254300 1 - O O36 1 0.20687800 0.11581400 0.01433500 1 - O O37 1 0.59245200 0.19596000 0.22439600 1 - O O38 1 0.60147900 0.19254300 0.48566500 1 - O O39 1 0.18858700 0.20906400 0.58290900 1 - O O40 1 0.89852100 0.38418600 0.59106300 1 - O O41 1 0.31141300 0.91709100 0.29093600 1 - O O42 1 0.90754800 0.27560400 0.30404000 1 - O O43 1 0.02843500 0.22439600 0.13194300 1 - O O44 1 0.18858700 0.47952300 0.60567900 1 - O O45 1 0.59245200 0.89649200 0.36805700 1 - O O46 1 0.12615600 0.02047700 0.20906400 1 - O O47 1 0.47156500 0.60350800 0.19596000 1 - O O48 1 0.37384400 0.58290900 0.89432100 1 - O O49 1 0.89852100 0.01433500 0.30745700 1 - O O50 1 0.60147900 0.90893700 0.11581400 1 - O O51 1 0.10147900 0.61581400 0.40893700 1 - O O52 1 0.90754800 0.13194300 0.60350800 1 - O O53 1 0.37384400 0.29093600 0.47952300 1 - O O54 1 0.31141300 0.89432100 0.02047700 1 - O O55 1 0.29312200 0.30745700 0.90893700 1 - O O56 1 0.70687800 0.51433500 0.61581400 1 - O O57 1 0.97156500 0.69596000 0.10350800 1 - O O58 1 0.87384400 0.39432100 0.08290900 1 - O O59 1 0.79312200 0.40893700 0.80745700 1 - O O60 1 0.79312200 0.88418600 0.98566500 1 - O O61 1 0.40754800 0.80404000 0.77560400 1 - O O62 1 0.39852100 0.80745700 0.51433500 1 - O O63 1 0.81141300 0.79093600 0.41709100 1 - O O64 1 0.70687800 0.69254300 0.09106300 1 - O O65 1 0.68858700 0.10567900 0.97952300 1 - O O66 1 0.62615600 0.70906400 0.52047700 1 - O O67 1 0.52843500 0.63194300 0.72439600 1 - O O68 1 0.09245200 0.86805700 0.39649200 1 - O O69 1 0.39852100 0.09106300 0.88418600 1 - O O70 1 0.10147900 0.98566500 0.69254300 1 - O O71 1 0.62615600 0.41709100 0.10567900 1 - O O72 1 0.52843500 0.39649200 0.80404000 1 - O O73 1 0.87384400 0.97952300 0.79093600 1 - O O74 1 0.40754800 0.10350800 0.63194300 1 - O O75 1 0.81141300 0.52047700 0.39432100 1 - O O76 1 0.97156500 0.77560400 0.86805700 1 - O O77 1 0.09245200 0.72439600 0.69596000 1 - O O78 1 0.68858700 0.08290900 0.70906400 1 - O O79 1 0.47156500 0.36805700 0.27560400 1 -" -Zn3Fe2(SiO4)3,mp-1258162,Ia-3d,[],0.12975292437501373,{'tags': []},"Full Formula (Zn12 Fe8 Si12 O48) -Reduced Formula: Zn3Fe2(SiO4)3 -abc : 10.269270 10.269270 10.269270 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 0.006 - 1 Zn 0.75 0.125 0.375 0.006 - 2 Zn 0.375 0.125 0.25 0.006 - 3 Zn 0.125 0.375 0.75 0.006 - 4 Zn 0.25 0.875 0.625 0.006 - 5 Zn 0.125 0.25 0.375 0.006 - 6 Zn 0.625 0.25 0.875 0.006 - 7 Zn 0.75 0.625 0.875 0.006 - 8 Zn 0.875 0.75 0.625 0.006 - 9 Zn 0.875 0.625 0.25 0.006 - 10 Zn 0.625 0.875 0.75 0.006 - 11 Zn 0.375 0.75 0.125 0.006 - 12 Fe 0.5 0 0 4.387 - 13 Fe 0.5 0.5 0 4.387 - 14 Fe 0 0.5 0.5 4.387 - 15 Fe 0 0 0.5 4.387 - 16 Fe 0.5 0.5 0.5 4.387 - 17 Fe 0 0.5 0 4.387 - 18 Fe 0.5 0 0.5 4.387 - 19 Fe 0 0 0 4.387 - 20 Si 0.125 0.75 0.875 0.014 - 21 Si 0.875 0.25 0.125 0.014 - 22 Si 0.75 0.375 0.625 0.014 - 23 Si 0.125 0.875 0.25 0.014 - 24 Si 0.25 0.125 0.875 0.014 - 25 Si 0.375 0.625 0.75 0.014 - 26 Si 0.375 0.25 0.625 0.014 - 27 Si 0.875 0.125 0.75 0.014 - 28 Si 0.625 0.375 0.25 0.014 - 29 Si 0.75 0.875 0.125 0.014 - 30 Si 0.25 0.625 0.375 0.014 - 31 Si 0.625 0.75 0.375 0.014 - 32 O 0.586613 0.894973 0.376245 0.078 - 33 O 0.376245 0.586613 0.894973 0.078 - 34 O 0.289632 0.30836 0.913387 0.078 - 35 O 0.481272 0.605027 0.19164 0.078 - 36 O 0.30836 0.894973 0.018728 0.078 - 37 O 0.123755 0.018728 0.210368 0.078 - 38 O 0.376245 0.289632 0.481272 0.078 - 39 O 0.894973 0.376245 0.586613 0.078 - 40 O 0.19164 0.210368 0.586613 0.078 - 41 O 0.481272 0.376245 0.289632 0.078 - 42 O 0.894973 0.018728 0.30836 0.078 - 43 O 0.605027 0.913387 0.123755 0.078 - 44 O 0.913387 0.123755 0.605027 0.078 - 45 O 0.289632 0.481272 0.376245 0.078 - 46 O 0.586613 0.19164 0.210368 0.078 - 47 O 0.210368 0.586613 0.19164 0.078 - 48 O 0.018728 0.30836 0.894973 0.078 - 49 O 0.913387 0.289632 0.30836 0.078 - 50 O 0.018728 0.210368 0.123755 0.078 - 51 O 0.80836 0.789632 0.413387 0.078 - 52 O 0.19164 0.481272 0.605027 0.078 - 53 O 0.605027 0.19164 0.481272 0.078 - 54 O 0.210368 0.123755 0.018728 0.078 - 55 O 0.123755 0.605027 0.913387 0.078 - 56 O 0.413387 0.105027 0.623755 0.078 - 57 O 0.623755 0.413387 0.105027 0.078 - 58 O 0.710368 0.69164 0.086613 0.078 - 59 O 0.518728 0.394973 0.80836 0.078 - 60 O 0.69164 0.105027 0.981272 0.078 - 61 O 0.876245 0.981272 0.789632 0.078 - 62 O 0.623755 0.710368 0.518728 0.078 - 63 O 0.105027 0.623755 0.413387 0.078 - 64 O 0.876245 0.394973 0.086613 0.078 - 65 O 0.789632 0.876245 0.981272 0.078 - 66 O 0.394973 0.80836 0.518728 0.078 - 67 O 0.69164 0.086613 0.710368 0.078 - 68 O 0.80836 0.518728 0.394973 0.078 - 69 O 0.981272 0.789632 0.876245 0.078 - 70 O 0.086613 0.710368 0.69164 0.078 - 71 O 0.981272 0.69164 0.105027 0.078 - 72 O 0.789632 0.413387 0.80836 0.078 - 73 O 0.413387 0.80836 0.789632 0.078 - 74 O 0.710368 0.518728 0.623755 0.078 - 75 O 0.086613 0.876245 0.394973 0.078 - 76 O 0.394973 0.086613 0.876245 0.078 - 77 O 0.105027 0.981272 0.69164 0.078 - 78 O 0.518728 0.623755 0.710368 0.078 - 79 O 0.30836 0.913387 0.289632 0.078","# generated using pymatgen -data_Zn3Fe2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.26927035 -_cell_length_b 10.26927035 -_cell_length_c 10.26927035 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Fe2(SiO4)3 -_chemical_formula_sum 'Zn12 Fe8 Si12 O48' -_cell_volume 833.67517800 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe12 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58661300 0.89497300 0.37624500 1 - O O33 1 0.37624500 0.58661300 0.89497300 1 - O O34 1 0.28963200 0.30836000 0.91338700 1 - O O35 1 0.48127200 0.60502700 0.19164000 1 - O O36 1 0.30836000 0.89497300 0.01872800 1 - O O37 1 0.12375500 0.01872800 0.21036800 1 - O O38 1 0.37624500 0.28963200 0.48127200 1 - O O39 1 0.89497300 0.37624500 0.58661300 1 - O O40 1 0.19164000 0.21036800 0.58661300 1 - O O41 1 0.48127200 0.37624500 0.28963200 1 - O O42 1 0.89497300 0.01872800 0.30836000 1 - O O43 1 0.60502700 0.91338700 0.12375500 1 - O O44 1 0.91338700 0.12375500 0.60502700 1 - O O45 1 0.28963200 0.48127200 0.37624500 1 - O O46 1 0.58661300 0.19164000 0.21036800 1 - O O47 1 0.21036800 0.58661300 0.19164000 1 - O O48 1 0.01872800 0.30836000 0.89497300 1 - O O49 1 0.91338700 0.28963200 0.30836000 1 - O O50 1 0.01872800 0.21036800 0.12375500 1 - O O51 1 0.80836000 0.78963200 0.41338700 1 - O O52 1 0.19164000 0.48127200 0.60502700 1 - O O53 1 0.60502700 0.19164000 0.48127200 1 - O O54 1 0.21036800 0.12375500 0.01872800 1 - O O55 1 0.12375500 0.60502700 0.91338700 1 - O O56 1 0.41338700 0.10502700 0.62375500 1 - O O57 1 0.62375500 0.41338700 0.10502700 1 - O O58 1 0.71036800 0.69164000 0.08661300 1 - O O59 1 0.51872800 0.39497300 0.80836000 1 - O O60 1 0.69164000 0.10502700 0.98127200 1 - O O61 1 0.87624500 0.98127200 0.78963200 1 - O O62 1 0.62375500 0.71036800 0.51872800 1 - O O63 1 0.10502700 0.62375500 0.41338700 1 - O O64 1 0.87624500 0.39497300 0.08661300 1 - O O65 1 0.78963200 0.87624500 0.98127200 1 - O O66 1 0.39497300 0.80836000 0.51872800 1 - O O67 1 0.69164000 0.08661300 0.71036800 1 - O O68 1 0.80836000 0.51872800 0.39497300 1 - O O69 1 0.98127200 0.78963200 0.87624500 1 - O O70 1 0.08661300 0.71036800 0.69164000 1 - O O71 1 0.98127200 0.69164000 0.10502700 1 - O O72 1 0.78963200 0.41338700 0.80836000 1 - O O73 1 0.41338700 0.80836000 0.78963200 1 - O O74 1 0.71036800 0.51872800 0.62375500 1 - O O75 1 0.08661300 0.87624500 0.39497300 1 - O O76 1 0.39497300 0.08661300 0.87624500 1 - O O77 1 0.10502700 0.98127200 0.69164000 1 - O O78 1 0.51872800 0.62375500 0.71036800 1 - O O79 1 0.30836000 0.91338700 0.28963200 1 -" -Y2Cu3(SiO4)3,mp-1261874,Ia-3d,[],0.31707789079167537,{'tags': []},"Full Formula (Y8 Cu12 Si12 O48) -Reduced Formula: Y2Cu3(SiO4)3 -abc : 10.767102 10.767102 10.767102 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0.5 -0.001 - 1 Y 0 0 0 -0.001 - 2 Y 0.5 0 0 -0.001 - 3 Y 0 0.5 0 -0.001 - 4 Y 0.5 0.5 0 -0.001 - 5 Y 0 0.5 0.5 -0.001 - 6 Y 0.5 0 0.5 -0.001 - 7 Y 0.5 0.5 0.5 -0.001 - 8 Cu 0.875 0.625 0.25 0.526 - 9 Cu 0.625 0.25 0.875 0.526 - 10 Cu 0.875 0.75 0.625 0.526 - 11 Cu 0.75 0.625 0.875 0.513 - 12 Cu 0.25 0.875 0.625 0.492 - 13 Cu 0.625 0.875 0.75 0.526 - 14 Cu 0.125 0.375 0.75 0.526 - 15 Cu 0.375 0.75 0.125 0.526 - 16 Cu 0.125 0.25 0.375 0.526 - 17 Cu 0.25 0.375 0.125 0.513 - 18 Cu 0.75 0.125 0.375 0.492 - 19 Cu 0.375 0.125 0.25 0.526 - 20 Si 0.125 0.875 0.25 -0.006 - 21 Si 0.25 0.125 0.875 -0.006 - 22 Si 0.75 0.375 0.625 -0.006 - 23 Si 0.625 0.375 0.25 -0.006 - 24 Si 0.625 0.75 0.375 -0.006 - 25 Si 0.375 0.625 0.75 -0.006 - 26 Si 0.125 0.75 0.875 -0.006 - 27 Si 0.75 0.875 0.125 -0.006 - 28 Si 0.875 0.25 0.125 -0.006 - 29 Si 0.375 0.25 0.625 -0.006 - 30 Si 0.25 0.625 0.375 -0.006 - 31 Si 0.875 0.125 0.75 -0.006 - 32 O 0.480523 0.369814 0.276688 0.109 - 33 O 0.296165 0.889291 0.019477 0.112 - 34 O 0.610709 0.906874 0.130186 0.11 - 35 O 0.593126 0.203835 0.223312 0.112 - 36 O 0.130186 0.019477 0.223312 0.106 - 37 O 0.203835 0.223312 0.593126 0.112 - 38 O 0.203835 0.480523 0.610709 0.112 - 39 O 0.223312 0.593126 0.203835 0.105 - 40 O 0.369814 0.593126 0.889291 0.106 - 41 O 0.906874 0.276688 0.296165 0.112 - 42 O 0.276688 0.296165 0.906874 0.105 - 43 O 0.223312 0.130186 0.019477 0.105 - 44 O 0.480523 0.610709 0.203835 0.109 - 45 O 0.889291 0.369814 0.593126 0.11 - 46 O 0.019477 0.223312 0.130186 0.109 - 47 O 0.610709 0.203835 0.480523 0.11 - 48 O 0.593126 0.889291 0.369814 0.112 - 49 O 0.019477 0.296165 0.889291 0.109 - 50 O 0.906874 0.130186 0.610709 0.112 - 51 O 0.630186 0.406874 0.110709 0.106 - 52 O 0.369814 0.276688 0.480523 0.106 - 53 O 0.276688 0.480523 0.369814 0.105 - 54 O 0.889291 0.019477 0.296165 0.11 - 55 O 0.296165 0.906874 0.276688 0.112 - 56 O 0.519477 0.630186 0.723312 0.109 - 57 O 0.703835 0.110709 0.980523 0.112 - 58 O 0.389291 0.093126 0.869814 0.11 - 59 O 0.406874 0.796165 0.776688 0.112 - 60 O 0.869814 0.980523 0.776688 0.106 - 61 O 0.796165 0.776688 0.406874 0.112 - 62 O 0.796165 0.519477 0.389291 0.112 - 63 O 0.776688 0.406874 0.796165 0.105 - 64 O 0.703835 0.093126 0.723312 0.112 - 65 O 0.110709 0.980523 0.703835 0.11 - 66 O 0.723312 0.519477 0.630186 0.105 - 67 O 0.630186 0.723312 0.519477 0.106 - 68 O 0.869814 0.389291 0.093126 0.106 - 69 O 0.093126 0.869814 0.389291 0.112 - 70 O 0.980523 0.703835 0.110709 0.109 - 71 O 0.406874 0.110709 0.630186 0.112 - 72 O 0.389291 0.796165 0.519477 0.11 - 73 O 0.980523 0.776688 0.869814 0.109 - 74 O 0.110709 0.630186 0.406874 0.11 - 75 O 0.519477 0.389291 0.796165 0.109 - 76 O 0.776688 0.869814 0.980523 0.105 - 77 O 0.723312 0.703835 0.093126 0.105 - 78 O 0.093126 0.723312 0.703835 0.112 - 79 O 0.130186 0.610709 0.906874 0.106","# generated using pymatgen -data_Y2Cu3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.76710159 -_cell_length_b 10.76710159 -_cell_length_c 10.76710159 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Cu3(SiO4)3 -_chemical_formula_sum 'Y8 Cu12 Si12 O48' -_cell_volume 960.89191932 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.50000000 1 - Y Y1 1 0.00000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.00000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.00000000 1 - Y Y4 1 0.50000000 0.50000000 0.00000000 1 - Y Y5 1 0.00000000 0.50000000 0.50000000 1 - Y Y6 1 0.50000000 0.00000000 0.50000000 1 - Y Y7 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu8 1 0.87500000 0.62500000 0.25000000 1 - Cu Cu9 1 0.62500000 0.25000000 0.87500000 1 - Cu Cu10 1 0.87500000 0.75000000 0.62500000 1 - Cu Cu11 1 0.75000000 0.62500000 0.87500000 1 - Cu Cu12 1 0.25000000 0.87500000 0.62500000 1 - Cu Cu13 1 0.62500000 0.87500000 0.75000000 1 - Cu Cu14 1 0.12500000 0.37500000 0.75000000 1 - Cu Cu15 1 0.37500000 0.75000000 0.12500000 1 - Cu Cu16 1 0.12500000 0.25000000 0.37500000 1 - Cu Cu17 1 0.25000000 0.37500000 0.12500000 1 - Cu Cu18 1 0.75000000 0.12500000 0.37500000 1 - Cu Cu19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.25000000 0.12500000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.37500000 0.25000000 0.62500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.48052300 0.36981400 0.27668800 1 - O O33 1 0.29616500 0.88929100 0.01947700 1 - O O34 1 0.61070900 0.90687400 0.13018600 1 - O O35 1 0.59312600 0.20383500 0.22331200 1 - O O36 1 0.13018600 0.01947700 0.22331200 1 - O O37 1 0.20383500 0.22331200 0.59312600 1 - O O38 1 0.20383500 0.48052300 0.61070900 1 - O O39 1 0.22331200 0.59312600 0.20383500 1 - O O40 1 0.36981400 0.59312600 0.88929100 1 - O O41 1 0.90687400 0.27668800 0.29616500 1 - O O42 1 0.27668800 0.29616500 0.90687400 1 - O O43 1 0.22331200 0.13018600 0.01947700 1 - O O44 1 0.48052300 0.61070900 0.20383500 1 - O O45 1 0.88929100 0.36981400 0.59312600 1 - O O46 1 0.01947700 0.22331200 0.13018600 1 - O O47 1 0.61070900 0.20383500 0.48052300 1 - O O48 1 0.59312600 0.88929100 0.36981400 1 - O O49 1 0.01947700 0.29616500 0.88929100 1 - O O50 1 0.90687400 0.13018600 0.61070900 1 - O O51 1 0.63018600 0.40687400 0.11070900 1 - O O52 1 0.36981400 0.27668800 0.48052300 1 - O O53 1 0.27668800 0.48052300 0.36981400 1 - O O54 1 0.88929100 0.01947700 0.29616500 1 - O O55 1 0.29616500 0.90687400 0.27668800 1 - O O56 1 0.51947700 0.63018600 0.72331200 1 - O O57 1 0.70383500 0.11070900 0.98052300 1 - O O58 1 0.38929100 0.09312600 0.86981400 1 - O O59 1 0.40687400 0.79616500 0.77668800 1 - O O60 1 0.86981400 0.98052300 0.77668800 1 - O O61 1 0.79616500 0.77668800 0.40687400 1 - O O62 1 0.79616500 0.51947700 0.38929100 1 - O O63 1 0.77668800 0.40687400 0.79616500 1 - O O64 1 0.70383500 0.09312600 0.72331200 1 - O O65 1 0.11070900 0.98052300 0.70383500 1 - O O66 1 0.72331200 0.51947700 0.63018600 1 - O O67 1 0.63018600 0.72331200 0.51947700 1 - O O68 1 0.86981400 0.38929100 0.09312600 1 - O O69 1 0.09312600 0.86981400 0.38929100 1 - O O70 1 0.98052300 0.70383500 0.11070900 1 - O O71 1 0.40687400 0.11070900 0.63018600 1 - O O72 1 0.38929100 0.79616500 0.51947700 1 - O O73 1 0.98052300 0.77668800 0.86981400 1 - O O74 1 0.11070900 0.63018600 0.40687400 1 - O O75 1 0.51947700 0.38929100 0.79616500 1 - O O76 1 0.77668800 0.86981400 0.98052300 1 - O O77 1 0.72331200 0.70383500 0.09312600 1 - O O78 1 0.09312600 0.72331200 0.70383500 1 - O O79 1 0.13018600 0.61070900 0.90687400 1 -" -Mg3Ti2(SiO4)3,mp-1262556,Ia-3d,[],0.12167664825000113,{'tags': []},"Full Formula (Mg12 Ti8 Si12 O48) -Reduced Formula: Mg3Ti2(SiO4)3 -abc : 10.286279 10.286279 10.286279 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0.001 - 1 Mg 0.75 0.125 0.375 0.001 - 2 Mg 0.375 0.125 0.25 0.001 - 3 Mg 0.125 0.375 0.75 0.001 - 4 Mg 0.25 0.875 0.625 0.001 - 5 Mg 0.125 0.25 0.375 0.001 - 6 Mg 0.625 0.25 0.875 0.001 - 7 Mg 0.75 0.625 0.875 0.001 - 8 Mg 0.875 0.75 0.625 0.001 - 9 Mg 0.875 0.625 0.25 0.001 - 10 Mg 0.625 0.875 0.75 0.001 - 11 Mg 0.375 0.75 0.125 0.001 - 12 Ti 0.5 0 0 0.899 - 13 Ti 0.5 0.5 0 0.899 - 14 Ti 0 0.5 0.5 0.899 - 15 Ti 0 0 0.5 0.899 - 16 Ti 0.5 0.5 0.5 0.899 - 17 Ti 0 0.5 0 0.899 - 18 Ti 0.5 0 0.5 0.899 - 19 Ti 0 0 0 0.899 - 20 Si 0.125 0.75 0.875 0.012 - 21 Si 0.875 0.25 0.125 0.012 - 22 Si 0.75 0.375 0.625 0.012 - 23 Si 0.125 0.875 0.25 0.012 - 24 Si 0.25 0.125 0.875 0.012 - 25 Si 0.375 0.625 0.75 0.012 - 26 Si 0.375 0.25 0.625 0.012 - 27 Si 0.875 0.125 0.75 0.012 - 28 Si 0.625 0.375 0.25 0.012 - 29 Si 0.75 0.875 0.125 0.012 - 30 Si 0.25 0.625 0.375 0.012 - 31 Si 0.625 0.75 0.375 0.012 - 32 O 0.58919 0.895626 0.375509 -0.002 - 33 O 0.375509 0.58919 0.895626 -0.002 - 34 O 0.286319 0.306436 0.91081 -0.002 - 35 O 0.479883 0.604374 0.193564 -0.002 - 36 O 0.306436 0.895626 0.020117 -0.002 - 37 O 0.124491 0.020117 0.213681 -0.002 - 38 O 0.375509 0.286319 0.479883 -0.002 - 39 O 0.895626 0.375509 0.58919 -0.002 - 40 O 0.193564 0.213681 0.58919 -0.002 - 41 O 0.479883 0.375509 0.286319 -0.002 - 42 O 0.895626 0.020117 0.306436 -0.002 - 43 O 0.604374 0.91081 0.124491 -0.002 - 44 O 0.91081 0.124491 0.604374 -0.002 - 45 O 0.286319 0.479883 0.375509 -0.002 - 46 O 0.58919 0.193564 0.213681 -0.002 - 47 O 0.213681 0.58919 0.193564 -0.002 - 48 O 0.020117 0.306436 0.895626 -0.002 - 49 O 0.91081 0.286319 0.306436 -0.002 - 50 O 0.020117 0.213681 0.124491 -0.002 - 51 O 0.806436 0.786319 0.41081 -0.002 - 52 O 0.193564 0.479883 0.604374 -0.002 - 53 O 0.604374 0.193564 0.479883 -0.002 - 54 O 0.213681 0.124491 0.020117 -0.002 - 55 O 0.124491 0.604374 0.91081 -0.002 - 56 O 0.41081 0.104374 0.624491 -0.002 - 57 O 0.624491 0.41081 0.104374 -0.002 - 58 O 0.713681 0.693564 0.08919 -0.002 - 59 O 0.520117 0.395626 0.806436 -0.002 - 60 O 0.693564 0.104374 0.979883 -0.002 - 61 O 0.875509 0.979883 0.786319 -0.002 - 62 O 0.624491 0.713681 0.520117 -0.002 - 63 O 0.104374 0.624491 0.41081 -0.002 - 64 O 0.875509 0.395626 0.08919 -0.002 - 65 O 0.786319 0.875509 0.979883 -0.002 - 66 O 0.395626 0.806436 0.520117 -0.002 - 67 O 0.693564 0.08919 0.713681 -0.002 - 68 O 0.806436 0.520117 0.395626 -0.002 - 69 O 0.979883 0.786319 0.875509 -0.002 - 70 O 0.08919 0.713681 0.693564 -0.002 - 71 O 0.979883 0.693564 0.104374 -0.002 - 72 O 0.786319 0.41081 0.806436 -0.002 - 73 O 0.41081 0.806436 0.786319 -0.002 - 74 O 0.713681 0.520117 0.624491 -0.002 - 75 O 0.08919 0.875509 0.395626 -0.002 - 76 O 0.395626 0.08919 0.875509 -0.002 - 77 O 0.104374 0.979883 0.693564 -0.002 - 78 O 0.520117 0.624491 0.713681 -0.002 - 79 O 0.306436 0.91081 0.286319 -0.002","# generated using pymatgen -data_Mg3Ti2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.28627909 -_cell_length_b 10.28627909 -_cell_length_c 10.28627909 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ti2(SiO4)3 -_chemical_formula_sum 'Mg12 Ti8 Si12 O48' -_cell_volume 837.82442956 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Ti Ti12 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti13 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti14 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti15 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti16 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti17 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti18 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58919000 0.89562600 0.37550900 1 - O O33 1 0.37550900 0.58919000 0.89562600 1 - O O34 1 0.28631900 0.30643600 0.91081000 1 - O O35 1 0.47988300 0.60437400 0.19356400 1 - O O36 1 0.30643600 0.89562600 0.02011700 1 - O O37 1 0.12449100 0.02011700 0.21368100 1 - O O38 1 0.37550900 0.28631900 0.47988300 1 - O O39 1 0.89562600 0.37550900 0.58919000 1 - O O40 1 0.19356400 0.21368100 0.58919000 1 - O O41 1 0.47988300 0.37550900 0.28631900 1 - O O42 1 0.89562600 0.02011700 0.30643600 1 - O O43 1 0.60437400 0.91081000 0.12449100 1 - O O44 1 0.91081000 0.12449100 0.60437400 1 - O O45 1 0.28631900 0.47988300 0.37550900 1 - O O46 1 0.58919000 0.19356400 0.21368100 1 - O O47 1 0.21368100 0.58919000 0.19356400 1 - O O48 1 0.02011700 0.30643600 0.89562600 1 - O O49 1 0.91081000 0.28631900 0.30643600 1 - O O50 1 0.02011700 0.21368100 0.12449100 1 - O O51 1 0.80643600 0.78631900 0.41081000 1 - O O52 1 0.19356400 0.47988300 0.60437400 1 - O O53 1 0.60437400 0.19356400 0.47988300 1 - O O54 1 0.21368100 0.12449100 0.02011700 1 - O O55 1 0.12449100 0.60437400 0.91081000 1 - O O56 1 0.41081000 0.10437400 0.62449100 1 - O O57 1 0.62449100 0.41081000 0.10437400 1 - O O58 1 0.71368100 0.69356400 0.08919000 1 - O O59 1 0.52011700 0.39562600 0.80643600 1 - O O60 1 0.69356400 0.10437400 0.97988300 1 - O O61 1 0.87550900 0.97988300 0.78631900 1 - O O62 1 0.62449100 0.71368100 0.52011700 1 - O O63 1 0.10437400 0.62449100 0.41081000 1 - O O64 1 0.87550900 0.39562600 0.08919000 1 - O O65 1 0.78631900 0.87550900 0.97988300 1 - O O66 1 0.39562600 0.80643600 0.52011700 1 - O O67 1 0.69356400 0.08919000 0.71368100 1 - O O68 1 0.80643600 0.52011700 0.39562600 1 - O O69 1 0.97988300 0.78631900 0.87550900 1 - O O70 1 0.08919000 0.71368100 0.69356400 1 - O O71 1 0.97988300 0.69356400 0.10437400 1 - O O72 1 0.78631900 0.41081000 0.80643600 1 - O O73 1 0.41081000 0.80643600 0.78631900 1 - O O74 1 0.71368100 0.52011700 0.62449100 1 - O O75 1 0.08919000 0.87550900 0.39562600 1 - O O76 1 0.39562600 0.08919000 0.87550900 1 - O O77 1 0.10437400 0.97988300 0.69356400 1 - O O78 1 0.52011700 0.62449100 0.71368100 1 - O O79 1 0.30643600 0.91081000 0.28631900 1 -" -Mn2Zn3(SiO4)3,mp-1264019,I4_1/acd,[],0.15487868475000788,{'tags': []},"Full Formula (Mn8 Zn12 Si12 O48) -Reduced Formula: Mn2Zn3(SiO4)3 -abc : 10.282161 10.282161 10.282160 -angles: 112.475336 107.990372 107.990373 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0 0 0 3.863 - 1 Mn 0 0.5 0 3.863 - 2 Mn 0 0 0.5 3.863 - 3 Mn 0 0.5 0.5 3.863 - 4 Mn 0.5 0 0.5 3.863 - 5 Mn 0.5 0.5 0 3.863 - 6 Mn 0.5 0.5 0.5 3.863 - 7 Mn 0.5 0 0 3.863 - 8 Zn 0.368235 0.75 0.118235 0.007 - 9 Zn 0.131765 0.25 0.381765 0.007 - 10 Zn 0.368235 0.118235 0.25 0.007 - 11 Zn 0.131765 0.381765 0.75 0.007 - 12 Zn 0.868235 0.75 0.618235 0.007 - 13 Zn 0.75 0.125 0.375 0.009 - 14 Zn 0.75 0.625 0.875 0.009 - 15 Zn 0.631765 0.25 0.881765 0.007 - 16 Zn 0.25 0.875 0.625 0.009 - 17 Zn 0.868235 0.618235 0.25 0.007 - 18 Zn 0.631765 0.881765 0.75 0.007 - 19 Zn 0.25 0.375 0.125 0.009 - 20 Si 0.25 0.125 0.875 0.012 - 21 Si 0.75 0.875 0.125 0.012 - 22 Si 0.374643 0.25 0.624643 0.011 - 23 Si 0.625357 0.375357 0.25 0.011 - 24 Si 0.125357 0.75 0.875357 0.011 - 25 Si 0.874643 0.124643 0.75 0.011 - 26 Si 0.75 0.375 0.625 0.012 - 27 Si 0.374643 0.624643 0.75 0.011 - 28 Si 0.125357 0.875357 0.25 0.011 - 29 Si 0.874643 0.25 0.124643 0.011 - 30 Si 0.625357 0.75 0.375357 0.011 - 31 Si 0.25 0.625 0.375 0.012 - 32 O 0.291653 0.480714 0.372495 -0 - 33 O 0.016426 0.310858 0.895572 -0.031 - 34 O 0.122103 0.601283 0.90289 0.027 - 35 O 0.208347 0.580841 0.18906 -0 - 36 O 0.208347 0.127505 0.019286 -0 - 37 O 0.584714 0.189142 0.205569 -0.031 - 38 O 0.608219 0.18906 0.480714 -0 - 39 O 0.198393 0.219213 0.59711 0.027 - 40 O 0.891781 0.372495 0.580841 -0 - 41 O 0.301607 0.90289 0.280787 0.027 - 42 O 0.915286 0.294431 0.310858 -0.031 - 43 O 0.016426 0.205569 0.120855 -0.031 - 44 O 0.198393 0.479182 0.601283 0.027 - 45 O 0.584714 0.895572 0.379145 -0.031 - 46 O 0.122103 0.020818 0.219213 0.027 - 47 O 0.483574 0.604428 0.189142 -0.031 - 48 O 0.377897 0.59711 0.898717 0.027 - 49 O 0.891781 0.019286 0.31094 -0 - 50 O 0.608219 0.919159 0.127505 -0 - 51 O 0.108219 0.627506 0.419159 -0 - 52 O 0.915286 0.120855 0.604428 -0.031 - 53 O 0.377897 0.280787 0.479182 0.027 - 54 O 0.301607 0.898717 0.020818 0.027 - 55 O 0.291653 0.31094 0.919159 -0 - 56 O 0.708347 0.519286 0.627506 -0 - 57 O 0.983574 0.689142 0.104428 -0.031 - 58 O 0.877897 0.398717 0.09711 0.027 - 59 O 0.791653 0.419159 0.81094 -0 - 60 O 0.791653 0.872494 0.980714 -0 - 61 O 0.415286 0.810858 0.794431 -0.031 - 62 O 0.391781 0.81094 0.519286 -0 - 63 O 0.801607 0.780787 0.40289 0.027 - 64 O 0.708347 0.68906 0.080841 -0 - 65 O 0.698393 0.101283 0.979182 0.027 - 66 O 0.622103 0.719213 0.520818 0.027 - 67 O 0.516426 0.620855 0.705569 -0.031 - 68 O 0.084714 0.879145 0.395572 -0.031 - 69 O 0.391781 0.080841 0.872494 -0 - 70 O 0.108219 0.980714 0.68906 -0 - 71 O 0.622103 0.40289 0.101283 0.027 - 72 O 0.516426 0.395572 0.810858 -0.031 - 73 O 0.877897 0.979182 0.780787 0.027 - 74 O 0.415286 0.104428 0.620855 -0.031 - 75 O 0.801607 0.520818 0.398717 0.027 - 76 O 0.983574 0.794431 0.879145 -0.031 - 77 O 0.084714 0.705569 0.689142 -0.031 - 78 O 0.698393 0.09711 0.719213 0.027 - 79 O 0.483574 0.379145 0.294431 -0.031","# generated using pymatgen -data_Mn2Zn3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.28216086 -_cell_length_b 10.28216083 -_cell_length_c 10.28216010 -_cell_angle_alpha 112.47533622 -_cell_angle_beta 107.99037215 -_cell_angle_gamma 107.99037262 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn2Zn3(SiO4)3 -_chemical_formula_sum 'Mn8 Zn12 Si12 O48' -_cell_volume 835.08325382 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn1 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn2 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn3 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn4 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn5 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn6 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn7 1 0.50000000 0.00000000 0.00000000 1 - Zn Zn8 1 0.36823500 0.75000000 0.11823500 1 - Zn Zn9 1 0.13176500 0.25000000 0.38176500 1 - Zn Zn10 1 0.36823500 0.11823500 0.25000000 1 - Zn Zn11 1 0.13176500 0.38176500 0.75000000 1 - Zn Zn12 1 0.86823500 0.75000000 0.61823500 1 - Zn Zn13 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn14 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn15 1 0.63176500 0.25000000 0.88176500 1 - Zn Zn16 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn17 1 0.86823500 0.61823500 0.25000000 1 - Zn Zn18 1 0.63176500 0.88176500 0.75000000 1 - Zn Zn19 1 0.25000000 0.37500000 0.12500000 1 - Si Si20 1 0.25000000 0.12500000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.37464300 0.25000000 0.62464300 1 - Si Si23 1 0.62535700 0.37535700 0.25000000 1 - Si Si24 1 0.12535700 0.75000000 0.87535700 1 - Si Si25 1 0.87464300 0.12464300 0.75000000 1 - Si Si26 1 0.75000000 0.37500000 0.62500000 1 - Si Si27 1 0.37464300 0.62464300 0.75000000 1 - Si Si28 1 0.12535700 0.87535700 0.25000000 1 - Si Si29 1 0.87464300 0.25000000 0.12464300 1 - Si Si30 1 0.62535700 0.75000000 0.37535700 1 - Si Si31 1 0.25000000 0.62500000 0.37500000 1 - O O32 1 0.29165300 0.48071400 0.37249500 1 - O O33 1 0.01642600 0.31085800 0.89557200 1 - O O34 1 0.12210300 0.60128300 0.90289000 1 - O O35 1 0.20834700 0.58084100 0.18906000 1 - O O36 1 0.20834700 0.12750500 0.01928600 1 - O O37 1 0.58471400 0.18914200 0.20556900 1 - O O38 1 0.60821900 0.18906000 0.48071400 1 - O O39 1 0.19839300 0.21921300 0.59711000 1 - O O40 1 0.89178100 0.37249500 0.58084100 1 - O O41 1 0.30160700 0.90289000 0.28078700 1 - O O42 1 0.91528600 0.29443100 0.31085800 1 - O O43 1 0.01642600 0.20556900 0.12085500 1 - O O44 1 0.19839300 0.47918200 0.60128300 1 - O O45 1 0.58471400 0.89557200 0.37914500 1 - O O46 1 0.12210300 0.02081800 0.21921300 1 - O O47 1 0.48357400 0.60442800 0.18914200 1 - O O48 1 0.37789700 0.59711000 0.89871700 1 - O O49 1 0.89178100 0.01928600 0.31094000 1 - O O50 1 0.60821900 0.91915900 0.12750500 1 - O O51 1 0.10821900 0.62750600 0.41915900 1 - O O52 1 0.91528600 0.12085500 0.60442800 1 - O O53 1 0.37789700 0.28078700 0.47918200 1 - O O54 1 0.30160700 0.89871700 0.02081800 1 - O O55 1 0.29165300 0.31094000 0.91915900 1 - O O56 1 0.70834700 0.51928600 0.62750600 1 - O O57 1 0.98357400 0.68914200 0.10442800 1 - O O58 1 0.87789700 0.39871700 0.09711000 1 - O O59 1 0.79165300 0.41915900 0.81094000 1 - O O60 1 0.79165300 0.87249400 0.98071400 1 - O O61 1 0.41528600 0.81085800 0.79443100 1 - O O62 1 0.39178100 0.81094000 0.51928600 1 - O O63 1 0.80160700 0.78078700 0.40289000 1 - O O64 1 0.70834700 0.68906000 0.08084100 1 - O O65 1 0.69839300 0.10128300 0.97918200 1 - O O66 1 0.62210300 0.71921300 0.52081800 1 - O O67 1 0.51642600 0.62085500 0.70556900 1 - O O68 1 0.08471400 0.87914500 0.39557200 1 - O O69 1 0.39178100 0.08084100 0.87249400 1 - O O70 1 0.10821900 0.98071400 0.68906000 1 - O O71 1 0.62210300 0.40289000 0.10128300 1 - O O72 1 0.51642600 0.39557200 0.81085800 1 - O O73 1 0.87789700 0.97918200 0.78078700 1 - O O74 1 0.41528600 0.10442800 0.62085500 1 - O O75 1 0.80160700 0.52081800 0.39871700 1 - O O76 1 0.98357400 0.79443100 0.87914500 1 - O O77 1 0.08471400 0.70556900 0.68914200 1 - O O78 1 0.69839300 0.09711000 0.71921300 1 - O O79 1 0.48357400 0.37914500 0.29443100 1 -" -Mg3Cu2(SiO4)3,mp-1265011,Ia-3d,[],0.12041774568749908,{'tags': []},"Full Formula (Mg12 Cu8 Si12 O48) -Reduced Formula: Mg3Cu2(SiO4)3 -abc : 10.146892 10.146892 10.146892 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 -0.002 - 1 Mg 0.75 0.125 0.375 -0.002 - 2 Mg 0.375 0.125 0.25 -0.002 - 3 Mg 0.125 0.375 0.75 -0.002 - 4 Mg 0.25 0.875 0.625 -0.002 - 5 Mg 0.125 0.25 0.375 -0.002 - 6 Mg 0.625 0.25 0.875 -0.002 - 7 Mg 0.75 0.625 0.875 -0.002 - 8 Mg 0.875 0.75 0.625 -0.002 - 9 Mg 0.875 0.625 0.25 -0.002 - 10 Mg 0.625 0.875 0.75 -0.002 - 11 Mg 0.375 0.75 0.125 -0.002 - 12 Cu 0.5 0 0 0.961 - 13 Cu 0.5 0.5 0 0.961 - 14 Cu 0 0.5 0.5 0.961 - 15 Cu 0 0 0.5 0.961 - 16 Cu 0.5 0.5 0.5 0.961 - 17 Cu 0 0.5 0 0.961 - 18 Cu 0.5 0 0.5 0.961 - 19 Cu 0 0 0 0.961 - 20 Si 0.125 0.75 0.875 0.005 - 21 Si 0.875 0.25 0.125 0.005 - 22 Si 0.75 0.375 0.625 0.005 - 23 Si 0.125 0.875 0.25 0.005 - 24 Si 0.25 0.125 0.875 0.005 - 25 Si 0.375 0.625 0.75 0.005 - 26 Si 0.375 0.25 0.625 0.005 - 27 Si 0.875 0.125 0.75 0.005 - 28 Si 0.625 0.375 0.25 0.005 - 29 Si 0.75 0.875 0.125 0.005 - 30 Si 0.25 0.625 0.375 0.005 - 31 Si 0.625 0.75 0.375 0.005 - 32 O 0.586531 0.896034 0.374778 0.148 - 33 O 0.374778 0.586531 0.896034 0.148 - 34 O 0.288248 0.309504 0.913469 0.148 - 35 O 0.478744 0.603966 0.190496 0.148 - 36 O 0.309504 0.896034 0.021256 0.148 - 37 O 0.125222 0.021256 0.211752 0.148 - 38 O 0.374778 0.288248 0.478744 0.148 - 39 O 0.896034 0.374778 0.586531 0.148 - 40 O 0.190496 0.211752 0.586531 0.148 - 41 O 0.478744 0.374778 0.288248 0.148 - 42 O 0.896034 0.021256 0.309504 0.148 - 43 O 0.603966 0.913469 0.125222 0.148 - 44 O 0.913469 0.125222 0.603966 0.148 - 45 O 0.288248 0.478744 0.374778 0.148 - 46 O 0.586531 0.190496 0.211752 0.148 - 47 O 0.211752 0.586531 0.190496 0.148 - 48 O 0.021256 0.309504 0.896034 0.148 - 49 O 0.913469 0.288248 0.309504 0.148 - 50 O 0.021256 0.211752 0.125222 0.148 - 51 O 0.809504 0.788248 0.413469 0.148 - 52 O 0.190496 0.478744 0.603966 0.148 - 53 O 0.603966 0.190496 0.478744 0.148 - 54 O 0.211752 0.125222 0.021256 0.148 - 55 O 0.125222 0.603966 0.913469 0.148 - 56 O 0.413469 0.103966 0.625222 0.148 - 57 O 0.625222 0.413469 0.103966 0.148 - 58 O 0.711752 0.690496 0.086531 0.148 - 59 O 0.521256 0.396034 0.809504 0.148 - 60 O 0.690496 0.103966 0.978744 0.148 - 61 O 0.874778 0.978744 0.788248 0.148 - 62 O 0.625222 0.711752 0.521256 0.148 - 63 O 0.103966 0.625222 0.413469 0.148 - 64 O 0.874778 0.396034 0.086531 0.148 - 65 O 0.788248 0.874778 0.978744 0.148 - 66 O 0.396034 0.809504 0.521256 0.148 - 67 O 0.690496 0.086531 0.711752 0.148 - 68 O 0.809504 0.521256 0.396034 0.148 - 69 O 0.978744 0.788248 0.874778 0.148 - 70 O 0.086531 0.711752 0.690496 0.148 - 71 O 0.978744 0.690496 0.103966 0.148 - 72 O 0.788248 0.413469 0.809504 0.148 - 73 O 0.413469 0.809504 0.788248 0.148 - 74 O 0.711752 0.521256 0.625222 0.148 - 75 O 0.086531 0.874778 0.396034 0.148 - 76 O 0.396034 0.086531 0.874778 0.148 - 77 O 0.103966 0.978744 0.690496 0.148 - 78 O 0.521256 0.625222 0.711752 0.148 - 79 O 0.309504 0.913469 0.288248 0.148","# generated using pymatgen -data_Mg3Cu2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.14689230 -_cell_length_b 10.14689230 -_cell_length_c 10.14689230 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Cu2(SiO4)3 -_chemical_formula_sum 'Mg12 Cu8 Si12 O48' -_cell_volume 804.22442957 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Cu Cu12 1 0.50000000 0.00000000 0.00000000 1 - Cu Cu13 1 0.50000000 0.50000000 0.00000000 1 - Cu Cu14 1 0.00000000 0.50000000 0.50000000 1 - Cu Cu15 1 0.00000000 0.00000000 0.50000000 1 - Cu Cu16 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu17 1 0.00000000 0.50000000 0.00000000 1 - Cu Cu18 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58653100 0.89603400 0.37477800 1 - O O33 1 0.37477800 0.58653100 0.89603400 1 - O O34 1 0.28824800 0.30950400 0.91346900 1 - O O35 1 0.47874400 0.60396600 0.19049600 1 - O O36 1 0.30950400 0.89603400 0.02125600 1 - O O37 1 0.12522200 0.02125600 0.21175200 1 - O O38 1 0.37477800 0.28824800 0.47874400 1 - O O39 1 0.89603400 0.37477800 0.58653100 1 - O O40 1 0.19049600 0.21175200 0.58653100 1 - O O41 1 0.47874400 0.37477800 0.28824800 1 - O O42 1 0.89603400 0.02125600 0.30950400 1 - O O43 1 0.60396600 0.91346900 0.12522200 1 - O O44 1 0.91346900 0.12522200 0.60396600 1 - O O45 1 0.28824800 0.47874400 0.37477800 1 - O O46 1 0.58653100 0.19049600 0.21175200 1 - O O47 1 0.21175200 0.58653100 0.19049600 1 - O O48 1 0.02125600 0.30950400 0.89603400 1 - O O49 1 0.91346900 0.28824800 0.30950400 1 - O O50 1 0.02125600 0.21175200 0.12522200 1 - O O51 1 0.80950400 0.78824800 0.41346900 1 - O O52 1 0.19049600 0.47874400 0.60396600 1 - O O53 1 0.60396600 0.19049600 0.47874400 1 - O O54 1 0.21175200 0.12522200 0.02125600 1 - O O55 1 0.12522200 0.60396600 0.91346900 1 - O O56 1 0.41346900 0.10396600 0.62522200 1 - O O57 1 0.62522200 0.41346900 0.10396600 1 - O O58 1 0.71175200 0.69049600 0.08653100 1 - O O59 1 0.52125600 0.39603400 0.80950400 1 - O O60 1 0.69049600 0.10396600 0.97874400 1 - O O61 1 0.87477800 0.97874400 0.78824800 1 - O O62 1 0.62522200 0.71175200 0.52125600 1 - O O63 1 0.10396600 0.62522200 0.41346900 1 - O O64 1 0.87477800 0.39603400 0.08653100 1 - O O65 1 0.78824800 0.87477800 0.97874400 1 - O O66 1 0.39603400 0.80950400 0.52125600 1 - O O67 1 0.69049600 0.08653100 0.71175200 1 - O O68 1 0.80950400 0.52125600 0.39603400 1 - O O69 1 0.97874400 0.78824800 0.87477800 1 - O O70 1 0.08653100 0.71175200 0.69049600 1 - O O71 1 0.97874400 0.69049600 0.10396600 1 - O O72 1 0.78824800 0.41346900 0.80950400 1 - O O73 1 0.41346900 0.80950400 0.78824800 1 - O O74 1 0.71175200 0.52125600 0.62522200 1 - O O75 1 0.08653100 0.87477800 0.39603400 1 - O O76 1 0.39603400 0.08653100 0.87477800 1 - O O77 1 0.10396600 0.97874400 0.69049600 1 - O O78 1 0.52125600 0.62522200 0.71175200 1 - O O79 1 0.30950400 0.91346900 0.28824800 1 -" -Ca3Mn2(SiO4)3,mp-1265277,I4_1/acd,[],0.02550670165279989,{'tags': []},"Full Formula (Ca12 Mn8 Si12 O48) -Reduced Formula: Ca3Mn2(SiO4)3 -abc : 10.590980 10.590980 10.590981 -angles: 107.103563 110.667862 110.667865 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.378878 0.75 0.128878 0.001 - 1 Ca 0.121122 0.25 0.371122 0.001 - 2 Ca 0.378878 0.128878 0.25 0.001 - 3 Ca 0.121122 0.371122 0.75 0.001 - 4 Ca 0.878878 0.75 0.628878 0.001 - 5 Ca 0.75 0.125 0.375 -0 - 6 Ca 0.75 0.625 0.875 -0 - 7 Ca 0.621122 0.25 0.871122 0.001 - 8 Ca 0.25 0.875 0.625 -0 - 9 Ca 0.878878 0.628878 0.25 0.001 - 10 Ca 0.621122 0.871122 0.75 0.001 - 11 Ca 0.25 0.375 0.125 -0 - 12 Mn 0 0 0 3.881 - 13 Mn 0 0.5 0 3.881 - 14 Mn 0 0 0.5 3.881 - 15 Mn 0 0.5 0.5 3.881 - 16 Mn 0.5 0 0.5 3.881 - 17 Mn 0.5 0.5 0 3.881 - 18 Mn 0.5 0.5 0.5 3.881 - 19 Mn 0.5 0 0 3.881 - 20 Si 0.25 0.125 0.875 0.008 - 21 Si 0.75 0.875 0.125 0.008 - 22 Si 0.3744 0.25 0.6244 0.011 - 23 Si 0.6256 0.3756 0.25 0.011 - 24 Si 0.1256 0.75 0.8756 0.011 - 25 Si 0.8744 0.1244 0.75 0.011 - 26 Si 0.75 0.375 0.625 0.008 - 27 Si 0.3744 0.6244 0.75 0.011 - 28 Si 0.1256 0.8756 0.25 0.011 - 29 Si 0.8744 0.25 0.1244 0.011 - 30 Si 0.6256 0.75 0.3756 0.011 - 31 Si 0.25 0.625 0.375 0.008 - 32 O 0.298975 0.493987 0.386962 -0.019 - 33 O 0.011116 0.298654 0.891657 0.04 - 34 O 0.118583 0.607594 0.91804 -0.027 - 35 O 0.201025 0.587986 0.195012 -0.019 - 36 O 0.201025 0.113038 0.006013 -0.019 - 37 O 0.593004 0.201346 0.212462 0.04 - 38 O 0.607026 0.195012 0.493987 -0.019 - 39 O 0.189554 0.200544 0.58196 -0.027 - 40 O 0.892974 0.386962 0.587986 -0.019 - 41 O 0.310446 0.91804 0.299456 -0.027 - 42 O 0.906996 0.287538 0.298654 0.04 - 43 O 0.011116 0.212462 0.119457 0.04 - 44 O 0.189554 0.48901 0.607594 -0.027 - 45 O 0.593004 0.891657 0.380543 0.04 - 46 O 0.118583 0.01099 0.200544 -0.027 - 47 O 0.488884 0.608343 0.201346 0.04 - 48 O 0.381417 0.58196 0.892406 -0.027 - 49 O 0.892974 0.006013 0.304988 -0.019 - 50 O 0.607026 0.912014 0.113038 -0.019 - 51 O 0.107026 0.613038 0.412014 -0.019 - 52 O 0.906996 0.119457 0.608343 0.04 - 53 O 0.381417 0.299456 0.48901 -0.027 - 54 O 0.310446 0.892406 0.01099 -0.027 - 55 O 0.298975 0.304988 0.912014 -0.019 - 56 O 0.701025 0.506013 0.613038 -0.019 - 57 O 0.988884 0.701346 0.108343 0.04 - 58 O 0.881417 0.392406 0.08196 -0.027 - 59 O 0.798975 0.412014 0.804988 -0.019 - 60 O 0.798975 0.886962 0.993987 -0.019 - 61 O 0.406996 0.798654 0.787538 0.04 - 62 O 0.392974 0.804988 0.506013 -0.019 - 63 O 0.810446 0.799456 0.41804 -0.027 - 64 O 0.701025 0.695012 0.087986 -0.019 - 65 O 0.689554 0.107594 0.98901 -0.027 - 66 O 0.618583 0.700544 0.51099 -0.027 - 67 O 0.511116 0.619457 0.712462 0.04 - 68 O 0.093004 0.880543 0.391657 0.04 - 69 O 0.392974 0.087986 0.886962 -0.019 - 70 O 0.107026 0.993987 0.695012 -0.019 - 71 O 0.618583 0.41804 0.107594 -0.027 - 72 O 0.511116 0.391657 0.798654 0.04 - 73 O 0.881417 0.98901 0.799456 -0.027 - 74 O 0.406996 0.108343 0.619457 0.04 - 75 O 0.810446 0.51099 0.392406 -0.027 - 76 O 0.988884 0.787538 0.880543 0.04 - 77 O 0.093004 0.712462 0.701346 0.04 - 78 O 0.689554 0.08196 0.700544 -0.027 - 79 O 0.488884 0.380543 0.287538 0.04","# generated using pymatgen -data_Ca3Mn2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.59098022 -_cell_length_b 10.59098019 -_cell_length_c 10.59098060 -_cell_angle_alpha 107.10356251 -_cell_angle_beta 110.66786202 -_cell_angle_gamma 110.66786548 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Mn2(SiO4)3 -_chemical_formula_sum 'Ca12 Mn8 Si12 O48' -_cell_volume 913.34091924 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.37887800 0.75000000 0.12887800 1 - Ca Ca1 1 0.12112200 0.25000000 0.37112200 1 - Ca Ca2 1 0.37887800 0.12887800 0.25000000 1 - Ca Ca3 1 0.12112200 0.37112200 0.75000000 1 - Ca Ca4 1 0.87887800 0.75000000 0.62887800 1 - Ca Ca5 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca6 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca7 1 0.62112200 0.25000000 0.87112200 1 - Ca Ca8 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca9 1 0.87887800 0.62887800 0.25000000 1 - Ca Ca10 1 0.62112200 0.87112200 0.75000000 1 - Ca Ca11 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn12 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn13 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn14 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn15 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn16 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn17 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn18 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn19 1 0.50000000 0.00000000 0.00000000 1 - Si Si20 1 0.25000000 0.12500000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.37440000 0.25000000 0.62440000 1 - Si Si23 1 0.62560000 0.37560000 0.25000000 1 - Si Si24 1 0.12560000 0.75000000 0.87560000 1 - Si Si25 1 0.87440000 0.12440000 0.75000000 1 - Si Si26 1 0.75000000 0.37500000 0.62500000 1 - Si Si27 1 0.37440000 0.62440000 0.75000000 1 - Si Si28 1 0.12560000 0.87560000 0.25000000 1 - Si Si29 1 0.87440000 0.25000000 0.12440000 1 - Si Si30 1 0.62560000 0.75000000 0.37560000 1 - Si Si31 1 0.25000000 0.62500000 0.37500000 1 - O O32 1 0.29897500 0.49398700 0.38696200 1 - O O33 1 0.01111600 0.29865400 0.89165700 1 - O O34 1 0.11858300 0.60759400 0.91804000 1 - O O35 1 0.20102500 0.58798600 0.19501200 1 - O O36 1 0.20102500 0.11303800 0.00601300 1 - O O37 1 0.59300400 0.20134600 0.21246200 1 - O O38 1 0.60702600 0.19501200 0.49398700 1 - O O39 1 0.18955400 0.20054400 0.58196000 1 - O O40 1 0.89297400 0.38696200 0.58798600 1 - O O41 1 0.31044600 0.91804000 0.29945600 1 - O O42 1 0.90699600 0.28753800 0.29865400 1 - O O43 1 0.01111600 0.21246200 0.11945700 1 - O O44 1 0.18955400 0.48901000 0.60759400 1 - O O45 1 0.59300400 0.89165700 0.38054300 1 - O O46 1 0.11858300 0.01099000 0.20054400 1 - O O47 1 0.48888400 0.60834300 0.20134600 1 - O O48 1 0.38141700 0.58196000 0.89240600 1 - O O49 1 0.89297400 0.00601300 0.30498800 1 - O O50 1 0.60702600 0.91201400 0.11303800 1 - O O51 1 0.10702600 0.61303800 0.41201400 1 - O O52 1 0.90699600 0.11945700 0.60834300 1 - O O53 1 0.38141700 0.29945600 0.48901000 1 - O O54 1 0.31044600 0.89240600 0.01099000 1 - O O55 1 0.29897500 0.30498800 0.91201400 1 - O O56 1 0.70102500 0.50601300 0.61303800 1 - O O57 1 0.98888400 0.70134600 0.10834300 1 - O O58 1 0.88141700 0.39240600 0.08196000 1 - O O59 1 0.79897500 0.41201400 0.80498800 1 - O O60 1 0.79897500 0.88696200 0.99398700 1 - O O61 1 0.40699600 0.79865400 0.78753800 1 - O O62 1 0.39297400 0.80498800 0.50601300 1 - O O63 1 0.81044600 0.79945600 0.41804000 1 - O O64 1 0.70102500 0.69501200 0.08798600 1 - O O65 1 0.68955400 0.10759400 0.98901000 1 - O O66 1 0.61858300 0.70054400 0.51099000 1 - O O67 1 0.51111600 0.61945700 0.71246200 1 - O O68 1 0.09300400 0.88054300 0.39165700 1 - O O69 1 0.39297400 0.08798600 0.88696200 1 - O O70 1 0.10702600 0.99398700 0.69501200 1 - O O71 1 0.61858300 0.41804000 0.10759400 1 - O O72 1 0.51111600 0.39165700 0.79865400 1 - O O73 1 0.88141700 0.98901000 0.79945600 1 - O O74 1 0.40699600 0.10834300 0.61945700 1 - O O75 1 0.81044600 0.51099000 0.39240600 1 - O O76 1 0.98888400 0.78753800 0.88054300 1 - O O77 1 0.09300400 0.71246200 0.70134600 1 - O O78 1 0.68955400 0.08196000 0.70054400 1 - O O79 1 0.48888400 0.38054300 0.28753800 1 -" -Sc2Cd3(GeO4)3,mp-13771,Ia-3d,[20216],0.012617160864586197,"{'tags': ['Tricadmium discandium tris(germanate)', 'Garnet-(Cd,Sc,Ge)']}","Full Formula (Sc8 Cd12 Ge12 O48) -Reduced Formula: Sc2Cd3(GeO4)3 -abc : 10.953184 10.953184 10.953184 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sc 0 0 0.5 -0.001 - 1 Sc 0 0 0 -0.001 - 2 Sc 0.5 0 0 -0.001 - 3 Sc 0 0.5 0 -0.001 - 4 Sc 0.5 0.5 0 -0.001 - 5 Sc 0 0.5 0.5 -0.001 - 6 Sc 0.5 0 0.5 -0.001 - 7 Sc 0.5 0.5 0.5 -0.001 - 8 Cd 0.875 0.625 0.25 -0 - 9 Cd 0.625 0.25 0.875 -0 - 10 Cd 0.875 0.75 0.625 -0 - 11 Cd 0.75 0.625 0.875 -0 - 12 Cd 0.25 0.875 0.625 -0 - 13 Cd 0.625 0.875 0.75 -0 - 14 Cd 0.125 0.375 0.75 -0 - 15 Cd 0.375 0.75 0.125 -0 - 16 Cd 0.125 0.25 0.375 -0 - 17 Cd 0.25 0.375 0.125 -0 - 18 Cd 0.75 0.125 0.375 -0 - 19 Cd 0.375 0.125 0.25 -0 - 20 Ge 0.125 0.875 0.25 -0.001 - 21 Ge 0.25 0.125 0.875 -0.001 - 22 Ge 0.75 0.375 0.625 -0.001 - 23 Ge 0.625 0.375 0.25 -0.001 - 24 Ge 0.625 0.75 0.375 -0.001 - 25 Ge 0.375 0.625 0.75 -0.001 - 26 Ge 0.125 0.75 0.875 -0.001 - 27 Ge 0.75 0.875 0.125 -0.001 - 28 Ge 0.875 0.25 0.125 -0.001 - 29 Ge 0.375 0.25 0.625 -0.001 - 30 Ge 0.25 0.625 0.375 -0.001 - 31 Ge 0.875 0.125 0.75 -0.001 - 32 O 0.414908 0.810809 0.793364 0.001 - 33 O 0.878456 0.395901 0.085092 0.001 - 34 O 0.104099 0.982555 0.689191 0.001 - 35 O 0.517445 0.621544 0.706636 0.001 - 36 O 0.689191 0.085092 0.706636 0.001 - 37 O 0.621544 0.706636 0.517445 0.001 - 38 O 0.621544 0.414908 0.104099 0.001 - 39 O 0.706636 0.517445 0.621544 0.001 - 40 O 0.810809 0.517445 0.395901 0.001 - 41 O 0.982555 0.793364 0.878456 0.001 - 42 O 0.793364 0.878456 0.982555 0.001 - 43 O 0.706636 0.689191 0.085092 0.001 - 44 O 0.414908 0.104099 0.621544 0.001 - 45 O 0.395901 0.810809 0.517445 0.001 - 46 O 0.085092 0.706636 0.689191 0.001 - 47 O 0.104099 0.621544 0.414908 0.001 - 48 O 0.517445 0.395901 0.810809 0.001 - 49 O 0.085092 0.878456 0.395901 0.001 - 50 O 0.982555 0.689191 0.104099 0.001 - 51 O 0.189191 0.482555 0.604099 0.001 - 52 O 0.689191 0.104099 0.982555 0.001 - 53 O 0.793364 0.414908 0.810809 0.001 - 54 O 0.395901 0.085092 0.878456 0.001 - 55 O 0.878456 0.982555 0.793364 0.001 - 56 O 0.585092 0.189191 0.206636 0.001 - 57 O 0.121544 0.604099 0.914908 0.001 - 58 O 0.895901 0.017445 0.310809 0.001 - 59 O 0.482555 0.378456 0.293364 0.001 - 60 O 0.310809 0.914908 0.293364 0.001 - 61 O 0.378456 0.293364 0.482555 0.001 - 62 O 0.378456 0.585092 0.895901 0.001 - 63 O 0.293364 0.482555 0.378456 0.001 - 64 O 0.121544 0.017445 0.206636 0.001 - 65 O 0.604099 0.914908 0.121544 0.001 - 66 O 0.206636 0.585092 0.189191 0.001 - 67 O 0.189191 0.206636 0.585092 0.001 - 68 O 0.310809 0.895901 0.017445 0.001 - 69 O 0.017445 0.310809 0.895901 0.001 - 70 O 0.914908 0.121544 0.604099 0.001 - 71 O 0.482555 0.604099 0.189191 0.001 - 72 O 0.895901 0.378456 0.585092 0.001 - 73 O 0.914908 0.293364 0.310809 0.001 - 74 O 0.604099 0.189191 0.482555 0.001 - 75 O 0.585092 0.895901 0.378456 0.001 - 76 O 0.293364 0.310809 0.914908 0.001 - 77 O 0.206636 0.121544 0.017445 0.001 - 78 O 0.017445 0.206636 0.121544 0.001 - 79 O 0.810809 0.793364 0.414908 0.001","# generated using pymatgen -data_Sc2Cd3(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.95318447 -_cell_length_b 10.95318447 -_cell_length_c 10.95318447 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sc2Cd3(GeO4)3 -_chemical_formula_sum 'Sc8 Cd12 Ge12 O48' -_cell_volume 1011.57785808 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sc Sc0 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc1 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc2 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc3 1 0.00000000 0.50000000 0.00000000 1 - Sc Sc4 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc5 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc6 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc7 1 0.50000000 0.50000000 0.50000000 1 - Cd Cd8 1 0.87500000 0.62500000 0.25000000 1 - Cd Cd9 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd10 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd11 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd12 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd13 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd14 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd15 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd16 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd17 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd18 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd19 1 0.37500000 0.12500000 0.25000000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge22 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge23 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.41490800 0.81080900 0.79336400 1 - O O33 1 0.87845600 0.39590100 0.08509200 1 - O O34 1 0.10409900 0.98255500 0.68919100 1 - O O35 1 0.51744500 0.62154400 0.70663600 1 - O O36 1 0.68919100 0.08509200 0.70663600 1 - O O37 1 0.62154400 0.70663600 0.51744500 1 - O O38 1 0.62154400 0.41490800 0.10409900 1 - O O39 1 0.70663600 0.51744500 0.62154400 1 - O O40 1 0.81080900 0.51744500 0.39590100 1 - O O41 1 0.98255500 0.79336400 0.87845600 1 - O O42 1 0.79336400 0.87845600 0.98255500 1 - O O43 1 0.70663600 0.68919100 0.08509200 1 - O O44 1 0.41490800 0.10409900 0.62154400 1 - O O45 1 0.39590100 0.81080900 0.51744500 1 - O O46 1 0.08509200 0.70663600 0.68919100 1 - O O47 1 0.10409900 0.62154400 0.41490800 1 - O O48 1 0.51744500 0.39590100 0.81080900 1 - O O49 1 0.08509200 0.87845600 0.39590100 1 - O O50 1 0.98255500 0.68919100 0.10409900 1 - O O51 1 0.18919100 0.48255500 0.60409900 1 - O O52 1 0.68919100 0.10409900 0.98255500 1 - O O53 1 0.79336400 0.41490800 0.81080900 1 - O O54 1 0.39590100 0.08509200 0.87845600 1 - O O55 1 0.87845600 0.98255500 0.79336400 1 - O O56 1 0.58509200 0.18919100 0.20663600 1 - O O57 1 0.12154400 0.60409900 0.91490800 1 - O O58 1 0.89590100 0.01744500 0.31080900 1 - O O59 1 0.48255500 0.37845600 0.29336400 1 - O O60 1 0.31080900 0.91490800 0.29336400 1 - O O61 1 0.37845600 0.29336400 0.48255500 1 - O O62 1 0.37845600 0.58509200 0.89590100 1 - O O63 1 0.29336400 0.48255500 0.37845600 1 - O O64 1 0.12154400 0.01744500 0.20663600 1 - O O65 1 0.60409900 0.91490800 0.12154400 1 - O O66 1 0.20663600 0.58509200 0.18919100 1 - O O67 1 0.18919100 0.20663600 0.58509200 1 - O O68 1 0.31080900 0.89590100 0.01744500 1 - O O69 1 0.01744500 0.31080900 0.89590100 1 - O O70 1 0.91490800 0.12154400 0.60409900 1 - O O71 1 0.48255500 0.60409900 0.18919100 1 - O O72 1 0.89590100 0.37845600 0.58509200 1 - O O73 1 0.91490800 0.29336400 0.31080900 1 - O O74 1 0.60409900 0.18919100 0.48255500 1 - O O75 1 0.58509200 0.89590100 0.37845600 1 - O O76 1 0.29336400 0.31080900 0.91490800 1 - O O77 1 0.20663600 0.12154400 0.01744500 1 - O O78 1 0.01744500 0.20663600 0.12154400 1 - O O79 1 0.81080900 0.79336400 0.41490800 1 -" -Na3Li3Sc2F12,mp-14023,Ia-3d,[27007],0.0,{'tags': ['Trisodium trilithium discandium fluoride']},"Full Formula (Na12 Li12 Sc8 F48) -Reduced Formula: Na3Li3Sc2F12 -abc : 11.061917 11.061917 11.061917 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.625 0.875 0.75 -0 - 1 Na 0.875 0.625 0.25 -0 - 2 Na 0.75 0.625 0.875 -0 - 3 Na 0.875 0.75 0.625 -0 - 4 Na 0.625 0.25 0.875 -0 - 5 Na 0.25 0.875 0.625 -0 - 6 Na 0.375 0.125 0.25 -0 - 7 Na 0.125 0.375 0.75 -0 - 8 Na 0.25 0.375 0.125 -0 - 9 Na 0.125 0.25 0.375 -0 - 10 Na 0.75 0.125 0.375 -0 - 11 Na 0.375 0.75 0.125 -0 - 12 Li 0.625 0.75 0.375 0 - 13 Li 0.75 0.875 0.125 0 - 14 Li 0.25 0.125 0.875 0 - 15 Li 0.375 0.625 0.75 0 - 16 Li 0.125 0.875 0.25 0 - 17 Li 0.875 0.25 0.125 0 - 18 Li 0.625 0.375 0.25 0 - 19 Li 0.875 0.125 0.75 0 - 20 Li 0.25 0.625 0.375 0 - 21 Li 0.375 0.25 0.625 0 - 22 Li 0.125 0.75 0.875 0 - 23 Li 0.75 0.375 0.625 0 - 24 Sc 0.5 0 0.5 -0 - 25 Sc 0 0.5 0 -0 - 26 Sc 0.5 0.5 0.5 -0 - 27 Sc 0 0 0.5 -0 - 28 Sc 0 0 0 -0 - 29 Sc 0 0.5 0.5 -0 - 30 Sc 0.5 0.5 0 -0 - 31 Sc 0.5 0 0 -0 - 32 F 0.520052 0.400712 0.821864 0 - 33 F 0.801812 0.421152 0.821864 0 - 34 F 0.520052 0.61934 0.698188 0 - 35 F 0.698188 0.520052 0.61934 0 - 36 F 0.078848 0.88066 0.400712 0 - 37 F 0.979948 0.801812 0.88066 0 - 38 F 0.078848 0.698188 0.678136 0 - 39 F 0.88066 0.979948 0.801812 0 - 40 F 0.099288 0.979948 0.678136 0 - 41 F 0.400712 0.078848 0.88066 0 - 42 F 0.421152 0.821864 0.801812 0 - 43 F 0.61934 0.698188 0.520052 0 - 44 F 0.400712 0.821864 0.520052 0 - 45 F 0.821864 0.801812 0.421152 0 - 46 F 0.678136 0.078848 0.698188 0 - 47 F 0.88066 0.400712 0.078848 0 - 48 F 0.421152 0.099288 0.61934 0 - 49 F 0.979948 0.678136 0.099288 0 - 50 F 0.801812 0.88066 0.979948 0 - 51 F 0.821864 0.520052 0.400712 0 - 52 F 0.321864 0.900712 0.020052 0 - 53 F 0.301812 0.321864 0.921152 0 - 54 F 0.900712 0.38066 0.578848 0 - 55 F 0.11934 0.020052 0.198188 0 - 56 F 0.38066 0.578848 0.900712 0 - 57 F 0.921152 0.301812 0.321864 0 - 58 F 0.020052 0.198188 0.11934 0 - 59 F 0.921152 0.11934 0.599288 0 - 60 F 0.301812 0.479948 0.38066 0 - 61 F 0.479948 0.38066 0.301812 0 - 62 F 0.198188 0.578848 0.178136 0 - 63 F 0.020052 0.321864 0.900712 0 - 64 F 0.900712 0.020052 0.321864 0 - 65 F 0.599288 0.921152 0.11934 0 - 66 F 0.578848 0.178136 0.198188 0 - 67 F 0.38066 0.301812 0.479948 0 - 68 F 0.599288 0.178136 0.479948 0 - 69 F 0.178136 0.198188 0.578848 0 - 70 F 0.321864 0.921152 0.301812 0 - 71 F 0.11934 0.599288 0.921152 0 - 72 F 0.578848 0.900712 0.38066 0 - 73 F 0.198188 0.11934 0.020052 0 - 74 F 0.178136 0.479948 0.599288 0 - 75 F 0.479948 0.599288 0.178136 0 - 76 F 0.678136 0.099288 0.979948 0 - 77 F 0.698188 0.678136 0.078848 0 - 78 F 0.099288 0.61934 0.421152 0 - 79 F 0.61934 0.421152 0.099288 0","# generated using pymatgen -data_Na3Li3Sc2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.06191742 -_cell_length_b 11.06191742 -_cell_length_c 11.06191742 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3Sc2F12 -_chemical_formula_sum 'Na12 Li12 Sc8 F48' -_cell_volume 1042.00390205 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.62500000 0.87500000 0.75000000 1 - Na Na1 1 0.87500000 0.62500000 0.25000000 1 - Na Na2 1 0.75000000 0.62500000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.62500000 0.25000000 0.87500000 1 - Na Na5 1 0.25000000 0.87500000 0.62500000 1 - Na Na6 1 0.37500000 0.12500000 0.25000000 1 - Na Na7 1 0.12500000 0.37500000 0.75000000 1 - Na Na8 1 0.25000000 0.37500000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.75000000 0.12500000 0.37500000 1 - Na Na11 1 0.37500000 0.75000000 0.12500000 1 - Li Li12 1 0.62500000 0.75000000 0.37500000 1 - Li Li13 1 0.75000000 0.87500000 0.12500000 1 - Li Li14 1 0.25000000 0.12500000 0.87500000 1 - Li Li15 1 0.37500000 0.62500000 0.75000000 1 - Li Li16 1 0.12500000 0.87500000 0.25000000 1 - Li Li17 1 0.87500000 0.25000000 0.12500000 1 - Li Li18 1 0.62500000 0.37500000 0.25000000 1 - Li Li19 1 0.87500000 0.12500000 0.75000000 1 - Li Li20 1 0.25000000 0.62500000 0.37500000 1 - Li Li21 1 0.37500000 0.25000000 0.62500000 1 - Li Li22 1 0.12500000 0.75000000 0.87500000 1 - Li Li23 1 0.75000000 0.37500000 0.62500000 1 - Sc Sc24 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc25 1 0.00000000 0.50000000 0.00000000 1 - Sc Sc26 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc27 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc28 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc29 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc30 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc31 1 0.50000000 0.00000000 0.00000000 1 - F F32 1 0.52005200 0.40071200 0.82186400 1 - F F33 1 0.80181200 0.42115200 0.82186400 1 - F F34 1 0.52005200 0.61934000 0.69818800 1 - F F35 1 0.69818800 0.52005200 0.61934000 1 - F F36 1 0.07884800 0.88066000 0.40071200 1 - F F37 1 0.97994800 0.80181200 0.88066000 1 - F F38 1 0.07884800 0.69818800 0.67813600 1 - F F39 1 0.88066000 0.97994800 0.80181200 1 - F F40 1 0.09928800 0.97994800 0.67813600 1 - F F41 1 0.40071200 0.07884800 0.88066000 1 - F F42 1 0.42115200 0.82186400 0.80181200 1 - F F43 1 0.61934000 0.69818800 0.52005200 1 - F F44 1 0.40071200 0.82186400 0.52005200 1 - F F45 1 0.82186400 0.80181200 0.42115200 1 - F F46 1 0.67813600 0.07884800 0.69818800 1 - F F47 1 0.88066000 0.40071200 0.07884800 1 - F F48 1 0.42115200 0.09928800 0.61934000 1 - F F49 1 0.97994800 0.67813600 0.09928800 1 - F F50 1 0.80181200 0.88066000 0.97994800 1 - F F51 1 0.82186400 0.52005200 0.40071200 1 - F F52 1 0.32186400 0.90071200 0.02005200 1 - F F53 1 0.30181200 0.32186400 0.92115200 1 - F F54 1 0.90071200 0.38066000 0.57884800 1 - F F55 1 0.11934000 0.02005200 0.19818800 1 - F F56 1 0.38066000 0.57884800 0.90071200 1 - F F57 1 0.92115200 0.30181200 0.32186400 1 - F F58 1 0.02005200 0.19818800 0.11934000 1 - F F59 1 0.92115200 0.11934000 0.59928800 1 - F F60 1 0.30181200 0.47994800 0.38066000 1 - F F61 1 0.47994800 0.38066000 0.30181200 1 - F F62 1 0.19818800 0.57884800 0.17813600 1 - F F63 1 0.02005200 0.32186400 0.90071200 1 - F F64 1 0.90071200 0.02005200 0.32186400 1 - F F65 1 0.59928800 0.92115200 0.11934000 1 - F F66 1 0.57884800 0.17813600 0.19818800 1 - F F67 1 0.38066000 0.30181200 0.47994800 1 - F F68 1 0.59928800 0.17813600 0.47994800 1 - F F69 1 0.17813600 0.19818800 0.57884800 1 - F F70 1 0.32186400 0.92115200 0.30181200 1 - F F71 1 0.11934000 0.59928800 0.92115200 1 - F F72 1 0.57884800 0.90071200 0.38066000 1 - F F73 1 0.19818800 0.11934000 0.02005200 1 - F F74 1 0.17813600 0.47994800 0.59928800 1 - F F75 1 0.47994800 0.59928800 0.17813600 1 - F F76 1 0.67813600 0.09928800 0.97994800 1 - F F77 1 0.69818800 0.67813600 0.07884800 1 - F F78 1 0.09928800 0.61934000 0.42115200 1 - F F79 1 0.61934000 0.42115200 0.09928800 1 -" -Mg3V2(SiO4)3,mp-14043,Ia-3d,[27372],0.05851459018750127,{'tags': ['Trimagnesium divanadium(III) silicate']},"Full Formula (Mg12 V8 Si12 O48) -Reduced Formula: Mg3V2(SiO4)3 -abc : 10.248778 10.248778 10.248778 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0.002 - 1 Mg 0.75 0.125 0.375 0.001 - 2 Mg 0.375 0.125 0.25 0.002 - 3 Mg 0.125 0.375 0.75 0.002 - 4 Mg 0.25 0.875 0.625 0.001 - 5 Mg 0.125 0.25 0.375 0.002 - 6 Mg 0.625 0.25 0.875 0.001 - 7 Mg 0.75 0.625 0.875 0.002 - 8 Mg 0.875 0.75 0.625 0.002 - 9 Mg 0.875 0.625 0.25 0.002 - 10 Mg 0.625 0.875 0.75 0.002 - 11 Mg 0.375 0.75 0.125 0.001 - 12 V 0.5 0 0 1.888 - 13 V 0.5 0.5 0 1.888 - 14 V 0 0.5 0.5 1.888 - 15 V 0 0 0.5 1.888 - 16 V 0.5 0.5 0.5 1.887 - 17 V 0 0.5 0 1.888 - 18 V 0.5 0 0.5 1.887 - 19 V 0 0 0 1.887 - 20 Si 0.125 0.75 0.875 0.006 - 21 Si 0.875 0.25 0.125 0.006 - 22 Si 0.75 0.375 0.625 0.006 - 23 Si 0.125 0.875 0.25 0.008 - 24 Si 0.25 0.125 0.875 0.007 - 25 Si 0.375 0.625 0.75 0.008 - 26 Si 0.375 0.25 0.625 0.008 - 27 Si 0.875 0.125 0.75 0.008 - 28 Si 0.625 0.375 0.25 0.008 - 29 Si 0.75 0.875 0.125 0.007 - 30 Si 0.25 0.625 0.375 0.006 - 31 Si 0.625 0.75 0.375 0.008 - 32 O 0.588626 0.895897 0.375829 -0.005 - 33 O 0.375829 0.588626 0.895897 -0.004 - 34 O 0.287204 0.307271 0.911374 0.003 - 35 O 0.479932 0.604103 0.192729 -0.004 - 36 O 0.307271 0.895897 0.020068 0.003 - 37 O 0.124171 0.020068 0.212796 -0.005 - 38 O 0.375829 0.287204 0.479932 -0.004 - 39 O 0.895897 0.375829 0.588626 -0.004 - 40 O 0.192729 0.212796 0.588626 0.003 - 41 O 0.479932 0.375829 0.287204 -0.005 - 42 O 0.895897 0.020068 0.307271 -0.001 - 43 O 0.604103 0.911374 0.124171 -0.005 - 44 O 0.911374 0.124171 0.604103 -0.007 - 45 O 0.287204 0.479932 0.375829 0.003 - 46 O 0.588626 0.192729 0.212796 -0.005 - 47 O 0.212796 0.588626 0.192729 -0.003 - 48 O 0.020068 0.307271 0.895897 0.003 - 49 O 0.911374 0.287204 0.307271 -0.004 - 50 O 0.020068 0.212796 0.124171 0.003 - 51 O 0.807271 0.787204 0.411374 0.003 - 52 O 0.192729 0.479932 0.604103 0.003 - 53 O 0.604103 0.192729 0.479932 0.003 - 54 O 0.212796 0.124171 0.020068 -0.004 - 55 O 0.124171 0.604103 0.911374 -0.004 - 56 O 0.411374 0.104103 0.624171 -0.005 - 57 O 0.624171 0.411374 0.104103 -0.004 - 58 O 0.712796 0.692729 0.088626 0.003 - 59 O 0.520068 0.395897 0.807271 -0.004 - 60 O 0.692729 0.104103 0.979932 0.003 - 61 O 0.875829 0.979932 0.787204 -0.005 - 62 O 0.624171 0.712796 0.520068 -0.004 - 63 O 0.104103 0.624171 0.411374 -0.004 - 64 O 0.875829 0.395897 0.088626 -0.004 - 65 O 0.787204 0.875829 0.979932 -0.004 - 66 O 0.395897 0.807271 0.520068 0.003 - 67 O 0.692729 0.088626 0.712796 -0.005 - 68 O 0.807271 0.520068 0.395897 0.003 - 69 O 0.979932 0.787204 0.875829 0.003 - 70 O 0.088626 0.712796 0.692729 -0.004 - 71 O 0.979932 0.692729 0.104103 0.003 - 72 O 0.787204 0.411374 0.807271 -0.003 - 73 O 0.411374 0.807271 0.787204 -0.005 - 74 O 0.712796 0.520068 0.624171 0.003 - 75 O 0.088626 0.875829 0.395897 -0.007 - 76 O 0.395897 0.088626 0.875829 -0.005 - 77 O 0.104103 0.979932 0.692729 -0.001 - 78 O 0.520068 0.624171 0.712796 -0.005 - 79 O 0.307271 0.911374 0.287204 -0.005","# generated using pymatgen -data_Mg3V2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.24877846 -_cell_length_b 10.24877846 -_cell_length_c 10.24877846 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3V2(SiO4)3 -_chemical_formula_sum 'Mg12 V8 Si12 O48' -_cell_volume 828.69443979 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - V V12 1 0.50000000 0.00000000 0.00000000 1 - V V13 1 0.50000000 0.50000000 0.00000000 1 - V V14 1 0.00000000 0.50000000 0.50000000 1 - V V15 1 0.00000000 0.00000000 0.50000000 1 - V V16 1 0.50000000 0.50000000 0.50000000 1 - V V17 1 0.00000000 0.50000000 0.00000000 1 - V V18 1 0.50000000 0.00000000 0.50000000 1 - V V19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58862600 0.89589700 0.37582900 1 - O O33 1 0.37582900 0.58862600 0.89589700 1 - O O34 1 0.28720400 0.30727100 0.91137400 1 - O O35 1 0.47993200 0.60410300 0.19272900 1 - O O36 1 0.30727100 0.89589700 0.02006800 1 - O O37 1 0.12417100 0.02006800 0.21279600 1 - O O38 1 0.37582900 0.28720400 0.47993200 1 - O O39 1 0.89589700 0.37582900 0.58862600 1 - O O40 1 0.19272900 0.21279600 0.58862600 1 - O O41 1 0.47993200 0.37582900 0.28720400 1 - O O42 1 0.89589700 0.02006800 0.30727100 1 - O O43 1 0.60410300 0.91137400 0.12417100 1 - O O44 1 0.91137400 0.12417100 0.60410300 1 - O O45 1 0.28720400 0.47993200 0.37582900 1 - O O46 1 0.58862600 0.19272900 0.21279600 1 - O O47 1 0.21279600 0.58862600 0.19272900 1 - O O48 1 0.02006800 0.30727100 0.89589700 1 - O O49 1 0.91137400 0.28720400 0.30727100 1 - O O50 1 0.02006800 0.21279600 0.12417100 1 - O O51 1 0.80727100 0.78720400 0.41137400 1 - O O52 1 0.19272900 0.47993200 0.60410300 1 - O O53 1 0.60410300 0.19272900 0.47993200 1 - O O54 1 0.21279600 0.12417100 0.02006800 1 - O O55 1 0.12417100 0.60410300 0.91137400 1 - O O56 1 0.41137400 0.10410300 0.62417100 1 - O O57 1 0.62417100 0.41137400 0.10410300 1 - O O58 1 0.71279600 0.69272900 0.08862600 1 - O O59 1 0.52006800 0.39589700 0.80727100 1 - O O60 1 0.69272900 0.10410300 0.97993200 1 - O O61 1 0.87582900 0.97993200 0.78720400 1 - O O62 1 0.62417100 0.71279600 0.52006800 1 - O O63 1 0.10410300 0.62417100 0.41137400 1 - O O64 1 0.87582900 0.39589700 0.08862600 1 - O O65 1 0.78720400 0.87582900 0.97993200 1 - O O66 1 0.39589700 0.80727100 0.52006800 1 - O O67 1 0.69272900 0.08862600 0.71279600 1 - O O68 1 0.80727100 0.52006800 0.39589700 1 - O O69 1 0.97993200 0.78720400 0.87582900 1 - O O70 1 0.08862600 0.71279600 0.69272900 1 - O O71 1 0.97993200 0.69272900 0.10410300 1 - O O72 1 0.78720400 0.41137400 0.80727100 1 - O O73 1 0.41137400 0.80727100 0.78720400 1 - O O74 1 0.71279600 0.52006800 0.62417100 1 - O O75 1 0.08862600 0.87582900 0.39589700 1 - O O76 1 0.39589700 0.08862600 0.87582900 1 - O O77 1 0.10410300 0.97993200 0.69272900 1 - O O78 1 0.52006800 0.62417100 0.71279600 1 - O O79 1 0.30727100 0.91137400 0.28720400 1 -" -Mg3Mn2(SiO4)3,mp-14044,Ia-3d,[27374],0.11415411477082582,{'tags': ['Trimagnesium dimanganese(III) silicate']},"Full Formula (Mg12 Mn8 Si12 O48) -Reduced Formula: Mg3Mn2(SiO4)3 -abc : 10.231551 10.231551 10.231551 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0.003 - 1 Mg 0.75 0.125 0.375 0.003 - 2 Mg 0.375 0.125 0.25 0.003 - 3 Mg 0.125 0.375 0.75 0.003 - 4 Mg 0.25 0.875 0.625 0.003 - 5 Mg 0.125 0.25 0.375 0.003 - 6 Mg 0.625 0.25 0.875 0.003 - 7 Mg 0.75 0.625 0.875 0.003 - 8 Mg 0.875 0.75 0.625 0.003 - 9 Mg 0.875 0.625 0.25 0.003 - 10 Mg 0.625 0.875 0.75 0.003 - 11 Mg 0.375 0.75 0.125 0.003 - 12 Mn 0.5 0 0 4.037 - 13 Mn 0.5 0.5 0 4.037 - 14 Mn 0 0.5 0.5 4.037 - 15 Mn 0 0 0.5 4.037 - 16 Mn 0.5 0.5 0.5 4.037 - 17 Mn 0 0.5 0 4.037 - 18 Mn 0.5 0 0.5 4.037 - 19 Mn 0 0 0 4.037 - 20 Si 0.125 0.75 0.875 0.013 - 21 Si 0.875 0.25 0.125 0.013 - 22 Si 0.75 0.375 0.625 0.013 - 23 Si 0.125 0.875 0.25 0.013 - 24 Si 0.25 0.125 0.875 0.013 - 25 Si 0.375 0.625 0.75 0.013 - 26 Si 0.375 0.25 0.625 0.013 - 27 Si 0.875 0.125 0.75 0.013 - 28 Si 0.625 0.375 0.25 0.013 - 29 Si 0.75 0.875 0.125 0.013 - 30 Si 0.25 0.625 0.375 0.013 - 31 Si 0.625 0.75 0.375 0.013 - 32 O 0.58931 0.896648 0.374775 -0.029 - 33 O 0.374775 0.58931 0.896648 -0.029 - 34 O 0.285465 0.307338 0.91069 -0.029 - 35 O 0.478127 0.603352 0.192662 -0.029 - 36 O 0.307338 0.896648 0.021873 -0.029 - 37 O 0.125225 0.021873 0.214535 -0.029 - 38 O 0.374775 0.285465 0.478127 -0.029 - 39 O 0.896648 0.374775 0.58931 -0.029 - 40 O 0.192662 0.214535 0.58931 -0.029 - 41 O 0.478127 0.374775 0.285465 -0.029 - 42 O 0.896648 0.021873 0.307338 -0.029 - 43 O 0.603352 0.91069 0.125225 -0.029 - 44 O 0.91069 0.125225 0.603352 -0.029 - 45 O 0.285465 0.478127 0.374775 -0.029 - 46 O 0.58931 0.192662 0.214535 -0.029 - 47 O 0.214535 0.58931 0.192662 -0.029 - 48 O 0.021873 0.307338 0.896648 -0.029 - 49 O 0.91069 0.285465 0.307338 -0.029 - 50 O 0.021873 0.214535 0.125225 -0.029 - 51 O 0.807338 0.785465 0.41069 -0.029 - 52 O 0.192662 0.478127 0.603352 -0.029 - 53 O 0.603352 0.192662 0.478127 -0.029 - 54 O 0.214535 0.125225 0.021873 -0.029 - 55 O 0.125225 0.603352 0.91069 -0.029 - 56 O 0.41069 0.103352 0.625225 -0.029 - 57 O 0.625225 0.41069 0.103352 -0.029 - 58 O 0.714535 0.692662 0.08931 -0.029 - 59 O 0.521873 0.396648 0.807338 -0.029 - 60 O 0.692662 0.103352 0.978127 -0.029 - 61 O 0.874775 0.978127 0.785465 -0.029 - 62 O 0.625225 0.714535 0.521873 -0.029 - 63 O 0.103352 0.625225 0.41069 -0.029 - 64 O 0.874775 0.396648 0.08931 -0.029 - 65 O 0.785465 0.874775 0.978127 -0.029 - 66 O 0.396648 0.807338 0.521873 -0.029 - 67 O 0.692662 0.08931 0.714535 -0.029 - 68 O 0.807338 0.521873 0.396648 -0.029 - 69 O 0.978127 0.785465 0.874775 -0.029 - 70 O 0.08931 0.714535 0.692662 -0.029 - 71 O 0.978127 0.692662 0.103352 -0.029 - 72 O 0.785465 0.41069 0.807338 -0.029 - 73 O 0.41069 0.807338 0.785465 -0.029 - 74 O 0.714535 0.521873 0.625225 -0.029 - 75 O 0.08931 0.874775 0.396648 -0.029 - 76 O 0.396648 0.08931 0.874775 -0.029 - 77 O 0.103352 0.978127 0.692662 -0.029 - 78 O 0.521873 0.625225 0.714535 -0.029 - 79 O 0.307338 0.91069 0.285465 -0.029","# generated using pymatgen -data_Mg3Mn2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.23155148 -_cell_length_b 10.23155148 -_cell_length_c 10.23155148 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Mn2(SiO4)3 -_chemical_formula_sum 'Mg12 Mn8 Si12 O48' -_cell_volume 824.52264963 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn12 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn13 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn14 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn15 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn16 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn17 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn18 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58931000 0.89664800 0.37477500 1 - O O33 1 0.37477500 0.58931000 0.89664800 1 - O O34 1 0.28546500 0.30733800 0.91069000 1 - O O35 1 0.47812700 0.60335200 0.19266200 1 - O O36 1 0.30733800 0.89664800 0.02187300 1 - O O37 1 0.12522500 0.02187300 0.21453500 1 - O O38 1 0.37477500 0.28546500 0.47812700 1 - O O39 1 0.89664800 0.37477500 0.58931000 1 - O O40 1 0.19266200 0.21453500 0.58931000 1 - O O41 1 0.47812700 0.37477500 0.28546500 1 - O O42 1 0.89664800 0.02187300 0.30733800 1 - O O43 1 0.60335200 0.91069000 0.12522500 1 - O O44 1 0.91069000 0.12522500 0.60335200 1 - O O45 1 0.28546500 0.47812700 0.37477500 1 - O O46 1 0.58931000 0.19266200 0.21453500 1 - O O47 1 0.21453500 0.58931000 0.19266200 1 - O O48 1 0.02187300 0.30733800 0.89664800 1 - O O49 1 0.91069000 0.28546500 0.30733800 1 - O O50 1 0.02187300 0.21453500 0.12522500 1 - O O51 1 0.80733800 0.78546500 0.41069000 1 - O O52 1 0.19266200 0.47812700 0.60335200 1 - O O53 1 0.60335200 0.19266200 0.47812700 1 - O O54 1 0.21453500 0.12522500 0.02187300 1 - O O55 1 0.12522500 0.60335200 0.91069000 1 - O O56 1 0.41069000 0.10335200 0.62522500 1 - O O57 1 0.62522500 0.41069000 0.10335200 1 - O O58 1 0.71453500 0.69266200 0.08931000 1 - O O59 1 0.52187300 0.39664800 0.80733800 1 - O O60 1 0.69266200 0.10335200 0.97812700 1 - O O61 1 0.87477500 0.97812700 0.78546500 1 - O O62 1 0.62522500 0.71453500 0.52187300 1 - O O63 1 0.10335200 0.62522500 0.41069000 1 - O O64 1 0.87477500 0.39664800 0.08931000 1 - O O65 1 0.78546500 0.87477500 0.97812700 1 - O O66 1 0.39664800 0.80733800 0.52187300 1 - O O67 1 0.69266200 0.08931000 0.71453500 1 - O O68 1 0.80733800 0.52187300 0.39664800 1 - O O69 1 0.97812700 0.78546500 0.87477500 1 - O O70 1 0.08931000 0.71453500 0.69266200 1 - O O71 1 0.97812700 0.69266200 0.10335200 1 - O O72 1 0.78546500 0.41069000 0.80733800 1 - O O73 1 0.41069000 0.80733800 0.78546500 1 - O O74 1 0.71453500 0.52187300 0.62522500 1 - O O75 1 0.08931000 0.87477500 0.39664800 1 - O O76 1 0.39664800 0.08931000 0.87477500 1 - O O77 1 0.10335200 0.97812700 0.69266200 1 - O O78 1 0.52187300 0.62522500 0.71453500 1 - O O79 1 0.30733800 0.91069000 0.28546500 1 -" -Mn3V2(SiO4)3,mp-14046,Ia-3d,[27380],0.06591125143749821,{'tags': ['Trimanganese divanadium(III) silicate']},"Full Formula (Mn12 V8 Si12 O48) -Reduced Formula: Mn3V2(SiO4)3 -abc : 10.386177 10.386177 10.386177 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.875 0.625 0.25 4.673 - 1 Mn 0.625 0.25 0.875 4.673 - 2 Mn 0.875 0.75 0.625 4.673 - 3 Mn 0.75 0.625 0.875 4.673 - 4 Mn 0.25 0.875 0.625 4.673 - 5 Mn 0.625 0.875 0.75 4.673 - 6 Mn 0.125 0.375 0.75 4.673 - 7 Mn 0.375 0.75 0.125 4.673 - 8 Mn 0.125 0.25 0.375 4.673 - 9 Mn 0.25 0.375 0.125 4.673 - 10 Mn 0.75 0.125 0.375 4.673 - 11 Mn 0.375 0.125 0.25 4.673 - 12 V 0.5 0.5 0.5 1.979 - 13 V 0.5 0 0.5 1.969 - 14 V 0 0.5 0.5 1.976 - 15 V 0.5 0.5 0 1.979 - 16 V 0 0 0.5 1.976 - 17 V 0 0.5 0 1.979 - 18 V 0.5 0 0 1.97 - 19 V 0 0 0 1.979 - 20 Si 0.125 0.875 0.25 0.016 - 21 Si 0.875 0.125 0.75 0.016 - 22 Si 0.25 0.625 0.375 0.016 - 23 Si 0.375 0.25 0.625 0.016 - 24 Si 0.75 0.875 0.125 0.016 - 25 Si 0.125 0.75 0.875 0.016 - 26 Si 0.375 0.625 0.75 0.016 - 27 Si 0.625 0.75 0.375 0.016 - 28 Si 0.875 0.25 0.125 0.016 - 29 Si 0.25 0.125 0.875 0.016 - 30 Si 0.75 0.375 0.625 0.016 - 31 Si 0.625 0.375 0.25 0.016 - 32 O 0.693731 0.088063 0.709089 0.008 - 33 O 0.105668 0.984642 0.693731 0.009 - 34 O 0.709089 0.515358 0.621026 0.01 - 35 O 0.621026 0.709089 0.515358 0.009 - 36 O 0.878974 0.394332 0.088063 0.008 - 37 O 0.088063 0.878974 0.394332 0.009 - 38 O 0.984642 0.693731 0.105668 0.009 - 39 O 0.411937 0.105668 0.621026 0.008 - 40 O 0.394332 0.806269 0.515358 0.008 - 41 O 0.984642 0.790911 0.878974 0.009 - 42 O 0.105668 0.621026 0.411937 0.009 - 43 O 0.515358 0.394332 0.806269 0.009 - 44 O 0.790911 0.878974 0.984642 0.009 - 45 O 0.709089 0.693731 0.088063 0.01 - 46 O 0.088063 0.709089 0.693731 0.009 - 47 O 0.621026 0.411937 0.105668 0.009 - 48 O 0.790911 0.411937 0.806269 0.009 - 49 O 0.806269 0.515358 0.394332 0.009 - 50 O 0.806269 0.790911 0.411937 0.009 - 51 O 0.878974 0.984642 0.790911 0.008 - 52 O 0.484642 0.378974 0.290911 0.009 - 53 O 0.394332 0.088063 0.878974 0.008 - 54 O 0.693731 0.105668 0.984642 0.008 - 55 O 0.515358 0.621026 0.709089 0.009 - 56 O 0.306269 0.911937 0.290911 0.008 - 57 O 0.894332 0.015358 0.306269 0.009 - 58 O 0.290911 0.484642 0.378974 0.01 - 59 O 0.378974 0.290911 0.484642 0.009 - 60 O 0.121026 0.605668 0.911937 0.008 - 61 O 0.911937 0.121026 0.605668 0.009 - 62 O 0.015358 0.306269 0.894332 0.009 - 63 O 0.588063 0.894332 0.378974 0.008 - 64 O 0.605668 0.193731 0.484642 0.008 - 65 O 0.015358 0.209089 0.121026 0.009 - 66 O 0.894332 0.378974 0.588063 0.009 - 67 O 0.484642 0.605668 0.193731 0.009 - 68 O 0.209089 0.121026 0.015358 0.009 - 69 O 0.290911 0.306269 0.911937 0.01 - 70 O 0.911937 0.290911 0.306269 0.009 - 71 O 0.378974 0.588063 0.894332 0.009 - 72 O 0.209089 0.588063 0.193731 0.009 - 73 O 0.193731 0.484642 0.605668 0.009 - 74 O 0.193731 0.209089 0.588063 0.009 - 75 O 0.121026 0.015358 0.209089 0.008 - 76 O 0.588063 0.193731 0.209089 0.008 - 77 O 0.605668 0.911937 0.121026 0.008 - 78 O 0.306269 0.894332 0.015358 0.008 - 79 O 0.411937 0.806269 0.790911 0.008","# generated using pymatgen -data_Mn3V2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.38617685 -_cell_length_b 10.38617685 -_cell_length_c 10.38617685 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn3V2(SiO4)3 -_chemical_formula_sum 'Mn12 V8 Si12 O48' -_cell_volume 862.47248508 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn1 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn2 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn3 1 0.75000000 0.62500000 0.87500000 1 - Mn Mn4 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn5 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn6 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn7 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn8 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn9 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn10 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn11 1 0.37500000 0.12500000 0.25000000 1 - V V12 1 0.50000000 0.50000000 0.50000000 1 - V V13 1 0.50000000 0.00000000 0.50000000 1 - V V14 1 0.00000000 0.50000000 0.50000000 1 - V V15 1 0.50000000 0.50000000 0.00000000 1 - V V16 1 0.00000000 0.00000000 0.50000000 1 - V V17 1 0.00000000 0.50000000 0.00000000 1 - V V18 1 0.50000000 0.00000000 0.00000000 1 - V V19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.69373100 0.08806300 0.70908900 1 - O O33 1 0.10566800 0.98464200 0.69373100 1 - O O34 1 0.70908900 0.51535800 0.62102600 1 - O O35 1 0.62102600 0.70908900 0.51535800 1 - O O36 1 0.87897400 0.39433200 0.08806300 1 - O O37 1 0.08806300 0.87897400 0.39433200 1 - O O38 1 0.98464200 0.69373100 0.10566800 1 - O O39 1 0.41193700 0.10566800 0.62102600 1 - O O40 1 0.39433200 0.80626900 0.51535800 1 - O O41 1 0.98464200 0.79091100 0.87897400 1 - O O42 1 0.10566800 0.62102600 0.41193700 1 - O O43 1 0.51535800 0.39433200 0.80626900 1 - O O44 1 0.79091100 0.87897400 0.98464200 1 - O O45 1 0.70908900 0.69373100 0.08806300 1 - O O46 1 0.08806300 0.70908900 0.69373100 1 - O O47 1 0.62102600 0.41193700 0.10566800 1 - O O48 1 0.79091100 0.41193700 0.80626900 1 - O O49 1 0.80626900 0.51535800 0.39433200 1 - O O50 1 0.80626900 0.79091100 0.41193700 1 - O O51 1 0.87897400 0.98464200 0.79091100 1 - O O52 1 0.48464200 0.37897400 0.29091100 1 - O O53 1 0.39433200 0.08806300 0.87897400 1 - O O54 1 0.69373100 0.10566800 0.98464200 1 - O O55 1 0.51535800 0.62102600 0.70908900 1 - O O56 1 0.30626900 0.91193700 0.29091100 1 - O O57 1 0.89433200 0.01535800 0.30626900 1 - O O58 1 0.29091100 0.48464200 0.37897400 1 - O O59 1 0.37897400 0.29091100 0.48464200 1 - O O60 1 0.12102600 0.60566800 0.91193700 1 - O O61 1 0.91193700 0.12102600 0.60566800 1 - O O62 1 0.01535800 0.30626900 0.89433200 1 - O O63 1 0.58806300 0.89433200 0.37897400 1 - O O64 1 0.60566800 0.19373100 0.48464200 1 - O O65 1 0.01535800 0.20908900 0.12102600 1 - O O66 1 0.89433200 0.37897400 0.58806300 1 - O O67 1 0.48464200 0.60566800 0.19373100 1 - O O68 1 0.20908900 0.12102600 0.01535800 1 - O O69 1 0.29091100 0.30626900 0.91193700 1 - O O70 1 0.91193700 0.29091100 0.30626900 1 - O O71 1 0.37897400 0.58806300 0.89433200 1 - O O72 1 0.20908900 0.58806300 0.19373100 1 - O O73 1 0.19373100 0.48464200 0.60566800 1 - O O74 1 0.19373100 0.20908900 0.58806300 1 - O O75 1 0.12102600 0.01535800 0.20908900 1 - O O76 1 0.58806300 0.19373100 0.20908900 1 - O O77 1 0.60566800 0.91193700 0.12102600 1 - O O78 1 0.30626900 0.89433200 0.01535800 1 - O O79 1 0.41193700 0.80626900 0.79091100 1 -" -Al2Cd3(SiO4)3,mp-14047,Ia-3d,[27384],0.005691859124997478,{'tags': ['Tricadmium dialuminium silicate']},"Full Formula (Al8 Cd12 Si12 O48) -Reduced Formula: Al2Cd3(SiO4)3 -abc : 10.369946 10.369946 10.369946 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0.5 0.5 0 0 - 1 Al 0 0.5 0.5 0 - 2 Al 0.5 0.5 0.5 0 - 3 Al 0 0 0.5 0 - 4 Al 0 0.5 0 0 - 5 Al 0.5 0 0 0 - 6 Al 0 0 0 0 - 7 Al 0.5 0 0.5 0 - 8 Cd 0.875 0.625 0.25 -0 - 9 Cd 0.625 0.25 0.875 -0 - 10 Cd 0.875 0.75 0.625 -0 - 11 Cd 0.75 0.625 0.875 -0 - 12 Cd 0.25 0.875 0.625 -0 - 13 Cd 0.625 0.875 0.75 -0 - 14 Cd 0.125 0.375 0.75 -0 - 15 Cd 0.375 0.75 0.125 -0 - 16 Cd 0.125 0.25 0.375 -0 - 17 Cd 0.25 0.375 0.125 -0 - 18 Cd 0.75 0.125 0.375 -0 - 19 Cd 0.375 0.125 0.25 -0 - 20 Si 0.875 0.25 0.125 0 - 21 Si 0.625 0.75 0.375 0 - 22 Si 0.75 0.375 0.625 0 - 23 Si 0.625 0.375 0.25 0 - 24 Si 0.375 0.625 0.75 0 - 25 Si 0.125 0.75 0.875 0 - 26 Si 0.75 0.875 0.125 0 - 27 Si 0.375 0.25 0.625 0 - 28 Si 0.25 0.625 0.375 0 - 29 Si 0.875 0.125 0.75 0 - 30 Si 0.25 0.125 0.875 0 - 31 Si 0.125 0.875 0.25 0 - 32 O 0.688737 0.081548 0.694528 -0 - 33 O 0.107189 0.994209 0.688737 -0 - 34 O 0.694528 0.505791 0.61298 -0 - 35 O 0.61298 0.694528 0.505791 -0 - 36 O 0.88702 0.392811 0.081548 -0 - 37 O 0.081548 0.88702 0.392811 -0 - 38 O 0.994209 0.688737 0.107189 -0 - 39 O 0.418452 0.107189 0.61298 -0 - 40 O 0.392811 0.811263 0.505791 -0 - 41 O 0.994209 0.805472 0.88702 -0 - 42 O 0.107189 0.61298 0.418452 -0 - 43 O 0.505791 0.392811 0.811263 -0 - 44 O 0.805472 0.88702 0.994209 -0 - 45 O 0.694528 0.688737 0.081548 -0 - 46 O 0.081548 0.694528 0.688737 -0 - 47 O 0.61298 0.418452 0.107189 -0 - 48 O 0.805472 0.418452 0.811263 -0 - 49 O 0.811263 0.505791 0.392811 -0 - 50 O 0.811263 0.805472 0.418452 -0 - 51 O 0.88702 0.994209 0.805472 -0 - 52 O 0.418452 0.811263 0.805472 -0 - 53 O 0.392811 0.081548 0.88702 -0 - 54 O 0.688737 0.107189 0.994209 -0 - 55 O 0.505791 0.61298 0.694528 -0 - 56 O 0.311263 0.918452 0.305472 -0 - 57 O 0.892811 0.005791 0.311263 -0 - 58 O 0.305472 0.494209 0.38702 -0 - 59 O 0.38702 0.305472 0.494209 -0 - 60 O 0.11298 0.607189 0.918452 -0 - 61 O 0.918452 0.11298 0.607189 -0 - 62 O 0.005791 0.311263 0.892811 -0 - 63 O 0.581548 0.892811 0.38702 -0 - 64 O 0.607189 0.188737 0.494209 -0 - 65 O 0.005791 0.194528 0.11298 -0 - 66 O 0.892811 0.38702 0.581548 -0 - 67 O 0.494209 0.607189 0.188737 -0 - 68 O 0.194528 0.11298 0.005791 -0 - 69 O 0.305472 0.311263 0.918452 -0 - 70 O 0.918452 0.305472 0.311263 -0 - 71 O 0.38702 0.581548 0.892811 -0 - 72 O 0.194528 0.581548 0.188737 -0 - 73 O 0.188737 0.494209 0.607189 -0 - 74 O 0.188737 0.194528 0.581548 -0 - 75 O 0.11298 0.005791 0.194528 -0 - 76 O 0.581548 0.188737 0.194528 -0 - 77 O 0.607189 0.918452 0.11298 -0 - 78 O 0.311263 0.892811 0.005791 -0 - 79 O 0.494209 0.38702 0.305472 -0","# generated using pymatgen -data_Al2Cd3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.36994580 -_cell_length_b 10.36994580 -_cell_length_c 10.36994580 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Cd3(SiO4)3 -_chemical_formula_sum 'Al8 Cd12 Si12 O48' -_cell_volume 858.43530164 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.50000000 0.50000000 0.00000000 1 - Al Al1 1 0.00000000 0.50000000 0.50000000 1 - Al Al2 1 0.50000000 0.50000000 0.50000000 1 - Al Al3 1 0.00000000 0.00000000 0.50000000 1 - Al Al4 1 0.00000000 0.50000000 0.00000000 1 - Al Al5 1 0.50000000 0.00000000 0.00000000 1 - Al Al6 1 0.00000000 0.00000000 0.00000000 1 - Al Al7 1 0.50000000 0.00000000 0.50000000 1 - Cd Cd8 1 0.87500000 0.62500000 0.25000000 1 - Cd Cd9 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd10 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd11 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd12 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd13 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd14 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd15 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd16 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd17 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd18 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.87500000 0.25000000 0.12500000 1 - Si Si21 1 0.62500000 0.75000000 0.37500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.37500000 0.62500000 0.75000000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.75000000 0.87500000 0.12500000 1 - Si Si27 1 0.37500000 0.25000000 0.62500000 1 - Si Si28 1 0.25000000 0.62500000 0.37500000 1 - Si Si29 1 0.87500000 0.12500000 0.75000000 1 - Si Si30 1 0.25000000 0.12500000 0.87500000 1 - Si Si31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.68873700 0.08154800 0.69452800 1 - O O33 1 0.10718900 0.99420900 0.68873700 1 - O O34 1 0.69452800 0.50579100 0.61298000 1 - O O35 1 0.61298000 0.69452800 0.50579100 1 - O O36 1 0.88702000 0.39281100 0.08154800 1 - O O37 1 0.08154800 0.88702000 0.39281100 1 - O O38 1 0.99420900 0.68873700 0.10718900 1 - O O39 1 0.41845200 0.10718900 0.61298000 1 - O O40 1 0.39281100 0.81126300 0.50579100 1 - O O41 1 0.99420900 0.80547200 0.88702000 1 - O O42 1 0.10718900 0.61298000 0.41845200 1 - O O43 1 0.50579100 0.39281100 0.81126300 1 - O O44 1 0.80547200 0.88702000 0.99420900 1 - O O45 1 0.69452800 0.68873700 0.08154800 1 - O O46 1 0.08154800 0.69452800 0.68873700 1 - O O47 1 0.61298000 0.41845200 0.10718900 1 - O O48 1 0.80547200 0.41845200 0.81126300 1 - O O49 1 0.81126300 0.50579100 0.39281100 1 - O O50 1 0.81126300 0.80547200 0.41845200 1 - O O51 1 0.88702000 0.99420900 0.80547200 1 - O O52 1 0.41845200 0.81126300 0.80547200 1 - O O53 1 0.39281100 0.08154800 0.88702000 1 - O O54 1 0.68873700 0.10718900 0.99420900 1 - O O55 1 0.50579100 0.61298000 0.69452800 1 - O O56 1 0.31126300 0.91845200 0.30547200 1 - O O57 1 0.89281100 0.00579100 0.31126300 1 - O O58 1 0.30547200 0.49420900 0.38702000 1 - O O59 1 0.38702000 0.30547200 0.49420900 1 - O O60 1 0.11298000 0.60718900 0.91845200 1 - O O61 1 0.91845200 0.11298000 0.60718900 1 - O O62 1 0.00579100 0.31126300 0.89281100 1 - O O63 1 0.58154800 0.89281100 0.38702000 1 - O O64 1 0.60718900 0.18873700 0.49420900 1 - O O65 1 0.00579100 0.19452800 0.11298000 1 - O O66 1 0.89281100 0.38702000 0.58154800 1 - O O67 1 0.49420900 0.60718900 0.18873700 1 - O O68 1 0.19452800 0.11298000 0.00579100 1 - O O69 1 0.30547200 0.31126300 0.91845200 1 - O O70 1 0.91845200 0.30547200 0.31126300 1 - O O71 1 0.38702000 0.58154800 0.89281100 1 - O O72 1 0.19452800 0.58154800 0.18873700 1 - O O73 1 0.18873700 0.49420900 0.60718900 1 - O O74 1 0.18873700 0.19452800 0.58154800 1 - O O75 1 0.11298000 0.00579100 0.19452800 1 - O O76 1 0.58154800 0.18873700 0.19452800 1 - O O77 1 0.60718900 0.91845200 0.11298000 1 - O O78 1 0.31126300 0.89281100 0.00579100 1 - O O79 1 0.49420900 0.38702000 0.30547200 1 -" -Sr3Al2(SiO4)3,mp-14048,Ia-3d,[27385],0.10492533337500021,{'tags': ['Tristrontium dialuminium silicate']},"Full Formula (Sr12 Al8 Si12 O48) -Reduced Formula: Sr3Al2(SiO4)3 -abc : 10.631136 10.631136 10.631136 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sr 0.875 0.75 0.625 -0 - 1 Sr 0.875 0.625 0.25 -0 - 2 Sr 0.625 0.875 0.75 -0 - 3 Sr 0.25 0.875 0.625 -0 - 4 Sr 0.75 0.625 0.875 -0 - 5 Sr 0.625 0.25 0.875 -0 - 6 Sr 0.125 0.25 0.375 -0 - 7 Sr 0.125 0.375 0.75 -0 - 8 Sr 0.375 0.125 0.25 -0 - 9 Sr 0.75 0.125 0.375 -0 - 10 Sr 0.25 0.375 0.125 -0 - 11 Sr 0.375 0.75 0.125 -0 - 12 Al 0 0 0.5 0 - 13 Al 0.5 0.5 0.5 0 - 14 Al 0.5 0 0.5 0 - 15 Al 0 0 0 0 - 16 Al 0 0.5 0.5 0 - 17 Al 0.5 0.5 0 0 - 18 Al 0.5 0 0 0 - 19 Al 0 0.5 0 0 - 20 Si 0.625 0.375 0.25 -0 - 21 Si 0.875 0.125 0.75 -0 - 22 Si 0.25 0.625 0.375 -0 - 23 Si 0.625 0.75 0.375 -0 - 24 Si 0.375 0.25 0.625 -0 - 25 Si 0.375 0.625 0.75 -0 - 26 Si 0.25 0.125 0.875 -0 - 27 Si 0.125 0.875 0.25 -0 - 28 Si 0.75 0.375 0.625 -0 - 29 Si 0.875 0.25 0.125 -0 - 30 Si 0.75 0.875 0.125 -0 - 31 Si 0.125 0.75 0.875 -0 - 32 O 0.891651 0.390677 0.082511 -0 - 33 O 0.80914 0.891651 0.000974 -0 - 34 O 0.390677 0.808166 0.499026 -0 - 35 O 0.691834 0.082511 0.69086 -0 - 36 O 0.808166 0.499026 0.390677 -0 - 37 O 0.000974 0.80914 0.891651 -0 - 38 O 0.082511 0.69086 0.691834 -0 - 39 O 0.000974 0.691834 0.109323 -0 - 40 O 0.80914 0.417489 0.808166 -0 - 41 O 0.417489 0.808166 0.80914 -0 - 42 O 0.69086 0.499026 0.608349 -0 - 43 O 0.082511 0.891651 0.390677 -0 - 44 O 0.390677 0.082511 0.891651 -0 - 45 O 0.109323 0.000974 0.691834 -0 - 46 O 0.499026 0.608349 0.69086 -0 - 47 O 0.808166 0.80914 0.417489 -0 - 48 O 0.109323 0.608349 0.417489 -0 - 49 O 0.608349 0.69086 0.499026 -0 - 50 O 0.891651 0.000974 0.80914 -0 - 51 O 0.691834 0.109323 0.000974 -0 - 52 O 0.499026 0.390677 0.808166 -0 - 53 O 0.69086 0.691834 0.082511 -0 - 54 O 0.608349 0.417489 0.109323 -0 - 55 O 0.417489 0.109323 0.608349 -0 - 56 O 0.108349 0.609323 0.917489 -0 - 57 O 0.19086 0.108349 0.999026 -0 - 58 O 0.609323 0.191834 0.500974 -0 - 59 O 0.308166 0.917489 0.30914 -0 - 60 O 0.191834 0.500974 0.609323 -0 - 61 O 0.999026 0.19086 0.108349 -0 - 62 O 0.917489 0.30914 0.308166 -0 - 63 O 0.999026 0.308166 0.890677 -0 - 64 O 0.19086 0.582511 0.191834 -0 - 65 O 0.582511 0.191834 0.19086 -0 - 66 O 0.30914 0.500974 0.391651 -0 - 67 O 0.917489 0.108349 0.609323 -0 - 68 O 0.609323 0.917489 0.108349 -0 - 69 O 0.890677 0.999026 0.308166 -0 - 70 O 0.500974 0.391651 0.30914 -0 - 71 O 0.191834 0.19086 0.582511 -0 - 72 O 0.890677 0.391651 0.582511 -0 - 73 O 0.391651 0.30914 0.500974 -0 - 74 O 0.108349 0.999026 0.19086 -0 - 75 O 0.308166 0.890677 0.999026 -0 - 76 O 0.500974 0.609323 0.191834 -0 - 77 O 0.30914 0.308166 0.917489 -0 - 78 O 0.391651 0.582511 0.890677 -0 - 79 O 0.582511 0.890677 0.391651 -0","# generated using pymatgen -data_Sr3Al2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.63113560 -_cell_length_b 10.63113560 -_cell_length_c 10.63113560 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sr3Al2(SiO4)3 -_chemical_formula_sum 'Sr12 Al8 Si12 O48' -_cell_volume 924.94749804 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sr Sr0 1 0.87500000 0.75000000 0.62500000 1 - Sr Sr1 1 0.87500000 0.62500000 0.25000000 1 - Sr Sr2 1 0.62500000 0.87500000 0.75000000 1 - Sr Sr3 1 0.25000000 0.87500000 0.62500000 1 - Sr Sr4 1 0.75000000 0.62500000 0.87500000 1 - Sr Sr5 1 0.62500000 0.25000000 0.87500000 1 - Sr Sr6 1 0.12500000 0.25000000 0.37500000 1 - Sr Sr7 1 0.12500000 0.37500000 0.75000000 1 - Sr Sr8 1 0.37500000 0.12500000 0.25000000 1 - Sr Sr9 1 0.75000000 0.12500000 0.37500000 1 - Sr Sr10 1 0.25000000 0.37500000 0.12500000 1 - Sr Sr11 1 0.37500000 0.75000000 0.12500000 1 - Al Al12 1 0.00000000 0.00000000 0.50000000 1 - Al Al13 1 0.50000000 0.50000000 0.50000000 1 - Al Al14 1 0.50000000 0.00000000 0.50000000 1 - Al Al15 1 0.00000000 0.00000000 0.00000000 1 - Al Al16 1 0.00000000 0.50000000 0.50000000 1 - Al Al17 1 0.50000000 0.50000000 0.00000000 1 - Al Al18 1 0.50000000 0.00000000 0.00000000 1 - Al Al19 1 0.00000000 0.50000000 0.00000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.37500000 0.25000000 0.62500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.25000000 0.12500000 0.87500000 1 - Si Si27 1 0.12500000 0.87500000 0.25000000 1 - Si Si28 1 0.75000000 0.37500000 0.62500000 1 - Si Si29 1 0.87500000 0.25000000 0.12500000 1 - Si Si30 1 0.75000000 0.87500000 0.12500000 1 - Si Si31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.89165100 0.39067700 0.08251100 1 - O O33 1 0.80914000 0.89165100 0.00097400 1 - O O34 1 0.39067700 0.80816600 0.49902600 1 - O O35 1 0.69183400 0.08251100 0.69086000 1 - O O36 1 0.80816600 0.49902600 0.39067700 1 - O O37 1 0.00097400 0.80914000 0.89165100 1 - O O38 1 0.08251100 0.69086000 0.69183400 1 - O O39 1 0.00097400 0.69183400 0.10932300 1 - O O40 1 0.80914000 0.41748900 0.80816600 1 - O O41 1 0.41748900 0.80816600 0.80914000 1 - O O42 1 0.69086000 0.49902600 0.60834900 1 - O O43 1 0.08251100 0.89165100 0.39067700 1 - O O44 1 0.39067700 0.08251100 0.89165100 1 - O O45 1 0.10932300 0.00097400 0.69183400 1 - O O46 1 0.49902600 0.60834900 0.69086000 1 - O O47 1 0.80816600 0.80914000 0.41748900 1 - O O48 1 0.10932300 0.60834900 0.41748900 1 - O O49 1 0.60834900 0.69086000 0.49902600 1 - O O50 1 0.89165100 0.00097400 0.80914000 1 - O O51 1 0.69183400 0.10932300 0.00097400 1 - O O52 1 0.49902600 0.39067700 0.80816600 1 - O O53 1 0.69086000 0.69183400 0.08251100 1 - O O54 1 0.60834900 0.41748900 0.10932300 1 - O O55 1 0.41748900 0.10932300 0.60834900 1 - O O56 1 0.10834900 0.60932300 0.91748900 1 - O O57 1 0.19086000 0.10834900 0.99902600 1 - O O58 1 0.60932300 0.19183400 0.50097400 1 - O O59 1 0.30816600 0.91748900 0.30914000 1 - O O60 1 0.19183400 0.50097400 0.60932300 1 - O O61 1 0.99902600 0.19086000 0.10834900 1 - O O62 1 0.91748900 0.30914000 0.30816600 1 - O O63 1 0.99902600 0.30816600 0.89067700 1 - O O64 1 0.19086000 0.58251100 0.19183400 1 - O O65 1 0.58251100 0.19183400 0.19086000 1 - O O66 1 0.30914000 0.50097400 0.39165100 1 - O O67 1 0.91748900 0.10834900 0.60932300 1 - O O68 1 0.60932300 0.91748900 0.10834900 1 - O O69 1 0.89067700 0.99902600 0.30816600 1 - O O70 1 0.50097400 0.39165100 0.30914000 1 - O O71 1 0.19183400 0.19086000 0.58251100 1 - O O72 1 0.89067700 0.39165100 0.58251100 1 - O O73 1 0.39165100 0.30914000 0.50097400 1 - O O74 1 0.10834900 0.99902600 0.19086000 1 - O O75 1 0.30816600 0.89067700 0.99902600 1 - O O76 1 0.50097400 0.60932300 0.19183400 1 - O O77 1 0.30914000 0.30816600 0.91748900 1 - O O78 1 0.39165100 0.58251100 0.89067700 1 - O O79 1 0.58251100 0.89067700 0.39165100 1 -" -Ba3Al2(SiO4)3,mp-14049,Ia-3d,[27386],0.2723653661875032,{'tags': ['Tribarium dialuminium silicate']},"Full Formula (Ba12 Al8 Si12 O48) -Reduced Formula: Ba3Al2(SiO4)3 -abc : 10.974504 10.974504 10.974504 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ba 0.875 0.625 0.25 0 - 1 Ba 0.625 0.25 0.875 0 - 2 Ba 0.875 0.75 0.625 0 - 3 Ba 0.75 0.625 0.875 0 - 4 Ba 0.25 0.875 0.625 0 - 5 Ba 0.625 0.875 0.75 0 - 6 Ba 0.125 0.375 0.75 0 - 7 Ba 0.375 0.75 0.125 0 - 8 Ba 0.125 0.25 0.375 0 - 9 Ba 0.25 0.375 0.125 0 - 10 Ba 0.75 0.125 0.375 0 - 11 Ba 0.375 0.125 0.25 0 - 12 Al 0.5 0.5 0 0 - 13 Al 0 0.5 0.5 0 - 14 Al 0.5 0.5 0.5 0 - 15 Al 0 0 0.5 0 - 16 Al 0 0.5 0 0 - 17 Al 0.5 0 0 0 - 18 Al 0 0 0 0 - 19 Al 0.5 0 0.5 0 - 20 Si 0.875 0.25 0.125 0 - 21 Si 0.625 0.75 0.375 0 - 22 Si 0.75 0.375 0.625 0 - 23 Si 0.625 0.375 0.25 0 - 24 Si 0.375 0.625 0.75 0 - 25 Si 0.125 0.75 0.875 0 - 26 Si 0.75 0.875 0.125 0 - 27 Si 0.375 0.25 0.625 0 - 28 Si 0.25 0.625 0.375 0 - 29 Si 0.875 0.125 0.75 0 - 30 Si 0.25 0.125 0.875 0 - 31 Si 0.125 0.875 0.25 0 - 32 O 0.695386 0.081932 0.68447 -0 - 33 O 0.113455 0.010916 0.695386 -0 - 34 O 0.68447 0.489084 0.602539 -0 - 35 O 0.602539 0.68447 0.489084 -0 - 36 O 0.897461 0.386545 0.081932 -0 - 37 O 0.081932 0.897461 0.386545 -0 - 38 O 0.010916 0.695386 0.113455 -0 - 39 O 0.418068 0.113455 0.602539 -0 - 40 O 0.386545 0.804614 0.489084 -0 - 41 O 0.010916 0.81553 0.897461 -0 - 42 O 0.113455 0.602539 0.418068 -0 - 43 O 0.489084 0.386545 0.804614 -0 - 44 O 0.81553 0.897461 0.010916 -0 - 45 O 0.68447 0.695386 0.081932 -0 - 46 O 0.081932 0.68447 0.695386 -0 - 47 O 0.602539 0.418068 0.113455 -0 - 48 O 0.81553 0.418068 0.804614 -0 - 49 O 0.804614 0.489084 0.386545 -0 - 50 O 0.804614 0.81553 0.418068 -0 - 51 O 0.897461 0.010916 0.81553 -0 - 52 O 0.418068 0.804614 0.81553 -0 - 53 O 0.386545 0.081932 0.897461 -0 - 54 O 0.695386 0.113455 0.010916 -0 - 55 O 0.489084 0.602539 0.68447 -0 - 56 O 0.304614 0.918068 0.31553 -0 - 57 O 0.886545 0.989084 0.304614 -0 - 58 O 0.31553 0.510916 0.397461 -0 - 59 O 0.397461 0.31553 0.510916 -0 - 60 O 0.102539 0.613455 0.918068 -0 - 61 O 0.918068 0.102539 0.613455 -0 - 62 O 0.989084 0.304614 0.886545 -0 - 63 O 0.581932 0.886545 0.397461 -0 - 64 O 0.613455 0.195386 0.510916 -0 - 65 O 0.989084 0.18447 0.102539 -0 - 66 O 0.886545 0.397461 0.581932 -0 - 67 O 0.510916 0.613455 0.195386 -0 - 68 O 0.18447 0.102539 0.989084 -0 - 69 O 0.31553 0.304614 0.918068 -0 - 70 O 0.918068 0.31553 0.304614 -0 - 71 O 0.397461 0.581932 0.886545 -0 - 72 O 0.18447 0.581932 0.195386 -0 - 73 O 0.195386 0.510916 0.613455 -0 - 74 O 0.195386 0.18447 0.581932 -0 - 75 O 0.102539 0.989084 0.18447 -0 - 76 O 0.581932 0.195386 0.18447 -0 - 77 O 0.613455 0.918068 0.102539 -0 - 78 O 0.304614 0.886545 0.989084 -0 - 79 O 0.510916 0.397461 0.31553 -0","# generated using pymatgen -data_Ba3Al2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.97450428 -_cell_length_b 10.97450428 -_cell_length_c 10.97450428 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ba3Al2(SiO4)3 -_chemical_formula_sum 'Ba12 Al8 Si12 O48' -_cell_volume 1017.49631682 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ba Ba0 1 0.87500000 0.62500000 0.25000000 1 - Ba Ba1 1 0.62500000 0.25000000 0.87500000 1 - Ba Ba2 1 0.87500000 0.75000000 0.62500000 1 - Ba Ba3 1 0.75000000 0.62500000 0.87500000 1 - Ba Ba4 1 0.25000000 0.87500000 0.62500000 1 - Ba Ba5 1 0.62500000 0.87500000 0.75000000 1 - Ba Ba6 1 0.12500000 0.37500000 0.75000000 1 - Ba Ba7 1 0.37500000 0.75000000 0.12500000 1 - Ba Ba8 1 0.12500000 0.25000000 0.37500000 1 - Ba Ba9 1 0.25000000 0.37500000 0.12500000 1 - Ba Ba10 1 0.75000000 0.12500000 0.37500000 1 - Ba Ba11 1 0.37500000 0.12500000 0.25000000 1 - Al Al12 1 0.50000000 0.50000000 0.00000000 1 - Al Al13 1 0.00000000 0.50000000 0.50000000 1 - Al Al14 1 0.50000000 0.50000000 0.50000000 1 - Al Al15 1 0.00000000 0.00000000 0.50000000 1 - Al Al16 1 0.00000000 0.50000000 0.00000000 1 - Al Al17 1 0.50000000 0.00000000 0.00000000 1 - Al Al18 1 0.00000000 0.00000000 0.00000000 1 - Al Al19 1 0.50000000 0.00000000 0.50000000 1 - Si Si20 1 0.87500000 0.25000000 0.12500000 1 - Si Si21 1 0.62500000 0.75000000 0.37500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.37500000 0.62500000 0.75000000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.75000000 0.87500000 0.12500000 1 - Si Si27 1 0.37500000 0.25000000 0.62500000 1 - Si Si28 1 0.25000000 0.62500000 0.37500000 1 - Si Si29 1 0.87500000 0.12500000 0.75000000 1 - Si Si30 1 0.25000000 0.12500000 0.87500000 1 - Si Si31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.69538600 0.08193200 0.68447000 1 - O O33 1 0.11345500 0.01091600 0.69538600 1 - O O34 1 0.68447000 0.48908400 0.60253900 1 - O O35 1 0.60253900 0.68447000 0.48908400 1 - O O36 1 0.89746100 0.38654500 0.08193200 1 - O O37 1 0.08193200 0.89746100 0.38654500 1 - O O38 1 0.01091600 0.69538600 0.11345500 1 - O O39 1 0.41806800 0.11345500 0.60253900 1 - O O40 1 0.38654500 0.80461400 0.48908400 1 - O O41 1 0.01091600 0.81553000 0.89746100 1 - O O42 1 0.11345500 0.60253900 0.41806800 1 - O O43 1 0.48908400 0.38654500 0.80461400 1 - O O44 1 0.81553000 0.89746100 0.01091600 1 - O O45 1 0.68447000 0.69538600 0.08193200 1 - O O46 1 0.08193200 0.68447000 0.69538600 1 - O O47 1 0.60253900 0.41806800 0.11345500 1 - O O48 1 0.81553000 0.41806800 0.80461400 1 - O O49 1 0.80461400 0.48908400 0.38654500 1 - O O50 1 0.80461400 0.81553000 0.41806800 1 - O O51 1 0.89746100 0.01091600 0.81553000 1 - O O52 1 0.41806800 0.80461400 0.81553000 1 - O O53 1 0.38654500 0.08193200 0.89746100 1 - O O54 1 0.69538600 0.11345500 0.01091600 1 - O O55 1 0.48908400 0.60253900 0.68447000 1 - O O56 1 0.30461400 0.91806800 0.31553000 1 - O O57 1 0.88654500 0.98908400 0.30461400 1 - O O58 1 0.31553000 0.51091600 0.39746100 1 - O O59 1 0.39746100 0.31553000 0.51091600 1 - O O60 1 0.10253900 0.61345500 0.91806800 1 - O O61 1 0.91806800 0.10253900 0.61345500 1 - O O62 1 0.98908400 0.30461400 0.88654500 1 - O O63 1 0.58193200 0.88654500 0.39746100 1 - O O64 1 0.61345500 0.19538600 0.51091600 1 - O O65 1 0.98908400 0.18447000 0.10253900 1 - O O66 1 0.88654500 0.39746100 0.58193200 1 - O O67 1 0.51091600 0.61345500 0.19538600 1 - O O68 1 0.18447000 0.10253900 0.98908400 1 - O O69 1 0.31553000 0.30461400 0.91806800 1 - O O70 1 0.91806800 0.31553000 0.30461400 1 - O O71 1 0.39746100 0.58193200 0.88654500 1 - O O72 1 0.18447000 0.58193200 0.19538600 1 - O O73 1 0.19538600 0.51091600 0.61345500 1 - O O74 1 0.19538600 0.18447000 0.58193200 1 - O O75 1 0.10253900 0.98908400 0.18447000 1 - O O76 1 0.58193200 0.19538600 0.18447000 1 - O O77 1 0.61345500 0.91806800 0.10253900 1 - O O78 1 0.30461400 0.88654500 0.98908400 1 - O O79 1 0.51091600 0.39746100 0.31553000 1 -" -Ca3Ga2(SiO4)3,mp-14050,Ia-3d,[27387],0.01178560237500026,{'tags': ['Tricalcium digallium silicate']},"Full Formula (Ca12 Ga8 Si12 O48) -Reduced Formula: Ca3Ga2(SiO4)3 -abc : 10.500729 10.500729 10.500729 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.625 0.25 0.875 0 - 1 Ca 0.875 0.75 0.625 0 - 2 Ca 0.75 0.625 0.875 0 - 3 Ca 0.25 0.875 0.625 0 - 4 Ca 0.625 0.875 0.75 0 - 5 Ca 0.125 0.375 0.75 0 - 6 Ca 0.375 0.75 0.125 0 - 7 Ca 0.125 0.25 0.375 0 - 8 Ca 0.25 0.375 0.125 0 - 9 Ca 0.75 0.125 0.375 0 - 10 Ca 0.875 0.625 0.25 0 - 11 Ca 0.375 0.125 0.25 0 - 12 Ga 0.5 0.5 0.5 0 - 13 Ga 0.5 0 0.5 0 - 14 Ga 0 0.5 0.5 0 - 15 Ga 0 0 0.5 0 - 16 Ga 0 0.5 0 0 - 17 Ga 0.5 0 0 0 - 18 Ga 0 0 0 0 - 19 Ga 0.5 0.5 0 0 - 20 Si 0.125 0.875 0.25 0 - 21 Si 0.75 0.375 0.625 0 - 22 Si 0.625 0.375 0.25 0 - 23 Si 0.625 0.75 0.375 0 - 24 Si 0.375 0.625 0.75 0 - 25 Si 0.125 0.75 0.875 0 - 26 Si 0.875 0.25 0.125 0 - 27 Si 0.75 0.875 0.125 0 - 28 Si 0.375 0.25 0.625 0 - 29 Si 0.25 0.625 0.375 0 - 30 Si 0.875 0.125 0.75 0 - 31 Si 0.25 0.125 0.875 0 - 32 O 0.693181 0.086213 0.702294 -0 - 33 O 0.106968 0.990887 0.693181 -0 - 34 O 0.702294 0.509113 0.616081 -0 - 35 O 0.616081 0.702294 0.509113 -0 - 36 O 0.883919 0.393032 0.086213 -0 - 37 O 0.086213 0.883919 0.393032 -0 - 38 O 0.990887 0.693181 0.106968 -0 - 39 O 0.413787 0.106968 0.616081 -0 - 40 O 0.393032 0.806819 0.509113 -0 - 41 O 0.990887 0.797706 0.883919 -0 - 42 O 0.106968 0.616081 0.413787 -0 - 43 O 0.509113 0.393032 0.806819 -0 - 44 O 0.797706 0.883919 0.990887 -0 - 45 O 0.702294 0.693181 0.086213 -0 - 46 O 0.086213 0.702294 0.693181 -0 - 47 O 0.616081 0.413787 0.106968 -0 - 48 O 0.797706 0.413787 0.806819 -0 - 49 O 0.806819 0.509113 0.393032 -0 - 50 O 0.806819 0.797706 0.413787 -0 - 51 O 0.883919 0.990887 0.797706 -0 - 52 O 0.413787 0.806819 0.797706 -0 - 53 O 0.393032 0.086213 0.883919 -0 - 54 O 0.693181 0.106968 0.990887 -0 - 55 O 0.509113 0.616081 0.702294 -0 - 56 O 0.306819 0.913787 0.297706 -0 - 57 O 0.893032 0.009113 0.306819 -0 - 58 O 0.297706 0.490887 0.383919 -0 - 59 O 0.383919 0.297706 0.490887 -0 - 60 O 0.116081 0.606968 0.913787 -0 - 61 O 0.913787 0.116081 0.606968 -0 - 62 O 0.009113 0.306819 0.893032 -0 - 63 O 0.586213 0.893032 0.383919 -0 - 64 O 0.606968 0.193181 0.490887 -0 - 65 O 0.009113 0.202294 0.116081 -0 - 66 O 0.893032 0.383919 0.586213 -0 - 67 O 0.490887 0.606968 0.193181 -0 - 68 O 0.202294 0.116081 0.009113 -0 - 69 O 0.297706 0.306819 0.913787 -0 - 70 O 0.913787 0.297706 0.306819 -0 - 71 O 0.383919 0.586213 0.893032 -0 - 72 O 0.202294 0.586213 0.193181 -0 - 73 O 0.193181 0.490887 0.606968 -0 - 74 O 0.193181 0.202294 0.586213 -0 - 75 O 0.116081 0.009113 0.202294 -0 - 76 O 0.586213 0.193181 0.202294 -0 - 77 O 0.606968 0.913787 0.116081 -0 - 78 O 0.306819 0.893032 0.009113 -0 - 79 O 0.490887 0.383919 0.297706 -0","# generated using pymatgen -data_Ca3Ga2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.50072949 -_cell_length_b 10.50072949 -_cell_length_c 10.50072949 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ga2(SiO4)3 -_chemical_formula_sum 'Ca12 Ga8 Si12 O48' -_cell_volume 891.32589092 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca1 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca2 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca3 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca4 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca5 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca6 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca7 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca8 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca9 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca10 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca11 1 0.37500000 0.12500000 0.25000000 1 - Ga Ga12 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga13 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga14 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga15 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga16 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga18 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga19 1 0.50000000 0.50000000 0.00000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.75000000 0.37500000 0.62500000 1 - Si Si22 1 0.62500000 0.37500000 0.25000000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.37500000 0.62500000 0.75000000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.87500000 0.25000000 0.12500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.37500000 0.25000000 0.62500000 1 - Si Si29 1 0.25000000 0.62500000 0.37500000 1 - Si Si30 1 0.87500000 0.12500000 0.75000000 1 - Si Si31 1 0.25000000 0.12500000 0.87500000 1 - O O32 1 0.69318100 0.08621300 0.70229400 1 - O O33 1 0.10696800 0.99088700 0.69318100 1 - O O34 1 0.70229400 0.50911300 0.61608100 1 - O O35 1 0.61608100 0.70229400 0.50911300 1 - O O36 1 0.88391900 0.39303200 0.08621300 1 - O O37 1 0.08621300 0.88391900 0.39303200 1 - O O38 1 0.99088700 0.69318100 0.10696800 1 - O O39 1 0.41378700 0.10696800 0.61608100 1 - O O40 1 0.39303200 0.80681900 0.50911300 1 - O O41 1 0.99088700 0.79770600 0.88391900 1 - O O42 1 0.10696800 0.61608100 0.41378700 1 - O O43 1 0.50911300 0.39303200 0.80681900 1 - O O44 1 0.79770600 0.88391900 0.99088700 1 - O O45 1 0.70229400 0.69318100 0.08621300 1 - O O46 1 0.08621300 0.70229400 0.69318100 1 - O O47 1 0.61608100 0.41378700 0.10696800 1 - O O48 1 0.79770600 0.41378700 0.80681900 1 - O O49 1 0.80681900 0.50911300 0.39303200 1 - O O50 1 0.80681900 0.79770600 0.41378700 1 - O O51 1 0.88391900 0.99088700 0.79770600 1 - O O52 1 0.41378700 0.80681900 0.79770600 1 - O O53 1 0.39303200 0.08621300 0.88391900 1 - O O54 1 0.69318100 0.10696800 0.99088700 1 - O O55 1 0.50911300 0.61608100 0.70229400 1 - O O56 1 0.30681900 0.91378700 0.29770600 1 - O O57 1 0.89303200 0.00911300 0.30681900 1 - O O58 1 0.29770600 0.49088700 0.38391900 1 - O O59 1 0.38391900 0.29770600 0.49088700 1 - O O60 1 0.11608100 0.60696800 0.91378700 1 - O O61 1 0.91378700 0.11608100 0.60696800 1 - O O62 1 0.00911300 0.30681900 0.89303200 1 - O O63 1 0.58621300 0.89303200 0.38391900 1 - O O64 1 0.60696800 0.19318100 0.49088700 1 - O O65 1 0.00911300 0.20229400 0.11608100 1 - O O66 1 0.89303200 0.38391900 0.58621300 1 - O O67 1 0.49088700 0.60696800 0.19318100 1 - O O68 1 0.20229400 0.11608100 0.00911300 1 - O O69 1 0.29770600 0.30681900 0.91378700 1 - O O70 1 0.91378700 0.29770600 0.30681900 1 - O O71 1 0.38391900 0.58621300 0.89303200 1 - O O72 1 0.20229400 0.58621300 0.19318100 1 - O O73 1 0.19318100 0.49088700 0.60696800 1 - O O74 1 0.19318100 0.20229400 0.58621300 1 - O O75 1 0.11608100 0.00911300 0.20229400 1 - O O76 1 0.58621300 0.19318100 0.20229400 1 - O O77 1 0.60696800 0.91378700 0.11608100 1 - O O78 1 0.30681900 0.89303200 0.00911300 1 - O O79 1 0.49088700 0.38391900 0.29770600 1 -" -Ca3Mn2(SiO4)3,mp-14051,Ia-3d,[27388],0.04759729490280051,{'tags': ['Tricalcium dimanganese(III) silicate']},"Full Formula (Ca12 Mn8 Si12 O48) -Reduced Formula: Ca3Mn2(SiO4)3 -abc : 10.598871 10.598871 10.598871 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0.001 - 1 Ca 0.75 0.125 0.375 0.001 - 2 Ca 0.375 0.125 0.25 0.001 - 3 Ca 0.125 0.375 0.75 0.001 - 4 Ca 0.25 0.875 0.625 0.001 - 5 Ca 0.125 0.25 0.375 0.001 - 6 Ca 0.625 0.25 0.875 0.001 - 7 Ca 0.75 0.625 0.875 0.001 - 8 Ca 0.875 0.75 0.625 0.001 - 9 Ca 0.875 0.625 0.25 0.001 - 10 Ca 0.625 0.875 0.75 0.001 - 11 Ca 0.375 0.75 0.125 0.001 - 12 Mn 0.5 0 0 4.076 - 13 Mn 0.5 0.5 0 4.07 - 14 Mn 0 0.5 0.5 4.08 - 15 Mn 0 0 0.5 4.074 - 16 Mn 0.5 0.5 0.5 3.947 - 17 Mn 0 0.5 0 4.081 - 18 Mn 0.5 0 0.5 4.076 - 19 Mn 0 0 0 3.947 - 20 Si 0.125 0.75 0.875 0.013 - 21 Si 0.875 0.25 0.125 0.013 - 22 Si 0.75 0.375 0.625 0.013 - 23 Si 0.125 0.875 0.25 0.011 - 24 Si 0.25 0.125 0.875 0.015 - 25 Si 0.375 0.625 0.75 0.011 - 26 Si 0.375 0.25 0.625 0.015 - 27 Si 0.875 0.125 0.75 0.011 - 28 Si 0.625 0.375 0.25 0.011 - 29 Si 0.75 0.875 0.125 0.015 - 30 Si 0.25 0.625 0.375 0.013 - 31 Si 0.625 0.75 0.375 0.015 - 32 O 0.588006 0.892007 0.382344 -0.023 - 33 O 0.382344 0.588006 0.892007 -0.037 - 34 O 0.294337 0.304001 0.911994 -0.03 - 35 O 0.490336 0.607993 0.195999 -0.033 - 36 O 0.304001 0.892007 0.009664 -0.035 - 37 O 0.117656 0.009664 0.205663 -0.053 - 38 O 0.382344 0.294337 0.490336 0.019 - 39 O 0.892007 0.382344 0.588006 -0.032 - 40 O 0.195999 0.205663 0.588006 -0.03 - 41 O 0.490336 0.382344 0.294337 -0.055 - 42 O 0.892007 0.009664 0.304001 -0.032 - 43 O 0.607993 0.911994 0.117656 -0.024 - 44 O 0.911994 0.117656 0.607993 -0.037 - 45 O 0.294337 0.490336 0.382344 -0.004 - 46 O 0.588006 0.195999 0.205663 -0.039 - 47 O 0.205663 0.588006 0.195999 -0.03 - 48 O 0.009664 0.304001 0.892007 -0.036 - 49 O 0.911994 0.294337 0.304001 -0.031 - 50 O 0.009664 0.205663 0.117656 -0.012 - 51 O 0.804001 0.794337 0.411994 -0.03 - 52 O 0.195999 0.490336 0.607993 -0.036 - 53 O 0.607993 0.195999 0.490336 -0.036 - 54 O 0.205663 0.117656 0.009664 0.024 - 55 O 0.117656 0.607993 0.911994 -0.032 - 56 O 0.411994 0.107993 0.617656 -0.023 - 57 O 0.617656 0.411994 0.107993 -0.037 - 58 O 0.705663 0.695999 0.088006 -0.03 - 59 O 0.509664 0.392007 0.804001 -0.033 - 60 O 0.695999 0.107993 0.990336 -0.035 - 61 O 0.882344 0.990336 0.794337 -0.053 - 62 O 0.617656 0.705663 0.509664 0.019 - 63 O 0.107993 0.617656 0.411994 -0.032 - 64 O 0.882344 0.392007 0.088006 -0.032 - 65 O 0.794337 0.882344 0.990336 0.024 - 66 O 0.392007 0.804001 0.509664 -0.036 - 67 O 0.695999 0.088006 0.705663 -0.039 - 68 O 0.804001 0.509664 0.392007 -0.036 - 69 O 0.990336 0.794337 0.882344 -0.012 - 70 O 0.088006 0.705663 0.695999 -0.031 - 71 O 0.990336 0.695999 0.107993 -0.036 - 72 O 0.794337 0.411994 0.804001 -0.03 - 73 O 0.411994 0.804001 0.794337 -0.039 - 74 O 0.705663 0.509664 0.617656 -0.004 - 75 O 0.088006 0.882344 0.392007 -0.037 - 76 O 0.392007 0.088006 0.882344 -0.024 - 77 O 0.107993 0.990336 0.695999 -0.032 - 78 O 0.509664 0.617656 0.705663 -0.055 - 79 O 0.304001 0.911994 0.294337 -0.039","# generated using pymatgen -data_Ca3Mn2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.59887096 -_cell_length_b 10.59887096 -_cell_length_c 10.59887096 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Mn2(SiO4)3 -_chemical_formula_sum 'Ca12 Mn8 Si12 O48' -_cell_volume 916.55160649 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn12 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn13 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn14 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn15 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn16 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn17 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn18 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58800600 0.89200700 0.38234400 1 - O O33 1 0.38234400 0.58800600 0.89200700 1 - O O34 1 0.29433700 0.30400100 0.91199400 1 - O O35 1 0.49033600 0.60799300 0.19599900 1 - O O36 1 0.30400100 0.89200700 0.00966400 1 - O O37 1 0.11765600 0.00966400 0.20566300 1 - O O38 1 0.38234400 0.29433700 0.49033600 1 - O O39 1 0.89200700 0.38234400 0.58800600 1 - O O40 1 0.19599900 0.20566300 0.58800600 1 - O O41 1 0.49033600 0.38234400 0.29433700 1 - O O42 1 0.89200700 0.00966400 0.30400100 1 - O O43 1 0.60799300 0.91199400 0.11765600 1 - O O44 1 0.91199400 0.11765600 0.60799300 1 - O O45 1 0.29433700 0.49033600 0.38234400 1 - O O46 1 0.58800600 0.19599900 0.20566300 1 - O O47 1 0.20566300 0.58800600 0.19599900 1 - O O48 1 0.00966400 0.30400100 0.89200700 1 - O O49 1 0.91199400 0.29433700 0.30400100 1 - O O50 1 0.00966400 0.20566300 0.11765600 1 - O O51 1 0.80400100 0.79433700 0.41199400 1 - O O52 1 0.19599900 0.49033600 0.60799300 1 - O O53 1 0.60799300 0.19599900 0.49033600 1 - O O54 1 0.20566300 0.11765600 0.00966400 1 - O O55 1 0.11765600 0.60799300 0.91199400 1 - O O56 1 0.41199400 0.10799300 0.61765600 1 - O O57 1 0.61765600 0.41199400 0.10799300 1 - O O58 1 0.70566300 0.69599900 0.08800600 1 - O O59 1 0.50966400 0.39200700 0.80400100 1 - O O60 1 0.69599900 0.10799300 0.99033600 1 - O O61 1 0.88234400 0.99033600 0.79433700 1 - O O62 1 0.61765600 0.70566300 0.50966400 1 - O O63 1 0.10799300 0.61765600 0.41199400 1 - O O64 1 0.88234400 0.39200700 0.08800600 1 - O O65 1 0.79433700 0.88234400 0.99033600 1 - O O66 1 0.39200700 0.80400100 0.50966400 1 - O O67 1 0.69599900 0.08800600 0.70566300 1 - O O68 1 0.80400100 0.50966400 0.39200700 1 - O O69 1 0.99033600 0.79433700 0.88234400 1 - O O70 1 0.08800600 0.70566300 0.69599900 1 - O O71 1 0.99033600 0.69599900 0.10799300 1 - O O72 1 0.79433700 0.41199400 0.80400100 1 - O O73 1 0.41199400 0.80400100 0.79433700 1 - O O74 1 0.70566300 0.50966400 0.61765600 1 - O O75 1 0.08800600 0.88234400 0.39200700 1 - O O76 1 0.39200700 0.08800600 0.88234400 1 - O O77 1 0.10799300 0.99033600 0.69599900 1 - O O78 1 0.50966400 0.61765600 0.70566300 1 - O O79 1 0.30400100 0.91199400 0.29433700 1 -" -Ca3In2(SiO4)3,mp-14052,Ia-3d,[27390],0.008378406750004785,{'tags': ['Tricalcium diindium silicate']},"Full Formula (Ca12 In8 Si12 O48) -Reduced Formula: Ca3In2(SiO4)3 -abc : 10.801024 10.801024 10.801024 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.625 0.25 0.875 0 - 1 Ca 0.875 0.75 0.625 0 - 2 Ca 0.75 0.625 0.875 0 - 3 Ca 0.25 0.875 0.625 0 - 4 Ca 0.625 0.875 0.75 0 - 5 Ca 0.125 0.375 0.75 0 - 6 Ca 0.375 0.75 0.125 0 - 7 Ca 0.125 0.25 0.375 0 - 8 Ca 0.25 0.375 0.125 0 - 9 Ca 0.75 0.125 0.375 0 - 10 Ca 0.875 0.625 0.25 0 - 11 Ca 0.375 0.125 0.25 0 - 12 In 0.5 0.5 0.5 0 - 13 In 0.5 0 0.5 0 - 14 In 0 0.5 0.5 0 - 15 In 0 0 0.5 0 - 16 In 0 0.5 0 0 - 17 In 0.5 0 0 0 - 18 In 0 0 0 0 - 19 In 0.5 0.5 0 0 - 20 Si 0.125 0.875 0.25 0 - 21 Si 0.75 0.375 0.625 0 - 22 Si 0.625 0.375 0.25 0 - 23 Si 0.625 0.75 0.375 0 - 24 Si 0.375 0.625 0.75 0 - 25 Si 0.125 0.75 0.875 0 - 26 Si 0.875 0.25 0.125 0 - 27 Si 0.75 0.875 0.125 0 - 28 Si 0.375 0.25 0.625 0 - 29 Si 0.25 0.625 0.375 0 - 30 Si 0.875 0.125 0.75 0 - 31 Si 0.25 0.125 0.875 0 - 32 O 0.701595 0.092856 0.714138 -0 - 33 O 0.108739 0.987457 0.701595 -0 - 34 O 0.714138 0.512543 0.621282 -0 - 35 O 0.621282 0.714138 0.512543 -0 - 36 O 0.878718 0.391261 0.092856 -0 - 37 O 0.092856 0.878718 0.391261 -0 - 38 O 0.987457 0.701595 0.108739 -0 - 39 O 0.407144 0.108739 0.621282 -0 - 40 O 0.391261 0.798405 0.512543 -0 - 41 O 0.987457 0.785862 0.878718 -0 - 42 O 0.108739 0.621282 0.407144 -0 - 43 O 0.512543 0.391261 0.798405 -0 - 44 O 0.785862 0.878718 0.987457 -0 - 45 O 0.714138 0.701595 0.092856 -0 - 46 O 0.092856 0.714138 0.701595 -0 - 47 O 0.621282 0.407144 0.108739 -0 - 48 O 0.785862 0.407144 0.798405 -0 - 49 O 0.798405 0.512543 0.391261 -0 - 50 O 0.798405 0.785862 0.407144 -0 - 51 O 0.878718 0.987457 0.785862 -0 - 52 O 0.407144 0.798405 0.785862 -0 - 53 O 0.391261 0.092856 0.878718 -0 - 54 O 0.701595 0.108739 0.987457 -0 - 55 O 0.512543 0.621282 0.714138 -0 - 56 O 0.298405 0.907144 0.285862 -0 - 57 O 0.891261 0.012543 0.298405 -0 - 58 O 0.285862 0.487457 0.378718 -0 - 59 O 0.378718 0.285862 0.487457 -0 - 60 O 0.121282 0.608739 0.907144 -0 - 61 O 0.907144 0.121282 0.608739 -0 - 62 O 0.012543 0.298405 0.891261 -0 - 63 O 0.592856 0.891261 0.378718 -0 - 64 O 0.608739 0.201595 0.487457 -0 - 65 O 0.012543 0.214138 0.121282 -0 - 66 O 0.891261 0.378718 0.592856 -0 - 67 O 0.487457 0.608739 0.201595 -0 - 68 O 0.214138 0.121282 0.012543 -0 - 69 O 0.285862 0.298405 0.907144 -0 - 70 O 0.907144 0.285862 0.298405 -0 - 71 O 0.378718 0.592856 0.891261 -0 - 72 O 0.214138 0.592856 0.201595 -0 - 73 O 0.201595 0.487457 0.608739 -0 - 74 O 0.201595 0.214138 0.592856 -0 - 75 O 0.121282 0.012543 0.214138 -0 - 76 O 0.592856 0.201595 0.214138 -0 - 77 O 0.608739 0.907144 0.121282 -0 - 78 O 0.298405 0.891261 0.012543 -0 - 79 O 0.487457 0.378718 0.285862 -0","# generated using pymatgen -data_Ca3In2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80102380 -_cell_length_b 10.80102380 -_cell_length_c 10.80102380 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3In2(SiO4)3 -_chemical_formula_sum 'Ca12 In8 Si12 O48' -_cell_volume 970.00255611 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca1 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca2 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca3 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca4 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca5 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca6 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca7 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca8 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca9 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca10 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca11 1 0.37500000 0.12500000 0.25000000 1 - In In12 1 0.50000000 0.50000000 0.50000000 1 - In In13 1 0.50000000 0.00000000 0.50000000 1 - In In14 1 0.00000000 0.50000000 0.50000000 1 - In In15 1 0.00000000 0.00000000 0.50000000 1 - In In16 1 0.00000000 0.50000000 0.00000000 1 - In In17 1 0.50000000 0.00000000 0.00000000 1 - In In18 1 0.00000000 0.00000000 0.00000000 1 - In In19 1 0.50000000 0.50000000 0.00000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.75000000 0.37500000 0.62500000 1 - Si Si22 1 0.62500000 0.37500000 0.25000000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.37500000 0.62500000 0.75000000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.87500000 0.25000000 0.12500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.37500000 0.25000000 0.62500000 1 - Si Si29 1 0.25000000 0.62500000 0.37500000 1 - Si Si30 1 0.87500000 0.12500000 0.75000000 1 - Si Si31 1 0.25000000 0.12500000 0.87500000 1 - O O32 1 0.70159500 0.09285600 0.71413800 1 - O O33 1 0.10873900 0.98745700 0.70159500 1 - O O34 1 0.71413800 0.51254300 0.62128200 1 - O O35 1 0.62128200 0.71413800 0.51254300 1 - O O36 1 0.87871800 0.39126100 0.09285600 1 - O O37 1 0.09285600 0.87871800 0.39126100 1 - O O38 1 0.98745700 0.70159500 0.10873900 1 - O O39 1 0.40714400 0.10873900 0.62128200 1 - O O40 1 0.39126100 0.79840500 0.51254300 1 - O O41 1 0.98745700 0.78586200 0.87871800 1 - O O42 1 0.10873900 0.62128200 0.40714400 1 - O O43 1 0.51254300 0.39126100 0.79840500 1 - O O44 1 0.78586200 0.87871800 0.98745700 1 - O O45 1 0.71413800 0.70159500 0.09285600 1 - O O46 1 0.09285600 0.71413800 0.70159500 1 - O O47 1 0.62128200 0.40714400 0.10873900 1 - O O48 1 0.78586200 0.40714400 0.79840500 1 - O O49 1 0.79840500 0.51254300 0.39126100 1 - O O50 1 0.79840500 0.78586200 0.40714400 1 - O O51 1 0.87871800 0.98745700 0.78586200 1 - O O52 1 0.40714400 0.79840500 0.78586200 1 - O O53 1 0.39126100 0.09285600 0.87871800 1 - O O54 1 0.70159500 0.10873900 0.98745700 1 - O O55 1 0.51254300 0.62128200 0.71413800 1 - O O56 1 0.29840500 0.90714400 0.28586200 1 - O O57 1 0.89126100 0.01254300 0.29840500 1 - O O58 1 0.28586200 0.48745700 0.37871800 1 - O O59 1 0.37871800 0.28586200 0.48745700 1 - O O60 1 0.12128200 0.60873900 0.90714400 1 - O O61 1 0.90714400 0.12128200 0.60873900 1 - O O62 1 0.01254300 0.29840500 0.89126100 1 - O O63 1 0.59285600 0.89126100 0.37871800 1 - O O64 1 0.60873900 0.20159500 0.48745700 1 - O O65 1 0.01254300 0.21413800 0.12128200 1 - O O66 1 0.89126100 0.37871800 0.59285600 1 - O O67 1 0.48745700 0.60873900 0.20159500 1 - O O68 1 0.21413800 0.12128200 0.01254300 1 - O O69 1 0.28586200 0.29840500 0.90714400 1 - O O70 1 0.90714400 0.28586200 0.29840500 1 - O O71 1 0.37871800 0.59285600 0.89126100 1 - O O72 1 0.21413800 0.59285600 0.20159500 1 - O O73 1 0.20159500 0.48745700 0.60873900 1 - O O74 1 0.20159500 0.21413800 0.59285600 1 - O O75 1 0.12128200 0.01254300 0.21413800 1 - O O76 1 0.59285600 0.20159500 0.21413800 1 - O O77 1 0.60873900 0.90714400 0.12128200 1 - O O78 1 0.29840500 0.89126100 0.01254300 1 - O O79 1 0.48745700 0.37871800 0.28586200 1 -" -Na3Li3Ti2F12,mp-14457,Ia-3d,[60363],0.0,{'tags': ['Trisodium trilithium dititanium dodecafluoride']},"Full Formula (Na12 Li12 Ti8 F48) -Reduced Formula: Na3Li3Ti2F12 -abc : 10.955412 10.955412 10.955412 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.875 0.75 0.625 0 - 1 Na 0.625 0.25 0.875 0 - 2 Na 0.25 0.875 0.625 0 - 3 Na 0.875 0.625 0.25 0 - 4 Na 0.625 0.875 0.75 0 - 5 Na 0.75 0.625 0.875 0 - 6 Na 0.125 0.25 0.375 0 - 7 Na 0.375 0.75 0.125 0 - 8 Na 0.75 0.125 0.375 0 - 9 Na 0.125 0.375 0.75 0 - 10 Na 0.25 0.375 0.125 0 - 11 Na 0.375 0.125 0.25 0 - 12 Li 0.625 0.375 0.25 0 - 13 Li 0.25 0.125 0.875 0 - 14 Li 0.75 0.875 0.125 0 - 15 Li 0.125 0.75 0.875 0 - 16 Li 0.375 0.25 0.625 0 - 17 Li 0.875 0.125 0.75 0 - 18 Li 0.875 0.25 0.125 0 - 19 Li 0.625 0.75 0.375 0 - 20 Li 0.75 0.375 0.625 0 - 21 Li 0.375 0.625 0.75 0 - 22 Li 0.125 0.875 0.25 0 - 23 Li 0.25 0.625 0.375 0 - 24 Ti 0.5 0.5 0.5 0.918 - 25 Ti 0.5 0 0.5 0.918 - 26 Ti 0 0.5 0.5 0.918 - 27 Ti 0.5 0.5 0 0.916 - 28 Ti 0 0 0.5 0.918 - 29 Ti 0 0.5 0 0.916 - 30 Ti 0.5 0 0 0.918 - 31 Ti 0 0 0 0.918 - 32 F 0.421879 0.824049 0.803751 0.002 - 33 F 0.402169 0.824049 0.520298 0.002 - 34 F 0.078121 0.696249 0.675951 0.002 - 35 F 0.097831 0.618128 0.421879 0.002 - 36 F 0.520298 0.402169 0.824049 0.002 - 37 F 0.078121 0.881872 0.402169 0.002 - 38 F 0.979702 0.675951 0.097831 0.002 - 39 F 0.824049 0.803751 0.421879 0.002 - 40 F 0.696249 0.675951 0.078121 0.002 - 41 F 0.803751 0.881872 0.979702 0.002 - 42 F 0.979702 0.803751 0.881872 0.002 - 43 F 0.824049 0.520298 0.402169 0.002 - 44 F 0.696249 0.520298 0.618128 0.002 - 45 F 0.618128 0.421879 0.097831 0.002 - 46 F 0.618128 0.696249 0.520298 0.002 - 47 F 0.675951 0.078121 0.696249 0.002 - 48 F 0.520298 0.618128 0.696249 0.002 - 49 F 0.421879 0.097831 0.618128 0.002 - 50 F 0.097831 0.979702 0.675951 0.002 - 51 F 0.881872 0.402169 0.078121 0.002 - 52 F 0.118128 0.020298 0.196249 0.002 - 53 F 0.597831 0.921879 0.118128 0.002 - 54 F 0.196249 0.578121 0.175951 0.002 - 55 F 0.175951 0.196249 0.578121 0.002 - 56 F 0.324049 0.902169 0.020298 0.002 - 57 F 0.020298 0.324049 0.902169 0.002 - 58 F 0.921879 0.118128 0.597831 0.002 - 59 F 0.479702 0.597831 0.175951 0.002 - 60 F 0.902169 0.381872 0.578121 0.002 - 61 F 0.921879 0.303751 0.324049 0.002 - 62 F 0.597831 0.175951 0.479702 0.002 - 63 F 0.578121 0.902169 0.381872 0.002 - 64 F 0.303751 0.324049 0.921879 0.002 - 65 F 0.196249 0.118128 0.020298 0.002 - 66 F 0.020298 0.196249 0.118128 0.002 - 67 F 0.175951 0.479702 0.597831 0.002 - 68 F 0.303751 0.479702 0.381872 0.002 - 69 F 0.381872 0.578121 0.902169 0.002 - 70 F 0.381872 0.303751 0.479702 0.002 - 71 F 0.324049 0.921879 0.303751 0.002 - 72 F 0.479702 0.381872 0.303751 0.002 - 73 F 0.902169 0.020298 0.324049 0.002 - 74 F 0.118128 0.597831 0.921879 0.002 - 75 F 0.578121 0.175951 0.196249 0.002 - 76 F 0.881872 0.979702 0.803751 0.002 - 77 F 0.402169 0.078121 0.881872 0.002 - 78 F 0.803751 0.421879 0.824049 0.002 - 79 F 0.675951 0.097831 0.979702 0.002","# generated using pymatgen -data_Na3Li3Ti2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.95541188 -_cell_length_b 10.95541188 -_cell_length_c 10.95541188 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3Ti2F12 -_chemical_formula_sum 'Na12 Li12 Ti8 F48' -_cell_volume 1012.19512084 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.87500000 0.75000000 0.62500000 1 - Na Na1 1 0.62500000 0.25000000 0.87500000 1 - Na Na2 1 0.25000000 0.87500000 0.62500000 1 - Na Na3 1 0.87500000 0.62500000 0.25000000 1 - Na Na4 1 0.62500000 0.87500000 0.75000000 1 - Na Na5 1 0.75000000 0.62500000 0.87500000 1 - Na Na6 1 0.12500000 0.25000000 0.37500000 1 - Na Na7 1 0.37500000 0.75000000 0.12500000 1 - Na Na8 1 0.75000000 0.12500000 0.37500000 1 - Na Na9 1 0.12500000 0.37500000 0.75000000 1 - Na Na10 1 0.25000000 0.37500000 0.12500000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Li Li12 1 0.62500000 0.37500000 0.25000000 1 - Li Li13 1 0.25000000 0.12500000 0.87500000 1 - Li Li14 1 0.75000000 0.87500000 0.12500000 1 - Li Li15 1 0.12500000 0.75000000 0.87500000 1 - Li Li16 1 0.37500000 0.25000000 0.62500000 1 - Li Li17 1 0.87500000 0.12500000 0.75000000 1 - Li Li18 1 0.87500000 0.25000000 0.12500000 1 - Li Li19 1 0.62500000 0.75000000 0.37500000 1 - Li Li20 1 0.75000000 0.37500000 0.62500000 1 - Li Li21 1 0.37500000 0.62500000 0.75000000 1 - Li Li22 1 0.12500000 0.87500000 0.25000000 1 - Li Li23 1 0.25000000 0.62500000 0.37500000 1 - Ti Ti24 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti25 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti26 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti27 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti28 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti29 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti30 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti31 1 0.00000000 0.00000000 0.00000000 1 - F F32 1 0.42187900 0.82404900 0.80375100 1 - F F33 1 0.40216900 0.82404900 0.52029800 1 - F F34 1 0.07812100 0.69624900 0.67595100 1 - F F35 1 0.09783100 0.61812800 0.42187900 1 - F F36 1 0.52029800 0.40216900 0.82404900 1 - F F37 1 0.07812100 0.88187200 0.40216900 1 - F F38 1 0.97970200 0.67595100 0.09783100 1 - F F39 1 0.82404900 0.80375100 0.42187900 1 - F F40 1 0.69624900 0.67595100 0.07812100 1 - F F41 1 0.80375100 0.88187200 0.97970200 1 - F F42 1 0.97970200 0.80375100 0.88187200 1 - F F43 1 0.82404900 0.52029800 0.40216900 1 - F F44 1 0.69624900 0.52029800 0.61812800 1 - F F45 1 0.61812800 0.42187900 0.09783100 1 - F F46 1 0.61812800 0.69624900 0.52029800 1 - F F47 1 0.67595100 0.07812100 0.69624900 1 - F F48 1 0.52029800 0.61812800 0.69624900 1 - F F49 1 0.42187900 0.09783100 0.61812800 1 - F F50 1 0.09783100 0.97970200 0.67595100 1 - F F51 1 0.88187200 0.40216900 0.07812100 1 - F F52 1 0.11812800 0.02029800 0.19624900 1 - F F53 1 0.59783100 0.92187900 0.11812800 1 - F F54 1 0.19624900 0.57812100 0.17595100 1 - F F55 1 0.17595100 0.19624900 0.57812100 1 - F F56 1 0.32404900 0.90216900 0.02029800 1 - F F57 1 0.02029800 0.32404900 0.90216900 1 - F F58 1 0.92187900 0.11812800 0.59783100 1 - F F59 1 0.47970200 0.59783100 0.17595100 1 - F F60 1 0.90216900 0.38187200 0.57812100 1 - F F61 1 0.92187900 0.30375100 0.32404900 1 - F F62 1 0.59783100 0.17595100 0.47970200 1 - F F63 1 0.57812100 0.90216900 0.38187200 1 - F F64 1 0.30375100 0.32404900 0.92187900 1 - F F65 1 0.19624900 0.11812800 0.02029800 1 - F F66 1 0.02029800 0.19624900 0.11812800 1 - F F67 1 0.17595100 0.47970200 0.59783100 1 - F F68 1 0.30375100 0.47970200 0.38187200 1 - F F69 1 0.38187200 0.57812100 0.90216900 1 - F F70 1 0.38187200 0.30375100 0.47970200 1 - F F71 1 0.32404900 0.92187900 0.30375100 1 - F F72 1 0.47970200 0.38187200 0.30375100 1 - F F73 1 0.90216900 0.02029800 0.32404900 1 - F F74 1 0.11812800 0.59783100 0.92187900 1 - F F75 1 0.57812100 0.17595100 0.19624900 1 - F F76 1 0.88187200 0.97970200 0.80375100 1 - F F77 1 0.40216900 0.07812100 0.88187200 1 - F F78 1 0.80375100 0.42187900 0.82404900 1 - F F79 1 0.67595100 0.09783100 0.97970200 1 -" -Na3Li3Cr2F12,mp-14458,Ia-3d,[60365],0.0,{'tags': ['Trisodium trilithium dichromium dodecafluoride']},"Full Formula (Na12 Li12 Cr8 F48) -Reduced Formula: Na3Li3Cr2F12 -abc : 10.871355 10.871355 10.871355 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.875 0.75 0.625 0.001 - 1 Na 0.625 0.25 0.875 0.001 - 2 Na 0.25 0.875 0.625 0.001 - 3 Na 0.875 0.625 0.25 0.001 - 4 Na 0.625 0.875 0.75 0.001 - 5 Na 0.75 0.625 0.875 0.001 - 6 Na 0.125 0.25 0.375 0.001 - 7 Na 0.375 0.75 0.125 0.001 - 8 Na 0.75 0.125 0.375 0.001 - 9 Na 0.125 0.375 0.75 0.001 - 10 Na 0.25 0.375 0.125 0.001 - 11 Na 0.375 0.125 0.25 0.001 - 12 Li 0.625 0.375 0.25 0 - 13 Li 0.25 0.125 0.875 0 - 14 Li 0.75 0.875 0.125 0 - 15 Li 0.125 0.75 0.875 0 - 16 Li 0.375 0.25 0.625 0 - 17 Li 0.875 0.125 0.75 0 - 18 Li 0.875 0.25 0.125 0 - 19 Li 0.625 0.75 0.375 0 - 20 Li 0.75 0.375 0.625 0 - 21 Li 0.375 0.625 0.75 0 - 22 Li 0.125 0.875 0.25 0 - 23 Li 0.25 0.625 0.375 0 - 24 Cr 0.5 0.5 0.5 2.922 - 25 Cr 0.5 0 0.5 2.922 - 26 Cr 0 0.5 0.5 2.922 - 27 Cr 0.5 0.5 0 2.922 - 28 Cr 0 0 0.5 2.922 - 29 Cr 0 0.5 0 2.922 - 30 Cr 0.5 0 0 2.922 - 31 Cr 0 0 0 2.922 - 32 F 0.423496 0.825724 0.807359 0.001 - 33 F 0.402228 0.825724 0.518365 0.001 - 34 F 0.076504 0.692641 0.674276 0.001 - 35 F 0.097772 0.616137 0.423496 0.001 - 36 F 0.518365 0.402228 0.825724 0.001 - 37 F 0.076504 0.883863 0.402228 0.001 - 38 F 0.981635 0.674276 0.097772 0.001 - 39 F 0.825724 0.807359 0.423496 0.001 - 40 F 0.692641 0.674276 0.076504 0.001 - 41 F 0.807359 0.883863 0.981635 0.001 - 42 F 0.981635 0.807359 0.883863 0.001 - 43 F 0.825724 0.518365 0.402228 0.001 - 44 F 0.692641 0.518365 0.616137 0.001 - 45 F 0.616137 0.423496 0.097772 0.001 - 46 F 0.616137 0.692641 0.518365 0.001 - 47 F 0.674276 0.076504 0.692641 0.001 - 48 F 0.518365 0.616137 0.692641 0.001 - 49 F 0.423496 0.097772 0.616137 0.001 - 50 F 0.097772 0.981635 0.674276 0.001 - 51 F 0.883863 0.402228 0.076504 0.001 - 52 F 0.116137 0.018365 0.192641 0.001 - 53 F 0.597772 0.923496 0.116137 0.001 - 54 F 0.192641 0.576504 0.174276 0.001 - 55 F 0.174276 0.192641 0.576504 0.001 - 56 F 0.325724 0.902228 0.018365 0.001 - 57 F 0.018365 0.325724 0.902228 0.001 - 58 F 0.923496 0.116137 0.597772 0.001 - 59 F 0.481635 0.597772 0.174276 0.001 - 60 F 0.902228 0.383863 0.576504 0.001 - 61 F 0.923496 0.307359 0.325724 0.001 - 62 F 0.597772 0.174276 0.481635 0.001 - 63 F 0.576504 0.902228 0.383863 0.001 - 64 F 0.307359 0.325724 0.923496 0.001 - 65 F 0.192641 0.116137 0.018365 0.001 - 66 F 0.018365 0.192641 0.116137 0.001 - 67 F 0.174276 0.481635 0.597772 0.001 - 68 F 0.307359 0.481635 0.383863 0.001 - 69 F 0.383863 0.576504 0.902228 0.001 - 70 F 0.383863 0.307359 0.481635 0.001 - 71 F 0.325724 0.923496 0.307359 0.001 - 72 F 0.481635 0.383863 0.307359 0.001 - 73 F 0.902228 0.018365 0.325724 0.001 - 74 F 0.116137 0.597772 0.923496 0.001 - 75 F 0.576504 0.174276 0.192641 0.001 - 76 F 0.883863 0.981635 0.807359 0.001 - 77 F 0.402228 0.076504 0.883863 0.001 - 78 F 0.807359 0.423496 0.825724 0.001 - 79 F 0.674276 0.097772 0.981635 0.001","# generated using pymatgen -data_Na3Li3Cr2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.87135546 -_cell_length_b 10.87135546 -_cell_length_c 10.87135546 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3Cr2F12 -_chemical_formula_sum 'Na12 Li12 Cr8 F48' -_cell_volume 989.07493734 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.87500000 0.75000000 0.62500000 1 - Na Na1 1 0.62500000 0.25000000 0.87500000 1 - Na Na2 1 0.25000000 0.87500000 0.62500000 1 - Na Na3 1 0.87500000 0.62500000 0.25000000 1 - Na Na4 1 0.62500000 0.87500000 0.75000000 1 - Na Na5 1 0.75000000 0.62500000 0.87500000 1 - Na Na6 1 0.12500000 0.25000000 0.37500000 1 - Na Na7 1 0.37500000 0.75000000 0.12500000 1 - Na Na8 1 0.75000000 0.12500000 0.37500000 1 - Na Na9 1 0.12500000 0.37500000 0.75000000 1 - Na Na10 1 0.25000000 0.37500000 0.12500000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Li Li12 1 0.62500000 0.37500000 0.25000000 1 - Li Li13 1 0.25000000 0.12500000 0.87500000 1 - Li Li14 1 0.75000000 0.87500000 0.12500000 1 - Li Li15 1 0.12500000 0.75000000 0.87500000 1 - Li Li16 1 0.37500000 0.25000000 0.62500000 1 - Li Li17 1 0.87500000 0.12500000 0.75000000 1 - Li Li18 1 0.87500000 0.25000000 0.12500000 1 - Li Li19 1 0.62500000 0.75000000 0.37500000 1 - Li Li20 1 0.75000000 0.37500000 0.62500000 1 - Li Li21 1 0.37500000 0.62500000 0.75000000 1 - Li Li22 1 0.12500000 0.87500000 0.25000000 1 - Li Li23 1 0.25000000 0.62500000 0.37500000 1 - Cr Cr24 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr25 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr26 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr27 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr28 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr29 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr30 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr31 1 0.00000000 0.00000000 0.00000000 1 - F F32 1 0.42349600 0.82572400 0.80735900 1 - F F33 1 0.40222800 0.82572400 0.51836500 1 - F F34 1 0.07650400 0.69264100 0.67427600 1 - F F35 1 0.09777200 0.61613700 0.42349600 1 - F F36 1 0.51836500 0.40222800 0.82572400 1 - F F37 1 0.07650400 0.88386300 0.40222800 1 - F F38 1 0.98163500 0.67427600 0.09777200 1 - F F39 1 0.82572400 0.80735900 0.42349600 1 - F F40 1 0.69264100 0.67427600 0.07650400 1 - F F41 1 0.80735900 0.88386300 0.98163500 1 - F F42 1 0.98163500 0.80735900 0.88386300 1 - F F43 1 0.82572400 0.51836500 0.40222800 1 - F F44 1 0.69264100 0.51836500 0.61613700 1 - F F45 1 0.61613700 0.42349600 0.09777200 1 - F F46 1 0.61613700 0.69264100 0.51836500 1 - F F47 1 0.67427600 0.07650400 0.69264100 1 - F F48 1 0.51836500 0.61613700 0.69264100 1 - F F49 1 0.42349600 0.09777200 0.61613700 1 - F F50 1 0.09777200 0.98163500 0.67427600 1 - F F51 1 0.88386300 0.40222800 0.07650400 1 - F F52 1 0.11613700 0.01836500 0.19264100 1 - F F53 1 0.59777200 0.92349600 0.11613700 1 - F F54 1 0.19264100 0.57650400 0.17427600 1 - F F55 1 0.17427600 0.19264100 0.57650400 1 - F F56 1 0.32572400 0.90222800 0.01836500 1 - F F57 1 0.01836500 0.32572400 0.90222800 1 - F F58 1 0.92349600 0.11613700 0.59777200 1 - F F59 1 0.48163500 0.59777200 0.17427600 1 - F F60 1 0.90222800 0.38386300 0.57650400 1 - F F61 1 0.92349600 0.30735900 0.32572400 1 - F F62 1 0.59777200 0.17427600 0.48163500 1 - F F63 1 0.57650400 0.90222800 0.38386300 1 - F F64 1 0.30735900 0.32572400 0.92349600 1 - F F65 1 0.19264100 0.11613700 0.01836500 1 - F F66 1 0.01836500 0.19264100 0.11613700 1 - F F67 1 0.17427600 0.48163500 0.59777200 1 - F F68 1 0.30735900 0.48163500 0.38386300 1 - F F69 1 0.38386300 0.57650400 0.90222800 1 - F F70 1 0.38386300 0.30735900 0.48163500 1 - F F71 1 0.32572400 0.92349600 0.30735900 1 - F F72 1 0.48163500 0.38386300 0.30735900 1 - F F73 1 0.90222800 0.01836500 0.32572400 1 - F F74 1 0.11613700 0.59777200 0.92349600 1 - F F75 1 0.57650400 0.17427600 0.19264100 1 - F F76 1 0.88386300 0.98163500 0.80735900 1 - F F77 1 0.40222800 0.07650400 0.88386300 1 - F F78 1 0.80735900 0.42349600 0.82572400 1 - F F79 1 0.67427600 0.09777200 0.98163500 1 -" -Y3Sc2Al3O12,mp-14678,Ia-3d,[67055],0.0,{'tags': ['Triyttrium discandium trialuminium oxide']},"Full Formula (Y12 Sc8 Al12 O48) -Reduced Formula: Y3Sc2Al3O12 -abc : 10.779455 10.779455 10.779455 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.375 0.125 0.25 -0 - 1 Y 0.125 0.375 0.75 -0 - 2 Y 0.375 0.75 0.125 -0 - 3 Y 0.125 0.25 0.375 -0 - 4 Y 0.25 0.375 0.125 -0 - 5 Y 0.75 0.125 0.375 -0 - 6 Y 0.875 0.75 0.625 -0 - 7 Y 0.875 0.625 0.25 -0 - 8 Y 0.625 0.875 0.75 -0 - 9 Y 0.75 0.625 0.875 -0 - 10 Y 0.25 0.875 0.625 -0 - 11 Y 0.625 0.25 0.875 -0 - 12 Sc 0.5 0 0 0 - 13 Sc 0 0.5 0 0 - 14 Sc 0 0 0.5 0 - 15 Sc 0.5 0.5 0 0 - 16 Sc 0.5 0.5 0.5 0 - 17 Sc 0 0.5 0.5 0 - 18 Sc 0.5 0 0.5 0 - 19 Sc 0 0 0 0 - 20 Al 0.125 0.75 0.875 -0 - 21 Al 0.875 0.25 0.125 -0 - 22 Al 0.625 0.375 0.25 -0 - 23 Al 0.75 0.875 0.125 -0 - 24 Al 0.875 0.125 0.75 -0 - 25 Al 0.25 0.625 0.375 -0 - 26 Al 0.75 0.375 0.625 -0 - 27 Al 0.25 0.125 0.875 -0 - 28 Al 0.125 0.875 0.25 -0 - 29 Al 0.375 0.25 0.625 -0 - 30 Al 0.625 0.75 0.375 -0 - 31 Al 0.375 0.625 0.75 -0 - 32 O 0.474812 0.374559 0.286716 0 - 33 O 0.311905 0.899747 0.025188 0 - 34 O 0.600253 0.912158 0.125441 0 - 35 O 0.587842 0.188095 0.213284 0 - 36 O 0.125441 0.025188 0.213284 0 - 37 O 0.188095 0.213284 0.587842 0 - 38 O 0.188095 0.474812 0.600253 0 - 39 O 0.213284 0.587842 0.188095 0 - 40 O 0.374559 0.587842 0.899747 0 - 41 O 0.912158 0.286716 0.311905 0 - 42 O 0.286716 0.311905 0.912158 0 - 43 O 0.213284 0.125441 0.025188 0 - 44 O 0.474812 0.600253 0.188095 0 - 45 O 0.899747 0.374559 0.587842 0 - 46 O 0.025188 0.213284 0.125441 0 - 47 O 0.600253 0.188095 0.474812 0 - 48 O 0.587842 0.899747 0.374559 0 - 49 O 0.025188 0.311905 0.899747 0 - 50 O 0.912158 0.125441 0.600253 0 - 51 O 0.625441 0.412158 0.100253 0 - 52 O 0.125441 0.600253 0.912158 0 - 53 O 0.286716 0.474812 0.374559 0 - 54 O 0.899747 0.025188 0.311905 0 - 55 O 0.311905 0.912158 0.286716 0 - 56 O 0.525188 0.625441 0.713284 0 - 57 O 0.688095 0.100253 0.974812 0 - 58 O 0.399747 0.087842 0.874559 0 - 59 O 0.412158 0.811905 0.786716 0 - 60 O 0.874559 0.974812 0.786716 0 - 61 O 0.811905 0.786716 0.412158 0 - 62 O 0.811905 0.525188 0.399747 0 - 63 O 0.786716 0.412158 0.811905 0 - 64 O 0.688095 0.087842 0.713284 0 - 65 O 0.100253 0.974812 0.688095 0 - 66 O 0.713284 0.525188 0.625441 0 - 67 O 0.625441 0.713284 0.525188 0 - 68 O 0.874559 0.399747 0.087842 0 - 69 O 0.087842 0.874559 0.399747 0 - 70 O 0.974812 0.688095 0.100253 0 - 71 O 0.412158 0.100253 0.625441 0 - 72 O 0.399747 0.811905 0.525188 0 - 73 O 0.974812 0.786716 0.874559 0 - 74 O 0.100253 0.625441 0.412158 0 - 75 O 0.525188 0.399747 0.811905 0 - 76 O 0.786716 0.874559 0.974812 0 - 77 O 0.713284 0.688095 0.087842 0 - 78 O 0.087842 0.713284 0.688095 0 - 79 O 0.374559 0.286716 0.474812 0","# generated using pymatgen -data_Y3Sc2Al3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.77945457 -_cell_length_b 10.77945457 -_cell_length_c 10.77945457 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Sc2Al3O12 -_chemical_formula_sum 'Y12 Sc8 Al12 O48' -_cell_volume 964.20297980 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.37500000 0.12500000 0.25000000 1 - Y Y1 1 0.12500000 0.37500000 0.75000000 1 - Y Y2 1 0.37500000 0.75000000 0.12500000 1 - Y Y3 1 0.12500000 0.25000000 0.37500000 1 - Y Y4 1 0.25000000 0.37500000 0.12500000 1 - Y Y5 1 0.75000000 0.12500000 0.37500000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.87500000 0.62500000 0.25000000 1 - Y Y8 1 0.62500000 0.87500000 0.75000000 1 - Y Y9 1 0.75000000 0.62500000 0.87500000 1 - Y Y10 1 0.25000000 0.87500000 0.62500000 1 - Y Y11 1 0.62500000 0.25000000 0.87500000 1 - Sc Sc12 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.00000000 0.50000000 0.00000000 1 - Sc Sc14 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc17 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.00000000 0.00000000 1 - Al Al20 1 0.12500000 0.75000000 0.87500000 1 - Al Al21 1 0.87500000 0.25000000 0.12500000 1 - Al Al22 1 0.62500000 0.37500000 0.25000000 1 - Al Al23 1 0.75000000 0.87500000 0.12500000 1 - Al Al24 1 0.87500000 0.12500000 0.75000000 1 - Al Al25 1 0.25000000 0.62500000 0.37500000 1 - Al Al26 1 0.75000000 0.37500000 0.62500000 1 - Al Al27 1 0.25000000 0.12500000 0.87500000 1 - Al Al28 1 0.12500000 0.87500000 0.25000000 1 - Al Al29 1 0.37500000 0.25000000 0.62500000 1 - Al Al30 1 0.62500000 0.75000000 0.37500000 1 - Al Al31 1 0.37500000 0.62500000 0.75000000 1 - O O32 1 0.47481200 0.37455900 0.28671600 1 - O O33 1 0.31190500 0.89974700 0.02518800 1 - O O34 1 0.60025300 0.91215800 0.12544100 1 - O O35 1 0.58784200 0.18809500 0.21328400 1 - O O36 1 0.12544100 0.02518800 0.21328400 1 - O O37 1 0.18809500 0.21328400 0.58784200 1 - O O38 1 0.18809500 0.47481200 0.60025300 1 - O O39 1 0.21328400 0.58784200 0.18809500 1 - O O40 1 0.37455900 0.58784200 0.89974700 1 - O O41 1 0.91215800 0.28671600 0.31190500 1 - O O42 1 0.28671600 0.31190500 0.91215800 1 - O O43 1 0.21328400 0.12544100 0.02518800 1 - O O44 1 0.47481200 0.60025300 0.18809500 1 - O O45 1 0.89974700 0.37455900 0.58784200 1 - O O46 1 0.02518800 0.21328400 0.12544100 1 - O O47 1 0.60025300 0.18809500 0.47481200 1 - O O48 1 0.58784200 0.89974700 0.37455900 1 - O O49 1 0.02518800 0.31190500 0.89974700 1 - O O50 1 0.91215800 0.12544100 0.60025300 1 - O O51 1 0.62544100 0.41215800 0.10025300 1 - O O52 1 0.12544100 0.60025300 0.91215800 1 - O O53 1 0.28671600 0.47481200 0.37455900 1 - O O54 1 0.89974700 0.02518800 0.31190500 1 - O O55 1 0.31190500 0.91215800 0.28671600 1 - O O56 1 0.52518800 0.62544100 0.71328400 1 - O O57 1 0.68809500 0.10025300 0.97481200 1 - O O58 1 0.39974700 0.08784200 0.87455900 1 - O O59 1 0.41215800 0.81190500 0.78671600 1 - O O60 1 0.87455900 0.97481200 0.78671600 1 - O O61 1 0.81190500 0.78671600 0.41215800 1 - O O62 1 0.81190500 0.52518800 0.39974700 1 - O O63 1 0.78671600 0.41215800 0.81190500 1 - O O64 1 0.68809500 0.08784200 0.71328400 1 - O O65 1 0.10025300 0.97481200 0.68809500 1 - O O66 1 0.71328400 0.52518800 0.62544100 1 - O O67 1 0.62544100 0.71328400 0.52518800 1 - O O68 1 0.87455900 0.39974700 0.08784200 1 - O O69 1 0.08784200 0.87455900 0.39974700 1 - O O70 1 0.97481200 0.68809500 0.10025300 1 - O O71 1 0.41215800 0.10025300 0.62544100 1 - O O72 1 0.39974700 0.81190500 0.52518800 1 - O O73 1 0.97481200 0.78671600 0.87455900 1 - O O74 1 0.10025300 0.62544100 0.41215800 1 - O O75 1 0.52518800 0.39974700 0.81190500 1 - O O76 1 0.78671600 0.87455900 0.97481200 1 - O O77 1 0.71328400 0.68809500 0.08784200 1 - O O78 1 0.08784200 0.71328400 0.68809500 1 - O O79 1 0.37455900 0.28671600 0.47481200 1 -" -Ca3Zn3(TeO6)2,mp-14778,Ia-3d,[67045],0.0,"{'tags': ['Tricalcium trizinc bis(tellurate(VI))', 'Yafsoanite']}","Full Formula (Ca12 Zn12 Te8 O48) -Reduced Formula: Ca3Zn3(TeO6)2 -abc : 11.044342 11.044342 11.044342 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.625 0.25 0.875 -0 - 1 Ca 0.125 0.25 0.375 -0 - 2 Ca 0.375 0.75 0.125 -0 - 3 Ca 0.125 0.375 0.75 -0 - 4 Ca 0.375 0.125 0.25 -0 - 5 Ca 0.25 0.375 0.125 -0 - 6 Ca 0.75 0.125 0.375 -0 - 7 Ca 0.875 0.75 0.625 -0 - 8 Ca 0.875 0.625 0.25 -0 - 9 Ca 0.625 0.875 0.75 -0 - 10 Ca 0.75 0.625 0.875 -0 - 11 Ca 0.25 0.875 0.625 -0 - 12 Zn 0.125 0.75 0.875 -0 - 13 Zn 0.625 0.75 0.375 -0 - 14 Zn 0.375 0.625 0.75 -0 - 15 Zn 0.125 0.875 0.25 -0 - 16 Zn 0.375 0.25 0.625 -0 - 17 Zn 0.25 0.125 0.875 -0 - 18 Zn 0.75 0.375 0.625 -0 - 19 Zn 0.25 0.625 0.375 -0 - 20 Zn 0.875 0.125 0.75 -0 - 21 Zn 0.75 0.875 0.125 -0 - 22 Zn 0.875 0.25 0.125 -0 - 23 Zn 0.625 0.375 0.25 -0 - 24 Te 0.5 0.5 0.5 0 - 25 Te 0.5 0 0.5 0 - 26 Te 0 0.5 0.5 0 - 27 Te 0.5 0.5 0 0 - 28 Te 0 0 0.5 0 - 29 Te 0 0.5 0 0 - 30 Te 0.5 0 0 0 - 31 Te 0 0 0 0 - 32 O 0.424692 0.830895 0.80721 0 - 33 O 0.882518 0.406203 0.075308 0 - 34 O 0.093797 0.976315 0.669105 0 - 35 O 0.523685 0.617482 0.69279 0 - 36 O 0.669105 0.075308 0.69279 0 - 37 O 0.617482 0.69279 0.523685 0 - 38 O 0.617482 0.424692 0.093797 0 - 39 O 0.69279 0.523685 0.617482 0 - 40 O 0.830895 0.523685 0.406203 0 - 41 O 0.976315 0.80721 0.882518 0 - 42 O 0.80721 0.882518 0.976315 0 - 43 O 0.69279 0.669105 0.075308 0 - 44 O 0.424692 0.093797 0.617482 0 - 45 O 0.406203 0.830895 0.523685 0 - 46 O 0.075308 0.69279 0.669105 0 - 47 O 0.093797 0.617482 0.424692 0 - 48 O 0.523685 0.406203 0.830895 0 - 49 O 0.075308 0.882518 0.406203 0 - 50 O 0.976315 0.669105 0.093797 0 - 51 O 0.169105 0.476315 0.593797 0 - 52 O 0.669105 0.093797 0.976315 0 - 53 O 0.80721 0.424692 0.830895 0 - 54 O 0.406203 0.075308 0.882518 0 - 55 O 0.882518 0.976315 0.80721 0 - 56 O 0.575308 0.169105 0.19279 0 - 57 O 0.117482 0.593797 0.924692 0 - 58 O 0.906203 0.023685 0.330895 0 - 59 O 0.476315 0.382518 0.30721 0 - 60 O 0.330895 0.924692 0.30721 0 - 61 O 0.382518 0.30721 0.476315 0 - 62 O 0.382518 0.575308 0.906203 0 - 63 O 0.30721 0.476315 0.382518 0 - 64 O 0.117482 0.023685 0.19279 0 - 65 O 0.593797 0.924692 0.117482 0 - 66 O 0.19279 0.575308 0.169105 0 - 67 O 0.169105 0.19279 0.575308 0 - 68 O 0.330895 0.906203 0.023685 0 - 69 O 0.023685 0.330895 0.906203 0 - 70 O 0.924692 0.117482 0.593797 0 - 71 O 0.476315 0.593797 0.169105 0 - 72 O 0.906203 0.382518 0.575308 0 - 73 O 0.924692 0.30721 0.330895 0 - 74 O 0.593797 0.169105 0.476315 0 - 75 O 0.575308 0.906203 0.382518 0 - 76 O 0.30721 0.330895 0.924692 0 - 77 O 0.19279 0.117482 0.023685 0 - 78 O 0.023685 0.19279 0.117482 0 - 79 O 0.830895 0.80721 0.424692 0","# generated using pymatgen -data_Ca3Zn3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.04434230 -_cell_length_b 11.04434230 -_cell_length_c 11.04434230 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Zn3(TeO6)2 -_chemical_formula_sum 'Ca12 Zn12 Te8 O48' -_cell_volume 1037.04519687 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca1 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca2 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca5 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca8 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca10 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca11 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn12 1 0.12500000 0.75000000 0.87500000 1 - Zn Zn13 1 0.62500000 0.75000000 0.37500000 1 - Zn Zn14 1 0.37500000 0.62500000 0.75000000 1 - Zn Zn15 1 0.12500000 0.87500000 0.25000000 1 - Zn Zn16 1 0.37500000 0.25000000 0.62500000 1 - Zn Zn17 1 0.25000000 0.12500000 0.87500000 1 - Zn Zn18 1 0.75000000 0.37500000 0.62500000 1 - Zn Zn19 1 0.25000000 0.62500000 0.37500000 1 - Zn Zn20 1 0.87500000 0.12500000 0.75000000 1 - Zn Zn21 1 0.75000000 0.87500000 0.12500000 1 - Zn Zn22 1 0.87500000 0.25000000 0.12500000 1 - Zn Zn23 1 0.62500000 0.37500000 0.25000000 1 - Te Te24 1 0.50000000 0.50000000 0.50000000 1 - Te Te25 1 0.50000000 0.00000000 0.50000000 1 - Te Te26 1 0.00000000 0.50000000 0.50000000 1 - Te Te27 1 0.50000000 0.50000000 0.00000000 1 - Te Te28 1 0.00000000 0.00000000 0.50000000 1 - Te Te29 1 0.00000000 0.50000000 0.00000000 1 - Te Te30 1 0.50000000 0.00000000 0.00000000 1 - Te Te31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.42469200 0.83089500 0.80721000 1 - O O33 1 0.88251800 0.40620300 0.07530800 1 - O O34 1 0.09379700 0.97631500 0.66910500 1 - O O35 1 0.52368500 0.61748200 0.69279000 1 - O O36 1 0.66910500 0.07530800 0.69279000 1 - O O37 1 0.61748200 0.69279000 0.52368500 1 - O O38 1 0.61748200 0.42469200 0.09379700 1 - O O39 1 0.69279000 0.52368500 0.61748200 1 - O O40 1 0.83089500 0.52368500 0.40620300 1 - O O41 1 0.97631500 0.80721000 0.88251800 1 - O O42 1 0.80721000 0.88251800 0.97631500 1 - O O43 1 0.69279000 0.66910500 0.07530800 1 - O O44 1 0.42469200 0.09379700 0.61748200 1 - O O45 1 0.40620300 0.83089500 0.52368500 1 - O O46 1 0.07530800 0.69279000 0.66910500 1 - O O47 1 0.09379700 0.61748200 0.42469200 1 - O O48 1 0.52368500 0.40620300 0.83089500 1 - O O49 1 0.07530800 0.88251800 0.40620300 1 - O O50 1 0.97631500 0.66910500 0.09379700 1 - O O51 1 0.16910500 0.47631500 0.59379700 1 - O O52 1 0.66910500 0.09379700 0.97631500 1 - O O53 1 0.80721000 0.42469200 0.83089500 1 - O O54 1 0.40620300 0.07530800 0.88251800 1 - O O55 1 0.88251800 0.97631500 0.80721000 1 - O O56 1 0.57530800 0.16910500 0.19279000 1 - O O57 1 0.11748200 0.59379700 0.92469200 1 - O O58 1 0.90620300 0.02368500 0.33089500 1 - O O59 1 0.47631500 0.38251800 0.30721000 1 - O O60 1 0.33089500 0.92469200 0.30721000 1 - O O61 1 0.38251800 0.30721000 0.47631500 1 - O O62 1 0.38251800 0.57530800 0.90620300 1 - O O63 1 0.30721000 0.47631500 0.38251800 1 - O O64 1 0.11748200 0.02368500 0.19279000 1 - O O65 1 0.59379700 0.92469200 0.11748200 1 - O O66 1 0.19279000 0.57530800 0.16910500 1 - O O67 1 0.16910500 0.19279000 0.57530800 1 - O O68 1 0.33089500 0.90620300 0.02368500 1 - O O69 1 0.02368500 0.33089500 0.90620300 1 - O O70 1 0.92469200 0.11748200 0.59379700 1 - O O71 1 0.47631500 0.59379700 0.16910500 1 - O O72 1 0.90620300 0.38251800 0.57530800 1 - O O73 1 0.92469200 0.30721000 0.33089500 1 - O O74 1 0.59379700 0.16910500 0.47631500 1 - O O75 1 0.57530800 0.90620300 0.38251800 1 - O O76 1 0.30721000 0.33089500 0.92469200 1 - O O77 1 0.19279000 0.11748200 0.02368500 1 - O O78 1 0.02368500 0.19279000 0.11748200 1 - O O79 1 0.83089500 0.80721000 0.42469200 1 -" -Sr3Y2(GeO4)3,mp-15103,Ia-3d,[80582],0.0,{'tags': ['Tristrontium diyttrium tris(germanate)']},"Full Formula (Sr12 Y8 Ge12 O48) -Reduced Formula: Sr3Y2(GeO4)3 -abc : 11.483052 11.483052 11.483052 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sr 0.75 0.125 0.375 -0 - 1 Sr 0.25 0.375 0.125 -0 - 2 Sr 0.125 0.25 0.375 -0 - 3 Sr 0.375 0.75 0.125 -0 - 4 Sr 0.75 0.625 0.875 -0 - 5 Sr 0.125 0.375 0.75 -0 - 6 Sr 0.625 0.875 0.75 -0 - 7 Sr 0.25 0.875 0.625 -0 - 8 Sr 0.875 0.625 0.25 -0 - 9 Sr 0.625 0.25 0.875 -0 - 10 Sr 0.875 0.75 0.625 -0 - 11 Sr 0.375 0.125 0.25 -0 - 12 Y 0 0 0 0 - 13 Y 0.5 0 0 0 - 14 Y 0 0.5 0 0 - 15 Y 0.5 0.5 0 0 - 16 Y 0 0.5 0.5 0 - 17 Y 0.5 0 0.5 0 - 18 Y 0.5 0.5 0.5 0 - 19 Y 0 0 0.5 0 - 20 Ge 0.125 0.875 0.25 -0 - 21 Ge 0.875 0.125 0.75 -0 - 22 Ge 0.25 0.625 0.375 -0 - 23 Ge 0.375 0.25 0.625 -0 - 24 Ge 0.75 0.875 0.125 -0 - 25 Ge 0.125 0.75 0.875 -0 - 26 Ge 0.375 0.625 0.75 -0 - 27 Ge 0.625 0.75 0.375 -0 - 28 Ge 0.875 0.25 0.125 -0 - 29 Ge 0.25 0.125 0.875 -0 - 30 Ge 0.75 0.375 0.625 -0 - 31 Ge 0.625 0.375 0.25 -0 - 32 O 0.409757 0.802187 0.7898 -0 - 33 O 0.880043 0.39243 0.090243 -0 - 34 O 0.10757 0.987613 0.697813 -0 - 35 O 0.512387 0.619957 0.7102 -0 - 36 O 0.697813 0.090243 0.7102 -0 - 37 O 0.619957 0.7102 0.512387 -0 - 38 O 0.619957 0.409757 0.10757 -0 - 39 O 0.7102 0.512387 0.619957 -0 - 40 O 0.802187 0.512387 0.39243 -0 - 41 O 0.987613 0.7898 0.880043 -0 - 42 O 0.7898 0.880043 0.987613 -0 - 43 O 0.7102 0.697813 0.090243 -0 - 44 O 0.409757 0.10757 0.619957 -0 - 45 O 0.39243 0.802187 0.512387 -0 - 46 O 0.090243 0.7102 0.697813 -0 - 47 O 0.10757 0.619957 0.409757 -0 - 48 O 0.512387 0.39243 0.802187 -0 - 49 O 0.090243 0.880043 0.39243 -0 - 50 O 0.987613 0.697813 0.10757 -0 - 51 O 0.197813 0.487613 0.60757 -0 - 52 O 0.697813 0.10757 0.987613 -0 - 53 O 0.7898 0.409757 0.802187 -0 - 54 O 0.39243 0.090243 0.880043 -0 - 55 O 0.880043 0.987613 0.7898 -0 - 56 O 0.590243 0.197813 0.2102 -0 - 57 O 0.119957 0.60757 0.909757 -0 - 58 O 0.89243 0.012387 0.302187 -0 - 59 O 0.487613 0.380043 0.2898 -0 - 60 O 0.302187 0.909757 0.2898 -0 - 61 O 0.380043 0.2898 0.487613 -0 - 62 O 0.380043 0.590243 0.89243 -0 - 63 O 0.2898 0.487613 0.380043 -0 - 64 O 0.119957 0.012387 0.2102 -0 - 65 O 0.60757 0.909757 0.119957 -0 - 66 O 0.2102 0.590243 0.197813 -0 - 67 O 0.197813 0.2102 0.590243 -0 - 68 O 0.302187 0.89243 0.012387 -0 - 69 O 0.012387 0.302187 0.89243 -0 - 70 O 0.909757 0.119957 0.60757 -0 - 71 O 0.487613 0.60757 0.197813 -0 - 72 O 0.89243 0.380043 0.590243 -0 - 73 O 0.909757 0.2898 0.302187 -0 - 74 O 0.60757 0.197813 0.487613 -0 - 75 O 0.590243 0.89243 0.380043 -0 - 76 O 0.2898 0.302187 0.909757 -0 - 77 O 0.2102 0.119957 0.012387 -0 - 78 O 0.012387 0.2102 0.119957 -0 - 79 O 0.802187 0.7898 0.409757 -0","# generated using pymatgen -data_Sr3Y2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.48305172 -_cell_length_b 11.48305172 -_cell_length_c 11.48305172 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sr3Y2(GeO4)3 -_chemical_formula_sum 'Sr12 Y8 Ge12 O48' -_cell_volume 1165.60143018 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sr Sr0 1 0.75000000 0.12500000 0.37500000 1 - Sr Sr1 1 0.25000000 0.37500000 0.12500000 1 - Sr Sr2 1 0.12500000 0.25000000 0.37500000 1 - Sr Sr3 1 0.37500000 0.75000000 0.12500000 1 - Sr Sr4 1 0.75000000 0.62500000 0.87500000 1 - Sr Sr5 1 0.12500000 0.37500000 0.75000000 1 - Sr Sr6 1 0.62500000 0.87500000 0.75000000 1 - Sr Sr7 1 0.25000000 0.87500000 0.62500000 1 - Sr Sr8 1 0.87500000 0.62500000 0.25000000 1 - Sr Sr9 1 0.62500000 0.25000000 0.87500000 1 - Sr Sr10 1 0.87500000 0.75000000 0.62500000 1 - Sr Sr11 1 0.37500000 0.12500000 0.25000000 1 - Y Y12 1 0.00000000 0.00000000 0.00000000 1 - Y Y13 1 0.50000000 0.00000000 0.00000000 1 - Y Y14 1 0.00000000 0.50000000 0.00000000 1 - Y Y15 1 0.50000000 0.50000000 0.00000000 1 - Y Y16 1 0.00000000 0.50000000 0.50000000 1 - Y Y17 1 0.50000000 0.00000000 0.50000000 1 - Y Y18 1 0.50000000 0.50000000 0.50000000 1 - Y Y19 1 0.00000000 0.00000000 0.50000000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge22 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge24 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge25 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge26 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge27 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge28 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge29 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge30 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.40975700 0.80218700 0.78980000 1 - O O33 1 0.88004300 0.39243000 0.09024300 1 - O O34 1 0.10757000 0.98761300 0.69781300 1 - O O35 1 0.51238700 0.61995700 0.71020000 1 - O O36 1 0.69781300 0.09024300 0.71020000 1 - O O37 1 0.61995700 0.71020000 0.51238700 1 - O O38 1 0.61995700 0.40975700 0.10757000 1 - O O39 1 0.71020000 0.51238700 0.61995700 1 - O O40 1 0.80218700 0.51238700 0.39243000 1 - O O41 1 0.98761300 0.78980000 0.88004300 1 - O O42 1 0.78980000 0.88004300 0.98761300 1 - O O43 1 0.71020000 0.69781300 0.09024300 1 - O O44 1 0.40975700 0.10757000 0.61995700 1 - O O45 1 0.39243000 0.80218700 0.51238700 1 - O O46 1 0.09024300 0.71020000 0.69781300 1 - O O47 1 0.10757000 0.61995700 0.40975700 1 - O O48 1 0.51238700 0.39243000 0.80218700 1 - O O49 1 0.09024300 0.88004300 0.39243000 1 - O O50 1 0.98761300 0.69781300 0.10757000 1 - O O51 1 0.19781300 0.48761300 0.60757000 1 - O O52 1 0.69781300 0.10757000 0.98761300 1 - O O53 1 0.78980000 0.40975700 0.80218700 1 - O O54 1 0.39243000 0.09024300 0.88004300 1 - O O55 1 0.88004300 0.98761300 0.78980000 1 - O O56 1 0.59024300 0.19781300 0.21020000 1 - O O57 1 0.11995700 0.60757000 0.90975700 1 - O O58 1 0.89243000 0.01238700 0.30218700 1 - O O59 1 0.48761300 0.38004300 0.28980000 1 - O O60 1 0.30218700 0.90975700 0.28980000 1 - O O61 1 0.38004300 0.28980000 0.48761300 1 - O O62 1 0.38004300 0.59024300 0.89243000 1 - O O63 1 0.28980000 0.48761300 0.38004300 1 - O O64 1 0.11995700 0.01238700 0.21020000 1 - O O65 1 0.60757000 0.90975700 0.11995700 1 - O O66 1 0.21020000 0.59024300 0.19781300 1 - O O67 1 0.19781300 0.21020000 0.59024300 1 - O O68 1 0.30218700 0.89243000 0.01238700 1 - O O69 1 0.01238700 0.30218700 0.89243000 1 - O O70 1 0.90975700 0.11995700 0.60757000 1 - O O71 1 0.48761300 0.60757000 0.19781300 1 - O O72 1 0.89243000 0.38004300 0.59024300 1 - O O73 1 0.90975700 0.28980000 0.30218700 1 - O O74 1 0.60757000 0.19781300 0.48761300 1 - O O75 1 0.59024300 0.89243000 0.38004300 1 - O O76 1 0.28980000 0.30218700 0.90975700 1 - O O77 1 0.21020000 0.11995700 0.01238700 1 - O O78 1 0.01238700 0.21020000 0.11995700 1 - O O79 1 0.80218700 0.78980000 0.40975700 1 -" -Na3Cr2(AsO4)3,mp-16383,Ia-3d,"[190756, 280946]",0.0,"{'tags': ['Trisodium dichromium tris(arsenate(V))', 'Trisodium dichromium triarsenate']}","Full Formula (Na12 Cr8 As12 O48) -Reduced Formula: Na3Cr2(AsO4)3 -abc : 10.720284 10.720284 10.720284 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.125 0.375 0.75 0.001 - 1 Na 0.375 0.125 0.25 0.001 - 2 Na 0.375 0.75 0.125 0.001 - 3 Na 0.125 0.25 0.375 0.001 - 4 Na 0.75 0.125 0.375 0.001 - 5 Na 0.25 0.375 0.125 0.001 - 6 Na 0.875 0.625 0.25 0.001 - 7 Na 0.625 0.875 0.75 0.001 - 8 Na 0.625 0.25 0.875 0.001 - 9 Na 0.875 0.75 0.625 0.001 - 10 Na 0.25 0.875 0.625 0.001 - 11 Na 0.75 0.625 0.875 0.001 - 12 Cr 0 0.5 0 2.939 - 13 Cr 0 0 0.5 2.938 - 14 Cr 0.5 0 0 2.938 - 15 Cr 0.5 0.5 0.5 2.939 - 16 Cr 0.5 0.5 0 2.939 - 17 Cr 0.5 0 0.5 2.938 - 18 Cr 0 0.5 0.5 2.938 - 19 Cr 0 0 0 2.939 - 20 As 0.375 0.625 0.75 0.012 - 21 As 0.125 0.875 0.25 0.012 - 22 As 0.625 0.75 0.375 0.012 - 23 As 0.875 0.25 0.125 0.012 - 24 As 0.75 0.375 0.625 0.012 - 25 As 0.25 0.125 0.875 0.012 - 26 As 0.625 0.375 0.25 0.012 - 27 As 0.875 0.125 0.75 0.012 - 28 As 0.375 0.25 0.625 0.012 - 29 As 0.125 0.75 0.875 0.012 - 30 As 0.25 0.625 0.375 0.012 - 31 As 0.75 0.875 0.125 0.012 - 32 O 0.086108 0.885824 0.396049 -0.009 - 33 O 0.989775 0.690059 0.103951 -0.009 - 34 O 0.510225 0.614176 0.700284 -0.009 - 35 O 0.413892 0.809941 0.799716 -0.009 - 36 O 0.885824 0.396049 0.086108 -0.009 - 37 O 0.690059 0.103951 0.989775 -0.007 - 38 O 0.614176 0.700284 0.510225 -0.009 - 39 O 0.809941 0.799716 0.413892 -0.007 - 40 O 0.396049 0.086108 0.885824 -0.008 - 41 O 0.103951 0.989775 0.690059 -0.008 - 42 O 0.700284 0.510225 0.614176 -0.008 - 43 O 0.799716 0.413892 0.809941 -0.008 - 44 O 0.913892 0.114176 0.603951 -0.009 - 45 O 0.010225 0.309941 0.896049 -0.009 - 46 O 0.489775 0.385824 0.299716 -0.009 - 47 O 0.586108 0.190059 0.200284 -0.009 - 48 O 0.114176 0.603951 0.913892 -0.009 - 49 O 0.309941 0.896049 0.010225 -0.007 - 50 O 0.385824 0.299716 0.489775 -0.009 - 51 O 0.190059 0.200284 0.586108 -0.007 - 52 O 0.603951 0.913892 0.114176 -0.008 - 53 O 0.896049 0.010225 0.309941 -0.008 - 54 O 0.299716 0.489775 0.385824 -0.008 - 55 O 0.200284 0.586108 0.190059 -0.008 - 56 O 0.586108 0.896049 0.385824 -0.009 - 57 O 0.489775 0.603951 0.190059 -0.009 - 58 O 0.010225 0.200284 0.114176 -0.009 - 59 O 0.913892 0.299716 0.309941 -0.009 - 60 O 0.385824 0.586108 0.896049 -0.009 - 61 O 0.190059 0.489775 0.603951 -0.007 - 62 O 0.114176 0.010225 0.200284 -0.009 - 63 O 0.309941 0.913892 0.299716 -0.007 - 64 O 0.896049 0.385824 0.586108 -0.008 - 65 O 0.603951 0.190059 0.489775 -0.008 - 66 O 0.200284 0.114176 0.010225 -0.008 - 67 O 0.299716 0.309941 0.913892 -0.008 - 68 O 0.413892 0.103951 0.614176 -0.009 - 69 O 0.510225 0.396049 0.809941 -0.009 - 70 O 0.989775 0.799716 0.885824 -0.009 - 71 O 0.086108 0.700284 0.690059 -0.009 - 72 O 0.614176 0.413892 0.103951 -0.009 - 73 O 0.809941 0.510225 0.396049 -0.007 - 74 O 0.885824 0.989775 0.799716 -0.009 - 75 O 0.690059 0.086108 0.700284 -0.007 - 76 O 0.103951 0.614176 0.413892 -0.008 - 77 O 0.396049 0.809941 0.510225 -0.008 - 78 O 0.799716 0.885824 0.989775 -0.008 - 79 O 0.700284 0.690059 0.086108 -0.008","# generated using pymatgen -data_Na3Cr2(AsO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.72028425 -_cell_length_b 10.72028425 -_cell_length_c 10.72028425 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Cr2(AsO4)3 -_chemical_formula_sum 'Na12 Cr8 As12 O48' -_cell_volume 948.41193908 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.12500000 0.37500000 0.75000000 1 - Na Na1 1 0.37500000 0.12500000 0.25000000 1 - Na Na2 1 0.37500000 0.75000000 0.12500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.75000000 0.12500000 0.37500000 1 - Na Na5 1 0.25000000 0.37500000 0.12500000 1 - Na Na6 1 0.87500000 0.62500000 0.25000000 1 - Na Na7 1 0.62500000 0.87500000 0.75000000 1 - Na Na8 1 0.62500000 0.25000000 0.87500000 1 - Na Na9 1 0.87500000 0.75000000 0.62500000 1 - Na Na10 1 0.25000000 0.87500000 0.62500000 1 - Na Na11 1 0.75000000 0.62500000 0.87500000 1 - Cr Cr12 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr13 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr14 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr15 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr16 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr17 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr18 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.00000000 1 - As As20 1 0.37500000 0.62500000 0.75000000 1 - As As21 1 0.12500000 0.87500000 0.25000000 1 - As As22 1 0.62500000 0.75000000 0.37500000 1 - As As23 1 0.87500000 0.25000000 0.12500000 1 - As As24 1 0.75000000 0.37500000 0.62500000 1 - As As25 1 0.25000000 0.12500000 0.87500000 1 - As As26 1 0.62500000 0.37500000 0.25000000 1 - As As27 1 0.87500000 0.12500000 0.75000000 1 - As As28 1 0.37500000 0.25000000 0.62500000 1 - As As29 1 0.12500000 0.75000000 0.87500000 1 - As As30 1 0.25000000 0.62500000 0.37500000 1 - As As31 1 0.75000000 0.87500000 0.12500000 1 - O O32 1 0.08610800 0.88582400 0.39604900 1 - O O33 1 0.98977500 0.69005900 0.10395100 1 - O O34 1 0.51022500 0.61417600 0.70028400 1 - O O35 1 0.41389200 0.80994100 0.79971600 1 - O O36 1 0.88582400 0.39604900 0.08610800 1 - O O37 1 0.69005900 0.10395100 0.98977500 1 - O O38 1 0.61417600 0.70028400 0.51022500 1 - O O39 1 0.80994100 0.79971600 0.41389200 1 - O O40 1 0.39604900 0.08610800 0.88582400 1 - O O41 1 0.10395100 0.98977500 0.69005900 1 - O O42 1 0.70028400 0.51022500 0.61417600 1 - O O43 1 0.79971600 0.41389200 0.80994100 1 - O O44 1 0.91389200 0.11417600 0.60395100 1 - O O45 1 0.01022500 0.30994100 0.89604900 1 - O O46 1 0.48977500 0.38582400 0.29971600 1 - O O47 1 0.58610800 0.19005900 0.20028400 1 - O O48 1 0.11417600 0.60395100 0.91389200 1 - O O49 1 0.30994100 0.89604900 0.01022500 1 - O O50 1 0.38582400 0.29971600 0.48977500 1 - O O51 1 0.19005900 0.20028400 0.58610800 1 - O O52 1 0.60395100 0.91389200 0.11417600 1 - O O53 1 0.89604900 0.01022500 0.30994100 1 - O O54 1 0.29971600 0.48977500 0.38582400 1 - O O55 1 0.20028400 0.58610800 0.19005900 1 - O O56 1 0.58610800 0.89604900 0.38582400 1 - O O57 1 0.48977500 0.60395100 0.19005900 1 - O O58 1 0.01022500 0.20028400 0.11417600 1 - O O59 1 0.91389200 0.29971600 0.30994100 1 - O O60 1 0.38582400 0.58610800 0.89604900 1 - O O61 1 0.19005900 0.48977500 0.60395100 1 - O O62 1 0.11417600 0.01022500 0.20028400 1 - O O63 1 0.30994100 0.91389200 0.29971600 1 - O O64 1 0.89604900 0.38582400 0.58610800 1 - O O65 1 0.60395100 0.19005900 0.48977500 1 - O O66 1 0.20028400 0.11417600 0.01022500 1 - O O67 1 0.29971600 0.30994100 0.91389200 1 - O O68 1 0.41389200 0.10395100 0.61417600 1 - O O69 1 0.51022500 0.39604900 0.80994100 1 - O O70 1 0.98977500 0.79971600 0.88582400 1 - O O71 1 0.08610800 0.70028400 0.69005900 1 - O O72 1 0.61417600 0.41389200 0.10395100 1 - O O73 1 0.80994100 0.51022500 0.39604900 1 - O O74 1 0.88582400 0.98977500 0.79971600 1 - O O75 1 0.69005900 0.08610800 0.70028400 1 - O O76 1 0.10395100 0.61417600 0.41389200 1 - O O77 1 0.39604900 0.80994100 0.51022500 1 - O O78 1 0.79971600 0.88582400 0.98977500 1 - O O79 1 0.70028400 0.69005900 0.08610800 1 -" -V2Fe3(SiO4)3,mp-21791,Ia-3d,[27376],0.0925292576874952,{'tags': ['Triiron divanadium(III) silicate']},"Full Formula (V8 Fe12 Si12 O48) -Reduced Formula: V2Fe3(SiO4)3 -abc : 10.309083 10.309083 10.309083 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 V 0.5 0.5 0.5 1.97 - 1 V 0.5 0 0.5 1.954 - 2 V 0 0.5 0.5 1.964 - 3 V 0.5 0.5 0 1.969 - 4 V 0 0 0.5 1.964 - 5 V 0 0.5 0 1.969 - 6 V 0.5 0 0 1.955 - 7 V 0 0 0 1.97 - 8 Fe 0.875 0.625 0.25 3.791 - 9 Fe 0.625 0.25 0.875 3.791 - 10 Fe 0.875 0.75 0.625 3.791 - 11 Fe 0.75 0.625 0.875 3.791 - 12 Fe 0.25 0.875 0.625 3.791 - 13 Fe 0.625 0.875 0.75 3.791 - 14 Fe 0.125 0.375 0.75 3.791 - 15 Fe 0.375 0.75 0.125 3.791 - 16 Fe 0.125 0.25 0.375 3.791 - 17 Fe 0.25 0.375 0.125 3.791 - 18 Fe 0.75 0.125 0.375 3.791 - 19 Fe 0.375 0.125 0.25 3.791 - 20 Si 0.125 0.875 0.25 0.013 - 21 Si 0.875 0.125 0.75 0.013 - 22 Si 0.25 0.625 0.375 0.013 - 23 Si 0.375 0.25 0.625 0.013 - 24 Si 0.75 0.875 0.125 0.013 - 25 Si 0.125 0.75 0.875 0.013 - 26 Si 0.375 0.625 0.75 0.013 - 27 Si 0.625 0.75 0.375 0.013 - 28 Si 0.875 0.25 0.125 0.013 - 29 Si 0.25 0.125 0.875 0.013 - 30 Si 0.75 0.375 0.625 0.013 - 31 Si 0.625 0.375 0.25 0.013 - 32 O 0.693405 0.088704 0.711077 0.011 - 33 O 0.1047 0.982328 0.693405 0.011 - 34 O 0.711077 0.517672 0.622372 0.012 - 35 O 0.622372 0.711077 0.517672 0.012 - 36 O 0.877628 0.3953 0.088704 0.011 - 37 O 0.088704 0.877628 0.3953 0.011 - 38 O 0.982328 0.693405 0.1047 0.012 - 39 O 0.411296 0.1047 0.622372 0.011 - 40 O 0.3953 0.806595 0.517672 0.011 - 41 O 0.982328 0.788923 0.877628 0.012 - 42 O 0.1047 0.622372 0.411296 0.011 - 43 O 0.517672 0.3953 0.806595 0.011 - 44 O 0.788923 0.877628 0.982328 0.012 - 45 O 0.711077 0.693405 0.088704 0.012 - 46 O 0.088704 0.711077 0.693405 0.011 - 47 O 0.622372 0.411296 0.1047 0.012 - 48 O 0.788923 0.411296 0.806595 0.012 - 49 O 0.806595 0.517672 0.3953 0.011 - 50 O 0.806595 0.788923 0.411296 0.011 - 51 O 0.877628 0.982328 0.788923 0.011 - 52 O 0.411296 0.806595 0.788923 0.011 - 53 O 0.3953 0.088704 0.877628 0.011 - 54 O 0.693405 0.1047 0.982328 0.011 - 55 O 0.517672 0.622372 0.711077 0.011 - 56 O 0.306595 0.911296 0.288923 0.011 - 57 O 0.8953 0.017672 0.306595 0.011 - 58 O 0.288923 0.482328 0.377628 0.012 - 59 O 0.377628 0.288923 0.482328 0.012 - 60 O 0.122372 0.6047 0.911296 0.011 - 61 O 0.911296 0.122372 0.6047 0.011 - 62 O 0.017672 0.306595 0.8953 0.012 - 63 O 0.588704 0.8953 0.377628 0.011 - 64 O 0.6047 0.193405 0.482328 0.011 - 65 O 0.017672 0.211077 0.122372 0.012 - 66 O 0.8953 0.377628 0.588704 0.011 - 67 O 0.482328 0.6047 0.193405 0.011 - 68 O 0.211077 0.122372 0.017672 0.012 - 69 O 0.288923 0.306595 0.911296 0.012 - 70 O 0.911296 0.288923 0.306595 0.011 - 71 O 0.377628 0.588704 0.8953 0.012 - 72 O 0.211077 0.588704 0.193405 0.012 - 73 O 0.193405 0.482328 0.6047 0.011 - 74 O 0.193405 0.211077 0.588704 0.011 - 75 O 0.122372 0.017672 0.211077 0.011 - 76 O 0.588704 0.193405 0.211077 0.011 - 77 O 0.6047 0.911296 0.122372 0.011 - 78 O 0.306595 0.8953 0.017672 0.011 - 79 O 0.482328 0.377628 0.288923 0.011","# generated using pymatgen -data_V2Fe3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.30908327 -_cell_length_b 10.30908327 -_cell_length_c 10.30908327 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural V2Fe3(SiO4)3 -_chemical_formula_sum 'V8 Fe12 Si12 O48' -_cell_volume 843.40904025 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - V V0 1 0.50000000 0.50000000 0.50000000 1 - V V1 1 0.50000000 0.00000000 0.50000000 1 - V V2 1 0.00000000 0.50000000 0.50000000 1 - V V3 1 0.50000000 0.50000000 0.00000000 1 - V V4 1 0.00000000 0.00000000 0.50000000 1 - V V5 1 0.00000000 0.50000000 0.00000000 1 - V V6 1 0.50000000 0.00000000 0.00000000 1 - V V7 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe8 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe9 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe10 1 0.87500000 0.75000000 0.62500000 1 - Fe Fe11 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe12 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe13 1 0.62500000 0.87500000 0.75000000 1 - Fe Fe14 1 0.12500000 0.37500000 0.75000000 1 - Fe Fe15 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe16 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe17 1 0.25000000 0.37500000 0.12500000 1 - Fe Fe18 1 0.75000000 0.12500000 0.37500000 1 - Fe Fe19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.69340500 0.08870400 0.71107700 1 - O O33 1 0.10470000 0.98232800 0.69340500 1 - O O34 1 0.71107700 0.51767200 0.62237200 1 - O O35 1 0.62237200 0.71107700 0.51767200 1 - O O36 1 0.87762800 0.39530000 0.08870400 1 - O O37 1 0.08870400 0.87762800 0.39530000 1 - O O38 1 0.98232800 0.69340500 0.10470000 1 - O O39 1 0.41129600 0.10470000 0.62237200 1 - O O40 1 0.39530000 0.80659500 0.51767200 1 - O O41 1 0.98232800 0.78892300 0.87762800 1 - O O42 1 0.10470000 0.62237200 0.41129600 1 - O O43 1 0.51767200 0.39530000 0.80659500 1 - O O44 1 0.78892300 0.87762800 0.98232800 1 - O O45 1 0.71107700 0.69340500 0.08870400 1 - O O46 1 0.08870400 0.71107700 0.69340500 1 - O O47 1 0.62237200 0.41129600 0.10470000 1 - O O48 1 0.78892300 0.41129600 0.80659500 1 - O O49 1 0.80659500 0.51767200 0.39530000 1 - O O50 1 0.80659500 0.78892300 0.41129600 1 - O O51 1 0.87762800 0.98232800 0.78892300 1 - O O52 1 0.41129600 0.80659500 0.78892300 1 - O O53 1 0.39530000 0.08870400 0.87762800 1 - O O54 1 0.69340500 0.10470000 0.98232800 1 - O O55 1 0.51767200 0.62237200 0.71107700 1 - O O56 1 0.30659500 0.91129600 0.28892300 1 - O O57 1 0.89530000 0.01767200 0.30659500 1 - O O58 1 0.28892300 0.48232800 0.37762800 1 - O O59 1 0.37762800 0.28892300 0.48232800 1 - O O60 1 0.12237200 0.60470000 0.91129600 1 - O O61 1 0.91129600 0.12237200 0.60470000 1 - O O62 1 0.01767200 0.30659500 0.89530000 1 - O O63 1 0.58870400 0.89530000 0.37762800 1 - O O64 1 0.60470000 0.19340500 0.48232800 1 - O O65 1 0.01767200 0.21107700 0.12237200 1 - O O66 1 0.89530000 0.37762800 0.58870400 1 - O O67 1 0.48232800 0.60470000 0.19340500 1 - O O68 1 0.21107700 0.12237200 0.01767200 1 - O O69 1 0.28892300 0.30659500 0.91129600 1 - O O70 1 0.91129600 0.28892300 0.30659500 1 - O O71 1 0.37762800 0.58870400 0.89530000 1 - O O72 1 0.21107700 0.58870400 0.19340500 1 - O O73 1 0.19340500 0.48232800 0.60470000 1 - O O74 1 0.19340500 0.21107700 0.58870400 1 - O O75 1 0.12237200 0.01767200 0.21107700 1 - O O76 1 0.58870400 0.19340500 0.21107700 1 - O O77 1 0.60470000 0.91129600 0.12237200 1 - O O78 1 0.30659500 0.89530000 0.01767200 1 - O O79 1 0.48232800 0.37762800 0.28892300 1 -" -Na3Li3Co2F12,mp-21932,Ia-3d,[60367],0.0,{'tags': ['Trisodium trilithium dicobalt dodecafluoride']},"Full Formula (Na12 Li12 Co8 F48) -Reduced Formula: Na3Li3Co2F12 -abc : 10.842096 10.842096 10.842096 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.875 0.75 0.625 0.001 - 1 Na 0.625 0.25 0.875 0.001 - 2 Na 0.25 0.875 0.625 0.001 - 3 Na 0.875 0.625 0.25 0.001 - 4 Na 0.625 0.875 0.75 0.001 - 5 Na 0.75 0.625 0.875 0.001 - 6 Na 0.125 0.25 0.375 0.001 - 7 Na 0.375 0.75 0.125 0.001 - 8 Na 0.75 0.125 0.375 0.001 - 9 Na 0.125 0.375 0.75 0.001 - 10 Na 0.25 0.375 0.125 0.001 - 11 Na 0.375 0.125 0.25 0.001 - 12 Li 0.625 0.375 0.25 0.002 - 13 Li 0.25 0.125 0.875 0.002 - 14 Li 0.75 0.875 0.125 0.002 - 15 Li 0.125 0.75 0.875 0.002 - 16 Li 0.375 0.25 0.625 0.002 - 17 Li 0.875 0.125 0.75 0.002 - 18 Li 0.875 0.25 0.125 0.002 - 19 Li 0.625 0.75 0.375 0.002 - 20 Li 0.75 0.375 0.625 0.002 - 21 Li 0.375 0.625 0.75 0.002 - 22 Li 0.125 0.875 0.25 0.002 - 23 Li 0.25 0.625 0.375 0.002 - 24 Co 0.5 0.5 0.5 3.266 - 25 Co 0.5 0 0.5 3.266 - 26 Co 0 0.5 0.5 3.266 - 27 Co 0.5 0.5 0 3.266 - 28 Co 0 0 0.5 3.266 - 29 Co 0 0.5 0 3.266 - 30 Co 0.5 0 0 3.266 - 31 Co 0 0 0 3.266 - 32 F 0.422367 0.825459 0.808693 0.107 - 33 F 0.403092 0.825459 0.516767 0.107 - 34 F 0.077633 0.691307 0.674541 0.107 - 35 F 0.096908 0.613675 0.422367 0.107 - 36 F 0.516767 0.403092 0.825459 0.107 - 37 F 0.077633 0.886325 0.403092 0.107 - 38 F 0.983233 0.674541 0.096908 0.107 - 39 F 0.825459 0.808693 0.422367 0.108 - 40 F 0.691307 0.674541 0.077633 0.108 - 41 F 0.808693 0.886325 0.983233 0.108 - 42 F 0.983233 0.808693 0.886325 0.107 - 43 F 0.825459 0.516767 0.403092 0.108 - 44 F 0.691307 0.516767 0.613675 0.108 - 45 F 0.613675 0.422367 0.096908 0.107 - 46 F 0.613675 0.691307 0.516767 0.107 - 47 F 0.674541 0.077633 0.691307 0.108 - 48 F 0.516767 0.613675 0.691307 0.107 - 49 F 0.422367 0.096908 0.613675 0.107 - 50 F 0.096908 0.983233 0.674541 0.107 - 51 F 0.886325 0.403092 0.077633 0.107 - 52 F 0.113675 0.016767 0.191307 0.107 - 53 F 0.596908 0.922367 0.113675 0.107 - 54 F 0.191307 0.577633 0.174541 0.108 - 55 F 0.174541 0.191307 0.577633 0.108 - 56 F 0.325459 0.903092 0.016767 0.108 - 57 F 0.016767 0.325459 0.903092 0.107 - 58 F 0.922367 0.113675 0.596908 0.107 - 59 F 0.483233 0.596908 0.174541 0.107 - 60 F 0.903092 0.386325 0.577633 0.107 - 61 F 0.922367 0.308693 0.325459 0.107 - 62 F 0.596908 0.174541 0.483233 0.107 - 63 F 0.577633 0.903092 0.386325 0.107 - 64 F 0.308693 0.325459 0.922367 0.108 - 65 F 0.191307 0.113675 0.016767 0.108 - 66 F 0.016767 0.191307 0.113675 0.107 - 67 F 0.174541 0.483233 0.596908 0.108 - 68 F 0.308693 0.483233 0.386325 0.108 - 69 F 0.386325 0.577633 0.903092 0.107 - 70 F 0.386325 0.308693 0.483233 0.107 - 71 F 0.325459 0.922367 0.308693 0.108 - 72 F 0.483233 0.386325 0.308693 0.107 - 73 F 0.903092 0.016767 0.325459 0.107 - 74 F 0.113675 0.596908 0.922367 0.107 - 75 F 0.577633 0.174541 0.191307 0.107 - 76 F 0.886325 0.983233 0.808693 0.107 - 77 F 0.403092 0.077633 0.886325 0.107 - 78 F 0.808693 0.422367 0.825459 0.108 - 79 F 0.674541 0.096908 0.983233 0.108","# generated using pymatgen -data_Na3Li3Co2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.84209592 -_cell_length_b 10.84209592 -_cell_length_c 10.84209592 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3Co2F12 -_chemical_formula_sum 'Na12 Li12 Co8 F48' -_cell_volume 981.11032273 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.87500000 0.75000000 0.62500000 1 - Na Na1 1 0.62500000 0.25000000 0.87500000 1 - Na Na2 1 0.25000000 0.87500000 0.62500000 1 - Na Na3 1 0.87500000 0.62500000 0.25000000 1 - Na Na4 1 0.62500000 0.87500000 0.75000000 1 - Na Na5 1 0.75000000 0.62500000 0.87500000 1 - Na Na6 1 0.12500000 0.25000000 0.37500000 1 - Na Na7 1 0.37500000 0.75000000 0.12500000 1 - Na Na8 1 0.75000000 0.12500000 0.37500000 1 - Na Na9 1 0.12500000 0.37500000 0.75000000 1 - Na Na10 1 0.25000000 0.37500000 0.12500000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Li Li12 1 0.62500000 0.37500000 0.25000000 1 - Li Li13 1 0.25000000 0.12500000 0.87500000 1 - Li Li14 1 0.75000000 0.87500000 0.12500000 1 - Li Li15 1 0.12500000 0.75000000 0.87500000 1 - Li Li16 1 0.37500000 0.25000000 0.62500000 1 - Li Li17 1 0.87500000 0.12500000 0.75000000 1 - Li Li18 1 0.87500000 0.25000000 0.12500000 1 - Li Li19 1 0.62500000 0.75000000 0.37500000 1 - Li Li20 1 0.75000000 0.37500000 0.62500000 1 - Li Li21 1 0.37500000 0.62500000 0.75000000 1 - Li Li22 1 0.12500000 0.87500000 0.25000000 1 - Li Li23 1 0.25000000 0.62500000 0.37500000 1 - Co Co24 1 0.50000000 0.50000000 0.50000000 1 - Co Co25 1 0.50000000 0.00000000 0.50000000 1 - Co Co26 1 0.00000000 0.50000000 0.50000000 1 - Co Co27 1 0.50000000 0.50000000 0.00000000 1 - Co Co28 1 0.00000000 0.00000000 0.50000000 1 - Co Co29 1 0.00000000 0.50000000 0.00000000 1 - Co Co30 1 0.50000000 0.00000000 0.00000000 1 - Co Co31 1 0.00000000 0.00000000 0.00000000 1 - F F32 1 0.42236700 0.82545900 0.80869300 1 - F F33 1 0.40309200 0.82545900 0.51676700 1 - F F34 1 0.07763300 0.69130700 0.67454100 1 - F F35 1 0.09690800 0.61367500 0.42236700 1 - F F36 1 0.51676700 0.40309200 0.82545900 1 - F F37 1 0.07763300 0.88632500 0.40309200 1 - F F38 1 0.98323300 0.67454100 0.09690800 1 - F F39 1 0.82545900 0.80869300 0.42236700 1 - F F40 1 0.69130700 0.67454100 0.07763300 1 - F F41 1 0.80869300 0.88632500 0.98323300 1 - F F42 1 0.98323300 0.80869300 0.88632500 1 - F F43 1 0.82545900 0.51676700 0.40309200 1 - F F44 1 0.69130700 0.51676700 0.61367500 1 - F F45 1 0.61367500 0.42236700 0.09690800 1 - F F46 1 0.61367500 0.69130700 0.51676700 1 - F F47 1 0.67454100 0.07763300 0.69130700 1 - F F48 1 0.51676700 0.61367500 0.69130700 1 - F F49 1 0.42236700 0.09690800 0.61367500 1 - F F50 1 0.09690800 0.98323300 0.67454100 1 - F F51 1 0.88632500 0.40309200 0.07763300 1 - F F52 1 0.11367500 0.01676700 0.19130700 1 - F F53 1 0.59690800 0.92236700 0.11367500 1 - F F54 1 0.19130700 0.57763300 0.17454100 1 - F F55 1 0.17454100 0.19130700 0.57763300 1 - F F56 1 0.32545900 0.90309200 0.01676700 1 - F F57 1 0.01676700 0.32545900 0.90309200 1 - F F58 1 0.92236700 0.11367500 0.59690800 1 - F F59 1 0.48323300 0.59690800 0.17454100 1 - F F60 1 0.90309200 0.38632500 0.57763300 1 - F F61 1 0.92236700 0.30869300 0.32545900 1 - F F62 1 0.59690800 0.17454100 0.48323300 1 - F F63 1 0.57763300 0.90309200 0.38632500 1 - F F64 1 0.30869300 0.32545900 0.92236700 1 - F F65 1 0.19130700 0.11367500 0.01676700 1 - F F66 1 0.01676700 0.19130700 0.11367500 1 - F F67 1 0.17454100 0.48323300 0.59690800 1 - F F68 1 0.30869300 0.48323300 0.38632500 1 - F F69 1 0.38632500 0.57763300 0.90309200 1 - F F70 1 0.38632500 0.30869300 0.48323300 1 - F F71 1 0.32545900 0.92236700 0.30869300 1 - F F72 1 0.48323300 0.38632500 0.30869300 1 - F F73 1 0.90309200 0.01676700 0.32545900 1 - F F74 1 0.11367500 0.59690800 0.92236700 1 - F F75 1 0.57763300 0.17454100 0.19130700 1 - F F76 1 0.88632500 0.98323300 0.80869300 1 - F F77 1 0.40309200 0.07763300 0.88632500 1 - F F78 1 0.80869300 0.42236700 0.82545900 1 - F F79 1 0.67454100 0.09690800 0.98323300 1 -" -Ca3Fe2(GeO4)3,mp-21971,Ia-3d,"[280047, 28176]",0.0,"{'tags': ['Germanoandradite', 'Tricalcium diiron trigermanium oxide', 'Tricalcium diiron(III) germanate']}","Full Formula (Ca12 Fe8 Ge12 O48) -Reduced Formula: Ca3Fe2(GeO4)3 -abc : 10.800880 10.800880 10.800880 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0.003 - 1 Ca 0.75 0.625 0.875 0.003 - 2 Ca 0.625 0.875 0.75 0.003 - 3 Ca 0.875 0.625 0.25 0.003 - 4 Ca 0.625 0.25 0.875 0.003 - 5 Ca 0.875 0.75 0.625 0.003 - 6 Ca 0.75 0.125 0.375 0.003 - 7 Ca 0.25 0.375 0.125 0.003 - 8 Ca 0.375 0.125 0.25 0.003 - 9 Ca 0.125 0.375 0.75 0.003 - 10 Ca 0.375 0.75 0.125 0.003 - 11 Ca 0.125 0.25 0.375 0.003 - 12 Fe 0.5 0.5 0.5 4.366 - 13 Fe 0.5 0 0.5 4.366 - 14 Fe 0 0.5 0.5 4.366 - 15 Fe 0.5 0.5 0 4.366 - 16 Fe 0 0 0.5 4.366 - 17 Fe 0 0.5 0 4.366 - 18 Fe 0.5 0 0 4.366 - 19 Fe 0 0 0 4.366 - 20 Ge 0.125 0.75 0.875 0.026 - 21 Ge 0.875 0.25 0.125 0.026 - 22 Ge 0.625 0.375 0.25 0.026 - 23 Ge 0.75 0.875 0.125 0.026 - 24 Ge 0.875 0.125 0.75 0.026 - 25 Ge 0.25 0.625 0.375 0.026 - 26 Ge 0.75 0.375 0.625 0.026 - 27 Ge 0.25 0.125 0.875 0.026 - 28 Ge 0.125 0.875 0.25 0.026 - 29 Ge 0.375 0.625 0.75 0.026 - 30 Ge 0.625 0.75 0.375 0.026 - 31 Ge 0.375 0.25 0.625 0.026 - 32 O 0.415366 0.814229 0.796676 0.081 - 33 O 0.88131 0.398863 0.084634 0.081 - 34 O 0.101137 0.982448 0.685771 0.081 - 35 O 0.517552 0.61869 0.703324 0.081 - 36 O 0.685771 0.084634 0.703324 0.081 - 37 O 0.61869 0.703324 0.517552 0.081 - 38 O 0.61869 0.415366 0.101137 0.081 - 39 O 0.703324 0.517552 0.61869 0.081 - 40 O 0.814229 0.517552 0.398863 0.081 - 41 O 0.982448 0.796676 0.88131 0.081 - 42 O 0.796676 0.88131 0.982448 0.081 - 43 O 0.703324 0.685771 0.084634 0.081 - 44 O 0.415366 0.101137 0.61869 0.081 - 45 O 0.398863 0.814229 0.517552 0.081 - 46 O 0.084634 0.703324 0.685771 0.081 - 47 O 0.101137 0.61869 0.415366 0.081 - 48 O 0.517552 0.398863 0.814229 0.081 - 49 O 0.084634 0.88131 0.398863 0.081 - 50 O 0.982448 0.685771 0.101137 0.081 - 51 O 0.185771 0.482448 0.601137 0.081 - 52 O 0.685771 0.101137 0.982448 0.081 - 53 O 0.796676 0.415366 0.814229 0.081 - 54 O 0.398863 0.084634 0.88131 0.081 - 55 O 0.88131 0.982448 0.796676 0.081 - 56 O 0.584634 0.185771 0.203324 0.081 - 57 O 0.11869 0.601137 0.915366 0.081 - 58 O 0.898863 0.017552 0.314229 0.081 - 59 O 0.482448 0.38131 0.296676 0.081 - 60 O 0.314229 0.915366 0.296676 0.081 - 61 O 0.38131 0.296676 0.482448 0.081 - 62 O 0.38131 0.584634 0.898863 0.081 - 63 O 0.296676 0.482448 0.38131 0.081 - 64 O 0.11869 0.017552 0.203324 0.081 - 65 O 0.601137 0.915366 0.11869 0.081 - 66 O 0.203324 0.584634 0.185771 0.081 - 67 O 0.185771 0.203324 0.584634 0.081 - 68 O 0.314229 0.898863 0.017552 0.081 - 69 O 0.017552 0.314229 0.898863 0.081 - 70 O 0.915366 0.11869 0.601137 0.081 - 71 O 0.482448 0.601137 0.185771 0.081 - 72 O 0.898863 0.38131 0.584634 0.081 - 73 O 0.915366 0.296676 0.314229 0.081 - 74 O 0.601137 0.185771 0.482448 0.081 - 75 O 0.584634 0.898863 0.38131 0.081 - 76 O 0.296676 0.314229 0.915366 0.081 - 77 O 0.203324 0.11869 0.017552 0.081 - 78 O 0.017552 0.203324 0.11869 0.081 - 79 O 0.814229 0.796676 0.415366 0.081","# generated using pymatgen -data_Ca3Fe2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80088004 -_cell_length_b 10.80088004 -_cell_length_c 10.80088004 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Fe2(GeO4)3 -_chemical_formula_sum 'Ca12 Fe8 Ge12 O48' -_cell_volume 969.96382481 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe12 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe13 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41536600 0.81422900 0.79667600 1 - O O33 1 0.88131000 0.39886300 0.08463400 1 - O O34 1 0.10113700 0.98244800 0.68577100 1 - O O35 1 0.51755200 0.61869000 0.70332400 1 - O O36 1 0.68577100 0.08463400 0.70332400 1 - O O37 1 0.61869000 0.70332400 0.51755200 1 - O O38 1 0.61869000 0.41536600 0.10113700 1 - O O39 1 0.70332400 0.51755200 0.61869000 1 - O O40 1 0.81422900 0.51755200 0.39886300 1 - O O41 1 0.98244800 0.79667600 0.88131000 1 - O O42 1 0.79667600 0.88131000 0.98244800 1 - O O43 1 0.70332400 0.68577100 0.08463400 1 - O O44 1 0.41536600 0.10113700 0.61869000 1 - O O45 1 0.39886300 0.81422900 0.51755200 1 - O O46 1 0.08463400 0.70332400 0.68577100 1 - O O47 1 0.10113700 0.61869000 0.41536600 1 - O O48 1 0.51755200 0.39886300 0.81422900 1 - O O49 1 0.08463400 0.88131000 0.39886300 1 - O O50 1 0.98244800 0.68577100 0.10113700 1 - O O51 1 0.18577100 0.48244800 0.60113700 1 - O O52 1 0.68577100 0.10113700 0.98244800 1 - O O53 1 0.79667600 0.41536600 0.81422900 1 - O O54 1 0.39886300 0.08463400 0.88131000 1 - O O55 1 0.88131000 0.98244800 0.79667600 1 - O O56 1 0.58463400 0.18577100 0.20332400 1 - O O57 1 0.11869000 0.60113700 0.91536600 1 - O O58 1 0.89886300 0.01755200 0.31422900 1 - O O59 1 0.48244800 0.38131000 0.29667600 1 - O O60 1 0.31422900 0.91536600 0.29667600 1 - O O61 1 0.38131000 0.29667600 0.48244800 1 - O O62 1 0.38131000 0.58463400 0.89886300 1 - O O63 1 0.29667600 0.48244800 0.38131000 1 - O O64 1 0.11869000 0.01755200 0.20332400 1 - O O65 1 0.60113700 0.91536600 0.11869000 1 - O O66 1 0.20332400 0.58463400 0.18577100 1 - O O67 1 0.18577100 0.20332400 0.58463400 1 - O O68 1 0.31422900 0.89886300 0.01755200 1 - O O69 1 0.01755200 0.31422900 0.89886300 1 - O O70 1 0.91536600 0.11869000 0.60113700 1 - O O71 1 0.48244800 0.60113700 0.18577100 1 - O O72 1 0.89886300 0.38131000 0.58463400 1 - O O73 1 0.91536600 0.29667600 0.31422900 1 - O O74 1 0.60113700 0.18577100 0.48244800 1 - O O75 1 0.58463400 0.89886300 0.38131000 1 - O O76 1 0.29667600 0.31422900 0.91536600 1 - O O77 1 0.20332400 0.11869000 0.01755200 1 - O O78 1 0.01755200 0.20332400 0.11869000 1 - O O79 1 0.81422900 0.79667600 0.41536600 1 -" -Ca3Sc2(GeO4)3,mp-21989,Ia-3d,[20215],0.0,"{'tags': ['Garnet-(Ca,Sc,Ge)', 'Tricalcium discandium tris(germanate)']}","Full Formula (Ca12 Sc8 Ge12 O48) -Reduced Formula: Ca3Sc2(GeO4)3 -abc : 10.955597 10.955597 10.955597 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.375 0.125 0.25 -0 - 1 Ca 0.75 0.125 0.375 -0 - 2 Ca 0.25 0.375 0.125 -0 - 3 Ca 0.125 0.25 0.375 -0 - 4 Ca 0.375 0.75 0.125 -0 - 5 Ca 0.125 0.375 0.75 -0 - 6 Ca 0.625 0.875 0.75 -0 - 7 Ca 0.25 0.875 0.625 -0 - 8 Ca 0.75 0.625 0.875 -0 - 9 Ca 0.875 0.75 0.625 -0 - 10 Ca 0.625 0.25 0.875 -0 - 11 Ca 0.875 0.625 0.25 -0 - 12 Sc 0 0 0 -0 - 13 Sc 0.5 0 0 -0 - 14 Sc 0 0.5 0 -0 - 15 Sc 0 0 0.5 -0 - 16 Sc 0.5 0.5 0 -0 - 17 Sc 0 0.5 0.5 -0 - 18 Sc 0.5 0 0.5 -0 - 19 Sc 0.5 0.5 0.5 -0 - 20 Ge 0.625 0.375 0.25 -0 - 21 Ge 0.75 0.375 0.625 -0 - 22 Ge 0.25 0.125 0.875 -0 - 23 Ge 0.875 0.25 0.125 -0 - 24 Ge 0.625 0.75 0.375 -0 - 25 Ge 0.375 0.625 0.75 -0 - 26 Ge 0.125 0.75 0.875 -0 - 27 Ge 0.75 0.875 0.125 -0 - 28 Ge 0.375 0.25 0.625 -0 - 29 Ge 0.25 0.625 0.375 -0 - 30 Ge 0.875 0.125 0.75 -0 - 31 Ge 0.125 0.875 0.25 -0 - 32 O 0.413304 0.810475 0.7926 0 - 33 O 0.879296 0.397171 0.086696 0 - 34 O 0.102829 0.982125 0.689525 0 - 35 O 0.517875 0.620704 0.7074 0 - 36 O 0.689525 0.086696 0.7074 0 - 37 O 0.620704 0.7074 0.517875 0 - 38 O 0.620704 0.413304 0.102829 0 - 39 O 0.7074 0.517875 0.620704 0 - 40 O 0.810475 0.517875 0.397171 0 - 41 O 0.982125 0.7926 0.879296 0 - 42 O 0.7926 0.879296 0.982125 0 - 43 O 0.7074 0.689525 0.086696 0 - 44 O 0.413304 0.102829 0.620704 0 - 45 O 0.397171 0.810475 0.517875 0 - 46 O 0.086696 0.7074 0.689525 0 - 47 O 0.102829 0.620704 0.413304 0 - 48 O 0.517875 0.397171 0.810475 0 - 49 O 0.086696 0.879296 0.397171 0 - 50 O 0.982125 0.689525 0.102829 0 - 51 O 0.189525 0.482125 0.602829 0 - 52 O 0.689525 0.102829 0.982125 0 - 53 O 0.7926 0.413304 0.810475 0 - 54 O 0.397171 0.086696 0.879296 0 - 55 O 0.879296 0.982125 0.7926 0 - 56 O 0.586696 0.189525 0.2074 0 - 57 O 0.120704 0.602829 0.913304 0 - 58 O 0.897171 0.017875 0.310475 0 - 59 O 0.482125 0.379296 0.2926 0 - 60 O 0.310475 0.913304 0.2926 0 - 61 O 0.379296 0.2926 0.482125 0 - 62 O 0.379296 0.586696 0.897171 0 - 63 O 0.2926 0.482125 0.379296 0 - 64 O 0.120704 0.017875 0.2074 0 - 65 O 0.602829 0.913304 0.120704 0 - 66 O 0.2074 0.586696 0.189525 0 - 67 O 0.189525 0.2074 0.586696 0 - 68 O 0.310475 0.897171 0.017875 0 - 69 O 0.017875 0.310475 0.897171 0 - 70 O 0.913304 0.120704 0.602829 0 - 71 O 0.482125 0.602829 0.189525 0 - 72 O 0.897171 0.379296 0.586696 0 - 73 O 0.913304 0.2926 0.310475 0 - 74 O 0.602829 0.189525 0.482125 0 - 75 O 0.586696 0.897171 0.379296 0 - 76 O 0.2926 0.310475 0.913304 0 - 77 O 0.2074 0.120704 0.017875 0 - 78 O 0.017875 0.2074 0.120704 0 - 79 O 0.810475 0.7926 0.413304 0","# generated using pymatgen -data_Ca3Sc2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.95559721 -_cell_length_b 10.95559721 -_cell_length_c 10.95559721 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Sc2(GeO4)3 -_chemical_formula_sum 'Ca12 Sc8 Ge12 O48' -_cell_volume 1012.24649072 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca3 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca4 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca5 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca6 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca7 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca8 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca9 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca10 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.00000000 1 - Sc Sc15 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.50000000 0.50000000 0.50000000 1 - Ge Ge20 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge21 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge22 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge23 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge24 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge25 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge26 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge29 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.41330400 0.81047500 0.79260000 1 - O O33 1 0.87929600 0.39717100 0.08669600 1 - O O34 1 0.10282900 0.98212500 0.68952500 1 - O O35 1 0.51787500 0.62070400 0.70740000 1 - O O36 1 0.68952500 0.08669600 0.70740000 1 - O O37 1 0.62070400 0.70740000 0.51787500 1 - O O38 1 0.62070400 0.41330400 0.10282900 1 - O O39 1 0.70740000 0.51787500 0.62070400 1 - O O40 1 0.81047500 0.51787500 0.39717100 1 - O O41 1 0.98212500 0.79260000 0.87929600 1 - O O42 1 0.79260000 0.87929600 0.98212500 1 - O O43 1 0.70740000 0.68952500 0.08669600 1 - O O44 1 0.41330400 0.10282900 0.62070400 1 - O O45 1 0.39717100 0.81047500 0.51787500 1 - O O46 1 0.08669600 0.70740000 0.68952500 1 - O O47 1 0.10282900 0.62070400 0.41330400 1 - O O48 1 0.51787500 0.39717100 0.81047500 1 - O O49 1 0.08669600 0.87929600 0.39717100 1 - O O50 1 0.98212500 0.68952500 0.10282900 1 - O O51 1 0.18952500 0.48212500 0.60282900 1 - O O52 1 0.68952500 0.10282900 0.98212500 1 - O O53 1 0.79260000 0.41330400 0.81047500 1 - O O54 1 0.39717100 0.08669600 0.87929600 1 - O O55 1 0.87929600 0.98212500 0.79260000 1 - O O56 1 0.58669600 0.18952500 0.20740000 1 - O O57 1 0.12070400 0.60282900 0.91330400 1 - O O58 1 0.89717100 0.01787500 0.31047500 1 - O O59 1 0.48212500 0.37929600 0.29260000 1 - O O60 1 0.31047500 0.91330400 0.29260000 1 - O O61 1 0.37929600 0.29260000 0.48212500 1 - O O62 1 0.37929600 0.58669600 0.89717100 1 - O O63 1 0.29260000 0.48212500 0.37929600 1 - O O64 1 0.12070400 0.01787500 0.20740000 1 - O O65 1 0.60282900 0.91330400 0.12070400 1 - O O66 1 0.20740000 0.58669600 0.18952500 1 - O O67 1 0.18952500 0.20740000 0.58669600 1 - O O68 1 0.31047500 0.89717100 0.01787500 1 - O O69 1 0.01787500 0.31047500 0.89717100 1 - O O70 1 0.91330400 0.12070400 0.60282900 1 - O O71 1 0.48212500 0.60282900 0.18952500 1 - O O72 1 0.89717100 0.37929600 0.58669600 1 - O O73 1 0.91330400 0.29260000 0.31047500 1 - O O74 1 0.60282900 0.18952500 0.48212500 1 - O O75 1 0.58669600 0.89717100 0.37929600 1 - O O76 1 0.29260000 0.31047500 0.91330400 1 - O O77 1 0.20740000 0.12070400 0.01787500 1 - O O78 1 0.01787500 0.20740000 0.12070400 1 - O O79 1 0.81047500 0.79260000 0.41330400 1 -" -Li3Cr2(PO4)3,mp-26739,Ia-3d,[],0.03329366700001035,{'tags': ['Li Electrode']},"Full Formula (Li12 Cr8 P12 O48) -Reduced Formula: Li3Cr2(PO4)3 -abc : 10.159902 10.159902 10.159902 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.125 0.25 0.375 0 - 1 Li 0.375 0.125 0.25 0 - 2 Li 0.875 0.625 0.25 0 - 3 Li 0.375 0.75 0.125 0 - 4 Li 0.75 0.625 0.875 0 - 5 Li 0.25 0.375 0.125 0 - 6 Li 0.75 0.125 0.375 0 - 7 Li 0.25 0.875 0.625 0 - 8 Li 0.625 0.25 0.875 0 - 9 Li 0.125 0.375 0.75 0 - 10 Li 0.625 0.875 0.75 0 - 11 Li 0.875 0.75 0.625 0 - 12 Cr 0 0 0 2.927 - 13 Cr 0.5 0 0 2.926 - 14 Cr 0 0.5 0 2.927 - 15 Cr 0.5 0.5 0.5 2.927 - 16 Cr 0.5 0.5 0 2.927 - 17 Cr 0 0.5 0.5 2.927 - 18 Cr 0.5 0 0.5 2.926 - 19 Cr 0 0 0.5 2.927 - 20 P 0.75 0.875 0.125 0.007 - 21 P 0.125 0.875 0.25 0.007 - 22 P 0.375 0.625 0.75 0.007 - 23 P 0.875 0.25 0.125 0.007 - 24 P 0.375 0.25 0.625 0.007 - 25 P 0.25 0.625 0.375 0.007 - 26 P 0.75 0.375 0.625 0.007 - 27 P 0.625 0.75 0.375 0.007 - 28 P 0.125 0.75 0.875 0.007 - 29 P 0.625 0.375 0.25 0.007 - 30 P 0.875 0.125 0.75 0.007 - 31 P 0.25 0.125 0.875 0.007 - 32 O 0.910002 0.293315 0.299887 -0.005 - 33 O 0.706685 0.700113 0.089998 -0.005 - 34 O 0.889885 0.006572 0.299887 -0.005 - 35 O 0.616687 0.410002 0.110115 -0.005 - 36 O 0.200113 0.493428 0.610115 -0.004 - 37 O 0.116687 0.006572 0.206685 -0.005 - 38 O 0.993428 0.700113 0.110115 -0.005 - 39 O 0.299887 0.889885 0.006572 -0.004 - 40 O 0.883313 0.389885 0.089998 -0.005 - 41 O 0.200113 0.206685 0.589998 -0.004 - 42 O 0.383313 0.293315 0.493428 -0.005 - 43 O 0.089998 0.883313 0.389885 -0.005 - 44 O 0.589998 0.200113 0.206685 -0.005 - 45 O 0.506572 0.616687 0.706685 -0.005 - 46 O 0.299887 0.910002 0.293315 -0.004 - 47 O 0.206685 0.589998 0.200113 -0.005 - 48 O 0.610115 0.910002 0.116687 -0.005 - 49 O 0.706685 0.506572 0.616687 -0.005 - 50 O 0.110115 0.616687 0.410002 -0.005 - 51 O 0.793315 0.883313 0.993428 -0.005 - 52 O 0.610115 0.200113 0.493428 -0.005 - 53 O 0.006572 0.206685 0.116687 -0.005 - 54 O 0.410002 0.110115 0.616687 -0.005 - 55 O 0.506572 0.389885 0.799887 -0.005 - 56 O 0.493428 0.610115 0.200113 -0.005 - 57 O 0.589998 0.889885 0.383313 -0.005 - 58 O 0.993428 0.793315 0.883313 -0.005 - 59 O 0.206685 0.116687 0.006572 -0.005 - 60 O 0.389885 0.799887 0.506572 -0.005 - 61 O 0.889885 0.383313 0.589998 -0.005 - 62 O 0.293315 0.493428 0.383313 -0.005 - 63 O 0.793315 0.410002 0.799887 -0.005 - 64 O 0.389885 0.089998 0.883313 -0.005 - 65 O 0.700113 0.089998 0.706685 -0.004 - 66 O 0.493428 0.383313 0.293315 -0.005 - 67 O 0.410002 0.799887 0.793315 -0.005 - 68 O 0.910002 0.116687 0.610115 -0.005 - 69 O 0.799887 0.793315 0.410002 -0.004 - 70 O 0.616687 0.706685 0.506572 -0.005 - 71 O 0.116687 0.610115 0.910002 -0.005 - 72 O 0.700113 0.110115 0.993428 -0.004 - 73 O 0.006572 0.299887 0.889885 -0.005 - 74 O 0.799887 0.506572 0.389885 -0.004 - 75 O 0.883313 0.993428 0.793315 -0.005 - 76 O 0.383313 0.589998 0.889885 -0.005 - 77 O 0.110115 0.993428 0.700113 -0.005 - 78 O 0.293315 0.299887 0.910002 -0.005 - 79 O 0.089998 0.706685 0.700113 -0.005","# generated using pymatgen -data_Li3Cr2(PO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.15990173 -_cell_length_b 10.15990173 -_cell_length_c 10.15990173 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Cr2(PO4)3 -_chemical_formula_sum 'Li12 Cr8 P12 O48' -_cell_volume 807.32171015 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.12500000 0.25000000 0.37500000 1 - Li Li1 1 0.37500000 0.12500000 0.25000000 1 - Li Li2 1 0.87500000 0.62500000 0.25000000 1 - Li Li3 1 0.37500000 0.75000000 0.12500000 1 - Li Li4 1 0.75000000 0.62500000 0.87500000 1 - Li Li5 1 0.25000000 0.37500000 0.12500000 1 - Li Li6 1 0.75000000 0.12500000 0.37500000 1 - Li Li7 1 0.25000000 0.87500000 0.62500000 1 - Li Li8 1 0.62500000 0.25000000 0.87500000 1 - Li Li9 1 0.12500000 0.37500000 0.75000000 1 - Li Li10 1 0.62500000 0.87500000 0.75000000 1 - Li Li11 1 0.87500000 0.75000000 0.62500000 1 - Cr Cr12 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr13 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr15 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr16 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr18 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.50000000 1 - P P20 1 0.75000000 0.87500000 0.12500000 1 - P P21 1 0.12500000 0.87500000 0.25000000 1 - P P22 1 0.37500000 0.62500000 0.75000000 1 - P P23 1 0.87500000 0.25000000 0.12500000 1 - P P24 1 0.37500000 0.25000000 0.62500000 1 - P P25 1 0.25000000 0.62500000 0.37500000 1 - P P26 1 0.75000000 0.37500000 0.62500000 1 - P P27 1 0.62500000 0.75000000 0.37500000 1 - P P28 1 0.12500000 0.75000000 0.87500000 1 - P P29 1 0.62500000 0.37500000 0.25000000 1 - P P30 1 0.87500000 0.12500000 0.75000000 1 - P P31 1 0.25000000 0.12500000 0.87500000 1 - O O32 1 0.91000200 0.29331500 0.29988700 1 - O O33 1 0.70668500 0.70011300 0.08999800 1 - O O34 1 0.88988500 0.00657200 0.29988700 1 - O O35 1 0.61668700 0.41000200 0.11011500 1 - O O36 1 0.20011300 0.49342800 0.61011500 1 - O O37 1 0.11668700 0.00657200 0.20668500 1 - O O38 1 0.99342800 0.70011300 0.11011500 1 - O O39 1 0.29988700 0.88988500 0.00657200 1 - O O40 1 0.88331300 0.38988500 0.08999800 1 - O O41 1 0.20011300 0.20668500 0.58999800 1 - O O42 1 0.38331300 0.29331500 0.49342800 1 - O O43 1 0.08999800 0.88331300 0.38988500 1 - O O44 1 0.58999800 0.20011300 0.20668500 1 - O O45 1 0.50657200 0.61668700 0.70668500 1 - O O46 1 0.29988700 0.91000200 0.29331500 1 - O O47 1 0.20668500 0.58999800 0.20011300 1 - O O48 1 0.61011500 0.91000200 0.11668700 1 - O O49 1 0.70668500 0.50657200 0.61668700 1 - O O50 1 0.11011500 0.61668700 0.41000200 1 - O O51 1 0.79331500 0.88331300 0.99342800 1 - O O52 1 0.61011500 0.20011300 0.49342800 1 - O O53 1 0.00657200 0.20668500 0.11668700 1 - O O54 1 0.41000200 0.11011500 0.61668700 1 - O O55 1 0.50657200 0.38988500 0.79988700 1 - O O56 1 0.49342800 0.61011500 0.20011300 1 - O O57 1 0.58999800 0.88988500 0.38331300 1 - O O58 1 0.99342800 0.79331500 0.88331300 1 - O O59 1 0.20668500 0.11668700 0.00657200 1 - O O60 1 0.38988500 0.79988700 0.50657200 1 - O O61 1 0.88988500 0.38331300 0.58999800 1 - O O62 1 0.29331500 0.49342800 0.38331300 1 - O O63 1 0.79331500 0.41000200 0.79988700 1 - O O64 1 0.38988500 0.08999800 0.88331300 1 - O O65 1 0.70011300 0.08999800 0.70668500 1 - O O66 1 0.49342800 0.38331300 0.29331500 1 - O O67 1 0.41000200 0.79988700 0.79331500 1 - O O68 1 0.91000200 0.11668700 0.61011500 1 - O O69 1 0.79988700 0.79331500 0.41000200 1 - O O70 1 0.61668700 0.70668500 0.50657200 1 - O O71 1 0.11668700 0.61011500 0.91000200 1 - O O72 1 0.70011300 0.11011500 0.99342800 1 - O O73 1 0.00657200 0.29988700 0.88988500 1 - O O74 1 0.79988700 0.50657200 0.38988500 1 - O O75 1 0.88331300 0.99342800 0.79331500 1 - O O76 1 0.38331300 0.58999800 0.88988500 1 - O O77 1 0.11011500 0.99342800 0.70011300 1 - O O78 1 0.29331500 0.29988700 0.91000200 1 - O O79 1 0.08999800 0.70668500 0.70011300 1 -" -Mn2Fe3(SiO4)3,mp-555470,Ia-3d,[27378],0.12907911999999477,{'tags': ['Triiron dimanganese(III) silicate']},"Full Formula (Mn8 Fe12 Si12 O48) -Reduced Formula: Mn2Fe3(SiO4)3 -abc : 10.304188 10.304188 10.304188 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0 0.5 0 4.061 - 1 Mn 0.5 0.5 0.5 4.061 - 2 Mn 0 0 0 4.061 - 3 Mn 0 0 0.5 4.061 - 4 Mn 0 0.5 0.5 4.06 - 5 Mn 0.5 0.5 0 4.06 - 6 Mn 0.5 0 0.5 4.06 - 7 Mn 0.5 0 0 4.061 - 8 Fe 0.125 0.25 0.375 3.79 - 9 Fe 0.75 0.125 0.375 3.79 - 10 Fe 0.25 0.875 0.625 3.79 - 11 Fe 0.375 0.75 0.125 3.79 - 12 Fe 0.875 0.625 0.25 3.79 - 13 Fe 0.75 0.625 0.875 3.79 - 14 Fe 0.625 0.25 0.875 3.79 - 15 Fe 0.875 0.75 0.625 3.79 - 16 Fe 0.125 0.375 0.75 3.79 - 17 Fe 0.625 0.875 0.75 3.79 - 18 Fe 0.375 0.125 0.25 3.79 - 19 Fe 0.25 0.375 0.125 3.79 - 20 Si 0.875 0.25 0.125 0.018 - 21 Si 0.125 0.75 0.875 0.018 - 22 Si 0.75 0.375 0.625 0.018 - 23 Si 0.375 0.625 0.75 0.018 - 24 Si 0.625 0.375 0.25 0.018 - 25 Si 0.625 0.75 0.375 0.018 - 26 Si 0.875 0.125 0.75 0.018 - 27 Si 0.25 0.625 0.375 0.018 - 28 Si 0.25 0.125 0.875 0.018 - 29 Si 0.125 0.875 0.25 0.018 - 30 Si 0.375 0.25 0.625 0.018 - 31 Si 0.75 0.875 0.125 0.018 - 32 O 0.410734 0.104233 0.623504 -0.002 - 33 O 0.519271 0.395767 0.806501 -0.002 - 34 O 0.104233 0.623504 0.410734 -0.002 - 35 O 0.895767 0.376496 0.589266 -0.002 - 36 O 0.287229 0.480729 0.376496 -0.002 - 37 O 0.589266 0.895767 0.376496 -0.002 - 38 O 0.212771 0.589266 0.193499 -0.002 - 39 O 0.019271 0.306501 0.895767 -0.002 - 40 O 0.480729 0.376496 0.287229 -0.002 - 41 O 0.693499 0.104233 0.980729 -0.002 - 42 O 0.376496 0.287229 0.480729 -0.002 - 43 O 0.123504 0.019271 0.212771 -0.002 - 44 O 0.212771 0.123504 0.019271 -0.002 - 45 O 0.876496 0.395767 0.089266 -0.002 - 46 O 0.287229 0.306501 0.910734 -0.002 - 47 O 0.410734 0.806501 0.787229 -0.002 - 48 O 0.395767 0.089266 0.876496 -0.002 - 49 O 0.306501 0.910734 0.287229 -0.002 - 50 O 0.712771 0.519271 0.623504 -0.002 - 51 O 0.895767 0.019271 0.306501 -0.002 - 52 O 0.623504 0.410734 0.104233 -0.002 - 53 O 0.910734 0.287229 0.306501 -0.002 - 54 O 0.019271 0.212771 0.123504 -0.002 - 55 O 0.876496 0.980729 0.787229 -0.002 - 56 O 0.193499 0.480729 0.604233 -0.002 - 57 O 0.806501 0.787229 0.410734 -0.002 - 58 O 0.623504 0.712771 0.519271 -0.002 - 59 O 0.395767 0.806501 0.519271 -0.002 - 60 O 0.089266 0.712771 0.693499 -0.002 - 61 O 0.712771 0.693499 0.089266 -0.002 - 62 O 0.806501 0.519271 0.395767 -0.002 - 63 O 0.980729 0.787229 0.876496 -0.002 - 64 O 0.104233 0.980729 0.693499 -0.002 - 65 O 0.787229 0.410734 0.806501 -0.002 - 66 O 0.519271 0.623504 0.712771 -0.002 - 67 O 0.480729 0.604233 0.193499 -0.002 - 68 O 0.604233 0.193499 0.480729 -0.002 - 69 O 0.376496 0.589266 0.895767 -0.002 - 70 O 0.193499 0.212771 0.589266 -0.002 - 71 O 0.589266 0.193499 0.212771 -0.002 - 72 O 0.787229 0.876496 0.980729 -0.002 - 73 O 0.123504 0.604233 0.910734 -0.002 - 74 O 0.693499 0.089266 0.712771 -0.002 - 75 O 0.604233 0.910734 0.123504 -0.002 - 76 O 0.910734 0.123504 0.604233 -0.002 - 77 O 0.306501 0.895767 0.019271 -0.002 - 78 O 0.089266 0.876496 0.395767 -0.002 - 79 O 0.980729 0.693499 0.104233 -0.002","# generated using pymatgen -data_Mn2Fe3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.30418849 -_cell_length_b 10.30418849 -_cell_length_c 10.30418849 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn2Fe3(SiO4)3 -_chemical_formula_sum 'Mn8 Fe12 Si12 O48' -_cell_volume 842.20825312 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn1 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn2 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn3 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn4 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn5 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn6 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn7 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe8 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe9 1 0.75000000 0.12500000 0.37500000 1 - Fe Fe10 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe11 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe12 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe13 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe14 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe15 1 0.87500000 0.75000000 0.62500000 1 - Fe Fe16 1 0.12500000 0.37500000 0.75000000 1 - Fe Fe17 1 0.62500000 0.87500000 0.75000000 1 - Fe Fe18 1 0.37500000 0.12500000 0.25000000 1 - Fe Fe19 1 0.25000000 0.37500000 0.12500000 1 - Si Si20 1 0.87500000 0.25000000 0.12500000 1 - Si Si21 1 0.12500000 0.75000000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.37500000 0.62500000 0.75000000 1 - Si Si24 1 0.62500000 0.37500000 0.25000000 1 - Si Si25 1 0.62500000 0.75000000 0.37500000 1 - Si Si26 1 0.87500000 0.12500000 0.75000000 1 - Si Si27 1 0.25000000 0.62500000 0.37500000 1 - Si Si28 1 0.25000000 0.12500000 0.87500000 1 - Si Si29 1 0.12500000 0.87500000 0.25000000 1 - Si Si30 1 0.37500000 0.25000000 0.62500000 1 - Si Si31 1 0.75000000 0.87500000 0.12500000 1 - O O32 1 0.41073400 0.10423300 0.62350400 1 - O O33 1 0.51927100 0.39576700 0.80650100 1 - O O34 1 0.10423300 0.62350400 0.41073400 1 - O O35 1 0.89576700 0.37649600 0.58926600 1 - O O36 1 0.28722900 0.48072900 0.37649600 1 - O O37 1 0.58926600 0.89576700 0.37649600 1 - O O38 1 0.21277100 0.58926600 0.19349900 1 - O O39 1 0.01927100 0.30650100 0.89576700 1 - O O40 1 0.48072900 0.37649600 0.28722900 1 - O O41 1 0.69349900 0.10423300 0.98072900 1 - O O42 1 0.37649600 0.28722900 0.48072900 1 - O O43 1 0.12350400 0.01927100 0.21277100 1 - O O44 1 0.21277100 0.12350400 0.01927100 1 - O O45 1 0.87649600 0.39576700 0.08926600 1 - O O46 1 0.28722900 0.30650100 0.91073400 1 - O O47 1 0.41073400 0.80650100 0.78722900 1 - O O48 1 0.39576700 0.08926600 0.87649600 1 - O O49 1 0.30650100 0.91073400 0.28722900 1 - O O50 1 0.71277100 0.51927100 0.62350400 1 - O O51 1 0.89576700 0.01927100 0.30650100 1 - O O52 1 0.62350400 0.41073400 0.10423300 1 - O O53 1 0.91073400 0.28722900 0.30650100 1 - O O54 1 0.01927100 0.21277100 0.12350400 1 - O O55 1 0.87649600 0.98072900 0.78722900 1 - O O56 1 0.19349900 0.48072900 0.60423300 1 - O O57 1 0.80650100 0.78722900 0.41073400 1 - O O58 1 0.62350400 0.71277100 0.51927100 1 - O O59 1 0.39576700 0.80650100 0.51927100 1 - O O60 1 0.08926600 0.71277100 0.69349900 1 - O O61 1 0.71277100 0.69349900 0.08926600 1 - O O62 1 0.80650100 0.51927100 0.39576700 1 - O O63 1 0.98072900 0.78722900 0.87649600 1 - O O64 1 0.10423300 0.98072900 0.69349900 1 - O O65 1 0.78722900 0.41073400 0.80650100 1 - O O66 1 0.51927100 0.62350400 0.71277100 1 - O O67 1 0.48072900 0.60423300 0.19349900 1 - O O68 1 0.60423300 0.19349900 0.48072900 1 - O O69 1 0.37649600 0.58926600 0.89576700 1 - O O70 1 0.19349900 0.21277100 0.58926600 1 - O O71 1 0.58926600 0.19349900 0.21277100 1 - O O72 1 0.78722900 0.87649600 0.98072900 1 - O O73 1 0.12350400 0.60423300 0.91073400 1 - O O74 1 0.69349900 0.08926600 0.71277100 1 - O O75 1 0.60423300 0.91073400 0.12350400 1 - O O76 1 0.91073400 0.12350400 0.60423300 1 - O O77 1 0.30650100 0.89576700 0.01927100 1 - O O78 1 0.08926600 0.87649600 0.39576700 1 - O O79 1 0.98072900 0.69349900 0.10423300 1 -" -Gd3Sc2(GaO4)3,mp-555835,Ia-3d,[162752],0.6879727653749903,{'tags': []},"Full Formula (Gd12 Sc8 Ga12 O48) -Reduced Formula: Gd3Sc2(GaO4)3 -abc : 11.046883 11.046883 11.046883 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Gd 0.25 0.125 0.875 6.876 - 1 Gd 0.375 0.625 0.75 6.876 - 2 Gd 0.25 0.625 0.375 6.876 - 3 Gd 0.625 0.75 0.375 6.876 - 4 Gd 0.125 0.75 0.875 6.876 - 5 Gd 0.75 0.375 0.625 6.876 - 6 Gd 0.75 0.875 0.125 6.876 - 7 Gd 0.875 0.125 0.75 6.876 - 8 Gd 0.125 0.875 0.25 6.876 - 9 Gd 0.375 0.25 0.625 6.876 - 10 Gd 0.875 0.25 0.125 6.876 - 11 Gd 0.625 0.375 0.25 6.876 - 12 Sc 0.5 0.5 0.5 0.005 - 13 Sc 0 0 0 0.005 - 14 Sc 0.5 0 0.5 0.005 - 15 Sc 0.5 0.5 0 0.005 - 16 Sc 0 0 0.5 0.005 - 17 Sc 0 0.5 0 0.005 - 18 Sc 0.5 0 0 0.005 - 19 Sc 0 0.5 0.5 0.005 - 20 Ga 0.625 0.25 0.875 0.003 - 21 Ga 0.25 0.375 0.125 0.003 - 22 Ga 0.875 0.625 0.25 0.003 - 23 Ga 0.375 0.125 0.25 0.003 - 24 Ga 0.75 0.625 0.875 0.003 - 25 Ga 0.125 0.375 0.75 0.003 - 26 Ga 0.875 0.75 0.625 0.003 - 27 Ga 0.25 0.875 0.625 0.003 - 28 Ga 0.75 0.125 0.375 0.003 - 29 Ga 0.375 0.75 0.125 0.003 - 30 Ga 0.625 0.875 0.75 0.003 - 31 Ga 0.125 0.25 0.375 0.003 - 32 O 0.941845 0.772287 0.883997 -0.004 - 33 O 0.169559 0.227713 0.611711 -0.004 - 34 O 0.169559 0.441845 0.557848 -0.004 - 35 O 0.116003 0.058154 0.227713 -0.004 - 36 O 0.388289 0.830441 0.772287 -0.004 - 37 O 0.888289 0.272287 0.330441 -0.004 - 38 O 0.883997 0.941845 0.772287 -0.004 - 39 O 0.442152 0.111711 0.883997 -0.004 - 40 O 0.772287 0.388289 0.830441 -0.003 - 41 O 0.941845 0.669559 0.057848 -0.004 - 42 O 0.058155 0.227713 0.116003 -0.004 - 43 O 0.272287 0.441845 0.383997 -0.003 - 44 O 0.557848 0.169559 0.441845 -0.004 - 45 O 0.883997 0.442152 0.111711 -0.004 - 46 O 0.057848 0.941845 0.669559 -0.004 - 47 O 0.772287 0.883997 0.941845 -0.003 - 48 O 0.330441 0.888289 0.272287 -0.004 - 49 O 0.057848 0.616003 0.388289 -0.004 - 50 O 0.942152 0.383997 0.611711 -0.004 - 51 O 0.058155 0.330441 0.942152 -0.004 - 52 O 0.442152 0.830441 0.558155 -0.004 - 53 O 0.558154 0.442152 0.830441 -0.004 - 54 O 0.116003 0.557848 0.888289 -0.004 - 55 O 0.616003 0.388289 0.057848 -0.004 - 56 O 0.727713 0.669559 0.111711 -0.003 - 57 O 0.727713 0.558155 0.616003 -0.003 - 58 O 0.272287 0.330441 0.888289 -0.003 - 59 O 0.441845 0.557848 0.169559 -0.004 - 60 O 0.669559 0.111711 0.727713 -0.004 - 61 O 0.383997 0.611711 0.942152 -0.004 - 62 O 0.330441 0.942152 0.058155 -0.004 - 63 O 0.830441 0.558154 0.442152 -0.004 - 64 O 0.669559 0.057848 0.941845 -0.004 - 65 O 0.111711 0.883997 0.442152 -0.004 - 66 O 0.830441 0.772287 0.388289 -0.004 - 67 O 0.388289 0.057848 0.616003 -0.004 - 68 O 0.616003 0.727713 0.558155 -0.004 - 69 O 0.888289 0.116003 0.557848 -0.004 - 70 O 0.441845 0.383997 0.272287 -0.004 - 71 O 0.611711 0.942152 0.383997 -0.004 - 72 O 0.558155 0.616003 0.727713 -0.004 - 73 O 0.942152 0.058155 0.330441 -0.004 - 74 O 0.111711 0.727713 0.669559 -0.004 - 75 O 0.611711 0.169559 0.227713 -0.004 - 76 O 0.383997 0.272287 0.441845 -0.004 - 77 O 0.227713 0.611711 0.169559 -0.003 - 78 O 0.557848 0.888289 0.116003 -0.004 - 79 O 0.227713 0.116003 0.058155 -0.003","# generated using pymatgen -data_Gd3Sc2(GaO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.04688322 -_cell_length_b 11.04688322 -_cell_length_c 11.04688322 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Gd3Sc2(GaO4)3 -_chemical_formula_sum 'Gd12 Sc8 Ga12 O48' -_cell_volume 1037.76112550 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Gd Gd0 1 0.25000000 0.12500000 0.87500000 1 - Gd Gd1 1 0.37500000 0.62500000 0.75000000 1 - Gd Gd2 1 0.25000000 0.62500000 0.37500000 1 - Gd Gd3 1 0.62500000 0.75000000 0.37500000 1 - Gd Gd4 1 0.12500000 0.75000000 0.87500000 1 - Gd Gd5 1 0.75000000 0.37500000 0.62500000 1 - Gd Gd6 1 0.75000000 0.87500000 0.12500000 1 - Gd Gd7 1 0.87500000 0.12500000 0.75000000 1 - Gd Gd8 1 0.12500000 0.87500000 0.25000000 1 - Gd Gd9 1 0.37500000 0.25000000 0.62500000 1 - Gd Gd10 1 0.87500000 0.25000000 0.12500000 1 - Gd Gd11 1 0.62500000 0.37500000 0.25000000 1 - Sc Sc12 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc13 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc14 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc15 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc16 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc17 1 0.00000000 0.50000000 0.00000000 1 - Sc Sc18 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc19 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga20 1 0.62500000 0.25000000 0.87500000 1 - Ga Ga21 1 0.25000000 0.37500000 0.12500000 1 - Ga Ga22 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga23 1 0.37500000 0.12500000 0.25000000 1 - Ga Ga24 1 0.75000000 0.62500000 0.87500000 1 - Ga Ga25 1 0.12500000 0.37500000 0.75000000 1 - Ga Ga26 1 0.87500000 0.75000000 0.62500000 1 - Ga Ga27 1 0.25000000 0.87500000 0.62500000 1 - Ga Ga28 1 0.75000000 0.12500000 0.37500000 1 - Ga Ga29 1 0.37500000 0.75000000 0.12500000 1 - Ga Ga30 1 0.62500000 0.87500000 0.75000000 1 - Ga Ga31 1 0.12500000 0.25000000 0.37500000 1 - O O32 1 0.94184500 0.77228700 0.88399700 1 - O O33 1 0.16955900 0.22771300 0.61171100 1 - O O34 1 0.16955900 0.44184500 0.55784800 1 - O O35 1 0.11600300 0.05815400 0.22771300 1 - O O36 1 0.38828900 0.83044100 0.77228700 1 - O O37 1 0.88828900 0.27228700 0.33044100 1 - O O38 1 0.88399700 0.94184500 0.77228700 1 - O O39 1 0.44215200 0.11171100 0.88399700 1 - O O40 1 0.77228700 0.38828900 0.83044100 1 - O O41 1 0.94184500 0.66955900 0.05784800 1 - O O42 1 0.05815500 0.22771300 0.11600300 1 - O O43 1 0.27228700 0.44184500 0.38399700 1 - O O44 1 0.55784800 0.16955900 0.44184500 1 - O O45 1 0.88399700 0.44215200 0.11171100 1 - O O46 1 0.05784800 0.94184500 0.66955900 1 - O O47 1 0.77228700 0.88399700 0.94184500 1 - O O48 1 0.33044100 0.88828900 0.27228700 1 - O O49 1 0.05784800 0.61600300 0.38828900 1 - O O50 1 0.94215200 0.38399700 0.61171100 1 - O O51 1 0.05815500 0.33044100 0.94215200 1 - O O52 1 0.44215200 0.83044100 0.55815500 1 - O O53 1 0.55815400 0.44215200 0.83044100 1 - O O54 1 0.11600300 0.55784800 0.88828900 1 - O O55 1 0.61600300 0.38828900 0.05784800 1 - O O56 1 0.72771300 0.66955900 0.11171100 1 - O O57 1 0.72771300 0.55815500 0.61600300 1 - O O58 1 0.27228700 0.33044100 0.88828900 1 - O O59 1 0.44184500 0.55784800 0.16955900 1 - O O60 1 0.66955900 0.11171100 0.72771300 1 - O O61 1 0.38399700 0.61171100 0.94215200 1 - O O62 1 0.33044100 0.94215200 0.05815500 1 - O O63 1 0.83044100 0.55815400 0.44215200 1 - O O64 1 0.66955900 0.05784800 0.94184500 1 - O O65 1 0.11171100 0.88399700 0.44215200 1 - O O66 1 0.83044100 0.77228700 0.38828900 1 - O O67 1 0.38828900 0.05784800 0.61600300 1 - O O68 1 0.61600300 0.72771300 0.55815500 1 - O O69 1 0.88828900 0.11600300 0.55784800 1 - O O70 1 0.44184500 0.38399700 0.27228700 1 - O O71 1 0.61171100 0.94215200 0.38399700 1 - O O72 1 0.55815500 0.61600300 0.72771300 1 - O O73 1 0.94215200 0.05815500 0.33044100 1 - O O74 1 0.11171100 0.72771300 0.66955900 1 - O O75 1 0.61171100 0.16955900 0.22771300 1 - O O76 1 0.38399700 0.27228700 0.44184500 1 - O O77 1 0.22771300 0.61171100 0.16955900 1 - O O78 1 0.55784800 0.88828900 0.11600300 1 - O O79 1 0.22771300 0.11600300 0.05815500 1 -" -Na3Ga3(TeO6)2,mp-556143,Ia-3d,[418645],0.0,{'tags': ['Trisodium trigallium ditellurate(VI)']},"Full Formula (Na12 Ga12 Te8 O48) -Reduced Formula: Na3Ga3(TeO6)2 -abc : 10.864382 10.864382 10.864382 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.375 0.75 0.125 -0 - 1 Na 0.875 0.625 0.25 -0 - 2 Na 0.625 0.25 0.875 -0 - 3 Na 0.25 0.375 0.125 -0 - 4 Na 0.125 0.375 0.75 -0 - 5 Na 0.375 0.125 0.25 -0 - 6 Na 0.75 0.625 0.875 -0 - 7 Na 0.875 0.75 0.625 -0 - 8 Na 0.25 0.875 0.625 -0 - 9 Na 0.75 0.125 0.375 -0 - 10 Na 0.625 0.875 0.75 -0 - 11 Na 0.125 0.25 0.375 -0 - 12 Ga 0.375 0.625 0.75 -0 - 13 Ga 0.25 0.625 0.375 -0 - 14 Ga 0.625 0.75 0.375 -0 - 15 Ga 0.25 0.125 0.875 -0 - 16 Ga 0.125 0.75 0.875 -0 - 17 Ga 0.75 0.875 0.125 -0 - 18 Ga 0.75 0.375 0.625 -0 - 19 Ga 0.875 0.125 0.75 -0 - 20 Ga 0.125 0.875 0.25 -0 - 21 Ga 0.375 0.25 0.625 -0 - 22 Ga 0.875 0.25 0.125 -0 - 23 Ga 0.625 0.375 0.25 -0 - 24 Te 0 0.5 0.5 -0 - 25 Te 0.5 0.5 0.5 -0 - 26 Te 0 0 0 -0 - 27 Te 0.5 0 0 -0 - 28 Te 0.5 0.5 0 -0 - 29 Te 0 0 0.5 -0 - 30 Te 0.5 0 0.5 -0 - 31 Te 0 0.5 0 -0 - 32 O 0.92342 0.115395 0.598849 0 - 33 O 0.115395 0.016546 0.191975 0 - 34 O 0.483454 0.598849 0.175429 0 - 35 O 0.07658 0.884605 0.401151 0 - 36 O 0.675429 0.07658 0.691975 0 - 37 O 0.098849 0.983454 0.675429 0 - 38 O 0.824571 0.808025 0.42342 0 - 39 O 0.175429 0.483454 0.598849 0 - 40 O 0.598849 0.92342 0.115395 0 - 41 O 0.57658 0.901151 0.384605 0 - 42 O 0.384605 0.57658 0.901151 0 - 43 O 0.808025 0.884605 0.983454 0 - 44 O 0.115395 0.598849 0.92342 0 - 45 O 0.615395 0.42342 0.098849 0 - 46 O 0.824571 0.516546 0.401151 0 - 47 O 0.598849 0.175429 0.483454 0 - 48 O 0.175429 0.191975 0.57658 0 - 49 O 0.92342 0.308025 0.324571 0 - 50 O 0.901151 0.384605 0.57658 0 - 51 O 0.308025 0.324571 0.92342 0 - 52 O 0.308025 0.483454 0.384605 0 - 53 O 0.191975 0.115395 0.016546 0 - 54 O 0.516546 0.615395 0.691975 0 - 55 O 0.57658 0.175429 0.191975 0 - 56 O 0.098849 0.615395 0.42342 0 - 57 O 0.884605 0.401151 0.07658 0 - 58 O 0.691975 0.675429 0.07658 0 - 59 O 0.401151 0.824571 0.516546 0 - 60 O 0.42342 0.824571 0.808025 0 - 61 O 0.191975 0.57658 0.175429 0 - 62 O 0.401151 0.07658 0.884605 0 - 63 O 0.615395 0.691975 0.516546 0 - 64 O 0.324571 0.92342 0.308025 0 - 65 O 0.016546 0.324571 0.901151 0 - 66 O 0.675429 0.098849 0.983454 0 - 67 O 0.983454 0.675429 0.098849 0 - 68 O 0.016546 0.191975 0.115395 0 - 69 O 0.884605 0.983454 0.808025 0 - 70 O 0.483454 0.384605 0.308025 0 - 71 O 0.808025 0.42342 0.824571 0 - 72 O 0.42342 0.098849 0.615395 0 - 73 O 0.691975 0.516546 0.615395 0 - 74 O 0.901151 0.016546 0.324571 0 - 75 O 0.07658 0.691975 0.675429 0 - 76 O 0.384605 0.308025 0.483454 0 - 77 O 0.516546 0.401151 0.824571 0 - 78 O 0.983454 0.808025 0.884605 0 - 79 O 0.324571 0.901151 0.016546 0","# generated using pymatgen -data_Na3Ga3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.86438222 -_cell_length_b 10.86438222 -_cell_length_c 10.86438222 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Ga3(TeO6)2 -_chemical_formula_sum 'Na12 Ga12 Te8 O48' -_cell_volume 987.17288461 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.37500000 0.75000000 0.12500000 1 - Na Na1 1 0.87500000 0.62500000 0.25000000 1 - Na Na2 1 0.62500000 0.25000000 0.87500000 1 - Na Na3 1 0.25000000 0.37500000 0.12500000 1 - Na Na4 1 0.12500000 0.37500000 0.75000000 1 - Na Na5 1 0.37500000 0.12500000 0.25000000 1 - Na Na6 1 0.75000000 0.62500000 0.87500000 1 - Na Na7 1 0.87500000 0.75000000 0.62500000 1 - Na Na8 1 0.25000000 0.87500000 0.62500000 1 - Na Na9 1 0.75000000 0.12500000 0.37500000 1 - Na Na10 1 0.62500000 0.87500000 0.75000000 1 - Na Na11 1 0.12500000 0.25000000 0.37500000 1 - Ga Ga12 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga13 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga14 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga15 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga16 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga17 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga18 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga19 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga20 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga21 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga22 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga23 1 0.62500000 0.37500000 0.25000000 1 - Te Te24 1 0.00000000 0.50000000 0.50000000 1 - Te Te25 1 0.50000000 0.50000000 0.50000000 1 - Te Te26 1 0.00000000 0.00000000 0.00000000 1 - Te Te27 1 0.50000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.00000000 1 - Te Te29 1 0.00000000 0.00000000 0.50000000 1 - Te Te30 1 0.50000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.92342000 0.11539500 0.59884900 1 - O O33 1 0.11539500 0.01654600 0.19197500 1 - O O34 1 0.48345400 0.59884900 0.17542900 1 - O O35 1 0.07658000 0.88460500 0.40115100 1 - O O36 1 0.67542900 0.07658000 0.69197500 1 - O O37 1 0.09884900 0.98345400 0.67542900 1 - O O38 1 0.82457100 0.80802500 0.42342000 1 - O O39 1 0.17542900 0.48345400 0.59884900 1 - O O40 1 0.59884900 0.92342000 0.11539500 1 - O O41 1 0.57658000 0.90115100 0.38460500 1 - O O42 1 0.38460500 0.57658000 0.90115100 1 - O O43 1 0.80802500 0.88460500 0.98345400 1 - O O44 1 0.11539500 0.59884900 0.92342000 1 - O O45 1 0.61539500 0.42342000 0.09884900 1 - O O46 1 0.82457100 0.51654600 0.40115100 1 - O O47 1 0.59884900 0.17542900 0.48345400 1 - O O48 1 0.17542900 0.19197500 0.57658000 1 - O O49 1 0.92342000 0.30802500 0.32457100 1 - O O50 1 0.90115100 0.38460500 0.57658000 1 - O O51 1 0.30802500 0.32457100 0.92342000 1 - O O52 1 0.30802500 0.48345400 0.38460500 1 - O O53 1 0.19197500 0.11539500 0.01654600 1 - O O54 1 0.51654600 0.61539500 0.69197500 1 - O O55 1 0.57658000 0.17542900 0.19197500 1 - O O56 1 0.09884900 0.61539500 0.42342000 1 - O O57 1 0.88460500 0.40115100 0.07658000 1 - O O58 1 0.69197500 0.67542900 0.07658000 1 - O O59 1 0.40115100 0.82457100 0.51654600 1 - O O60 1 0.42342000 0.82457100 0.80802500 1 - O O61 1 0.19197500 0.57658000 0.17542900 1 - O O62 1 0.40115100 0.07658000 0.88460500 1 - O O63 1 0.61539500 0.69197500 0.51654600 1 - O O64 1 0.32457100 0.92342000 0.30802500 1 - O O65 1 0.01654600 0.32457100 0.90115100 1 - O O66 1 0.67542900 0.09884900 0.98345400 1 - O O67 1 0.98345400 0.67542900 0.09884900 1 - O O68 1 0.01654600 0.19197500 0.11539500 1 - O O69 1 0.88460500 0.98345400 0.80802500 1 - O O70 1 0.48345400 0.38460500 0.30802500 1 - O O71 1 0.80802500 0.42342000 0.82457100 1 - O O72 1 0.42342000 0.09884900 0.61539500 1 - O O73 1 0.69197500 0.51654600 0.61539500 1 - O O74 1 0.90115100 0.01654600 0.32457100 1 - O O75 1 0.07658000 0.69197500 0.67542900 1 - O O76 1 0.38460500 0.30802500 0.48345400 1 - O O77 1 0.51654600 0.40115100 0.82457100 1 - O O78 1 0.98345400 0.80802500 0.88460500 1 - O O79 1 0.32457100 0.90115100 0.01654600 1 -" -Na3Fe2(AsO4)3,mp-556723,Ia-3d,[241123],0.0,{'tags': ['Trisodium diiron(III) triarsenate(V)']},"Full Formula (Na12 Fe8 As12 O48) -Reduced Formula: Na3Fe2(AsO4)3 -abc : 10.761389 10.761389 10.761389 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.375 0.75 0.125 0.001 - 1 Na 0.25 0.375 0.125 0.001 - 2 Na 0.875 0.625 0.25 0.001 - 3 Na 0.125 0.375 0.75 0.001 - 4 Na 0.375 0.125 0.25 0.001 - 5 Na 0.75 0.625 0.875 0.001 - 6 Na 0.25 0.875 0.625 0.001 - 7 Na 0.75 0.125 0.375 0.001 - 8 Na 0.875 0.75 0.625 0.001 - 9 Na 0.625 0.875 0.75 0.001 - 10 Na 0.125 0.25 0.375 0.001 - 11 Na 0.625 0.25 0.875 0.001 - 12 Fe 0.5 0.5 0.5 4.361 - 13 Fe 0.5 0 0.5 4.359 - 14 Fe 0.5 0 0 4.359 - 15 Fe 0.5 0.5 0 4.361 - 16 Fe 0 0 0 4.361 - 17 Fe 0 0 0.5 4.359 - 18 Fe 0 0.5 0 4.361 - 19 Fe 0 0.5 0.5 4.359 - 20 As 0.25 0.125 0.875 0.024 - 21 As 0.875 0.125 0.75 0.024 - 22 As 0.625 0.75 0.375 0.024 - 23 As 0.375 0.625 0.75 0.024 - 24 As 0.25 0.625 0.375 0.024 - 25 As 0.75 0.375 0.625 0.024 - 26 As 0.75 0.875 0.125 0.024 - 27 As 0.875 0.25 0.125 0.024 - 28 As 0.125 0.75 0.875 0.024 - 29 As 0.375 0.25 0.625 0.024 - 30 As 0.125 0.875 0.25 0.024 - 31 As 0.625 0.375 0.25 0.024 - 32 O 0.604319 0.190619 0.489965 0.082 - 33 O 0.5863 0.190619 0.200654 0.081 - 34 O 0.4137 0.809381 0.799346 0.081 - 35 O 0.799346 0.885646 0.989965 0.082 - 36 O 0.614354 0.700654 0.510035 0.081 - 37 O 0.9137 0.299346 0.309381 0.081 - 38 O 0.0863 0.700654 0.690619 0.081 - 39 O 0.885646 0.395681 0.0863 0.081 - 40 O 0.510035 0.395681 0.809381 0.081 - 41 O 0.5863 0.895681 0.385646 0.081 - 42 O 0.0863 0.885646 0.395681 0.081 - 43 O 0.809381 0.799346 0.4137 0.083 - 44 O 0.799346 0.4137 0.809381 0.082 - 45 O 0.4137 0.104319 0.614354 0.081 - 46 O 0.604319 0.9137 0.114354 0.082 - 47 O 0.489965 0.604319 0.190619 0.081 - 48 O 0.700654 0.510035 0.614354 0.082 - 49 O 0.104319 0.989965 0.690619 0.082 - 50 O 0.104319 0.614354 0.4137 0.082 - 51 O 0.385646 0.299346 0.489965 0.081 - 52 O 0.885646 0.989965 0.799346 0.081 - 53 O 0.385646 0.5863 0.895681 0.081 - 54 O 0.690619 0.0863 0.700654 0.083 - 55 O 0.114354 0.010035 0.200654 0.081 - 56 O 0.299346 0.309381 0.9137 0.082 - 57 O 0.489965 0.385646 0.299346 0.081 - 58 O 0.895681 0.385646 0.5863 0.082 - 59 O 0.700654 0.690619 0.0863 0.082 - 60 O 0.690619 0.104319 0.989965 0.083 - 61 O 0.395681 0.809381 0.510035 0.082 - 62 O 0.114354 0.604319 0.9137 0.081 - 63 O 0.510035 0.614354 0.700654 0.081 - 64 O 0.614354 0.4137 0.104319 0.081 - 65 O 0.9137 0.114354 0.604319 0.081 - 66 O 0.989965 0.690619 0.104319 0.081 - 67 O 0.010035 0.200654 0.114354 0.081 - 68 O 0.010035 0.309381 0.895681 0.081 - 69 O 0.895681 0.010035 0.309381 0.082 - 70 O 0.299346 0.489965 0.385646 0.082 - 71 O 0.190619 0.200654 0.5863 0.083 - 72 O 0.200654 0.114354 0.010035 0.082 - 73 O 0.309381 0.9137 0.299346 0.083 - 74 O 0.395681 0.0863 0.885646 0.082 - 75 O 0.200654 0.5863 0.190619 0.082 - 76 O 0.809381 0.510035 0.395681 0.083 - 77 O 0.989965 0.799346 0.885646 0.081 - 78 O 0.309381 0.895681 0.010035 0.083 - 79 O 0.190619 0.489965 0.604319 0.083","# generated using pymatgen -data_Na3Fe2(AsO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.76138928 -_cell_length_b 10.76138928 -_cell_length_c 10.76138928 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Fe2(AsO4)3 -_chemical_formula_sum 'Na12 Fe8 As12 O48' -_cell_volume 959.36337570 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.37500000 0.75000000 0.12500000 1 - Na Na1 1 0.25000000 0.37500000 0.12500000 1 - Na Na2 1 0.87500000 0.62500000 0.25000000 1 - Na Na3 1 0.12500000 0.37500000 0.75000000 1 - Na Na4 1 0.37500000 0.12500000 0.25000000 1 - Na Na5 1 0.75000000 0.62500000 0.87500000 1 - Na Na6 1 0.25000000 0.87500000 0.62500000 1 - Na Na7 1 0.75000000 0.12500000 0.37500000 1 - Na Na8 1 0.87500000 0.75000000 0.62500000 1 - Na Na9 1 0.62500000 0.87500000 0.75000000 1 - Na Na10 1 0.12500000 0.25000000 0.37500000 1 - Na Na11 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe12 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe13 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe17 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe18 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe19 1 0.00000000 0.50000000 0.50000000 1 - As As20 1 0.25000000 0.12500000 0.87500000 1 - As As21 1 0.87500000 0.12500000 0.75000000 1 - As As22 1 0.62500000 0.75000000 0.37500000 1 - As As23 1 0.37500000 0.62500000 0.75000000 1 - As As24 1 0.25000000 0.62500000 0.37500000 1 - As As25 1 0.75000000 0.37500000 0.62500000 1 - As As26 1 0.75000000 0.87500000 0.12500000 1 - As As27 1 0.87500000 0.25000000 0.12500000 1 - As As28 1 0.12500000 0.75000000 0.87500000 1 - As As29 1 0.37500000 0.25000000 0.62500000 1 - As As30 1 0.12500000 0.87500000 0.25000000 1 - As As31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.60431900 0.19061900 0.48996500 1 - O O33 1 0.58630000 0.19061900 0.20065400 1 - O O34 1 0.41370000 0.80938100 0.79934600 1 - O O35 1 0.79934600 0.88564600 0.98996500 1 - O O36 1 0.61435400 0.70065400 0.51003500 1 - O O37 1 0.91370000 0.29934600 0.30938100 1 - O O38 1 0.08630000 0.70065400 0.69061900 1 - O O39 1 0.88564600 0.39568100 0.08630000 1 - O O40 1 0.51003500 0.39568100 0.80938100 1 - O O41 1 0.58630000 0.89568100 0.38564600 1 - O O42 1 0.08630000 0.88564600 0.39568100 1 - O O43 1 0.80938100 0.79934600 0.41370000 1 - O O44 1 0.79934600 0.41370000 0.80938100 1 - O O45 1 0.41370000 0.10431900 0.61435400 1 - O O46 1 0.60431900 0.91370000 0.11435400 1 - O O47 1 0.48996500 0.60431900 0.19061900 1 - O O48 1 0.70065400 0.51003500 0.61435400 1 - O O49 1 0.10431900 0.98996500 0.69061900 1 - O O50 1 0.10431900 0.61435400 0.41370000 1 - O O51 1 0.38564600 0.29934600 0.48996500 1 - O O52 1 0.88564600 0.98996500 0.79934600 1 - O O53 1 0.38564600 0.58630000 0.89568100 1 - O O54 1 0.69061900 0.08630000 0.70065400 1 - O O55 1 0.11435400 0.01003500 0.20065400 1 - O O56 1 0.29934600 0.30938100 0.91370000 1 - O O57 1 0.48996500 0.38564600 0.29934600 1 - O O58 1 0.89568100 0.38564600 0.58630000 1 - O O59 1 0.70065400 0.69061900 0.08630000 1 - O O60 1 0.69061900 0.10431900 0.98996500 1 - O O61 1 0.39568100 0.80938100 0.51003500 1 - O O62 1 0.11435400 0.60431900 0.91370000 1 - O O63 1 0.51003500 0.61435400 0.70065400 1 - O O64 1 0.61435400 0.41370000 0.10431900 1 - O O65 1 0.91370000 0.11435400 0.60431900 1 - O O66 1 0.98996500 0.69061900 0.10431900 1 - O O67 1 0.01003500 0.20065400 0.11435400 1 - O O68 1 0.01003500 0.30938100 0.89568100 1 - O O69 1 0.89568100 0.01003500 0.30938100 1 - O O70 1 0.29934600 0.48996500 0.38564600 1 - O O71 1 0.19061900 0.20065400 0.58630000 1 - O O72 1 0.20065400 0.11435400 0.01003500 1 - O O73 1 0.30938100 0.91370000 0.29934600 1 - O O74 1 0.39568100 0.08630000 0.88564600 1 - O O75 1 0.20065400 0.58630000 0.19061900 1 - O O76 1 0.80938100 0.51003500 0.39568100 1 - O O77 1 0.98996500 0.79934600 0.88564600 1 - O O78 1 0.30938100 0.89568100 0.01003500 1 - O O79 1 0.19061900 0.48996500 0.60431900 1 -" -Li3Nd3(WO6)2,mp-557717,Ia-3d,[245640],0.0,{'tags': ['Trilithium trineodymium dodecaoxoditungstate(VI)']},"Full Formula (Li12 Nd12 W8 O48) -Reduced Formula: Li3Nd3(WO6)2 -abc : 10.945714 10.945714 10.945714 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.25 0.125 0.875 -0 - 1 Li 0.375 0.625 0.75 -0 - 2 Li 0.25 0.625 0.375 -0 - 3 Li 0.875 0.125 0.75 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.125 0.875 0.25 -0 - 6 Li 0.125 0.75 0.875 -0 - 7 Li 0.75 0.375 0.625 -0 - 8 Li 0.75 0.875 0.125 -0 - 9 Li 0.625 0.375 0.25 -0 - 10 Li 0.375 0.25 0.625 -0 - 11 Li 0.875 0.25 0.125 -0 - 12 Nd 0.375 0.125 0.25 -0 - 13 Nd 0.875 0.625 0.25 -0 - 14 Nd 0.625 0.25 0.875 -0 - 15 Nd 0.25 0.375 0.125 -0 - 16 Nd 0.125 0.375 0.75 -0 - 17 Nd 0.375 0.75 0.125 -0 - 18 Nd 0.875 0.75 0.625 -0 - 19 Nd 0.75 0.125 0.375 -0 - 20 Nd 0.625 0.875 0.75 -0 - 21 Nd 0.125 0.25 0.375 -0 - 22 Nd 0.75 0.625 0.875 -0 - 23 Nd 0.25 0.875 0.625 -0 - 24 W 0 0.5 0.5 -0.001 - 25 W 0.5 0.5 0.5 -0.001 - 26 W 0.5 0 0.5 -0.001 - 27 W 0.5 0 0 -0.001 - 28 W 0.5 0.5 0 -0.001 - 29 W 0 0 0 -0.001 - 30 W 0 0 0.5 -0.001 - 31 W 0 0.5 0 -0.001 - 32 O 0.579988 0.908338 0.384536 0 - 33 O 0.591662 0.17165 0.476199 0 - 34 O 0.115464 0.023801 0.195452 0 - 35 O 0.976199 0.804548 0.884536 0 - 36 O 0.32835 0.920012 0.304548 0 - 37 O 0.384536 0.579988 0.908338 0 - 38 O 0.82835 0.804548 0.420012 0 - 39 O 0.920012 0.115464 0.591662 0 - 40 O 0.091662 0.976199 0.67165 0 - 41 O 0.804548 0.420012 0.82835 0 - 42 O 0.408338 0.82835 0.523801 0 - 43 O 0.32835 0.908338 0.023801 0 - 44 O 0.884536 0.408338 0.079988 0 - 45 O 0.476199 0.591662 0.17165 0 - 46 O 0.195452 0.115464 0.023801 0 - 47 O 0.304548 0.32835 0.920012 0 - 48 O 0.908338 0.384536 0.579988 0 - 49 O 0.591662 0.920012 0.115464 0 - 50 O 0.476199 0.384536 0.304548 0 - 51 O 0.420012 0.82835 0.804548 0 - 52 O 0.195452 0.579988 0.17165 0 - 53 O 0.804548 0.884536 0.976199 0 - 54 O 0.695452 0.523801 0.615464 0 - 55 O 0.523801 0.408338 0.82835 0 - 56 O 0.304548 0.476199 0.384536 0 - 57 O 0.384536 0.304548 0.476199 0 - 58 O 0.17165 0.476199 0.591662 0 - 59 O 0.023801 0.32835 0.908338 0 - 60 O 0.408338 0.079988 0.884536 0 - 61 O 0.976199 0.67165 0.091662 0 - 62 O 0.079988 0.695452 0.67165 0 - 63 O 0.615464 0.420012 0.091662 0 - 64 O 0.420012 0.091662 0.615464 0 - 65 O 0.579988 0.17165 0.195452 0 - 66 O 0.523801 0.615464 0.695452 0 - 67 O 0.115464 0.591662 0.920012 0 - 68 O 0.884536 0.976199 0.804548 0 - 69 O 0.023801 0.195452 0.115464 0 - 70 O 0.67165 0.079988 0.695452 0 - 71 O 0.908338 0.023801 0.32835 0 - 72 O 0.695452 0.67165 0.079988 0 - 73 O 0.079988 0.884536 0.408338 0 - 74 O 0.82835 0.523801 0.408338 0 - 75 O 0.67165 0.091662 0.976199 0 - 76 O 0.920012 0.304548 0.32835 0 - 77 O 0.17165 0.195452 0.579988 0 - 78 O 0.091662 0.615464 0.420012 0 - 79 O 0.615464 0.695452 0.523801 0","# generated using pymatgen -data_Li3Nd3(WO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.94571413 -_cell_length_b 10.94571413 -_cell_length_c 10.94571413 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Nd3(WO6)2 -_chemical_formula_sum 'Li12 Nd12 W8 O48' -_cell_volume 1009.50950813 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.25000000 0.12500000 0.87500000 1 - Li Li1 1 0.37500000 0.62500000 0.75000000 1 - Li Li2 1 0.25000000 0.62500000 0.37500000 1 - Li Li3 1 0.87500000 0.12500000 0.75000000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.12500000 0.87500000 0.25000000 1 - Li Li6 1 0.12500000 0.75000000 0.87500000 1 - Li Li7 1 0.75000000 0.37500000 0.62500000 1 - Li Li8 1 0.75000000 0.87500000 0.12500000 1 - Li Li9 1 0.62500000 0.37500000 0.25000000 1 - Li Li10 1 0.37500000 0.25000000 0.62500000 1 - Li Li11 1 0.87500000 0.25000000 0.12500000 1 - Nd Nd12 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd13 1 0.87500000 0.62500000 0.25000000 1 - Nd Nd14 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd15 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd16 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd17 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd18 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd19 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd20 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd21 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd22 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd23 1 0.25000000 0.87500000 0.62500000 1 - W W24 1 0.00000000 0.50000000 0.50000000 1 - W W25 1 0.50000000 0.50000000 0.50000000 1 - W W26 1 0.50000000 0.00000000 0.50000000 1 - W W27 1 0.50000000 0.00000000 0.00000000 1 - W W28 1 0.50000000 0.50000000 0.00000000 1 - W W29 1 0.00000000 0.00000000 0.00000000 1 - W W30 1 0.00000000 0.00000000 0.50000000 1 - W W31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.57998800 0.90833800 0.38453600 1 - O O33 1 0.59166200 0.17165000 0.47619900 1 - O O34 1 0.11546400 0.02380100 0.19545200 1 - O O35 1 0.97619900 0.80454800 0.88453600 1 - O O36 1 0.32835000 0.92001200 0.30454800 1 - O O37 1 0.38453600 0.57998800 0.90833800 1 - O O38 1 0.82835000 0.80454800 0.42001200 1 - O O39 1 0.92001200 0.11546400 0.59166200 1 - O O40 1 0.09166200 0.97619900 0.67165000 1 - O O41 1 0.80454800 0.42001200 0.82835000 1 - O O42 1 0.40833800 0.82835000 0.52380100 1 - O O43 1 0.32835000 0.90833800 0.02380100 1 - O O44 1 0.88453600 0.40833800 0.07998800 1 - O O45 1 0.47619900 0.59166200 0.17165000 1 - O O46 1 0.19545200 0.11546400 0.02380100 1 - O O47 1 0.30454800 0.32835000 0.92001200 1 - O O48 1 0.90833800 0.38453600 0.57998800 1 - O O49 1 0.59166200 0.92001200 0.11546400 1 - O O50 1 0.47619900 0.38453600 0.30454800 1 - O O51 1 0.42001200 0.82835000 0.80454800 1 - O O52 1 0.19545200 0.57998800 0.17165000 1 - O O53 1 0.80454800 0.88453600 0.97619900 1 - O O54 1 0.69545200 0.52380100 0.61546400 1 - O O55 1 0.52380100 0.40833800 0.82835000 1 - O O56 1 0.30454800 0.47619900 0.38453600 1 - O O57 1 0.38453600 0.30454800 0.47619900 1 - O O58 1 0.17165000 0.47619900 0.59166200 1 - O O59 1 0.02380100 0.32835000 0.90833800 1 - O O60 1 0.40833800 0.07998800 0.88453600 1 - O O61 1 0.97619900 0.67165000 0.09166200 1 - O O62 1 0.07998800 0.69545200 0.67165000 1 - O O63 1 0.61546400 0.42001200 0.09166200 1 - O O64 1 0.42001200 0.09166200 0.61546400 1 - O O65 1 0.57998800 0.17165000 0.19545200 1 - O O66 1 0.52380100 0.61546400 0.69545200 1 - O O67 1 0.11546400 0.59166200 0.92001200 1 - O O68 1 0.88453600 0.97619900 0.80454800 1 - O O69 1 0.02380100 0.19545200 0.11546400 1 - O O70 1 0.67165000 0.07998800 0.69545200 1 - O O71 1 0.90833800 0.02380100 0.32835000 1 - O O72 1 0.69545200 0.67165000 0.07998800 1 - O O73 1 0.07998800 0.88453600 0.40833800 1 - O O74 1 0.82835000 0.52380100 0.40833800 1 - O O75 1 0.67165000 0.09166200 0.97619900 1 - O O76 1 0.92001200 0.30454800 0.32835000 1 - O O77 1 0.17165000 0.19545200 0.57998800 1 - O O78 1 0.09166200 0.61546400 0.42001200 1 - O O79 1 0.61546400 0.69545200 0.52380100 1 -" -Ca3Al2(SiO4)3,mp-6008,Ia-3d,"[94614, 24944, 202311, 100621, 50626, 100620, 94618, 94612, 89675, 24945, 94610, 41316, 100619, 100622, 31082, 94613, 94619, 94615, 77429, 26797, 26798, 24946, 94617, 16750, 94611, 94616, 64752, 50625, 86350, 83460, 83461, 83462]",0.0009067950972232453,"{'tags': ['Tricalcium dialuminium trisilicate', 'Dialuminium tricalcium tris(silicate)', 'Dialuminium tricalcium silicate', 'Grossular', 'Tricalcium dialuminium tris(silicate)', 'Tricalcium aluminium tris(silicate)', 'Tricalcium dialuminium silicate', 'High pressure experimental phase', 'Tricalcium dialuminum tris(silicate)']}","Full Formula (Ca12 Al8 Si12 O48) -Reduced Formula: Ca3Al2(SiO4)3 -abc : 10.365449 10.365449 10.365449 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.875 0.75 0.625 0 - 1 Ca 0.875 0.625 0.25 0 - 2 Ca 0.625 0.875 0.75 0 - 3 Ca 0.25 0.875 0.625 0 - 4 Ca 0.75 0.625 0.875 0 - 5 Ca 0.625 0.25 0.875 0 - 6 Ca 0.125 0.25 0.375 0 - 7 Ca 0.125 0.375 0.75 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.75 0.125 0.375 0 - 10 Ca 0.25 0.375 0.125 0 - 11 Ca 0.375 0.75 0.125 0 - 12 Al 0 0 0 0 - 13 Al 0.5 0 0 0 - 14 Al 0.5 0.5 0 0 - 15 Al 0 0.5 0.5 0 - 16 Al 0 0 0.5 0 - 17 Al 0.5 0.5 0.5 0 - 18 Al 0 0.5 0 0 - 19 Al 0.5 0 0.5 0 - 20 Si 0.125 0.75 0.875 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 0 - 24 Si 0.875 0.125 0.75 0 - 25 Si 0.375 0.25 0.625 0 - 26 Si 0.375 0.625 0.75 0 - 27 Si 0.25 0.125 0.875 0 - 28 Si 0.625 0.375 0.25 0 - 29 Si 0.125 0.875 0.25 0 - 30 Si 0.75 0.375 0.625 0 - 31 Si 0.875 0.25 0.125 0 - 32 O 0.804024 0.417303 0.810772 -0 - 33 O 0.810772 0.804024 0.417303 -0 - 34 O 0.506748 0.613279 0.695976 -0 - 35 O 0.393469 0.082697 0.886721 -0 - 36 O 0.613279 0.417303 0.106531 -0 - 37 O 0.689228 0.106531 0.993252 -0 - 38 O 0.810772 0.506748 0.393469 -0 - 39 O 0.417303 0.810772 0.804024 -0 - 40 O 0.886721 0.993252 0.804024 -0 - 41 O 0.393469 0.810772 0.506748 -0 - 42 O 0.417303 0.106531 0.613279 -0 - 43 O 0.082697 0.695976 0.689228 -0 - 44 O 0.695976 0.689228 0.082697 -0 - 45 O 0.506748 0.393469 0.810772 -0 - 46 O 0.804024 0.886721 0.993252 -0 - 47 O 0.993252 0.804024 0.886721 -0 - 48 O 0.106531 0.613279 0.417303 -0 - 49 O 0.695976 0.506748 0.613279 -0 - 50 O 0.106531 0.993252 0.689228 -0 - 51 O 0.113279 0.006748 0.195976 -0 - 52 O 0.886721 0.393469 0.082697 -0 - 53 O 0.082697 0.886721 0.393469 -0 - 54 O 0.993252 0.689228 0.106531 -0 - 55 O 0.689228 0.082697 0.695976 -0 - 56 O 0.195976 0.582697 0.189228 -0 - 57 O 0.189228 0.195976 0.582697 -0 - 58 O 0.493252 0.386721 0.304024 -0 - 59 O 0.606531 0.917303 0.113279 -0 - 60 O 0.386721 0.582697 0.893469 -0 - 61 O 0.310772 0.893469 0.006748 -0 - 62 O 0.189228 0.493252 0.606531 -0 - 63 O 0.582697 0.189228 0.195976 -0 - 64 O 0.310772 0.917303 0.304024 -0 - 65 O 0.006748 0.310772 0.893469 -0 - 66 O 0.917303 0.113279 0.606531 -0 - 67 O 0.386721 0.304024 0.493252 -0 - 68 O 0.113279 0.606531 0.917303 -0 - 69 O 0.893469 0.006748 0.310772 -0 - 70 O 0.304024 0.493252 0.386721 -0 - 71 O 0.893469 0.386721 0.582697 -0 - 72 O 0.006748 0.195976 0.113279 -0 - 73 O 0.195976 0.113279 0.006748 -0 - 74 O 0.493252 0.606531 0.189228 -0 - 75 O 0.304024 0.310772 0.917303 -0 - 76 O 0.917303 0.304024 0.310772 -0 - 77 O 0.582697 0.893469 0.386721 -0 - 78 O 0.606531 0.189228 0.493252 -0 - 79 O 0.613279 0.695976 0.506748 -0","# generated using pymatgen -data_Ca3Al2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.36544940 -_cell_length_b 10.36544940 -_cell_length_c 10.36544940 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Al2(SiO4)3 -_chemical_formula_sum 'Ca12 Al8 Si12 O48' -_cell_volume 857.31913425 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca1 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca4 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca5 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca6 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca7 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca10 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Al Al12 1 0.00000000 0.00000000 0.00000000 1 - Al Al13 1 0.50000000 0.00000000 0.00000000 1 - Al Al14 1 0.50000000 0.50000000 0.00000000 1 - Al Al15 1 0.00000000 0.50000000 0.50000000 1 - Al Al16 1 0.00000000 0.00000000 0.50000000 1 - Al Al17 1 0.50000000 0.50000000 0.50000000 1 - Al Al18 1 0.00000000 0.50000000 0.00000000 1 - Al Al19 1 0.50000000 0.00000000 0.50000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.87500000 0.12500000 0.75000000 1 - Si Si25 1 0.37500000 0.25000000 0.62500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.25000000 0.12500000 0.87500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.12500000 0.87500000 0.25000000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.87500000 0.25000000 0.12500000 1 - O O32 1 0.80402400 0.41730300 0.81077200 1 - O O33 1 0.81077200 0.80402400 0.41730300 1 - O O34 1 0.50674800 0.61327900 0.69597600 1 - O O35 1 0.39346900 0.08269700 0.88672100 1 - O O36 1 0.61327900 0.41730300 0.10653100 1 - O O37 1 0.68922800 0.10653100 0.99325200 1 - O O38 1 0.81077200 0.50674800 0.39346900 1 - O O39 1 0.41730300 0.81077200 0.80402400 1 - O O40 1 0.88672100 0.99325200 0.80402400 1 - O O41 1 0.39346900 0.81077200 0.50674800 1 - O O42 1 0.41730300 0.10653100 0.61327900 1 - O O43 1 0.08269700 0.69597600 0.68922800 1 - O O44 1 0.69597600 0.68922800 0.08269700 1 - O O45 1 0.50674800 0.39346900 0.81077200 1 - O O46 1 0.80402400 0.88672100 0.99325200 1 - O O47 1 0.99325200 0.80402400 0.88672100 1 - O O48 1 0.10653100 0.61327900 0.41730300 1 - O O49 1 0.69597600 0.50674800 0.61327900 1 - O O50 1 0.10653100 0.99325200 0.68922800 1 - O O51 1 0.11327900 0.00674800 0.19597600 1 - O O52 1 0.88672100 0.39346900 0.08269700 1 - O O53 1 0.08269700 0.88672100 0.39346900 1 - O O54 1 0.99325200 0.68922800 0.10653100 1 - O O55 1 0.68922800 0.08269700 0.69597600 1 - O O56 1 0.19597600 0.58269700 0.18922800 1 - O O57 1 0.18922800 0.19597600 0.58269700 1 - O O58 1 0.49325200 0.38672100 0.30402400 1 - O O59 1 0.60653100 0.91730300 0.11327900 1 - O O60 1 0.38672100 0.58269700 0.89346900 1 - O O61 1 0.31077200 0.89346900 0.00674800 1 - O O62 1 0.18922800 0.49325200 0.60653100 1 - O O63 1 0.58269700 0.18922800 0.19597600 1 - O O64 1 0.31077200 0.91730300 0.30402400 1 - O O65 1 0.00674800 0.31077200 0.89346900 1 - O O66 1 0.91730300 0.11327900 0.60653100 1 - O O67 1 0.38672100 0.30402400 0.49325200 1 - O O68 1 0.11327900 0.60653100 0.91730300 1 - O O69 1 0.89346900 0.00674800 0.31077200 1 - O O70 1 0.30402400 0.49325200 0.38672100 1 - O O71 1 0.89346900 0.38672100 0.58269700 1 - O O72 1 0.00674800 0.19597600 0.11327900 1 - O O73 1 0.19597600 0.11327900 0.00674800 1 - O O74 1 0.49325200 0.60653100 0.18922800 1 - O O75 1 0.30402400 0.31077200 0.91730300 1 - O O76 1 0.91730300 0.30402400 0.31077200 1 - O O77 1 0.58269700 0.89346900 0.38672100 1 - O O78 1 0.60653100 0.18922800 0.49325200 1 - O O79 1 0.61327900 0.69597600 0.50674800 1 -" -Mg3Al2(SiO4)3,mp-6073,Ia-3d,"[71887, 86908, 50617, 182382, 15438, 86911, 27362, 50618, 89676, 100618, 100614, 34810, 182378, 86349, 100616, 182376, 41310, 182384, 86913, 182388, 80844, 82829, 182387, 182389, 182385, 80847, 86914, 182391, 100617, 86912, 86909, 86910, 182374, 182377, 80845, 24940, 89252, 71892, 182383, 182390, 182371, 24943, 182373, 182379, 182380, 182386, 182381, 24942, 80846, 24941, 182375, 89250, 100615, 77426, 79275]",0.03907302529999512,"{'tags': ['Tricalcium dialuminium tris(silicate)', 'Trimagnesium dialuminum tris(silicate)', 'Trimagnesium dialuminium tris(silicate)', 'Pyrope', 'High pressure experimental phase', 'Trimagnesium dialuminium trisilicate']}","Full Formula (Mg12 Al8 Si12 O48) -Reduced Formula: Mg3Al2(SiO4)3 -abc : 10.020979 10.020979 10.020979 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.375 0.125 0.25 0 - 1 Mg 0.75 0.125 0.375 0 - 2 Mg 0.25 0.375 0.125 0 - 3 Mg 0.125 0.25 0.375 0 - 4 Mg 0.375 0.75 0.125 0 - 5 Mg 0.125 0.375 0.75 0 - 6 Mg 0.625 0.875 0.75 0 - 7 Mg 0.25 0.875 0.625 0 - 8 Mg 0.75 0.625 0.875 0 - 9 Mg 0.875 0.75 0.625 0 - 10 Mg 0.625 0.25 0.875 0 - 11 Mg 0.875 0.625 0.25 0 - 12 Al 0 0 0 -0 - 13 Al 0.5 0 0 -0 - 14 Al 0 0.5 0 -0 - 15 Al 0 0 0.5 -0 - 16 Al 0.5 0.5 0 -0 - 17 Al 0 0.5 0.5 -0 - 18 Al 0.5 0 0.5 -0 - 19 Al 0.5 0.5 0.5 -0 - 20 Si 0.625 0.375 0.25 -0 - 21 Si 0.75 0.375 0.625 -0 - 22 Si 0.25 0.125 0.875 -0 - 23 Si 0.875 0.25 0.125 -0 - 24 Si 0.625 0.75 0.375 -0 - 25 Si 0.375 0.625 0.75 -0 - 26 Si 0.125 0.75 0.875 -0 - 27 Si 0.75 0.875 0.125 -0 - 28 Si 0.375 0.25 0.625 -0 - 29 Si 0.25 0.625 0.375 -0 - 30 Si 0.875 0.125 0.75 -0 - 31 Si 0.125 0.875 0.25 -0 - 32 O 0.685953 0.082813 0.703501 0 - 33 O 0.103141 0.982452 0.685953 0 - 34 O 0.703501 0.517548 0.620689 0 - 35 O 0.620689 0.703501 0.517548 0 - 36 O 0.879311 0.396859 0.082813 0 - 37 O 0.082813 0.879311 0.396859 0 - 38 O 0.982452 0.685953 0.103141 0 - 39 O 0.417187 0.103141 0.620689 0 - 40 O 0.396859 0.814047 0.517548 0 - 41 O 0.982452 0.796499 0.879311 0 - 42 O 0.103141 0.620689 0.417187 0 - 43 O 0.517548 0.396859 0.814047 0 - 44 O 0.796499 0.879311 0.982452 0 - 45 O 0.703501 0.685953 0.082813 0 - 46 O 0.082813 0.703501 0.685953 0 - 47 O 0.620689 0.417187 0.103141 0 - 48 O 0.796499 0.417187 0.814047 0 - 49 O 0.814047 0.517548 0.396859 0 - 50 O 0.814047 0.796499 0.417187 0 - 51 O 0.879311 0.982452 0.796499 0 - 52 O 0.417187 0.814047 0.796499 0 - 53 O 0.396859 0.082813 0.879311 0 - 54 O 0.685953 0.103141 0.982452 0 - 55 O 0.517548 0.620689 0.703501 0 - 56 O 0.314047 0.917187 0.296499 0 - 57 O 0.896859 0.017548 0.314047 0 - 58 O 0.296499 0.482452 0.379311 0 - 59 O 0.379311 0.296499 0.482452 0 - 60 O 0.120689 0.603141 0.917187 0 - 61 O 0.917187 0.120689 0.603141 0 - 62 O 0.017548 0.314047 0.896859 0 - 63 O 0.582813 0.896859 0.379311 0 - 64 O 0.603141 0.185953 0.482452 0 - 65 O 0.017548 0.203501 0.120689 0 - 66 O 0.896859 0.379311 0.582813 0 - 67 O 0.482452 0.603141 0.185953 0 - 68 O 0.203501 0.120689 0.017548 0 - 69 O 0.296499 0.314047 0.917187 0 - 70 O 0.917187 0.296499 0.314047 0 - 71 O 0.379311 0.582813 0.896859 0 - 72 O 0.203501 0.582813 0.185953 0 - 73 O 0.185953 0.482452 0.603141 0 - 74 O 0.185953 0.203501 0.582813 0 - 75 O 0.120689 0.017548 0.203501 0 - 76 O 0.582813 0.185953 0.203501 0 - 77 O 0.603141 0.917187 0.120689 0 - 78 O 0.314047 0.896859 0.017548 0 - 79 O 0.482452 0.379311 0.296499 0","# generated using pymatgen -data_Mg3Al2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.02097913 -_cell_length_b 10.02097913 -_cell_length_c 10.02097913 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Al2(SiO4)3 -_chemical_formula_sum 'Mg12 Al8 Si12 O48' -_cell_volume 774.65545350 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg3 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg4 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg5 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg6 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg7 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg8 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg9 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg10 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.00000000 0.00000000 0.00000000 1 - Al Al13 1 0.50000000 0.00000000 0.00000000 1 - Al Al14 1 0.00000000 0.50000000 0.00000000 1 - Al Al15 1 0.00000000 0.00000000 0.50000000 1 - Al Al16 1 0.50000000 0.50000000 0.00000000 1 - Al Al17 1 0.00000000 0.50000000 0.50000000 1 - Al Al18 1 0.50000000 0.00000000 0.50000000 1 - Al Al19 1 0.50000000 0.50000000 0.50000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.37500000 0.62500000 1 - Si Si22 1 0.25000000 0.12500000 0.87500000 1 - Si Si23 1 0.87500000 0.25000000 0.12500000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.37500000 0.25000000 0.62500000 1 - Si Si29 1 0.25000000 0.62500000 0.37500000 1 - Si Si30 1 0.87500000 0.12500000 0.75000000 1 - Si Si31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.68595300 0.08281300 0.70350100 1 - O O33 1 0.10314100 0.98245200 0.68595300 1 - O O34 1 0.70350100 0.51754800 0.62068900 1 - O O35 1 0.62068900 0.70350100 0.51754800 1 - O O36 1 0.87931100 0.39685900 0.08281300 1 - O O37 1 0.08281300 0.87931100 0.39685900 1 - O O38 1 0.98245200 0.68595300 0.10314100 1 - O O39 1 0.41718700 0.10314100 0.62068900 1 - O O40 1 0.39685900 0.81404700 0.51754800 1 - O O41 1 0.98245200 0.79649900 0.87931100 1 - O O42 1 0.10314100 0.62068900 0.41718700 1 - O O43 1 0.51754800 0.39685900 0.81404700 1 - O O44 1 0.79649900 0.87931100 0.98245200 1 - O O45 1 0.70350100 0.68595300 0.08281300 1 - O O46 1 0.08281300 0.70350100 0.68595300 1 - O O47 1 0.62068900 0.41718700 0.10314100 1 - O O48 1 0.79649900 0.41718700 0.81404700 1 - O O49 1 0.81404700 0.51754800 0.39685900 1 - O O50 1 0.81404700 0.79649900 0.41718700 1 - O O51 1 0.87931100 0.98245200 0.79649900 1 - O O52 1 0.41718700 0.81404700 0.79649900 1 - O O53 1 0.39685900 0.08281300 0.87931100 1 - O O54 1 0.68595300 0.10314100 0.98245200 1 - O O55 1 0.51754800 0.62068900 0.70350100 1 - O O56 1 0.31404700 0.91718700 0.29649900 1 - O O57 1 0.89685900 0.01754800 0.31404700 1 - O O58 1 0.29649900 0.48245200 0.37931100 1 - O O59 1 0.37931100 0.29649900 0.48245200 1 - O O60 1 0.12068900 0.60314100 0.91718700 1 - O O61 1 0.91718700 0.12068900 0.60314100 1 - O O62 1 0.01754800 0.31404700 0.89685900 1 - O O63 1 0.58281300 0.89685900 0.37931100 1 - O O64 1 0.60314100 0.18595300 0.48245200 1 - O O65 1 0.01754800 0.20350100 0.12068900 1 - O O66 1 0.89685900 0.37931100 0.58281300 1 - O O67 1 0.48245200 0.60314100 0.18595300 1 - O O68 1 0.20350100 0.12068900 0.01754800 1 - O O69 1 0.29649900 0.31404700 0.91718700 1 - O O70 1 0.91718700 0.29649900 0.31404700 1 - O O71 1 0.37931100 0.58281300 0.89685900 1 - O O72 1 0.20350100 0.58281300 0.18595300 1 - O O73 1 0.18595300 0.48245200 0.60314100 1 - O O74 1 0.18595300 0.20350100 0.58281300 1 - O O75 1 0.12068900 0.01754800 0.20350100 1 - O O76 1 0.58281300 0.18595300 0.20350100 1 - O O77 1 0.60314100 0.91718700 0.12068900 1 - O O78 1 0.31404700 0.89685900 0.01754800 1 - O O79 1 0.48245200 0.37931100 0.29649900 1 -" -Na3Li3V2F12,mp-6153,Ia-3d,"[60364, 61611]",0.0,"{'tags': ['Trilithium trisodium divanadium dodecafluoride', 'Trisodium trilithium divanadium dodecafluoride']}","Full Formula (Na12 Li12 V8 F48) -Reduced Formula: Na3Li3V2F12 -abc : 10.933928 10.933928 10.933928 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.375 0.125 0.25 0 - 1 Na 0.75 0.125 0.375 0 - 2 Na 0.25 0.375 0.125 0 - 3 Na 0.125 0.25 0.375 0 - 4 Na 0.375 0.75 0.125 0 - 5 Na 0.125 0.375 0.75 0 - 6 Na 0.625 0.875 0.75 0 - 7 Na 0.25 0.875 0.625 0 - 8 Na 0.875 0.625 0.25 0 - 9 Na 0.625 0.25 0.875 0 - 10 Na 0.75 0.625 0.875 0 - 11 Na 0.875 0.75 0.625 0 - 12 Li 0.625 0.375 0.25 0 - 13 Li 0.125 0.875 0.25 0 - 14 Li 0.875 0.125 0.75 0 - 15 Li 0.25 0.625 0.375 0 - 16 Li 0.375 0.25 0.625 0 - 17 Li 0.75 0.875 0.125 0 - 18 Li 0.125 0.75 0.875 0 - 19 Li 0.375 0.625 0.75 0 - 20 Li 0.625 0.75 0.375 0 - 21 Li 0.875 0.25 0.125 0 - 22 Li 0.25 0.125 0.875 0 - 23 Li 0.75 0.375 0.625 0 - 24 V 0 0 0 1.892 - 25 V 0.5 0 0 1.892 - 26 V 0 0.5 0 1.892 - 27 V 0 0 0.5 1.892 - 28 V 0.5 0.5 0 1.892 - 29 V 0 0.5 0.5 1.892 - 30 V 0.5 0 0.5 1.892 - 31 V 0.5 0.5 0.5 1.892 - 32 F 0.077649 0.882827 0.402241 0.003 - 33 F 0.694822 0.675407 0.077649 0.003 - 34 F 0.805178 0.882827 0.980585 0.003 - 35 F 0.980585 0.805178 0.882827 0.003 - 36 F 0.824593 0.519415 0.402241 0.003 - 37 F 0.694822 0.519415 0.617173 0.003 - 38 F 0.617173 0.422351 0.097759 0.003 - 39 F 0.617173 0.694822 0.519415 0.003 - 40 F 0.675407 0.077649 0.694822 0.003 - 41 F 0.519415 0.617173 0.694822 0.003 - 42 F 0.097759 0.980585 0.675407 0.003 - 43 F 0.882827 0.402241 0.077649 0.003 - 44 F 0.422351 0.097759 0.617173 0.003 - 45 F 0.402241 0.824593 0.519415 0.003 - 46 F 0.077649 0.694822 0.675407 0.003 - 47 F 0.097759 0.617173 0.422351 0.003 - 48 F 0.519415 0.402241 0.824593 0.003 - 49 F 0.422351 0.824593 0.805178 0.003 - 50 F 0.980585 0.675407 0.097759 0.003 - 51 F 0.824593 0.805178 0.422351 0.003 - 52 F 0.117173 0.019415 0.194822 0.003 - 53 F 0.597759 0.922351 0.117173 0.003 - 54 F 0.194822 0.577649 0.175407 0.003 - 55 F 0.175407 0.194822 0.577649 0.003 - 56 F 0.324593 0.902241 0.019415 0.003 - 57 F 0.019415 0.324593 0.902241 0.003 - 58 F 0.922351 0.117173 0.597759 0.003 - 59 F 0.480585 0.597759 0.175407 0.003 - 60 F 0.902241 0.382827 0.577649 0.003 - 61 F 0.922351 0.305178 0.324593 0.003 - 62 F 0.597759 0.175407 0.480585 0.003 - 63 F 0.577649 0.902241 0.382827 0.003 - 64 F 0.305178 0.324593 0.922351 0.003 - 65 F 0.194822 0.117173 0.019415 0.003 - 66 F 0.019415 0.194822 0.117173 0.003 - 67 F 0.175407 0.480585 0.597759 0.003 - 68 F 0.305178 0.480585 0.382827 0.003 - 69 F 0.382827 0.577649 0.902241 0.003 - 70 F 0.382827 0.305178 0.480585 0.003 - 71 F 0.324593 0.922351 0.305178 0.003 - 72 F 0.480585 0.382827 0.305178 0.003 - 73 F 0.902241 0.019415 0.324593 0.003 - 74 F 0.117173 0.597759 0.922351 0.003 - 75 F 0.577649 0.175407 0.194822 0.003 - 76 F 0.882827 0.980585 0.805178 0.003 - 77 F 0.402241 0.077649 0.882827 0.003 - 78 F 0.805178 0.422351 0.824593 0.003 - 79 F 0.675407 0.097759 0.980585 0.003","# generated using pymatgen -data_Na3Li3V2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.93392753 -_cell_length_b 10.93392753 -_cell_length_c 10.93392753 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3V2F12 -_chemical_formula_sum 'Na12 Li12 V8 F48' -_cell_volume 1006.25182693 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.37500000 0.12500000 0.25000000 1 - Na Na1 1 0.75000000 0.12500000 0.37500000 1 - Na Na2 1 0.25000000 0.37500000 0.12500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.37500000 0.75000000 0.12500000 1 - Na Na5 1 0.12500000 0.37500000 0.75000000 1 - Na Na6 1 0.62500000 0.87500000 0.75000000 1 - Na Na7 1 0.25000000 0.87500000 0.62500000 1 - Na Na8 1 0.87500000 0.62500000 0.25000000 1 - Na Na9 1 0.62500000 0.25000000 0.87500000 1 - Na Na10 1 0.75000000 0.62500000 0.87500000 1 - Na Na11 1 0.87500000 0.75000000 0.62500000 1 - Li Li12 1 0.62500000 0.37500000 0.25000000 1 - Li Li13 1 0.12500000 0.87500000 0.25000000 1 - Li Li14 1 0.87500000 0.12500000 0.75000000 1 - Li Li15 1 0.25000000 0.62500000 0.37500000 1 - Li Li16 1 0.37500000 0.25000000 0.62500000 1 - Li Li17 1 0.75000000 0.87500000 0.12500000 1 - Li Li18 1 0.12500000 0.75000000 0.87500000 1 - Li Li19 1 0.37500000 0.62500000 0.75000000 1 - Li Li20 1 0.62500000 0.75000000 0.37500000 1 - Li Li21 1 0.87500000 0.25000000 0.12500000 1 - Li Li22 1 0.25000000 0.12500000 0.87500000 1 - Li Li23 1 0.75000000 0.37500000 0.62500000 1 - V V24 1 0.00000000 0.00000000 0.00000000 1 - V V25 1 0.50000000 0.00000000 0.00000000 1 - V V26 1 0.00000000 0.50000000 0.00000000 1 - V V27 1 0.00000000 0.00000000 0.50000000 1 - V V28 1 0.50000000 0.50000000 0.00000000 1 - V V29 1 0.00000000 0.50000000 0.50000000 1 - V V30 1 0.50000000 0.00000000 0.50000000 1 - V V31 1 0.50000000 0.50000000 0.50000000 1 - F F32 1 0.07764900 0.88282700 0.40224100 1 - F F33 1 0.69482200 0.67540700 0.07764900 1 - F F34 1 0.80517800 0.88282700 0.98058500 1 - F F35 1 0.98058500 0.80517800 0.88282700 1 - F F36 1 0.82459300 0.51941500 0.40224100 1 - F F37 1 0.69482200 0.51941500 0.61717300 1 - F F38 1 0.61717300 0.42235100 0.09775900 1 - F F39 1 0.61717300 0.69482200 0.51941500 1 - F F40 1 0.67540700 0.07764900 0.69482200 1 - F F41 1 0.51941500 0.61717300 0.69482200 1 - F F42 1 0.09775900 0.98058500 0.67540700 1 - F F43 1 0.88282700 0.40224100 0.07764900 1 - F F44 1 0.42235100 0.09775900 0.61717300 1 - F F45 1 0.40224100 0.82459300 0.51941500 1 - F F46 1 0.07764900 0.69482200 0.67540700 1 - F F47 1 0.09775900 0.61717300 0.42235100 1 - F F48 1 0.51941500 0.40224100 0.82459300 1 - F F49 1 0.42235100 0.82459300 0.80517800 1 - F F50 1 0.98058500 0.67540700 0.09775900 1 - F F51 1 0.82459300 0.80517800 0.42235100 1 - F F52 1 0.11717300 0.01941500 0.19482200 1 - F F53 1 0.59775900 0.92235100 0.11717300 1 - F F54 1 0.19482200 0.57764900 0.17540700 1 - F F55 1 0.17540700 0.19482200 0.57764900 1 - F F56 1 0.32459300 0.90224100 0.01941500 1 - F F57 1 0.01941500 0.32459300 0.90224100 1 - F F58 1 0.92235100 0.11717300 0.59775900 1 - F F59 1 0.48058500 0.59775900 0.17540700 1 - F F60 1 0.90224100 0.38282700 0.57764900 1 - F F61 1 0.92235100 0.30517800 0.32459300 1 - F F62 1 0.59775900 0.17540700 0.48058500 1 - F F63 1 0.57764900 0.90224100 0.38282700 1 - F F64 1 0.30517800 0.32459300 0.92235100 1 - F F65 1 0.19482200 0.11717300 0.01941500 1 - F F66 1 0.01941500 0.19482200 0.11717300 1 - F F67 1 0.17540700 0.48058500 0.59775900 1 - F F68 1 0.30517800 0.48058500 0.38282700 1 - F F69 1 0.38282700 0.57764900 0.90224100 1 - F F70 1 0.38282700 0.30517800 0.48058500 1 - F F71 1 0.32459300 0.92235100 0.30517800 1 - F F72 1 0.48058500 0.38282700 0.30517800 1 - F F73 1 0.90224100 0.01941500 0.32459300 1 - F F74 1 0.11717300 0.59775900 0.92235100 1 - F F75 1 0.57764900 0.17540700 0.19482200 1 - F F76 1 0.88282700 0.98058500 0.80517800 1 - F F77 1 0.40224100 0.07764900 0.88282700 1 - F F78 1 0.80517800 0.42235100 0.82459300 1 - F F79 1 0.67540700 0.09775900 0.98058500 1 -" -Al2Fe3(SiO4)3,mp-6172,Ia-3d,"[71896, 96735, 96736, 80672, 89677, 80671, 28031, 28030, 77427, 96737, 96738, 80670, 71891, 52395, 80673, 80674]",0.024439558500001013,"{'tags': ['Triiron dialuminotrisilicate', 'Triiron dialuminium tris(silicate)', 'Tricalcium dialuminium tris(silicate)', 'Almandine', 'Dialuminium triiron silicate', 'Triiron dialuminum tris(silicate)']}","Full Formula (Al8 Fe12 Si12 O48) -Reduced Formula: Al2Fe3(SiO4)3 -abc : 10.103063 10.103063 10.103063 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0 0.001 - 1 Al 0.5 0 0 0.001 - 2 Al 0.5 0.5 0 0.001 - 3 Al 0 0.5 0.5 0.001 - 4 Al 0 0 0.5 0.001 - 5 Al 0.5 0.5 0.5 0.001 - 6 Al 0 0.5 0 0.001 - 7 Al 0.5 0 0.5 0.001 - 8 Fe 0.75 0.625 0.875 3.782 - 9 Fe 0.25 0.875 0.625 3.782 - 10 Fe 0.625 0.25 0.875 3.782 - 11 Fe 0.875 0.75 0.625 3.782 - 12 Fe 0.875 0.625 0.25 3.782 - 13 Fe 0.625 0.875 0.75 3.782 - 14 Fe 0.25 0.375 0.125 3.782 - 15 Fe 0.75 0.125 0.375 3.782 - 16 Fe 0.375 0.75 0.125 3.782 - 17 Fe 0.125 0.25 0.375 3.782 - 18 Fe 0.125 0.375 0.75 3.782 - 19 Fe 0.375 0.125 0.25 3.782 - 20 Si 0.125 0.75 0.875 0.004 - 21 Si 0.75 0.875 0.125 0.004 - 22 Si 0.25 0.625 0.375 0.004 - 23 Si 0.625 0.75 0.375 0.004 - 24 Si 0.875 0.125 0.75 0.004 - 25 Si 0.375 0.25 0.625 0.004 - 26 Si 0.375 0.625 0.75 0.004 - 27 Si 0.25 0.125 0.875 0.004 - 28 Si 0.625 0.375 0.25 0.004 - 29 Si 0.125 0.875 0.25 0.004 - 30 Si 0.75 0.375 0.625 0.004 - 31 Si 0.875 0.25 0.125 0.004 - 32 O 0.58174 0.895301 0.381319 0.033 - 33 O 0.381319 0.58174 0.895301 0.033 - 34 O 0.299579 0.313561 0.91826 0.033 - 35 O 0.486018 0.604699 0.186439 0.033 - 36 O 0.313561 0.895301 0.013982 0.033 - 37 O 0.118681 0.013982 0.200421 0.033 - 38 O 0.381319 0.299579 0.486018 0.033 - 39 O 0.895301 0.381319 0.58174 0.033 - 40 O 0.186439 0.200421 0.58174 0.033 - 41 O 0.486018 0.381319 0.299579 0.033 - 42 O 0.895301 0.013982 0.313561 0.033 - 43 O 0.604699 0.91826 0.118681 0.033 - 44 O 0.91826 0.118681 0.604699 0.033 - 45 O 0.299579 0.486018 0.381319 0.033 - 46 O 0.58174 0.186439 0.200421 0.033 - 47 O 0.200421 0.58174 0.186439 0.033 - 48 O 0.013982 0.313561 0.895301 0.033 - 49 O 0.91826 0.299579 0.313561 0.033 - 50 O 0.013982 0.200421 0.118681 0.033 - 51 O 0.813561 0.799579 0.41826 0.033 - 52 O 0.186439 0.486018 0.604699 0.033 - 53 O 0.604699 0.186439 0.486018 0.033 - 54 O 0.200421 0.118681 0.013982 0.033 - 55 O 0.118681 0.604699 0.91826 0.033 - 56 O 0.41826 0.104699 0.618681 0.033 - 57 O 0.618681 0.41826 0.104699 0.033 - 58 O 0.700421 0.686439 0.08174 0.033 - 59 O 0.513982 0.395301 0.813561 0.033 - 60 O 0.686439 0.104699 0.986018 0.033 - 61 O 0.881319 0.986018 0.799579 0.033 - 62 O 0.618681 0.700421 0.513982 0.033 - 63 O 0.104699 0.618681 0.41826 0.033 - 64 O 0.881319 0.395301 0.08174 0.033 - 65 O 0.799579 0.881319 0.986018 0.033 - 66 O 0.395301 0.813561 0.513982 0.033 - 67 O 0.686439 0.08174 0.700421 0.033 - 68 O 0.813561 0.513982 0.395301 0.033 - 69 O 0.986018 0.799579 0.881319 0.033 - 70 O 0.08174 0.700421 0.686439 0.033 - 71 O 0.986018 0.686439 0.104699 0.033 - 72 O 0.799579 0.41826 0.813561 0.033 - 73 O 0.41826 0.813561 0.799579 0.033 - 74 O 0.700421 0.513982 0.618681 0.033 - 75 O 0.08174 0.881319 0.395301 0.033 - 76 O 0.395301 0.08174 0.881319 0.033 - 77 O 0.104699 0.986018 0.686439 0.033 - 78 O 0.513982 0.618681 0.700421 0.033 - 79 O 0.313561 0.91826 0.299579 0.033","# generated using pymatgen -data_Al2Fe3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.10306275 -_cell_length_b 10.10306275 -_cell_length_c 10.10306275 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Fe3(SiO4)3 -_chemical_formula_sum 'Al8 Fe12 Si12 O48' -_cell_volume 793.84782787 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.00000000 1 - Al Al1 1 0.50000000 0.00000000 0.00000000 1 - Al Al2 1 0.50000000 0.50000000 0.00000000 1 - Al Al3 1 0.00000000 0.50000000 0.50000000 1 - Al Al4 1 0.00000000 0.00000000 0.50000000 1 - Al Al5 1 0.50000000 0.50000000 0.50000000 1 - Al Al6 1 0.00000000 0.50000000 0.00000000 1 - Al Al7 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe8 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe9 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe10 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe11 1 0.87500000 0.75000000 0.62500000 1 - Fe Fe12 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe13 1 0.62500000 0.87500000 0.75000000 1 - Fe Fe14 1 0.25000000 0.37500000 0.12500000 1 - Fe Fe15 1 0.75000000 0.12500000 0.37500000 1 - Fe Fe16 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe17 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe18 1 0.12500000 0.37500000 0.75000000 1 - Fe Fe19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.87500000 0.12500000 0.75000000 1 - Si Si25 1 0.37500000 0.25000000 0.62500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.25000000 0.12500000 0.87500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.12500000 0.87500000 0.25000000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.87500000 0.25000000 0.12500000 1 - O O32 1 0.58174000 0.89530100 0.38131900 1 - O O33 1 0.38131900 0.58174000 0.89530100 1 - O O34 1 0.29957900 0.31356100 0.91826000 1 - O O35 1 0.48601800 0.60469900 0.18643900 1 - O O36 1 0.31356100 0.89530100 0.01398200 1 - O O37 1 0.11868100 0.01398200 0.20042100 1 - O O38 1 0.38131900 0.29957900 0.48601800 1 - O O39 1 0.89530100 0.38131900 0.58174000 1 - O O40 1 0.18643900 0.20042100 0.58174000 1 - O O41 1 0.48601800 0.38131900 0.29957900 1 - O O42 1 0.89530100 0.01398200 0.31356100 1 - O O43 1 0.60469900 0.91826000 0.11868100 1 - O O44 1 0.91826000 0.11868100 0.60469900 1 - O O45 1 0.29957900 0.48601800 0.38131900 1 - O O46 1 0.58174000 0.18643900 0.20042100 1 - O O47 1 0.20042100 0.58174000 0.18643900 1 - O O48 1 0.01398200 0.31356100 0.89530100 1 - O O49 1 0.91826000 0.29957900 0.31356100 1 - O O50 1 0.01398200 0.20042100 0.11868100 1 - O O51 1 0.81356100 0.79957900 0.41826000 1 - O O52 1 0.18643900 0.48601800 0.60469900 1 - O O53 1 0.60469900 0.18643900 0.48601800 1 - O O54 1 0.20042100 0.11868100 0.01398200 1 - O O55 1 0.11868100 0.60469900 0.91826000 1 - O O56 1 0.41826000 0.10469900 0.61868100 1 - O O57 1 0.61868100 0.41826000 0.10469900 1 - O O58 1 0.70042100 0.68643900 0.08174000 1 - O O59 1 0.51398200 0.39530100 0.81356100 1 - O O60 1 0.68643900 0.10469900 0.98601800 1 - O O61 1 0.88131900 0.98601800 0.79957900 1 - O O62 1 0.61868100 0.70042100 0.51398200 1 - O O63 1 0.10469900 0.61868100 0.41826000 1 - O O64 1 0.88131900 0.39530100 0.08174000 1 - O O65 1 0.79957900 0.88131900 0.98601800 1 - O O66 1 0.39530100 0.81356100 0.51398200 1 - O O67 1 0.68643900 0.08174000 0.70042100 1 - O O68 1 0.81356100 0.51398200 0.39530100 1 - O O69 1 0.98601800 0.79957900 0.88131900 1 - O O70 1 0.08174000 0.70042100 0.68643900 1 - O O71 1 0.98601800 0.68643900 0.10469900 1 - O O72 1 0.79957900 0.41826000 0.81356100 1 - O O73 1 0.41826000 0.81356100 0.79957900 1 - O O74 1 0.70042100 0.51398200 0.61868100 1 - O O75 1 0.08174000 0.88131900 0.39530100 1 - O O76 1 0.39530100 0.08174000 0.88131900 1 - O O77 1 0.10469900 0.98601800 0.68643900 1 - O O78 1 0.51398200 0.61868100 0.70042100 1 - O O79 1 0.31356100 0.91826000 0.29957900 1 -" -Al2Co3(SiO4)3,mp-6186,Ia-3d,"[158161, 27383, 39193, 158162, 158166, 158159, 158164, 80825, 158165, 81358, 158163, 158160, 158158, 158157]",0.04807070012500958,"{'tags': ['Tricobalt dialuminium tris(silicate) - beta', 'Tricobalt dialuminium silicate', 'Tricobalt dialuminium tris(silicate)', 'Garnet-(Co)', 'Garnet-(Co,Al,Si)', 'Unnamed_Garnet', 'High pressure experimental phase']}","Full Formula (Al8 Co12 Si12 O48) -Reduced Formula: Al2Co3(SiO4)3 -abc : 10.018367 10.018367 10.018367 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0.5 0.5 0 - 1 Al 0 0.5 0 0 - 2 Al 0.5 0.5 0.5 0 - 3 Al 0 0 0 0 - 4 Al 0.5 0.5 0 0 - 5 Al 0.5 0 0.5 0 - 6 Al 0 0 0.5 0 - 7 Al 0.5 0 0 0 - 8 Co 0.625 0.875 0.75 2.746 - 9 Co 0.75 0.125 0.375 2.746 - 10 Co 0.625 0.25 0.875 2.746 - 11 Co 0.125 0.25 0.375 2.746 - 12 Co 0.25 0.375 0.125 2.746 - 13 Co 0.875 0.75 0.625 2.746 - 14 Co 0.875 0.625 0.25 2.746 - 15 Co 0.125 0.375 0.75 2.746 - 16 Co 0.375 0.125 0.25 2.746 - 17 Co 0.25 0.875 0.625 2.746 - 18 Co 0.75 0.625 0.875 2.746 - 19 Co 0.375 0.75 0.125 2.746 - 20 Si 0.875 0.25 0.125 0.004 - 21 Si 0.75 0.875 0.125 0.004 - 22 Si 0.125 0.75 0.875 0.004 - 23 Si 0.375 0.625 0.75 0.004 - 24 Si 0.625 0.75 0.375 0.004 - 25 Si 0.625 0.375 0.25 0.004 - 26 Si 0.75 0.375 0.625 0.004 - 27 Si 0.25 0.625 0.375 0.004 - 28 Si 0.25 0.125 0.875 0.004 - 29 Si 0.375 0.25 0.625 0.004 - 30 Si 0.125 0.875 0.25 0.004 - 31 Si 0.875 0.125 0.75 0.004 - 32 O 0.398334 0.084717 0.880697 0.049 - 33 O 0.584717 0.186382 0.20402 0.049 - 34 O 0.380697 0.584717 0.898334 0.049 - 35 O 0.601666 0.915283 0.119303 0.049 - 36 O 0.017637 0.20402 0.119303 0.049 - 37 O 0.415283 0.101666 0.619303 0.049 - 38 O 0.380697 0.29598 0.482363 0.049 - 39 O 0.119303 0.601666 0.915283 0.049 - 40 O 0.70402 0.686382 0.084717 0.049 - 41 O 0.686382 0.101666 0.982363 0.049 - 42 O 0.70402 0.517637 0.619303 0.049 - 43 O 0.601666 0.186382 0.482363 0.049 - 44 O 0.982363 0.79598 0.880697 0.049 - 45 O 0.186382 0.482363 0.601666 0.049 - 46 O 0.101666 0.982363 0.686382 0.049 - 47 O 0.915283 0.119303 0.601666 0.049 - 48 O 0.686382 0.084717 0.70402 0.049 - 49 O 0.813618 0.79598 0.415283 0.049 - 50 O 0.619303 0.70402 0.517637 0.049 - 51 O 0.982363 0.686382 0.101666 0.049 - 52 O 0.880697 0.982363 0.79598 0.049 - 53 O 0.880697 0.398334 0.084717 0.049 - 54 O 0.619303 0.415283 0.101666 0.049 - 55 O 0.017637 0.313618 0.898334 0.049 - 56 O 0.79598 0.415283 0.813618 0.049 - 57 O 0.482363 0.380697 0.29598 0.049 - 58 O 0.313618 0.898334 0.017637 0.049 - 59 O 0.084717 0.70402 0.686382 0.049 - 60 O 0.084717 0.880697 0.398334 0.049 - 61 O 0.517637 0.619303 0.70402 0.049 - 62 O 0.20402 0.584717 0.186382 0.049 - 63 O 0.398334 0.813618 0.517637 0.049 - 64 O 0.186382 0.20402 0.584717 0.049 - 65 O 0.813618 0.517637 0.398334 0.049 - 66 O 0.79598 0.880697 0.982363 0.049 - 67 O 0.20402 0.119303 0.017637 0.049 - 68 O 0.313618 0.915283 0.29598 0.049 - 69 O 0.482363 0.601666 0.186382 0.049 - 70 O 0.119303 0.017637 0.20402 0.049 - 71 O 0.584717 0.898334 0.380697 0.049 - 72 O 0.898334 0.017637 0.313618 0.049 - 73 O 0.898334 0.380697 0.584717 0.049 - 74 O 0.415283 0.813618 0.79598 0.049 - 75 O 0.29598 0.313618 0.915283 0.049 - 76 O 0.101666 0.619303 0.415283 0.049 - 77 O 0.915283 0.29598 0.313618 0.049 - 78 O 0.517637 0.398334 0.813618 0.049 - 79 O 0.29598 0.482363 0.380697 0.049","# generated using pymatgen -data_Al2Co3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.01836720 -_cell_length_b 10.01836720 -_cell_length_c 10.01836720 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Co3(SiO4)3 -_chemical_formula_sum 'Al8 Co12 Si12 O48' -_cell_volume 774.04987779 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.50000000 0.50000000 1 - Al Al1 1 0.00000000 0.50000000 0.00000000 1 - Al Al2 1 0.50000000 0.50000000 0.50000000 1 - Al Al3 1 0.00000000 0.00000000 0.00000000 1 - Al Al4 1 0.50000000 0.50000000 0.00000000 1 - Al Al5 1 0.50000000 0.00000000 0.50000000 1 - Al Al6 1 0.00000000 0.00000000 0.50000000 1 - Al Al7 1 0.50000000 0.00000000 0.00000000 1 - Co Co8 1 0.62500000 0.87500000 0.75000000 1 - Co Co9 1 0.75000000 0.12500000 0.37500000 1 - Co Co10 1 0.62500000 0.25000000 0.87500000 1 - Co Co11 1 0.12500000 0.25000000 0.37500000 1 - Co Co12 1 0.25000000 0.37500000 0.12500000 1 - Co Co13 1 0.87500000 0.75000000 0.62500000 1 - Co Co14 1 0.87500000 0.62500000 0.25000000 1 - Co Co15 1 0.12500000 0.37500000 0.75000000 1 - Co Co16 1 0.37500000 0.12500000 0.25000000 1 - Co Co17 1 0.25000000 0.87500000 0.62500000 1 - Co Co18 1 0.75000000 0.62500000 0.87500000 1 - Co Co19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.87500000 0.25000000 0.12500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.12500000 0.75000000 0.87500000 1 - Si Si23 1 0.37500000 0.62500000 0.75000000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.62500000 0.37500000 0.25000000 1 - Si Si26 1 0.75000000 0.37500000 0.62500000 1 - Si Si27 1 0.25000000 0.62500000 0.37500000 1 - Si Si28 1 0.25000000 0.12500000 0.87500000 1 - Si Si29 1 0.37500000 0.25000000 0.62500000 1 - Si Si30 1 0.12500000 0.87500000 0.25000000 1 - Si Si31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.39833400 0.08471700 0.88069700 1 - O O33 1 0.58471700 0.18638200 0.20402000 1 - O O34 1 0.38069700 0.58471700 0.89833400 1 - O O35 1 0.60166600 0.91528300 0.11930300 1 - O O36 1 0.01763700 0.20402000 0.11930300 1 - O O37 1 0.41528300 0.10166600 0.61930300 1 - O O38 1 0.38069700 0.29598000 0.48236300 1 - O O39 1 0.11930300 0.60166600 0.91528300 1 - O O40 1 0.70402000 0.68638200 0.08471700 1 - O O41 1 0.68638200 0.10166600 0.98236300 1 - O O42 1 0.70402000 0.51763700 0.61930300 1 - O O43 1 0.60166600 0.18638200 0.48236300 1 - O O44 1 0.98236300 0.79598000 0.88069700 1 - O O45 1 0.18638200 0.48236300 0.60166600 1 - O O46 1 0.10166600 0.98236300 0.68638200 1 - O O47 1 0.91528300 0.11930300 0.60166600 1 - O O48 1 0.68638200 0.08471700 0.70402000 1 - O O49 1 0.81361800 0.79598000 0.41528300 1 - O O50 1 0.61930300 0.70402000 0.51763700 1 - O O51 1 0.98236300 0.68638200 0.10166600 1 - O O52 1 0.88069700 0.98236300 0.79598000 1 - O O53 1 0.88069700 0.39833400 0.08471700 1 - O O54 1 0.61930300 0.41528300 0.10166600 1 - O O55 1 0.01763700 0.31361800 0.89833400 1 - O O56 1 0.79598000 0.41528300 0.81361800 1 - O O57 1 0.48236300 0.38069700 0.29598000 1 - O O58 1 0.31361800 0.89833400 0.01763700 1 - O O59 1 0.08471700 0.70402000 0.68638200 1 - O O60 1 0.08471700 0.88069700 0.39833400 1 - O O61 1 0.51763700 0.61930300 0.70402000 1 - O O62 1 0.20402000 0.58471700 0.18638200 1 - O O63 1 0.39833400 0.81361800 0.51763700 1 - O O64 1 0.18638200 0.20402000 0.58471700 1 - O O65 1 0.81361800 0.51763700 0.39833400 1 - O O66 1 0.79598000 0.88069700 0.98236300 1 - O O67 1 0.20402000 0.11930300 0.01763700 1 - O O68 1 0.31361800 0.91528300 0.29598000 1 - O O69 1 0.48236300 0.60166600 0.18638200 1 - O O70 1 0.11930300 0.01763700 0.20402000 1 - O O71 1 0.58471700 0.89833400 0.38069700 1 - O O72 1 0.89833400 0.01763700 0.31361800 1 - O O73 1 0.89833400 0.38069700 0.58471700 1 - O O74 1 0.41528300 0.81361800 0.79598000 1 - O O75 1 0.29598000 0.31361800 0.91528300 1 - O O76 1 0.10166600 0.61930300 0.41528300 1 - O O77 1 0.91528300 0.29598000 0.31361800 1 - O O78 1 0.51763700 0.39833400 0.81361800 1 - O O79 1 0.29598000 0.48236300 0.38069700 1 -" -Na3Sc2V3O12,mp-6213,Ia-3d,"[86306, 6110]",0.0,"{'tags': ['Trisodium discandium trivanadate', 'Unnamed_Garnet', 'Garnet-(Na,Sc,V)', 'Trisodium discandium tris(vanadate)']}","Full Formula (Na12 Sc8 V12 O48) -Reduced Formula: Na3Sc2V3O12 -abc : 11.071004 11.071004 11.071004 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.375 0.125 0.25 -0 - 1 Na 0.75 0.125 0.375 -0 - 2 Na 0.25 0.375 0.125 -0 - 3 Na 0.125 0.25 0.375 -0 - 4 Na 0.375 0.75 0.125 -0 - 5 Na 0.125 0.375 0.75 -0 - 6 Na 0.625 0.875 0.75 -0 - 7 Na 0.25 0.875 0.625 -0 - 8 Na 0.75 0.625 0.875 -0 - 9 Na 0.875 0.75 0.625 -0 - 10 Na 0.625 0.25 0.875 -0 - 11 Na 0.875 0.625 0.25 -0 - 12 Sc 0 0 0 -0 - 13 Sc 0.5 0 0 -0 - 14 Sc 0 0.5 0 -0 - 15 Sc 0 0 0.5 -0 - 16 Sc 0.5 0.5 0 -0 - 17 Sc 0 0.5 0.5 -0 - 18 Sc 0.5 0 0.5 -0 - 19 Sc 0.5 0.5 0.5 -0 - 20 V 0.625 0.375 0.25 -0 - 21 V 0.75 0.375 0.625 -0 - 22 V 0.25 0.125 0.875 -0 - 23 V 0.875 0.25 0.125 -0 - 24 V 0.625 0.75 0.375 -0 - 25 V 0.375 0.625 0.75 -0 - 26 V 0.125 0.75 0.875 -0 - 27 V 0.75 0.875 0.125 -0 - 28 V 0.375 0.25 0.625 -0 - 29 V 0.25 0.625 0.375 -0 - 30 V 0.875 0.125 0.75 -0 - 31 V 0.125 0.875 0.25 -0 - 32 O 0.412084 0.806079 0.799157 0 - 33 O 0.887073 0.393995 0.087916 0 - 34 O 0.106005 0.993077 0.693921 0 - 35 O 0.506923 0.612927 0.700843 0 - 36 O 0.693921 0.087916 0.700843 0 - 37 O 0.612927 0.700843 0.506923 0 - 38 O 0.612927 0.412084 0.106005 0 - 39 O 0.700843 0.506923 0.612927 0 - 40 O 0.806079 0.506923 0.393995 0 - 41 O 0.993077 0.799157 0.887073 0 - 42 O 0.799157 0.887073 0.993077 0 - 43 O 0.700843 0.693921 0.087916 0 - 44 O 0.412084 0.106005 0.612927 0 - 45 O 0.393995 0.806079 0.506923 0 - 46 O 0.087916 0.700843 0.693921 0 - 47 O 0.106005 0.612927 0.412084 0 - 48 O 0.506923 0.393995 0.806079 0 - 49 O 0.087916 0.887073 0.393995 0 - 50 O 0.993077 0.693921 0.106005 0 - 51 O 0.193921 0.493077 0.606005 0 - 52 O 0.693921 0.106005 0.993077 0 - 53 O 0.799157 0.412084 0.806079 0 - 54 O 0.393995 0.087916 0.887073 0 - 55 O 0.887073 0.993077 0.799157 0 - 56 O 0.587916 0.193921 0.200843 0 - 57 O 0.112927 0.606005 0.912084 0 - 58 O 0.893995 0.006923 0.306079 0 - 59 O 0.493077 0.387073 0.299157 0 - 60 O 0.306079 0.912084 0.299157 0 - 61 O 0.387073 0.299157 0.493077 0 - 62 O 0.387073 0.587916 0.893995 0 - 63 O 0.299157 0.493077 0.387073 0 - 64 O 0.112927 0.006923 0.200843 0 - 65 O 0.606005 0.912084 0.112927 0 - 66 O 0.200843 0.587916 0.193921 0 - 67 O 0.193921 0.200843 0.587916 0 - 68 O 0.306079 0.893995 0.006923 0 - 69 O 0.006923 0.306079 0.893995 0 - 70 O 0.912084 0.112927 0.606005 0 - 71 O 0.493077 0.606005 0.193921 0 - 72 O 0.893995 0.387073 0.587916 0 - 73 O 0.912084 0.299157 0.306079 0 - 74 O 0.606005 0.193921 0.493077 0 - 75 O 0.587916 0.893995 0.387073 0 - 76 O 0.299157 0.306079 0.912084 0 - 77 O 0.200843 0.112927 0.006923 0 - 78 O 0.006923 0.200843 0.112927 0 - 79 O 0.806079 0.799157 0.412084 0","# generated using pymatgen -data_Na3Sc2V3O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.07100376 -_cell_length_b 11.07100376 -_cell_length_c 11.07100376 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Sc2V3O12 -_chemical_formula_sum 'Na12 Sc8 V12 O48' -_cell_volume 1044.57374028 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.37500000 0.12500000 0.25000000 1 - Na Na1 1 0.75000000 0.12500000 0.37500000 1 - Na Na2 1 0.25000000 0.37500000 0.12500000 1 - Na Na3 1 0.12500000 0.25000000 0.37500000 1 - Na Na4 1 0.37500000 0.75000000 0.12500000 1 - Na Na5 1 0.12500000 0.37500000 0.75000000 1 - Na Na6 1 0.62500000 0.87500000 0.75000000 1 - Na Na7 1 0.25000000 0.87500000 0.62500000 1 - Na Na8 1 0.75000000 0.62500000 0.87500000 1 - Na Na9 1 0.87500000 0.75000000 0.62500000 1 - Na Na10 1 0.62500000 0.25000000 0.87500000 1 - Na Na11 1 0.87500000 0.62500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.00000000 1 - Sc Sc15 1 0.00000000 0.00000000 0.50000000 1 - Sc Sc16 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc17 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc18 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc19 1 0.50000000 0.50000000 0.50000000 1 - V V20 1 0.62500000 0.37500000 0.25000000 1 - V V21 1 0.75000000 0.37500000 0.62500000 1 - V V22 1 0.25000000 0.12500000 0.87500000 1 - V V23 1 0.87500000 0.25000000 0.12500000 1 - V V24 1 0.62500000 0.75000000 0.37500000 1 - V V25 1 0.37500000 0.62500000 0.75000000 1 - V V26 1 0.12500000 0.75000000 0.87500000 1 - V V27 1 0.75000000 0.87500000 0.12500000 1 - V V28 1 0.37500000 0.25000000 0.62500000 1 - V V29 1 0.25000000 0.62500000 0.37500000 1 - V V30 1 0.87500000 0.12500000 0.75000000 1 - V V31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.41208400 0.80607900 0.79915700 1 - O O33 1 0.88707300 0.39399500 0.08791600 1 - O O34 1 0.10600500 0.99307700 0.69392100 1 - O O35 1 0.50692300 0.61292700 0.70084300 1 - O O36 1 0.69392100 0.08791600 0.70084300 1 - O O37 1 0.61292700 0.70084300 0.50692300 1 - O O38 1 0.61292700 0.41208400 0.10600500 1 - O O39 1 0.70084300 0.50692300 0.61292700 1 - O O40 1 0.80607900 0.50692300 0.39399500 1 - O O41 1 0.99307700 0.79915700 0.88707300 1 - O O42 1 0.79915700 0.88707300 0.99307700 1 - O O43 1 0.70084300 0.69392100 0.08791600 1 - O O44 1 0.41208400 0.10600500 0.61292700 1 - O O45 1 0.39399500 0.80607900 0.50692300 1 - O O46 1 0.08791600 0.70084300 0.69392100 1 - O O47 1 0.10600500 0.61292700 0.41208400 1 - O O48 1 0.50692300 0.39399500 0.80607900 1 - O O49 1 0.08791600 0.88707300 0.39399500 1 - O O50 1 0.99307700 0.69392100 0.10600500 1 - O O51 1 0.19392100 0.49307700 0.60600500 1 - O O52 1 0.69392100 0.10600500 0.99307700 1 - O O53 1 0.79915700 0.41208400 0.80607900 1 - O O54 1 0.39399500 0.08791600 0.88707300 1 - O O55 1 0.88707300 0.99307700 0.79915700 1 - O O56 1 0.58791600 0.19392100 0.20084300 1 - O O57 1 0.11292700 0.60600500 0.91208400 1 - O O58 1 0.89399500 0.00692300 0.30607900 1 - O O59 1 0.49307700 0.38707300 0.29915700 1 - O O60 1 0.30607900 0.91208400 0.29915700 1 - O O61 1 0.38707300 0.29915700 0.49307700 1 - O O62 1 0.38707300 0.58791600 0.89399500 1 - O O63 1 0.29915700 0.49307700 0.38707300 1 - O O64 1 0.11292700 0.00692300 0.20084300 1 - O O65 1 0.60600500 0.91208400 0.11292700 1 - O O66 1 0.20084300 0.58791600 0.19392100 1 - O O67 1 0.19392100 0.20084300 0.58791600 1 - O O68 1 0.30607900 0.89399500 0.00692300 1 - O O69 1 0.00692300 0.30607900 0.89399500 1 - O O70 1 0.91208400 0.11292700 0.60600500 1 - O O71 1 0.49307700 0.60600500 0.19392100 1 - O O72 1 0.89399500 0.38707300 0.58791600 1 - O O73 1 0.91208400 0.29915700 0.30607900 1 - O O74 1 0.60600500 0.19392100 0.49307700 1 - O O75 1 0.58791600 0.89399500 0.38707300 1 - O O76 1 0.29915700 0.30607900 0.91208400 1 - O O77 1 0.20084300 0.11292700 0.00692300 1 - O O78 1 0.00692300 0.20084300 0.11292700 1 - O O79 1 0.80607900 0.79915700 0.41208400 1 -" -Mn3Fe2(SiO4)3,mp-6239,Ia-3d,"[27381, 77433]",0.03304967774998424,"{'tags': ['Calderite', 'Trimanganese diiron(III) tris(silicate)']}","Full Formula (Mn12 Fe8 Si12 O48) -Reduced Formula: Mn3Fe2(SiO4)3 -abc : 10.362664 10.362664 10.362664 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.875 0.625 0.25 4.676 - 1 Mn 0.625 0.875 0.75 4.676 - 2 Mn 0.25 0.875 0.625 4.676 - 3 Mn 0.75 0.625 0.875 4.676 - 4 Mn 0.625 0.25 0.875 4.676 - 5 Mn 0.125 0.25 0.375 4.676 - 6 Mn 0.125 0.375 0.75 4.676 - 7 Mn 0.375 0.125 0.25 4.676 - 8 Mn 0.75 0.125 0.375 4.676 - 9 Mn 0.25 0.375 0.125 4.676 - 10 Mn 0.875 0.75 0.625 4.676 - 11 Mn 0.375 0.75 0.125 4.676 - 12 Fe 0.5 0 0.5 4.39 - 13 Fe 0 0.5 0 4.39 - 14 Fe 0.5 0.5 0.5 4.39 - 15 Fe 0 0 0 4.39 - 16 Fe 0 0.5 0.5 4.39 - 17 Fe 0.5 0.5 0 4.39 - 18 Fe 0.5 0 0 4.39 - 19 Fe 0 0 0.5 4.39 - 20 Si 0.125 0.75 0.875 0.022 - 21 Si 0.25 0.625 0.375 0.022 - 22 Si 0.625 0.75 0.375 0.022 - 23 Si 0.875 0.125 0.75 0.022 - 24 Si 0.375 0.25 0.625 0.022 - 25 Si 0.375 0.625 0.75 0.022 - 26 Si 0.625 0.375 0.25 0.022 - 27 Si 0.25 0.125 0.875 0.022 - 28 Si 0.125 0.875 0.25 0.022 - 29 Si 0.75 0.375 0.625 0.022 - 30 Si 0.875 0.25 0.125 0.022 - 31 Si 0.75 0.875 0.125 0.022 - 32 O 0.879368 0.394762 0.087859 0.107 - 33 O 0.791509 0.879368 0.984606 0.107 - 34 O 0.394762 0.806903 0.515394 0.107 - 35 O 0.693097 0.087859 0.708491 0.107 - 36 O 0.806903 0.515394 0.394762 0.107 - 37 O 0.984606 0.791509 0.879368 0.107 - 38 O 0.087859 0.708491 0.693097 0.107 - 39 O 0.984606 0.693097 0.105238 0.107 - 40 O 0.791509 0.412141 0.806903 0.107 - 41 O 0.412141 0.806903 0.791509 0.107 - 42 O 0.708491 0.515394 0.620632 0.107 - 43 O 0.087859 0.879368 0.394762 0.107 - 44 O 0.394762 0.087859 0.879368 0.107 - 45 O 0.105238 0.984606 0.693097 0.107 - 46 O 0.515394 0.620632 0.708491 0.107 - 47 O 0.806903 0.791509 0.412141 0.107 - 48 O 0.105238 0.620632 0.412141 0.107 - 49 O 0.620632 0.708491 0.515394 0.107 - 50 O 0.879368 0.984606 0.791509 0.107 - 51 O 0.693097 0.105238 0.984606 0.107 - 52 O 0.587859 0.894762 0.379368 0.107 - 53 O 0.708491 0.693097 0.087859 0.107 - 54 O 0.620632 0.412141 0.105238 0.107 - 55 O 0.412141 0.105238 0.620632 0.107 - 56 O 0.120632 0.605238 0.912141 0.107 - 57 O 0.208491 0.120632 0.015394 0.107 - 58 O 0.605238 0.193097 0.484606 0.107 - 59 O 0.306903 0.912141 0.291509 0.107 - 60 O 0.193097 0.484606 0.605238 0.107 - 61 O 0.015394 0.208491 0.120632 0.107 - 62 O 0.912141 0.291509 0.306903 0.107 - 63 O 0.015394 0.306903 0.894762 0.107 - 64 O 0.208491 0.587859 0.193097 0.107 - 65 O 0.587859 0.193097 0.208491 0.107 - 66 O 0.291509 0.484606 0.379368 0.107 - 67 O 0.912141 0.120632 0.605238 0.107 - 68 O 0.605238 0.912141 0.120632 0.107 - 69 O 0.894762 0.015394 0.306903 0.107 - 70 O 0.484606 0.379368 0.291509 0.107 - 71 O 0.193097 0.208491 0.587859 0.107 - 72 O 0.894762 0.379368 0.587859 0.107 - 73 O 0.379368 0.291509 0.484606 0.107 - 74 O 0.120632 0.015394 0.208491 0.107 - 75 O 0.306903 0.894762 0.015394 0.107 - 76 O 0.484606 0.605238 0.193097 0.107 - 77 O 0.291509 0.306903 0.912141 0.107 - 78 O 0.379368 0.587859 0.894762 0.107 - 79 O 0.515394 0.394762 0.806903 0.107","# generated using pymatgen -data_Mn3Fe2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.36266426 -_cell_length_b 10.36266426 -_cell_length_c 10.36266426 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn3Fe2(SiO4)3 -_chemical_formula_sum 'Mn12 Fe8 Si12 O48' -_cell_volume 856.62824950 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn1 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn2 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn3 1 0.75000000 0.62500000 0.87500000 1 - Mn Mn4 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn5 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn6 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn7 1 0.37500000 0.12500000 0.25000000 1 - Mn Mn8 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn9 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn10 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn11 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe12 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe13 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe14 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe17 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.50000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.25000000 0.62500000 0.37500000 1 - Si Si22 1 0.62500000 0.75000000 0.37500000 1 - Si Si23 1 0.87500000 0.12500000 0.75000000 1 - Si Si24 1 0.37500000 0.25000000 0.62500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.62500000 0.37500000 0.25000000 1 - Si Si27 1 0.25000000 0.12500000 0.87500000 1 - Si Si28 1 0.12500000 0.87500000 0.25000000 1 - Si Si29 1 0.75000000 0.37500000 0.62500000 1 - Si Si30 1 0.87500000 0.25000000 0.12500000 1 - Si Si31 1 0.75000000 0.87500000 0.12500000 1 - O O32 1 0.87936800 0.39476200 0.08785900 1 - O O33 1 0.79150900 0.87936800 0.98460600 1 - O O34 1 0.39476200 0.80690300 0.51539400 1 - O O35 1 0.69309700 0.08785900 0.70849100 1 - O O36 1 0.80690300 0.51539400 0.39476200 1 - O O37 1 0.98460600 0.79150900 0.87936800 1 - O O38 1 0.08785900 0.70849100 0.69309700 1 - O O39 1 0.98460600 0.69309700 0.10523800 1 - O O40 1 0.79150900 0.41214100 0.80690300 1 - O O41 1 0.41214100 0.80690300 0.79150900 1 - O O42 1 0.70849100 0.51539400 0.62063200 1 - O O43 1 0.08785900 0.87936800 0.39476200 1 - O O44 1 0.39476200 0.08785900 0.87936800 1 - O O45 1 0.10523800 0.98460600 0.69309700 1 - O O46 1 0.51539400 0.62063200 0.70849100 1 - O O47 1 0.80690300 0.79150900 0.41214100 1 - O O48 1 0.10523800 0.62063200 0.41214100 1 - O O49 1 0.62063200 0.70849100 0.51539400 1 - O O50 1 0.87936800 0.98460600 0.79150900 1 - O O51 1 0.69309700 0.10523800 0.98460600 1 - O O52 1 0.58785900 0.89476200 0.37936800 1 - O O53 1 0.70849100 0.69309700 0.08785900 1 - O O54 1 0.62063200 0.41214100 0.10523800 1 - O O55 1 0.41214100 0.10523800 0.62063200 1 - O O56 1 0.12063200 0.60523800 0.91214100 1 - O O57 1 0.20849100 0.12063200 0.01539400 1 - O O58 1 0.60523800 0.19309700 0.48460600 1 - O O59 1 0.30690300 0.91214100 0.29150900 1 - O O60 1 0.19309700 0.48460600 0.60523800 1 - O O61 1 0.01539400 0.20849100 0.12063200 1 - O O62 1 0.91214100 0.29150900 0.30690300 1 - O O63 1 0.01539400 0.30690300 0.89476200 1 - O O64 1 0.20849100 0.58785900 0.19309700 1 - O O65 1 0.58785900 0.19309700 0.20849100 1 - O O66 1 0.29150900 0.48460600 0.37936800 1 - O O67 1 0.91214100 0.12063200 0.60523800 1 - O O68 1 0.60523800 0.91214100 0.12063200 1 - O O69 1 0.89476200 0.01539400 0.30690300 1 - O O70 1 0.48460600 0.37936800 0.29150900 1 - O O71 1 0.19309700 0.20849100 0.58785900 1 - O O72 1 0.89476200 0.37936800 0.58785900 1 - O O73 1 0.37936800 0.29150900 0.48460600 1 - O O74 1 0.12063200 0.01539400 0.20849100 1 - O O75 1 0.30690300 0.89476200 0.01539400 1 - O O76 1 0.48460600 0.60523800 0.19309700 1 - O O77 1 0.29150900 0.30690300 0.91214100 1 - O O78 1 0.37936800 0.58785900 0.89476200 1 - O O79 1 0.51539400 0.39476200 0.80690300 1 -" -Na3Li3Fe2F12,mp-6247,Ia-3d,"[17056, 60366]",0.0,"{'tags': ['Trisodium trilithium diiron dodecafluoride', 'Trisodium trilithium dodecafluorodiferrate(III)']}","Full Formula (Na12 Li12 Fe8 F48) -Reduced Formula: Na3Li3Fe2F12 -abc : 10.896442 10.896442 10.896442 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.625 0.875 0.75 0.001 - 1 Na 0.875 0.625 0.25 0.001 - 2 Na 0.75 0.625 0.875 0.001 - 3 Na 0.875 0.75 0.625 0.001 - 4 Na 0.625 0.25 0.875 0.001 - 5 Na 0.25 0.875 0.625 0.001 - 6 Na 0.375 0.125 0.25 0.001 - 7 Na 0.125 0.375 0.75 0.001 - 8 Na 0.25 0.375 0.125 0.001 - 9 Na 0.125 0.25 0.375 0.001 - 10 Na 0.75 0.125 0.375 0.001 - 11 Na 0.375 0.75 0.125 0.001 - 12 Li 0.625 0.75 0.375 0.002 - 13 Li 0.75 0.875 0.125 0.002 - 14 Li 0.25 0.125 0.875 0.002 - 15 Li 0.375 0.625 0.75 0.002 - 16 Li 0.125 0.875 0.25 0.002 - 17 Li 0.875 0.25 0.125 0.002 - 18 Li 0.625 0.375 0.25 0.002 - 19 Li 0.875 0.125 0.75 0.002 - 20 Li 0.25 0.625 0.375 0.002 - 21 Li 0.375 0.25 0.625 0.002 - 22 Li 0.125 0.75 0.875 0.002 - 23 Li 0.75 0.375 0.625 0.002 - 24 Fe 0.5 0 0.5 4.466 - 25 Fe 0 0.5 0 4.466 - 26 Fe 0.5 0.5 0.5 4.466 - 27 Fe 0 0 0.5 4.466 - 28 Fe 0 0 0 4.466 - 29 Fe 0 0.5 0.5 4.466 - 30 Fe 0.5 0.5 0 4.466 - 31 Fe 0.5 0 0 4.466 - 32 F 0.518811 0.402792 0.825137 0.077 - 33 F 0.806326 0.422345 0.825137 0.077 - 34 F 0.518811 0.616019 0.693674 0.077 - 35 F 0.693674 0.518811 0.616019 0.077 - 36 F 0.077655 0.883981 0.402792 0.077 - 37 F 0.981189 0.806326 0.883981 0.077 - 38 F 0.077655 0.693674 0.674863 0.077 - 39 F 0.883981 0.981189 0.806326 0.077 - 40 F 0.097208 0.981189 0.674863 0.077 - 41 F 0.402792 0.077655 0.883981 0.077 - 42 F 0.422345 0.825137 0.806326 0.077 - 43 F 0.616019 0.693674 0.518811 0.077 - 44 F 0.402792 0.825137 0.518811 0.077 - 45 F 0.825137 0.806326 0.422345 0.077 - 46 F 0.674863 0.077655 0.693674 0.077 - 47 F 0.883981 0.402792 0.077655 0.077 - 48 F 0.422345 0.097208 0.616019 0.077 - 49 F 0.981189 0.674863 0.097208 0.077 - 50 F 0.806326 0.883981 0.981189 0.077 - 51 F 0.825137 0.518811 0.402792 0.077 - 52 F 0.325137 0.902792 0.018811 0.077 - 53 F 0.306326 0.325137 0.922345 0.077 - 54 F 0.902792 0.383981 0.577655 0.077 - 55 F 0.116019 0.018811 0.193674 0.077 - 56 F 0.383981 0.577655 0.902792 0.077 - 57 F 0.922345 0.306326 0.325137 0.077 - 58 F 0.018811 0.193674 0.116019 0.077 - 59 F 0.922345 0.116019 0.597208 0.077 - 60 F 0.306326 0.481189 0.383981 0.077 - 61 F 0.481189 0.383981 0.306326 0.077 - 62 F 0.193674 0.577655 0.174863 0.077 - 63 F 0.018811 0.325137 0.902792 0.077 - 64 F 0.902792 0.018811 0.325137 0.077 - 65 F 0.597208 0.922345 0.116019 0.077 - 66 F 0.577655 0.174863 0.193674 0.077 - 67 F 0.383981 0.306326 0.481189 0.077 - 68 F 0.597208 0.174863 0.481189 0.077 - 69 F 0.174863 0.193674 0.577655 0.077 - 70 F 0.325137 0.922345 0.306326 0.077 - 71 F 0.116019 0.597208 0.922345 0.077 - 72 F 0.577655 0.902792 0.383981 0.077 - 73 F 0.193674 0.116019 0.018811 0.077 - 74 F 0.174863 0.481189 0.597208 0.077 - 75 F 0.481189 0.597208 0.174863 0.077 - 76 F 0.674863 0.097208 0.981189 0.077 - 77 F 0.693674 0.674863 0.077655 0.077 - 78 F 0.097208 0.616019 0.422345 0.077 - 79 F 0.616019 0.422345 0.097208 0.077","# generated using pymatgen -data_Na3Li3Fe2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.89644248 -_cell_length_b 10.89644248 -_cell_length_c 10.89644248 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3Fe2F12 -_chemical_formula_sum 'Na12 Li12 Fe8 F48' -_cell_volume 995.93799588 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.62500000 0.87500000 0.75000000 1 - Na Na1 1 0.87500000 0.62500000 0.25000000 1 - Na Na2 1 0.75000000 0.62500000 0.87500000 1 - Na Na3 1 0.87500000 0.75000000 0.62500000 1 - Na Na4 1 0.62500000 0.25000000 0.87500000 1 - Na Na5 1 0.25000000 0.87500000 0.62500000 1 - Na Na6 1 0.37500000 0.12500000 0.25000000 1 - Na Na7 1 0.12500000 0.37500000 0.75000000 1 - Na Na8 1 0.25000000 0.37500000 0.12500000 1 - Na Na9 1 0.12500000 0.25000000 0.37500000 1 - Na Na10 1 0.75000000 0.12500000 0.37500000 1 - Na Na11 1 0.37500000 0.75000000 0.12500000 1 - Li Li12 1 0.62500000 0.75000000 0.37500000 1 - Li Li13 1 0.75000000 0.87500000 0.12500000 1 - Li Li14 1 0.25000000 0.12500000 0.87500000 1 - Li Li15 1 0.37500000 0.62500000 0.75000000 1 - Li Li16 1 0.12500000 0.87500000 0.25000000 1 - Li Li17 1 0.87500000 0.25000000 0.12500000 1 - Li Li18 1 0.62500000 0.37500000 0.25000000 1 - Li Li19 1 0.87500000 0.12500000 0.75000000 1 - Li Li20 1 0.25000000 0.62500000 0.37500000 1 - Li Li21 1 0.37500000 0.25000000 0.62500000 1 - Li Li22 1 0.12500000 0.75000000 0.87500000 1 - Li Li23 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe24 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe25 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe26 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe27 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe28 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe29 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe30 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe31 1 0.50000000 0.00000000 0.00000000 1 - F F32 1 0.51881100 0.40279200 0.82513700 1 - F F33 1 0.80632600 0.42234500 0.82513700 1 - F F34 1 0.51881100 0.61601900 0.69367400 1 - F F35 1 0.69367400 0.51881100 0.61601900 1 - F F36 1 0.07765500 0.88398100 0.40279200 1 - F F37 1 0.98118900 0.80632600 0.88398100 1 - F F38 1 0.07765500 0.69367400 0.67486300 1 - F F39 1 0.88398100 0.98118900 0.80632600 1 - F F40 1 0.09720800 0.98118900 0.67486300 1 - F F41 1 0.40279200 0.07765500 0.88398100 1 - F F42 1 0.42234500 0.82513700 0.80632600 1 - F F43 1 0.61601900 0.69367400 0.51881100 1 - F F44 1 0.40279200 0.82513700 0.51881100 1 - F F45 1 0.82513700 0.80632600 0.42234500 1 - F F46 1 0.67486300 0.07765500 0.69367400 1 - F F47 1 0.88398100 0.40279200 0.07765500 1 - F F48 1 0.42234500 0.09720800 0.61601900 1 - F F49 1 0.98118900 0.67486300 0.09720800 1 - F F50 1 0.80632600 0.88398100 0.98118900 1 - F F51 1 0.82513700 0.51881100 0.40279200 1 - F F52 1 0.32513700 0.90279200 0.01881100 1 - F F53 1 0.30632600 0.32513700 0.92234500 1 - F F54 1 0.90279200 0.38398100 0.57765500 1 - F F55 1 0.11601900 0.01881100 0.19367400 1 - F F56 1 0.38398100 0.57765500 0.90279200 1 - F F57 1 0.92234500 0.30632600 0.32513700 1 - F F58 1 0.01881100 0.19367400 0.11601900 1 - F F59 1 0.92234500 0.11601900 0.59720800 1 - F F60 1 0.30632600 0.48118900 0.38398100 1 - F F61 1 0.48118900 0.38398100 0.30632600 1 - F F62 1 0.19367400 0.57765500 0.17486300 1 - F F63 1 0.01881100 0.32513700 0.90279200 1 - F F64 1 0.90279200 0.01881100 0.32513700 1 - F F65 1 0.59720800 0.92234500 0.11601900 1 - F F66 1 0.57765500 0.17486300 0.19367400 1 - F F67 1 0.38398100 0.30632600 0.48118900 1 - F F68 1 0.59720800 0.17486300 0.48118900 1 - F F69 1 0.17486300 0.19367400 0.57765500 1 - F F70 1 0.32513700 0.92234500 0.30632600 1 - F F71 1 0.11601900 0.59720800 0.92234500 1 - F F72 1 0.57765500 0.90279200 0.38398100 1 - F F73 1 0.19367400 0.11601900 0.01881100 1 - F F74 1 0.17486300 0.48118900 0.59720800 1 - F F75 1 0.48118900 0.59720800 0.17486300 1 - F F76 1 0.67486300 0.09720800 0.98118900 1 - F F77 1 0.69367400 0.67486300 0.07765500 1 - F F78 1 0.09720800 0.61601900 0.42234500 1 - F F79 1 0.61601900 0.42234500 0.09720800 1 -" -Ca3Sc2(SiO4)3,mp-6255,Ia-3d,"[27389, 156537, 20214]",0.0,"{'tags': ['Tricalcium discandium tris(silicate)', 'Garnet-(Ca,Sc)', 'Unnamed_Garnet', 'Tricalcium discandium silicate']}","Full Formula (Ca12 Sc8 Si12 O48) -Reduced Formula: Ca3Sc2(SiO4)3 -abc : 10.710422 10.710422 10.710422 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.75 0.125 0.375 -0 - 1 Ca 0.25 0.375 0.125 -0 - 2 Ca 0.125 0.25 0.375 -0 - 3 Ca 0.375 0.75 0.125 -0 - 4 Ca 0.75 0.625 0.875 -0 - 5 Ca 0.125 0.375 0.75 -0 - 6 Ca 0.625 0.875 0.75 -0 - 7 Ca 0.25 0.875 0.625 -0 - 8 Ca 0.875 0.625 0.25 -0 - 9 Ca 0.625 0.25 0.875 -0 - 10 Ca 0.875 0.75 0.625 -0 - 11 Ca 0.375 0.125 0.25 -0 - 12 Sc 0 0 0 -0 - 13 Sc 0.5 0 0 -0 - 14 Sc 0 0.5 0 -0 - 15 Sc 0.5 0.5 0 -0 - 16 Sc 0 0.5 0.5 -0 - 17 Sc 0.5 0 0.5 -0 - 18 Sc 0.5 0.5 0.5 -0 - 19 Sc 0 0 0.5 -0 - 20 Si 0.125 0.875 0.25 0 - 21 Si 0.875 0.125 0.75 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.375 0.25 0.625 0 - 24 Si 0.75 0.875 0.125 0 - 25 Si 0.125 0.75 0.875 0 - 26 Si 0.375 0.625 0.75 0 - 27 Si 0.625 0.75 0.375 0 - 28 Si 0.875 0.25 0.125 0 - 29 Si 0.25 0.125 0.875 0 - 30 Si 0.75 0.375 0.625 0 - 31 Si 0.625 0.375 0.25 0 - 32 O 0.490107 0.381475 0.291672 -0 - 33 O 0.301565 0.891368 0.009893 -0 - 34 O 0.608632 0.910197 0.118525 -0 - 35 O 0.589803 0.198435 0.208328 -0 - 36 O 0.118525 0.009893 0.208328 0 - 37 O 0.198435 0.208328 0.589803 -0 - 38 O 0.198435 0.490107 0.608632 -0 - 39 O 0.208328 0.589803 0.198435 -0 - 40 O 0.381475 0.589803 0.891368 -0 - 41 O 0.910197 0.291672 0.301565 -0 - 42 O 0.291672 0.301565 0.910197 -0 - 43 O 0.208328 0.118525 0.009893 -0 - 44 O 0.490107 0.608632 0.198435 0 - 45 O 0.891368 0.381475 0.589803 -0 - 46 O 0.009893 0.208328 0.118525 -0 - 47 O 0.608632 0.198435 0.490107 -0 - 48 O 0.589803 0.891368 0.381475 -0 - 49 O 0.009893 0.301565 0.891368 0 - 50 O 0.910197 0.118525 0.608632 -0 - 51 O 0.618525 0.410197 0.108632 -0 - 52 O 0.118525 0.608632 0.910197 0 - 53 O 0.291672 0.490107 0.381475 -0 - 54 O 0.891368 0.009893 0.301565 -0 - 55 O 0.301565 0.910197 0.291672 0 - 56 O 0.509893 0.618525 0.708328 0 - 57 O 0.698435 0.108632 0.990107 -0 - 58 O 0.391368 0.089803 0.881475 -0 - 59 O 0.410197 0.801565 0.791672 -0 - 60 O 0.881475 0.990107 0.791672 -0 - 61 O 0.801565 0.791672 0.410197 -0 - 62 O 0.801565 0.509893 0.391368 -0 - 63 O 0.791672 0.410197 0.801565 -0 - 64 O 0.698435 0.089803 0.708328 0 - 65 O 0.108632 0.990107 0.698435 -0 - 66 O 0.708328 0.509893 0.618525 -0 - 67 O 0.618525 0.708328 0.509893 -0 - 68 O 0.881475 0.391368 0.089803 -0 - 69 O 0.089803 0.881475 0.391368 -0 - 70 O 0.990107 0.698435 0.108632 0 - 71 O 0.410197 0.108632 0.618525 -0 - 72 O 0.391368 0.801565 0.509893 -0 - 73 O 0.990107 0.791672 0.881475 -0 - 74 O 0.108632 0.618525 0.410197 -0 - 75 O 0.509893 0.391368 0.801565 0 - 76 O 0.791672 0.881475 0.990107 -0 - 77 O 0.708328 0.698435 0.089803 -0 - 78 O 0.089803 0.708328 0.698435 -0 - 79 O 0.381475 0.291672 0.490107 -0","# generated using pymatgen -data_Ca3Sc2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.71042196 -_cell_length_b 10.71042196 -_cell_length_c 10.71042196 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Sc2(SiO4)3 -_chemical_formula_sum 'Ca12 Sc8 Si12 O48' -_cell_volume 945.79682608 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca1 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca2 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca3 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca4 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca5 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca6 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca7 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca8 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca9 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca10 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca11 1 0.37500000 0.12500000 0.25000000 1 - Sc Sc12 1 0.00000000 0.00000000 0.00000000 1 - Sc Sc13 1 0.50000000 0.00000000 0.00000000 1 - Sc Sc14 1 0.00000000 0.50000000 0.00000000 1 - Sc Sc15 1 0.50000000 0.50000000 0.00000000 1 - Sc Sc16 1 0.00000000 0.50000000 0.50000000 1 - Sc Sc17 1 0.50000000 0.00000000 0.50000000 1 - Sc Sc18 1 0.50000000 0.50000000 0.50000000 1 - Sc Sc19 1 0.00000000 0.00000000 0.50000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.49010700 0.38147500 0.29167200 1 - O O33 1 0.30156500 0.89136800 0.00989300 1 - O O34 1 0.60863200 0.91019700 0.11852500 1 - O O35 1 0.58980300 0.19843500 0.20832800 1 - O O36 1 0.11852500 0.00989300 0.20832800 1 - O O37 1 0.19843500 0.20832800 0.58980300 1 - O O38 1 0.19843500 0.49010700 0.60863200 1 - O O39 1 0.20832800 0.58980300 0.19843500 1 - O O40 1 0.38147500 0.58980300 0.89136800 1 - O O41 1 0.91019700 0.29167200 0.30156500 1 - O O42 1 0.29167200 0.30156500 0.91019700 1 - O O43 1 0.20832800 0.11852500 0.00989300 1 - O O44 1 0.49010700 0.60863200 0.19843500 1 - O O45 1 0.89136800 0.38147500 0.58980300 1 - O O46 1 0.00989300 0.20832800 0.11852500 1 - O O47 1 0.60863200 0.19843500 0.49010700 1 - O O48 1 0.58980300 0.89136800 0.38147500 1 - O O49 1 0.00989300 0.30156500 0.89136800 1 - O O50 1 0.91019700 0.11852500 0.60863200 1 - O O51 1 0.61852500 0.41019700 0.10863200 1 - O O52 1 0.11852500 0.60863200 0.91019700 1 - O O53 1 0.29167200 0.49010700 0.38147500 1 - O O54 1 0.89136800 0.00989300 0.30156500 1 - O O55 1 0.30156500 0.91019700 0.29167200 1 - O O56 1 0.50989300 0.61852500 0.70832800 1 - O O57 1 0.69843500 0.10863200 0.99010700 1 - O O58 1 0.39136800 0.08980300 0.88147500 1 - O O59 1 0.41019700 0.80156500 0.79167200 1 - O O60 1 0.88147500 0.99010700 0.79167200 1 - O O61 1 0.80156500 0.79167200 0.41019700 1 - O O62 1 0.80156500 0.50989300 0.39136800 1 - O O63 1 0.79167200 0.41019700 0.80156500 1 - O O64 1 0.69843500 0.08980300 0.70832800 1 - O O65 1 0.10863200 0.99010700 0.69843500 1 - O O66 1 0.70832800 0.50989300 0.61852500 1 - O O67 1 0.61852500 0.70832800 0.50989300 1 - O O68 1 0.88147500 0.39136800 0.08980300 1 - O O69 1 0.08980300 0.88147500 0.39136800 1 - O O70 1 0.99010700 0.69843500 0.10863200 1 - O O71 1 0.41019700 0.10863200 0.61852500 1 - O O72 1 0.39136800 0.80156500 0.50989300 1 - O O73 1 0.99010700 0.79167200 0.88147500 1 - O O74 1 0.10863200 0.61852500 0.41019700 1 - O O75 1 0.50989300 0.39136800 0.80156500 1 - O O76 1 0.79167200 0.88147500 0.99010700 1 - O O77 1 0.70832800 0.69843500 0.08980300 1 - O O78 1 0.08980300 0.70832800 0.69843500 1 - O O79 1 0.38147500 0.29167200 0.49010700 1 -" -Mn3Cr2(SiO4)3,mp-6274,Ia-3d,"[77436, 27379]",0.02712669799999823,"{'tags': ['Trimanganese dichromium tris(silicate)', 'Trimanganese dichromium silicate']}","Full Formula (Mn12 Cr8 Si12 O48) -Reduced Formula: Mn3Cr2(SiO4)3 -abc : 10.336954 10.336954 10.336954 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.875 0.625 0.25 4.675 - 1 Mn 0.625 0.25 0.875 4.675 - 2 Mn 0.875 0.75 0.625 4.675 - 3 Mn 0.75 0.625 0.875 4.675 - 4 Mn 0.25 0.875 0.625 4.675 - 5 Mn 0.625 0.875 0.75 4.675 - 6 Mn 0.125 0.375 0.75 4.675 - 7 Mn 0.375 0.75 0.125 4.675 - 8 Mn 0.125 0.25 0.375 4.675 - 9 Mn 0.25 0.375 0.125 4.675 - 10 Mn 0.75 0.125 0.375 4.675 - 11 Mn 0.375 0.125 0.25 4.675 - 12 Cr 0.5 0.5 0.5 2.949 - 13 Cr 0.5 0 0.5 2.949 - 14 Cr 0 0.5 0.5 2.949 - 15 Cr 0.5 0.5 0 2.949 - 16 Cr 0 0 0.5 2.949 - 17 Cr 0 0.5 0 2.949 - 18 Cr 0.5 0 0 2.949 - 19 Cr 0 0 0 2.949 - 20 Si 0.125 0.875 0.25 0.014 - 21 Si 0.875 0.125 0.75 0.014 - 22 Si 0.25 0.625 0.375 0.014 - 23 Si 0.375 0.25 0.625 0.014 - 24 Si 0.75 0.875 0.125 0.014 - 25 Si 0.125 0.75 0.875 0.014 - 26 Si 0.375 0.625 0.75 0.014 - 27 Si 0.625 0.75 0.375 0.014 - 28 Si 0.875 0.25 0.125 0.014 - 29 Si 0.25 0.125 0.875 0.014 - 30 Si 0.75 0.375 0.625 0.014 - 31 Si 0.625 0.375 0.25 0.014 - 32 O 0.692176 0.086739 0.707282 0.02 - 33 O 0.105437 0.984894 0.692176 0.02 - 34 O 0.707282 0.515106 0.620543 0.02 - 35 O 0.620543 0.707282 0.515106 0.02 - 36 O 0.879457 0.394563 0.086739 0.02 - 37 O 0.086739 0.879457 0.394563 0.02 - 38 O 0.984894 0.692176 0.105437 0.02 - 39 O 0.413261 0.105437 0.620543 0.02 - 40 O 0.394563 0.807824 0.515106 0.02 - 41 O 0.984894 0.792718 0.879457 0.02 - 42 O 0.105437 0.620543 0.413261 0.02 - 43 O 0.515106 0.394563 0.807824 0.02 - 44 O 0.792718 0.879457 0.984894 0.02 - 45 O 0.707282 0.692176 0.086739 0.02 - 46 O 0.086739 0.707282 0.692176 0.02 - 47 O 0.620543 0.413261 0.105437 0.02 - 48 O 0.792718 0.413261 0.807824 0.02 - 49 O 0.807824 0.515106 0.394563 0.02 - 50 O 0.807824 0.792718 0.413261 0.02 - 51 O 0.879457 0.984894 0.792718 0.02 - 52 O 0.413261 0.807824 0.792718 0.02 - 53 O 0.394563 0.086739 0.879457 0.02 - 54 O 0.692176 0.105437 0.984894 0.02 - 55 O 0.515106 0.620543 0.707282 0.02 - 56 O 0.307824 0.913261 0.292718 0.02 - 57 O 0.894563 0.015106 0.307824 0.02 - 58 O 0.292718 0.484894 0.379457 0.02 - 59 O 0.379457 0.292718 0.484894 0.02 - 60 O 0.120543 0.605437 0.913261 0.02 - 61 O 0.913261 0.120543 0.605437 0.02 - 62 O 0.015106 0.307824 0.894563 0.02 - 63 O 0.586739 0.894563 0.379457 0.02 - 64 O 0.605437 0.192176 0.484894 0.02 - 65 O 0.015106 0.207282 0.120543 0.02 - 66 O 0.894563 0.379457 0.586739 0.02 - 67 O 0.484894 0.605437 0.192176 0.02 - 68 O 0.207282 0.120543 0.015106 0.02 - 69 O 0.292718 0.307824 0.913261 0.02 - 70 O 0.913261 0.292718 0.307824 0.02 - 71 O 0.379457 0.586739 0.894563 0.02 - 72 O 0.207282 0.586739 0.192176 0.02 - 73 O 0.192176 0.484894 0.605437 0.02 - 74 O 0.192176 0.207282 0.586739 0.02 - 75 O 0.120543 0.015106 0.207282 0.02 - 76 O 0.586739 0.192176 0.207282 0.02 - 77 O 0.605437 0.913261 0.120543 0.02 - 78 O 0.307824 0.894563 0.015106 0.02 - 79 O 0.484894 0.379457 0.292718 0.02","# generated using pymatgen -data_Mn3Cr2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.33695370 -_cell_length_b 10.33695370 -_cell_length_c 10.33695370 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn3Cr2(SiO4)3 -_chemical_formula_sum 'Mn12 Cr8 Si12 O48' -_cell_volume 850.26797544 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn1 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn2 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn3 1 0.75000000 0.62500000 0.87500000 1 - Mn Mn4 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn5 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn6 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn7 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn8 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn9 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn10 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn11 1 0.37500000 0.12500000 0.25000000 1 - Cr Cr12 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr13 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr16 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr18 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.69217600 0.08673900 0.70728200 1 - O O33 1 0.10543700 0.98489400 0.69217600 1 - O O34 1 0.70728200 0.51510600 0.62054300 1 - O O35 1 0.62054300 0.70728200 0.51510600 1 - O O36 1 0.87945700 0.39456300 0.08673900 1 - O O37 1 0.08673900 0.87945700 0.39456300 1 - O O38 1 0.98489400 0.69217600 0.10543700 1 - O O39 1 0.41326100 0.10543700 0.62054300 1 - O O40 1 0.39456300 0.80782400 0.51510600 1 - O O41 1 0.98489400 0.79271800 0.87945700 1 - O O42 1 0.10543700 0.62054300 0.41326100 1 - O O43 1 0.51510600 0.39456300 0.80782400 1 - O O44 1 0.79271800 0.87945700 0.98489400 1 - O O45 1 0.70728200 0.69217600 0.08673900 1 - O O46 1 0.08673900 0.70728200 0.69217600 1 - O O47 1 0.62054300 0.41326100 0.10543700 1 - O O48 1 0.79271800 0.41326100 0.80782400 1 - O O49 1 0.80782400 0.51510600 0.39456300 1 - O O50 1 0.80782400 0.79271800 0.41326100 1 - O O51 1 0.87945700 0.98489400 0.79271800 1 - O O52 1 0.41326100 0.80782400 0.79271800 1 - O O53 1 0.39456300 0.08673900 0.87945700 1 - O O54 1 0.69217600 0.10543700 0.98489400 1 - O O55 1 0.51510600 0.62054300 0.70728200 1 - O O56 1 0.30782400 0.91326100 0.29271800 1 - O O57 1 0.89456300 0.01510600 0.30782400 1 - O O58 1 0.29271800 0.48489400 0.37945700 1 - O O59 1 0.37945700 0.29271800 0.48489400 1 - O O60 1 0.12054300 0.60543700 0.91326100 1 - O O61 1 0.91326100 0.12054300 0.60543700 1 - O O62 1 0.01510600 0.30782400 0.89456300 1 - O O63 1 0.58673900 0.89456300 0.37945700 1 - O O64 1 0.60543700 0.19217600 0.48489400 1 - O O65 1 0.01510600 0.20728200 0.12054300 1 - O O66 1 0.89456300 0.37945700 0.58673900 1 - O O67 1 0.48489400 0.60543700 0.19217600 1 - O O68 1 0.20728200 0.12054300 0.01510600 1 - O O69 1 0.29271800 0.30782400 0.91326100 1 - O O70 1 0.91326100 0.29271800 0.30782400 1 - O O71 1 0.37945700 0.58673900 0.89456300 1 - O O72 1 0.20728200 0.58673900 0.19217600 1 - O O73 1 0.19217600 0.48489400 0.60543700 1 - O O74 1 0.19217600 0.20728200 0.58673900 1 - O O75 1 0.12054300 0.01510600 0.20728200 1 - O O76 1 0.58673900 0.19217600 0.20728200 1 - O O77 1 0.60543700 0.91326100 0.12054300 1 - O O78 1 0.30782400 0.89456300 0.01510600 1 - O O79 1 0.48489400 0.37945700 0.29271800 1 -" -Ca3Cr2(SiO4)3,mp-6414,Ia-3d,"[158537, 78017, 52394, 77430, 82743]",0.0,"{'tags': ['Uvarovite', 'Tricalcium dichromium tris(silicate)']}","Full Formula (Ca12 Cr8 Si12 O48) -Reduced Formula: Ca3Cr2(SiO4)3 -abc : 10.528823 10.528823 10.528823 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.125 0.375 0 - 2 Ca 0.375 0.125 0.25 0 - 3 Ca 0.125 0.375 0.75 0 - 4 Ca 0.25 0.875 0.625 0 - 5 Ca 0.125 0.25 0.375 0 - 6 Ca 0.625 0.25 0.875 0 - 7 Ca 0.75 0.625 0.875 0 - 8 Ca 0.875 0.75 0.625 0 - 9 Ca 0.875 0.625 0.25 0 - 10 Ca 0.625 0.875 0.75 0 - 11 Ca 0.375 0.75 0.125 0 - 12 Cr 0.5 0 0 2.933 - 13 Cr 0.5 0.5 0 2.933 - 14 Cr 0 0.5 0.5 2.933 - 15 Cr 0 0 0.5 2.933 - 16 Cr 0.5 0.5 0.5 2.933 - 17 Cr 0 0.5 0 2.933 - 18 Cr 0.5 0 0.5 2.933 - 19 Cr 0 0 0 2.933 - 20 Si 0.125 0.75 0.875 0.005 - 21 Si 0.875 0.25 0.125 0.005 - 22 Si 0.75 0.375 0.625 0.005 - 23 Si 0.125 0.875 0.25 0.005 - 24 Si 0.25 0.125 0.875 0.005 - 25 Si 0.375 0.625 0.75 0.005 - 26 Si 0.375 0.25 0.625 0.005 - 27 Si 0.875 0.125 0.75 0.005 - 28 Si 0.625 0.375 0.25 0.005 - 29 Si 0.75 0.875 0.125 0.005 - 30 Si 0.25 0.625 0.375 0.005 - 31 Si 0.625 0.75 0.375 0.005 - 32 O 0.586998 0.892713 0.383981 -0.006 - 33 O 0.383981 0.586998 0.892713 -0.006 - 34 O 0.296983 0.305715 0.913002 -0.006 - 35 O 0.491268 0.607287 0.194285 -0.006 - 36 O 0.305715 0.892713 0.008732 -0.006 - 37 O 0.116019 0.008732 0.203017 -0.006 - 38 O 0.383981 0.296983 0.491268 -0.006 - 39 O 0.892713 0.383981 0.586998 -0.006 - 40 O 0.194285 0.203017 0.586998 -0.006 - 41 O 0.491268 0.383981 0.296983 -0.006 - 42 O 0.892713 0.008732 0.305715 -0.006 - 43 O 0.607287 0.913002 0.116019 -0.006 - 44 O 0.913002 0.116019 0.607287 -0.006 - 45 O 0.296983 0.491268 0.383981 -0.006 - 46 O 0.586998 0.194285 0.203017 -0.006 - 47 O 0.203017 0.586998 0.194285 -0.006 - 48 O 0.008732 0.305715 0.892713 -0.006 - 49 O 0.913002 0.296983 0.305715 -0.006 - 50 O 0.008732 0.203017 0.116019 -0.006 - 51 O 0.805715 0.796983 0.413002 -0.006 - 52 O 0.194285 0.491268 0.607287 -0.006 - 53 O 0.607287 0.194285 0.491268 -0.006 - 54 O 0.203017 0.116019 0.008732 -0.006 - 55 O 0.116019 0.607287 0.913002 -0.006 - 56 O 0.413002 0.107287 0.616019 -0.006 - 57 O 0.616019 0.413002 0.107287 -0.006 - 58 O 0.703017 0.694285 0.086998 -0.006 - 59 O 0.508732 0.392713 0.805715 -0.006 - 60 O 0.694285 0.107287 0.991268 -0.006 - 61 O 0.883981 0.991268 0.796983 -0.006 - 62 O 0.616019 0.703017 0.508732 -0.006 - 63 O 0.107287 0.616019 0.413002 -0.006 - 64 O 0.883981 0.392713 0.086998 -0.006 - 65 O 0.796983 0.883981 0.991268 -0.006 - 66 O 0.392713 0.805715 0.508732 -0.006 - 67 O 0.694285 0.086998 0.703017 -0.006 - 68 O 0.805715 0.508732 0.392713 -0.006 - 69 O 0.991268 0.796983 0.883981 -0.006 - 70 O 0.086998 0.703017 0.694285 -0.006 - 71 O 0.991268 0.694285 0.107287 -0.006 - 72 O 0.796983 0.413002 0.805715 -0.006 - 73 O 0.413002 0.805715 0.796983 -0.006 - 74 O 0.703017 0.508732 0.616019 -0.006 - 75 O 0.086998 0.883981 0.392713 -0.006 - 76 O 0.392713 0.086998 0.883981 -0.006 - 77 O 0.107287 0.991268 0.694285 -0.006 - 78 O 0.508732 0.616019 0.703017 -0.006 - 79 O 0.305715 0.913002 0.296983 -0.006","# generated using pymatgen -data_Ca3Cr2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.52882336 -_cell_length_b 10.52882336 -_cell_length_c 10.52882336 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Cr2(SiO4)3 -_chemical_formula_sum 'Ca12 Cr8 Si12 O48' -_cell_volume 898.49906193 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Cr Cr12 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr13 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr16 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr18 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58699800 0.89271300 0.38398100 1 - O O33 1 0.38398100 0.58699800 0.89271300 1 - O O34 1 0.29698300 0.30571500 0.91300200 1 - O O35 1 0.49126800 0.60728700 0.19428500 1 - O O36 1 0.30571500 0.89271300 0.00873200 1 - O O37 1 0.11601900 0.00873200 0.20301700 1 - O O38 1 0.38398100 0.29698300 0.49126800 1 - O O39 1 0.89271300 0.38398100 0.58699800 1 - O O40 1 0.19428500 0.20301700 0.58699800 1 - O O41 1 0.49126800 0.38398100 0.29698300 1 - O O42 1 0.89271300 0.00873200 0.30571500 1 - O O43 1 0.60728700 0.91300200 0.11601900 1 - O O44 1 0.91300200 0.11601900 0.60728700 1 - O O45 1 0.29698300 0.49126800 0.38398100 1 - O O46 1 0.58699800 0.19428500 0.20301700 1 - O O47 1 0.20301700 0.58699800 0.19428500 1 - O O48 1 0.00873200 0.30571500 0.89271300 1 - O O49 1 0.91300200 0.29698300 0.30571500 1 - O O50 1 0.00873200 0.20301700 0.11601900 1 - O O51 1 0.80571500 0.79698300 0.41300200 1 - O O52 1 0.19428500 0.49126800 0.60728700 1 - O O53 1 0.60728700 0.19428500 0.49126800 1 - O O54 1 0.20301700 0.11601900 0.00873200 1 - O O55 1 0.11601900 0.60728700 0.91300200 1 - O O56 1 0.41300200 0.10728700 0.61601900 1 - O O57 1 0.61601900 0.41300200 0.10728700 1 - O O58 1 0.70301700 0.69428500 0.08699800 1 - O O59 1 0.50873200 0.39271300 0.80571500 1 - O O60 1 0.69428500 0.10728700 0.99126800 1 - O O61 1 0.88398100 0.99126800 0.79698300 1 - O O62 1 0.61601900 0.70301700 0.50873200 1 - O O63 1 0.10728700 0.61601900 0.41300200 1 - O O64 1 0.88398100 0.39271300 0.08699800 1 - O O65 1 0.79698300 0.88398100 0.99126800 1 - O O66 1 0.39271300 0.80571500 0.50873200 1 - O O67 1 0.69428500 0.08699800 0.70301700 1 - O O68 1 0.80571500 0.50873200 0.39271300 1 - O O69 1 0.99126800 0.79698300 0.88398100 1 - O O70 1 0.08699800 0.70301700 0.69428500 1 - O O71 1 0.99126800 0.69428500 0.10728700 1 - O O72 1 0.79698300 0.41300200 0.80571500 1 - O O73 1 0.41300200 0.80571500 0.79698300 1 - O O74 1 0.70301700 0.50873200 0.61601900 1 - O O75 1 0.08699800 0.88398100 0.39271300 1 - O O76 1 0.39271300 0.08699800 0.88398100 1 - O O77 1 0.10728700 0.99126800 0.69428500 1 - O O78 1 0.50873200 0.61601900 0.70301700 1 - O O79 1 0.30571500 0.91300200 0.29698300 1 -" -Mn3Al2(SiO4)3,mp-6480,Ia-3d,"[193638, 193636, 193634, 193635, 193639, 193637, 193633, 83459, 94597, 94609, 94604, 94603, 94599, 83458, 77428, 95273, 94602, 83457, 281136, 89678, 164594, 94605, 95275, 94600, 94608, 52396, 94606, 95274, 94601, 94607, 94598]",0.009527368899991728,"{'tags': ['Tricalcium dialuminium tris(silicate)', 'Trimanganese dialuminium tris(silicate)', 'Trimanganese dialuminium trisilicate', 'Spessartine', 'Trimangamese dialuminium tris(silicate)', 'Trimanganese dialuminum tris(silicate)']}","Full Formula (Mn12 Al8 Si12 O48) -Reduced Formula: Mn3Al2(SiO4)3 -abc : 10.169780 10.169780 10.169780 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.375 0.125 0.25 4.665 - 1 Mn 0.75 0.125 0.375 4.665 - 2 Mn 0.25 0.375 0.125 4.665 - 3 Mn 0.375 0.75 0.125 4.665 - 4 Mn 0.125 0.375 0.75 4.665 - 5 Mn 0.125 0.25 0.375 4.665 - 6 Mn 0.625 0.25 0.875 4.665 - 7 Mn 0.25 0.875 0.625 4.665 - 8 Mn 0.625 0.875 0.75 4.665 - 9 Mn 0.875 0.625 0.25 4.665 - 10 Mn 0.875 0.75 0.625 4.665 - 11 Mn 0.75 0.625 0.875 4.665 - 12 Al 0.5 0 0 0.002 - 13 Al 0.5 0.5 0.5 0.002 - 14 Al 0.5 0 0.5 0.002 - 15 Al 0 0 0.5 0.002 - 16 Al 0 0 0 0.002 - 17 Al 0 0.5 0.5 0.002 - 18 Al 0.5 0.5 0 0.002 - 19 Al 0 0.5 0 0.002 - 20 Si 0.625 0.375 0.25 0.007 - 21 Si 0.875 0.125 0.75 0.007 - 22 Si 0.25 0.625 0.375 0.007 - 23 Si 0.625 0.75 0.375 0.007 - 24 Si 0.375 0.25 0.625 0.007 - 25 Si 0.375 0.625 0.75 0.007 - 26 Si 0.25 0.125 0.875 0.007 - 27 Si 0.125 0.875 0.25 0.007 - 28 Si 0.75 0.375 0.625 0.007 - 29 Si 0.875 0.25 0.125 0.007 - 30 Si 0.75 0.875 0.125 0.007 - 31 Si 0.125 0.75 0.875 0.007 - 32 O 0.58215 0.89506 0.382698 0.031 - 33 O 0.382698 0.58215 0.89506 0.031 - 34 O 0.300547 0.312909 0.91785 0.031 - 35 O 0.487638 0.60494 0.187091 0.031 - 36 O 0.312909 0.89506 0.012362 0.031 - 37 O 0.117302 0.012362 0.199453 0.031 - 38 O 0.382698 0.300547 0.487638 0.031 - 39 O 0.89506 0.382698 0.58215 0.031 - 40 O 0.187091 0.199453 0.58215 0.031 - 41 O 0.487638 0.382698 0.300547 0.031 - 42 O 0.89506 0.012362 0.312909 0.031 - 43 O 0.60494 0.91785 0.117302 0.031 - 44 O 0.91785 0.117302 0.60494 0.031 - 45 O 0.300547 0.487638 0.382698 0.031 - 46 O 0.58215 0.187091 0.199453 0.031 - 47 O 0.199453 0.58215 0.187091 0.031 - 48 O 0.012362 0.312909 0.89506 0.031 - 49 O 0.91785 0.300547 0.312909 0.031 - 50 O 0.012362 0.199453 0.117302 0.031 - 51 O 0.812909 0.800547 0.41785 0.031 - 52 O 0.187091 0.487638 0.60494 0.031 - 53 O 0.60494 0.187091 0.487638 0.031 - 54 O 0.199453 0.117302 0.012362 0.031 - 55 O 0.117302 0.60494 0.91785 0.031 - 56 O 0.41785 0.10494 0.617302 0.031 - 57 O 0.617302 0.41785 0.10494 0.031 - 58 O 0.699453 0.687091 0.08215 0.031 - 59 O 0.512362 0.39506 0.812909 0.031 - 60 O 0.687091 0.10494 0.987638 0.031 - 61 O 0.882698 0.987638 0.800547 0.031 - 62 O 0.617302 0.699453 0.512362 0.031 - 63 O 0.10494 0.617302 0.41785 0.031 - 64 O 0.882698 0.39506 0.08215 0.031 - 65 O 0.800547 0.882698 0.987638 0.031 - 66 O 0.39506 0.812909 0.512362 0.031 - 67 O 0.687091 0.08215 0.699453 0.031 - 68 O 0.812909 0.512362 0.39506 0.031 - 69 O 0.987638 0.800547 0.882698 0.031 - 70 O 0.08215 0.699453 0.687091 0.031 - 71 O 0.987638 0.687091 0.10494 0.031 - 72 O 0.800547 0.41785 0.812909 0.031 - 73 O 0.41785 0.812909 0.800547 0.031 - 74 O 0.699453 0.512362 0.617302 0.031 - 75 O 0.08215 0.882698 0.39506 0.031 - 76 O 0.39506 0.08215 0.882698 0.031 - 77 O 0.10494 0.987638 0.687091 0.031 - 78 O 0.512362 0.617302 0.699453 0.031 - 79 O 0.312909 0.91785 0.300547 0.031","# generated using pymatgen -data_Mn3Al2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.16977962 -_cell_length_b 10.16977962 -_cell_length_c 10.16977962 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn3Al2(SiO4)3 -_chemical_formula_sum 'Mn12 Al8 Si12 O48' -_cell_volume 809.67873710 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.37500000 0.12500000 0.25000000 1 - Mn Mn1 1 0.75000000 0.12500000 0.37500000 1 - Mn Mn2 1 0.25000000 0.37500000 0.12500000 1 - Mn Mn3 1 0.37500000 0.75000000 0.12500000 1 - Mn Mn4 1 0.12500000 0.37500000 0.75000000 1 - Mn Mn5 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn6 1 0.62500000 0.25000000 0.87500000 1 - Mn Mn7 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn8 1 0.62500000 0.87500000 0.75000000 1 - Mn Mn9 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn10 1 0.87500000 0.75000000 0.62500000 1 - Mn Mn11 1 0.75000000 0.62500000 0.87500000 1 - Al Al12 1 0.50000000 0.00000000 0.00000000 1 - Al Al13 1 0.50000000 0.50000000 0.50000000 1 - Al Al14 1 0.50000000 0.00000000 0.50000000 1 - Al Al15 1 0.00000000 0.00000000 0.50000000 1 - Al Al16 1 0.00000000 0.00000000 0.00000000 1 - Al Al17 1 0.00000000 0.50000000 0.50000000 1 - Al Al18 1 0.50000000 0.50000000 0.00000000 1 - Al Al19 1 0.00000000 0.50000000 0.00000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.37500000 0.25000000 0.62500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.25000000 0.12500000 0.87500000 1 - Si Si27 1 0.12500000 0.87500000 0.25000000 1 - Si Si28 1 0.75000000 0.37500000 0.62500000 1 - Si Si29 1 0.87500000 0.25000000 0.12500000 1 - Si Si30 1 0.75000000 0.87500000 0.12500000 1 - Si Si31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.58215000 0.89506000 0.38269800 1 - O O33 1 0.38269800 0.58215000 0.89506000 1 - O O34 1 0.30054700 0.31290900 0.91785000 1 - O O35 1 0.48763800 0.60494000 0.18709100 1 - O O36 1 0.31290900 0.89506000 0.01236200 1 - O O37 1 0.11730200 0.01236200 0.19945300 1 - O O38 1 0.38269800 0.30054700 0.48763800 1 - O O39 1 0.89506000 0.38269800 0.58215000 1 - O O40 1 0.18709100 0.19945300 0.58215000 1 - O O41 1 0.48763800 0.38269800 0.30054700 1 - O O42 1 0.89506000 0.01236200 0.31290900 1 - O O43 1 0.60494000 0.91785000 0.11730200 1 - O O44 1 0.91785000 0.11730200 0.60494000 1 - O O45 1 0.30054700 0.48763800 0.38269800 1 - O O46 1 0.58215000 0.18709100 0.19945300 1 - O O47 1 0.19945300 0.58215000 0.18709100 1 - O O48 1 0.01236200 0.31290900 0.89506000 1 - O O49 1 0.91785000 0.30054700 0.31290900 1 - O O50 1 0.01236200 0.19945300 0.11730200 1 - O O51 1 0.81290900 0.80054700 0.41785000 1 - O O52 1 0.18709100 0.48763800 0.60494000 1 - O O53 1 0.60494000 0.18709100 0.48763800 1 - O O54 1 0.19945300 0.11730200 0.01236200 1 - O O55 1 0.11730200 0.60494000 0.91785000 1 - O O56 1 0.41785000 0.10494000 0.61730200 1 - O O57 1 0.61730200 0.41785000 0.10494000 1 - O O58 1 0.69945300 0.68709100 0.08215000 1 - O O59 1 0.51236200 0.39506000 0.81290900 1 - O O60 1 0.68709100 0.10494000 0.98763800 1 - O O61 1 0.88269800 0.98763800 0.80054700 1 - O O62 1 0.61730200 0.69945300 0.51236200 1 - O O63 1 0.10494000 0.61730200 0.41785000 1 - O O64 1 0.88269800 0.39506000 0.08215000 1 - O O65 1 0.80054700 0.88269800 0.98763800 1 - O O66 1 0.39506000 0.81290900 0.51236200 1 - O O67 1 0.68709100 0.08215000 0.69945300 1 - O O68 1 0.81290900 0.51236200 0.39506000 1 - O O69 1 0.98763800 0.80054700 0.88269800 1 - O O70 1 0.08215000 0.69945300 0.68709100 1 - O O71 1 0.98763800 0.68709100 0.10494000 1 - O O72 1 0.80054700 0.41785000 0.81290900 1 - O O73 1 0.41785000 0.81290900 0.80054700 1 - O O74 1 0.69945300 0.51236200 0.61730200 1 - O O75 1 0.08215000 0.88269800 0.39506000 1 - O O76 1 0.39506000 0.08215000 0.88269800 1 - O O77 1 0.10494000 0.98763800 0.68709100 1 - O O78 1 0.51236200 0.61730200 0.69945300 1 - O O79 1 0.31290900 0.91785000 0.30054700 1 -" -Na3Li3In2F12,mp-6527,Ia-3d,"[27008, 416927, 416929, 416928, 416926]",0.0,"{'tags': ['Trilithium trisodium bis(hexafluoroindate)', 'Trisodium trilithium diindium fluoride']}","Full Formula (Na12 Li12 In8 F48) -Reduced Formula: Na3Li3In2F12 -abc : 11.168222 11.168222 11.168222 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.875 0.75 0.625 0 - 1 Na 0.875 0.625 0.25 0 - 2 Na 0.625 0.875 0.75 0 - 3 Na 0.25 0.875 0.625 0 - 4 Na 0.75 0.625 0.875 0 - 5 Na 0.625 0.25 0.875 0 - 6 Na 0.125 0.25 0.375 0 - 7 Na 0.125 0.375 0.75 0 - 8 Na 0.375 0.125 0.25 0 - 9 Na 0.75 0.125 0.375 0 - 10 Na 0.25 0.375 0.125 0 - 11 Na 0.375 0.75 0.125 0 - 12 Li 0.375 0.625 0.75 -0 - 13 Li 0.625 0.375 0.25 -0 - 14 Li 0.625 0.75 0.375 -0 - 15 Li 0.25 0.125 0.875 -0 - 16 Li 0.875 0.25 0.125 -0 - 17 Li 0.75 0.375 0.625 -0 - 18 Li 0.25 0.625 0.375 -0 - 19 Li 0.75 0.875 0.125 -0 - 20 Li 0.125 0.75 0.875 -0 - 21 Li 0.375 0.25 0.625 -0 - 22 Li 0.875 0.125 0.75 -0 - 23 Li 0.125 0.875 0.25 -0 - 24 In 0.5 0 0.5 -0 - 25 In 0 0.5 0 -0 - 26 In 0.5 0.5 0.5 -0 - 27 In 0 0 0.5 -0 - 28 In 0 0 0 -0 - 29 In 0 0.5 0.5 -0 - 30 In 0.5 0.5 0 -0 - 31 In 0.5 0 0 -0 - 32 F 0.681565 0.082513 0.704697 0 - 33 F 0.704697 0.681565 0.082513 0 - 34 F 0.523132 0.400948 0.818435 0 - 35 F 0.622184 0.417487 0.099052 0 - 36 F 0.400948 0.082513 0.877816 0 - 37 F 0.795303 0.877816 0.976868 0 - 38 F 0.704697 0.523132 0.622184 0 - 39 F 0.082513 0.704697 0.681565 0 - 40 F 0.099052 0.976868 0.681565 0 - 41 F 0.622184 0.704697 0.523132 0 - 42 F 0.082513 0.877816 0.400948 0 - 43 F 0.417487 0.818435 0.795303 0 - 44 F 0.818435 0.795303 0.417487 0 - 45 F 0.523132 0.622184 0.704697 0 - 46 F 0.681565 0.099052 0.976868 0 - 47 F 0.976868 0.681565 0.099052 0 - 48 F 0.877816 0.400948 0.082513 0 - 49 F 0.818435 0.523132 0.400948 0 - 50 F 0.877816 0.976868 0.795303 0 - 51 F 0.099052 0.622184 0.417487 0 - 52 F 0.400948 0.818435 0.523132 0 - 53 F 0.417487 0.099052 0.622184 0 - 54 F 0.976868 0.795303 0.877816 0 - 55 F 0.795303 0.417487 0.818435 0 - 56 F 0.318435 0.917487 0.295303 0 - 57 F 0.295303 0.318435 0.917487 0 - 58 F 0.476868 0.599052 0.181565 0 - 59 F 0.377816 0.582513 0.900948 0 - 60 F 0.599052 0.917487 0.122184 0 - 61 F 0.204697 0.122184 0.023132 0 - 62 F 0.295303 0.476868 0.377816 0 - 63 F 0.917487 0.295303 0.318435 0 - 64 F 0.900948 0.023132 0.318435 0 - 65 F 0.377816 0.295303 0.476868 0 - 66 F 0.917487 0.122184 0.599052 0 - 67 F 0.582513 0.181565 0.204697 0 - 68 F 0.181565 0.204697 0.582513 0 - 69 F 0.476868 0.377816 0.295303 0 - 70 F 0.318435 0.900948 0.023132 0 - 71 F 0.023132 0.318435 0.900948 0 - 72 F 0.122184 0.599052 0.917487 0 - 73 F 0.181565 0.476868 0.599052 0 - 74 F 0.122184 0.023132 0.204697 0 - 75 F 0.900948 0.377816 0.582513 0 - 76 F 0.599052 0.181565 0.476868 0 - 77 F 0.582513 0.900948 0.377816 0 - 78 F 0.023132 0.204697 0.122184 0 - 79 F 0.204697 0.582513 0.181565 0","# generated using pymatgen -data_Na3Li3In2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.16822204 -_cell_length_b 11.16822204 -_cell_length_c 11.16822204 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3In2F12 -_chemical_formula_sum 'Na12 Li12 In8 F48' -_cell_volume 1072.33437552 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.87500000 0.75000000 0.62500000 1 - Na Na1 1 0.87500000 0.62500000 0.25000000 1 - Na Na2 1 0.62500000 0.87500000 0.75000000 1 - Na Na3 1 0.25000000 0.87500000 0.62500000 1 - Na Na4 1 0.75000000 0.62500000 0.87500000 1 - Na Na5 1 0.62500000 0.25000000 0.87500000 1 - Na Na6 1 0.12500000 0.25000000 0.37500000 1 - Na Na7 1 0.12500000 0.37500000 0.75000000 1 - Na Na8 1 0.37500000 0.12500000 0.25000000 1 - Na Na9 1 0.75000000 0.12500000 0.37500000 1 - Na Na10 1 0.25000000 0.37500000 0.12500000 1 - Na Na11 1 0.37500000 0.75000000 0.12500000 1 - Li Li12 1 0.37500000 0.62500000 0.75000000 1 - Li Li13 1 0.62500000 0.37500000 0.25000000 1 - Li Li14 1 0.62500000 0.75000000 0.37500000 1 - Li Li15 1 0.25000000 0.12500000 0.87500000 1 - Li Li16 1 0.87500000 0.25000000 0.12500000 1 - Li Li17 1 0.75000000 0.37500000 0.62500000 1 - Li Li18 1 0.25000000 0.62500000 0.37500000 1 - Li Li19 1 0.75000000 0.87500000 0.12500000 1 - Li Li20 1 0.12500000 0.75000000 0.87500000 1 - Li Li21 1 0.37500000 0.25000000 0.62500000 1 - Li Li22 1 0.87500000 0.12500000 0.75000000 1 - Li Li23 1 0.12500000 0.87500000 0.25000000 1 - In In24 1 0.50000000 0.00000000 0.50000000 1 - In In25 1 0.00000000 0.50000000 0.00000000 1 - In In26 1 0.50000000 0.50000000 0.50000000 1 - In In27 1 0.00000000 0.00000000 0.50000000 1 - In In28 1 0.00000000 0.00000000 0.00000000 1 - In In29 1 0.00000000 0.50000000 0.50000000 1 - In In30 1 0.50000000 0.50000000 0.00000000 1 - In In31 1 0.50000000 0.00000000 0.00000000 1 - F F32 1 0.68156500 0.08251300 0.70469700 1 - F F33 1 0.70469700 0.68156500 0.08251300 1 - F F34 1 0.52313200 0.40094800 0.81843500 1 - F F35 1 0.62218400 0.41748700 0.09905200 1 - F F36 1 0.40094800 0.08251300 0.87781600 1 - F F37 1 0.79530300 0.87781600 0.97686800 1 - F F38 1 0.70469700 0.52313200 0.62218400 1 - F F39 1 0.08251300 0.70469700 0.68156500 1 - F F40 1 0.09905200 0.97686800 0.68156500 1 - F F41 1 0.62218400 0.70469700 0.52313200 1 - F F42 1 0.08251300 0.87781600 0.40094800 1 - F F43 1 0.41748700 0.81843500 0.79530300 1 - F F44 1 0.81843500 0.79530300 0.41748700 1 - F F45 1 0.52313200 0.62218400 0.70469700 1 - F F46 1 0.68156500 0.09905200 0.97686800 1 - F F47 1 0.97686800 0.68156500 0.09905200 1 - F F48 1 0.87781600 0.40094800 0.08251300 1 - F F49 1 0.81843500 0.52313200 0.40094800 1 - F F50 1 0.87781600 0.97686800 0.79530300 1 - F F51 1 0.09905200 0.62218400 0.41748700 1 - F F52 1 0.40094800 0.81843500 0.52313200 1 - F F53 1 0.41748700 0.09905200 0.62218400 1 - F F54 1 0.97686800 0.79530300 0.87781600 1 - F F55 1 0.79530300 0.41748700 0.81843500 1 - F F56 1 0.31843500 0.91748700 0.29530300 1 - F F57 1 0.29530300 0.31843500 0.91748700 1 - F F58 1 0.47686800 0.59905200 0.18156500 1 - F F59 1 0.37781600 0.58251300 0.90094800 1 - F F60 1 0.59905200 0.91748700 0.12218400 1 - F F61 1 0.20469700 0.12218400 0.02313200 1 - F F62 1 0.29530300 0.47686800 0.37781600 1 - F F63 1 0.91748700 0.29530300 0.31843500 1 - F F64 1 0.90094800 0.02313200 0.31843500 1 - F F65 1 0.37781600 0.29530300 0.47686800 1 - F F66 1 0.91748700 0.12218400 0.59905200 1 - F F67 1 0.58251300 0.18156500 0.20469700 1 - F F68 1 0.18156500 0.20469700 0.58251300 1 - F F69 1 0.47686800 0.37781600 0.29530300 1 - F F70 1 0.31843500 0.90094800 0.02313200 1 - F F71 1 0.02313200 0.31843500 0.90094800 1 - F F72 1 0.12218400 0.59905200 0.91748700 1 - F F73 1 0.18156500 0.47686800 0.59905200 1 - F F74 1 0.12218400 0.02313200 0.20469700 1 - F F75 1 0.90094800 0.37781600 0.58251300 1 - F F76 1 0.59905200 0.18156500 0.47686800 1 - F F77 1 0.58251300 0.90094800 0.37781600 1 - F F78 1 0.02313200 0.20469700 0.12218400 1 - F F79 1 0.20469700 0.58251300 0.18156500 1 -" -Mg3Fe2(SiO4)3,mp-6551,Ia-3d,"[27373, 66672, 77435]",0.06652682687499656,"{'tags': ['Majorite', 'Trimagnesium diiron(III) tris(silicate)', 'Pyrope']}","Full Formula (Mg12 Fe8 Si12 O48) -Reduced Formula: Mg3Fe2(SiO4)3 -abc : 10.210935 10.210935 10.210935 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.375 0.75 0.125 0.002 - 1 Mg 0.25 0.375 0.125 0.002 - 2 Mg 0.75 0.125 0.375 0.002 - 3 Mg 0.375 0.125 0.25 0.002 - 4 Mg 0.125 0.375 0.75 0.002 - 5 Mg 0.125 0.25 0.375 0.002 - 6 Mg 0.625 0.25 0.875 0.002 - 7 Mg 0.75 0.625 0.875 0.002 - 8 Mg 0.25 0.875 0.625 0.002 - 9 Mg 0.625 0.875 0.75 0.002 - 10 Mg 0.875 0.625 0.25 0.002 - 11 Mg 0.875 0.75 0.625 0.002 - 12 Fe 0.5 0 0.5 4.383 - 13 Fe 0 0.5 0 4.383 - 14 Fe 0.5 0.5 0.5 4.383 - 15 Fe 0 0 0 4.383 - 16 Fe 0 0.5 0.5 4.383 - 17 Fe 0.5 0.5 0 4.383 - 18 Fe 0.5 0 0 4.383 - 19 Fe 0 0 0.5 4.383 - 20 Si 0.875 0.25 0.125 0.014 - 21 Si 0.75 0.375 0.625 0.014 - 22 Si 0.125 0.875 0.25 0.014 - 23 Si 0.25 0.125 0.875 0.014 - 24 Si 0.625 0.375 0.25 0.014 - 25 Si 0.375 0.625 0.75 0.014 - 26 Si 0.375 0.25 0.625 0.014 - 27 Si 0.875 0.125 0.75 0.014 - 28 Si 0.625 0.75 0.375 0.014 - 29 Si 0.25 0.625 0.375 0.014 - 30 Si 0.75 0.875 0.125 0.014 - 31 Si 0.125 0.75 0.875 0.014 - 32 O 0.875943 0.396502 0.088475 0.08 - 33 O 0.787468 0.875943 0.979441 0.08 - 34 O 0.396502 0.808027 0.520559 0.08 - 35 O 0.691973 0.088475 0.712532 0.08 - 36 O 0.808027 0.520559 0.396502 0.08 - 37 O 0.979441 0.787468 0.875943 0.08 - 38 O 0.088475 0.712532 0.691973 0.08 - 39 O 0.979441 0.691973 0.103498 0.08 - 40 O 0.787468 0.411525 0.808027 0.08 - 41 O 0.411525 0.808027 0.787468 0.08 - 42 O 0.712532 0.520559 0.624057 0.08 - 43 O 0.088475 0.875943 0.396502 0.08 - 44 O 0.396502 0.088475 0.875943 0.08 - 45 O 0.103498 0.979441 0.691973 0.08 - 46 O 0.520559 0.624057 0.712532 0.08 - 47 O 0.808027 0.787468 0.411525 0.08 - 48 O 0.103498 0.624057 0.411525 0.08 - 49 O 0.624057 0.712532 0.520559 0.08 - 50 O 0.875943 0.979441 0.787468 0.08 - 51 O 0.691973 0.103498 0.979441 0.08 - 52 O 0.520559 0.396502 0.808027 0.08 - 53 O 0.712532 0.691973 0.088475 0.08 - 54 O 0.624057 0.411525 0.103498 0.08 - 55 O 0.411525 0.103498 0.624057 0.08 - 56 O 0.124057 0.603498 0.911525 0.08 - 57 O 0.212532 0.124057 0.020559 0.08 - 58 O 0.603498 0.191973 0.479441 0.08 - 59 O 0.308027 0.911525 0.287468 0.08 - 60 O 0.191973 0.479441 0.603498 0.08 - 61 O 0.020559 0.212532 0.124057 0.08 - 62 O 0.911525 0.287468 0.308027 0.08 - 63 O 0.020559 0.308027 0.896502 0.08 - 64 O 0.212532 0.588475 0.191973 0.08 - 65 O 0.588475 0.191973 0.212532 0.08 - 66 O 0.287468 0.479441 0.375943 0.08 - 67 O 0.911525 0.124057 0.603498 0.08 - 68 O 0.603498 0.911525 0.124057 0.08 - 69 O 0.896502 0.020559 0.308027 0.08 - 70 O 0.479441 0.375943 0.287468 0.08 - 71 O 0.191973 0.212532 0.588475 0.08 - 72 O 0.896502 0.375943 0.588475 0.08 - 73 O 0.375943 0.287468 0.479441 0.08 - 74 O 0.124057 0.020559 0.212532 0.08 - 75 O 0.308027 0.896502 0.020559 0.08 - 76 O 0.479441 0.603498 0.191973 0.08 - 77 O 0.287468 0.308027 0.911525 0.08 - 78 O 0.375943 0.588475 0.896502 0.08 - 79 O 0.588475 0.896502 0.375943 0.08","# generated using pymatgen -data_Mg3Fe2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.21093488 -_cell_length_b 10.21093488 -_cell_length_c 10.21093488 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Fe2(SiO4)3 -_chemical_formula_sum 'Mg12 Fe8 Si12 O48' -_cell_volume 819.54844080 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg1 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg2 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg3 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg4 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg9 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg10 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg11 1 0.87500000 0.75000000 0.62500000 1 - Fe Fe12 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe13 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe14 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe17 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.50000000 1 - Si Si20 1 0.87500000 0.25000000 0.12500000 1 - Si Si21 1 0.75000000 0.37500000 0.62500000 1 - Si Si22 1 0.12500000 0.87500000 0.25000000 1 - Si Si23 1 0.25000000 0.12500000 0.87500000 1 - Si Si24 1 0.62500000 0.37500000 0.25000000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.75000000 0.37500000 1 - Si Si29 1 0.25000000 0.62500000 0.37500000 1 - Si Si30 1 0.75000000 0.87500000 0.12500000 1 - Si Si31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.87594300 0.39650200 0.08847500 1 - O O33 1 0.78746800 0.87594300 0.97944100 1 - O O34 1 0.39650200 0.80802700 0.52055900 1 - O O35 1 0.69197300 0.08847500 0.71253200 1 - O O36 1 0.80802700 0.52055900 0.39650200 1 - O O37 1 0.97944100 0.78746800 0.87594300 1 - O O38 1 0.08847500 0.71253200 0.69197300 1 - O O39 1 0.97944100 0.69197300 0.10349800 1 - O O40 1 0.78746800 0.41152500 0.80802700 1 - O O41 1 0.41152500 0.80802700 0.78746800 1 - O O42 1 0.71253200 0.52055900 0.62405700 1 - O O43 1 0.08847500 0.87594300 0.39650200 1 - O O44 1 0.39650200 0.08847500 0.87594300 1 - O O45 1 0.10349800 0.97944100 0.69197300 1 - O O46 1 0.52055900 0.62405700 0.71253200 1 - O O47 1 0.80802700 0.78746800 0.41152500 1 - O O48 1 0.10349800 0.62405700 0.41152500 1 - O O49 1 0.62405700 0.71253200 0.52055900 1 - O O50 1 0.87594300 0.97944100 0.78746800 1 - O O51 1 0.69197300 0.10349800 0.97944100 1 - O O52 1 0.52055900 0.39650200 0.80802700 1 - O O53 1 0.71253200 0.69197300 0.08847500 1 - O O54 1 0.62405700 0.41152500 0.10349800 1 - O O55 1 0.41152500 0.10349800 0.62405700 1 - O O56 1 0.12405700 0.60349800 0.91152500 1 - O O57 1 0.21253200 0.12405700 0.02055900 1 - O O58 1 0.60349800 0.19197300 0.47944100 1 - O O59 1 0.30802700 0.91152500 0.28746800 1 - O O60 1 0.19197300 0.47944100 0.60349800 1 - O O61 1 0.02055900 0.21253200 0.12405700 1 - O O62 1 0.91152500 0.28746800 0.30802700 1 - O O63 1 0.02055900 0.30802700 0.89650200 1 - O O64 1 0.21253200 0.58847500 0.19197300 1 - O O65 1 0.58847500 0.19197300 0.21253200 1 - O O66 1 0.28746800 0.47944100 0.37594300 1 - O O67 1 0.91152500 0.12405700 0.60349800 1 - O O68 1 0.60349800 0.91152500 0.12405700 1 - O O69 1 0.89650200 0.02055900 0.30802700 1 - O O70 1 0.47944100 0.37594300 0.28746800 1 - O O71 1 0.19197300 0.21253200 0.58847500 1 - O O72 1 0.89650200 0.37594300 0.58847500 1 - O O73 1 0.37594300 0.28746800 0.47944100 1 - O O74 1 0.12405700 0.02055900 0.21253200 1 - O O75 1 0.30802700 0.89650200 0.02055900 1 - O O76 1 0.47944100 0.60349800 0.19197300 1 - O O77 1 0.28746800 0.30802700 0.91152500 1 - O O78 1 0.37594300 0.58847500 0.89650200 1 - O O79 1 0.58847500 0.89650200 0.37594300 1 -" -Cr2Fe3(SiO4)3,mp-6670,Ia-3d,"[27375, 77437]",0.046923813124999825,"{'tags': ['Triiron dichromium tris(silicate)', 'Triiron dichromium silicate']}","Full Formula (Cr8 Fe12 Si12 O48) -Reduced Formula: Cr2Fe3(SiO4)3 -abc : 10.259384 10.259384 10.259384 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Cr 0.5 0.5 0.5 2.944 - 1 Cr 0.5 0 0.5 2.944 - 2 Cr 0 0.5 0.5 2.944 - 3 Cr 0.5 0.5 0 2.944 - 4 Cr 0 0 0.5 2.944 - 5 Cr 0 0.5 0 2.944 - 6 Cr 0.5 0 0 2.944 - 7 Cr 0 0 0 2.944 - 8 Fe 0.875 0.625 0.25 3.792 - 9 Fe 0.625 0.25 0.875 3.792 - 10 Fe 0.875 0.75 0.625 3.792 - 11 Fe 0.75 0.625 0.875 3.792 - 12 Fe 0.25 0.875 0.625 3.792 - 13 Fe 0.625 0.875 0.75 3.792 - 14 Fe 0.125 0.375 0.75 3.792 - 15 Fe 0.375 0.75 0.125 3.792 - 16 Fe 0.125 0.25 0.375 3.792 - 17 Fe 0.25 0.375 0.125 3.792 - 18 Fe 0.75 0.125 0.375 3.792 - 19 Fe 0.375 0.125 0.25 3.792 - 20 Si 0.125 0.875 0.25 0.011 - 21 Si 0.875 0.125 0.75 0.011 - 22 Si 0.25 0.625 0.375 0.011 - 23 Si 0.375 0.25 0.625 0.011 - 24 Si 0.75 0.875 0.125 0.011 - 25 Si 0.125 0.75 0.875 0.011 - 26 Si 0.375 0.625 0.75 0.011 - 27 Si 0.625 0.75 0.375 0.011 - 28 Si 0.875 0.25 0.125 0.011 - 29 Si 0.25 0.125 0.875 0.011 - 30 Si 0.75 0.375 0.625 0.011 - 31 Si 0.625 0.375 0.25 0.011 - 32 O 0.6918 0.087264 0.709216 0.023 - 33 O 0.104535 0.982583 0.6918 0.023 - 34 O 0.709216 0.517417 0.621952 0.023 - 35 O 0.621952 0.709216 0.517417 0.023 - 36 O 0.878048 0.395465 0.087264 0.023 - 37 O 0.087264 0.878048 0.395465 0.023 - 38 O 0.982583 0.6918 0.104535 0.023 - 39 O 0.412736 0.104535 0.621952 0.023 - 40 O 0.395465 0.8082 0.517417 0.023 - 41 O 0.982583 0.790784 0.878048 0.023 - 42 O 0.104535 0.621952 0.412736 0.023 - 43 O 0.517417 0.395465 0.8082 0.023 - 44 O 0.790784 0.878048 0.982583 0.023 - 45 O 0.709216 0.6918 0.087264 0.023 - 46 O 0.087264 0.709216 0.6918 0.023 - 47 O 0.621952 0.412736 0.104535 0.023 - 48 O 0.790784 0.412736 0.8082 0.023 - 49 O 0.8082 0.517417 0.395465 0.023 - 50 O 0.8082 0.790784 0.412736 0.023 - 51 O 0.878048 0.982583 0.790784 0.023 - 52 O 0.412736 0.8082 0.790784 0.023 - 53 O 0.395465 0.087264 0.878048 0.023 - 54 O 0.6918 0.104535 0.982583 0.023 - 55 O 0.517417 0.621952 0.709216 0.023 - 56 O 0.3082 0.912736 0.290784 0.023 - 57 O 0.895465 0.017417 0.3082 0.023 - 58 O 0.290784 0.482583 0.378048 0.023 - 59 O 0.378048 0.290784 0.482583 0.023 - 60 O 0.121952 0.604535 0.912736 0.023 - 61 O 0.912736 0.121952 0.604535 0.023 - 62 O 0.017417 0.3082 0.895465 0.023 - 63 O 0.587264 0.895465 0.378048 0.023 - 64 O 0.604535 0.1918 0.482583 0.023 - 65 O 0.017417 0.209216 0.121952 0.023 - 66 O 0.895465 0.378048 0.587264 0.023 - 67 O 0.482583 0.604535 0.1918 0.023 - 68 O 0.209216 0.121952 0.017417 0.023 - 69 O 0.290784 0.3082 0.912736 0.023 - 70 O 0.912736 0.290784 0.3082 0.023 - 71 O 0.378048 0.587264 0.895465 0.023 - 72 O 0.209216 0.587264 0.1918 0.023 - 73 O 0.1918 0.482583 0.604535 0.023 - 74 O 0.1918 0.209216 0.587264 0.023 - 75 O 0.121952 0.017417 0.209216 0.023 - 76 O 0.587264 0.1918 0.209216 0.023 - 77 O 0.604535 0.912736 0.121952 0.023 - 78 O 0.3082 0.895465 0.017417 0.023 - 79 O 0.482583 0.378048 0.290784 0.023","# generated using pymatgen -data_Cr2Fe3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.25938380 -_cell_length_b 10.25938380 -_cell_length_c 10.25938380 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Cr2Fe3(SiO4)3 -_chemical_formula_sum 'Cr8 Fe12 Si12 O48' -_cell_volume 831.26968025 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Cr Cr0 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr1 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr2 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr3 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr4 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr5 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr6 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr7 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe8 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe9 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe10 1 0.87500000 0.75000000 0.62500000 1 - Fe Fe11 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe12 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe13 1 0.62500000 0.87500000 0.75000000 1 - Fe Fe14 1 0.12500000 0.37500000 0.75000000 1 - Fe Fe15 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe16 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe17 1 0.25000000 0.37500000 0.12500000 1 - Fe Fe18 1 0.75000000 0.12500000 0.37500000 1 - Fe Fe19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.69180000 0.08726400 0.70921600 1 - O O33 1 0.10453500 0.98258300 0.69180000 1 - O O34 1 0.70921600 0.51741700 0.62195200 1 - O O35 1 0.62195200 0.70921600 0.51741700 1 - O O36 1 0.87804800 0.39546500 0.08726400 1 - O O37 1 0.08726400 0.87804800 0.39546500 1 - O O38 1 0.98258300 0.69180000 0.10453500 1 - O O39 1 0.41273600 0.10453500 0.62195200 1 - O O40 1 0.39546500 0.80820000 0.51741700 1 - O O41 1 0.98258300 0.79078400 0.87804800 1 - O O42 1 0.10453500 0.62195200 0.41273600 1 - O O43 1 0.51741700 0.39546500 0.80820000 1 - O O44 1 0.79078400 0.87804800 0.98258300 1 - O O45 1 0.70921600 0.69180000 0.08726400 1 - O O46 1 0.08726400 0.70921600 0.69180000 1 - O O47 1 0.62195200 0.41273600 0.10453500 1 - O O48 1 0.79078400 0.41273600 0.80820000 1 - O O49 1 0.80820000 0.51741700 0.39546500 1 - O O50 1 0.80820000 0.79078400 0.41273600 1 - O O51 1 0.87804800 0.98258300 0.79078400 1 - O O52 1 0.41273600 0.80820000 0.79078400 1 - O O53 1 0.39546500 0.08726400 0.87804800 1 - O O54 1 0.69180000 0.10453500 0.98258300 1 - O O55 1 0.51741700 0.62195200 0.70921600 1 - O O56 1 0.30820000 0.91273600 0.29078400 1 - O O57 1 0.89546500 0.01741700 0.30820000 1 - O O58 1 0.29078400 0.48258300 0.37804800 1 - O O59 1 0.37804800 0.29078400 0.48258300 1 - O O60 1 0.12195200 0.60453500 0.91273600 1 - O O61 1 0.91273600 0.12195200 0.60453500 1 - O O62 1 0.01741700 0.30820000 0.89546500 1 - O O63 1 0.58726400 0.89546500 0.37804800 1 - O O64 1 0.60453500 0.19180000 0.48258300 1 - O O65 1 0.01741700 0.20921600 0.12195200 1 - O O66 1 0.89546500 0.37804800 0.58726400 1 - O O67 1 0.48258300 0.60453500 0.19180000 1 - O O68 1 0.20921600 0.12195200 0.01741700 1 - O O69 1 0.29078400 0.30820000 0.91273600 1 - O O70 1 0.91273600 0.29078400 0.30820000 1 - O O71 1 0.37804800 0.58726400 0.89546500 1 - O O72 1 0.20921600 0.58726400 0.19180000 1 - O O73 1 0.19180000 0.48258300 0.60453500 1 - O O74 1 0.19180000 0.20921600 0.58726400 1 - O O75 1 0.12195200 0.01741700 0.20921600 1 - O O76 1 0.58726400 0.19180000 0.20921600 1 - O O77 1 0.60453500 0.91273600 0.12195200 1 - O O78 1 0.30820000 0.89546500 0.01741700 1 - O O79 1 0.48258300 0.37804800 0.29078400 1 -" -Ca3Fe2(SiO4)3,mp-6672,Ia-3d,"[187907, 52393, 66667, 202965, 187913, 187914, 203209, 38115, 50627, 202961, 202963, 187912, 187909, 66670, 187915, 34845, 187910, 66668, 50628, 202962, 202960, 187918, 66671, 187916, 77431, 187919, 187911, 202964, 187917, 187908, 28271, 66669, 156530]",0.0,"{'tags': ['Tricalcium diiron(III) silicate', 'Tricalcium diiron trisilicate', 'Tricalcium diiron tris(silicate)', 'Calcium iron(III) silicate *', 'Andradite', 'Tricalcium diiron(III) tris(silicate)', 'High pressure experimental phase', 'Tricalcium iron tris(silicate)', 'Calcium diiron(III) tris(silicate)', 'Tricalcium diiron silicate']}","Full Formula (Ca12 Fe8 Si12 O48) -Reduced Formula: Ca3Fe2(SiO4)3 -abc : 10.559519 10.559519 10.559519 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0.001 - 1 Ca 0.75 0.125 0.375 0.001 - 2 Ca 0.375 0.125 0.25 0.001 - 3 Ca 0.125 0.375 0.75 0.001 - 4 Ca 0.25 0.875 0.625 0.001 - 5 Ca 0.125 0.25 0.375 0.001 - 6 Ca 0.625 0.25 0.875 0.001 - 7 Ca 0.75 0.625 0.875 0.001 - 8 Ca 0.875 0.75 0.625 0.001 - 9 Ca 0.875 0.625 0.25 0.001 - 10 Ca 0.625 0.875 0.75 0.001 - 11 Ca 0.375 0.75 0.125 0.001 - 12 Fe 0.5 0 0 4.376 - 13 Fe 0.5 0.5 0 4.376 - 14 Fe 0 0.5 0.5 4.376 - 15 Fe 0 0 0.5 4.376 - 16 Fe 0.5 0.5 0.5 4.376 - 17 Fe 0 0.5 0 4.376 - 18 Fe 0.5 0 0.5 4.376 - 19 Fe 0 0 0 4.376 - 20 Si 0.125 0.75 0.875 0.015 - 21 Si 0.875 0.25 0.125 0.015 - 22 Si 0.75 0.375 0.625 0.015 - 23 Si 0.125 0.875 0.25 0.015 - 24 Si 0.25 0.125 0.875 0.015 - 25 Si 0.375 0.625 0.75 0.015 - 26 Si 0.375 0.25 0.625 0.015 - 27 Si 0.875 0.125 0.75 0.015 - 28 Si 0.625 0.375 0.25 0.015 - 29 Si 0.75 0.875 0.125 0.015 - 30 Si 0.25 0.625 0.375 0.015 - 31 Si 0.625 0.75 0.375 0.015 - 32 O 0.587822 0.892821 0.383447 0.081 - 33 O 0.383447 0.587822 0.892821 0.081 - 34 O 0.295625 0.304999 0.912178 0.081 - 35 O 0.490626 0.607179 0.195001 0.081 - 36 O 0.304999 0.892821 0.009374 0.081 - 37 O 0.116553 0.009374 0.204375 0.081 - 38 O 0.383447 0.295625 0.490626 0.081 - 39 O 0.892821 0.383447 0.587822 0.081 - 40 O 0.195001 0.204375 0.587822 0.081 - 41 O 0.490626 0.383447 0.295625 0.081 - 42 O 0.892821 0.009374 0.304999 0.081 - 43 O 0.607179 0.912178 0.116553 0.081 - 44 O 0.912178 0.116553 0.607179 0.081 - 45 O 0.295625 0.490626 0.383447 0.081 - 46 O 0.587822 0.195001 0.204375 0.081 - 47 O 0.204375 0.587822 0.195001 0.081 - 48 O 0.009374 0.304999 0.892821 0.081 - 49 O 0.912178 0.295625 0.304999 0.081 - 50 O 0.009374 0.204375 0.116553 0.081 - 51 O 0.804999 0.795625 0.412178 0.081 - 52 O 0.195001 0.490626 0.607179 0.081 - 53 O 0.607179 0.195001 0.490626 0.081 - 54 O 0.204375 0.116553 0.009374 0.081 - 55 O 0.116553 0.607179 0.912178 0.081 - 56 O 0.412178 0.107179 0.616553 0.081 - 57 O 0.616553 0.412178 0.107179 0.081 - 58 O 0.704375 0.695001 0.087822 0.081 - 59 O 0.509374 0.392821 0.804999 0.081 - 60 O 0.695001 0.107179 0.990626 0.081 - 61 O 0.883447 0.990626 0.795625 0.081 - 62 O 0.616553 0.704375 0.509374 0.081 - 63 O 0.107179 0.616553 0.412178 0.081 - 64 O 0.883447 0.392821 0.087822 0.081 - 65 O 0.795625 0.883447 0.990626 0.081 - 66 O 0.392821 0.804999 0.509374 0.081 - 67 O 0.695001 0.087822 0.704375 0.081 - 68 O 0.804999 0.509374 0.392821 0.081 - 69 O 0.990626 0.795625 0.883447 0.081 - 70 O 0.087822 0.704375 0.695001 0.081 - 71 O 0.990626 0.695001 0.107179 0.081 - 72 O 0.795625 0.412178 0.804999 0.081 - 73 O 0.412178 0.804999 0.795625 0.081 - 74 O 0.704375 0.509374 0.616553 0.081 - 75 O 0.087822 0.883447 0.392821 0.081 - 76 O 0.392821 0.087822 0.883447 0.081 - 77 O 0.107179 0.990626 0.695001 0.081 - 78 O 0.509374 0.616553 0.704375 0.081 - 79 O 0.304999 0.912178 0.295625 0.081","# generated using pymatgen -data_Ca3Fe2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.55951876 -_cell_length_b 10.55951876 -_cell_length_c 10.55951876 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Fe2(SiO4)3 -_chemical_formula_sum 'Ca12 Fe8 Si12 O48' -_cell_volume 906.38036297 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe12 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58782200 0.89282100 0.38344700 1 - O O33 1 0.38344700 0.58782200 0.89282100 1 - O O34 1 0.29562500 0.30499900 0.91217800 1 - O O35 1 0.49062600 0.60717900 0.19500100 1 - O O36 1 0.30499900 0.89282100 0.00937400 1 - O O37 1 0.11655300 0.00937400 0.20437500 1 - O O38 1 0.38344700 0.29562500 0.49062600 1 - O O39 1 0.89282100 0.38344700 0.58782200 1 - O O40 1 0.19500100 0.20437500 0.58782200 1 - O O41 1 0.49062600 0.38344700 0.29562500 1 - O O42 1 0.89282100 0.00937400 0.30499900 1 - O O43 1 0.60717900 0.91217800 0.11655300 1 - O O44 1 0.91217800 0.11655300 0.60717900 1 - O O45 1 0.29562500 0.49062600 0.38344700 1 - O O46 1 0.58782200 0.19500100 0.20437500 1 - O O47 1 0.20437500 0.58782200 0.19500100 1 - O O48 1 0.00937400 0.30499900 0.89282100 1 - O O49 1 0.91217800 0.29562500 0.30499900 1 - O O50 1 0.00937400 0.20437500 0.11655300 1 - O O51 1 0.80499900 0.79562500 0.41217800 1 - O O52 1 0.19500100 0.49062600 0.60717900 1 - O O53 1 0.60717900 0.19500100 0.49062600 1 - O O54 1 0.20437500 0.11655300 0.00937400 1 - O O55 1 0.11655300 0.60717900 0.91217800 1 - O O56 1 0.41217800 0.10717900 0.61655300 1 - O O57 1 0.61655300 0.41217800 0.10717900 1 - O O58 1 0.70437500 0.69500100 0.08782200 1 - O O59 1 0.50937400 0.39282100 0.80499900 1 - O O60 1 0.69500100 0.10717900 0.99062600 1 - O O61 1 0.88344700 0.99062600 0.79562500 1 - O O62 1 0.61655300 0.70437500 0.50937400 1 - O O63 1 0.10717900 0.61655300 0.41217800 1 - O O64 1 0.88344700 0.39282100 0.08782200 1 - O O65 1 0.79562500 0.88344700 0.99062600 1 - O O66 1 0.39282100 0.80499900 0.50937400 1 - O O67 1 0.69500100 0.08782200 0.70437500 1 - O O68 1 0.80499900 0.50937400 0.39282100 1 - O O69 1 0.99062600 0.79562500 0.88344700 1 - O O70 1 0.08782200 0.70437500 0.69500100 1 - O O71 1 0.99062600 0.69500100 0.10717900 1 - O O72 1 0.79562500 0.41217800 0.80499900 1 - O O73 1 0.41217800 0.80499900 0.79562500 1 - O O74 1 0.70437500 0.50937400 0.61655300 1 - O O75 1 0.08782200 0.88344700 0.39282100 1 - O O76 1 0.39282100 0.08782200 0.88344700 1 - O O77 1 0.10717900 0.99062600 0.69500100 1 - O O78 1 0.50937400 0.61655300 0.70437500 1 - O O79 1 0.30499900 0.91217800 0.29562500 1 -" -Ca3Y2(GeO4)3,mp-669331,Ia-3d,[280048],0.010502482062496377,"{'tags': ['Tricalcium diyttrium trigermanium oxide', 'Unnamed_Garnet']}","Full Formula (Ca12 Y8 Ge12 O48) -Reduced Formula: Ca3Y2(GeO4)3 -abc : 11.221616 11.221616 11.221616 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.375 0.125 0.25 -0 - 1 Ca 0.625 0.25 0.875 -0 - 2 Ca 0.25 0.375 0.125 -0 - 3 Ca 0.625 0.875 0.75 -0 - 4 Ca 0.75 0.125 0.375 -0 - 5 Ca 0.125 0.25 0.375 -0 - 6 Ca 0.875 0.625 0.25 -0 - 7 Ca 0.75 0.625 0.875 -0 - 8 Ca 0.25 0.875 0.625 -0 - 9 Ca 0.875 0.75 0.625 -0 - 10 Ca 0.125 0.375 0.75 -0 - 11 Ca 0.375 0.75 0.125 -0 - 12 Y 0.5 0.5 0.5 0 - 13 Y 0 0 0.5 0 - 14 Y 0 0.5 0.5 0 - 15 Y 0.5 0 0.5 0 - 16 Y 0 0 0 0 - 17 Y 0.5 0.5 0 0 - 18 Y 0.5 0 0 0 - 19 Y 0 0.5 0 0 - 20 Ge 0.875 0.25 0.125 -0 - 21 Ge 0.75 0.875 0.125 -0 - 22 Ge 0.125 0.75 0.875 -0 - 23 Ge 0.75 0.375 0.625 -0 - 24 Ge 0.375 0.625 0.75 -0 - 25 Ge 0.25 0.625 0.375 -0 - 26 Ge 0.125 0.875 0.25 -0 - 27 Ge 0.875 0.125 0.75 -0 - 28 Ge 0.25 0.125 0.875 -0 - 29 Ge 0.625 0.75 0.375 -0 - 30 Ge 0.625 0.375 0.25 -0 - 31 Ge 0.375 0.25 0.625 -0 - 32 O 0.716999 0.696569 0.091779 0 - 33 O 0.87478 0.97957 0.783001 0 - 34 O 0.696569 0.091779 0.716999 0 - 35 O 0.908221 0.283001 0.303431 0 - 36 O 0.408221 0.10479 0.62522 0 - 37 O 0.39521 0.091779 0.87478 0 - 38 O 0.803431 0.783001 0.408221 0 - 39 O 0.02043 0.303431 0.89521 0 - 40 O 0.196569 0.216999 0.591779 0 - 41 O 0.39521 0.803431 0.52043 0 - 42 O 0.908221 0.12522 0.60479 0 - 43 O 0.303431 0.908221 0.283001 0 - 44 O 0.87478 0.39521 0.091779 0 - 45 O 0.52043 0.39521 0.803431 0 - 46 O 0.60479 0.908221 0.12522 0 - 47 O 0.52043 0.62522 0.716999 0 - 48 O 0.216999 0.591779 0.196569 0 - 49 O 0.37478 0.283001 0.47957 0 - 50 O 0.89521 0.02043 0.303431 0 - 51 O 0.37478 0.591779 0.89521 0 - 52 O 0.47957 0.37478 0.283001 0 - 53 O 0.10479 0.97957 0.696569 0 - 54 O 0.47957 0.60479 0.196569 0 - 55 O 0.408221 0.803431 0.783001 0 - 56 O 0.97957 0.783001 0.87478 0 - 57 O 0.716999 0.52043 0.62522 0 - 58 O 0.091779 0.716999 0.696569 0 - 59 O 0.196569 0.47957 0.60479 0 - 60 O 0.62522 0.408221 0.10479 0 - 61 O 0.12522 0.60479 0.908221 0 - 62 O 0.62522 0.716999 0.52043 0 - 63 O 0.803431 0.52043 0.39521 0 - 64 O 0.216999 0.12522 0.02043 0 - 65 O 0.303431 0.89521 0.02043 0 - 66 O 0.02043 0.216999 0.12522 0 - 67 O 0.783001 0.408221 0.803431 0 - 68 O 0.591779 0.89521 0.37478 0 - 69 O 0.283001 0.47957 0.37478 0 - 70 O 0.783001 0.87478 0.97957 0 - 71 O 0.696569 0.10479 0.97957 0 - 72 O 0.10479 0.62522 0.408221 0 - 73 O 0.12522 0.02043 0.216999 0 - 74 O 0.60479 0.196569 0.47957 0 - 75 O 0.091779 0.87478 0.39521 0 - 76 O 0.97957 0.696569 0.10479 0 - 77 O 0.591779 0.196569 0.216999 0 - 78 O 0.283001 0.303431 0.908221 0 - 79 O 0.89521 0.37478 0.591779 0","# generated using pymatgen -data_Ca3Y2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.22161597 -_cell_length_b 11.22161597 -_cell_length_c 11.22161597 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Y2(GeO4)3 -_chemical_formula_sum 'Ca12 Y8 Ge12 O48' -_cell_volume 1087.78812930 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca1 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca2 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca3 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca4 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca9 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Y Y12 1 0.50000000 0.50000000 0.50000000 1 - Y Y13 1 0.00000000 0.00000000 0.50000000 1 - Y Y14 1 0.00000000 0.50000000 0.50000000 1 - Y Y15 1 0.50000000 0.00000000 0.50000000 1 - Y Y16 1 0.00000000 0.00000000 0.00000000 1 - Y Y17 1 0.50000000 0.50000000 0.00000000 1 - Y Y18 1 0.50000000 0.00000000 0.00000000 1 - Y Y19 1 0.00000000 0.50000000 0.00000000 1 - Ge Ge20 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge21 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge22 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge23 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge24 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge27 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge28 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge29 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge30 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.71699900 0.69656900 0.09177900 1 - O O33 1 0.87478000 0.97957000 0.78300100 1 - O O34 1 0.69656900 0.09177900 0.71699900 1 - O O35 1 0.90822100 0.28300100 0.30343100 1 - O O36 1 0.40822100 0.10479000 0.62522000 1 - O O37 1 0.39521000 0.09177900 0.87478000 1 - O O38 1 0.80343100 0.78300100 0.40822100 1 - O O39 1 0.02043000 0.30343100 0.89521000 1 - O O40 1 0.19656900 0.21699900 0.59177900 1 - O O41 1 0.39521000 0.80343100 0.52043000 1 - O O42 1 0.90822100 0.12522000 0.60479000 1 - O O43 1 0.30343100 0.90822100 0.28300100 1 - O O44 1 0.87478000 0.39521000 0.09177900 1 - O O45 1 0.52043000 0.39521000 0.80343100 1 - O O46 1 0.60479000 0.90822100 0.12522000 1 - O O47 1 0.52043000 0.62522000 0.71699900 1 - O O48 1 0.21699900 0.59177900 0.19656900 1 - O O49 1 0.37478000 0.28300100 0.47957000 1 - O O50 1 0.89521000 0.02043000 0.30343100 1 - O O51 1 0.37478000 0.59177900 0.89521000 1 - O O52 1 0.47957000 0.37478000 0.28300100 1 - O O53 1 0.10479000 0.97957000 0.69656900 1 - O O54 1 0.47957000 0.60479000 0.19656900 1 - O O55 1 0.40822100 0.80343100 0.78300100 1 - O O56 1 0.97957000 0.78300100 0.87478000 1 - O O57 1 0.71699900 0.52043000 0.62522000 1 - O O58 1 0.09177900 0.71699900 0.69656900 1 - O O59 1 0.19656900 0.47957000 0.60479000 1 - O O60 1 0.62522000 0.40822100 0.10479000 1 - O O61 1 0.12522000 0.60479000 0.90822100 1 - O O62 1 0.62522000 0.71699900 0.52043000 1 - O O63 1 0.80343100 0.52043000 0.39521000 1 - O O64 1 0.21699900 0.12522000 0.02043000 1 - O O65 1 0.30343100 0.89521000 0.02043000 1 - O O66 1 0.02043000 0.21699900 0.12522000 1 - O O67 1 0.78300100 0.40822100 0.80343100 1 - O O68 1 0.59177900 0.89521000 0.37478000 1 - O O69 1 0.28300100 0.47957000 0.37478000 1 - O O70 1 0.78300100 0.87478000 0.97957000 1 - O O71 1 0.69656900 0.10479000 0.97957000 1 - O O72 1 0.10479000 0.62522000 0.40822100 1 - O O73 1 0.12522000 0.02043000 0.21699900 1 - O O74 1 0.60479000 0.19656900 0.47957000 1 - O O75 1 0.09177900 0.87478000 0.39521000 1 - O O76 1 0.97957000 0.69656900 0.10479000 1 - O O77 1 0.59177900 0.19656900 0.21699900 1 - O O78 1 0.28300100 0.30343100 0.90822100 1 - O O79 1 0.89521000 0.37478000 0.59177900 1 -" -Mg3Cr2(SiO4)3,mp-6700,Ia-3d,"[77432, 27371]",0.6845877004999981,"{'tags': ['Knorringite', 'Trimagnesium dichromium silicate', 'Trimagnesium dichromium tris(silicate)']}","Full Formula (Mg12 Cr8 Si12 O48) -Reduced Formula: Mg3Cr2(SiO4)3 -abc : 10.184111 10.184111 10.184111 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.75 0.125 0.375 0.003 - 1 Mg 0.25 0.375 0.125 0.003 - 2 Mg 0.125 0.25 0.375 0.003 - 3 Mg 0.375 0.75 0.125 0.003 - 4 Mg 0.75 0.625 0.875 0.003 - 5 Mg 0.125 0.375 0.75 0.003 - 6 Mg 0.625 0.875 0.75 0.003 - 7 Mg 0.25 0.875 0.625 0.003 - 8 Mg 0.875 0.625 0.25 0.003 - 9 Mg 0.625 0.25 0.875 0.003 - 10 Mg 0.875 0.75 0.625 0.003 - 11 Mg 0.375 0.125 0.25 0.003 - 12 Cr 0 0 0 2.938 - 13 Cr 0.5 0 0 2.938 - 14 Cr 0 0.5 0 2.938 - 15 Cr 0.5 0.5 0 2.938 - 16 Cr 0 0.5 0.5 2.938 - 17 Cr 0.5 0 0.5 2.938 - 18 Cr 0.5 0.5 0.5 2.938 - 19 Cr 0 0 0.5 2.938 - 20 Si 0.125 0.875 0.25 0.007 - 21 Si 0.875 0.125 0.75 0.007 - 22 Si 0.25 0.625 0.375 0.007 - 23 Si 0.375 0.25 0.625 0.007 - 24 Si 0.75 0.875 0.125 0.007 - 25 Si 0.125 0.75 0.875 0.007 - 26 Si 0.375 0.625 0.75 0.007 - 27 Si 0.625 0.75 0.375 0.007 - 28 Si 0.875 0.25 0.125 0.007 - 29 Si 0.25 0.125 0.875 0.007 - 30 Si 0.75 0.375 0.625 0.007 - 31 Si 0.625 0.375 0.25 0.007 - 32 O 0.479743 0.376115 0.288572 -0.006 - 33 O 0.30883 0.896373 0.020257 -0.006 - 34 O 0.603627 0.912457 0.123885 -0.006 - 35 O 0.587543 0.19117 0.211428 -0.006 - 36 O 0.123885 0.020257 0.211428 -0.006 - 37 O 0.19117 0.211428 0.587543 -0.006 - 38 O 0.19117 0.479743 0.603627 -0.006 - 39 O 0.211428 0.587543 0.19117 -0.006 - 40 O 0.376115 0.587543 0.896373 -0.006 - 41 O 0.912457 0.288572 0.30883 -0.006 - 42 O 0.288572 0.30883 0.912457 -0.006 - 43 O 0.211428 0.123885 0.020257 -0.006 - 44 O 0.479743 0.603627 0.19117 -0.006 - 45 O 0.896373 0.376115 0.587543 -0.006 - 46 O 0.020257 0.211428 0.123885 -0.006 - 47 O 0.603627 0.19117 0.479743 -0.006 - 48 O 0.587543 0.896373 0.376115 -0.006 - 49 O 0.020257 0.30883 0.896373 -0.006 - 50 O 0.912457 0.123885 0.603627 -0.006 - 51 O 0.623885 0.412457 0.103627 -0.006 - 52 O 0.123885 0.603627 0.912457 -0.006 - 53 O 0.288572 0.479743 0.376115 -0.006 - 54 O 0.896373 0.020257 0.30883 -0.006 - 55 O 0.30883 0.912457 0.288572 -0.006 - 56 O 0.520257 0.623885 0.711428 -0.006 - 57 O 0.69117 0.103627 0.979743 -0.006 - 58 O 0.396373 0.087543 0.876115 -0.006 - 59 O 0.412457 0.80883 0.788572 -0.006 - 60 O 0.876115 0.979743 0.788572 -0.006 - 61 O 0.80883 0.788572 0.412457 -0.006 - 62 O 0.80883 0.520257 0.396373 -0.006 - 63 O 0.788572 0.412457 0.80883 -0.006 - 64 O 0.69117 0.087543 0.711428 -0.006 - 65 O 0.103627 0.979743 0.69117 -0.006 - 66 O 0.711428 0.520257 0.623885 -0.006 - 67 O 0.623885 0.711428 0.520257 -0.006 - 68 O 0.876115 0.396373 0.087543 -0.006 - 69 O 0.087543 0.876115 0.396373 -0.006 - 70 O 0.979743 0.69117 0.103627 -0.006 - 71 O 0.412457 0.103627 0.623885 -0.006 - 72 O 0.396373 0.80883 0.520257 -0.006 - 73 O 0.979743 0.788572 0.876115 -0.006 - 74 O 0.103627 0.623885 0.412457 -0.006 - 75 O 0.520257 0.396373 0.80883 -0.006 - 76 O 0.788572 0.876115 0.979743 -0.006 - 77 O 0.711428 0.69117 0.087543 -0.006 - 78 O 0.087543 0.711428 0.69117 -0.006 - 79 O 0.376115 0.288572 0.479743 -0.006","# generated using pymatgen -data_Mg3Cr2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.18411061 -_cell_length_b 10.18411061 -_cell_length_c 10.18411061 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Cr2(SiO4)3 -_chemical_formula_sum 'Mg12 Cr8 Si12 O48' -_cell_volume 813.10649740 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg1 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg2 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg3 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg4 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg5 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg6 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg7 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg8 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg9 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg10 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg11 1 0.37500000 0.12500000 0.25000000 1 - Cr Cr12 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr13 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr15 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr16 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr17 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr18 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.50000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.87500000 0.12500000 0.75000000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.37500000 0.25000000 0.62500000 1 - Si Si24 1 0.75000000 0.87500000 0.12500000 1 - Si Si25 1 0.12500000 0.75000000 0.87500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.62500000 0.75000000 0.37500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.25000000 0.12500000 0.87500000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.47974300 0.37611500 0.28857200 1 - O O33 1 0.30883000 0.89637300 0.02025700 1 - O O34 1 0.60362700 0.91245700 0.12388500 1 - O O35 1 0.58754300 0.19117000 0.21142800 1 - O O36 1 0.12388500 0.02025700 0.21142800 1 - O O37 1 0.19117000 0.21142800 0.58754300 1 - O O38 1 0.19117000 0.47974300 0.60362700 1 - O O39 1 0.21142800 0.58754300 0.19117000 1 - O O40 1 0.37611500 0.58754300 0.89637300 1 - O O41 1 0.91245700 0.28857200 0.30883000 1 - O O42 1 0.28857200 0.30883000 0.91245700 1 - O O43 1 0.21142800 0.12388500 0.02025700 1 - O O44 1 0.47974300 0.60362700 0.19117000 1 - O O45 1 0.89637300 0.37611500 0.58754300 1 - O O46 1 0.02025700 0.21142800 0.12388500 1 - O O47 1 0.60362700 0.19117000 0.47974300 1 - O O48 1 0.58754300 0.89637300 0.37611500 1 - O O49 1 0.02025700 0.30883000 0.89637300 1 - O O50 1 0.91245700 0.12388500 0.60362700 1 - O O51 1 0.62388500 0.41245700 0.10362700 1 - O O52 1 0.12388500 0.60362700 0.91245700 1 - O O53 1 0.28857200 0.47974300 0.37611500 1 - O O54 1 0.89637300 0.02025700 0.30883000 1 - O O55 1 0.30883000 0.91245700 0.28857200 1 - O O56 1 0.52025700 0.62388500 0.71142800 1 - O O57 1 0.69117000 0.10362700 0.97974300 1 - O O58 1 0.39637300 0.08754300 0.87611500 1 - O O59 1 0.41245700 0.80883000 0.78857200 1 - O O60 1 0.87611500 0.97974300 0.78857200 1 - O O61 1 0.80883000 0.78857200 0.41245700 1 - O O62 1 0.80883000 0.52025700 0.39637300 1 - O O63 1 0.78857200 0.41245700 0.80883000 1 - O O64 1 0.69117000 0.08754300 0.71142800 1 - O O65 1 0.10362700 0.97974300 0.69117000 1 - O O66 1 0.71142800 0.52025700 0.62388500 1 - O O67 1 0.62388500 0.71142800 0.52025700 1 - O O68 1 0.87611500 0.39637300 0.08754300 1 - O O69 1 0.08754300 0.87611500 0.39637300 1 - O O70 1 0.97974300 0.69117000 0.10362700 1 - O O71 1 0.41245700 0.10362700 0.62388500 1 - O O72 1 0.39637300 0.80883000 0.52025700 1 - O O73 1 0.97974300 0.78857200 0.87611500 1 - O O74 1 0.10362700 0.62388500 0.41245700 1 - O O75 1 0.52025700 0.39637300 0.80883000 1 - O O76 1 0.78857200 0.87611500 0.97974300 1 - O O77 1 0.71142800 0.69117000 0.08754300 1 - O O78 1 0.08754300 0.71142800 0.69117000 1 - O O79 1 0.37611500 0.28857200 0.47974300 1 -" -Na3Li3Al2F12,mp-6711,Ia-3d,"[9923, 30253, 31110]",0.0,"{'tags': ['Trisodium trilithium hexafluoroaluminate', 'Cryolithionite', 'Trilithium trisodium dialuminium fluoride']}","Full Formula (Na12 Li12 Al8 F48) -Reduced Formula: Na3Li3Al2F12 -abc : 10.668387 10.668387 10.668387 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Na 0.875 0.75 0.625 0 - 1 Na 0.625 0.25 0.875 0 - 2 Na 0.25 0.875 0.625 0 - 3 Na 0.875 0.625 0.25 0 - 4 Na 0.625 0.875 0.75 0 - 5 Na 0.75 0.625 0.875 0 - 6 Na 0.125 0.25 0.375 0 - 7 Na 0.375 0.75 0.125 0 - 8 Na 0.75 0.125 0.375 0 - 9 Na 0.125 0.375 0.75 0 - 10 Na 0.25 0.375 0.125 0 - 11 Na 0.375 0.125 0.25 0 - 12 Li 0.625 0.375 0.25 0 - 13 Li 0.25 0.125 0.875 -0 - 14 Li 0.75 0.875 0.125 -0 - 15 Li 0.125 0.75 0.875 -0 - 16 Li 0.375 0.25 0.625 -0 - 17 Li 0.875 0.125 0.75 0 - 18 Li 0.875 0.25 0.125 -0 - 19 Li 0.625 0.75 0.375 0 - 20 Li 0.75 0.375 0.625 -0 - 21 Li 0.375 0.625 0.75 0 - 22 Li 0.125 0.875 0.25 0 - 23 Li 0.25 0.625 0.375 -0 - 24 Al 0.5 0.5 0.5 -0 - 25 Al 0.5 0 0.5 -0 - 26 Al 0 0.5 0.5 -0 - 27 Al 0.5 0.5 0 -0 - 28 Al 0 0 0.5 -0 - 29 Al 0 0.5 0 -0 - 30 Al 0.5 0 0 -0 - 31 Al 0 0 0 -0 - 32 F 0.48595 0.388709 0.317454 0 - 33 F 0.902759 0.388709 0.571255 0 - 34 F 0.01405 0.182546 0.111291 0 - 35 F 0.597241 0.168496 0.48595 0 - 36 F 0.571255 0.902759 0.388709 0 - 37 F 0.01405 0.331504 0.902759 0 - 38 F 0.928745 0.111291 0.597241 0 - 39 F 0.388709 0.317454 0.48595 0 - 40 F 0.182546 0.111291 0.01405 0 - 41 F 0.317454 0.331504 0.928745 0 - 42 F 0.928745 0.317454 0.331504 0 - 43 F 0.388709 0.571255 0.902759 0 - 44 F 0.182546 0.571255 0.168496 0 - 45 F 0.168496 0.48595 0.597241 0 - 46 F 0.168496 0.182546 0.571255 0 - 47 F 0.111291 0.01405 0.182546 0 - 48 F 0.571255 0.168496 0.182546 0 - 49 F 0.48595 0.597241 0.168496 0 - 50 F 0.597241 0.928745 0.111291 0 - 51 F 0.331504 0.902759 0.01405 0 - 52 F 0.668496 0.071255 0.682546 0 - 53 F 0.097241 0.98595 0.668496 0 - 54 F 0.682546 0.51405 0.611291 0 - 55 F 0.611291 0.682546 0.51405 0 - 56 F 0.888709 0.402759 0.071255 0 - 57 F 0.071255 0.888709 0.402759 0 - 58 F 0.98595 0.668496 0.097241 0 - 59 F 0.428745 0.097241 0.611291 0 - 60 F 0.402759 0.831504 0.51405 0 - 61 F 0.98595 0.817454 0.888709 0 - 62 F 0.097241 0.611291 0.428745 0 - 63 F 0.51405 0.402759 0.831504 0 - 64 F 0.817454 0.888709 0.98595 0 - 65 F 0.682546 0.668496 0.071255 0 - 66 F 0.071255 0.682546 0.668496 0 - 67 F 0.611291 0.428745 0.097241 0 - 68 F 0.817454 0.428745 0.831504 0 - 69 F 0.831504 0.51405 0.402759 0 - 70 F 0.831504 0.817454 0.428745 0 - 71 F 0.888709 0.98595 0.817454 0 - 72 F 0.428745 0.831504 0.817454 0 - 73 F 0.402759 0.071255 0.888709 0 - 74 F 0.668496 0.097241 0.98595 0 - 75 F 0.51405 0.611291 0.682546 0 - 76 F 0.331504 0.928745 0.317454 0 - 77 F 0.902759 0.01405 0.331504 0 - 78 F 0.317454 0.48595 0.388709 0 - 79 F 0.111291 0.597241 0.928745 0","# generated using pymatgen -data_Na3Li3Al2F12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.66838682 -_cell_length_b 10.66838682 -_cell_length_c 10.66838682 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Na3Li3Al2F12 -_chemical_formula_sum 'Na12 Li12 Al8 F48' -_cell_volume 934.70458126 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Na Na0 1 0.87500000 0.75000000 0.62500000 1 - Na Na1 1 0.62500000 0.25000000 0.87500000 1 - Na Na2 1 0.25000000 0.87500000 0.62500000 1 - Na Na3 1 0.87500000 0.62500000 0.25000000 1 - Na Na4 1 0.62500000 0.87500000 0.75000000 1 - Na Na5 1 0.75000000 0.62500000 0.87500000 1 - Na Na6 1 0.12500000 0.25000000 0.37500000 1 - Na Na7 1 0.37500000 0.75000000 0.12500000 1 - Na Na8 1 0.75000000 0.12500000 0.37500000 1 - Na Na9 1 0.12500000 0.37500000 0.75000000 1 - Na Na10 1 0.25000000 0.37500000 0.12500000 1 - Na Na11 1 0.37500000 0.12500000 0.25000000 1 - Li Li12 1 0.62500000 0.37500000 0.25000000 1 - Li Li13 1 0.25000000 0.12500000 0.87500000 1 - Li Li14 1 0.75000000 0.87500000 0.12500000 1 - Li Li15 1 0.12500000 0.75000000 0.87500000 1 - Li Li16 1 0.37500000 0.25000000 0.62500000 1 - Li Li17 1 0.87500000 0.12500000 0.75000000 1 - Li Li18 1 0.87500000 0.25000000 0.12500000 1 - Li Li19 1 0.62500000 0.75000000 0.37500000 1 - Li Li20 1 0.75000000 0.37500000 0.62500000 1 - Li Li21 1 0.37500000 0.62500000 0.75000000 1 - Li Li22 1 0.12500000 0.87500000 0.25000000 1 - Li Li23 1 0.25000000 0.62500000 0.37500000 1 - Al Al24 1 0.50000000 0.50000000 0.50000000 1 - Al Al25 1 0.50000000 0.00000000 0.50000000 1 - Al Al26 1 0.00000000 0.50000000 0.50000000 1 - Al Al27 1 0.50000000 0.50000000 0.00000000 1 - Al Al28 1 0.00000000 0.00000000 0.50000000 1 - Al Al29 1 0.00000000 0.50000000 0.00000000 1 - Al Al30 1 0.50000000 0.00000000 0.00000000 1 - Al Al31 1 0.00000000 0.00000000 0.00000000 1 - F F32 1 0.48595000 0.38870900 0.31745400 1 - F F33 1 0.90275900 0.38870900 0.57125500 1 - F F34 1 0.01405000 0.18254600 0.11129100 1 - F F35 1 0.59724100 0.16849600 0.48595000 1 - F F36 1 0.57125500 0.90275900 0.38870900 1 - F F37 1 0.01405000 0.33150400 0.90275900 1 - F F38 1 0.92874500 0.11129100 0.59724100 1 - F F39 1 0.38870900 0.31745400 0.48595000 1 - F F40 1 0.18254600 0.11129100 0.01405000 1 - F F41 1 0.31745400 0.33150400 0.92874500 1 - F F42 1 0.92874500 0.31745400 0.33150400 1 - F F43 1 0.38870900 0.57125500 0.90275900 1 - F F44 1 0.18254600 0.57125500 0.16849600 1 - F F45 1 0.16849600 0.48595000 0.59724100 1 - F F46 1 0.16849600 0.18254600 0.57125500 1 - F F47 1 0.11129100 0.01405000 0.18254600 1 - F F48 1 0.57125500 0.16849600 0.18254600 1 - F F49 1 0.48595000 0.59724100 0.16849600 1 - F F50 1 0.59724100 0.92874500 0.11129100 1 - F F51 1 0.33150400 0.90275900 0.01405000 1 - F F52 1 0.66849600 0.07125500 0.68254600 1 - F F53 1 0.09724100 0.98595000 0.66849600 1 - F F54 1 0.68254600 0.51405000 0.61129100 1 - F F55 1 0.61129100 0.68254600 0.51405000 1 - F F56 1 0.88870900 0.40275900 0.07125500 1 - F F57 1 0.07125500 0.88870900 0.40275900 1 - F F58 1 0.98595000 0.66849600 0.09724100 1 - F F59 1 0.42874500 0.09724100 0.61129100 1 - F F60 1 0.40275900 0.83150400 0.51405000 1 - F F61 1 0.98595000 0.81745400 0.88870900 1 - F F62 1 0.09724100 0.61129100 0.42874500 1 - F F63 1 0.51405000 0.40275900 0.83150400 1 - F F64 1 0.81745400 0.88870900 0.98595000 1 - F F65 1 0.68254600 0.66849600 0.07125500 1 - F F66 1 0.07125500 0.68254600 0.66849600 1 - F F67 1 0.61129100 0.42874500 0.09724100 1 - F F68 1 0.81745400 0.42874500 0.83150400 1 - F F69 1 0.83150400 0.51405000 0.40275900 1 - F F70 1 0.83150400 0.81745400 0.42874500 1 - F F71 1 0.88870900 0.98595000 0.81745400 1 - F F72 1 0.42874500 0.83150400 0.81745400 1 - F F73 1 0.40275900 0.07125500 0.88870900 1 - F F74 1 0.66849600 0.09724100 0.98595000 1 - F F75 1 0.51405000 0.61129100 0.68254600 1 - F F76 1 0.33150400 0.92874500 0.31745400 1 - F F77 1 0.90275900 0.01405000 0.33150400 1 - F F78 1 0.31745400 0.48595000 0.38870900 1 - F F79 1 0.11129100 0.59724100 0.92874500 1 -" -Li3Nd3(TeO6)2,mp-677627,Ia-3d,[],0.0,{'tags': []},"Full Formula (Li12 Nd12 Te8 O48) -Reduced Formula: Li3Nd3(TeO6)2 -abc : 11.005193 11.005193 11.005193 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.875 0.125 -0 - 1 Li 0.875 0.25 0.125 -0 - 2 Li 0.625 0.375 0.25 -0 - 3 Li 0.125 0.875 0.25 -0 - 4 Li 0.625 0.75 0.375 -0 - 5 Li 0.25 0.625 0.375 -0 - 6 Li 0.75 0.375 0.625 -0 - 7 Li 0.375 0.25 0.625 -0 - 8 Li 0.875 0.125 0.75 -0 - 9 Li 0.375 0.625 0.75 -0 - 10 Li 0.125 0.75 0.875 -0 - 11 Li 0.25 0.125 0.875 -0 - 12 Nd 0.125 0.375 0.75 -0 - 13 Nd 0.875 0.75 0.625 -0 - 14 Nd 0.625 0.25 0.875 -0 - 15 Nd 0.25 0.375 0.125 -0 - 16 Nd 0.625 0.875 0.75 -0 - 17 Nd 0.25 0.875 0.625 0 - 18 Nd 0.75 0.125 0.375 0 - 19 Nd 0.375 0.125 0.25 -0 - 20 Nd 0.75 0.625 0.875 -0 - 21 Nd 0.375 0.75 0.125 -0 - 22 Nd 0.125 0.25 0.375 -0 - 23 Nd 0.875 0.625 0.25 -0 - 24 Te 0.5 0.5 0 0 - 25 Te 0.5 0 0 0 - 26 Te 0 0.5 0 0 - 27 Te 0 0 0 0 - 28 Te 0.5 0.5 0.5 0 - 29 Te 0 0.5 0.5 0 - 30 Te 0.5 0 0.5 0 - 31 Te 0 0 0.5 0 - 32 O 0.076295 0.883052 0.406129 -0 - 33 O 0.093871 0.616948 0.423705 -0 - 34 O 0.829834 0.806757 0.423705 -0 - 35 O 0.383052 0.576295 0.906129 -0 - 36 O 0.829834 0.523077 0.406129 -0 - 37 O 0.093871 0.976923 0.670166 -0 - 38 O 0.116948 0.593871 0.923705 -0 - 39 O 0.306757 0.329834 0.923705 -0 - 40 O 0.076295 0.693243 0.670166 -0 - 41 O 0.616948 0.693243 0.523077 -0 - 42 O 0.670166 0.076295 0.693243 -0 - 43 O 0.423705 0.093871 0.616948 -0 - 44 O 0.406129 0.829834 0.523077 -0 - 45 O 0.023077 0.329834 0.906129 -0 - 46 O 0.476923 0.593871 0.170166 -0 - 47 O 0.883052 0.976923 0.806757 -0 - 48 O 0.693243 0.523077 0.616948 -0 - 49 O 0.193243 0.576295 0.170166 -0 - 50 O 0.193243 0.116948 0.023077 -0 - 51 O 0.576295 0.170166 0.193243 -0 - 52 O 0.593871 0.923705 0.116948 -0 - 53 O 0.329834 0.906129 0.023077 -0 - 54 O 0.976923 0.806757 0.883052 -0 - 55 O 0.523077 0.616948 0.693243 -0 - 56 O 0.476923 0.383052 0.306757 -0 - 57 O 0.023077 0.193243 0.116948 -0 - 58 O 0.670166 0.093871 0.976923 -0 - 59 O 0.406129 0.076295 0.883052 -0 - 60 O 0.423705 0.829834 0.806757 -0 - 61 O 0.806757 0.883052 0.976923 -0 - 62 O 0.806757 0.423705 0.829834 -0 - 63 O 0.306757 0.476923 0.383052 -0 - 64 O 0.116948 0.023077 0.193243 -0 - 65 O 0.523077 0.406129 0.829834 -0 - 66 O 0.976923 0.670166 0.093871 -0 - 67 O 0.593871 0.170166 0.476923 -0 - 68 O 0.576295 0.906129 0.383052 -0 - 69 O 0.329834 0.923705 0.306757 -0 - 70 O 0.383052 0.306757 0.476923 -0 - 71 O 0.923705 0.306757 0.329834 -0 - 72 O 0.693243 0.670166 0.076295 -0 - 73 O 0.883052 0.406129 0.076295 -0 - 74 O 0.906129 0.023077 0.329834 -0 - 75 O 0.170166 0.476923 0.593871 -0 - 76 O 0.616948 0.423705 0.093871 -0 - 77 O 0.170166 0.193243 0.576295 -0 - 78 O 0.906129 0.383052 0.576295 -0 - 79 O 0.923705 0.116948 0.593871 -0","# generated using pymatgen -data_Li3Nd3(TeO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.00519276 -_cell_length_b 11.00519276 -_cell_length_c 11.00519276 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Nd3(TeO6)2 -_chemical_formula_sum 'Li12 Nd12 Te8 O48' -_cell_volume 1026.05601366 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.87500000 0.12500000 1 - Li Li1 1 0.87500000 0.25000000 0.12500000 1 - Li Li2 1 0.62500000 0.37500000 0.25000000 1 - Li Li3 1 0.12500000 0.87500000 0.25000000 1 - Li Li4 1 0.62500000 0.75000000 0.37500000 1 - Li Li5 1 0.25000000 0.62500000 0.37500000 1 - Li Li6 1 0.75000000 0.37500000 0.62500000 1 - Li Li7 1 0.37500000 0.25000000 0.62500000 1 - Li Li8 1 0.87500000 0.12500000 0.75000000 1 - Li Li9 1 0.37500000 0.62500000 0.75000000 1 - Li Li10 1 0.12500000 0.75000000 0.87500000 1 - Li Li11 1 0.25000000 0.12500000 0.87500000 1 - Nd Nd12 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd13 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd14 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd15 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd16 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd17 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd18 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd19 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd20 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd21 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd22 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd23 1 0.87500000 0.62500000 0.25000000 1 - Te Te24 1 0.50000000 0.50000000 0.00000000 1 - Te Te25 1 0.50000000 0.00000000 0.00000000 1 - Te Te26 1 0.00000000 0.50000000 0.00000000 1 - Te Te27 1 0.00000000 0.00000000 0.00000000 1 - Te Te28 1 0.50000000 0.50000000 0.50000000 1 - Te Te29 1 0.00000000 0.50000000 0.50000000 1 - Te Te30 1 0.50000000 0.00000000 0.50000000 1 - Te Te31 1 0.00000000 0.00000000 0.50000000 1 - O O32 1 0.07629500 0.88305200 0.40612900 1 - O O33 1 0.09387100 0.61694800 0.42370500 1 - O O34 1 0.82983400 0.80675700 0.42370500 1 - O O35 1 0.38305200 0.57629500 0.90612900 1 - O O36 1 0.82983400 0.52307700 0.40612900 1 - O O37 1 0.09387100 0.97692300 0.67016600 1 - O O38 1 0.11694800 0.59387100 0.92370500 1 - O O39 1 0.30675700 0.32983400 0.92370500 1 - O O40 1 0.07629500 0.69324300 0.67016600 1 - O O41 1 0.61694800 0.69324300 0.52307700 1 - O O42 1 0.67016600 0.07629500 0.69324300 1 - O O43 1 0.42370500 0.09387100 0.61694800 1 - O O44 1 0.40612900 0.82983400 0.52307700 1 - O O45 1 0.02307700 0.32983400 0.90612900 1 - O O46 1 0.47692300 0.59387100 0.17016600 1 - O O47 1 0.88305200 0.97692300 0.80675700 1 - O O48 1 0.69324300 0.52307700 0.61694800 1 - O O49 1 0.19324300 0.57629500 0.17016600 1 - O O50 1 0.19324300 0.11694800 0.02307700 1 - O O51 1 0.57629500 0.17016600 0.19324300 1 - O O52 1 0.59387100 0.92370500 0.11694800 1 - O O53 1 0.32983400 0.90612900 0.02307700 1 - O O54 1 0.97692300 0.80675700 0.88305200 1 - O O55 1 0.52307700 0.61694800 0.69324300 1 - O O56 1 0.47692300 0.38305200 0.30675700 1 - O O57 1 0.02307700 0.19324300 0.11694800 1 - O O58 1 0.67016600 0.09387100 0.97692300 1 - O O59 1 0.40612900 0.07629500 0.88305200 1 - O O60 1 0.42370500 0.82983400 0.80675700 1 - O O61 1 0.80675700 0.88305200 0.97692300 1 - O O62 1 0.80675700 0.42370500 0.82983400 1 - O O63 1 0.30675700 0.47692300 0.38305200 1 - O O64 1 0.11694800 0.02307700 0.19324300 1 - O O65 1 0.52307700 0.40612900 0.82983400 1 - O O66 1 0.97692300 0.67016600 0.09387100 1 - O O67 1 0.59387100 0.17016600 0.47692300 1 - O O68 1 0.57629500 0.90612900 0.38305200 1 - O O69 1 0.32983400 0.92370500 0.30675700 1 - O O70 1 0.38305200 0.30675700 0.47692300 1 - O O71 1 0.92370500 0.30675700 0.32983400 1 - O O72 1 0.69324300 0.67016600 0.07629500 1 - O O73 1 0.88305200 0.40612900 0.07629500 1 - O O74 1 0.90612900 0.02307700 0.32983400 1 - O O75 1 0.17016600 0.47692300 0.59387100 1 - O O76 1 0.61694800 0.42370500 0.09387100 1 - O O77 1 0.17016600 0.19324300 0.57629500 1 - O O78 1 0.90612900 0.38305200 0.57629500 1 - O O79 1 0.92370500 0.11694800 0.59387100 1 -" -Ca3Mn2(GeO4)3,mp-744259,I4_1/a,[89835],0.0,"{'tags': ['Tricalcium dimanganese(III) trigermanium oxide', 'Unnamed_Garnet']}","Full Formula (Ca12 Mn8 Ge12 O48) -Reduced Formula: Ca3Mn2(GeO4)3 -abc : 10.808302 10.808302 10.808302 -angles: 109.547787 109.547787 109.318197 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.499435 0.876902 0.127069 0.002 - 1 Ca 0.250565 0.373098 0.372931 0.002 - 2 Ca 0.497956 0.997956 0.5 0.002 - 3 Ca 0.747956 0.747956 0 0.002 - 4 Ca 0.002044 0.502044 0.5 0.002 - 5 Ca 0.000167 0.877634 0.627069 0.002 - 6 Ca 0.626902 0.999833 0.877467 0.002 - 7 Ca 0.122366 0.749435 0.122533 0.002 - 8 Ca 0.123098 0.250167 0.622533 0.002 - 9 Ca 0.749833 0.372366 0.872931 0.002 - 10 Ca 0.252044 0.252044 0 0.002 - 11 Ca 0.627634 0.500565 0.377467 0.002 - 12 Mn 0.375 0.625 0.25 3.881 - 13 Mn 0.875 0.125 0.25 3.883 - 14 Mn 0.875 0.625 0.25 3.881 - 15 Mn 0.375 0.125 0.75 3.881 - 16 Mn 0.375 0.625 0.75 3.881 - 17 Mn 0.875 0.125 0.75 3.883 - 18 Mn 0.875 0.625 0.75 3.883 - 19 Mn 0.375 0.125 0.25 3.883 - 20 Ge 0.743386 0.871136 0.377649 0.019 - 21 Ge 0.621136 0.743487 0.62775 0.019 - 22 Ge 0.006614 0.378864 0.122351 0.019 - 23 Ge 0 0 0 0.018 - 24 Ge 0.5 0.5 0 0.017 - 25 Ge 0.493487 0.365737 0.622351 0.019 - 26 Ge 0.75 0.25 0.5 0.018 - 27 Ge 0.128864 0.506513 0.87225 0.019 - 28 Ge 0.25 0.75 0.5 0.017 - 29 Ge 0.256513 0.884263 0.877649 0.019 - 30 Ge 0.634263 0.256614 0.12775 0.019 - 31 Ge 0.115737 0.993386 0.37225 0.019 - 32 O 0.066863 0.135174 0.358683 -0.032 - 33 O 0.593548 0.21337 0.941762 0.035 - 34 O 0.78663 0.728392 0.380178 0.035 - 35 O 0.271608 0.651786 0.058238 0.035 - 36 O 0.749282 0.914092 0.234826 0.02 - 37 O 0.29182 0.933137 0.068311 -0.032 - 38 O 0.689789 0.541161 0.051212 -0.017 - 39 O 0.458839 0.510051 0.148627 -0.017 - 40 O 0.260051 0.611423 0.551212 -0.017 - 41 O 0.291161 0.739949 0.351373 -0.017 - 42 O 0.26123 0.032943 0.835151 -0.023 - 43 O 0.188864 0.144677 0.148693 -0.005 - 44 O 0.973509 0.54182 0.858683 -0.032 - 45 O 0.489949 0.638577 0.948788 -0.017 - 46 O 0.790171 0.438864 0.544187 -0.005 - 47 O 0.96337 0.521608 0.119822 0.035 - 48 O 0.070734 0.735545 0.734826 0.02 - 49 O 0.561136 0.105323 0.351307 -0.005 - 50 O 0.085908 0.320734 0.835189 0.02 - 51 O 0.894677 0.245984 0.455813 -0.005 - 52 O 0.060211 0.708839 0.448788 -0.017 - 53 O 0.967057 0.802208 0.228287 -0.023 - 54 O 0.45818 0.316863 0.431689 -0.032 - 55 O 0.959829 0.811136 0.955813 -0.005 - 56 O 0.683137 0.114826 0.141317 -0.032 - 57 O 0.48877 0.217057 0.664849 -0.023 - 58 O 0.176079 0.51123 0.728287 -0.023 - 59 O 0.388577 0.939789 0.648627 -0.017 - 60 O 0.401786 0.843548 0.880178 0.035 - 61 O 0.995984 0.040171 0.851307 -0.005 - 62 O 0.664092 0.929266 0.664811 0.02 - 63 O 0.782943 0.447792 0.271713 -0.023 - 64 O 0.552208 0.823921 0.335151 -0.023 - 65 O 0.264455 0.999282 0.335189 0.02 - 66 O 0.885174 0.026491 0.568311 -0.032 - 67 O 0.864826 0.223509 0.931689 -0.032 - 68 O 0.776491 0.70818 0.641317 -0.032 - 69 O 0.156452 0.03663 0.558238 0.035 - 70 O 0.855323 0.004016 0.044187 -0.005 - 71 O 0.485545 0.250718 0.164811 0.02 - 72 O 0.000718 0.335908 0.265174 0.02 - 73 O 0.361423 0.310211 0.851373 -0.017 - 74 O 0.348214 0.406452 0.619822 0.035 - 75 O 0.197792 0.426079 0.164849 -0.023 - 76 O 0.754016 0.209829 0.648693 -0.005 - 77 O 0.679266 0.514455 0.765174 0.02 - 78 O 0.478392 0.598214 0.441762 0.035 - 79 O 0.573921 0.73877 0.771713 -0.023","# generated using pymatgen -data_Ca3Mn2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80830170 -_cell_length_b 10.80830170 -_cell_length_c 10.80830170 -_cell_angle_alpha 109.54778654 -_cell_angle_beta 109.54778654 -_cell_angle_gamma 109.31819710 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Mn2(GeO4)3 -_chemical_formula_sum 'Ca12 Mn8 Ge12 O48' -_cell_volume 971.95948839 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.49943500 0.87690200 0.12706900 1 - Ca Ca1 1 0.25056500 0.37309800 0.37293100 1 - Ca Ca2 1 0.49795600 0.99795600 0.50000000 1 - Ca Ca3 1 0.74795600 0.74795600 0.00000000 1 - Ca Ca4 1 0.00204400 0.50204400 0.50000000 1 - Ca Ca5 1 0.00016700 0.87763400 0.62706900 1 - Ca Ca6 1 0.62690200 0.99983300 0.87746700 1 - Ca Ca7 1 0.12236600 0.74943500 0.12253300 1 - Ca Ca8 1 0.12309800 0.25016700 0.62253300 1 - Ca Ca9 1 0.74983300 0.37236600 0.87293100 1 - Ca Ca10 1 0.25204400 0.25204400 0.00000000 1 - Ca Ca11 1 0.62763400 0.50056500 0.37746700 1 - Mn Mn12 1 0.37500000 0.62500000 0.25000000 1 - Mn Mn13 1 0.87500000 0.12500000 0.25000000 1 - Mn Mn14 1 0.87500000 0.62500000 0.25000000 1 - Mn Mn15 1 0.37500000 0.12500000 0.75000000 1 - Mn Mn16 1 0.37500000 0.62500000 0.75000000 1 - Mn Mn17 1 0.87500000 0.12500000 0.75000000 1 - Mn Mn18 1 0.87500000 0.62500000 0.75000000 1 - Mn Mn19 1 0.37500000 0.12500000 0.25000000 1 - Ge Ge20 1 0.74338600 0.87113600 0.37764900 1 - Ge Ge21 1 0.62113600 0.74348700 0.62775000 1 - Ge Ge22 1 0.00661400 0.37886400 0.12235100 1 - Ge Ge23 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge24 1 0.50000000 0.50000000 0.00000000 1 - Ge Ge25 1 0.49348700 0.36573700 0.62235100 1 - Ge Ge26 1 0.75000000 0.25000000 0.50000000 1 - Ge Ge27 1 0.12886400 0.50651300 0.87225000 1 - Ge Ge28 1 0.25000000 0.75000000 0.50000000 1 - Ge Ge29 1 0.25651300 0.88426300 0.87764900 1 - Ge Ge30 1 0.63426300 0.25661400 0.12775000 1 - Ge Ge31 1 0.11573700 0.99338600 0.37225000 1 - O O32 1 0.06686300 0.13517400 0.35868300 1 - O O33 1 0.59354800 0.21337000 0.94176200 1 - O O34 1 0.78663000 0.72839200 0.38017800 1 - O O35 1 0.27160800 0.65178600 0.05823800 1 - O O36 1 0.74928200 0.91409200 0.23482600 1 - O O37 1 0.29182000 0.93313700 0.06831100 1 - O O38 1 0.68978900 0.54116100 0.05121200 1 - O O39 1 0.45883900 0.51005100 0.14862700 1 - O O40 1 0.26005100 0.61142300 0.55121200 1 - O O41 1 0.29116100 0.73994900 0.35137300 1 - O O42 1 0.26123000 0.03294300 0.83515100 1 - O O43 1 0.18886400 0.14467700 0.14869300 1 - O O44 1 0.97350900 0.54182000 0.85868300 1 - O O45 1 0.48994900 0.63857700 0.94878800 1 - O O46 1 0.79017100 0.43886400 0.54418700 1 - O O47 1 0.96337000 0.52160800 0.11982200 1 - O O48 1 0.07073400 0.73554500 0.73482600 1 - O O49 1 0.56113600 0.10532300 0.35130700 1 - O O50 1 0.08590800 0.32073400 0.83518900 1 - O O51 1 0.89467700 0.24598400 0.45581300 1 - O O52 1 0.06021100 0.70883900 0.44878800 1 - O O53 1 0.96705700 0.80220800 0.22828700 1 - O O54 1 0.45818000 0.31686300 0.43168900 1 - O O55 1 0.95982900 0.81113600 0.95581300 1 - O O56 1 0.68313700 0.11482600 0.14131700 1 - O O57 1 0.48877000 0.21705700 0.66484900 1 - O O58 1 0.17607900 0.51123000 0.72828700 1 - O O59 1 0.38857700 0.93978900 0.64862700 1 - O O60 1 0.40178600 0.84354800 0.88017800 1 - O O61 1 0.99598400 0.04017100 0.85130700 1 - O O62 1 0.66409200 0.92926600 0.66481100 1 - O O63 1 0.78294300 0.44779200 0.27171300 1 - O O64 1 0.55220800 0.82392100 0.33515100 1 - O O65 1 0.26445500 0.99928200 0.33518900 1 - O O66 1 0.88517400 0.02649100 0.56831100 1 - O O67 1 0.86482600 0.22350900 0.93168900 1 - O O68 1 0.77649100 0.70818000 0.64131700 1 - O O69 1 0.15645200 0.03663000 0.55823800 1 - O O70 1 0.85532300 0.00401600 0.04418700 1 - O O71 1 0.48554500 0.25071800 0.16481100 1 - O O72 1 0.00071800 0.33590800 0.26517400 1 - O O73 1 0.36142300 0.31021100 0.85137300 1 - O O74 1 0.34821400 0.40645200 0.61982200 1 - O O75 1 0.19779200 0.42607900 0.16484900 1 - O O76 1 0.75401600 0.20982900 0.64869300 1 - O O77 1 0.67926600 0.51445500 0.76517400 1 - O O78 1 0.47839200 0.59821400 0.44176200 1 - O O79 1 0.57392100 0.73877000 0.77171300 1 -" -Li3V2(PO4)3,mp-756749,Ia-3d,[],0.046621961375000076,{'tags': []},"Full Formula (Li12 V8 P12 O48) -Reduced Formula: Li3V2(PO4)3 -abc : 10.246922 10.246922 10.246922 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.125 0.375 -0 - 1 Li 0.875 0.625 0.25 -0 - 2 Li 0.375 0.125 0.25 -0 - 3 Li 0.25 0.375 0.125 -0 - 4 Li 0.375 0.75 0.125 -0 - 5 Li 0.125 0.25 0.375 -0 - 6 Li 0.625 0.25 0.875 -0 - 7 Li 0.875 0.75 0.625 -0 - 8 Li 0.75 0.625 0.875 -0 - 9 Li 0.125 0.375 0.75 -0 - 10 Li 0.625 0.875 0.75 -0 - 11 Li 0.25 0.875 0.625 -0 - 12 V 0.5 0 0 1.887 - 13 V 0 0 0 1.89 - 14 V 0.5 0.5 0 1.887 - 15 V 0.5 0 0.5 1.887 - 16 V 0 0.5 0 1.887 - 17 V 0 0 0.5 1.887 - 18 V 0.5 0.5 0.5 1.89 - 19 V 0 0.5 0.5 1.887 - 20 P 0.875 0.25 0.125 0.008 - 21 P 0.625 0.375 0.25 0.008 - 22 P 0.875 0.125 0.75 0.008 - 23 P 0.75 0.875 0.125 0.006 - 24 P 0.75 0.375 0.625 0.006 - 25 P 0.625 0.75 0.375 0.008 - 26 P 0.375 0.25 0.625 0.008 - 27 P 0.25 0.625 0.375 0.006 - 28 P 0.25 0.125 0.875 0.006 - 29 P 0.375 0.625 0.75 0.008 - 30 P 0.125 0.875 0.25 0.008 - 31 P 0.125 0.75 0.875 0.008 - 32 O 0.888875 0.005439 0.298253 -0.006 - 33 O 0.883435 0.388875 0.090622 -0.005 - 34 O 0.909378 0.292813 0.298253 0.003 - 35 O 0.909378 0.116565 0.611125 -0.006 - 36 O 0.590622 0.201747 0.207187 0.003 - 37 O 0.994561 0.701747 0.111125 -0.006 - 38 O 0.616565 0.409378 0.111125 -0.005 - 39 O 0.207187 0.116565 0.005439 0.004 - 40 O 0.888875 0.383435 0.590622 -0.005 - 41 O 0.611125 0.201747 0.494561 -0.006 - 42 O 0.707187 0.701747 0.090622 0.004 - 43 O 0.798253 0.505439 0.388875 -0.006 - 44 O 0.701747 0.090622 0.707187 0.003 - 45 O 0.116565 0.005439 0.207187 -0.004 - 46 O 0.494561 0.383435 0.292813 -0.005 - 47 O 0.494561 0.611125 0.201747 -0.006 - 48 O 0.005439 0.207187 0.116565 -0.005 - 49 O 0.409378 0.111125 0.616565 -0.006 - 50 O 0.383435 0.292813 0.494561 -0.004 - 51 O 0.798253 0.792813 0.409378 0.003 - 52 O 0.701747 0.111125 0.994561 -0.006 - 53 O 0.707187 0.505439 0.616565 0.004 - 54 O 0.792813 0.409378 0.798253 0.004 - 55 O 0.611125 0.909378 0.116565 -0.006 - 56 O 0.292813 0.494561 0.383435 0.004 - 57 O 0.207187 0.590622 0.201747 0.004 - 58 O 0.388875 0.090622 0.883435 -0.006 - 59 O 0.298253 0.888875 0.005439 -0.006 - 60 O 0.616565 0.707187 0.505439 -0.004 - 61 O 0.201747 0.207187 0.590622 0.003 - 62 O 0.505439 0.388875 0.798253 -0.006 - 63 O 0.590622 0.888875 0.383435 -0.006 - 64 O 0.994561 0.792813 0.883435 -0.005 - 65 O 0.505439 0.616565 0.707187 -0.005 - 66 O 0.883435 0.994561 0.792813 -0.004 - 67 O 0.201747 0.494561 0.611125 -0.006 - 68 O 0.298253 0.909378 0.292813 0.003 - 69 O 0.292813 0.298253 0.909378 0.004 - 70 O 0.111125 0.616565 0.409378 -0.005 - 71 O 0.388875 0.798253 0.505439 -0.006 - 72 O 0.792813 0.883435 0.994561 0.004 - 73 O 0.383435 0.590622 0.888875 -0.005 - 74 O 0.090622 0.883435 0.388875 -0.006 - 75 O 0.005439 0.298253 0.888875 -0.006 - 76 O 0.409378 0.798253 0.792813 0.003 - 77 O 0.090622 0.707187 0.701747 0.003 - 78 O 0.116565 0.611125 0.909378 -0.005 - 79 O 0.111125 0.994561 0.701747 -0.006","# generated using pymatgen -data_Li3V2(PO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.24692170 -_cell_length_b 10.24692170 -_cell_length_c 10.24692170 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3V2(PO4)3 -_chemical_formula_sum 'Li12 V8 P12 O48' -_cell_volume 828.24412075 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.12500000 0.37500000 1 - Li Li1 1 0.87500000 0.62500000 0.25000000 1 - Li Li2 1 0.37500000 0.12500000 0.25000000 1 - Li Li3 1 0.25000000 0.37500000 0.12500000 1 - Li Li4 1 0.37500000 0.75000000 0.12500000 1 - Li Li5 1 0.12500000 0.25000000 0.37500000 1 - Li Li6 1 0.62500000 0.25000000 0.87500000 1 - Li Li7 1 0.87500000 0.75000000 0.62500000 1 - Li Li8 1 0.75000000 0.62500000 0.87500000 1 - Li Li9 1 0.12500000 0.37500000 0.75000000 1 - Li Li10 1 0.62500000 0.87500000 0.75000000 1 - Li Li11 1 0.25000000 0.87500000 0.62500000 1 - V V12 1 0.50000000 0.00000000 0.00000000 1 - V V13 1 0.00000000 0.00000000 0.00000000 1 - V V14 1 0.50000000 0.50000000 0.00000000 1 - V V15 1 0.50000000 0.00000000 0.50000000 1 - V V16 1 0.00000000 0.50000000 0.00000000 1 - V V17 1 0.00000000 0.00000000 0.50000000 1 - V V18 1 0.50000000 0.50000000 0.50000000 1 - V V19 1 0.00000000 0.50000000 0.50000000 1 - P P20 1 0.87500000 0.25000000 0.12500000 1 - P P21 1 0.62500000 0.37500000 0.25000000 1 - P P22 1 0.87500000 0.12500000 0.75000000 1 - P P23 1 0.75000000 0.87500000 0.12500000 1 - P P24 1 0.75000000 0.37500000 0.62500000 1 - P P25 1 0.62500000 0.75000000 0.37500000 1 - P P26 1 0.37500000 0.25000000 0.62500000 1 - P P27 1 0.25000000 0.62500000 0.37500000 1 - P P28 1 0.25000000 0.12500000 0.87500000 1 - P P29 1 0.37500000 0.62500000 0.75000000 1 - P P30 1 0.12500000 0.87500000 0.25000000 1 - P P31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.88887500 0.00543900 0.29825300 1 - O O33 1 0.88343500 0.38887500 0.09062200 1 - O O34 1 0.90937800 0.29281300 0.29825300 1 - O O35 1 0.90937800 0.11656500 0.61112500 1 - O O36 1 0.59062200 0.20174700 0.20718700 1 - O O37 1 0.99456100 0.70174700 0.11112500 1 - O O38 1 0.61656500 0.40937800 0.11112500 1 - O O39 1 0.20718700 0.11656500 0.00543900 1 - O O40 1 0.88887500 0.38343500 0.59062200 1 - O O41 1 0.61112500 0.20174700 0.49456100 1 - O O42 1 0.70718700 0.70174700 0.09062200 1 - O O43 1 0.79825300 0.50543900 0.38887500 1 - O O44 1 0.70174700 0.09062200 0.70718700 1 - O O45 1 0.11656500 0.00543900 0.20718700 1 - O O46 1 0.49456100 0.38343500 0.29281300 1 - O O47 1 0.49456100 0.61112500 0.20174700 1 - O O48 1 0.00543900 0.20718700 0.11656500 1 - O O49 1 0.40937800 0.11112500 0.61656500 1 - O O50 1 0.38343500 0.29281300 0.49456100 1 - O O51 1 0.79825300 0.79281300 0.40937800 1 - O O52 1 0.70174700 0.11112500 0.99456100 1 - O O53 1 0.70718700 0.50543900 0.61656500 1 - O O54 1 0.79281300 0.40937800 0.79825300 1 - O O55 1 0.61112500 0.90937800 0.11656500 1 - O O56 1 0.29281300 0.49456100 0.38343500 1 - O O57 1 0.20718700 0.59062200 0.20174700 1 - O O58 1 0.38887500 0.09062200 0.88343500 1 - O O59 1 0.29825300 0.88887500 0.00543900 1 - O O60 1 0.61656500 0.70718700 0.50543900 1 - O O61 1 0.20174700 0.20718700 0.59062200 1 - O O62 1 0.50543900 0.38887500 0.79825300 1 - O O63 1 0.59062200 0.88887500 0.38343500 1 - O O64 1 0.99456100 0.79281300 0.88343500 1 - O O65 1 0.50543900 0.61656500 0.70718700 1 - O O66 1 0.88343500 0.99456100 0.79281300 1 - O O67 1 0.20174700 0.49456100 0.61112500 1 - O O68 1 0.29825300 0.90937800 0.29281300 1 - O O69 1 0.29281300 0.29825300 0.90937800 1 - O O70 1 0.11112500 0.61656500 0.40937800 1 - O O71 1 0.38887500 0.79825300 0.50543900 1 - O O72 1 0.79281300 0.88343500 0.99456100 1 - O O73 1 0.38343500 0.59062200 0.88887500 1 - O O74 1 0.09062200 0.88343500 0.38887500 1 - O O75 1 0.00543900 0.29825300 0.88887500 1 - O O76 1 0.40937800 0.79825300 0.79281300 1 - O O77 1 0.09062200 0.70718700 0.70174700 1 - O O78 1 0.11656500 0.61112500 0.90937800 1 - O O79 1 0.11112500 0.99456100 0.70174700 1 -" -Li3Ti2(PO4)3,mp-757914,Ia-3d,[],0.09890983765278527,{'tags': []},"Full Formula (Li12 Ti8 P12 O48) -Reduced Formula: Li3Ti2(PO4)3 -abc : 10.325399 10.325399 10.325399 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.125 0.375 -0 - 1 Li 0.875 0.625 0.25 -0 - 2 Li 0.375 0.125 0.25 -0 - 3 Li 0.25 0.375 0.125 -0 - 4 Li 0.875 0.75 0.625 -0 - 5 Li 0.375 0.75 0.125 -0 - 6 Li 0.625 0.25 0.875 -0 - 7 Li 0.125 0.25 0.375 -0 - 8 Li 0.75 0.625 0.875 -0 - 9 Li 0.125 0.375 0.75 -0 - 10 Li 0.625 0.875 0.75 -0 - 11 Li 0.25 0.875 0.625 -0 - 12 Ti 0.5 0 0 0.889 - 13 Ti 0 0 0 0.887 - 14 Ti 0.5 0 0.5 0.889 - 15 Ti 0.5 0.5 0 0.887 - 16 Ti 0.5 0.5 0.5 0.887 - 17 Ti 0 0.5 0 0.887 - 18 Ti 0 0 0.5 0.888 - 19 Ti 0 0.5 0.5 0.888 - 20 P 0.875 0.25 0.125 0.013 - 21 P 0.625 0.375 0.25 0.013 - 22 P 0.875 0.125 0.75 0.013 - 23 P 0.75 0.875 0.125 0.013 - 24 P 0.75 0.375 0.625 0.013 - 25 P 0.625 0.75 0.375 0.013 - 26 P 0.375 0.25 0.625 0.013 - 27 P 0.25 0.625 0.375 0.013 - 28 P 0.25 0.125 0.875 0.013 - 29 P 0.125 0.875 0.25 0.013 - 30 P 0.375 0.625 0.75 0.013 - 31 P 0.125 0.75 0.875 0.013 - 32 O 0.886904 0.003028 0.297754 -0.003 - 33 O 0.883876 0.386904 0.08915 -0.003 - 34 O 0.91085 0.294726 0.297754 -0.003 - 35 O 0.91085 0.116124 0.613096 -0.003 - 36 O 0.996972 0.702246 0.113096 -0.002 - 37 O 0.58915 0.202246 0.205274 -0.002 - 38 O 0.616124 0.41085 0.113096 -0.003 - 39 O 0.205274 0.116124 0.003028 -0.003 - 40 O 0.705274 0.702246 0.08915 -0.002 - 41 O 0.886904 0.383876 0.58915 -0.003 - 42 O 0.613096 0.202246 0.496972 -0.002 - 43 O 0.702246 0.08915 0.705274 -0.002 - 44 O 0.116124 0.003028 0.205274 -0.003 - 45 O 0.797754 0.503028 0.386904 -0.002 - 46 O 0.496972 0.383876 0.294726 -0.003 - 47 O 0.496972 0.613096 0.202246 -0.003 - 48 O 0.41085 0.113096 0.616124 -0.002 - 49 O 0.003028 0.205274 0.116124 -0.002 - 50 O 0.702246 0.113096 0.996972 -0.002 - 51 O 0.383876 0.294726 0.496972 -0.003 - 52 O 0.797754 0.794726 0.41085 -0.002 - 53 O 0.705274 0.503028 0.616124 -0.002 - 54 O 0.613096 0.91085 0.116124 -0.002 - 55 O 0.794726 0.41085 0.797754 -0.003 - 56 O 0.386904 0.08915 0.883876 -0.002 - 57 O 0.205274 0.58915 0.202246 -0.003 - 58 O 0.294726 0.496972 0.383876 -0.002 - 59 O 0.202246 0.205274 0.58915 -0.002 - 60 O 0.297754 0.886904 0.003028 -0.002 - 61 O 0.616124 0.705274 0.503028 -0.003 - 62 O 0.58915 0.886904 0.383876 -0.002 - 63 O 0.996972 0.794726 0.883876 -0.002 - 64 O 0.503028 0.386904 0.797754 -0.003 - 65 O 0.503028 0.616124 0.705274 -0.003 - 66 O 0.883876 0.996972 0.794726 -0.003 - 67 O 0.297754 0.91085 0.294726 -0.002 - 68 O 0.202246 0.496972 0.613096 -0.002 - 69 O 0.113096 0.616124 0.41085 -0.003 - 70 O 0.386904 0.797754 0.503028 -0.002 - 71 O 0.294726 0.297754 0.91085 -0.002 - 72 O 0.794726 0.883876 0.996972 -0.003 - 73 O 0.383876 0.58915 0.886904 -0.003 - 74 O 0.08915 0.883876 0.386904 -0.003 - 75 O 0.41085 0.797754 0.794726 -0.002 - 76 O 0.003028 0.297754 0.886904 -0.002 - 77 O 0.08915 0.705274 0.702246 -0.003 - 78 O 0.116124 0.613096 0.91085 -0.003 - 79 O 0.113096 0.996972 0.702246 -0.003","# generated using pymatgen -data_Li3Ti2(PO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.32539919 -_cell_length_b 10.32539919 -_cell_length_c 10.32539919 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Ti2(PO4)3 -_chemical_formula_sum 'Li12 Ti8 P12 O48' -_cell_volume 847.41990626 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.12500000 0.37500000 1 - Li Li1 1 0.87500000 0.62500000 0.25000000 1 - Li Li2 1 0.37500000 0.12500000 0.25000000 1 - Li Li3 1 0.25000000 0.37500000 0.12500000 1 - Li Li4 1 0.87500000 0.75000000 0.62500000 1 - Li Li5 1 0.37500000 0.75000000 0.12500000 1 - Li Li6 1 0.62500000 0.25000000 0.87500000 1 - Li Li7 1 0.12500000 0.25000000 0.37500000 1 - Li Li8 1 0.75000000 0.62500000 0.87500000 1 - Li Li9 1 0.12500000 0.37500000 0.75000000 1 - Li Li10 1 0.62500000 0.87500000 0.75000000 1 - Li Li11 1 0.25000000 0.87500000 0.62500000 1 - Ti Ti12 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti13 1 0.00000000 0.00000000 0.00000000 1 - Ti Ti14 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti15 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti16 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti17 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti18 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti19 1 0.00000000 0.50000000 0.50000000 1 - P P20 1 0.87500000 0.25000000 0.12500000 1 - P P21 1 0.62500000 0.37500000 0.25000000 1 - P P22 1 0.87500000 0.12500000 0.75000000 1 - P P23 1 0.75000000 0.87500000 0.12500000 1 - P P24 1 0.75000000 0.37500000 0.62500000 1 - P P25 1 0.62500000 0.75000000 0.37500000 1 - P P26 1 0.37500000 0.25000000 0.62500000 1 - P P27 1 0.25000000 0.62500000 0.37500000 1 - P P28 1 0.25000000 0.12500000 0.87500000 1 - P P29 1 0.12500000 0.87500000 0.25000000 1 - P P30 1 0.37500000 0.62500000 0.75000000 1 - P P31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.88690400 0.00302800 0.29775400 1 - O O33 1 0.88387600 0.38690400 0.08915000 1 - O O34 1 0.91085000 0.29472600 0.29775400 1 - O O35 1 0.91085000 0.11612400 0.61309600 1 - O O36 1 0.99697200 0.70224600 0.11309600 1 - O O37 1 0.58915000 0.20224600 0.20527400 1 - O O38 1 0.61612400 0.41085000 0.11309600 1 - O O39 1 0.20527400 0.11612400 0.00302800 1 - O O40 1 0.70527400 0.70224600 0.08915000 1 - O O41 1 0.88690400 0.38387600 0.58915000 1 - O O42 1 0.61309600 0.20224600 0.49697200 1 - O O43 1 0.70224600 0.08915000 0.70527400 1 - O O44 1 0.11612400 0.00302800 0.20527400 1 - O O45 1 0.79775400 0.50302800 0.38690400 1 - O O46 1 0.49697200 0.38387600 0.29472600 1 - O O47 1 0.49697200 0.61309600 0.20224600 1 - O O48 1 0.41085000 0.11309600 0.61612400 1 - O O49 1 0.00302800 0.20527400 0.11612400 1 - O O50 1 0.70224600 0.11309600 0.99697200 1 - O O51 1 0.38387600 0.29472600 0.49697200 1 - O O52 1 0.79775400 0.79472600 0.41085000 1 - O O53 1 0.70527400 0.50302800 0.61612400 1 - O O54 1 0.61309600 0.91085000 0.11612400 1 - O O55 1 0.79472600 0.41085000 0.79775400 1 - O O56 1 0.38690400 0.08915000 0.88387600 1 - O O57 1 0.20527400 0.58915000 0.20224600 1 - O O58 1 0.29472600 0.49697200 0.38387600 1 - O O59 1 0.20224600 0.20527400 0.58915000 1 - O O60 1 0.29775400 0.88690400 0.00302800 1 - O O61 1 0.61612400 0.70527400 0.50302800 1 - O O62 1 0.58915000 0.88690400 0.38387600 1 - O O63 1 0.99697200 0.79472600 0.88387600 1 - O O64 1 0.50302800 0.38690400 0.79775400 1 - O O65 1 0.50302800 0.61612400 0.70527400 1 - O O66 1 0.88387600 0.99697200 0.79472600 1 - O O67 1 0.29775400 0.91085000 0.29472600 1 - O O68 1 0.20224600 0.49697200 0.61309600 1 - O O69 1 0.11309600 0.61612400 0.41085000 1 - O O70 1 0.38690400 0.79775400 0.50302800 1 - O O71 1 0.29472600 0.29775400 0.91085000 1 - O O72 1 0.79472600 0.88387600 0.99697200 1 - O O73 1 0.38387600 0.58915000 0.88690400 1 - O O74 1 0.08915000 0.88387600 0.38690400 1 - O O75 1 0.41085000 0.79775400 0.79472600 1 - O O76 1 0.00302800 0.29775400 0.88690400 1 - O O77 1 0.08915000 0.70527400 0.70224600 1 - O O78 1 0.11612400 0.61309600 0.91085000 1 - O O79 1 0.11309600 0.99697200 0.70224600 1 -" -Li3Fe2(PO4)3,mp-765598,Ia-3d,[],0.04843130162500042,{'tags': []},"Full Formula (Li12 Fe8 P12 O48) -Reduced Formula: Li3Fe2(PO4)3 -abc : 10.195670 10.195670 10.195670 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.125 0.375 0.001 - 1 Li 0.375 0.125 0.25 0.001 - 2 Li 0.875 0.625 0.25 0.001 - 3 Li 0.25 0.375 0.125 0.001 - 4 Li 0.375 0.75 0.125 0.001 - 5 Li 0.625 0.25 0.875 0.001 - 6 Li 0.125 0.25 0.375 0.001 - 7 Li 0.875 0.75 0.625 0.001 - 8 Li 0.75 0.625 0.875 0.001 - 9 Li 0.625 0.875 0.75 0.001 - 10 Li 0.125 0.375 0.75 0.001 - 11 Li 0.25 0.875 0.625 0.001 - 12 Fe 0.5 0 0 4.386 - 13 Fe 0 0 0 4.386 - 14 Fe 0.5 0.5 0 4.386 - 15 Fe 0.5 0 0.5 4.386 - 16 Fe 0 0.5 0 4.386 - 17 Fe 0 0 0.5 4.386 - 18 Fe 0.5 0.5 0.5 4.386 - 19 Fe 0 0.5 0.5 4.386 - 20 P 0.875 0.25 0.125 0.015 - 21 P 0.625 0.375 0.25 0.015 - 22 P 0.875 0.125 0.75 0.015 - 23 P 0.75 0.875 0.125 0.015 - 24 P 0.75 0.375 0.625 0.015 - 25 P 0.625 0.75 0.375 0.015 - 26 P 0.375 0.25 0.625 0.015 - 27 P 0.25 0.625 0.375 0.015 - 28 P 0.25 0.125 0.875 0.015 - 29 P 0.125 0.875 0.25 0.015 - 30 P 0.375 0.625 0.75 0.015 - 31 P 0.125 0.75 0.875 0.015 - 32 O 0.89015 0.006823 0.299051 0.08 - 33 O 0.883327 0.39015 0.091099 0.08 - 34 O 0.908901 0.292228 0.299051 0.08 - 35 O 0.908901 0.116673 0.60985 0.08 - 36 O 0.993177 0.700949 0.10985 0.08 - 37 O 0.591099 0.200949 0.207772 0.08 - 38 O 0.616673 0.408901 0.10985 0.08 - 39 O 0.207772 0.116673 0.006823 0.08 - 40 O 0.89015 0.383327 0.591099 0.08 - 41 O 0.60985 0.200949 0.493177 0.08 - 42 O 0.707772 0.700949 0.091099 0.08 - 43 O 0.799051 0.506823 0.39015 0.08 - 44 O 0.116673 0.006823 0.207772 0.08 - 45 O 0.700949 0.091099 0.707772 0.08 - 46 O 0.493177 0.383327 0.292228 0.08 - 47 O 0.006823 0.207772 0.116673 0.08 - 48 O 0.493177 0.60985 0.200949 0.08 - 49 O 0.408901 0.10985 0.616673 0.08 - 50 O 0.383327 0.292228 0.493177 0.08 - 51 O 0.799051 0.792228 0.408901 0.08 - 52 O 0.700949 0.10985 0.993177 0.08 - 53 O 0.707772 0.506823 0.616673 0.08 - 54 O 0.792228 0.408901 0.799051 0.08 - 55 O 0.60985 0.908901 0.116673 0.08 - 56 O 0.292228 0.493177 0.383327 0.08 - 57 O 0.207772 0.591099 0.200949 0.08 - 58 O 0.39015 0.091099 0.883327 0.08 - 59 O 0.616673 0.707772 0.506823 0.08 - 60 O 0.299051 0.89015 0.006823 0.08 - 61 O 0.200949 0.207772 0.591099 0.08 - 62 O 0.591099 0.89015 0.383327 0.08 - 63 O 0.506823 0.39015 0.799051 0.08 - 64 O 0.993177 0.792228 0.883327 0.08 - 65 O 0.506823 0.616673 0.707772 0.08 - 66 O 0.883327 0.993177 0.792228 0.08 - 67 O 0.200949 0.493177 0.60985 0.08 - 68 O 0.299051 0.908901 0.292228 0.08 - 69 O 0.10985 0.616673 0.408901 0.08 - 70 O 0.292228 0.299051 0.908901 0.08 - 71 O 0.39015 0.799051 0.506823 0.08 - 72 O 0.792228 0.883327 0.993177 0.08 - 73 O 0.383327 0.591099 0.89015 0.08 - 74 O 0.006823 0.299051 0.89015 0.08 - 75 O 0.091099 0.883327 0.39015 0.08 - 76 O 0.408901 0.799051 0.792228 0.08 - 77 O 0.091099 0.707772 0.700949 0.08 - 78 O 0.116673 0.60985 0.908901 0.08 - 79 O 0.10985 0.993177 0.700949 0.08","# generated using pymatgen -data_Li3Fe2(PO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.19567031 -_cell_length_b 10.19567031 -_cell_length_c 10.19567031 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Fe2(PO4)3 -_chemical_formula_sum 'Li12 Fe8 P12 O48' -_cell_volume 815.87844662 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.12500000 0.37500000 1 - Li Li1 1 0.37500000 0.12500000 0.25000000 1 - Li Li2 1 0.87500000 0.62500000 0.25000000 1 - Li Li3 1 0.25000000 0.37500000 0.12500000 1 - Li Li4 1 0.37500000 0.75000000 0.12500000 1 - Li Li5 1 0.62500000 0.25000000 0.87500000 1 - Li Li6 1 0.12500000 0.25000000 0.37500000 1 - Li Li7 1 0.87500000 0.75000000 0.62500000 1 - Li Li8 1 0.75000000 0.62500000 0.87500000 1 - Li Li9 1 0.62500000 0.87500000 0.75000000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe12 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe14 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe15 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe18 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.50000000 0.50000000 1 - P P20 1 0.87500000 0.25000000 0.12500000 1 - P P21 1 0.62500000 0.37500000 0.25000000 1 - P P22 1 0.87500000 0.12500000 0.75000000 1 - P P23 1 0.75000000 0.87500000 0.12500000 1 - P P24 1 0.75000000 0.37500000 0.62500000 1 - P P25 1 0.62500000 0.75000000 0.37500000 1 - P P26 1 0.37500000 0.25000000 0.62500000 1 - P P27 1 0.25000000 0.62500000 0.37500000 1 - P P28 1 0.25000000 0.12500000 0.87500000 1 - P P29 1 0.12500000 0.87500000 0.25000000 1 - P P30 1 0.37500000 0.62500000 0.75000000 1 - P P31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.89015000 0.00682300 0.29905100 1 - O O33 1 0.88332700 0.39015000 0.09109900 1 - O O34 1 0.90890100 0.29222800 0.29905100 1 - O O35 1 0.90890100 0.11667300 0.60985000 1 - O O36 1 0.99317700 0.70094900 0.10985000 1 - O O37 1 0.59109900 0.20094900 0.20777200 1 - O O38 1 0.61667300 0.40890100 0.10985000 1 - O O39 1 0.20777200 0.11667300 0.00682300 1 - O O40 1 0.89015000 0.38332700 0.59109900 1 - O O41 1 0.60985000 0.20094900 0.49317700 1 - O O42 1 0.70777200 0.70094900 0.09109900 1 - O O43 1 0.79905100 0.50682300 0.39015000 1 - O O44 1 0.11667300 0.00682300 0.20777200 1 - O O45 1 0.70094900 0.09109900 0.70777200 1 - O O46 1 0.49317700 0.38332700 0.29222800 1 - O O47 1 0.00682300 0.20777200 0.11667300 1 - O O48 1 0.49317700 0.60985000 0.20094900 1 - O O49 1 0.40890100 0.10985000 0.61667300 1 - O O50 1 0.38332700 0.29222800 0.49317700 1 - O O51 1 0.79905100 0.79222800 0.40890100 1 - O O52 1 0.70094900 0.10985000 0.99317700 1 - O O53 1 0.70777200 0.50682300 0.61667300 1 - O O54 1 0.79222800 0.40890100 0.79905100 1 - O O55 1 0.60985000 0.90890100 0.11667300 1 - O O56 1 0.29222800 0.49317700 0.38332700 1 - O O57 1 0.20777200 0.59109900 0.20094900 1 - O O58 1 0.39015000 0.09109900 0.88332700 1 - O O59 1 0.61667300 0.70777200 0.50682300 1 - O O60 1 0.29905100 0.89015000 0.00682300 1 - O O61 1 0.20094900 0.20777200 0.59109900 1 - O O62 1 0.59109900 0.89015000 0.38332700 1 - O O63 1 0.50682300 0.39015000 0.79905100 1 - O O64 1 0.99317700 0.79222800 0.88332700 1 - O O65 1 0.50682300 0.61667300 0.70777200 1 - O O66 1 0.88332700 0.99317700 0.79222800 1 - O O67 1 0.20094900 0.49317700 0.60985000 1 - O O68 1 0.29905100 0.90890100 0.29222800 1 - O O69 1 0.10985000 0.61667300 0.40890100 1 - O O70 1 0.29222800 0.29905100 0.90890100 1 - O O71 1 0.39015000 0.79905100 0.50682300 1 - O O72 1 0.79222800 0.88332700 0.99317700 1 - O O73 1 0.38332700 0.59109900 0.89015000 1 - O O74 1 0.00682300 0.29905100 0.89015000 1 - O O75 1 0.09109900 0.88332700 0.39015000 1 - O O76 1 0.40890100 0.79905100 0.79222800 1 - O O77 1 0.09109900 0.70777200 0.70094900 1 - O O78 1 0.11667300 0.60985000 0.90890100 1 - O O79 1 0.10985000 0.99317700 0.70094900 1 -" -Li3Cr2(AsO4)3,mp-779404,Ia-3d,[],0.013870571708330282,{'tags': []},"Full Formula (Li12 Cr8 As12 O48) -Reduced Formula: Li3Cr2(AsO4)3 -abc : 10.510529 10.510529 10.510529 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.125 0.375 0.001 - 1 Li 0.875 0.625 0.25 0.001 - 2 Li 0.375 0.125 0.25 0.001 - 3 Li 0.25 0.375 0.125 0.001 - 4 Li 0.875 0.75 0.625 0.001 - 5 Li 0.375 0.75 0.125 0.001 - 6 Li 0.125 0.25 0.375 0.001 - 7 Li 0.625 0.25 0.875 0.001 - 8 Li 0.75 0.625 0.875 0.001 - 9 Li 0.625 0.875 0.75 0.001 - 10 Li 0.125 0.375 0.75 0.001 - 11 Li 0.25 0.875 0.625 0.001 - 12 Cr 0.5 0 0 2.933 - 13 Cr 0 0 0 2.934 - 14 Cr 0.5 0 0.5 2.933 - 15 Cr 0.5 0.5 0 2.934 - 16 Cr 0.5 0.5 0.5 2.934 - 17 Cr 0 0.5 0 2.934 - 18 Cr 0 0 0.5 2.933 - 19 Cr 0 0.5 0.5 2.933 - 20 As 0.875 0.25 0.125 0.014 - 21 As 0.625 0.375 0.25 0.014 - 22 As 0.875 0.125 0.75 0.014 - 23 As 0.75 0.375 0.625 0.014 - 24 As 0.75 0.875 0.125 0.014 - 25 As 0.625 0.75 0.375 0.014 - 26 As 0.375 0.25 0.625 0.014 - 27 As 0.25 0.625 0.375 0.014 - 28 As 0.25 0.125 0.875 0.014 - 29 As 0.125 0.875 0.25 0.014 - 30 As 0.375 0.625 0.75 0.014 - 31 As 0.125 0.75 0.875 0.014 - 32 O 0.897189 0.017501 0.312558 -0.008 - 33 O 0.879688 0.397189 0.084631 -0.008 - 34 O 0.915369 0.295057 0.312558 -0.008 - 35 O 0.915369 0.120312 0.602811 -0.008 - 36 O 0.584631 0.187442 0.204943 -0.007 - 37 O 0.982499 0.687442 0.102811 -0.007 - 38 O 0.620312 0.415369 0.102811 -0.008 - 39 O 0.204943 0.120312 0.017501 -0.007 - 40 O 0.704943 0.687442 0.084631 -0.007 - 41 O 0.602811 0.187442 0.482499 -0.007 - 42 O 0.897189 0.379688 0.584631 -0.008 - 43 O 0.687442 0.084631 0.704943 -0.007 - 44 O 0.120312 0.017501 0.204943 -0.008 - 45 O 0.812558 0.517501 0.397189 -0.007 - 46 O 0.482499 0.379688 0.295057 -0.008 - 47 O 0.482499 0.602811 0.187442 -0.008 - 48 O 0.017501 0.204943 0.120312 -0.007 - 49 O 0.415369 0.102811 0.620312 -0.007 - 50 O 0.687442 0.102811 0.982499 -0.007 - 51 O 0.379688 0.295057 0.482499 -0.008 - 52 O 0.812558 0.795057 0.415369 -0.007 - 53 O 0.704943 0.517501 0.620312 -0.007 - 54 O 0.602811 0.915369 0.120312 -0.007 - 55 O 0.795057 0.415369 0.812558 -0.007 - 56 O 0.295057 0.482499 0.379688 -0.007 - 57 O 0.397189 0.084631 0.879688 -0.007 - 58 O 0.204943 0.584631 0.187442 -0.007 - 59 O 0.187442 0.204943 0.584631 -0.007 - 60 O 0.620312 0.704943 0.517501 -0.008 - 61 O 0.312558 0.897189 0.017501 -0.007 - 62 O 0.584631 0.897189 0.379688 -0.007 - 63 O 0.982499 0.795057 0.879688 -0.007 - 64 O 0.517501 0.397189 0.812558 -0.008 - 65 O 0.517501 0.620312 0.704943 -0.008 - 66 O 0.879688 0.982499 0.795057 -0.008 - 67 O 0.312558 0.915369 0.295057 -0.007 - 68 O 0.187442 0.482499 0.602811 -0.007 - 69 O 0.102811 0.620312 0.415369 -0.008 - 70 O 0.397189 0.812558 0.517501 -0.007 - 71 O 0.295057 0.312558 0.915369 -0.007 - 72 O 0.795057 0.879688 0.982499 -0.007 - 73 O 0.379688 0.584631 0.897189 -0.008 - 74 O 0.084631 0.879688 0.397189 -0.008 - 75 O 0.415369 0.812558 0.795057 -0.007 - 76 O 0.017501 0.312558 0.897189 -0.007 - 77 O 0.084631 0.704943 0.687442 -0.008 - 78 O 0.120312 0.602811 0.915369 -0.008 - 79 O 0.102811 0.982499 0.687442 -0.008","# generated using pymatgen -data_Li3Cr2(AsO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.51052944 -_cell_length_b 10.51052944 -_cell_length_c 10.51052944 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Cr2(AsO4)3 -_chemical_formula_sum 'Li12 Cr8 As12 O48' -_cell_volume 893.82374534 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.12500000 0.37500000 1 - Li Li1 1 0.87500000 0.62500000 0.25000000 1 - Li Li2 1 0.37500000 0.12500000 0.25000000 1 - Li Li3 1 0.25000000 0.37500000 0.12500000 1 - Li Li4 1 0.87500000 0.75000000 0.62500000 1 - Li Li5 1 0.37500000 0.75000000 0.12500000 1 - Li Li6 1 0.12500000 0.25000000 0.37500000 1 - Li Li7 1 0.62500000 0.25000000 0.87500000 1 - Li Li8 1 0.75000000 0.62500000 0.87500000 1 - Li Li9 1 0.62500000 0.87500000 0.75000000 1 - Li Li10 1 0.12500000 0.37500000 0.75000000 1 - Li Li11 1 0.25000000 0.87500000 0.62500000 1 - Cr Cr12 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr13 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr14 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr15 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr16 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr18 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr19 1 0.00000000 0.50000000 0.50000000 1 - As As20 1 0.87500000 0.25000000 0.12500000 1 - As As21 1 0.62500000 0.37500000 0.25000000 1 - As As22 1 0.87500000 0.12500000 0.75000000 1 - As As23 1 0.75000000 0.37500000 0.62500000 1 - As As24 1 0.75000000 0.87500000 0.12500000 1 - As As25 1 0.62500000 0.75000000 0.37500000 1 - As As26 1 0.37500000 0.25000000 0.62500000 1 - As As27 1 0.25000000 0.62500000 0.37500000 1 - As As28 1 0.25000000 0.12500000 0.87500000 1 - As As29 1 0.12500000 0.87500000 0.25000000 1 - As As30 1 0.37500000 0.62500000 0.75000000 1 - As As31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.89718900 0.01750100 0.31255800 1 - O O33 1 0.87968800 0.39718900 0.08463100 1 - O O34 1 0.91536900 0.29505700 0.31255800 1 - O O35 1 0.91536900 0.12031200 0.60281100 1 - O O36 1 0.58463100 0.18744200 0.20494300 1 - O O37 1 0.98249900 0.68744200 0.10281100 1 - O O38 1 0.62031200 0.41536900 0.10281100 1 - O O39 1 0.20494300 0.12031200 0.01750100 1 - O O40 1 0.70494300 0.68744200 0.08463100 1 - O O41 1 0.60281100 0.18744200 0.48249900 1 - O O42 1 0.89718900 0.37968800 0.58463100 1 - O O43 1 0.68744200 0.08463100 0.70494300 1 - O O44 1 0.12031200 0.01750100 0.20494300 1 - O O45 1 0.81255800 0.51750100 0.39718900 1 - O O46 1 0.48249900 0.37968800 0.29505700 1 - O O47 1 0.48249900 0.60281100 0.18744200 1 - O O48 1 0.01750100 0.20494300 0.12031200 1 - O O49 1 0.41536900 0.10281100 0.62031200 1 - O O50 1 0.68744200 0.10281100 0.98249900 1 - O O51 1 0.37968800 0.29505700 0.48249900 1 - O O52 1 0.81255800 0.79505700 0.41536900 1 - O O53 1 0.70494300 0.51750100 0.62031200 1 - O O54 1 0.60281100 0.91536900 0.12031200 1 - O O55 1 0.79505700 0.41536900 0.81255800 1 - O O56 1 0.29505700 0.48249900 0.37968800 1 - O O57 1 0.39718900 0.08463100 0.87968800 1 - O O58 1 0.20494300 0.58463100 0.18744200 1 - O O59 1 0.18744200 0.20494300 0.58463100 1 - O O60 1 0.62031200 0.70494300 0.51750100 1 - O O61 1 0.31255800 0.89718900 0.01750100 1 - O O62 1 0.58463100 0.89718900 0.37968800 1 - O O63 1 0.98249900 0.79505700 0.87968800 1 - O O64 1 0.51750100 0.39718900 0.81255800 1 - O O65 1 0.51750100 0.62031200 0.70494300 1 - O O66 1 0.87968800 0.98249900 0.79505700 1 - O O67 1 0.31255800 0.91536900 0.29505700 1 - O O68 1 0.18744200 0.48249900 0.60281100 1 - O O69 1 0.10281100 0.62031200 0.41536900 1 - O O70 1 0.39718900 0.81255800 0.51750100 1 - O O71 1 0.29505700 0.31255800 0.91536900 1 - O O72 1 0.79505700 0.87968800 0.98249900 1 - O O73 1 0.37968800 0.58463100 0.89718900 1 - O O74 1 0.08463100 0.87968800 0.39718900 1 - O O75 1 0.41536900 0.81255800 0.79505700 1 - O O76 1 0.01750100 0.31255800 0.89718900 1 - O O77 1 0.08463100 0.70494300 0.68744200 1 - O O78 1 0.12031200 0.60281100 0.91536900 1 - O O79 1 0.10281100 0.98249900 0.68744200 1 -" -Li3Mn2(PO4)3,mp-863434,Ia-3d,[],0.07987724759726955,{'tags': []},"Full Formula (Li12 Mn8 P12 O48) -Reduced Formula: Li3Mn2(PO4)3 -abc : 10.253474 10.253474 10.253474 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Li 0.75 0.125 0.375 0 - 1 Li 0.375 0.125 0.25 0 - 2 Li 0.875 0.625 0.25 0 - 3 Li 0.25 0.375 0.125 0 - 4 Li 0.625 0.25 0.875 0 - 5 Li 0.125 0.25 0.375 0 - 6 Li 0.375 0.75 0.125 0 - 7 Li 0.875 0.75 0.625 0 - 8 Li 0.75 0.625 0.875 0 - 9 Li 0.125 0.375 0.75 0 - 10 Li 0.625 0.875 0.75 0 - 11 Li 0.25 0.875 0.625 0 - 12 Mn 0.5 0 0 4.112 - 13 Mn 0 0 0 4.107 - 14 Mn 0.5 0 0.5 4.112 - 15 Mn 0.5 0.5 0 4.106 - 16 Mn 0 0.5 0 4.106 - 17 Mn 0.5 0.5 0.5 4.107 - 18 Mn 0 0 0.5 4.119 - 19 Mn 0 0.5 0.5 4.119 - 20 P 0.875 0.25 0.125 0.019 - 21 P 0.625 0.375 0.25 0.019 - 22 P 0.875 0.125 0.75 0.019 - 23 P 0.75 0.875 0.125 0.019 - 24 P 0.75 0.375 0.625 0.019 - 25 P 0.625 0.75 0.375 0.019 - 26 P 0.375 0.25 0.625 0.019 - 27 P 0.25 0.625 0.375 0.019 - 28 P 0.25 0.125 0.875 0.019 - 29 P 0.125 0.875 0.25 0.019 - 30 P 0.375 0.625 0.75 0.019 - 31 P 0.125 0.75 0.875 0.019 - 32 O 0.889399 0.007339 0.297623 -0.037 - 33 O 0.88206 0.389399 0.091775 -0.041 - 34 O 0.908225 0.290285 0.297623 -0.041 - 35 O 0.992661 0.702377 0.110601 -0.039 - 36 O 0.908225 0.11794 0.610601 -0.041 - 37 O 0.591775 0.202377 0.209715 -0.041 - 38 O 0.61794 0.408225 0.110601 -0.042 - 39 O 0.209715 0.11794 0.007339 -0.039 - 40 O 0.709715 0.702377 0.091775 -0.036 - 41 O 0.610601 0.202377 0.492661 -0.037 - 42 O 0.889399 0.38206 0.591775 -0.037 - 43 O 0.797623 0.507339 0.389399 -0.038 - 44 O 0.702377 0.091775 0.709715 -0.04 - 45 O 0.11794 0.007339 0.209715 -0.041 - 46 O 0.492661 0.38206 0.290285 -0.041 - 47 O 0.007339 0.209715 0.11794 -0.039 - 48 O 0.408225 0.110601 0.61794 -0.041 - 49 O 0.492661 0.610601 0.202377 -0.042 - 50 O 0.38206 0.290285 0.492661 -0.042 - 51 O 0.797623 0.790285 0.408225 -0.038 - 52 O 0.702377 0.110601 0.992661 -0.04 - 53 O 0.790285 0.408225 0.797623 -0.04 - 54 O 0.709715 0.507339 0.61794 -0.036 - 55 O 0.610601 0.908225 0.11794 -0.037 - 56 O 0.290285 0.492661 0.38206 -0.036 - 57 O 0.209715 0.591775 0.202377 -0.04 - 58 O 0.389399 0.091775 0.88206 -0.037 - 59 O 0.202377 0.209715 0.591775 -0.038 - 60 O 0.297623 0.889399 0.007339 -0.04 - 61 O 0.61794 0.709715 0.507339 -0.042 - 62 O 0.992661 0.790285 0.88206 -0.039 - 63 O 0.591775 0.889399 0.38206 -0.041 - 64 O 0.507339 0.389399 0.797623 -0.042 - 65 O 0.507339 0.61794 0.709715 -0.041 - 66 O 0.202377 0.492661 0.610601 -0.038 - 67 O 0.297623 0.908225 0.290285 -0.04 - 68 O 0.88206 0.992661 0.790285 -0.041 - 69 O 0.110601 0.61794 0.408225 -0.037 - 70 O 0.290285 0.297623 0.908225 -0.036 - 71 O 0.389399 0.797623 0.507339 -0.037 - 72 O 0.790285 0.88206 0.992661 -0.039 - 73 O 0.38206 0.591775 0.889399 -0.042 - 74 O 0.091775 0.88206 0.389399 -0.041 - 75 O 0.408225 0.797623 0.790285 -0.041 - 76 O 0.007339 0.297623 0.889399 -0.039 - 77 O 0.091775 0.709715 0.702377 -0.041 - 78 O 0.11794 0.610601 0.908225 -0.041 - 79 O 0.110601 0.992661 0.702377 -0.037","# generated using pymatgen -data_Li3Mn2(PO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.25347404 -_cell_length_b 10.25347404 -_cell_length_c 10.25347404 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Li3Mn2(PO4)3 -_chemical_formula_sum 'Li12 Mn8 P12 O48' -_cell_volume 829.83398794 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Li Li0 1 0.75000000 0.12500000 0.37500000 1 - Li Li1 1 0.37500000 0.12500000 0.25000000 1 - Li Li2 1 0.87500000 0.62500000 0.25000000 1 - Li Li3 1 0.25000000 0.37500000 0.12500000 1 - Li Li4 1 0.62500000 0.25000000 0.87500000 1 - Li Li5 1 0.12500000 0.25000000 0.37500000 1 - Li Li6 1 0.37500000 0.75000000 0.12500000 1 - Li Li7 1 0.87500000 0.75000000 0.62500000 1 - Li Li8 1 0.75000000 0.62500000 0.87500000 1 - Li Li9 1 0.12500000 0.37500000 0.75000000 1 - Li Li10 1 0.62500000 0.87500000 0.75000000 1 - Li Li11 1 0.25000000 0.87500000 0.62500000 1 - Mn Mn12 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn13 1 0.00000000 0.00000000 0.00000000 1 - Mn Mn14 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn15 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn16 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn17 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn18 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn19 1 0.00000000 0.50000000 0.50000000 1 - P P20 1 0.87500000 0.25000000 0.12500000 1 - P P21 1 0.62500000 0.37500000 0.25000000 1 - P P22 1 0.87500000 0.12500000 0.75000000 1 - P P23 1 0.75000000 0.87500000 0.12500000 1 - P P24 1 0.75000000 0.37500000 0.62500000 1 - P P25 1 0.62500000 0.75000000 0.37500000 1 - P P26 1 0.37500000 0.25000000 0.62500000 1 - P P27 1 0.25000000 0.62500000 0.37500000 1 - P P28 1 0.25000000 0.12500000 0.87500000 1 - P P29 1 0.12500000 0.87500000 0.25000000 1 - P P30 1 0.37500000 0.62500000 0.75000000 1 - P P31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.88939900 0.00733900 0.29762300 1 - O O33 1 0.88206000 0.38939900 0.09177500 1 - O O34 1 0.90822500 0.29028500 0.29762300 1 - O O35 1 0.99266100 0.70237700 0.11060100 1 - O O36 1 0.90822500 0.11794000 0.61060100 1 - O O37 1 0.59177500 0.20237700 0.20971500 1 - O O38 1 0.61794000 0.40822500 0.11060100 1 - O O39 1 0.20971500 0.11794000 0.00733900 1 - O O40 1 0.70971500 0.70237700 0.09177500 1 - O O41 1 0.61060100 0.20237700 0.49266100 1 - O O42 1 0.88939900 0.38206000 0.59177500 1 - O O43 1 0.79762300 0.50733900 0.38939900 1 - O O44 1 0.70237700 0.09177500 0.70971500 1 - O O45 1 0.11794000 0.00733900 0.20971500 1 - O O46 1 0.49266100 0.38206000 0.29028500 1 - O O47 1 0.00733900 0.20971500 0.11794000 1 - O O48 1 0.40822500 0.11060100 0.61794000 1 - O O49 1 0.49266100 0.61060100 0.20237700 1 - O O50 1 0.38206000 0.29028500 0.49266100 1 - O O51 1 0.79762300 0.79028500 0.40822500 1 - O O52 1 0.70237700 0.11060100 0.99266100 1 - O O53 1 0.79028500 0.40822500 0.79762300 1 - O O54 1 0.70971500 0.50733900 0.61794000 1 - O O55 1 0.61060100 0.90822500 0.11794000 1 - O O56 1 0.29028500 0.49266100 0.38206000 1 - O O57 1 0.20971500 0.59177500 0.20237700 1 - O O58 1 0.38939900 0.09177500 0.88206000 1 - O O59 1 0.20237700 0.20971500 0.59177500 1 - O O60 1 0.29762300 0.88939900 0.00733900 1 - O O61 1 0.61794000 0.70971500 0.50733900 1 - O O62 1 0.99266100 0.79028500 0.88206000 1 - O O63 1 0.59177500 0.88939900 0.38206000 1 - O O64 1 0.50733900 0.38939900 0.79762300 1 - O O65 1 0.50733900 0.61794000 0.70971500 1 - O O66 1 0.20237700 0.49266100 0.61060100 1 - O O67 1 0.29762300 0.90822500 0.29028500 1 - O O68 1 0.88206000 0.99266100 0.79028500 1 - O O69 1 0.11060100 0.61794000 0.40822500 1 - O O70 1 0.29028500 0.29762300 0.90822500 1 - O O71 1 0.38939900 0.79762300 0.50733900 1 - O O72 1 0.79028500 0.88206000 0.99266100 1 - O O73 1 0.38206000 0.59177500 0.88939900 1 - O O74 1 0.09177500 0.88206000 0.38939900 1 - O O75 1 0.40822500 0.79762300 0.79028500 1 - O O76 1 0.00733900 0.29762300 0.88939900 1 - O O77 1 0.09177500 0.70971500 0.70237700 1 - O O78 1 0.11794000 0.61060100 0.90822500 1 - O O79 1 0.11060100 0.99266100 0.70237700 1 -" -Ca3Cr2(GeO4)3,mvc-13324,Ia-3d,[],0.0,{'tags': ['garnet family']},"Full Formula (Ca12 Cr8 Ge12 O48) -Reduced Formula: Ca3Cr2(GeO4)3 -abc : 10.795757 10.795757 10.795757 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.75 0.625 0.875 0.001 - 1 Ca 0.25 0.875 0.625 0.001 - 2 Ca 0.625 0.25 0.875 0.001 - 3 Ca 0.875 0.75 0.625 0.001 - 4 Ca 0.875 0.625 0.25 0.001 - 5 Ca 0.625 0.875 0.75 0.001 - 6 Ca 0.25 0.375 0.125 0.001 - 7 Ca 0.75 0.125 0.375 0.001 - 8 Ca 0.375 0.75 0.125 0.001 - 9 Ca 0.125 0.25 0.375 0.001 - 10 Ca 0.125 0.375 0.75 0.001 - 11 Ca 0.375 0.125 0.25 0.001 - 12 Cr 0.5 0 0.5 2.938 - 13 Cr 0 0.5 0 2.938 - 14 Cr 0.5 0.5 0.5 2.938 - 15 Cr 0 0 0.5 2.938 - 16 Cr 0 0 0 2.938 - 17 Cr 0 0.5 0.5 2.938 - 18 Cr 0.5 0.5 0 2.938 - 19 Cr 0.5 0 0 2.938 - 20 Ge 0.375 0.625 0.75 0.011 - 21 Ge 0.625 0.375 0.25 0.011 - 22 Ge 0.625 0.75 0.375 0.011 - 23 Ge 0.25 0.125 0.875 0.011 - 24 Ge 0.875 0.25 0.125 0.011 - 25 Ge 0.75 0.375 0.625 0.011 - 26 Ge 0.25 0.625 0.375 0.011 - 27 Ge 0.75 0.875 0.125 0.011 - 28 Ge 0.125 0.75 0.875 0.011 - 29 Ge 0.375 0.25 0.625 0.011 - 30 Ge 0.875 0.125 0.75 0.011 - 31 Ge 0.125 0.875 0.25 0.011 - 32 O 0.516346 0.397974 0.815223 -0.007 - 33 O 0.815223 0.516346 0.397974 -0.007 - 34 O 0.798877 0.881628 0.983654 -0.007 - 35 O 0.417248 0.102026 0.618372 -0.007 - 36 O 0.881628 0.397974 0.082751 -0.007 - 37 O 0.684777 0.082751 0.701123 -0.007 - 38 O 0.815223 0.798877 0.417248 -0.007 - 39 O 0.397974 0.815223 0.516346 -0.007 - 40 O 0.618372 0.701123 0.516346 -0.007 - 41 O 0.417249 0.815223 0.798877 -0.007 - 42 O 0.397974 0.082751 0.881628 -0.007 - 43 O 0.102026 0.983654 0.684777 -0.007 - 44 O 0.983654 0.684777 0.102026 -0.007 - 45 O 0.798877 0.417248 0.815223 -0.007 - 46 O 0.516346 0.618372 0.701123 -0.007 - 47 O 0.701123 0.516346 0.618372 -0.007 - 48 O 0.082751 0.881628 0.397974 -0.007 - 49 O 0.983654 0.798877 0.881628 -0.007 - 50 O 0.082751 0.701123 0.684777 -0.007 - 51 O 0.381628 0.298877 0.483654 -0.007 - 52 O 0.618372 0.417248 0.102026 -0.007 - 53 O 0.102026 0.618372 0.417248 -0.007 - 54 O 0.701123 0.684777 0.082751 -0.007 - 55 O 0.684777 0.102026 0.983654 -0.007 - 56 O 0.483654 0.602026 0.184777 -0.007 - 57 O 0.184777 0.483654 0.602026 -0.007 - 58 O 0.201123 0.118372 0.016346 -0.007 - 59 O 0.582751 0.897974 0.381628 -0.007 - 60 O 0.118372 0.602026 0.917249 -0.007 - 61 O 0.315223 0.917248 0.298877 -0.007 - 62 O 0.184777 0.201123 0.582751 -0.007 - 63 O 0.602026 0.184777 0.483654 -0.007 - 64 O 0.315223 0.897974 0.016346 -0.007 - 65 O 0.298877 0.315223 0.917248 -0.007 - 66 O 0.897974 0.381628 0.582752 -0.007 - 67 O 0.118372 0.016346 0.201123 -0.007 - 68 O 0.381628 0.582751 0.897974 -0.007 - 69 O 0.917248 0.298877 0.315223 -0.007 - 70 O 0.016346 0.201123 0.118372 -0.007 - 71 O 0.917249 0.118372 0.602026 -0.007 - 72 O 0.298877 0.483654 0.381628 -0.007 - 73 O 0.483654 0.381628 0.298877 -0.007 - 74 O 0.201123 0.582751 0.184777 -0.007 - 75 O 0.016346 0.315223 0.897974 -0.007 - 76 O 0.897974 0.016346 0.315223 -0.007 - 77 O 0.602026 0.917248 0.118372 -0.007 - 78 O 0.582752 0.184777 0.201123 -0.007 - 79 O 0.881628 0.983654 0.798877 -0.007","# generated using pymatgen -data_Ca3Cr2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.79575664 -_cell_length_b 10.79575664 -_cell_length_c 10.79575664 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Cr2(GeO4)3 -_chemical_formula_sum 'Ca12 Cr8 Ge12 O48' -_cell_volume 968.58417005 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca1 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca2 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca3 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca4 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca5 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca6 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca7 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca8 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca9 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca10 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.12500000 0.25000000 1 - Cr Cr12 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr13 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr14 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr16 1 0.00000000 0.00000000 0.00000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr18 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr19 1 0.50000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge21 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge24 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge25 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge26 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge27 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge28 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge29 1 0.37500000 0.25000000 0.62500000 1 - Ge Ge30 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.51634600 0.39797400 0.81522300 1 - O O33 1 0.81522300 0.51634600 0.39797400 1 - O O34 1 0.79887700 0.88162800 0.98365400 1 - O O35 1 0.41724800 0.10202600 0.61837200 1 - O O36 1 0.88162800 0.39797400 0.08275100 1 - O O37 1 0.68477700 0.08275100 0.70112300 1 - O O38 1 0.81522300 0.79887700 0.41724800 1 - O O39 1 0.39797400 0.81522300 0.51634600 1 - O O40 1 0.61837200 0.70112300 0.51634600 1 - O O41 1 0.41724900 0.81522300 0.79887700 1 - O O42 1 0.39797400 0.08275100 0.88162800 1 - O O43 1 0.10202600 0.98365400 0.68477700 1 - O O44 1 0.98365400 0.68477700 0.10202600 1 - O O45 1 0.79887700 0.41724800 0.81522300 1 - O O46 1 0.51634600 0.61837200 0.70112300 1 - O O47 1 0.70112300 0.51634600 0.61837200 1 - O O48 1 0.08275100 0.88162800 0.39797400 1 - O O49 1 0.98365400 0.79887700 0.88162800 1 - O O50 1 0.08275100 0.70112300 0.68477700 1 - O O51 1 0.38162800 0.29887700 0.48365400 1 - O O52 1 0.61837200 0.41724800 0.10202600 1 - O O53 1 0.10202600 0.61837200 0.41724800 1 - O O54 1 0.70112300 0.68477700 0.08275100 1 - O O55 1 0.68477700 0.10202600 0.98365400 1 - O O56 1 0.48365400 0.60202600 0.18477700 1 - O O57 1 0.18477700 0.48365400 0.60202600 1 - O O58 1 0.20112300 0.11837200 0.01634600 1 - O O59 1 0.58275100 0.89797400 0.38162800 1 - O O60 1 0.11837200 0.60202600 0.91724900 1 - O O61 1 0.31522300 0.91724800 0.29887700 1 - O O62 1 0.18477700 0.20112300 0.58275100 1 - O O63 1 0.60202600 0.18477700 0.48365400 1 - O O64 1 0.31522300 0.89797400 0.01634600 1 - O O65 1 0.29887700 0.31522300 0.91724800 1 - O O66 1 0.89797400 0.38162800 0.58275200 1 - O O67 1 0.11837200 0.01634600 0.20112300 1 - O O68 1 0.38162800 0.58275100 0.89797400 1 - O O69 1 0.91724800 0.29887700 0.31522300 1 - O O70 1 0.01634600 0.20112300 0.11837200 1 - O O71 1 0.91724900 0.11837200 0.60202600 1 - O O72 1 0.29887700 0.48365400 0.38162800 1 - O O73 1 0.48365400 0.38162800 0.29887700 1 - O O74 1 0.20112300 0.58275100 0.18477700 1 - O O75 1 0.01634600 0.31522300 0.89797400 1 - O O76 1 0.89797400 0.01634600 0.31522300 1 - O O77 1 0.60202600 0.91724800 0.11837200 1 - O O78 1 0.58275200 0.18477700 0.20112300 1 - O O79 1 0.88162800 0.98365400 0.79887700 1 -" -Mg3Si3(SnO6)2,mvc-3630,Ia-3d,[],0.26109805149999765,{'tags': []},"Full Formula (Mg12 Si12 Sn8 O48) -Reduced Formula: Mg3Si3(SnO6)2 -abc : 10.594265 10.594265 10.594265 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0 - 1 Mg 0.75 0.125 0.375 0 - 2 Mg 0.375 0.125 0.25 0 - 3 Mg 0.125 0.375 0.75 0 - 4 Mg 0.25 0.875 0.625 0 - 5 Mg 0.125 0.25 0.375 0 - 6 Mg 0.625 0.25 0.875 0 - 7 Mg 0.75 0.625 0.875 0 - 8 Mg 0.875 0.75 0.625 0 - 9 Mg 0.875 0.625 0.25 0 - 10 Mg 0.625 0.875 0.75 0 - 11 Mg 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 -0 - 13 Si 0.875 0.25 0.125 -0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 0 - 16 Si 0.25 0.125 0.875 -0 - 17 Si 0.375 0.625 0.75 -0 - 18 Si 0.375 0.25 0.625 -0 - 19 Si 0.875 0.125 0.75 0 - 20 Si 0.625 0.375 0.25 -0 - 21 Si 0.75 0.875 0.125 -0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 -0 - 24 Sn 0.5 0 0 -0 - 25 Sn 0.5 0.5 0 -0 - 26 Sn 0 0.5 0.5 0 - 27 Sn 0 0 0.5 -0 - 28 Sn 0.5 0.5 0.5 -0 - 29 Sn 0 0.5 0 0 - 30 Sn 0.5 0 0.5 0 - 31 Sn 0 0 0 0 - 32 O 0.596948 0.894864 0.369862 0 - 33 O 0.369862 0.596948 0.894864 -0 - 34 O 0.272914 0.297916 0.903052 -0 - 35 O 0.474999 0.605136 0.202084 -0 - 36 O 0.297916 0.894864 0.025001 -0 - 37 O 0.130138 0.025001 0.227086 0 - 38 O 0.369862 0.272914 0.474999 -0 - 39 O 0.894864 0.369862 0.596948 0 - 40 O 0.202084 0.227086 0.596948 -0 - 41 O 0.474999 0.369862 0.272914 -0 - 42 O 0.894864 0.025001 0.297916 -0 - 43 O 0.605136 0.903052 0.130138 -0 - 44 O 0.903052 0.130138 0.605136 -0 - 45 O 0.272914 0.474999 0.369862 -0 - 46 O 0.596948 0.202084 0.227086 -0 - 47 O 0.227086 0.596948 0.202084 0 - 48 O 0.025001 0.297916 0.894864 0 - 49 O 0.903052 0.272914 0.297916 0 - 50 O 0.025001 0.227086 0.130138 -0 - 51 O 0.797916 0.772914 0.403052 -0 - 52 O 0.202084 0.474999 0.605136 -0 - 53 O 0.605136 0.202084 0.474999 0 - 54 O 0.227086 0.130138 0.025001 0 - 55 O 0.130138 0.605136 0.903052 0 - 56 O 0.403052 0.105136 0.630138 0 - 57 O 0.630138 0.403052 0.105136 -0 - 58 O 0.727086 0.702084 0.096948 -0 - 59 O 0.525001 0.394864 0.797916 -0 - 60 O 0.702084 0.105136 0.974999 -0 - 61 O 0.869862 0.974999 0.772914 0 - 62 O 0.630138 0.727086 0.525001 -0 - 63 O 0.105136 0.630138 0.403052 0 - 64 O 0.869862 0.394864 0.096948 0 - 65 O 0.772914 0.869862 0.974999 -0 - 66 O 0.394864 0.797916 0.525001 0 - 67 O 0.702084 0.096948 0.727086 0 - 68 O 0.797916 0.525001 0.394864 -0 - 69 O 0.974999 0.772914 0.869862 -0 - 70 O 0.096948 0.727086 0.702084 0 - 71 O 0.974999 0.702084 0.105136 0 - 72 O 0.772914 0.403052 0.797916 0 - 73 O 0.403052 0.797916 0.772914 -0 - 74 O 0.727086 0.525001 0.630138 -0 - 75 O 0.096948 0.869862 0.394864 -0 - 76 O 0.394864 0.096948 0.869862 -0 - 77 O 0.105136 0.974999 0.702084 -0 - 78 O 0.525001 0.630138 0.727086 -0 - 79 O 0.297916 0.903052 0.272914 0","# generated using pymatgen -data_Mg3Si3(SnO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.59426543 -_cell_length_b 10.59426543 -_cell_length_c 10.59426543 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Si3(SnO6)2 -_chemical_formula_sum 'Mg12 Si12 Sn8 O48' -_cell_volume 915.35731920 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Sn Sn24 1 0.50000000 0.00000000 0.00000000 1 - Sn Sn25 1 0.50000000 0.50000000 0.00000000 1 - Sn Sn26 1 0.00000000 0.50000000 0.50000000 1 - Sn Sn27 1 0.00000000 0.00000000 0.50000000 1 - Sn Sn28 1 0.50000000 0.50000000 0.50000000 1 - Sn Sn29 1 0.00000000 0.50000000 0.00000000 1 - Sn Sn30 1 0.50000000 0.00000000 0.50000000 1 - Sn Sn31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59694800 0.89486400 0.36986200 1 - O O33 1 0.36986200 0.59694800 0.89486400 1 - O O34 1 0.27291400 0.29791600 0.90305200 1 - O O35 1 0.47499900 0.60513600 0.20208400 1 - O O36 1 0.29791600 0.89486400 0.02500100 1 - O O37 1 0.13013800 0.02500100 0.22708600 1 - O O38 1 0.36986200 0.27291400 0.47499900 1 - O O39 1 0.89486400 0.36986200 0.59694800 1 - O O40 1 0.20208400 0.22708600 0.59694800 1 - O O41 1 0.47499900 0.36986200 0.27291400 1 - O O42 1 0.89486400 0.02500100 0.29791600 1 - O O43 1 0.60513600 0.90305200 0.13013800 1 - O O44 1 0.90305200 0.13013800 0.60513600 1 - O O45 1 0.27291400 0.47499900 0.36986200 1 - O O46 1 0.59694800 0.20208400 0.22708600 1 - O O47 1 0.22708600 0.59694800 0.20208400 1 - O O48 1 0.02500100 0.29791600 0.89486400 1 - O O49 1 0.90305200 0.27291400 0.29791600 1 - O O50 1 0.02500100 0.22708600 0.13013800 1 - O O51 1 0.79791600 0.77291400 0.40305200 1 - O O52 1 0.20208400 0.47499900 0.60513600 1 - O O53 1 0.60513600 0.20208400 0.47499900 1 - O O54 1 0.22708600 0.13013800 0.02500100 1 - O O55 1 0.13013800 0.60513600 0.90305200 1 - O O56 1 0.40305200 0.10513600 0.63013800 1 - O O57 1 0.63013800 0.40305200 0.10513600 1 - O O58 1 0.72708600 0.70208400 0.09694800 1 - O O59 1 0.52500100 0.39486400 0.79791600 1 - O O60 1 0.70208400 0.10513600 0.97499900 1 - O O61 1 0.86986200 0.97499900 0.77291400 1 - O O62 1 0.63013800 0.72708600 0.52500100 1 - O O63 1 0.10513600 0.63013800 0.40305200 1 - O O64 1 0.86986200 0.39486400 0.09694800 1 - O O65 1 0.77291400 0.86986200 0.97499900 1 - O O66 1 0.39486400 0.79791600 0.52500100 1 - O O67 1 0.70208400 0.09694800 0.72708600 1 - O O68 1 0.79791600 0.52500100 0.39486400 1 - O O69 1 0.97499900 0.77291400 0.86986200 1 - O O70 1 0.09694800 0.72708600 0.70208400 1 - O O71 1 0.97499900 0.70208400 0.10513600 1 - O O72 1 0.77291400 0.40305200 0.79791600 1 - O O73 1 0.40305200 0.79791600 0.77291400 1 - O O74 1 0.72708600 0.52500100 0.63013800 1 - O O75 1 0.09694800 0.86986200 0.39486400 1 - O O76 1 0.39486400 0.09694800 0.86986200 1 - O O77 1 0.10513600 0.97499900 0.70208400 1 - O O78 1 0.52500100 0.63013800 0.72708600 1 - O O79 1 0.29791600 0.90305200 0.27291400 1 -" -Mg3Si3(BiO6)2,mvc-3636,Ia-3d,[],0.24600890887499904,{'tags': []},"Full Formula (Mg12 Si12 Bi8 O48) -Reduced Formula: Mg3Si3(BiO6)2 -abc : 10.809097 10.809097 10.809097 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0 - 1 Mg 0.75 0.125 0.375 0 - 2 Mg 0.375 0.125 0.25 0 - 3 Mg 0.125 0.375 0.75 0 - 4 Mg 0.25 0.875 0.625 0 - 5 Mg 0.125 0.25 0.375 0 - 6 Mg 0.625 0.25 0.875 0 - 7 Mg 0.75 0.625 0.875 0 - 8 Mg 0.875 0.75 0.625 0 - 9 Mg 0.875 0.625 0.25 0 - 10 Mg 0.625 0.875 0.75 0 - 11 Mg 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 0 - 13 Si 0.875 0.25 0.125 0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 0 - 16 Si 0.25 0.125 0.875 0 - 17 Si 0.375 0.625 0.75 0 - 18 Si 0.375 0.25 0.625 0 - 19 Si 0.875 0.125 0.75 0 - 20 Si 0.625 0.375 0.25 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 0 - 24 Bi 0.5 0 0 0 - 25 Bi 0.5 0.5 0 0 - 26 Bi 0 0.5 0.5 0 - 27 Bi 0 0 0.5 0 - 28 Bi 0.5 0.5 0.5 0 - 29 Bi 0 0.5 0 0 - 30 Bi 0.5 0 0.5 0 - 31 Bi 0 0 0 0 - 32 O 0.601661 0.892796 0.36753 -0 - 33 O 0.36753 0.601661 0.892796 -0 - 34 O 0.26587 0.291136 0.898339 -0 - 35 O 0.474734 0.607204 0.208864 -0 - 36 O 0.291136 0.892796 0.025266 -0 - 37 O 0.13247 0.025266 0.23413 -0 - 38 O 0.36753 0.26587 0.474734 -0 - 39 O 0.892796 0.36753 0.601661 -0 - 40 O 0.208864 0.23413 0.601661 -0 - 41 O 0.474734 0.36753 0.26587 -0 - 42 O 0.892796 0.025266 0.291136 -0 - 43 O 0.607204 0.898339 0.13247 -0 - 44 O 0.898339 0.13247 0.607204 -0 - 45 O 0.26587 0.474734 0.36753 -0 - 46 O 0.601661 0.208864 0.23413 -0 - 47 O 0.23413 0.601661 0.208864 -0 - 48 O 0.025266 0.291136 0.892796 -0 - 49 O 0.898339 0.26587 0.291136 -0 - 50 O 0.025266 0.23413 0.13247 -0 - 51 O 0.791136 0.76587 0.398339 -0 - 52 O 0.208864 0.474734 0.607204 -0 - 53 O 0.607204 0.208864 0.474734 -0 - 54 O 0.23413 0.13247 0.025266 -0 - 55 O 0.13247 0.607204 0.898339 -0 - 56 O 0.398339 0.107204 0.63247 -0 - 57 O 0.63247 0.398339 0.107204 -0 - 58 O 0.73413 0.708864 0.101661 -0 - 59 O 0.525266 0.392796 0.791136 -0 - 60 O 0.708864 0.107204 0.974734 -0 - 61 O 0.86753 0.974734 0.76587 -0 - 62 O 0.63247 0.73413 0.525266 -0 - 63 O 0.107204 0.63247 0.398339 -0 - 64 O 0.86753 0.392796 0.101661 -0 - 65 O 0.76587 0.86753 0.974734 -0 - 66 O 0.392796 0.791136 0.525266 -0 - 67 O 0.708864 0.101661 0.73413 -0 - 68 O 0.791136 0.525266 0.392796 -0 - 69 O 0.974734 0.76587 0.86753 -0 - 70 O 0.101661 0.73413 0.708864 -0 - 71 O 0.974734 0.708864 0.107204 -0 - 72 O 0.76587 0.398339 0.791136 -0 - 73 O 0.398339 0.791136 0.76587 -0 - 74 O 0.73413 0.525266 0.63247 -0 - 75 O 0.101661 0.86753 0.392796 -0 - 76 O 0.392796 0.101661 0.86753 -0 - 77 O 0.107204 0.974734 0.708864 -0 - 78 O 0.525266 0.63247 0.73413 -0 - 79 O 0.291136 0.898339 0.26587 -0","# generated using pymatgen -data_Mg3Si3(BiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80909689 -_cell_length_b 10.80909689 -_cell_length_c 10.80909689 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Si3(BiO6)2 -_chemical_formula_sum 'Mg12 Si12 Bi8 O48' -_cell_volume 972.17923071 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Bi Bi24 1 0.50000000 0.00000000 0.00000000 1 - Bi Bi25 1 0.50000000 0.50000000 0.00000000 1 - Bi Bi26 1 0.00000000 0.50000000 0.50000000 1 - Bi Bi27 1 0.00000000 0.00000000 0.50000000 1 - Bi Bi28 1 0.50000000 0.50000000 0.50000000 1 - Bi Bi29 1 0.00000000 0.50000000 0.00000000 1 - Bi Bi30 1 0.50000000 0.00000000 0.50000000 1 - Bi Bi31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.60166100 0.89279600 0.36753000 1 - O O33 1 0.36753000 0.60166100 0.89279600 1 - O O34 1 0.26587000 0.29113600 0.89833900 1 - O O35 1 0.47473400 0.60720400 0.20886400 1 - O O36 1 0.29113600 0.89279600 0.02526600 1 - O O37 1 0.13247000 0.02526600 0.23413000 1 - O O38 1 0.36753000 0.26587000 0.47473400 1 - O O39 1 0.89279600 0.36753000 0.60166100 1 - O O40 1 0.20886400 0.23413000 0.60166100 1 - O O41 1 0.47473400 0.36753000 0.26587000 1 - O O42 1 0.89279600 0.02526600 0.29113600 1 - O O43 1 0.60720400 0.89833900 0.13247000 1 - O O44 1 0.89833900 0.13247000 0.60720400 1 - O O45 1 0.26587000 0.47473400 0.36753000 1 - O O46 1 0.60166100 0.20886400 0.23413000 1 - O O47 1 0.23413000 0.60166100 0.20886400 1 - O O48 1 0.02526600 0.29113600 0.89279600 1 - O O49 1 0.89833900 0.26587000 0.29113600 1 - O O50 1 0.02526600 0.23413000 0.13247000 1 - O O51 1 0.79113600 0.76587000 0.39833900 1 - O O52 1 0.20886400 0.47473400 0.60720400 1 - O O53 1 0.60720400 0.20886400 0.47473400 1 - O O54 1 0.23413000 0.13247000 0.02526600 1 - O O55 1 0.13247000 0.60720400 0.89833900 1 - O O56 1 0.39833900 0.10720400 0.63247000 1 - O O57 1 0.63247000 0.39833900 0.10720400 1 - O O58 1 0.73413000 0.70886400 0.10166100 1 - O O59 1 0.52526600 0.39279600 0.79113600 1 - O O60 1 0.70886400 0.10720400 0.97473400 1 - O O61 1 0.86753000 0.97473400 0.76587000 1 - O O62 1 0.63247000 0.73413000 0.52526600 1 - O O63 1 0.10720400 0.63247000 0.39833900 1 - O O64 1 0.86753000 0.39279600 0.10166100 1 - O O65 1 0.76587000 0.86753000 0.97473400 1 - O O66 1 0.39279600 0.79113600 0.52526600 1 - O O67 1 0.70886400 0.10166100 0.73413000 1 - O O68 1 0.79113600 0.52526600 0.39279600 1 - O O69 1 0.97473400 0.76587000 0.86753000 1 - O O70 1 0.10166100 0.73413000 0.70886400 1 - O O71 1 0.97473400 0.70886400 0.10720400 1 - O O72 1 0.76587000 0.39833900 0.79113600 1 - O O73 1 0.39833900 0.79113600 0.76587000 1 - O O74 1 0.73413000 0.52526600 0.63247000 1 - O O75 1 0.10166100 0.86753000 0.39279600 1 - O O76 1 0.39279600 0.10166100 0.86753000 1 - O O77 1 0.10720400 0.97473400 0.70886400 1 - O O78 1 0.52526600 0.63247000 0.73413000 1 - O O79 1 0.29113600 0.89833900 0.26587000 1 -" -Zn3Si3(AgO6)2,mvc-3646,Ia-3d,[],0.26856012666666196,{'tags': []},"Full Formula (Zn12 Si12 Ag8 O48) -Reduced Formula: Zn3Si3(AgO6)2 -abc : 10.438445 10.438445 10.438445 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 -0.001 - 1 Zn 0.75 0.125 0.375 -0.001 - 2 Zn 0.375 0.125 0.25 -0.001 - 3 Zn 0.125 0.375 0.75 -0.001 - 4 Zn 0.25 0.875 0.625 -0.001 - 5 Zn 0.125 0.25 0.375 -0.001 - 6 Zn 0.625 0.25 0.875 -0.001 - 7 Zn 0.75 0.625 0.875 -0.001 - 8 Zn 0.875 0.75 0.625 -0.001 - 9 Zn 0.875 0.625 0.25 -0.001 - 10 Zn 0.625 0.875 0.75 -0.001 - 11 Zn 0.375 0.75 0.125 -0.001 - 12 Si 0.125 0.75 0.875 -0 - 13 Si 0.875 0.25 0.125 -0 - 14 Si 0.75 0.375 0.625 -0.001 - 15 Si 0.125 0.875 0.25 -0 - 16 Si 0.25 0.125 0.875 -0.001 - 17 Si 0.375 0.625 0.75 -0 - 18 Si 0.375 0.25 0.625 -0 - 19 Si 0.875 0.125 0.75 -0 - 20 Si 0.625 0.375 0.25 -0 - 21 Si 0.75 0.875 0.125 -0.001 - 22 Si 0.25 0.625 0.375 -0.001 - 23 Si 0.625 0.75 0.375 -0 - 24 Ag 0.5 0 0 0.048 - 25 Ag 0.5 0.5 0 0.112 - 26 Ag 0 0.5 0.5 0.07 - 27 Ag 0 0 0.5 0.07 - 28 Ag 0.5 0.5 0.5 0.112 - 29 Ag 0 0.5 0 0.112 - 30 Ag 0.5 0 0.5 0.048 - 31 Ag 0 0 0 0.112 - 32 O 0.596445 0.896127 0.369336 0.012 - 33 O 0.369336 0.596445 0.896127 0.032 - 34 O 0.272891 0.299683 0.903555 0.023 - 35 O 0.473208 0.603873 0.200317 0.016 - 36 O 0.299683 0.896127 0.026792 0.013 - 37 O 0.130664 0.026792 0.227109 0.03 - 38 O 0.369336 0.272891 0.473208 0.032 - 39 O 0.896127 0.369336 0.596445 0.016 - 40 O 0.200317 0.227109 0.596445 0.017 - 41 O 0.473208 0.369336 0.272891 0.016 - 42 O 0.896127 0.026792 0.299683 0.016 - 43 O 0.603873 0.903555 0.130664 0.013 - 44 O 0.903555 0.130664 0.603873 0.017 - 45 O 0.272891 0.473208 0.369336 0.023 - 46 O 0.596445 0.200317 0.227109 0.012 - 47 O 0.227109 0.596445 0.200317 0.023 - 48 O 0.026792 0.299683 0.896127 0.018 - 49 O 0.903555 0.272891 0.299683 0.017 - 50 O 0.026792 0.227109 0.130664 0.018 - 51 O 0.799683 0.772891 0.403555 0.017 - 52 O 0.200317 0.473208 0.603873 0.017 - 53 O 0.603873 0.200317 0.473208 0.013 - 54 O 0.227109 0.130664 0.026792 0.023 - 55 O 0.130664 0.603873 0.903555 0.03 - 56 O 0.403555 0.103873 0.630664 0.012 - 57 O 0.630664 0.403555 0.103873 0.032 - 58 O 0.727109 0.700317 0.096445 0.023 - 59 O 0.526792 0.396127 0.799683 0.016 - 60 O 0.700317 0.103873 0.973208 0.013 - 61 O 0.869336 0.973208 0.772891 0.03 - 62 O 0.630664 0.727109 0.526792 0.032 - 63 O 0.103873 0.630664 0.403555 0.016 - 64 O 0.869336 0.396127 0.096445 0.03 - 65 O 0.772891 0.869336 0.973208 0.023 - 66 O 0.396127 0.799683 0.526792 0.013 - 67 O 0.700317 0.096445 0.727109 0.013 - 68 O 0.799683 0.526792 0.396127 0.017 - 69 O 0.973208 0.772891 0.869336 0.018 - 70 O 0.096445 0.727109 0.700317 0.017 - 71 O 0.973208 0.700317 0.103873 0.018 - 72 O 0.772891 0.403555 0.799683 0.023 - 73 O 0.403555 0.799683 0.772891 0.012 - 74 O 0.727109 0.526792 0.630664 0.023 - 75 O 0.096445 0.869336 0.396127 0.017 - 76 O 0.396127 0.096445 0.869336 0.013 - 77 O 0.103873 0.973208 0.700317 0.016 - 78 O 0.526792 0.630664 0.727109 0.016 - 79 O 0.299683 0.903555 0.272891 0.013","# generated using pymatgen -data_Zn3Si3(AgO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.43844495 -_cell_length_b 10.43844495 -_cell_length_c 10.43844495 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Si3(AgO6)2 -_chemical_formula_sum 'Zn12 Si12 Ag8 O48' -_cell_volume 875.55921743 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Ag Ag24 1 0.50000000 0.00000000 0.00000000 1 - Ag Ag25 1 0.50000000 0.50000000 0.00000000 1 - Ag Ag26 1 0.00000000 0.50000000 0.50000000 1 - Ag Ag27 1 0.00000000 0.00000000 0.50000000 1 - Ag Ag28 1 0.50000000 0.50000000 0.50000000 1 - Ag Ag29 1 0.00000000 0.50000000 0.00000000 1 - Ag Ag30 1 0.50000000 0.00000000 0.50000000 1 - Ag Ag31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59644500 0.89612700 0.36933600 1 - O O33 1 0.36933600 0.59644500 0.89612700 1 - O O34 1 0.27289100 0.29968300 0.90355500 1 - O O35 1 0.47320800 0.60387300 0.20031700 1 - O O36 1 0.29968300 0.89612700 0.02679200 1 - O O37 1 0.13066400 0.02679200 0.22710900 1 - O O38 1 0.36933600 0.27289100 0.47320800 1 - O O39 1 0.89612700 0.36933600 0.59644500 1 - O O40 1 0.20031700 0.22710900 0.59644500 1 - O O41 1 0.47320800 0.36933600 0.27289100 1 - O O42 1 0.89612700 0.02679200 0.29968300 1 - O O43 1 0.60387300 0.90355500 0.13066400 1 - O O44 1 0.90355500 0.13066400 0.60387300 1 - O O45 1 0.27289100 0.47320800 0.36933600 1 - O O46 1 0.59644500 0.20031700 0.22710900 1 - O O47 1 0.22710900 0.59644500 0.20031700 1 - O O48 1 0.02679200 0.29968300 0.89612700 1 - O O49 1 0.90355500 0.27289100 0.29968300 1 - O O50 1 0.02679200 0.22710900 0.13066400 1 - O O51 1 0.79968300 0.77289100 0.40355500 1 - O O52 1 0.20031700 0.47320800 0.60387300 1 - O O53 1 0.60387300 0.20031700 0.47320800 1 - O O54 1 0.22710900 0.13066400 0.02679200 1 - O O55 1 0.13066400 0.60387300 0.90355500 1 - O O56 1 0.40355500 0.10387300 0.63066400 1 - O O57 1 0.63066400 0.40355500 0.10387300 1 - O O58 1 0.72710900 0.70031700 0.09644500 1 - O O59 1 0.52679200 0.39612700 0.79968300 1 - O O60 1 0.70031700 0.10387300 0.97320800 1 - O O61 1 0.86933600 0.97320800 0.77289100 1 - O O62 1 0.63066400 0.72710900 0.52679200 1 - O O63 1 0.10387300 0.63066400 0.40355500 1 - O O64 1 0.86933600 0.39612700 0.09644500 1 - O O65 1 0.77289100 0.86933600 0.97320800 1 - O O66 1 0.39612700 0.79968300 0.52679200 1 - O O67 1 0.70031700 0.09644500 0.72710900 1 - O O68 1 0.79968300 0.52679200 0.39612700 1 - O O69 1 0.97320800 0.77289100 0.86933600 1 - O O70 1 0.09644500 0.72710900 0.70031700 1 - O O71 1 0.97320800 0.70031700 0.10387300 1 - O O72 1 0.77289100 0.40355500 0.79968300 1 - O O73 1 0.40355500 0.79968300 0.77289100 1 - O O74 1 0.72710900 0.52679200 0.63066400 1 - O O75 1 0.09644500 0.86933600 0.39612700 1 - O O76 1 0.39612700 0.09644500 0.86933600 1 - O O77 1 0.10387300 0.97320800 0.70031700 1 - O O78 1 0.52679200 0.63066400 0.72710900 1 - O O79 1 0.29968300 0.90355500 0.27289100 1 -" -Ca3Si3(SbO6)2,mvc-3679,Ia-3d,[],0.12146717312500144,{'tags': []},"Full Formula (Ca12 Si12 Sb8 O48) -Reduced Formula: Ca3Si3(SbO6)2 -abc : 11.032194 11.032194 11.032194 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.125 0.375 0 - 2 Ca 0.375 0.125 0.25 0 - 3 Ca 0.125 0.375 0.75 0 - 4 Ca 0.25 0.875 0.625 0 - 5 Ca 0.125 0.25 0.375 0 - 6 Ca 0.625 0.25 0.875 0 - 7 Ca 0.75 0.625 0.875 0 - 8 Ca 0.875 0.75 0.625 0 - 9 Ca 0.875 0.625 0.25 0 - 10 Ca 0.625 0.875 0.75 0 - 11 Ca 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 0 - 13 Si 0.875 0.25 0.125 0 - 14 Si 0.75 0.375 0.625 0 - 15 Si 0.125 0.875 0.25 0 - 16 Si 0.25 0.125 0.875 0 - 17 Si 0.375 0.625 0.75 0 - 18 Si 0.375 0.25 0.625 0 - 19 Si 0.875 0.125 0.75 0 - 20 Si 0.625 0.375 0.25 0 - 21 Si 0.75 0.875 0.125 0 - 22 Si 0.25 0.625 0.375 0 - 23 Si 0.625 0.75 0.375 0 - 24 Sb 0.5 0 0 0 - 25 Sb 0.5 0.5 0 0 - 26 Sb 0 0.5 0.5 0 - 27 Sb 0 0 0.5 0 - 28 Sb 0.5 0.5 0.5 0 - 29 Sb 0 0.5 0 0 - 30 Sb 0.5 0 0.5 0 - 31 Sb 0 0 0 0 - 32 O 0.596573 0.889513 0.374989 0 - 33 O 0.374989 0.596573 0.889513 0 - 34 O 0.278416 0.292939 0.903427 0 - 35 O 0.485476 0.610487 0.207061 0 - 36 O 0.292939 0.889513 0.014524 0 - 37 O 0.125011 0.014524 0.221584 0 - 38 O 0.374989 0.278416 0.485476 0 - 39 O 0.889513 0.374989 0.596573 0 - 40 O 0.207061 0.221584 0.596573 0 - 41 O 0.485476 0.374989 0.278416 0 - 42 O 0.889513 0.014524 0.292939 0 - 43 O 0.610487 0.903427 0.125011 0 - 44 O 0.903427 0.125011 0.610487 0 - 45 O 0.278416 0.485476 0.374989 0 - 46 O 0.596573 0.207061 0.221584 0 - 47 O 0.221584 0.596573 0.207061 0 - 48 O 0.014524 0.292939 0.889513 0 - 49 O 0.903427 0.278416 0.292939 0 - 50 O 0.014524 0.221584 0.125011 0 - 51 O 0.792939 0.778416 0.403427 0 - 52 O 0.207061 0.485476 0.610487 0 - 53 O 0.610487 0.207061 0.485476 0 - 54 O 0.221584 0.125011 0.014524 0 - 55 O 0.125011 0.610487 0.903427 0 - 56 O 0.403427 0.110487 0.625011 0 - 57 O 0.625011 0.403427 0.110487 0 - 58 O 0.721584 0.707061 0.096573 0 - 59 O 0.514524 0.389513 0.792939 0 - 60 O 0.707061 0.110487 0.985476 0 - 61 O 0.874989 0.985476 0.778416 0 - 62 O 0.625011 0.721584 0.514524 0 - 63 O 0.110487 0.625011 0.403427 0 - 64 O 0.874989 0.389513 0.096573 0 - 65 O 0.778416 0.874989 0.985476 0 - 66 O 0.389513 0.792939 0.514524 0 - 67 O 0.707061 0.096573 0.721584 0 - 68 O 0.792939 0.514524 0.389513 0 - 69 O 0.985476 0.778416 0.874989 0 - 70 O 0.096573 0.721584 0.707061 0 - 71 O 0.985476 0.707061 0.110487 0 - 72 O 0.778416 0.403427 0.792939 0 - 73 O 0.403427 0.792939 0.778416 0 - 74 O 0.721584 0.514524 0.625011 0 - 75 O 0.096573 0.874989 0.389513 0 - 76 O 0.389513 0.096573 0.874989 0 - 77 O 0.110487 0.985476 0.707061 0 - 78 O 0.514524 0.625011 0.721584 0 - 79 O 0.292939 0.903427 0.278416 0","# generated using pymatgen -data_Ca3Si3(SbO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.03219370 -_cell_length_b 11.03219370 -_cell_length_c 11.03219370 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Si3(SbO6)2 -_chemical_formula_sum 'Ca12 Si12 Sb8 O48' -_cell_volume 1033.62675920 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Sb Sb24 1 0.50000000 0.00000000 0.00000000 1 - Sb Sb25 1 0.50000000 0.50000000 0.00000000 1 - Sb Sb26 1 0.00000000 0.50000000 0.50000000 1 - Sb Sb27 1 0.00000000 0.00000000 0.50000000 1 - Sb Sb28 1 0.50000000 0.50000000 0.50000000 1 - Sb Sb29 1 0.00000000 0.50000000 0.00000000 1 - Sb Sb30 1 0.50000000 0.00000000 0.50000000 1 - Sb Sb31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59657300 0.88951300 0.37498900 1 - O O33 1 0.37498900 0.59657300 0.88951300 1 - O O34 1 0.27841600 0.29293900 0.90342700 1 - O O35 1 0.48547600 0.61048700 0.20706100 1 - O O36 1 0.29293900 0.88951300 0.01452400 1 - O O37 1 0.12501100 0.01452400 0.22158400 1 - O O38 1 0.37498900 0.27841600 0.48547600 1 - O O39 1 0.88951300 0.37498900 0.59657300 1 - O O40 1 0.20706100 0.22158400 0.59657300 1 - O O41 1 0.48547600 0.37498900 0.27841600 1 - O O42 1 0.88951300 0.01452400 0.29293900 1 - O O43 1 0.61048700 0.90342700 0.12501100 1 - O O44 1 0.90342700 0.12501100 0.61048700 1 - O O45 1 0.27841600 0.48547600 0.37498900 1 - O O46 1 0.59657300 0.20706100 0.22158400 1 - O O47 1 0.22158400 0.59657300 0.20706100 1 - O O48 1 0.01452400 0.29293900 0.88951300 1 - O O49 1 0.90342700 0.27841600 0.29293900 1 - O O50 1 0.01452400 0.22158400 0.12501100 1 - O O51 1 0.79293900 0.77841600 0.40342700 1 - O O52 1 0.20706100 0.48547600 0.61048700 1 - O O53 1 0.61048700 0.20706100 0.48547600 1 - O O54 1 0.22158400 0.12501100 0.01452400 1 - O O55 1 0.12501100 0.61048700 0.90342700 1 - O O56 1 0.40342700 0.11048700 0.62501100 1 - O O57 1 0.62501100 0.40342700 0.11048700 1 - O O58 1 0.72158400 0.70706100 0.09657300 1 - O O59 1 0.51452400 0.38951300 0.79293900 1 - O O60 1 0.70706100 0.11048700 0.98547600 1 - O O61 1 0.87498900 0.98547600 0.77841600 1 - O O62 1 0.62501100 0.72158400 0.51452400 1 - O O63 1 0.11048700 0.62501100 0.40342700 1 - O O64 1 0.87498900 0.38951300 0.09657300 1 - O O65 1 0.77841600 0.87498900 0.98547600 1 - O O66 1 0.38951300 0.79293900 0.51452400 1 - O O67 1 0.70706100 0.09657300 0.72158400 1 - O O68 1 0.79293900 0.51452400 0.38951300 1 - O O69 1 0.98547600 0.77841600 0.87498900 1 - O O70 1 0.09657300 0.72158400 0.70706100 1 - O O71 1 0.98547600 0.70706100 0.11048700 1 - O O72 1 0.77841600 0.40342700 0.79293900 1 - O O73 1 0.40342700 0.79293900 0.77841600 1 - O O74 1 0.72158400 0.51452400 0.62501100 1 - O O75 1 0.09657300 0.87498900 0.38951300 1 - O O76 1 0.38951300 0.09657300 0.87498900 1 - O O77 1 0.11048700 0.98547600 0.70706100 1 - O O78 1 0.51452400 0.62501100 0.72158400 1 - O O79 1 0.29293900 0.90342700 0.27841600 1 -" -Zn3Si3(SnO6)2,mvc-3700,Ia-3d,[],0.30747541537499856,{'tags': []},"Full Formula (Zn12 Si12 Sn8 O48) -Reduced Formula: Zn3Si3(SnO6)2 -abc : 10.703277 10.703277 10.703277 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 0.019 - 1 Zn 0.75 0.125 0.375 0.011 - 2 Zn 0.375 0.125 0.25 0.034 - 3 Zn 0.125 0.375 0.75 0.034 - 4 Zn 0.25 0.875 0.625 0.011 - 5 Zn 0.125 0.25 0.375 0.034 - 6 Zn 0.625 0.25 0.875 0.034 - 7 Zn 0.75 0.625 0.875 0.019 - 8 Zn 0.875 0.75 0.625 0.034 - 9 Zn 0.875 0.625 0.25 0.034 - 10 Zn 0.625 0.875 0.75 0.034 - 11 Zn 0.375 0.75 0.125 0.034 - 12 Si 0.125 0.75 0.875 0.003 - 13 Si 0.875 0.25 0.125 0.003 - 14 Si 0.75 0.375 0.625 0.003 - 15 Si 0.125 0.875 0.25 0.003 - 16 Si 0.25 0.125 0.875 0.003 - 17 Si 0.375 0.625 0.75 0.003 - 18 Si 0.375 0.25 0.625 0.003 - 19 Si 0.875 0.125 0.75 0.003 - 20 Si 0.625 0.375 0.25 0.003 - 21 Si 0.75 0.875 0.125 0.003 - 22 Si 0.25 0.625 0.375 0.003 - 23 Si 0.625 0.75 0.375 0.003 - 24 Sn 0.5 0 0 0.035 - 25 Sn 0.5 0.5 0 0.015 - 26 Sn 0 0.5 0.5 0.035 - 27 Sn 0 0 0.5 0.035 - 28 Sn 0.5 0.5 0.5 0.015 - 29 Sn 0 0.5 0 0.015 - 30 Sn 0.5 0 0.5 0.035 - 31 Sn 0 0 0 0.015 - 32 O 0.586538 0.889734 0.376234 0.014 - 33 O 0.376234 0.586538 0.889734 0.011 - 34 O 0.289696 0.303196 0.913462 0.01 - 35 O 0.4865 0.610266 0.196804 0.01 - 36 O 0.303196 0.889734 0.0135 0.014 - 37 O 0.123766 0.0135 0.210304 0.011 - 38 O 0.376234 0.289696 0.4865 0.011 - 39 O 0.889734 0.376234 0.586538 0.011 - 40 O 0.196804 0.210304 0.586538 0.014 - 41 O 0.4865 0.376234 0.289696 0.01 - 42 O 0.889734 0.0135 0.303196 0.011 - 43 O 0.610266 0.913462 0.123766 0.011 - 44 O 0.913462 0.123766 0.610266 0.014 - 45 O 0.289696 0.4865 0.376234 0.01 - 46 O 0.586538 0.196804 0.210304 0.014 - 47 O 0.210304 0.586538 0.196804 0.01 - 48 O 0.0135 0.303196 0.889734 0.01 - 49 O 0.913462 0.289696 0.303196 0.014 - 50 O 0.0135 0.210304 0.123766 0.01 - 51 O 0.803196 0.789696 0.413462 0.014 - 52 O 0.196804 0.4865 0.610266 0.014 - 53 O 0.610266 0.196804 0.4865 0.011 - 54 O 0.210304 0.123766 0.0135 0.01 - 55 O 0.123766 0.610266 0.913462 0.011 - 56 O 0.413462 0.110266 0.623766 0.014 - 57 O 0.623766 0.413462 0.110266 0.011 - 58 O 0.710304 0.696804 0.086538 0.01 - 59 O 0.5135 0.389734 0.803196 0.01 - 60 O 0.696804 0.110266 0.9865 0.014 - 61 O 0.876234 0.9865 0.789696 0.011 - 62 O 0.623766 0.710304 0.5135 0.011 - 63 O 0.110266 0.623766 0.413462 0.011 - 64 O 0.876234 0.389734 0.086538 0.011 - 65 O 0.789696 0.876234 0.9865 0.01 - 66 O 0.389734 0.803196 0.5135 0.011 - 67 O 0.696804 0.086538 0.710304 0.014 - 68 O 0.803196 0.5135 0.389734 0.014 - 69 O 0.9865 0.789696 0.876234 0.01 - 70 O 0.086538 0.710304 0.696804 0.014 - 71 O 0.9865 0.696804 0.110266 0.01 - 72 O 0.789696 0.413462 0.803196 0.01 - 73 O 0.413462 0.803196 0.789696 0.014 - 74 O 0.710304 0.5135 0.623766 0.01 - 75 O 0.086538 0.876234 0.389734 0.014 - 76 O 0.389734 0.086538 0.876234 0.011 - 77 O 0.110266 0.9865 0.696804 0.011 - 78 O 0.5135 0.623766 0.710304 0.01 - 79 O 0.303196 0.913462 0.289696 0.014","# generated using pymatgen -data_Zn3Si3(SnO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.70327725 -_cell_length_b 10.70327725 -_cell_length_c 10.70327725 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Si3(SnO6)2 -_chemical_formula_sum 'Zn12 Si12 Sn8 O48' -_cell_volume 943.90532164 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Sn Sn24 1 0.50000000 0.00000000 0.00000000 1 - Sn Sn25 1 0.50000000 0.50000000 0.00000000 1 - Sn Sn26 1 0.00000000 0.50000000 0.50000000 1 - Sn Sn27 1 0.00000000 0.00000000 0.50000000 1 - Sn Sn28 1 0.50000000 0.50000000 0.50000000 1 - Sn Sn29 1 0.00000000 0.50000000 0.00000000 1 - Sn Sn30 1 0.50000000 0.00000000 0.50000000 1 - Sn Sn31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.58653800 0.88973400 0.37623400 1 - O O33 1 0.37623400 0.58653800 0.88973400 1 - O O34 1 0.28969600 0.30319600 0.91346200 1 - O O35 1 0.48650000 0.61026600 0.19680400 1 - O O36 1 0.30319600 0.88973400 0.01350000 1 - O O37 1 0.12376600 0.01350000 0.21030400 1 - O O38 1 0.37623400 0.28969600 0.48650000 1 - O O39 1 0.88973400 0.37623400 0.58653800 1 - O O40 1 0.19680400 0.21030400 0.58653800 1 - O O41 1 0.48650000 0.37623400 0.28969600 1 - O O42 1 0.88973400 0.01350000 0.30319600 1 - O O43 1 0.61026600 0.91346200 0.12376600 1 - O O44 1 0.91346200 0.12376600 0.61026600 1 - O O45 1 0.28969600 0.48650000 0.37623400 1 - O O46 1 0.58653800 0.19680400 0.21030400 1 - O O47 1 0.21030400 0.58653800 0.19680400 1 - O O48 1 0.01350000 0.30319600 0.88973400 1 - O O49 1 0.91346200 0.28969600 0.30319600 1 - O O50 1 0.01350000 0.21030400 0.12376600 1 - O O51 1 0.80319600 0.78969600 0.41346200 1 - O O52 1 0.19680400 0.48650000 0.61026600 1 - O O53 1 0.61026600 0.19680400 0.48650000 1 - O O54 1 0.21030400 0.12376600 0.01350000 1 - O O55 1 0.12376600 0.61026600 0.91346200 1 - O O56 1 0.41346200 0.11026600 0.62376600 1 - O O57 1 0.62376600 0.41346200 0.11026600 1 - O O58 1 0.71030400 0.69680400 0.08653800 1 - O O59 1 0.51350000 0.38973400 0.80319600 1 - O O60 1 0.69680400 0.11026600 0.98650000 1 - O O61 1 0.87623400 0.98650000 0.78969600 1 - O O62 1 0.62376600 0.71030400 0.51350000 1 - O O63 1 0.11026600 0.62376600 0.41346200 1 - O O64 1 0.87623400 0.38973400 0.08653800 1 - O O65 1 0.78969600 0.87623400 0.98650000 1 - O O66 1 0.38973400 0.80319600 0.51350000 1 - O O67 1 0.69680400 0.08653800 0.71030400 1 - O O68 1 0.80319600 0.51350000 0.38973400 1 - O O69 1 0.98650000 0.78969600 0.87623400 1 - O O70 1 0.08653800 0.71030400 0.69680400 1 - O O71 1 0.98650000 0.69680400 0.11026600 1 - O O72 1 0.78969600 0.41346200 0.80319600 1 - O O73 1 0.41346200 0.80319600 0.78969600 1 - O O74 1 0.71030400 0.51350000 0.62376600 1 - O O75 1 0.08653800 0.87623400 0.38973400 1 - O O76 1 0.38973400 0.08653800 0.87623400 1 - O O77 1 0.11026600 0.98650000 0.69680400 1 - O O78 1 0.51350000 0.62376600 0.71030400 1 - O O79 1 0.30319600 0.91346200 0.28969600 1 -" -Ca3Si3(SnO6)2,mvc-3709,Ia-3d,[],0.14486463275000094,{'tags': []},"Full Formula (Ca12 Si12 Sn8 O48) -Reduced Formula: Ca3Si3(SnO6)2 -abc : 10.947715 10.947715 10.947715 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.375 0.125 0 - 1 Ca 0.75 0.125 0.375 -0 - 2 Ca 0.375 0.125 0.25 0 - 3 Ca 0.125 0.375 0.75 0 - 4 Ca 0.25 0.875 0.625 -0 - 5 Ca 0.125 0.25 0.375 0 - 6 Ca 0.625 0.25 0.875 0 - 7 Ca 0.75 0.625 0.875 0 - 8 Ca 0.875 0.75 0.625 0 - 9 Ca 0.875 0.625 0.25 0 - 10 Ca 0.625 0.875 0.75 0 - 11 Ca 0.375 0.75 0.125 0 - 12 Si 0.125 0.75 0.875 0.008 - 13 Si 0.875 0.25 0.125 0.008 - 14 Si 0.75 0.375 0.625 0.009 - 15 Si 0.125 0.875 0.25 0.008 - 16 Si 0.25 0.125 0.875 0.009 - 17 Si 0.375 0.625 0.75 0.008 - 18 Si 0.375 0.25 0.625 0.008 - 19 Si 0.875 0.125 0.75 0.008 - 20 Si 0.625 0.375 0.25 0.008 - 21 Si 0.75 0.875 0.125 0.009 - 22 Si 0.25 0.625 0.375 0.009 - 23 Si 0.625 0.75 0.375 0.008 - 24 Sn 0.5 0 0 0.097 - 25 Sn 0.5 0.5 0 0.28 - 26 Sn 0 0.5 0.5 0.097 - 27 Sn 0 0 0.5 0.097 - 28 Sn 0.5 0.5 0.5 0.28 - 29 Sn 0 0.5 0 0.28 - 30 Sn 0.5 0 0.5 0.097 - 31 Sn 0 0 0 0.28 - 32 O 0.596337 0.891093 0.375988 0.022 - 33 O 0.375988 0.596337 0.891093 0.057 - 34 O 0.279651 0.294756 0.903663 0.054 - 35 O 0.484895 0.608907 0.205244 0.054 - 36 O 0.294756 0.891093 0.015105 0.02 - 37 O 0.124012 0.015105 0.220349 0.057 - 38 O 0.375988 0.279651 0.484895 0.057 - 39 O 0.891093 0.375988 0.596337 0.021 - 40 O 0.205244 0.220349 0.596337 0.02 - 41 O 0.484895 0.375988 0.279651 0.054 - 42 O 0.891093 0.015105 0.294756 0.021 - 43 O 0.608907 0.903663 0.124012 0.021 - 44 O 0.903663 0.124012 0.608907 0.022 - 45 O 0.279651 0.484895 0.375988 0.054 - 46 O 0.596337 0.205244 0.220349 0.022 - 47 O 0.220349 0.596337 0.205244 0.054 - 48 O 0.015105 0.294756 0.891093 0.054 - 49 O 0.903663 0.279651 0.294756 0.022 - 50 O 0.015105 0.220349 0.124012 0.054 - 51 O 0.794756 0.779651 0.403663 0.02 - 52 O 0.205244 0.484895 0.608907 0.02 - 53 O 0.608907 0.205244 0.484895 0.021 - 54 O 0.220349 0.124012 0.015105 0.054 - 55 O 0.124012 0.608907 0.903663 0.057 - 56 O 0.403663 0.108907 0.624012 0.022 - 57 O 0.624012 0.403663 0.108907 0.057 - 58 O 0.720349 0.705244 0.096337 0.054 - 59 O 0.515105 0.391093 0.794756 0.054 - 60 O 0.705244 0.108907 0.984895 0.02 - 61 O 0.875988 0.984895 0.779651 0.057 - 62 O 0.624012 0.720349 0.515105 0.057 - 63 O 0.108907 0.624012 0.403663 0.021 - 64 O 0.875988 0.391093 0.096337 0.057 - 65 O 0.779651 0.875988 0.984895 0.054 - 66 O 0.391093 0.794756 0.515105 0.021 - 67 O 0.705244 0.096337 0.720349 0.02 - 68 O 0.794756 0.515105 0.391093 0.02 - 69 O 0.984895 0.779651 0.875988 0.054 - 70 O 0.096337 0.720349 0.705244 0.022 - 71 O 0.984895 0.705244 0.108907 0.054 - 72 O 0.779651 0.403663 0.794756 0.054 - 73 O 0.403663 0.794756 0.779651 0.022 - 74 O 0.720349 0.515105 0.624012 0.054 - 75 O 0.096337 0.875988 0.391093 0.022 - 76 O 0.391093 0.096337 0.875988 0.021 - 77 O 0.108907 0.984895 0.705244 0.021 - 78 O 0.515105 0.624012 0.720349 0.054 - 79 O 0.294756 0.903663 0.279651 0.02","# generated using pymatgen -data_Ca3Si3(SnO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.94771465 -_cell_length_b 10.94771465 -_cell_length_c 10.94771465 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Si3(SnO6)2 -_chemical_formula_sum 'Ca12 Si12 Sn8 O48' -_cell_volume 1010.06312530 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca1 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca2 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca3 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca4 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca5 1 0.12500000 0.25000000 0.37500000 1 - Ca Ca6 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca7 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca8 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca9 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca10 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Sn Sn24 1 0.50000000 0.00000000 0.00000000 1 - Sn Sn25 1 0.50000000 0.50000000 0.00000000 1 - Sn Sn26 1 0.00000000 0.50000000 0.50000000 1 - Sn Sn27 1 0.00000000 0.00000000 0.50000000 1 - Sn Sn28 1 0.50000000 0.50000000 0.50000000 1 - Sn Sn29 1 0.00000000 0.50000000 0.00000000 1 - Sn Sn30 1 0.50000000 0.00000000 0.50000000 1 - Sn Sn31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59633700 0.89109300 0.37598800 1 - O O33 1 0.37598800 0.59633700 0.89109300 1 - O O34 1 0.27965100 0.29475600 0.90366300 1 - O O35 1 0.48489500 0.60890700 0.20524400 1 - O O36 1 0.29475600 0.89109300 0.01510500 1 - O O37 1 0.12401200 0.01510500 0.22034900 1 - O O38 1 0.37598800 0.27965100 0.48489500 1 - O O39 1 0.89109300 0.37598800 0.59633700 1 - O O40 1 0.20524400 0.22034900 0.59633700 1 - O O41 1 0.48489500 0.37598800 0.27965100 1 - O O42 1 0.89109300 0.01510500 0.29475600 1 - O O43 1 0.60890700 0.90366300 0.12401200 1 - O O44 1 0.90366300 0.12401200 0.60890700 1 - O O45 1 0.27965100 0.48489500 0.37598800 1 - O O46 1 0.59633700 0.20524400 0.22034900 1 - O O47 1 0.22034900 0.59633700 0.20524400 1 - O O48 1 0.01510500 0.29475600 0.89109300 1 - O O49 1 0.90366300 0.27965100 0.29475600 1 - O O50 1 0.01510500 0.22034900 0.12401200 1 - O O51 1 0.79475600 0.77965100 0.40366300 1 - O O52 1 0.20524400 0.48489500 0.60890700 1 - O O53 1 0.60890700 0.20524400 0.48489500 1 - O O54 1 0.22034900 0.12401200 0.01510500 1 - O O55 1 0.12401200 0.60890700 0.90366300 1 - O O56 1 0.40366300 0.10890700 0.62401200 1 - O O57 1 0.62401200 0.40366300 0.10890700 1 - O O58 1 0.72034900 0.70524400 0.09633700 1 - O O59 1 0.51510500 0.39109300 0.79475600 1 - O O60 1 0.70524400 0.10890700 0.98489500 1 - O O61 1 0.87598800 0.98489500 0.77965100 1 - O O62 1 0.62401200 0.72034900 0.51510500 1 - O O63 1 0.10890700 0.62401200 0.40366300 1 - O O64 1 0.87598800 0.39109300 0.09633700 1 - O O65 1 0.77965100 0.87598800 0.98489500 1 - O O66 1 0.39109300 0.79475600 0.51510500 1 - O O67 1 0.70524400 0.09633700 0.72034900 1 - O O68 1 0.79475600 0.51510500 0.39109300 1 - O O69 1 0.98489500 0.77965100 0.87598800 1 - O O70 1 0.09633700 0.72034900 0.70524400 1 - O O71 1 0.98489500 0.70524400 0.10890700 1 - O O72 1 0.77965100 0.40366300 0.79475600 1 - O O73 1 0.40366300 0.79475600 0.77965100 1 - O O74 1 0.72034900 0.51510500 0.62401200 1 - O O75 1 0.09633700 0.87598800 0.39109300 1 - O O76 1 0.39109300 0.09633700 0.87598800 1 - O O77 1 0.10890700 0.98489500 0.70524400 1 - O O78 1 0.51510500 0.62401200 0.72034900 1 - O O79 1 0.29475600 0.90366300 0.27965100 1 -" -Mg3Co2(SiO4)3,mvc-3872,Ia-3d,[],0.08669269049999606,{'tags': []},"Full Formula (Mg12 Co8 Si12 O48) -Reduced Formula: Mg3Co2(SiO4)3 -abc : 10.013012 10.013012 10.013012 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0 - 1 Mg 0.75 0.125 0.375 0 - 2 Mg 0.375 0.125 0.25 0 - 3 Mg 0.125 0.375 0.75 0 - 4 Mg 0.25 0.875 0.625 0 - 5 Mg 0.125 0.25 0.375 0 - 6 Mg 0.625 0.25 0.875 0 - 7 Mg 0.75 0.625 0.875 0 - 8 Mg 0.875 0.75 0.625 0 - 9 Mg 0.875 0.625 0.25 0 - 10 Mg 0.625 0.875 0.75 0 - 11 Mg 0.375 0.75 0.125 0 - 12 Co 0.5 0 0 -0 - 13 Co 0.5 0.5 0 -0 - 14 Co 0 0.5 0.5 -0 - 15 Co 0 0 0.5 -0 - 16 Co 0.5 0.5 0.5 -0 - 17 Co 0 0.5 0 -0 - 18 Co 0.5 0 0.5 -0 - 19 Co 0 0 0 -0 - 20 Si 0.125 0.75 0.875 -0 - 21 Si 0.875 0.25 0.125 -0 - 22 Si 0.75 0.375 0.625 -0 - 23 Si 0.125 0.875 0.25 -0 - 24 Si 0.25 0.125 0.875 -0 - 25 Si 0.375 0.625 0.75 -0 - 26 Si 0.375 0.25 0.625 -0 - 27 Si 0.875 0.125 0.75 -0 - 28 Si 0.625 0.375 0.25 -0 - 29 Si 0.75 0.875 0.125 -0 - 30 Si 0.25 0.625 0.375 -0 - 31 Si 0.625 0.75 0.375 -0 - 32 O 0.583583 0.897166 0.377335 -0 - 33 O 0.377335 0.583583 0.897166 -0 - 34 O 0.293752 0.313583 0.916417 -0 - 35 O 0.480169 0.602834 0.186417 -0 - 36 O 0.313583 0.897166 0.019831 -0 - 37 O 0.122665 0.019831 0.206248 -0 - 38 O 0.377335 0.293752 0.480169 -0 - 39 O 0.897166 0.377335 0.583583 -0 - 40 O 0.186417 0.206248 0.583583 -0 - 41 O 0.480169 0.377335 0.293752 -0 - 42 O 0.897166 0.019831 0.313583 -0 - 43 O 0.602834 0.916417 0.122665 -0 - 44 O 0.916417 0.122665 0.602834 -0 - 45 O 0.293752 0.480169 0.377335 -0 - 46 O 0.583583 0.186417 0.206248 -0 - 47 O 0.206248 0.583583 0.186417 -0 - 48 O 0.019831 0.313583 0.897166 -0 - 49 O 0.916417 0.293752 0.313583 -0 - 50 O 0.019831 0.206248 0.122665 -0 - 51 O 0.813583 0.793752 0.416417 -0 - 52 O 0.186417 0.480169 0.602834 -0 - 53 O 0.602834 0.186417 0.480169 -0 - 54 O 0.206248 0.122665 0.019831 -0 - 55 O 0.122665 0.602834 0.916417 -0 - 56 O 0.416417 0.102834 0.622665 -0 - 57 O 0.622665 0.416417 0.102834 -0 - 58 O 0.706248 0.686417 0.083583 -0 - 59 O 0.519831 0.397166 0.813583 -0 - 60 O 0.686417 0.102834 0.980169 -0 - 61 O 0.877335 0.980169 0.793752 -0 - 62 O 0.622665 0.706248 0.519831 -0 - 63 O 0.102834 0.622665 0.416417 -0 - 64 O 0.877335 0.397166 0.083583 -0 - 65 O 0.793752 0.877335 0.980169 -0 - 66 O 0.397166 0.813583 0.519831 -0 - 67 O 0.686417 0.083583 0.706248 -0 - 68 O 0.813583 0.519831 0.397166 -0 - 69 O 0.980169 0.793752 0.877335 -0 - 70 O 0.083583 0.706248 0.686417 -0 - 71 O 0.980169 0.686417 0.102834 -0 - 72 O 0.793752 0.416417 0.813583 -0 - 73 O 0.416417 0.813583 0.793752 -0 - 74 O 0.706248 0.519831 0.622665 -0 - 75 O 0.083583 0.877335 0.397166 -0 - 76 O 0.397166 0.083583 0.877335 -0 - 77 O 0.102834 0.980169 0.686417 -0 - 78 O 0.519831 0.622665 0.706248 -0 - 79 O 0.313583 0.916417 0.293752 -0","# generated using pymatgen -data_Mg3Co2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.01301170 -_cell_length_b 10.01301170 -_cell_length_c 10.01301170 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Co2(SiO4)3 -_chemical_formula_sum 'Mg12 Co8 Si12 O48' -_cell_volume 772.80919377 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Co Co12 1 0.50000000 0.00000000 0.00000000 1 - Co Co13 1 0.50000000 0.50000000 0.00000000 1 - Co Co14 1 0.00000000 0.50000000 0.50000000 1 - Co Co15 1 0.00000000 0.00000000 0.50000000 1 - Co Co16 1 0.50000000 0.50000000 0.50000000 1 - Co Co17 1 0.00000000 0.50000000 0.00000000 1 - Co Co18 1 0.50000000 0.00000000 0.50000000 1 - Co Co19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58358300 0.89716600 0.37733500 1 - O O33 1 0.37733500 0.58358300 0.89716600 1 - O O34 1 0.29375200 0.31358300 0.91641700 1 - O O35 1 0.48016900 0.60283400 0.18641700 1 - O O36 1 0.31358300 0.89716600 0.01983100 1 - O O37 1 0.12266500 0.01983100 0.20624800 1 - O O38 1 0.37733500 0.29375200 0.48016900 1 - O O39 1 0.89716600 0.37733500 0.58358300 1 - O O40 1 0.18641700 0.20624800 0.58358300 1 - O O41 1 0.48016900 0.37733500 0.29375200 1 - O O42 1 0.89716600 0.01983100 0.31358300 1 - O O43 1 0.60283400 0.91641700 0.12266500 1 - O O44 1 0.91641700 0.12266500 0.60283400 1 - O O45 1 0.29375200 0.48016900 0.37733500 1 - O O46 1 0.58358300 0.18641700 0.20624800 1 - O O47 1 0.20624800 0.58358300 0.18641700 1 - O O48 1 0.01983100 0.31358300 0.89716600 1 - O O49 1 0.91641700 0.29375200 0.31358300 1 - O O50 1 0.01983100 0.20624800 0.12266500 1 - O O51 1 0.81358300 0.79375200 0.41641700 1 - O O52 1 0.18641700 0.48016900 0.60283400 1 - O O53 1 0.60283400 0.18641700 0.48016900 1 - O O54 1 0.20624800 0.12266500 0.01983100 1 - O O55 1 0.12266500 0.60283400 0.91641700 1 - O O56 1 0.41641700 0.10283400 0.62266500 1 - O O57 1 0.62266500 0.41641700 0.10283400 1 - O O58 1 0.70624800 0.68641700 0.08358300 1 - O O59 1 0.51983100 0.39716600 0.81358300 1 - O O60 1 0.68641700 0.10283400 0.98016900 1 - O O61 1 0.87733500 0.98016900 0.79375200 1 - O O62 1 0.62266500 0.70624800 0.51983100 1 - O O63 1 0.10283400 0.62266500 0.41641700 1 - O O64 1 0.87733500 0.39716600 0.08358300 1 - O O65 1 0.79375200 0.87733500 0.98016900 1 - O O66 1 0.39716600 0.81358300 0.51983100 1 - O O67 1 0.68641700 0.08358300 0.70624800 1 - O O68 1 0.81358300 0.51983100 0.39716600 1 - O O69 1 0.98016900 0.79375200 0.87733500 1 - O O70 1 0.08358300 0.70624800 0.68641700 1 - O O71 1 0.98016900 0.68641700 0.10283400 1 - O O72 1 0.79375200 0.41641700 0.81358300 1 - O O73 1 0.41641700 0.81358300 0.79375200 1 - O O74 1 0.70624800 0.51983100 0.62266500 1 - O O75 1 0.08358300 0.87733500 0.39716600 1 - O O76 1 0.39716600 0.08358300 0.87733500 1 - O O77 1 0.10283400 0.98016900 0.68641700 1 - O O78 1 0.51983100 0.62266500 0.70624800 1 - O O79 1 0.31358300 0.91641700 0.29375200 1 -" -Mg3Si3(MoO6)2,mvc-3885,Ia-3d,[],0.08577458943749683,{'tags': []},"Full Formula (Mg12 Si12 Mo8 O48) -Reduced Formula: Mg3Si3(MoO6)2 -abc : 10.448347 10.448347 10.448347 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.375 0.125 0.002 - 1 Mg 0.75 0.125 0.375 0.002 - 2 Mg 0.375 0.125 0.25 0.002 - 3 Mg 0.125 0.375 0.75 0.002 - 4 Mg 0.25 0.875 0.625 0.002 - 5 Mg 0.125 0.25 0.375 0.002 - 6 Mg 0.625 0.25 0.875 0.002 - 7 Mg 0.75 0.625 0.875 0.002 - 8 Mg 0.875 0.75 0.625 0.002 - 9 Mg 0.875 0.625 0.25 0.002 - 10 Mg 0.625 0.875 0.75 0.002 - 11 Mg 0.375 0.75 0.125 0.002 - 12 Si 0.125 0.75 0.875 0.013 - 13 Si 0.875 0.25 0.125 0.013 - 14 Si 0.75 0.375 0.625 0.013 - 15 Si 0.125 0.875 0.25 0.013 - 16 Si 0.25 0.125 0.875 0.013 - 17 Si 0.375 0.625 0.75 0.013 - 18 Si 0.375 0.25 0.625 0.013 - 19 Si 0.875 0.125 0.75 0.013 - 20 Si 0.625 0.375 0.25 0.013 - 21 Si 0.75 0.875 0.125 0.013 - 22 Si 0.25 0.625 0.375 0.013 - 23 Si 0.625 0.75 0.375 0.013 - 24 Mo 0.5 0 0 2.742 - 25 Mo 0.5 0.5 0 2.742 - 26 Mo 0 0.5 0.5 2.742 - 27 Mo 0 0 0.5 2.742 - 28 Mo 0.5 0.5 0.5 2.742 - 29 Mo 0 0.5 0 2.742 - 30 Mo 0.5 0 0.5 2.742 - 31 Mo 0 0 0 2.742 - 32 O 0.593551 0.894891 0.37264 0.015 - 33 O 0.37264 0.593551 0.894891 0.015 - 34 O 0.279089 0.30134 0.906449 0.015 - 35 O 0.477749 0.605109 0.19866 0.015 - 36 O 0.30134 0.894891 0.022251 0.015 - 37 O 0.12736 0.022251 0.220911 0.015 - 38 O 0.37264 0.279089 0.477749 0.015 - 39 O 0.894891 0.37264 0.593551 0.015 - 40 O 0.19866 0.220911 0.593551 0.015 - 41 O 0.477749 0.37264 0.279089 0.015 - 42 O 0.894891 0.022251 0.30134 0.015 - 43 O 0.605109 0.906449 0.12736 0.015 - 44 O 0.906449 0.12736 0.605109 0.015 - 45 O 0.279089 0.477749 0.37264 0.015 - 46 O 0.593551 0.19866 0.220911 0.015 - 47 O 0.220911 0.593551 0.19866 0.015 - 48 O 0.022251 0.30134 0.894891 0.015 - 49 O 0.906449 0.279089 0.30134 0.015 - 50 O 0.022251 0.220911 0.12736 0.015 - 51 O 0.80134 0.779089 0.406449 0.015 - 52 O 0.19866 0.477749 0.605109 0.015 - 53 O 0.605109 0.19866 0.477749 0.015 - 54 O 0.220911 0.12736 0.022251 0.015 - 55 O 0.12736 0.605109 0.906449 0.015 - 56 O 0.406449 0.105109 0.62736 0.015 - 57 O 0.62736 0.406449 0.105109 0.015 - 58 O 0.720911 0.69866 0.093551 0.015 - 59 O 0.522251 0.394891 0.80134 0.015 - 60 O 0.69866 0.105109 0.977749 0.015 - 61 O 0.87264 0.977749 0.779089 0.015 - 62 O 0.62736 0.720911 0.522251 0.015 - 63 O 0.105109 0.62736 0.406449 0.015 - 64 O 0.87264 0.394891 0.093551 0.015 - 65 O 0.779089 0.87264 0.977749 0.015 - 66 O 0.394891 0.80134 0.522251 0.015 - 67 O 0.69866 0.093551 0.720911 0.015 - 68 O 0.80134 0.522251 0.394891 0.015 - 69 O 0.977749 0.779089 0.87264 0.015 - 70 O 0.093551 0.720911 0.69866 0.015 - 71 O 0.977749 0.69866 0.105109 0.015 - 72 O 0.779089 0.406449 0.80134 0.015 - 73 O 0.406449 0.80134 0.779089 0.015 - 74 O 0.720911 0.522251 0.62736 0.015 - 75 O 0.093551 0.87264 0.394891 0.015 - 76 O 0.394891 0.093551 0.87264 0.015 - 77 O 0.105109 0.977749 0.69866 0.015 - 78 O 0.522251 0.62736 0.720911 0.015 - 79 O 0.30134 0.906449 0.279089 0.015","# generated using pymatgen -data_Mg3Si3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.44834708 -_cell_length_b 10.44834708 -_cell_length_c 10.44834708 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Si3(MoO6)2 -_chemical_formula_sum 'Mg12 Si12 Mo8 O48' -_cell_volume 878.05330507 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg1 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg2 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg3 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg4 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg5 1 0.12500000 0.25000000 0.37500000 1 - Mg Mg6 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg7 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg8 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg9 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg10 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg11 1 0.37500000 0.75000000 0.12500000 1 - Si Si12 1 0.12500000 0.75000000 0.87500000 1 - Si Si13 1 0.87500000 0.25000000 0.12500000 1 - Si Si14 1 0.75000000 0.37500000 0.62500000 1 - Si Si15 1 0.12500000 0.87500000 0.25000000 1 - Si Si16 1 0.25000000 0.12500000 0.87500000 1 - Si Si17 1 0.37500000 0.62500000 0.75000000 1 - Si Si18 1 0.37500000 0.25000000 0.62500000 1 - Si Si19 1 0.87500000 0.12500000 0.75000000 1 - Si Si20 1 0.62500000 0.37500000 0.25000000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Mo Mo24 1 0.50000000 0.00000000 0.00000000 1 - Mo Mo25 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo26 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo27 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo28 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo29 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo30 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.59355100 0.89489100 0.37264000 1 - O O33 1 0.37264000 0.59355100 0.89489100 1 - O O34 1 0.27908900 0.30134000 0.90644900 1 - O O35 1 0.47774900 0.60510900 0.19866000 1 - O O36 1 0.30134000 0.89489100 0.02225100 1 - O O37 1 0.12736000 0.02225100 0.22091100 1 - O O38 1 0.37264000 0.27908900 0.47774900 1 - O O39 1 0.89489100 0.37264000 0.59355100 1 - O O40 1 0.19866000 0.22091100 0.59355100 1 - O O41 1 0.47774900 0.37264000 0.27908900 1 - O O42 1 0.89489100 0.02225100 0.30134000 1 - O O43 1 0.60510900 0.90644900 0.12736000 1 - O O44 1 0.90644900 0.12736000 0.60510900 1 - O O45 1 0.27908900 0.47774900 0.37264000 1 - O O46 1 0.59355100 0.19866000 0.22091100 1 - O O47 1 0.22091100 0.59355100 0.19866000 1 - O O48 1 0.02225100 0.30134000 0.89489100 1 - O O49 1 0.90644900 0.27908900 0.30134000 1 - O O50 1 0.02225100 0.22091100 0.12736000 1 - O O51 1 0.80134000 0.77908900 0.40644900 1 - O O52 1 0.19866000 0.47774900 0.60510900 1 - O O53 1 0.60510900 0.19866000 0.47774900 1 - O O54 1 0.22091100 0.12736000 0.02225100 1 - O O55 1 0.12736000 0.60510900 0.90644900 1 - O O56 1 0.40644900 0.10510900 0.62736000 1 - O O57 1 0.62736000 0.40644900 0.10510900 1 - O O58 1 0.72091100 0.69866000 0.09355100 1 - O O59 1 0.52225100 0.39489100 0.80134000 1 - O O60 1 0.69866000 0.10510900 0.97774900 1 - O O61 1 0.87264000 0.97774900 0.77908900 1 - O O62 1 0.62736000 0.72091100 0.52225100 1 - O O63 1 0.10510900 0.62736000 0.40644900 1 - O O64 1 0.87264000 0.39489100 0.09355100 1 - O O65 1 0.77908900 0.87264000 0.97774900 1 - O O66 1 0.39489100 0.80134000 0.52225100 1 - O O67 1 0.69866000 0.09355100 0.72091100 1 - O O68 1 0.80134000 0.52225100 0.39489100 1 - O O69 1 0.97774900 0.77908900 0.87264000 1 - O O70 1 0.09355100 0.72091100 0.69866000 1 - O O71 1 0.97774900 0.69866000 0.10510900 1 - O O72 1 0.77908900 0.40644900 0.80134000 1 - O O73 1 0.40644900 0.80134000 0.77908900 1 - O O74 1 0.72091100 0.52225100 0.62736000 1 - O O75 1 0.09355100 0.87264000 0.39489100 1 - O O76 1 0.39489100 0.09355100 0.87264000 1 - O O77 1 0.10510900 0.97774900 0.69866000 1 - O O78 1 0.52225100 0.62736000 0.72091100 1 - O O79 1 0.30134000 0.90644900 0.27908900 1 -" -Mn2Zn3(SiO4)3,mvc-3903,Ia-3d,[],0.1824864403750075,{'tags': []},"Full Formula (Mn8 Zn12 Si12 O48) -Reduced Formula: Mn2Zn3(SiO4)3 -abc : 10.280198 10.280198 10.280198 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.5 0 0 4.038 - 1 Mn 0.5 0.5 0 4.038 - 2 Mn 0 0.5 0.5 4.038 - 3 Mn 0 0 0.5 4.038 - 4 Mn 0.5 0.5 0.5 4.039 - 5 Mn 0 0.5 0 4.038 - 6 Mn 0.5 0 0.5 4.038 - 7 Mn 0 0 0 4.038 - 8 Zn 0.25 0.375 0.125 0.009 - 9 Zn 0.75 0.125 0.375 0.009 - 10 Zn 0.375 0.125 0.25 0.009 - 11 Zn 0.125 0.375 0.75 0.009 - 12 Zn 0.25 0.875 0.625 0.009 - 13 Zn 0.125 0.25 0.375 0.009 - 14 Zn 0.625 0.25 0.875 0.009 - 15 Zn 0.75 0.625 0.875 0.009 - 16 Zn 0.875 0.75 0.625 0.009 - 17 Zn 0.875 0.625 0.25 0.009 - 18 Zn 0.625 0.875 0.75 0.009 - 19 Zn 0.375 0.75 0.125 0.009 - 20 Si 0.125 0.75 0.875 0.014 - 21 Si 0.875 0.25 0.125 0.014 - 22 Si 0.75 0.375 0.625 0.014 - 23 Si 0.125 0.875 0.25 0.014 - 24 Si 0.25 0.125 0.875 0.014 - 25 Si 0.375 0.625 0.75 0.014 - 26 Si 0.375 0.25 0.625 0.014 - 27 Si 0.875 0.125 0.75 0.014 - 28 Si 0.625 0.375 0.25 0.014 - 29 Si 0.75 0.875 0.125 0.014 - 30 Si 0.25 0.625 0.375 0.014 - 31 Si 0.625 0.75 0.375 0.014 - 32 O 0.587257 0.895083 0.375386 -0.031 - 33 O 0.375386 0.587257 0.895083 -0.031 - 34 O 0.288129 0.307826 0.912743 -0.031 - 35 O 0.480304 0.604917 0.192174 -0.031 - 36 O 0.307826 0.895083 0.019696 -0.031 - 37 O 0.124614 0.019696 0.211871 -0.03 - 38 O 0.375386 0.288129 0.480304 -0.031 - 39 O 0.895083 0.375386 0.587257 -0.031 - 40 O 0.192174 0.211871 0.587257 -0.031 - 41 O 0.480304 0.375386 0.288129 -0.03 - 42 O 0.895083 0.019696 0.307826 -0.03 - 43 O 0.604917 0.912743 0.124614 -0.031 - 44 O 0.912743 0.124614 0.604917 -0.031 - 45 O 0.288129 0.480304 0.375386 -0.03 - 46 O 0.587257 0.192174 0.211871 -0.031 - 47 O 0.211871 0.587257 0.192174 -0.031 - 48 O 0.019696 0.307826 0.895083 -0.031 - 49 O 0.912743 0.288129 0.307826 -0.031 - 50 O 0.019696 0.211871 0.124614 -0.031 - 51 O 0.807826 0.788129 0.412743 -0.031 - 52 O 0.192174 0.480304 0.604917 -0.031 - 53 O 0.604917 0.192174 0.480304 -0.031 - 54 O 0.211871 0.124614 0.019696 -0.031 - 55 O 0.124614 0.604917 0.912743 -0.03 - 56 O 0.412743 0.104917 0.624614 -0.031 - 57 O 0.624614 0.412743 0.104917 -0.031 - 58 O 0.711871 0.692174 0.087257 -0.031 - 59 O 0.519696 0.395083 0.807826 -0.031 - 60 O 0.692174 0.104917 0.980304 -0.031 - 61 O 0.875386 0.980304 0.788129 -0.03 - 62 O 0.624614 0.711871 0.519696 -0.031 - 63 O 0.104917 0.624614 0.412743 -0.031 - 64 O 0.875386 0.395083 0.087257 -0.03 - 65 O 0.788129 0.875386 0.980304 -0.031 - 66 O 0.395083 0.807826 0.519696 -0.031 - 67 O 0.692174 0.087257 0.711871 -0.03 - 68 O 0.807826 0.519696 0.395083 -0.031 - 69 O 0.980304 0.788129 0.875386 -0.031 - 70 O 0.087257 0.711871 0.692174 -0.031 - 71 O 0.980304 0.692174 0.104917 -0.031 - 72 O 0.788129 0.412743 0.807826 -0.031 - 73 O 0.412743 0.807826 0.788129 -0.031 - 74 O 0.711871 0.519696 0.624614 -0.03 - 75 O 0.087257 0.875386 0.395083 -0.031 - 76 O 0.395083 0.087257 0.875386 -0.031 - 77 O 0.104917 0.980304 0.692174 -0.03 - 78 O 0.519696 0.624614 0.711871 -0.03 - 79 O 0.307826 0.912743 0.288129 -0.03","# generated using pymatgen -data_Mn2Zn3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.28019786 -_cell_length_b 10.28019786 -_cell_length_c 10.28019786 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn2Zn3(SiO4)3 -_chemical_formula_sum 'Mn8 Zn12 Si12 O48' -_cell_volume 836.33934683 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn1 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn2 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn3 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn4 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn5 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn6 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn7 1 0.00000000 0.00000000 0.00000000 1 - Zn Zn8 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn9 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn10 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn11 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn12 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn13 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn14 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn15 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn16 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn17 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn18 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58725700 0.89508300 0.37538600 1 - O O33 1 0.37538600 0.58725700 0.89508300 1 - O O34 1 0.28812900 0.30782600 0.91274300 1 - O O35 1 0.48030400 0.60491700 0.19217400 1 - O O36 1 0.30782600 0.89508300 0.01969600 1 - O O37 1 0.12461400 0.01969600 0.21187100 1 - O O38 1 0.37538600 0.28812900 0.48030400 1 - O O39 1 0.89508300 0.37538600 0.58725700 1 - O O40 1 0.19217400 0.21187100 0.58725700 1 - O O41 1 0.48030400 0.37538600 0.28812900 1 - O O42 1 0.89508300 0.01969600 0.30782600 1 - O O43 1 0.60491700 0.91274300 0.12461400 1 - O O44 1 0.91274300 0.12461400 0.60491700 1 - O O45 1 0.28812900 0.48030400 0.37538600 1 - O O46 1 0.58725700 0.19217400 0.21187100 1 - O O47 1 0.21187100 0.58725700 0.19217400 1 - O O48 1 0.01969600 0.30782600 0.89508300 1 - O O49 1 0.91274300 0.28812900 0.30782600 1 - O O50 1 0.01969600 0.21187100 0.12461400 1 - O O51 1 0.80782600 0.78812900 0.41274300 1 - O O52 1 0.19217400 0.48030400 0.60491700 1 - O O53 1 0.60491700 0.19217400 0.48030400 1 - O O54 1 0.21187100 0.12461400 0.01969600 1 - O O55 1 0.12461400 0.60491700 0.91274300 1 - O O56 1 0.41274300 0.10491700 0.62461400 1 - O O57 1 0.62461400 0.41274300 0.10491700 1 - O O58 1 0.71187100 0.69217400 0.08725700 1 - O O59 1 0.51969600 0.39508300 0.80782600 1 - O O60 1 0.69217400 0.10491700 0.98030400 1 - O O61 1 0.87538600 0.98030400 0.78812900 1 - O O62 1 0.62461400 0.71187100 0.51969600 1 - O O63 1 0.10491700 0.62461400 0.41274300 1 - O O64 1 0.87538600 0.39508300 0.08725700 1 - O O65 1 0.78812900 0.87538600 0.98030400 1 - O O66 1 0.39508300 0.80782600 0.51969600 1 - O O67 1 0.69217400 0.08725700 0.71187100 1 - O O68 1 0.80782600 0.51969600 0.39508300 1 - O O69 1 0.98030400 0.78812900 0.87538600 1 - O O70 1 0.08725700 0.71187100 0.69217400 1 - O O71 1 0.98030400 0.69217400 0.10491700 1 - O O72 1 0.78812900 0.41274300 0.80782600 1 - O O73 1 0.41274300 0.80782600 0.78812900 1 - O O74 1 0.71187100 0.51969600 0.62461400 1 - O O75 1 0.08725700 0.87538600 0.39508300 1 - O O76 1 0.39508300 0.08725700 0.87538600 1 - O O77 1 0.10491700 0.98030400 0.69217400 1 - O O78 1 0.51969600 0.62461400 0.71187100 1 - O O79 1 0.30782600 0.91274300 0.28812900 1 -" -Zn3Co2(SiO4)3,mvc-3915,Ia-3d,[],0.15172852073684862,{'tags': []},"Full Formula (Zn12 Co8 Si12 O48) -Reduced Formula: Zn3Co2(SiO4)3 -abc : 10.060461 10.060461 10.060461 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.375 0.125 -0 - 1 Zn 0.75 0.125 0.375 -0 - 2 Zn 0.375 0.125 0.25 -0 - 3 Zn 0.125 0.375 0.75 -0 - 4 Zn 0.25 0.875 0.625 -0 - 5 Zn 0.125 0.25 0.375 -0 - 6 Zn 0.625 0.25 0.875 -0 - 7 Zn 0.75 0.625 0.875 -0 - 8 Zn 0.875 0.75 0.625 -0 - 9 Zn 0.875 0.625 0.25 -0 - 10 Zn 0.625 0.875 0.75 -0 - 11 Zn 0.375 0.75 0.125 -0 - 12 Co 0.5 0 0 -0 - 13 Co 0.5 0.5 0 -0 - 14 Co 0 0.5 0.5 -0 - 15 Co 0 0 0.5 -0 - 16 Co 0.5 0.5 0.5 -0 - 17 Co 0 0.5 0 -0 - 18 Co 0.5 0 0.5 -0 - 19 Co 0 0 0 -0 - 20 Si 0.125 0.75 0.875 -0 - 21 Si 0.875 0.25 0.125 -0 - 22 Si 0.75 0.375 0.625 -0 - 23 Si 0.125 0.875 0.25 -0 - 24 Si 0.25 0.125 0.875 -0 - 25 Si 0.375 0.625 0.75 -0 - 26 Si 0.375 0.25 0.625 -0 - 27 Si 0.875 0.125 0.75 -0 - 28 Si 0.625 0.375 0.25 -0 - 29 Si 0.75 0.875 0.125 -0 - 30 Si 0.25 0.625 0.375 -0 - 31 Si 0.625 0.75 0.375 -0 - 32 O 0.58226 0.896289 0.378538 -0 - 33 O 0.378538 0.58226 0.896289 -0 - 34 O 0.296278 0.314029 0.91774 -0 - 35 O 0.482249 0.603711 0.185971 -0 - 36 O 0.314029 0.896289 0.017751 -0 - 37 O 0.121462 0.017751 0.203722 -0 - 38 O 0.378538 0.296278 0.482249 -0 - 39 O 0.896289 0.378538 0.58226 -0 - 40 O 0.185971 0.203722 0.58226 -0 - 41 O 0.482249 0.378538 0.296278 -0 - 42 O 0.896289 0.017751 0.314029 -0 - 43 O 0.603711 0.91774 0.121462 -0 - 44 O 0.91774 0.121462 0.603711 -0 - 45 O 0.296278 0.482249 0.378538 -0 - 46 O 0.58226 0.185971 0.203722 -0 - 47 O 0.203722 0.58226 0.185971 -0 - 48 O 0.017751 0.314029 0.896289 -0 - 49 O 0.91774 0.296278 0.314029 -0 - 50 O 0.017751 0.203722 0.121462 -0 - 51 O 0.814029 0.796278 0.41774 -0 - 52 O 0.185971 0.482249 0.603711 -0 - 53 O 0.603711 0.185971 0.482249 -0 - 54 O 0.203722 0.121462 0.017751 -0 - 55 O 0.121462 0.603711 0.91774 -0 - 56 O 0.41774 0.103711 0.621462 -0 - 57 O 0.621462 0.41774 0.103711 -0 - 58 O 0.703722 0.685971 0.08226 -0 - 59 O 0.517751 0.396289 0.814029 -0 - 60 O 0.685971 0.103711 0.982249 -0 - 61 O 0.878538 0.982249 0.796278 -0 - 62 O 0.621462 0.703722 0.517751 -0 - 63 O 0.103711 0.621462 0.41774 -0 - 64 O 0.878538 0.396289 0.08226 -0 - 65 O 0.796278 0.878538 0.982249 -0 - 66 O 0.396289 0.814029 0.517751 -0 - 67 O 0.685971 0.08226 0.703722 -0 - 68 O 0.814029 0.517751 0.396289 -0 - 69 O 0.982249 0.796278 0.878538 -0 - 70 O 0.08226 0.703722 0.685971 -0 - 71 O 0.982249 0.685971 0.103711 -0 - 72 O 0.796278 0.41774 0.814029 -0 - 73 O 0.41774 0.814029 0.796278 -0 - 74 O 0.703722 0.517751 0.621462 -0 - 75 O 0.08226 0.878538 0.396289 -0 - 76 O 0.396289 0.08226 0.878538 -0 - 77 O 0.103711 0.982249 0.685971 -0 - 78 O 0.517751 0.621462 0.703722 -0 - 79 O 0.314029 0.91774 0.296278 -0","# generated using pymatgen -data_Zn3Co2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.06046123 -_cell_length_b 10.06046123 -_cell_length_c 10.06046123 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Co2(SiO4)3 -_chemical_formula_sum 'Zn12 Co8 Si12 O48' -_cell_volume 783.84787386 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn1 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn2 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn3 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn4 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn5 1 0.12500000 0.25000000 0.37500000 1 - Zn Zn6 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn7 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn8 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn9 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.37500000 0.75000000 0.12500000 1 - Co Co12 1 0.50000000 0.00000000 0.00000000 1 - Co Co13 1 0.50000000 0.50000000 0.00000000 1 - Co Co14 1 0.00000000 0.50000000 0.50000000 1 - Co Co15 1 0.00000000 0.00000000 0.50000000 1 - Co Co16 1 0.50000000 0.50000000 0.50000000 1 - Co Co17 1 0.00000000 0.50000000 0.00000000 1 - Co Co18 1 0.50000000 0.00000000 0.50000000 1 - Co Co19 1 0.00000000 0.00000000 0.00000000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.87500000 0.25000000 0.12500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.12500000 0.87500000 0.25000000 1 - Si Si24 1 0.25000000 0.12500000 0.87500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.37500000 0.25000000 0.62500000 1 - Si Si27 1 0.87500000 0.12500000 0.75000000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.75000000 0.87500000 0.12500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.58226000 0.89628900 0.37853800 1 - O O33 1 0.37853800 0.58226000 0.89628900 1 - O O34 1 0.29627800 0.31402900 0.91774000 1 - O O35 1 0.48224900 0.60371100 0.18597100 1 - O O36 1 0.31402900 0.89628900 0.01775100 1 - O O37 1 0.12146200 0.01775100 0.20372200 1 - O O38 1 0.37853800 0.29627800 0.48224900 1 - O O39 1 0.89628900 0.37853800 0.58226000 1 - O O40 1 0.18597100 0.20372200 0.58226000 1 - O O41 1 0.48224900 0.37853800 0.29627800 1 - O O42 1 0.89628900 0.01775100 0.31402900 1 - O O43 1 0.60371100 0.91774000 0.12146200 1 - O O44 1 0.91774000 0.12146200 0.60371100 1 - O O45 1 0.29627800 0.48224900 0.37853800 1 - O O46 1 0.58226000 0.18597100 0.20372200 1 - O O47 1 0.20372200 0.58226000 0.18597100 1 - O O48 1 0.01775100 0.31402900 0.89628900 1 - O O49 1 0.91774000 0.29627800 0.31402900 1 - O O50 1 0.01775100 0.20372200 0.12146200 1 - O O51 1 0.81402900 0.79627800 0.41774000 1 - O O52 1 0.18597100 0.48224900 0.60371100 1 - O O53 1 0.60371100 0.18597100 0.48224900 1 - O O54 1 0.20372200 0.12146200 0.01775100 1 - O O55 1 0.12146200 0.60371100 0.91774000 1 - O O56 1 0.41774000 0.10371100 0.62146200 1 - O O57 1 0.62146200 0.41774000 0.10371100 1 - O O58 1 0.70372200 0.68597100 0.08226000 1 - O O59 1 0.51775100 0.39628900 0.81402900 1 - O O60 1 0.68597100 0.10371100 0.98224900 1 - O O61 1 0.87853800 0.98224900 0.79627800 1 - O O62 1 0.62146200 0.70372200 0.51775100 1 - O O63 1 0.10371100 0.62146200 0.41774000 1 - O O64 1 0.87853800 0.39628900 0.08226000 1 - O O65 1 0.79627800 0.87853800 0.98224900 1 - O O66 1 0.39628900 0.81402900 0.51775100 1 - O O67 1 0.68597100 0.08226000 0.70372200 1 - O O68 1 0.81402900 0.51775100 0.39628900 1 - O O69 1 0.98224900 0.79627800 0.87853800 1 - O O70 1 0.08226000 0.70372200 0.68597100 1 - O O71 1 0.98224900 0.68597100 0.10371100 1 - O O72 1 0.79627800 0.41774000 0.81402900 1 - O O73 1 0.41774000 0.81402900 0.79627800 1 - O O74 1 0.70372200 0.51775100 0.62146200 1 - O O75 1 0.08226000 0.87853800 0.39628900 1 - O O76 1 0.39628900 0.08226000 0.87853800 1 - O O77 1 0.10371100 0.98224900 0.68597100 1 - O O78 1 0.51775100 0.62146200 0.70372200 1 - O O79 1 0.31402900 0.91774000 0.29627800 1 -" -Ti3Al2(SiO4)3,mvc-4030,Ia-3d,[],0.21366010667855484,{'tags': []},"Full Formula (Ti12 Al8 Si12 O48) -Reduced Formula: Ti3Al2(SiO4)3 -abc : 10.106378 10.106378 10.106378 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ti 0.875 0.625 0.25 1.687 - 1 Ti 0.625 0.25 0.875 1.687 - 2 Ti 0.875 0.75 0.625 1.687 - 3 Ti 0.75 0.625 0.875 1.687 - 4 Ti 0.25 0.875 0.625 1.687 - 5 Ti 0.625 0.875 0.75 1.687 - 6 Ti 0.125 0.375 0.75 1.687 - 7 Ti 0.375 0.75 0.125 1.687 - 8 Ti 0.125 0.25 0.375 1.687 - 9 Ti 0.25 0.375 0.125 1.687 - 10 Ti 0.75 0.125 0.375 1.687 - 11 Ti 0.375 0.125 0.25 1.687 - 12 Al 0 0 0.5 0.006 - 13 Al 0 0 0 0.006 - 14 Al 0.5 0 0 0.006 - 15 Al 0 0.5 0 0.006 - 16 Al 0.5 0.5 0 0.006 - 17 Al 0 0.5 0.5 0.006 - 18 Al 0.5 0 0.5 0.006 - 19 Al 0.5 0.5 0.5 0.006 - 20 Si 0.125 0.875 0.25 0.008 - 21 Si 0.25 0.125 0.875 0.008 - 22 Si 0.75 0.375 0.625 0.008 - 23 Si 0.625 0.375 0.25 0.008 - 24 Si 0.625 0.75 0.375 0.008 - 25 Si 0.375 0.625 0.75 0.008 - 26 Si 0.125 0.75 0.875 0.008 - 27 Si 0.75 0.875 0.125 0.008 - 28 Si 0.875 0.25 0.125 0.008 - 29 Si 0.375 0.25 0.625 0.008 - 30 Si 0.25 0.625 0.375 0.008 - 31 Si 0.875 0.125 0.75 0.008 - 32 O 0.48423 0.383474 0.296739 0.002 - 33 O 0.312509 0.899244 0.01577 0.002 - 34 O 0.600756 0.913265 0.116526 0.002 - 35 O 0.586735 0.187491 0.203261 0.002 - 36 O 0.116526 0.01577 0.203261 0.002 - 37 O 0.187491 0.203261 0.586735 0.002 - 38 O 0.187491 0.48423 0.600756 0.002 - 39 O 0.203261 0.586735 0.187491 0.002 - 40 O 0.383474 0.586735 0.899244 0.002 - 41 O 0.913265 0.296739 0.312509 0.002 - 42 O 0.296739 0.312509 0.913265 0.002 - 43 O 0.203261 0.116526 0.01577 0.002 - 44 O 0.48423 0.600756 0.187491 0.002 - 45 O 0.899244 0.383474 0.586735 0.002 - 46 O 0.01577 0.203261 0.116526 0.002 - 47 O 0.600756 0.187491 0.48423 0.002 - 48 O 0.586735 0.899244 0.383474 0.002 - 49 O 0.01577 0.312509 0.899244 0.002 - 50 O 0.913265 0.116526 0.600756 0.002 - 51 O 0.616526 0.413265 0.100756 0.002 - 52 O 0.383474 0.296739 0.48423 0.002 - 53 O 0.296739 0.48423 0.383474 0.002 - 54 O 0.899244 0.01577 0.312509 0.002 - 55 O 0.312509 0.913265 0.296739 0.002 - 56 O 0.51577 0.616526 0.703261 0.002 - 57 O 0.687491 0.100756 0.98423 0.002 - 58 O 0.399244 0.086735 0.883474 0.002 - 59 O 0.413265 0.812509 0.796739 0.002 - 60 O 0.883474 0.98423 0.796739 0.002 - 61 O 0.812509 0.796739 0.413265 0.002 - 62 O 0.812509 0.51577 0.399244 0.002 - 63 O 0.796739 0.413265 0.812509 0.002 - 64 O 0.687491 0.086735 0.703261 0.002 - 65 O 0.100756 0.98423 0.687491 0.002 - 66 O 0.703261 0.51577 0.616526 0.002 - 67 O 0.616526 0.703261 0.51577 0.002 - 68 O 0.883474 0.399244 0.086735 0.002 - 69 O 0.086735 0.883474 0.399244 0.002 - 70 O 0.98423 0.687491 0.100756 0.002 - 71 O 0.413265 0.100756 0.616526 0.002 - 72 O 0.399244 0.812509 0.51577 0.002 - 73 O 0.98423 0.796739 0.883474 0.002 - 74 O 0.100756 0.616526 0.413265 0.002 - 75 O 0.51577 0.399244 0.812509 0.002 - 76 O 0.796739 0.883474 0.98423 0.002 - 77 O 0.703261 0.687491 0.086735 0.002 - 78 O 0.086735 0.703261 0.687491 0.002 - 79 O 0.116526 0.600756 0.913265 0.002","# generated using pymatgen -data_Ti3Al2(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.10637790 -_cell_length_b 10.10637790 -_cell_length_c 10.10637790 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ti3Al2(SiO4)3 -_chemical_formula_sum 'Ti12 Al8 Si12 O48' -_cell_volume 794.62954661 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ti Ti0 1 0.87500000 0.62500000 0.25000000 1 - Ti Ti1 1 0.62500000 0.25000000 0.87500000 1 - Ti Ti2 1 0.87500000 0.75000000 0.62500000 1 - Ti Ti3 1 0.75000000 0.62500000 0.87500000 1 - Ti Ti4 1 0.25000000 0.87500000 0.62500000 1 - Ti Ti5 1 0.62500000 0.87500000 0.75000000 1 - Ti Ti6 1 0.12500000 0.37500000 0.75000000 1 - Ti Ti7 1 0.37500000 0.75000000 0.12500000 1 - Ti Ti8 1 0.12500000 0.25000000 0.37500000 1 - Ti Ti9 1 0.25000000 0.37500000 0.12500000 1 - Ti Ti10 1 0.75000000 0.12500000 0.37500000 1 - Ti Ti11 1 0.37500000 0.12500000 0.25000000 1 - Al Al12 1 0.00000000 0.00000000 0.50000000 1 - Al Al13 1 0.00000000 0.00000000 0.00000000 1 - Al Al14 1 0.50000000 0.00000000 0.00000000 1 - Al Al15 1 0.00000000 0.50000000 0.00000000 1 - Al Al16 1 0.50000000 0.50000000 0.00000000 1 - Al Al17 1 0.00000000 0.50000000 0.50000000 1 - Al Al18 1 0.50000000 0.00000000 0.50000000 1 - Al Al19 1 0.50000000 0.50000000 0.50000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.25000000 0.12500000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.37500000 0.25000000 0.62500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.48423000 0.38347400 0.29673900 1 - O O33 1 0.31250900 0.89924400 0.01577000 1 - O O34 1 0.60075600 0.91326500 0.11652600 1 - O O35 1 0.58673500 0.18749100 0.20326100 1 - O O36 1 0.11652600 0.01577000 0.20326100 1 - O O37 1 0.18749100 0.20326100 0.58673500 1 - O O38 1 0.18749100 0.48423000 0.60075600 1 - O O39 1 0.20326100 0.58673500 0.18749100 1 - O O40 1 0.38347400 0.58673500 0.89924400 1 - O O41 1 0.91326500 0.29673900 0.31250900 1 - O O42 1 0.29673900 0.31250900 0.91326500 1 - O O43 1 0.20326100 0.11652600 0.01577000 1 - O O44 1 0.48423000 0.60075600 0.18749100 1 - O O45 1 0.89924400 0.38347400 0.58673500 1 - O O46 1 0.01577000 0.20326100 0.11652600 1 - O O47 1 0.60075600 0.18749100 0.48423000 1 - O O48 1 0.58673500 0.89924400 0.38347400 1 - O O49 1 0.01577000 0.31250900 0.89924400 1 - O O50 1 0.91326500 0.11652600 0.60075600 1 - O O51 1 0.61652600 0.41326500 0.10075600 1 - O O52 1 0.38347400 0.29673900 0.48423000 1 - O O53 1 0.29673900 0.48423000 0.38347400 1 - O O54 1 0.89924400 0.01577000 0.31250900 1 - O O55 1 0.31250900 0.91326500 0.29673900 1 - O O56 1 0.51577000 0.61652600 0.70326100 1 - O O57 1 0.68749100 0.10075600 0.98423000 1 - O O58 1 0.39924400 0.08673500 0.88347400 1 - O O59 1 0.41326500 0.81250900 0.79673900 1 - O O60 1 0.88347400 0.98423000 0.79673900 1 - O O61 1 0.81250900 0.79673900 0.41326500 1 - O O62 1 0.81250900 0.51577000 0.39924400 1 - O O63 1 0.79673900 0.41326500 0.81250900 1 - O O64 1 0.68749100 0.08673500 0.70326100 1 - O O65 1 0.10075600 0.98423000 0.68749100 1 - O O66 1 0.70326100 0.51577000 0.61652600 1 - O O67 1 0.61652600 0.70326100 0.51577000 1 - O O68 1 0.88347400 0.39924400 0.08673500 1 - O O69 1 0.08673500 0.88347400 0.39924400 1 - O O70 1 0.98423000 0.68749100 0.10075600 1 - O O71 1 0.41326500 0.10075600 0.61652600 1 - O O72 1 0.39924400 0.81250900 0.51577000 1 - O O73 1 0.98423000 0.79673900 0.88347400 1 - O O74 1 0.10075600 0.61652600 0.41326500 1 - O O75 1 0.51577000 0.39924400 0.81250900 1 - O O76 1 0.79673900 0.88347400 0.98423000 1 - O O77 1 0.70326100 0.68749100 0.08673500 1 - O O78 1 0.08673500 0.70326100 0.68749100 1 - O O79 1 0.11652600 0.60075600 0.91326500 1 -" -Ca3Ti2(GeO4)3,mvc-4198,Ia-3d,[],0.062388007250003596,{'tags': []},"Full Formula (Ca12 Ti8 Ge12 O48) -Reduced Formula: Ca3Ti2(GeO4)3 -abc : 10.857360 10.857360 10.857360 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0.002 - 1 Ca 0.75 0.625 0.875 0.002 - 2 Ca 0.625 0.875 0.75 0.002 - 3 Ca 0.875 0.625 0.25 0.002 - 4 Ca 0.625 0.25 0.875 0.002 - 5 Ca 0.875 0.75 0.625 0.002 - 6 Ca 0.75 0.125 0.375 0.002 - 7 Ca 0.25 0.375 0.125 0.002 - 8 Ca 0.375 0.125 0.25 0.002 - 9 Ca 0.125 0.375 0.75 0.002 - 10 Ca 0.375 0.75 0.125 0.002 - 11 Ca 0.125 0.25 0.375 0.002 - 12 Ti 0.5 0.5 0.5 0.814 - 13 Ti 0.5 0 0.5 0.812 - 14 Ti 0 0.5 0.5 0.816 - 15 Ti 0.5 0.5 0 0.805 - 16 Ti 0 0 0.5 0.812 - 17 Ti 0 0.5 0 0.809 - 18 Ti 0.5 0 0 0.811 - 19 Ti 0 0 0 0.813 - 20 Ge 0.125 0.75 0.875 0.041 - 21 Ge 0.875 0.25 0.125 0.041 - 22 Ge 0.625 0.375 0.25 0.041 - 23 Ge 0.75 0.875 0.125 0.041 - 24 Ge 0.875 0.125 0.75 0.041 - 25 Ge 0.25 0.625 0.375 0.041 - 26 Ge 0.75 0.375 0.625 0.041 - 27 Ge 0.25 0.125 0.875 0.041 - 28 Ge 0.125 0.875 0.25 0.041 - 29 Ge 0.375 0.625 0.75 0.041 - 30 Ge 0.625 0.75 0.375 0.041 - 31 Ge 0.375 0.25 0.625 0.041 - 32 O 0.415732 0.814444 0.797258 0.002 - 33 O 0.881526 0.398711 0.084268 0.001 - 34 O 0.101289 0.982815 0.685556 0.003 - 35 O 0.517185 0.618474 0.702741 0.002 - 36 O 0.685556 0.084268 0.702742 0.003 - 37 O 0.618474 0.702741 0.517185 0.001 - 38 O 0.618474 0.415732 0.101289 0.003 - 39 O 0.702742 0.517185 0.618474 0.003 - 40 O 0.814444 0.517185 0.398711 0.003 - 41 O 0.982815 0.797258 0.881526 0.001 - 42 O 0.797259 0.881526 0.982815 0.002 - 43 O 0.702742 0.685556 0.084268 0.001 - 44 O 0.415732 0.101289 0.618474 0.001 - 45 O 0.398711 0.814444 0.517185 0.002 - 46 O 0.084268 0.702742 0.685556 0.001 - 47 O 0.101289 0.618474 0.415732 0.002 - 48 O 0.517185 0.398711 0.814444 0.001 - 49 O 0.084268 0.881526 0.398711 0.002 - 50 O 0.982815 0.685556 0.101289 0.002 - 51 O 0.185556 0.482815 0.601289 0.003 - 52 O 0.685556 0.101289 0.982815 0.001 - 53 O 0.797259 0.415732 0.814444 0.003 - 54 O 0.398711 0.084268 0.881526 0.003 - 55 O 0.881526 0.982815 0.797259 0.003 - 56 O 0.584268 0.185556 0.202741 0.002 - 57 O 0.118474 0.601289 0.915732 0.001 - 58 O 0.898711 0.017185 0.314444 0.003 - 59 O 0.482815 0.381526 0.297259 0.002 - 60 O 0.314444 0.915732 0.297259 0.003 - 61 O 0.381526 0.297259 0.482815 0.001 - 62 O 0.381526 0.584268 0.898711 0.003 - 63 O 0.297259 0.482815 0.381526 0.003 - 64 O 0.118474 0.017185 0.202741 0.003 - 65 O 0.601289 0.915732 0.118474 0.003 - 66 O 0.202741 0.584268 0.185556 0.003 - 67 O 0.185556 0.202741 0.584268 0.001 - 68 O 0.314444 0.898711 0.017185 0.001 - 69 O 0.017185 0.314444 0.898711 0.002 - 70 O 0.915732 0.118474 0.601289 0.002 - 71 O 0.482815 0.601289 0.185556 0.001 - 72 O 0.898711 0.381526 0.584268 0.002 - 73 O 0.915732 0.297259 0.314444 0.001 - 74 O 0.601289 0.185556 0.482815 0.002 - 75 O 0.584268 0.898711 0.381526 0.001 - 76 O 0.297259 0.314444 0.915732 0.001 - 77 O 0.202742 0.118474 0.017185 0.002 - 78 O 0.017185 0.202742 0.118474 0.001 - 79 O 0.814444 0.797259 0.415732 0.001","# generated using pymatgen -data_Ca3Ti2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.85736049 -_cell_length_b 10.85736049 -_cell_length_c 10.85736049 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ti2(GeO4)3 -_chemical_formula_sum 'Ca12 Ti8 Ge12 O48' -_cell_volume 985.26006908 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Ti Ti12 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti13 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti14 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti15 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti16 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti17 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti18 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41573200 0.81444400 0.79725800 1 - O O33 1 0.88152600 0.39871100 0.08426800 1 - O O34 1 0.10128900 0.98281500 0.68555600 1 - O O35 1 0.51718500 0.61847400 0.70274100 1 - O O36 1 0.68555600 0.08426800 0.70274200 1 - O O37 1 0.61847400 0.70274100 0.51718500 1 - O O38 1 0.61847400 0.41573200 0.10128900 1 - O O39 1 0.70274200 0.51718500 0.61847400 1 - O O40 1 0.81444400 0.51718500 0.39871100 1 - O O41 1 0.98281500 0.79725800 0.88152600 1 - O O42 1 0.79725900 0.88152600 0.98281500 1 - O O43 1 0.70274200 0.68555600 0.08426800 1 - O O44 1 0.41573200 0.10128900 0.61847400 1 - O O45 1 0.39871100 0.81444400 0.51718500 1 - O O46 1 0.08426800 0.70274200 0.68555600 1 - O O47 1 0.10128900 0.61847400 0.41573200 1 - O O48 1 0.51718500 0.39871100 0.81444400 1 - O O49 1 0.08426800 0.88152600 0.39871100 1 - O O50 1 0.98281500 0.68555600 0.10128900 1 - O O51 1 0.18555600 0.48281500 0.60128900 1 - O O52 1 0.68555600 0.10128900 0.98281500 1 - O O53 1 0.79725900 0.41573200 0.81444400 1 - O O54 1 0.39871100 0.08426800 0.88152600 1 - O O55 1 0.88152600 0.98281500 0.79725900 1 - O O56 1 0.58426800 0.18555600 0.20274100 1 - O O57 1 0.11847400 0.60128900 0.91573200 1 - O O58 1 0.89871100 0.01718500 0.31444400 1 - O O59 1 0.48281500 0.38152600 0.29725900 1 - O O60 1 0.31444400 0.91573200 0.29725900 1 - O O61 1 0.38152600 0.29725900 0.48281500 1 - O O62 1 0.38152600 0.58426800 0.89871100 1 - O O63 1 0.29725900 0.48281500 0.38152600 1 - O O64 1 0.11847400 0.01718500 0.20274100 1 - O O65 1 0.60128900 0.91573200 0.11847400 1 - O O66 1 0.20274100 0.58426800 0.18555600 1 - O O67 1 0.18555600 0.20274100 0.58426800 1 - O O68 1 0.31444400 0.89871100 0.01718500 1 - O O69 1 0.01718500 0.31444400 0.89871100 1 - O O70 1 0.91573200 0.11847400 0.60128900 1 - O O71 1 0.48281500 0.60128900 0.18555600 1 - O O72 1 0.89871100 0.38152600 0.58426800 1 - O O73 1 0.91573200 0.29725900 0.31444400 1 - O O74 1 0.60128900 0.18555600 0.48281500 1 - O O75 1 0.58426800 0.89871100 0.38152600 1 - O O76 1 0.29725900 0.31444400 0.91573200 1 - O O77 1 0.20274200 0.11847400 0.01718500 1 - O O78 1 0.01718500 0.20274200 0.11847400 1 - O O79 1 0.81444400 0.79725900 0.41573200 1 -" -Mg3Ti2(GeO4)3,mvc-4201,Ia-3d,[],0.17718060250001333,{'tags': []},"Full Formula (Mg12 Ti8 Ge12 O48) -Reduced Formula: Mg3Ti2(GeO4)3 -abc : 10.563430 10.563430 10.563430 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.002 - 1 Mg 0.75 0.625 0.875 0.002 - 2 Mg 0.625 0.875 0.75 0.002 - 3 Mg 0.875 0.625 0.25 0.002 - 4 Mg 0.625 0.25 0.875 0.002 - 5 Mg 0.875 0.75 0.625 0.002 - 6 Mg 0.75 0.125 0.375 0.002 - 7 Mg 0.25 0.375 0.125 0.002 - 8 Mg 0.375 0.125 0.25 0.002 - 9 Mg 0.125 0.375 0.75 0.002 - 10 Mg 0.375 0.75 0.125 0.002 - 11 Mg 0.125 0.25 0.375 0.002 - 12 Ti 0.5 0.5 0.5 0.796 - 13 Ti 0.5 0 0.5 0.796 - 14 Ti 0 0.5 0.5 0.796 - 15 Ti 0.5 0.5 0 0.796 - 16 Ti 0 0 0.5 0.796 - 17 Ti 0 0.5 0 0.796 - 18 Ti 0.5 0 0 0.796 - 19 Ti 0 0 0 0.796 - 20 Ge 0.125 0.75 0.875 0.032 - 21 Ge 0.875 0.25 0.125 0.032 - 22 Ge 0.625 0.375 0.25 0.032 - 23 Ge 0.75 0.875 0.125 0.032 - 24 Ge 0.875 0.125 0.75 0.032 - 25 Ge 0.25 0.625 0.375 0.032 - 26 Ge 0.75 0.375 0.625 0.032 - 27 Ge 0.25 0.125 0.875 0.032 - 28 Ge 0.125 0.875 0.25 0.032 - 29 Ge 0.375 0.625 0.75 0.032 - 30 Ge 0.625 0.75 0.375 0.032 - 31 Ge 0.375 0.25 0.625 0.032 - 32 O 0.417782 0.817482 0.790426 -0.002 - 33 O 0.872644 0.3997 0.082218 -0.002 - 34 O 0.1003 0.972944 0.682518 -0.002 - 35 O 0.527056 0.627356 0.709574 -0.002 - 36 O 0.682518 0.082218 0.709574 -0.002 - 37 O 0.627356 0.709574 0.527056 -0.002 - 38 O 0.627356 0.417782 0.1003 -0.002 - 39 O 0.709574 0.527056 0.627356 -0.002 - 40 O 0.817482 0.527056 0.3997 -0.002 - 41 O 0.972944 0.790426 0.872644 -0.002 - 42 O 0.790426 0.872644 0.972944 -0.002 - 43 O 0.709574 0.682518 0.082218 -0.002 - 44 O 0.417782 0.1003 0.627356 -0.002 - 45 O 0.3997 0.817482 0.527056 -0.002 - 46 O 0.082218 0.709574 0.682518 -0.002 - 47 O 0.1003 0.627356 0.417782 -0.002 - 48 O 0.527056 0.3997 0.817482 -0.002 - 49 O 0.082218 0.872644 0.3997 -0.002 - 50 O 0.972944 0.682518 0.1003 -0.002 - 51 O 0.182518 0.472944 0.6003 -0.002 - 52 O 0.682518 0.1003 0.972944 -0.002 - 53 O 0.790426 0.417782 0.817482 -0.002 - 54 O 0.3997 0.082218 0.872644 -0.002 - 55 O 0.872644 0.972944 0.790426 -0.002 - 56 O 0.582218 0.182518 0.209574 -0.002 - 57 O 0.127356 0.6003 0.917782 -0.002 - 58 O 0.8997 0.027056 0.317482 -0.002 - 59 O 0.472944 0.372644 0.290426 -0.002 - 60 O 0.317482 0.917782 0.290426 -0.002 - 61 O 0.372644 0.290426 0.472944 -0.002 - 62 O 0.372644 0.582218 0.8997 -0.002 - 63 O 0.290426 0.472944 0.372644 -0.002 - 64 O 0.127356 0.027056 0.209574 -0.002 - 65 O 0.6003 0.917782 0.127356 -0.002 - 66 O 0.209574 0.582218 0.182518 -0.002 - 67 O 0.182518 0.209574 0.582218 -0.002 - 68 O 0.317482 0.8997 0.027056 -0.002 - 69 O 0.027056 0.317482 0.8997 -0.002 - 70 O 0.917782 0.127356 0.6003 -0.002 - 71 O 0.472944 0.6003 0.182518 -0.002 - 72 O 0.8997 0.372644 0.582218 -0.002 - 73 O 0.917782 0.290426 0.317482 -0.002 - 74 O 0.6003 0.182518 0.472944 -0.002 - 75 O 0.582218 0.8997 0.372644 -0.002 - 76 O 0.290426 0.317482 0.917782 -0.002 - 77 O 0.209574 0.127356 0.027056 -0.002 - 78 O 0.027056 0.209574 0.127356 -0.002 - 79 O 0.817482 0.790426 0.417782 -0.002","# generated using pymatgen -data_Mg3Ti2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.56342973 -_cell_length_b 10.56342973 -_cell_length_c 10.56342973 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ti2(GeO4)3 -_chemical_formula_sum 'Mg12 Ti8 Ge12 O48' -_cell_volume 907.38783506 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Ti Ti12 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti13 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti14 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti15 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti16 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti17 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti18 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41778200 0.81748200 0.79042600 1 - O O33 1 0.87264400 0.39970000 0.08221800 1 - O O34 1 0.10030000 0.97294400 0.68251800 1 - O O35 1 0.52705600 0.62735600 0.70957400 1 - O O36 1 0.68251800 0.08221800 0.70957400 1 - O O37 1 0.62735600 0.70957400 0.52705600 1 - O O38 1 0.62735600 0.41778200 0.10030000 1 - O O39 1 0.70957400 0.52705600 0.62735600 1 - O O40 1 0.81748200 0.52705600 0.39970000 1 - O O41 1 0.97294400 0.79042600 0.87264400 1 - O O42 1 0.79042600 0.87264400 0.97294400 1 - O O43 1 0.70957400 0.68251800 0.08221800 1 - O O44 1 0.41778200 0.10030000 0.62735600 1 - O O45 1 0.39970000 0.81748200 0.52705600 1 - O O46 1 0.08221800 0.70957400 0.68251800 1 - O O47 1 0.10030000 0.62735600 0.41778200 1 - O O48 1 0.52705600 0.39970000 0.81748200 1 - O O49 1 0.08221800 0.87264400 0.39970000 1 - O O50 1 0.97294400 0.68251800 0.10030000 1 - O O51 1 0.18251800 0.47294400 0.60030000 1 - O O52 1 0.68251800 0.10030000 0.97294400 1 - O O53 1 0.79042600 0.41778200 0.81748200 1 - O O54 1 0.39970000 0.08221800 0.87264400 1 - O O55 1 0.87264400 0.97294400 0.79042600 1 - O O56 1 0.58221800 0.18251800 0.20957400 1 - O O57 1 0.12735600 0.60030000 0.91778200 1 - O O58 1 0.89970000 0.02705600 0.31748200 1 - O O59 1 0.47294400 0.37264400 0.29042600 1 - O O60 1 0.31748200 0.91778200 0.29042600 1 - O O61 1 0.37264400 0.29042600 0.47294400 1 - O O62 1 0.37264400 0.58221800 0.89970000 1 - O O63 1 0.29042600 0.47294400 0.37264400 1 - O O64 1 0.12735600 0.02705600 0.20957400 1 - O O65 1 0.60030000 0.91778200 0.12735600 1 - O O66 1 0.20957400 0.58221800 0.18251800 1 - O O67 1 0.18251800 0.20957400 0.58221800 1 - O O68 1 0.31748200 0.89970000 0.02705600 1 - O O69 1 0.02705600 0.31748200 0.89970000 1 - O O70 1 0.91778200 0.12735600 0.60030000 1 - O O71 1 0.47294400 0.60030000 0.18251800 1 - O O72 1 0.89970000 0.37264400 0.58221800 1 - O O73 1 0.91778200 0.29042600 0.31748200 1 - O O74 1 0.60030000 0.18251800 0.47294400 1 - O O75 1 0.58221800 0.89970000 0.37264400 1 - O O76 1 0.29042600 0.31748200 0.91778200 1 - O O77 1 0.20957400 0.12735600 0.02705600 1 - O O78 1 0.02705600 0.20957400 0.12735600 1 - O O79 1 0.81748200 0.79042600 0.41778200 1 -" -Ca3Cu2(GeO4)3,mvc-4220,Ia-3d,[],0.05183471505833648,{'tags': []},"Full Formula (Ca12 Cu8 Ge12 O48) -Reduced Formula: Ca3Cu2(GeO4)3 -abc : 10.778902 10.778902 10.778902 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0.001 - 1 Ca 0.75 0.625 0.875 0.001 - 2 Ca 0.625 0.875 0.75 0.001 - 3 Ca 0.875 0.625 0.25 0.001 - 4 Ca 0.625 0.25 0.875 0.001 - 5 Ca 0.875 0.75 0.625 0.001 - 6 Ca 0.75 0.125 0.375 0.001 - 7 Ca 0.25 0.375 0.125 0.001 - 8 Ca 0.375 0.125 0.25 0.001 - 9 Ca 0.125 0.375 0.75 0.001 - 10 Ca 0.375 0.75 0.125 0.001 - 11 Ca 0.125 0.25 0.375 0.001 - 12 Cu 0.5 0.5 0.5 0.925 - 13 Cu 0.5 0 0.5 0.924 - 14 Cu 0 0.5 0.5 0.924 - 15 Cu 0.5 0.5 0 0.924 - 16 Cu 0 0 0.5 0.924 - 17 Cu 0 0.5 0 0.924 - 18 Cu 0.5 0 0 0.924 - 19 Cu 0 0 0 0.924 - 20 Ge 0.125 0.75 0.875 0.015 - 21 Ge 0.875 0.25 0.125 0.015 - 22 Ge 0.625 0.375 0.25 0.015 - 23 Ge 0.75 0.875 0.125 0.015 - 24 Ge 0.875 0.125 0.75 0.015 - 25 Ge 0.25 0.625 0.375 0.015 - 26 Ge 0.75 0.375 0.625 0.015 - 27 Ge 0.25 0.125 0.875 0.015 - 28 Ge 0.125 0.875 0.25 0.015 - 29 Ge 0.375 0.625 0.75 0.015 - 30 Ge 0.625 0.75 0.375 0.015 - 31 Ge 0.375 0.25 0.625 0.015 - 32 O 0.41574 0.814881 0.79668 0.152 - 33 O 0.88094 0.39914 0.08426 0.152 - 34 O 0.10086 0.981799 0.685119 0.152 - 35 O 0.518201 0.61906 0.70332 0.152 - 36 O 0.685119 0.08426 0.70332 0.152 - 37 O 0.61906 0.70332 0.518201 0.152 - 38 O 0.61906 0.41574 0.10086 0.152 - 39 O 0.70332 0.518201 0.61906 0.152 - 40 O 0.814881 0.518201 0.39914 0.152 - 41 O 0.981799 0.79668 0.88094 0.152 - 42 O 0.79668 0.88094 0.981799 0.152 - 43 O 0.70332 0.685119 0.08426 0.152 - 44 O 0.41574 0.10086 0.61906 0.152 - 45 O 0.39914 0.814881 0.518201 0.152 - 46 O 0.08426 0.70332 0.685119 0.152 - 47 O 0.10086 0.61906 0.41574 0.152 - 48 O 0.518201 0.39914 0.814881 0.152 - 49 O 0.08426 0.88094 0.39914 0.152 - 50 O 0.981799 0.685119 0.10086 0.152 - 51 O 0.185119 0.481799 0.60086 0.152 - 52 O 0.685119 0.10086 0.981799 0.152 - 53 O 0.79668 0.41574 0.814881 0.152 - 54 O 0.39914 0.08426 0.88094 0.152 - 55 O 0.88094 0.981799 0.79668 0.152 - 56 O 0.58426 0.185119 0.20332 0.152 - 57 O 0.11906 0.60086 0.91574 0.152 - 58 O 0.89914 0.018201 0.314881 0.152 - 59 O 0.481799 0.38094 0.29668 0.152 - 60 O 0.314881 0.91574 0.29668 0.152 - 61 O 0.38094 0.29668 0.481799 0.152 - 62 O 0.38094 0.58426 0.89914 0.152 - 63 O 0.29668 0.481799 0.38094 0.152 - 64 O 0.11906 0.018201 0.20332 0.152 - 65 O 0.60086 0.91574 0.11906 0.152 - 66 O 0.20332 0.58426 0.185119 0.152 - 67 O 0.185119 0.20332 0.58426 0.152 - 68 O 0.314881 0.89914 0.018201 0.152 - 69 O 0.018201 0.314881 0.89914 0.152 - 70 O 0.91574 0.11906 0.60086 0.152 - 71 O 0.481799 0.60086 0.185119 0.152 - 72 O 0.89914 0.38094 0.58426 0.152 - 73 O 0.91574 0.29668 0.314881 0.152 - 74 O 0.60086 0.185119 0.481799 0.152 - 75 O 0.58426 0.89914 0.38094 0.152 - 76 O 0.29668 0.314881 0.91574 0.152 - 77 O 0.20332 0.11906 0.018201 0.152 - 78 O 0.018201 0.20332 0.11906 0.152 - 79 O 0.814881 0.79668 0.41574 0.152","# generated using pymatgen -data_Ca3Cu2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.77890205 -_cell_length_b 10.77890205 -_cell_length_c 10.77890205 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Cu2(GeO4)3 -_chemical_formula_sum 'Ca12 Cu8 Ge12 O48' -_cell_volume 964.05472048 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Cu Cu12 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu13 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu14 1 0.00000000 0.50000000 0.50000000 1 - Cu Cu15 1 0.50000000 0.50000000 0.00000000 1 - Cu Cu16 1 0.00000000 0.00000000 0.50000000 1 - Cu Cu17 1 0.00000000 0.50000000 0.00000000 1 - Cu Cu18 1 0.50000000 0.00000000 0.00000000 1 - Cu Cu19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41574000 0.81488100 0.79668000 1 - O O33 1 0.88094000 0.39914000 0.08426000 1 - O O34 1 0.10086000 0.98179900 0.68511900 1 - O O35 1 0.51820100 0.61906000 0.70332000 1 - O O36 1 0.68511900 0.08426000 0.70332000 1 - O O37 1 0.61906000 0.70332000 0.51820100 1 - O O38 1 0.61906000 0.41574000 0.10086000 1 - O O39 1 0.70332000 0.51820100 0.61906000 1 - O O40 1 0.81488100 0.51820100 0.39914000 1 - O O41 1 0.98179900 0.79668000 0.88094000 1 - O O42 1 0.79668000 0.88094000 0.98179900 1 - O O43 1 0.70332000 0.68511900 0.08426000 1 - O O44 1 0.41574000 0.10086000 0.61906000 1 - O O45 1 0.39914000 0.81488100 0.51820100 1 - O O46 1 0.08426000 0.70332000 0.68511900 1 - O O47 1 0.10086000 0.61906000 0.41574000 1 - O O48 1 0.51820100 0.39914000 0.81488100 1 - O O49 1 0.08426000 0.88094000 0.39914000 1 - O O50 1 0.98179900 0.68511900 0.10086000 1 - O O51 1 0.18511900 0.48179900 0.60086000 1 - O O52 1 0.68511900 0.10086000 0.98179900 1 - O O53 1 0.79668000 0.41574000 0.81488100 1 - O O54 1 0.39914000 0.08426000 0.88094000 1 - O O55 1 0.88094000 0.98179900 0.79668000 1 - O O56 1 0.58426000 0.18511900 0.20332000 1 - O O57 1 0.11906000 0.60086000 0.91574000 1 - O O58 1 0.89914000 0.01820100 0.31488100 1 - O O59 1 0.48179900 0.38094000 0.29668000 1 - O O60 1 0.31488100 0.91574000 0.29668000 1 - O O61 1 0.38094000 0.29668000 0.48179900 1 - O O62 1 0.38094000 0.58426000 0.89914000 1 - O O63 1 0.29668000 0.48179900 0.38094000 1 - O O64 1 0.11906000 0.01820100 0.20332000 1 - O O65 1 0.60086000 0.91574000 0.11906000 1 - O O66 1 0.20332000 0.58426000 0.18511900 1 - O O67 1 0.18511900 0.20332000 0.58426000 1 - O O68 1 0.31488100 0.89914000 0.01820100 1 - O O69 1 0.01820100 0.31488100 0.89914000 1 - O O70 1 0.91574000 0.11906000 0.60086000 1 - O O71 1 0.48179900 0.60086000 0.18511900 1 - O O72 1 0.89914000 0.38094000 0.58426000 1 - O O73 1 0.91574000 0.29668000 0.31488100 1 - O O74 1 0.60086000 0.18511900 0.48179900 1 - O O75 1 0.58426000 0.89914000 0.38094000 1 - O O76 1 0.29668000 0.31488100 0.91574000 1 - O O77 1 0.20332000 0.11906000 0.01820100 1 - O O78 1 0.01820100 0.20332000 0.11906000 1 - O O79 1 0.81488100 0.79668000 0.41574000 1 -" -Ti2Zn3(GeO4)3,mvc-4223,Ia-3d,[],0.22356885595833553,{'tags': []},"Full Formula (Ti8 Zn12 Ge12 O48) -Reduced Formula: Ti2Zn3(GeO4)3 -abc : 10.609502 10.609502 10.609502 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ti 0.5 0.5 0.5 0.611 - 1 Ti 0.5 0 0.5 0.594 - 2 Ti 0 0.5 0.5 0.594 - 3 Ti 0.5 0.5 0 0.611 - 4 Ti 0 0 0.5 0.594 - 5 Ti 0 0.5 0 0.611 - 6 Ti 0.5 0 0 0.594 - 7 Ti 0 0 0 0.611 - 8 Zn 0.25 0.875 0.625 0.023 - 9 Zn 0.75 0.625 0.875 0.007 - 10 Zn 0.625 0.875 0.75 0.031 - 11 Zn 0.875 0.625 0.25 0.031 - 12 Zn 0.625 0.25 0.875 0.031 - 13 Zn 0.875 0.75 0.625 0.031 - 14 Zn 0.75 0.125 0.375 0.023 - 15 Zn 0.25 0.375 0.125 0.007 - 16 Zn 0.375 0.125 0.25 0.031 - 17 Zn 0.125 0.375 0.75 0.031 - 18 Zn 0.375 0.75 0.125 0.031 - 19 Zn 0.125 0.25 0.375 0.031 - 20 Ge 0.125 0.75 0.875 0.017 - 21 Ge 0.875 0.25 0.125 0.017 - 22 Ge 0.625 0.375 0.25 0.017 - 23 Ge 0.75 0.875 0.125 0.016 - 24 Ge 0.875 0.125 0.75 0.017 - 25 Ge 0.25 0.625 0.375 0.016 - 26 Ge 0.75 0.375 0.625 0.016 - 27 Ge 0.25 0.125 0.875 0.016 - 28 Ge 0.125 0.875 0.25 0.017 - 29 Ge 0.375 0.625 0.75 0.017 - 30 Ge 0.625 0.75 0.375 0.017 - 31 Ge 0.375 0.25 0.625 0.017 - 32 O 0.419569 0.818055 0.794882 -0.008 - 33 O 0.875313 0.398486 0.080431 -0.005 - 34 O 0.101514 0.976827 0.681945 -0.007 - 35 O 0.523173 0.624687 0.705118 -0.008 - 36 O 0.681945 0.080431 0.705118 -0.007 - 37 O 0.624687 0.705118 0.523173 -0.005 - 38 O 0.624687 0.419569 0.101514 -0.005 - 39 O 0.705118 0.523173 0.624687 -0.007 - 40 O 0.818055 0.523173 0.398486 -0.007 - 41 O 0.976827 0.794882 0.875313 -0.008 - 42 O 0.794882 0.875313 0.976827 -0.007 - 43 O 0.705118 0.681945 0.080431 -0.007 - 44 O 0.419569 0.101514 0.624687 -0.008 - 45 O 0.398486 0.818055 0.523173 -0.007 - 46 O 0.080431 0.705118 0.681945 -0.008 - 47 O 0.101514 0.624687 0.419569 -0.007 - 48 O 0.523173 0.398486 0.818055 -0.008 - 49 O 0.080431 0.875313 0.398486 -0.008 - 50 O 0.976827 0.681945 0.101514 -0.008 - 51 O 0.181945 0.476827 0.601514 -0.007 - 52 O 0.681945 0.101514 0.976827 -0.007 - 53 O 0.794882 0.419569 0.818055 -0.007 - 54 O 0.398486 0.080431 0.875313 -0.007 - 55 O 0.875313 0.976827 0.794882 -0.005 - 56 O 0.580431 0.181945 0.205118 -0.008 - 57 O 0.124687 0.601514 0.919569 -0.005 - 58 O 0.898486 0.023173 0.318055 -0.007 - 59 O 0.476827 0.375313 0.294882 -0.008 - 60 O 0.318055 0.919569 0.294882 -0.007 - 61 O 0.375313 0.294882 0.476827 -0.005 - 62 O 0.375313 0.580431 0.898486 -0.005 - 63 O 0.294882 0.476827 0.375313 -0.007 - 64 O 0.124687 0.023173 0.205118 -0.005 - 65 O 0.601514 0.919569 0.124687 -0.007 - 66 O 0.205118 0.580431 0.181945 -0.007 - 67 O 0.181945 0.205118 0.580431 -0.007 - 68 O 0.318055 0.898486 0.023173 -0.007 - 69 O 0.023173 0.318055 0.898486 -0.008 - 70 O 0.919569 0.124687 0.601514 -0.008 - 71 O 0.476827 0.601514 0.181945 -0.008 - 72 O 0.898486 0.375313 0.580431 -0.007 - 73 O 0.919569 0.294882 0.318055 -0.008 - 74 O 0.601514 0.181945 0.476827 -0.007 - 75 O 0.580431 0.898486 0.375313 -0.008 - 76 O 0.294882 0.318055 0.919569 -0.007 - 77 O 0.205118 0.124687 0.023173 -0.007 - 78 O 0.023173 0.205118 0.124687 -0.008 - 79 O 0.818055 0.794882 0.419569 -0.007","# generated using pymatgen -data_Ti2Zn3(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.60950228 -_cell_length_b 10.60950228 -_cell_length_c 10.60950228 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ti2Zn3(GeO4)3 -_chemical_formula_sum 'Ti8 Zn12 Ge12 O48' -_cell_volume 919.31244901 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ti Ti0 1 0.50000000 0.50000000 0.50000000 1 - Ti Ti1 1 0.50000000 0.00000000 0.50000000 1 - Ti Ti2 1 0.00000000 0.50000000 0.50000000 1 - Ti Ti3 1 0.50000000 0.50000000 0.00000000 1 - Ti Ti4 1 0.00000000 0.00000000 0.50000000 1 - Ti Ti5 1 0.00000000 0.50000000 0.00000000 1 - Ti Ti6 1 0.50000000 0.00000000 0.00000000 1 - Ti Ti7 1 0.00000000 0.00000000 0.00000000 1 - Zn Zn8 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn9 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn12 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn13 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn14 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn15 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn16 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn17 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn18 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn19 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41956900 0.81805500 0.79488200 1 - O O33 1 0.87531300 0.39848600 0.08043100 1 - O O34 1 0.10151400 0.97682700 0.68194500 1 - O O35 1 0.52317300 0.62468700 0.70511800 1 - O O36 1 0.68194500 0.08043100 0.70511800 1 - O O37 1 0.62468700 0.70511800 0.52317300 1 - O O38 1 0.62468700 0.41956900 0.10151400 1 - O O39 1 0.70511800 0.52317300 0.62468700 1 - O O40 1 0.81805500 0.52317300 0.39848600 1 - O O41 1 0.97682700 0.79488200 0.87531300 1 - O O42 1 0.79488200 0.87531300 0.97682700 1 - O O43 1 0.70511800 0.68194500 0.08043100 1 - O O44 1 0.41956900 0.10151400 0.62468700 1 - O O45 1 0.39848600 0.81805500 0.52317300 1 - O O46 1 0.08043100 0.70511800 0.68194500 1 - O O47 1 0.10151400 0.62468700 0.41956900 1 - O O48 1 0.52317300 0.39848600 0.81805500 1 - O O49 1 0.08043100 0.87531300 0.39848600 1 - O O50 1 0.97682700 0.68194500 0.10151400 1 - O O51 1 0.18194500 0.47682700 0.60151400 1 - O O52 1 0.68194500 0.10151400 0.97682700 1 - O O53 1 0.79488200 0.41956900 0.81805500 1 - O O54 1 0.39848600 0.08043100 0.87531300 1 - O O55 1 0.87531300 0.97682700 0.79488200 1 - O O56 1 0.58043100 0.18194500 0.20511800 1 - O O57 1 0.12468700 0.60151400 0.91956900 1 - O O58 1 0.89848600 0.02317300 0.31805500 1 - O O59 1 0.47682700 0.37531300 0.29488200 1 - O O60 1 0.31805500 0.91956900 0.29488200 1 - O O61 1 0.37531300 0.29488200 0.47682700 1 - O O62 1 0.37531300 0.58043100 0.89848600 1 - O O63 1 0.29488200 0.47682700 0.37531300 1 - O O64 1 0.12468700 0.02317300 0.20511800 1 - O O65 1 0.60151400 0.91956900 0.12468700 1 - O O66 1 0.20511800 0.58043100 0.18194500 1 - O O67 1 0.18194500 0.20511800 0.58043100 1 - O O68 1 0.31805500 0.89848600 0.02317300 1 - O O69 1 0.02317300 0.31805500 0.89848600 1 - O O70 1 0.91956900 0.12468700 0.60151400 1 - O O71 1 0.47682700 0.60151400 0.18194500 1 - O O72 1 0.89848600 0.37531300 0.58043100 1 - O O73 1 0.91956900 0.29488200 0.31805500 1 - O O74 1 0.60151400 0.18194500 0.47682700 1 - O O75 1 0.58043100 0.89848600 0.37531300 1 - O O76 1 0.29488200 0.31805500 0.91956900 1 - O O77 1 0.20511800 0.12468700 0.02317300 1 - O O78 1 0.02317300 0.20511800 0.12468700 1 - O O79 1 0.81805500 0.79488200 0.41956900 1 -" -Zn3Sn2(GeO4)3,mvc-4227,Ia-3d,[],0.21111745604166998,{'tags': []},"Full Formula (Zn12 Sn8 Ge12 O48) -Reduced Formula: Zn3Sn2(GeO4)3 -abc : 10.888567 10.888567 10.888567 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 0 - 1 Zn 0.75 0.625 0.875 -0 - 2 Zn 0.625 0.875 0.75 0 - 3 Zn 0.875 0.625 0.25 -0 - 4 Zn 0.625 0.25 0.875 -0 - 5 Zn 0.875 0.75 0.625 -0 - 6 Zn 0.75 0.125 0.375 0 - 7 Zn 0.25 0.375 0.125 -0 - 8 Zn 0.375 0.125 0.25 0 - 9 Zn 0.125 0.375 0.75 -0 - 10 Zn 0.375 0.75 0.125 0 - 11 Zn 0.125 0.25 0.375 0 - 12 Sn 0.5 0.5 0.5 0 - 13 Sn 0.5 0 0.5 0 - 14 Sn 0 0.5 0.5 0 - 15 Sn 0.5 0.5 0 0 - 16 Sn 0 0 0.5 0 - 17 Sn 0 0.5 0 0 - 18 Sn 0.5 0 0 0 - 19 Sn 0 0 0 0 - 20 Ge 0.125 0.75 0.875 -0 - 21 Ge 0.875 0.25 0.125 -0 - 22 Ge 0.625 0.375 0.25 0 - 23 Ge 0.75 0.875 0.125 -0 - 24 Ge 0.875 0.125 0.75 0 - 25 Ge 0.25 0.625 0.375 0 - 26 Ge 0.75 0.375 0.625 -0 - 27 Ge 0.25 0.125 0.875 0 - 28 Ge 0.125 0.875 0.25 0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.625 0.75 0.375 0 - 31 Ge 0.375 0.25 0.625 -0 - 32 O 0.417927 0.814381 0.787971 -0 - 33 O 0.870044 0.396455 0.082073 -0 - 34 O 0.103545 0.97359 0.685619 -0 - 35 O 0.52641 0.629956 0.712029 -0 - 36 O 0.685619 0.082073 0.712029 -0 - 37 O 0.629956 0.712029 0.52641 -0 - 38 O 0.629956 0.417927 0.103545 -0 - 39 O 0.712029 0.52641 0.629956 -0 - 40 O 0.814381 0.52641 0.396455 -0 - 41 O 0.97359 0.787971 0.870044 -0 - 42 O 0.787971 0.870044 0.97359 -0 - 43 O 0.712029 0.685619 0.082073 -0 - 44 O 0.417927 0.103545 0.629956 -0 - 45 O 0.396455 0.814381 0.52641 -0 - 46 O 0.082073 0.712029 0.685619 -0 - 47 O 0.103545 0.629956 0.417927 -0 - 48 O 0.52641 0.396455 0.814381 -0 - 49 O 0.082073 0.870044 0.396455 -0 - 50 O 0.97359 0.685619 0.103545 -0 - 51 O 0.185619 0.47359 0.603545 -0 - 52 O 0.685619 0.103545 0.97359 -0 - 53 O 0.787971 0.417927 0.814381 -0 - 54 O 0.396455 0.082073 0.870044 -0 - 55 O 0.870044 0.97359 0.787971 -0 - 56 O 0.582073 0.185619 0.212029 -0 - 57 O 0.129956 0.603545 0.917927 -0 - 58 O 0.896455 0.02641 0.314381 -0 - 59 O 0.47359 0.370044 0.287971 -0 - 60 O 0.314381 0.917927 0.287971 -0 - 61 O 0.370044 0.287971 0.47359 -0 - 62 O 0.370044 0.582073 0.896455 -0 - 63 O 0.287971 0.47359 0.370044 -0 - 64 O 0.129956 0.02641 0.212029 -0 - 65 O 0.603545 0.917927 0.129956 -0 - 66 O 0.212029 0.582073 0.185619 -0 - 67 O 0.185619 0.212029 0.582073 -0 - 68 O 0.314381 0.896455 0.02641 -0 - 69 O 0.02641 0.314381 0.896455 -0 - 70 O 0.917927 0.129956 0.603545 -0 - 71 O 0.47359 0.603545 0.185619 -0 - 72 O 0.896455 0.370044 0.582073 -0 - 73 O 0.917927 0.287971 0.314381 -0 - 74 O 0.603545 0.185619 0.47359 -0 - 75 O 0.582073 0.896455 0.370044 -0 - 76 O 0.287971 0.314381 0.917927 -0 - 77 O 0.212029 0.129956 0.02641 -0 - 78 O 0.02641 0.212029 0.129956 -0 - 79 O 0.814381 0.787971 0.417927 -0","# generated using pymatgen -data_Zn3Sn2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.88856685 -_cell_length_b 10.88856685 -_cell_length_c 10.88856685 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Sn2(GeO4)3 -_chemical_formula_sum 'Zn12 Sn8 Ge12 O48' -_cell_volume 993.78005038 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Sn Sn12 1 0.50000000 0.50000000 0.50000000 1 - Sn Sn13 1 0.50000000 0.00000000 0.50000000 1 - Sn Sn14 1 0.00000000 0.50000000 0.50000000 1 - Sn Sn15 1 0.50000000 0.50000000 0.00000000 1 - Sn Sn16 1 0.00000000 0.00000000 0.50000000 1 - Sn Sn17 1 0.00000000 0.50000000 0.00000000 1 - Sn Sn18 1 0.50000000 0.00000000 0.00000000 1 - Sn Sn19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41792700 0.81438100 0.78797100 1 - O O33 1 0.87004400 0.39645500 0.08207300 1 - O O34 1 0.10354500 0.97359000 0.68561900 1 - O O35 1 0.52641000 0.62995600 0.71202900 1 - O O36 1 0.68561900 0.08207300 0.71202900 1 - O O37 1 0.62995600 0.71202900 0.52641000 1 - O O38 1 0.62995600 0.41792700 0.10354500 1 - O O39 1 0.71202900 0.52641000 0.62995600 1 - O O40 1 0.81438100 0.52641000 0.39645500 1 - O O41 1 0.97359000 0.78797100 0.87004400 1 - O O42 1 0.78797100 0.87004400 0.97359000 1 - O O43 1 0.71202900 0.68561900 0.08207300 1 - O O44 1 0.41792700 0.10354500 0.62995600 1 - O O45 1 0.39645500 0.81438100 0.52641000 1 - O O46 1 0.08207300 0.71202900 0.68561900 1 - O O47 1 0.10354500 0.62995600 0.41792700 1 - O O48 1 0.52641000 0.39645500 0.81438100 1 - O O49 1 0.08207300 0.87004400 0.39645500 1 - O O50 1 0.97359000 0.68561900 0.10354500 1 - O O51 1 0.18561900 0.47359000 0.60354500 1 - O O52 1 0.68561900 0.10354500 0.97359000 1 - O O53 1 0.78797100 0.41792700 0.81438100 1 - O O54 1 0.39645500 0.08207300 0.87004400 1 - O O55 1 0.87004400 0.97359000 0.78797100 1 - O O56 1 0.58207300 0.18561900 0.21202900 1 - O O57 1 0.12995600 0.60354500 0.91792700 1 - O O58 1 0.89645500 0.02641000 0.31438100 1 - O O59 1 0.47359000 0.37004400 0.28797100 1 - O O60 1 0.31438100 0.91792700 0.28797100 1 - O O61 1 0.37004400 0.28797100 0.47359000 1 - O O62 1 0.37004400 0.58207300 0.89645500 1 - O O63 1 0.28797100 0.47359000 0.37004400 1 - O O64 1 0.12995600 0.02641000 0.21202900 1 - O O65 1 0.60354500 0.91792700 0.12995600 1 - O O66 1 0.21202900 0.58207300 0.18561900 1 - O O67 1 0.18561900 0.21202900 0.58207300 1 - O O68 1 0.31438100 0.89645500 0.02641000 1 - O O69 1 0.02641000 0.31438100 0.89645500 1 - O O70 1 0.91792700 0.12995600 0.60354500 1 - O O71 1 0.47359000 0.60354500 0.18561900 1 - O O72 1 0.89645500 0.37004400 0.58207300 1 - O O73 1 0.91792700 0.28797100 0.31438100 1 - O O74 1 0.60354500 0.18561900 0.47359000 1 - O O75 1 0.58207300 0.89645500 0.37004400 1 - O O76 1 0.28797100 0.31438100 0.91792700 1 - O O77 1 0.21202900 0.12995600 0.02641000 1 - O O78 1 0.02641000 0.21202900 0.12995600 1 - O O79 1 0.81438100 0.78797100 0.41792700 1 -" -Mg3Ag2(GeO4)3,mvc-4236,Ia-3d,[],0.20362333766667007,{'tags': []},"Full Formula (Mg12 Ag8 Ge12 O48) -Reduced Formula: Mg3Ag2(GeO4)3 -abc : 10.640700 10.640700 10.640700 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 -0.001 - 1 Mg 0.75 0.625 0.875 -0.001 - 2 Mg 0.625 0.875 0.75 -0.001 - 3 Mg 0.875 0.625 0.25 -0.001 - 4 Mg 0.625 0.25 0.875 -0.001 - 5 Mg 0.875 0.75 0.625 -0.001 - 6 Mg 0.75 0.125 0.375 -0.001 - 7 Mg 0.25 0.375 0.125 -0.001 - 8 Mg 0.375 0.125 0.25 -0.001 - 9 Mg 0.125 0.375 0.75 -0.001 - 10 Mg 0.375 0.75 0.125 -0.001 - 11 Mg 0.125 0.25 0.375 -0.001 - 12 Ag 0.5 0.5 0.5 0.61 - 13 Ag 0.5 0 0.5 0.106 - 14 Ag 0 0.5 0.5 0.106 - 15 Ag 0.5 0.5 0 0.61 - 16 Ag 0 0 0.5 0.106 - 17 Ag 0 0.5 0 0.61 - 18 Ag 0.5 0 0 0.106 - 19 Ag 0 0 0 0.61 - 20 Ge 0.125 0.75 0.875 0.005 - 21 Ge 0.875 0.25 0.125 0.005 - 22 Ge 0.625 0.375 0.25 0.005 - 23 Ge 0.75 0.875 0.125 0.005 - 24 Ge 0.875 0.125 0.75 0.005 - 25 Ge 0.25 0.625 0.375 0.005 - 26 Ge 0.75 0.375 0.625 0.005 - 27 Ge 0.25 0.125 0.875 0.005 - 28 Ge 0.125 0.875 0.25 0.005 - 29 Ge 0.375 0.625 0.75 0.005 - 30 Ge 0.625 0.75 0.375 0.005 - 31 Ge 0.375 0.25 0.625 0.005 - 32 O 0.407637 0.809437 0.772076 0.043 - 33 O 0.864439 0.4018 0.092363 0.145 - 34 O 0.0982 0.962639 0.690563 0.038 - 35 O 0.537361 0.635561 0.727924 0.14 - 36 O 0.690563 0.092363 0.727924 0.04 - 37 O 0.635561 0.727924 0.537361 0.145 - 38 O 0.635561 0.407637 0.0982 0.145 - 39 O 0.727924 0.537361 0.635561 0.145 - 40 O 0.809437 0.537361 0.4018 0.04 - 41 O 0.962639 0.772076 0.864439 0.14 - 42 O 0.772076 0.864439 0.962639 0.145 - 43 O 0.727924 0.690563 0.092363 0.145 - 44 O 0.407637 0.0982 0.635561 0.043 - 45 O 0.4018 0.809437 0.537361 0.038 - 46 O 0.092363 0.727924 0.690563 0.043 - 47 O 0.0982 0.635561 0.407637 0.038 - 48 O 0.537361 0.4018 0.809437 0.14 - 49 O 0.092363 0.864439 0.4018 0.043 - 50 O 0.962639 0.690563 0.0982 0.14 - 51 O 0.190563 0.462639 0.5982 0.04 - 52 O 0.690563 0.0982 0.962639 0.04 - 53 O 0.772076 0.407637 0.809437 0.145 - 54 O 0.4018 0.092363 0.864439 0.038 - 55 O 0.864439 0.962639 0.772076 0.145 - 56 O 0.592363 0.190563 0.227924 0.043 - 57 O 0.135561 0.5982 0.907637 0.145 - 58 O 0.9018 0.037361 0.309437 0.038 - 59 O 0.462639 0.364439 0.272076 0.14 - 60 O 0.309437 0.907637 0.272076 0.04 - 61 O 0.364439 0.272076 0.462639 0.145 - 62 O 0.364439 0.592363 0.9018 0.145 - 63 O 0.272076 0.462639 0.364439 0.145 - 64 O 0.135561 0.037361 0.227924 0.145 - 65 O 0.5982 0.907637 0.135561 0.038 - 66 O 0.227924 0.592363 0.190563 0.145 - 67 O 0.190563 0.227924 0.592363 0.04 - 68 O 0.309437 0.9018 0.037361 0.04 - 69 O 0.037361 0.309437 0.9018 0.14 - 70 O 0.907637 0.135561 0.5982 0.043 - 71 O 0.462639 0.5982 0.190563 0.14 - 72 O 0.9018 0.364439 0.592363 0.038 - 73 O 0.907637 0.272076 0.309437 0.043 - 74 O 0.5982 0.190563 0.462639 0.038 - 75 O 0.592363 0.9018 0.364439 0.043 - 76 O 0.272076 0.309437 0.907637 0.145 - 77 O 0.227924 0.135561 0.037361 0.145 - 78 O 0.037361 0.227924 0.135561 0.14 - 79 O 0.809437 0.772076 0.407637 0.04","# generated using pymatgen -data_Mg3Ag2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.64069998 -_cell_length_b 10.64069998 -_cell_length_c 10.64069998 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ag2(GeO4)3 -_chemical_formula_sum 'Mg12 Ag8 Ge12 O48' -_cell_volume 927.44615345 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Ag Ag12 1 0.50000000 0.50000000 0.50000000 1 - Ag Ag13 1 0.50000000 0.00000000 0.50000000 1 - Ag Ag14 1 0.00000000 0.50000000 0.50000000 1 - Ag Ag15 1 0.50000000 0.50000000 0.00000000 1 - Ag Ag16 1 0.00000000 0.00000000 0.50000000 1 - Ag Ag17 1 0.00000000 0.50000000 0.00000000 1 - Ag Ag18 1 0.50000000 0.00000000 0.00000000 1 - Ag Ag19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.40763700 0.80943700 0.77207600 1 - O O33 1 0.86443900 0.40180000 0.09236300 1 - O O34 1 0.09820000 0.96263900 0.69056300 1 - O O35 1 0.53736100 0.63556100 0.72792400 1 - O O36 1 0.69056300 0.09236300 0.72792400 1 - O O37 1 0.63556100 0.72792400 0.53736100 1 - O O38 1 0.63556100 0.40763700 0.09820000 1 - O O39 1 0.72792400 0.53736100 0.63556100 1 - O O40 1 0.80943700 0.53736100 0.40180000 1 - O O41 1 0.96263900 0.77207600 0.86443900 1 - O O42 1 0.77207600 0.86443900 0.96263900 1 - O O43 1 0.72792400 0.69056300 0.09236300 1 - O O44 1 0.40763700 0.09820000 0.63556100 1 - O O45 1 0.40180000 0.80943700 0.53736100 1 - O O46 1 0.09236300 0.72792400 0.69056300 1 - O O47 1 0.09820000 0.63556100 0.40763700 1 - O O48 1 0.53736100 0.40180000 0.80943700 1 - O O49 1 0.09236300 0.86443900 0.40180000 1 - O O50 1 0.96263900 0.69056300 0.09820000 1 - O O51 1 0.19056300 0.46263900 0.59820000 1 - O O52 1 0.69056300 0.09820000 0.96263900 1 - O O53 1 0.77207600 0.40763700 0.80943700 1 - O O54 1 0.40180000 0.09236300 0.86443900 1 - O O55 1 0.86443900 0.96263900 0.77207600 1 - O O56 1 0.59236300 0.19056300 0.22792400 1 - O O57 1 0.13556100 0.59820000 0.90763700 1 - O O58 1 0.90180000 0.03736100 0.30943700 1 - O O59 1 0.46263900 0.36443900 0.27207600 1 - O O60 1 0.30943700 0.90763700 0.27207600 1 - O O61 1 0.36443900 0.27207600 0.46263900 1 - O O62 1 0.36443900 0.59236300 0.90180000 1 - O O63 1 0.27207600 0.46263900 0.36443900 1 - O O64 1 0.13556100 0.03736100 0.22792400 1 - O O65 1 0.59820000 0.90763700 0.13556100 1 - O O66 1 0.22792400 0.59236300 0.19056300 1 - O O67 1 0.19056300 0.22792400 0.59236300 1 - O O68 1 0.30943700 0.90180000 0.03736100 1 - O O69 1 0.03736100 0.30943700 0.90180000 1 - O O70 1 0.90763700 0.13556100 0.59820000 1 - O O71 1 0.46263900 0.59820000 0.19056300 1 - O O72 1 0.90180000 0.36443900 0.59236300 1 - O O73 1 0.90763700 0.27207600 0.30943700 1 - O O74 1 0.59820000 0.19056300 0.46263900 1 - O O75 1 0.59236300 0.90180000 0.36443900 1 - O O76 1 0.27207600 0.30943700 0.90763700 1 - O O77 1 0.22792400 0.13556100 0.03736100 1 - O O78 1 0.03736100 0.22792400 0.13556100 1 - O O79 1 0.80943700 0.77207600 0.40763700 1 -" -Mg3Sn2(GeO4)3,mvc-4240,Ia-3d,[],0.20561376774999207,{'tags': []},"Full Formula (Mg12 Sn8 Ge12 O48) -Reduced Formula: Mg3Sn2(GeO4)3 -abc : 10.848175 10.848175 10.848175 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0 - 1 Mg 0.75 0.625 0.875 0 - 2 Mg 0.625 0.875 0.75 0 - 3 Mg 0.875 0.625 0.25 0 - 4 Mg 0.625 0.25 0.875 0 - 5 Mg 0.875 0.75 0.625 0 - 6 Mg 0.75 0.125 0.375 0 - 7 Mg 0.25 0.375 0.125 0 - 8 Mg 0.375 0.125 0.25 0 - 9 Mg 0.125 0.375 0.75 0 - 10 Mg 0.375 0.75 0.125 0 - 11 Mg 0.125 0.25 0.375 0 - 12 Sn 0.5 0.5 0.5 0 - 13 Sn 0.5 0 0.5 0 - 14 Sn 0 0.5 0.5 0 - 15 Sn 0.5 0.5 0 0 - 16 Sn 0 0 0.5 0 - 17 Sn 0 0.5 0 0 - 18 Sn 0.5 0 0 0 - 19 Sn 0 0 0 0 - 20 Ge 0.125 0.75 0.875 0 - 21 Ge 0.875 0.25 0.125 0 - 22 Ge 0.625 0.375 0.25 0 - 23 Ge 0.75 0.875 0.125 0 - 24 Ge 0.875 0.125 0.75 0 - 25 Ge 0.25 0.625 0.375 0 - 26 Ge 0.75 0.375 0.625 0 - 27 Ge 0.25 0.125 0.875 0 - 28 Ge 0.125 0.875 0.25 0 - 29 Ge 0.375 0.625 0.75 0 - 30 Ge 0.625 0.75 0.375 0 - 31 Ge 0.375 0.25 0.625 0 - 32 O 0.414929 0.812684 0.781561 -0 - 33 O 0.866631 0.397755 0.085071 -0 - 34 O 0.102245 0.968876 0.687316 -0 - 35 O 0.531124 0.633369 0.718439 -0 - 36 O 0.687316 0.085071 0.718439 -0 - 37 O 0.633369 0.718439 0.531124 -0 - 38 O 0.633369 0.414929 0.102245 -0 - 39 O 0.718439 0.531124 0.633369 -0 - 40 O 0.812684 0.531124 0.397755 -0 - 41 O 0.968876 0.781561 0.866631 -0 - 42 O 0.781561 0.866631 0.968876 -0 - 43 O 0.718439 0.687316 0.085071 -0 - 44 O 0.414929 0.102245 0.633369 -0 - 45 O 0.397755 0.812684 0.531124 -0 - 46 O 0.085071 0.718439 0.687316 -0 - 47 O 0.102245 0.633369 0.414929 -0 - 48 O 0.531124 0.397755 0.812684 -0 - 49 O 0.085071 0.866631 0.397755 -0 - 50 O 0.968876 0.687316 0.102245 -0 - 51 O 0.187316 0.468876 0.602245 -0 - 52 O 0.687316 0.102245 0.968876 -0 - 53 O 0.781561 0.414929 0.812684 -0 - 54 O 0.397755 0.085071 0.866631 -0 - 55 O 0.866631 0.968876 0.781561 -0 - 56 O 0.585071 0.187316 0.218439 -0 - 57 O 0.133369 0.602245 0.914929 -0 - 58 O 0.897755 0.031124 0.312684 -0 - 59 O 0.468876 0.366631 0.281561 -0 - 60 O 0.312684 0.914929 0.281561 -0 - 61 O 0.366631 0.281561 0.468876 -0 - 62 O 0.366631 0.585071 0.897755 -0 - 63 O 0.281561 0.468876 0.366631 -0 - 64 O 0.133369 0.031124 0.218439 -0 - 65 O 0.602245 0.914929 0.133369 -0 - 66 O 0.218439 0.585071 0.187316 -0 - 67 O 0.187316 0.218439 0.585071 -0 - 68 O 0.312684 0.897755 0.031124 -0 - 69 O 0.031124 0.312684 0.897755 -0 - 70 O 0.914929 0.133369 0.602245 -0 - 71 O 0.468876 0.602245 0.187316 -0 - 72 O 0.897755 0.366631 0.585071 -0 - 73 O 0.914929 0.281561 0.312684 -0 - 74 O 0.602245 0.187316 0.468876 -0 - 75 O 0.585071 0.897755 0.366631 -0 - 76 O 0.281561 0.312684 0.914929 -0 - 77 O 0.218439 0.133369 0.031124 -0 - 78 O 0.031124 0.218439 0.133369 -0 - 79 O 0.812684 0.781561 0.414929 -0","# generated using pymatgen -data_Mg3Sn2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.84817542 -_cell_length_b 10.84817542 -_cell_length_c 10.84817542 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Sn2(GeO4)3 -_chemical_formula_sum 'Mg12 Sn8 Ge12 O48' -_cell_volume 982.76166500 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Sn Sn12 1 0.50000000 0.50000000 0.50000000 1 - Sn Sn13 1 0.50000000 0.00000000 0.50000000 1 - Sn Sn14 1 0.00000000 0.50000000 0.50000000 1 - Sn Sn15 1 0.50000000 0.50000000 0.00000000 1 - Sn Sn16 1 0.00000000 0.00000000 0.50000000 1 - Sn Sn17 1 0.00000000 0.50000000 0.00000000 1 - Sn Sn18 1 0.50000000 0.00000000 0.00000000 1 - Sn Sn19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41492900 0.81268400 0.78156100 1 - O O33 1 0.86663100 0.39775500 0.08507100 1 - O O34 1 0.10224500 0.96887600 0.68731600 1 - O O35 1 0.53112400 0.63336900 0.71843900 1 - O O36 1 0.68731600 0.08507100 0.71843900 1 - O O37 1 0.63336900 0.71843900 0.53112400 1 - O O38 1 0.63336900 0.41492900 0.10224500 1 - O O39 1 0.71843900 0.53112400 0.63336900 1 - O O40 1 0.81268400 0.53112400 0.39775500 1 - O O41 1 0.96887600 0.78156100 0.86663100 1 - O O42 1 0.78156100 0.86663100 0.96887600 1 - O O43 1 0.71843900 0.68731600 0.08507100 1 - O O44 1 0.41492900 0.10224500 0.63336900 1 - O O45 1 0.39775500 0.81268400 0.53112400 1 - O O46 1 0.08507100 0.71843900 0.68731600 1 - O O47 1 0.10224500 0.63336900 0.41492900 1 - O O48 1 0.53112400 0.39775500 0.81268400 1 - O O49 1 0.08507100 0.86663100 0.39775500 1 - O O50 1 0.96887600 0.68731600 0.10224500 1 - O O51 1 0.18731600 0.46887600 0.60224500 1 - O O52 1 0.68731600 0.10224500 0.96887600 1 - O O53 1 0.78156100 0.41492900 0.81268400 1 - O O54 1 0.39775500 0.08507100 0.86663100 1 - O O55 1 0.86663100 0.96887600 0.78156100 1 - O O56 1 0.58507100 0.18731600 0.21843900 1 - O O57 1 0.13336900 0.60224500 0.91492900 1 - O O58 1 0.89775500 0.03112400 0.31268400 1 - O O59 1 0.46887600 0.36663100 0.28156100 1 - O O60 1 0.31268400 0.91492900 0.28156100 1 - O O61 1 0.36663100 0.28156100 0.46887600 1 - O O62 1 0.36663100 0.58507100 0.89775500 1 - O O63 1 0.28156100 0.46887600 0.36663100 1 - O O64 1 0.13336900 0.03112400 0.21843900 1 - O O65 1 0.60224500 0.91492900 0.13336900 1 - O O66 1 0.21843900 0.58507100 0.18731600 1 - O O67 1 0.18731600 0.21843900 0.58507100 1 - O O68 1 0.31268400 0.89775500 0.03112400 1 - O O69 1 0.03112400 0.31268400 0.89775500 1 - O O70 1 0.91492900 0.13336900 0.60224500 1 - O O71 1 0.46887600 0.60224500 0.18731600 1 - O O72 1 0.89775500 0.36663100 0.58507100 1 - O O73 1 0.91492900 0.28156100 0.31268400 1 - O O74 1 0.60224500 0.18731600 0.46887600 1 - O O75 1 0.58507100 0.89775500 0.36663100 1 - O O76 1 0.28156100 0.31268400 0.91492900 1 - O O77 1 0.21843900 0.13336900 0.03112400 1 - O O78 1 0.03112400 0.21843900 0.13336900 1 - O O79 1 0.81268400 0.78156100 0.41492900 1 -" -Zn3Cu2(GeO4)3,mvc-4242,Ia-3d,[],0.14043792118749643,{'tags': []},"Full Formula (Zn12 Cu8 Ge12 O48) -Reduced Formula: Zn3Cu2(GeO4)3 -abc : 10.417420 10.417420 10.417420 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 0 - 1 Zn 0.75 0.625 0.875 0 - 2 Zn 0.625 0.875 0.75 0 - 3 Zn 0.875 0.625 0.25 0 - 4 Zn 0.625 0.25 0.875 0 - 5 Zn 0.875 0.75 0.625 0 - 6 Zn 0.75 0.125 0.375 0 - 7 Zn 0.25 0.375 0.125 0 - 8 Zn 0.375 0.125 0.25 0 - 9 Zn 0.125 0.375 0.75 0 - 10 Zn 0.375 0.75 0.125 0 - 11 Zn 0.125 0.25 0.375 0 - 12 Cu 0.5 0.5 0.5 0.932 - 13 Cu 0.5 0 0.5 0.932 - 14 Cu 0 0.5 0.5 0.932 - 15 Cu 0.5 0.5 0 0.932 - 16 Cu 0 0 0.5 0.932 - 17 Cu 0 0.5 0 0.932 - 18 Cu 0.5 0 0 0.932 - 19 Cu 0 0 0 0.932 - 20 Ge 0.125 0.75 0.875 0.011 - 21 Ge 0.875 0.25 0.125 0.011 - 22 Ge 0.625 0.375 0.25 0.011 - 23 Ge 0.75 0.875 0.125 0.011 - 24 Ge 0.875 0.125 0.75 0.011 - 25 Ge 0.25 0.625 0.375 0.011 - 26 Ge 0.75 0.375 0.625 0.011 - 27 Ge 0.25 0.125 0.875 0.011 - 28 Ge 0.125 0.875 0.25 0.011 - 29 Ge 0.375 0.625 0.75 0.011 - 30 Ge 0.625 0.75 0.375 0.011 - 31 Ge 0.375 0.25 0.625 0.011 - 32 O 0.419823 0.819804 0.791311 0.154 - 33 O 0.871488 0.399981 0.080177 0.154 - 34 O 0.100019 0.971507 0.680196 0.154 - 35 O 0.528493 0.628512 0.708689 0.154 - 36 O 0.680196 0.080177 0.708689 0.154 - 37 O 0.628512 0.708689 0.528493 0.154 - 38 O 0.628512 0.419823 0.100019 0.154 - 39 O 0.708689 0.528493 0.628512 0.154 - 40 O 0.819804 0.528493 0.399981 0.154 - 41 O 0.971507 0.791311 0.871488 0.154 - 42 O 0.791311 0.871488 0.971507 0.154 - 43 O 0.708689 0.680196 0.080177 0.154 - 44 O 0.419823 0.100019 0.628512 0.154 - 45 O 0.399981 0.819804 0.528493 0.154 - 46 O 0.080177 0.708689 0.680196 0.154 - 47 O 0.100019 0.628512 0.419823 0.154 - 48 O 0.528493 0.399981 0.819804 0.154 - 49 O 0.080177 0.871488 0.399981 0.154 - 50 O 0.971507 0.680196 0.100019 0.154 - 51 O 0.180196 0.471507 0.600019 0.154 - 52 O 0.680196 0.100019 0.971507 0.154 - 53 O 0.791311 0.419823 0.819804 0.154 - 54 O 0.399981 0.080177 0.871488 0.154 - 55 O 0.871488 0.971507 0.791311 0.154 - 56 O 0.580177 0.180196 0.208689 0.154 - 57 O 0.128512 0.600019 0.919823 0.154 - 58 O 0.899981 0.028493 0.319804 0.154 - 59 O 0.471507 0.371488 0.291311 0.154 - 60 O 0.319804 0.919823 0.291311 0.154 - 61 O 0.371488 0.291311 0.471507 0.154 - 62 O 0.371488 0.580177 0.899981 0.154 - 63 O 0.291311 0.471507 0.371488 0.154 - 64 O 0.128512 0.028493 0.208689 0.154 - 65 O 0.600019 0.919823 0.128512 0.154 - 66 O 0.208689 0.580177 0.180196 0.154 - 67 O 0.180196 0.208689 0.580177 0.154 - 68 O 0.319804 0.899981 0.028493 0.154 - 69 O 0.028493 0.319804 0.899981 0.154 - 70 O 0.919823 0.128512 0.600019 0.154 - 71 O 0.471507 0.600019 0.180196 0.154 - 72 O 0.899981 0.371488 0.580177 0.154 - 73 O 0.919823 0.291311 0.319804 0.154 - 74 O 0.600019 0.180196 0.471507 0.154 - 75 O 0.580177 0.899981 0.371488 0.154 - 76 O 0.291311 0.319804 0.919823 0.154 - 77 O 0.208689 0.128512 0.028493 0.154 - 78 O 0.028493 0.208689 0.128512 0.154 - 79 O 0.819804 0.791311 0.419823 0.154","# generated using pymatgen -data_Zn3Cu2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.41741958 -_cell_length_b 10.41741958 -_cell_length_c 10.41741958 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Cu2(GeO4)3 -_chemical_formula_sum 'Zn12 Cu8 Ge12 O48' -_cell_volume 870.27915019 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Cu Cu12 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu13 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu14 1 0.00000000 0.50000000 0.50000000 1 - Cu Cu15 1 0.50000000 0.50000000 0.00000000 1 - Cu Cu16 1 0.00000000 0.00000000 0.50000000 1 - Cu Cu17 1 0.00000000 0.50000000 0.00000000 1 - Cu Cu18 1 0.50000000 0.00000000 0.00000000 1 - Cu Cu19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41982300 0.81980400 0.79131100 1 - O O33 1 0.87148800 0.39998100 0.08017700 1 - O O34 1 0.10001900 0.97150700 0.68019600 1 - O O35 1 0.52849300 0.62851200 0.70868900 1 - O O36 1 0.68019600 0.08017700 0.70868900 1 - O O37 1 0.62851200 0.70868900 0.52849300 1 - O O38 1 0.62851200 0.41982300 0.10001900 1 - O O39 1 0.70868900 0.52849300 0.62851200 1 - O O40 1 0.81980400 0.52849300 0.39998100 1 - O O41 1 0.97150700 0.79131100 0.87148800 1 - O O42 1 0.79131100 0.87148800 0.97150700 1 - O O43 1 0.70868900 0.68019600 0.08017700 1 - O O44 1 0.41982300 0.10001900 0.62851200 1 - O O45 1 0.39998100 0.81980400 0.52849300 1 - O O46 1 0.08017700 0.70868900 0.68019600 1 - O O47 1 0.10001900 0.62851200 0.41982300 1 - O O48 1 0.52849300 0.39998100 0.81980400 1 - O O49 1 0.08017700 0.87148800 0.39998100 1 - O O50 1 0.97150700 0.68019600 0.10001900 1 - O O51 1 0.18019600 0.47150700 0.60001900 1 - O O52 1 0.68019600 0.10001900 0.97150700 1 - O O53 1 0.79131100 0.41982300 0.81980400 1 - O O54 1 0.39998100 0.08017700 0.87148800 1 - O O55 1 0.87148800 0.97150700 0.79131100 1 - O O56 1 0.58017700 0.18019600 0.20868900 1 - O O57 1 0.12851200 0.60001900 0.91982300 1 - O O58 1 0.89998100 0.02849300 0.31980400 1 - O O59 1 0.47150700 0.37148800 0.29131100 1 - O O60 1 0.31980400 0.91982300 0.29131100 1 - O O61 1 0.37148800 0.29131100 0.47150700 1 - O O62 1 0.37148800 0.58017700 0.89998100 1 - O O63 1 0.29131100 0.47150700 0.37148800 1 - O O64 1 0.12851200 0.02849300 0.20868900 1 - O O65 1 0.60001900 0.91982300 0.12851200 1 - O O66 1 0.20868900 0.58017700 0.18019600 1 - O O67 1 0.18019600 0.20868900 0.58017700 1 - O O68 1 0.31980400 0.89998100 0.02849300 1 - O O69 1 0.02849300 0.31980400 0.89998100 1 - O O70 1 0.91982300 0.12851200 0.60001900 1 - O O71 1 0.47150700 0.60001900 0.18019600 1 - O O72 1 0.89998100 0.37148800 0.58017700 1 - O O73 1 0.91982300 0.29131100 0.31980400 1 - O O74 1 0.60001900 0.18019600 0.47150700 1 - O O75 1 0.58017700 0.89998100 0.37148800 1 - O O76 1 0.29131100 0.31980400 0.91982300 1 - O O77 1 0.20868900 0.12851200 0.02849300 1 - O O78 1 0.02849300 0.20868900 0.12851200 1 - O O79 1 0.81980400 0.79131100 0.41982300 1 -" -Zn3Ag2(GeO4)3,mvc-4247,Ia-3d,[],0.20426449341666597,{'tags': []},"Full Formula (Zn12 Ag8 Ge12 O48) -Reduced Formula: Zn3Ag2(GeO4)3 -abc : 10.687635 10.687635 10.687635 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 -0 - 1 Zn 0.75 0.625 0.875 -0 - 2 Zn 0.625 0.875 0.75 -0 - 3 Zn 0.875 0.625 0.25 -0 - 4 Zn 0.625 0.25 0.875 -0 - 5 Zn 0.875 0.75 0.625 -0 - 6 Zn 0.75 0.125 0.375 -0 - 7 Zn 0.25 0.375 0.125 -0 - 8 Zn 0.375 0.125 0.25 -0 - 9 Zn 0.125 0.375 0.75 -0 - 10 Zn 0.375 0.75 0.125 -0 - 11 Zn 0.125 0.25 0.375 -0 - 12 Ag 0.5 0.5 0.5 -0.001 - 13 Ag 0.5 0 0.5 -0 - 14 Ag 0 0.5 0.5 0.001 - 15 Ag 0.5 0.5 0 0.002 - 16 Ag 0 0 0.5 -0.001 - 17 Ag 0 0.5 0 -0.002 - 18 Ag 0.5 0 0 0 - 19 Ag 0 0 0 0.001 - 20 Ge 0.125 0.75 0.875 0 - 21 Ge 0.875 0.25 0.125 0 - 22 Ge 0.625 0.375 0.25 0 - 23 Ge 0.75 0.875 0.125 0 - 24 Ge 0.875 0.125 0.75 -0 - 25 Ge 0.25 0.625 0.375 -0 - 26 Ge 0.75 0.375 0.625 -0 - 27 Ge 0.25 0.125 0.875 0 - 28 Ge 0.125 0.875 0.25 -0 - 29 Ge 0.375 0.625 0.75 0 - 30 Ge 0.625 0.75 0.375 -0 - 31 Ge 0.375 0.25 0.625 -0 - 32 O 0.409381 0.81014 0.7744 0 - 33 O 0.865018 0.400759 0.090619 -0 - 34 O 0.099241 0.96426 0.68986 -0 - 35 O 0.53574 0.634982 0.7256 -0 - 36 O 0.68986 0.090619 0.7256 -0 - 37 O 0.634982 0.7256 0.53574 -0 - 38 O 0.634982 0.409381 0.099241 0 - 39 O 0.7256 0.53574 0.634982 -0 - 40 O 0.81014 0.53574 0.400759 0 - 41 O 0.96426 0.7744 0.865018 0 - 42 O 0.7744 0.865018 0.96426 0 - 43 O 0.7256 0.68986 0.090619 0 - 44 O 0.409381 0.099241 0.634982 -0 - 45 O 0.400759 0.81014 0.53574 -0 - 46 O 0.090619 0.7256 0.68986 0 - 47 O 0.099241 0.634982 0.409381 0 - 48 O 0.53574 0.400759 0.81014 0 - 49 O 0.090619 0.865018 0.400759 -0 - 50 O 0.96426 0.68986 0.099241 -0 - 51 O 0.18986 0.46426 0.599241 0 - 52 O 0.68986 0.099241 0.96426 0 - 53 O 0.7744 0.409381 0.81014 -0 - 54 O 0.400759 0.090619 0.865018 0 - 55 O 0.865018 0.96426 0.7744 0 - 56 O 0.590619 0.18986 0.2256 0 - 57 O 0.134982 0.599241 0.909381 -0 - 58 O 0.900759 0.03574 0.31014 -0 - 59 O 0.46426 0.365018 0.2744 -0 - 60 O 0.31014 0.909381 0.2744 -0 - 61 O 0.365018 0.2744 0.46426 -0 - 62 O 0.365018 0.590619 0.900759 0 - 63 O 0.2744 0.46426 0.365018 -0 - 64 O 0.134982 0.03574 0.2256 0 - 65 O 0.599241 0.909381 0.134982 0 - 66 O 0.2256 0.590619 0.18986 -0 - 67 O 0.18986 0.2256 0.590619 -0 - 68 O 0.31014 0.900759 0.03574 0 - 69 O 0.03574 0.31014 0.900759 -0 - 70 O 0.909381 0.134982 0.599241 -0 - 71 O 0.46426 0.599241 0.18986 0 - 72 O 0.900759 0.365018 0.590619 0 - 73 O 0.909381 0.2744 0.31014 0 - 74 O 0.599241 0.18986 0.46426 -0 - 75 O 0.590619 0.900759 0.365018 -0 - 76 O 0.2744 0.31014 0.909381 0 - 77 O 0.2256 0.134982 0.03574 0 - 78 O 0.03574 0.2256 0.134982 0 - 79 O 0.81014 0.7744 0.409381 -0","# generated using pymatgen -data_Zn3Ag2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.68763510 -_cell_length_b 10.68763510 -_cell_length_c 10.68763510 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Ag2(GeO4)3 -_chemical_formula_sum 'Zn12 Ag8 Ge12 O48' -_cell_volume 939.77299602 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Ag Ag12 1 0.50000000 0.50000000 0.50000000 1 - Ag Ag13 1 0.50000000 0.00000000 0.50000000 1 - Ag Ag14 1 0.00000000 0.50000000 0.50000000 1 - Ag Ag15 1 0.50000000 0.50000000 0.00000000 1 - Ag Ag16 1 0.00000000 0.00000000 0.50000000 1 - Ag Ag17 1 0.00000000 0.50000000 0.00000000 1 - Ag Ag18 1 0.50000000 0.00000000 0.00000000 1 - Ag Ag19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.40938100 0.81014000 0.77440000 1 - O O33 1 0.86501800 0.40075900 0.09061900 1 - O O34 1 0.09924100 0.96426000 0.68986000 1 - O O35 1 0.53574000 0.63498200 0.72560000 1 - O O36 1 0.68986000 0.09061900 0.72560000 1 - O O37 1 0.63498200 0.72560000 0.53574000 1 - O O38 1 0.63498200 0.40938100 0.09924100 1 - O O39 1 0.72560000 0.53574000 0.63498200 1 - O O40 1 0.81014000 0.53574000 0.40075900 1 - O O41 1 0.96426000 0.77440000 0.86501800 1 - O O42 1 0.77440000 0.86501800 0.96426000 1 - O O43 1 0.72560000 0.68986000 0.09061900 1 - O O44 1 0.40938100 0.09924100 0.63498200 1 - O O45 1 0.40075900 0.81014000 0.53574000 1 - O O46 1 0.09061900 0.72560000 0.68986000 1 - O O47 1 0.09924100 0.63498200 0.40938100 1 - O O48 1 0.53574000 0.40075900 0.81014000 1 - O O49 1 0.09061900 0.86501800 0.40075900 1 - O O50 1 0.96426000 0.68986000 0.09924100 1 - O O51 1 0.18986000 0.46426000 0.59924100 1 - O O52 1 0.68986000 0.09924100 0.96426000 1 - O O53 1 0.77440000 0.40938100 0.81014000 1 - O O54 1 0.40075900 0.09061900 0.86501800 1 - O O55 1 0.86501800 0.96426000 0.77440000 1 - O O56 1 0.59061900 0.18986000 0.22560000 1 - O O57 1 0.13498200 0.59924100 0.90938100 1 - O O58 1 0.90075900 0.03574000 0.31014000 1 - O O59 1 0.46426000 0.36501800 0.27440000 1 - O O60 1 0.31014000 0.90938100 0.27440000 1 - O O61 1 0.36501800 0.27440000 0.46426000 1 - O O62 1 0.36501800 0.59061900 0.90075900 1 - O O63 1 0.27440000 0.46426000 0.36501800 1 - O O64 1 0.13498200 0.03574000 0.22560000 1 - O O65 1 0.59924100 0.90938100 0.13498200 1 - O O66 1 0.22560000 0.59061900 0.18986000 1 - O O67 1 0.18986000 0.22560000 0.59061900 1 - O O68 1 0.31014000 0.90075900 0.03574000 1 - O O69 1 0.03574000 0.31014000 0.90075900 1 - O O70 1 0.90938100 0.13498200 0.59924100 1 - O O71 1 0.46426000 0.59924100 0.18986000 1 - O O72 1 0.90075900 0.36501800 0.59061900 1 - O O73 1 0.90938100 0.27440000 0.31014000 1 - O O74 1 0.59924100 0.18986000 0.46426000 1 - O O75 1 0.59061900 0.90075900 0.36501800 1 - O O76 1 0.27440000 0.31014000 0.90938100 1 - O O77 1 0.22560000 0.13498200 0.03574000 1 - O O78 1 0.03574000 0.22560000 0.13498200 1 - O O79 1 0.81014000 0.77440000 0.40938100 1 -" -Ca3Ag2(GeO4)3,mvc-4248,Ia-3d,[],0.06693187993333272,{'tags': []},"Full Formula (Ca12 Ag8 Ge12 O48) -Reduced Formula: Ca3Ag2(GeO4)3 -abc : 11.062589 11.062589 11.062589 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 -0.001 - 1 Ca 0.75 0.625 0.875 -0.001 - 2 Ca 0.625 0.875 0.75 -0.001 - 3 Ca 0.875 0.625 0.25 -0.001 - 4 Ca 0.625 0.25 0.875 -0.001 - 5 Ca 0.875 0.75 0.625 -0.001 - 6 Ca 0.75 0.125 0.375 -0.001 - 7 Ca 0.25 0.375 0.125 -0.001 - 8 Ca 0.375 0.125 0.25 -0.001 - 9 Ca 0.125 0.375 0.75 -0.001 - 10 Ca 0.375 0.75 0.125 -0.001 - 11 Ca 0.125 0.25 0.375 -0.001 - 12 Ag 0.5 0.5 0.5 0.696 - 13 Ag 0.5 0 0.5 0.696 - 14 Ag 0 0.5 0.5 0.696 - 15 Ag 0.5 0.5 0 0.696 - 16 Ag 0 0 0.5 0.696 - 17 Ag 0 0.5 0 0.696 - 18 Ag 0.5 0 0 0.696 - 19 Ag 0 0 0 0.696 - 20 Ge 0.125 0.75 0.875 0.013 - 21 Ge 0.875 0.25 0.125 0.013 - 22 Ge 0.625 0.375 0.25 0.013 - 23 Ge 0.75 0.875 0.125 0.013 - 24 Ge 0.875 0.125 0.75 0.013 - 25 Ge 0.25 0.625 0.375 0.013 - 26 Ge 0.75 0.375 0.625 0.013 - 27 Ge 0.25 0.125 0.875 0.013 - 28 Ge 0.125 0.875 0.25 0.013 - 29 Ge 0.375 0.625 0.75 0.013 - 30 Ge 0.625 0.75 0.375 0.013 - 31 Ge 0.375 0.25 0.625 0.013 - 32 O 0.410186 0.806472 0.783154 0.184 - 33 O 0.872969 0.396287 0.089814 0.184 - 34 O 0.103713 0.976682 0.693528 0.184 - 35 O 0.523318 0.627031 0.716846 0.184 - 36 O 0.693528 0.089814 0.716846 0.184 - 37 O 0.627031 0.716846 0.523318 0.184 - 38 O 0.627031 0.410186 0.103713 0.184 - 39 O 0.716846 0.523318 0.627031 0.184 - 40 O 0.806472 0.523318 0.396287 0.184 - 41 O 0.976682 0.783154 0.872969 0.184 - 42 O 0.783154 0.872969 0.976682 0.184 - 43 O 0.716846 0.693528 0.089814 0.184 - 44 O 0.410186 0.103713 0.627031 0.184 - 45 O 0.396287 0.806472 0.523318 0.184 - 46 O 0.089814 0.716846 0.693528 0.184 - 47 O 0.103713 0.627031 0.410186 0.184 - 48 O 0.523318 0.396287 0.806472 0.184 - 49 O 0.089814 0.872969 0.396287 0.184 - 50 O 0.976682 0.693528 0.103713 0.184 - 51 O 0.193528 0.476682 0.603713 0.184 - 52 O 0.693528 0.103713 0.976682 0.184 - 53 O 0.783154 0.410186 0.806472 0.184 - 54 O 0.396287 0.089814 0.872969 0.184 - 55 O 0.872969 0.976682 0.783154 0.184 - 56 O 0.589814 0.193528 0.216846 0.184 - 57 O 0.127031 0.603713 0.910186 0.184 - 58 O 0.896287 0.023318 0.306472 0.184 - 59 O 0.476682 0.372969 0.283154 0.184 - 60 O 0.306472 0.910186 0.283154 0.184 - 61 O 0.372969 0.283154 0.476682 0.184 - 62 O 0.372969 0.589814 0.896287 0.184 - 63 O 0.283154 0.476682 0.372969 0.184 - 64 O 0.127031 0.023318 0.216846 0.184 - 65 O 0.603713 0.910186 0.127031 0.184 - 66 O 0.216846 0.589814 0.193528 0.184 - 67 O 0.193528 0.216846 0.589814 0.184 - 68 O 0.306472 0.896287 0.023318 0.184 - 69 O 0.023318 0.306472 0.896287 0.184 - 70 O 0.910186 0.127031 0.603713 0.184 - 71 O 0.476682 0.603713 0.193528 0.184 - 72 O 0.896287 0.372969 0.589814 0.184 - 73 O 0.910186 0.283154 0.306472 0.184 - 74 O 0.603713 0.193528 0.476682 0.184 - 75 O 0.589814 0.896287 0.372969 0.184 - 76 O 0.283154 0.306472 0.910186 0.184 - 77 O 0.216846 0.127031 0.023318 0.184 - 78 O 0.023318 0.216846 0.127031 0.184 - 79 O 0.806472 0.783154 0.410186 0.184","# generated using pymatgen -data_Ca3Ag2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.06258946 -_cell_length_b 11.06258946 -_cell_length_c 11.06258946 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ag2(GeO4)3 -_chemical_formula_sum 'Ca12 Ag8 Ge12 O48' -_cell_volume 1042.19382564 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Ag Ag12 1 0.50000000 0.50000000 0.50000000 1 - Ag Ag13 1 0.50000000 0.00000000 0.50000000 1 - Ag Ag14 1 0.00000000 0.50000000 0.50000000 1 - Ag Ag15 1 0.50000000 0.50000000 0.00000000 1 - Ag Ag16 1 0.00000000 0.00000000 0.50000000 1 - Ag Ag17 1 0.00000000 0.50000000 0.00000000 1 - Ag Ag18 1 0.50000000 0.00000000 0.00000000 1 - Ag Ag19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41018600 0.80647200 0.78315400 1 - O O33 1 0.87296900 0.39628700 0.08981400 1 - O O34 1 0.10371300 0.97668200 0.69352800 1 - O O35 1 0.52331800 0.62703100 0.71684600 1 - O O36 1 0.69352800 0.08981400 0.71684600 1 - O O37 1 0.62703100 0.71684600 0.52331800 1 - O O38 1 0.62703100 0.41018600 0.10371300 1 - O O39 1 0.71684600 0.52331800 0.62703100 1 - O O40 1 0.80647200 0.52331800 0.39628700 1 - O O41 1 0.97668200 0.78315400 0.87296900 1 - O O42 1 0.78315400 0.87296900 0.97668200 1 - O O43 1 0.71684600 0.69352800 0.08981400 1 - O O44 1 0.41018600 0.10371300 0.62703100 1 - O O45 1 0.39628700 0.80647200 0.52331800 1 - O O46 1 0.08981400 0.71684600 0.69352800 1 - O O47 1 0.10371300 0.62703100 0.41018600 1 - O O48 1 0.52331800 0.39628700 0.80647200 1 - O O49 1 0.08981400 0.87296900 0.39628700 1 - O O50 1 0.97668200 0.69352800 0.10371300 1 - O O51 1 0.19352800 0.47668200 0.60371300 1 - O O52 1 0.69352800 0.10371300 0.97668200 1 - O O53 1 0.78315400 0.41018600 0.80647200 1 - O O54 1 0.39628700 0.08981400 0.87296900 1 - O O55 1 0.87296900 0.97668200 0.78315400 1 - O O56 1 0.58981400 0.19352800 0.21684600 1 - O O57 1 0.12703100 0.60371300 0.91018600 1 - O O58 1 0.89628700 0.02331800 0.30647200 1 - O O59 1 0.47668200 0.37296900 0.28315400 1 - O O60 1 0.30647200 0.91018600 0.28315400 1 - O O61 1 0.37296900 0.28315400 0.47668200 1 - O O62 1 0.37296900 0.58981400 0.89628700 1 - O O63 1 0.28315400 0.47668200 0.37296900 1 - O O64 1 0.12703100 0.02331800 0.21684600 1 - O O65 1 0.60371300 0.91018600 0.12703100 1 - O O66 1 0.21684600 0.58981400 0.19352800 1 - O O67 1 0.19352800 0.21684600 0.58981400 1 - O O68 1 0.30647200 0.89628700 0.02331800 1 - O O69 1 0.02331800 0.30647200 0.89628700 1 - O O70 1 0.91018600 0.12703100 0.60371300 1 - O O71 1 0.47668200 0.60371300 0.19352800 1 - O O72 1 0.89628700 0.37296900 0.58981400 1 - O O73 1 0.91018600 0.28315400 0.30647200 1 - O O74 1 0.60371300 0.19352800 0.47668200 1 - O O75 1 0.58981400 0.89628700 0.37296900 1 - O O76 1 0.28315400 0.30647200 0.91018600 1 - O O77 1 0.21684600 0.12703100 0.02331800 1 - O O78 1 0.02331800 0.21684600 0.12703100 1 - O O79 1 0.80647200 0.78315400 0.41018600 1 -" -Mg3Ge3(SbO6)2,mvc-4249,Ia-3d,[],0.22849065545000347,{'tags': []},"Full Formula (Mg12 Ge12 Sb8 O48) -Reduced Formula: Mg3Ge3(SbO6)2 -abc : 10.952506 10.952506 10.952506 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0 - 1 Mg 0.75 0.625 0.875 0 - 2 Mg 0.625 0.875 0.75 0 - 3 Mg 0.875 0.625 0.25 0 - 4 Mg 0.625 0.25 0.875 0 - 5 Mg 0.875 0.75 0.625 0 - 6 Mg 0.75 0.125 0.375 0 - 7 Mg 0.25 0.375 0.125 0 - 8 Mg 0.375 0.125 0.25 0 - 9 Mg 0.125 0.375 0.75 0 - 10 Mg 0.375 0.75 0.125 0 - 11 Mg 0.125 0.25 0.375 0 - 12 Ge 0.125 0.75 0.875 0 - 13 Ge 0.875 0.25 0.125 0 - 14 Ge 0.625 0.375 0.25 0 - 15 Ge 0.75 0.875 0.125 0 - 16 Ge 0.875 0.125 0.75 0 - 17 Ge 0.25 0.625 0.375 0 - 18 Ge 0.75 0.375 0.625 0 - 19 Ge 0.25 0.125 0.875 0 - 20 Ge 0.125 0.875 0.25 0 - 21 Ge 0.375 0.625 0.75 0 - 22 Ge 0.625 0.75 0.375 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Sb 0.5 0.5 0.5 0 - 25 Sb 0.5 0 0.5 0 - 26 Sb 0 0.5 0.5 0 - 27 Sb 0.5 0.5 0 0 - 28 Sb 0 0 0.5 0 - 29 Sb 0 0.5 0 0 - 30 Sb 0.5 0 0 0 - 31 Sb 0 0 0 0 - 32 O 0.408035 0.805484 0.773982 -0 - 33 O 0.865946 0.397449 0.091964 -0 - 34 O 0.102551 0.968497 0.694516 -0 - 35 O 0.531503 0.634054 0.726018 -0 - 36 O 0.694516 0.091964 0.726018 -0 - 37 O 0.634054 0.726018 0.531503 -0 - 38 O 0.634054 0.408035 0.102551 -0 - 39 O 0.726018 0.531503 0.634054 -0 - 40 O 0.805484 0.531503 0.397449 -0 - 41 O 0.968497 0.773982 0.865946 -0 - 42 O 0.773982 0.865946 0.968497 -0 - 43 O 0.726018 0.694516 0.091965 -0 - 44 O 0.408035 0.102551 0.634054 -0 - 45 O 0.397449 0.805484 0.531503 -0 - 46 O 0.091965 0.726018 0.694516 -0 - 47 O 0.102551 0.634054 0.408035 -0 - 48 O 0.531503 0.397449 0.805484 -0 - 49 O 0.091964 0.865946 0.397449 -0 - 50 O 0.968497 0.694516 0.102551 -0 - 51 O 0.194516 0.468497 0.602551 -0 - 52 O 0.694516 0.102551 0.968497 -0 - 53 O 0.773982 0.408035 0.805484 -0 - 54 O 0.397449 0.091964 0.865946 -0 - 55 O 0.865946 0.968497 0.773982 -0 - 56 O 0.591964 0.194516 0.226018 -0 - 57 O 0.134054 0.602551 0.908035 -0 - 58 O 0.897449 0.031503 0.305484 -0 - 59 O 0.468497 0.365946 0.273982 -0 - 60 O 0.305484 0.908035 0.273982 -0 - 61 O 0.365946 0.273982 0.468497 -0 - 62 O 0.365946 0.591964 0.897449 -0 - 63 O 0.273982 0.468497 0.365946 -0 - 64 O 0.134054 0.031503 0.226018 -0 - 65 O 0.602551 0.908035 0.134054 -0 - 66 O 0.226018 0.591964 0.194516 -0 - 67 O 0.194516 0.226018 0.591965 -0 - 68 O 0.305484 0.897449 0.031503 -0 - 69 O 0.031503 0.305484 0.897449 -0 - 70 O 0.908035 0.134054 0.602551 -0 - 71 O 0.468497 0.602551 0.194516 -0 - 72 O 0.897449 0.365946 0.591965 -0 - 73 O 0.908035 0.273982 0.305484 -0 - 74 O 0.602551 0.194516 0.468497 -0 - 75 O 0.591964 0.897449 0.365946 -0 - 76 O 0.273982 0.305484 0.908035 -0 - 77 O 0.226018 0.134054 0.031503 -0 - 78 O 0.031503 0.226018 0.134054 -0 - 79 O 0.805484 0.773982 0.408035 -0","# generated using pymatgen -data_Mg3Ge3(SbO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.95250550 -_cell_length_b 10.95250550 -_cell_length_c 10.95250550 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ge3(SbO6)2 -_chemical_formula_sum 'Mg12 Ge12 Sb8 O48' -_cell_volume 1011.38975325 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Sb Sb24 1 0.50000000 0.50000000 0.50000000 1 - Sb Sb25 1 0.50000000 0.00000000 0.50000000 1 - Sb Sb26 1 0.00000000 0.50000000 0.50000000 1 - Sb Sb27 1 0.50000000 0.50000000 0.00000000 1 - Sb Sb28 1 0.00000000 0.00000000 0.50000000 1 - Sb Sb29 1 0.00000000 0.50000000 0.00000000 1 - Sb Sb30 1 0.50000000 0.00000000 0.00000000 1 - Sb Sb31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.40803500 0.80548400 0.77398200 1 - O O33 1 0.86594600 0.39744900 0.09196400 1 - O O34 1 0.10255100 0.96849700 0.69451600 1 - O O35 1 0.53150300 0.63405400 0.72601800 1 - O O36 1 0.69451600 0.09196400 0.72601800 1 - O O37 1 0.63405400 0.72601800 0.53150300 1 - O O38 1 0.63405400 0.40803500 0.10255100 1 - O O39 1 0.72601800 0.53150300 0.63405400 1 - O O40 1 0.80548400 0.53150300 0.39744900 1 - O O41 1 0.96849700 0.77398200 0.86594600 1 - O O42 1 0.77398200 0.86594600 0.96849700 1 - O O43 1 0.72601800 0.69451600 0.09196500 1 - O O44 1 0.40803500 0.10255100 0.63405400 1 - O O45 1 0.39744900 0.80548400 0.53150300 1 - O O46 1 0.09196500 0.72601800 0.69451600 1 - O O47 1 0.10255100 0.63405400 0.40803500 1 - O O48 1 0.53150300 0.39744900 0.80548400 1 - O O49 1 0.09196400 0.86594600 0.39744900 1 - O O50 1 0.96849700 0.69451600 0.10255100 1 - O O51 1 0.19451600 0.46849700 0.60255100 1 - O O52 1 0.69451600 0.10255100 0.96849700 1 - O O53 1 0.77398200 0.40803500 0.80548400 1 - O O54 1 0.39744900 0.09196400 0.86594600 1 - O O55 1 0.86594600 0.96849700 0.77398200 1 - O O56 1 0.59196400 0.19451600 0.22601800 1 - O O57 1 0.13405400 0.60255100 0.90803500 1 - O O58 1 0.89744900 0.03150300 0.30548400 1 - O O59 1 0.46849700 0.36594600 0.27398200 1 - O O60 1 0.30548400 0.90803500 0.27398200 1 - O O61 1 0.36594600 0.27398200 0.46849700 1 - O O62 1 0.36594600 0.59196400 0.89744900 1 - O O63 1 0.27398200 0.46849700 0.36594600 1 - O O64 1 0.13405400 0.03150300 0.22601800 1 - O O65 1 0.60255100 0.90803500 0.13405400 1 - O O66 1 0.22601800 0.59196400 0.19451600 1 - O O67 1 0.19451600 0.22601800 0.59196500 1 - O O68 1 0.30548400 0.89744900 0.03150300 1 - O O69 1 0.03150300 0.30548400 0.89744900 1 - O O70 1 0.90803500 0.13405400 0.60255100 1 - O O71 1 0.46849700 0.60255100 0.19451600 1 - O O72 1 0.89744900 0.36594600 0.59196500 1 - O O73 1 0.90803500 0.27398200 0.30548400 1 - O O74 1 0.60255100 0.19451600 0.46849700 1 - O O75 1 0.59196400 0.89744900 0.36594600 1 - O O76 1 0.27398200 0.30548400 0.90803500 1 - O O77 1 0.22601800 0.13405400 0.03150300 1 - O O78 1 0.03150300 0.22601800 0.13405400 1 - O O79 1 0.80548400 0.77398200 0.40803500 1 -" -Mg3Cu2(GeO4)3,mvc-4251,Ia-3d,[],0.10800505481250422,{'tags': []},"Full Formula (Mg12 Cu8 Ge12 O48) -Reduced Formula: Mg3Cu2(GeO4)3 -abc : 10.383378 10.383378 10.383378 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 -0.002 - 1 Mg 0.75 0.625 0.875 -0.002 - 2 Mg 0.625 0.875 0.75 -0.002 - 3 Mg 0.875 0.625 0.25 -0.002 - 4 Mg 0.625 0.25 0.875 -0.002 - 5 Mg 0.875 0.75 0.625 -0.002 - 6 Mg 0.75 0.125 0.375 -0.002 - 7 Mg 0.25 0.375 0.125 -0.002 - 8 Mg 0.375 0.125 0.25 -0.002 - 9 Mg 0.125 0.375 0.75 -0.002 - 10 Mg 0.375 0.75 0.125 -0.002 - 11 Mg 0.125 0.25 0.375 -0.002 - 12 Cu 0.5 0.5 0.5 0.942 - 13 Cu 0.5 0 0.5 0.942 - 14 Cu 0 0.5 0.5 0.942 - 15 Cu 0.5 0.5 0 0.942 - 16 Cu 0 0 0.5 0.942 - 17 Cu 0 0.5 0 0.942 - 18 Cu 0.5 0 0 0.942 - 19 Cu 0 0 0 0.942 - 20 Ge 0.125 0.75 0.875 0.013 - 21 Ge 0.875 0.25 0.125 0.013 - 22 Ge 0.625 0.375 0.25 0.013 - 23 Ge 0.75 0.875 0.125 0.013 - 24 Ge 0.875 0.125 0.75 0.013 - 25 Ge 0.25 0.625 0.375 0.013 - 26 Ge 0.75 0.375 0.625 0.013 - 27 Ge 0.25 0.125 0.875 0.013 - 28 Ge 0.125 0.875 0.25 0.013 - 29 Ge 0.375 0.625 0.75 0.013 - 30 Ge 0.625 0.75 0.375 0.013 - 31 Ge 0.375 0.25 0.625 0.013 - 32 O 0.41849 0.819253 0.789558 0.152 - 33 O 0.871068 0.400763 0.08151 0.152 - 34 O 0.099237 0.970305 0.680747 0.152 - 35 O 0.529695 0.628932 0.710442 0.152 - 36 O 0.680747 0.08151 0.710442 0.152 - 37 O 0.628932 0.710442 0.529695 0.152 - 38 O 0.628932 0.41849 0.099237 0.152 - 39 O 0.710442 0.529695 0.628932 0.152 - 40 O 0.819253 0.529695 0.400763 0.152 - 41 O 0.970305 0.789558 0.871068 0.152 - 42 O 0.789558 0.871068 0.970305 0.152 - 43 O 0.710442 0.680747 0.08151 0.152 - 44 O 0.41849 0.099237 0.628932 0.152 - 45 O 0.400763 0.819253 0.529695 0.152 - 46 O 0.08151 0.710442 0.680747 0.152 - 47 O 0.099237 0.628932 0.41849 0.152 - 48 O 0.529695 0.400763 0.819253 0.152 - 49 O 0.08151 0.871068 0.400763 0.152 - 50 O 0.970305 0.680747 0.099237 0.152 - 51 O 0.180747 0.470305 0.599237 0.152 - 52 O 0.680747 0.099237 0.970305 0.152 - 53 O 0.789558 0.41849 0.819253 0.152 - 54 O 0.400763 0.08151 0.871068 0.152 - 55 O 0.871068 0.970305 0.789558 0.152 - 56 O 0.58151 0.180747 0.210442 0.152 - 57 O 0.128932 0.599237 0.91849 0.152 - 58 O 0.900763 0.029695 0.319253 0.152 - 59 O 0.470305 0.371068 0.289558 0.152 - 60 O 0.319253 0.91849 0.289558 0.152 - 61 O 0.371068 0.289558 0.470305 0.152 - 62 O 0.371068 0.58151 0.900763 0.152 - 63 O 0.289558 0.470305 0.371068 0.152 - 64 O 0.128932 0.029695 0.210442 0.152 - 65 O 0.599237 0.91849 0.128932 0.152 - 66 O 0.210442 0.58151 0.180747 0.152 - 67 O 0.180747 0.210442 0.58151 0.152 - 68 O 0.319253 0.900763 0.029695 0.152 - 69 O 0.029695 0.319253 0.900763 0.152 - 70 O 0.91849 0.128932 0.599237 0.152 - 71 O 0.470305 0.599237 0.180747 0.152 - 72 O 0.900763 0.371068 0.58151 0.152 - 73 O 0.91849 0.289558 0.319253 0.152 - 74 O 0.599237 0.180747 0.470305 0.152 - 75 O 0.58151 0.900763 0.371068 0.152 - 76 O 0.289558 0.319253 0.91849 0.152 - 77 O 0.210442 0.128932 0.029695 0.152 - 78 O 0.029695 0.210442 0.128932 0.152 - 79 O 0.819253 0.789558 0.41849 0.152","# generated using pymatgen -data_Mg3Cu2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.38337786 -_cell_length_b 10.38337786 -_cell_length_c 10.38337786 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Cu2(GeO4)3 -_chemical_formula_sum 'Mg12 Cu8 Ge12 O48' -_cell_volume 861.77538404 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Cu Cu12 1 0.50000000 0.50000000 0.50000000 1 - Cu Cu13 1 0.50000000 0.00000000 0.50000000 1 - Cu Cu14 1 0.00000000 0.50000000 0.50000000 1 - Cu Cu15 1 0.50000000 0.50000000 0.00000000 1 - Cu Cu16 1 0.00000000 0.00000000 0.50000000 1 - Cu Cu17 1 0.00000000 0.50000000 0.00000000 1 - Cu Cu18 1 0.50000000 0.00000000 0.00000000 1 - Cu Cu19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41849000 0.81925300 0.78955800 1 - O O33 1 0.87106800 0.40076300 0.08151000 1 - O O34 1 0.09923700 0.97030500 0.68074700 1 - O O35 1 0.52969500 0.62893200 0.71044200 1 - O O36 1 0.68074700 0.08151000 0.71044200 1 - O O37 1 0.62893200 0.71044200 0.52969500 1 - O O38 1 0.62893200 0.41849000 0.09923700 1 - O O39 1 0.71044200 0.52969500 0.62893200 1 - O O40 1 0.81925300 0.52969500 0.40076300 1 - O O41 1 0.97030500 0.78955800 0.87106800 1 - O O42 1 0.78955800 0.87106800 0.97030500 1 - O O43 1 0.71044200 0.68074700 0.08151000 1 - O O44 1 0.41849000 0.09923700 0.62893200 1 - O O45 1 0.40076300 0.81925300 0.52969500 1 - O O46 1 0.08151000 0.71044200 0.68074700 1 - O O47 1 0.09923700 0.62893200 0.41849000 1 - O O48 1 0.52969500 0.40076300 0.81925300 1 - O O49 1 0.08151000 0.87106800 0.40076300 1 - O O50 1 0.97030500 0.68074700 0.09923700 1 - O O51 1 0.18074700 0.47030500 0.59923700 1 - O O52 1 0.68074700 0.09923700 0.97030500 1 - O O53 1 0.78955800 0.41849000 0.81925300 1 - O O54 1 0.40076300 0.08151000 0.87106800 1 - O O55 1 0.87106800 0.97030500 0.78955800 1 - O O56 1 0.58151000 0.18074700 0.21044200 1 - O O57 1 0.12893200 0.59923700 0.91849000 1 - O O58 1 0.90076300 0.02969500 0.31925300 1 - O O59 1 0.47030500 0.37106800 0.28955800 1 - O O60 1 0.31925300 0.91849000 0.28955800 1 - O O61 1 0.37106800 0.28955800 0.47030500 1 - O O62 1 0.37106800 0.58151000 0.90076300 1 - O O63 1 0.28955800 0.47030500 0.37106800 1 - O O64 1 0.12893200 0.02969500 0.21044200 1 - O O65 1 0.59923700 0.91849000 0.12893200 1 - O O66 1 0.21044200 0.58151000 0.18074700 1 - O O67 1 0.18074700 0.21044200 0.58151000 1 - O O68 1 0.31925300 0.90076300 0.02969500 1 - O O69 1 0.02969500 0.31925300 0.90076300 1 - O O70 1 0.91849000 0.12893200 0.59923700 1 - O O71 1 0.47030500 0.59923700 0.18074700 1 - O O72 1 0.90076300 0.37106800 0.58151000 1 - O O73 1 0.91849000 0.28955800 0.31925300 1 - O O74 1 0.59923700 0.18074700 0.47030500 1 - O O75 1 0.58151000 0.90076300 0.37106800 1 - O O76 1 0.28955800 0.31925300 0.91849000 1 - O O77 1 0.21044200 0.12893200 0.02969500 1 - O O78 1 0.02969500 0.21044200 0.12893200 1 - O O79 1 0.81925300 0.78955800 0.41849000 1 -" -Zn3Ge3(SbO6)2,mvc-4256,Ia-3d,[],0.2848058091250003,{'tags': []},"Full Formula (Zn12 Ge12 Sb8 O48) -Reduced Formula: Zn3Ge3(SbO6)2 -abc : 10.968681 10.968681 10.968681 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 -0 - 1 Zn 0.75 0.625 0.875 -0 - 2 Zn 0.625 0.875 0.75 -0 - 3 Zn 0.875 0.625 0.25 -0 - 4 Zn 0.625 0.25 0.875 -0 - 5 Zn 0.875 0.75 0.625 -0 - 6 Zn 0.75 0.125 0.375 -0 - 7 Zn 0.25 0.375 0.125 -0 - 8 Zn 0.375 0.125 0.25 -0 - 9 Zn 0.125 0.375 0.75 -0 - 10 Zn 0.375 0.75 0.125 -0 - 11 Zn 0.125 0.25 0.375 -0 - 12 Ge 0.125 0.75 0.875 -0.001 - 13 Ge 0.875 0.25 0.125 -0.001 - 14 Ge 0.625 0.375 0.25 -0.001 - 15 Ge 0.75 0.875 0.125 -0.001 - 16 Ge 0.875 0.125 0.75 -0.001 - 17 Ge 0.25 0.625 0.375 -0.001 - 18 Ge 0.75 0.375 0.625 -0.001 - 19 Ge 0.25 0.125 0.875 -0.001 - 20 Ge 0.125 0.875 0.25 -0.001 - 21 Ge 0.375 0.625 0.75 -0.001 - 22 Ge 0.625 0.75 0.375 -0.001 - 23 Ge 0.375 0.25 0.625 -0.001 - 24 Sb 0.5 0.5 0.5 -0 - 25 Sb 0.5 0 0.5 -0 - 26 Sb 0 0.5 0.5 -0 - 27 Sb 0.5 0.5 0 -0 - 28 Sb 0 0 0.5 -0 - 29 Sb 0 0.5 0 -0 - 30 Sb 0.5 0 0 -0 - 31 Sb 0 0 0 -0 - 32 O 0.410926 0.806649 0.776302 0.001 - 33 O 0.865376 0.395723 0.089074 0.001 - 34 O 0.104277 0.969653 0.693351 0.001 - 35 O 0.530347 0.634624 0.723698 0.001 - 36 O 0.693351 0.089074 0.723698 0.001 - 37 O 0.634624 0.723698 0.530347 0.001 - 38 O 0.634624 0.410926 0.104277 0.001 - 39 O 0.723698 0.530347 0.634624 0.001 - 40 O 0.806649 0.530347 0.395723 0.001 - 41 O 0.969653 0.776302 0.865376 0.001 - 42 O 0.776302 0.865376 0.969653 0.001 - 43 O 0.723698 0.693351 0.089074 0.001 - 44 O 0.410926 0.104277 0.634624 0.001 - 45 O 0.395723 0.806649 0.530347 0.001 - 46 O 0.089074 0.723698 0.693351 0.001 - 47 O 0.104277 0.634624 0.410926 0.001 - 48 O 0.530347 0.395723 0.806649 0.001 - 49 O 0.089074 0.865376 0.395723 0.001 - 50 O 0.969653 0.693351 0.104277 0.001 - 51 O 0.193351 0.469653 0.604277 0.001 - 52 O 0.693351 0.104277 0.969653 0.001 - 53 O 0.776302 0.410926 0.806649 0.001 - 54 O 0.395723 0.089074 0.865376 0.001 - 55 O 0.865376 0.969653 0.776302 0.001 - 56 O 0.589074 0.193351 0.223698 0.001 - 57 O 0.134624 0.604277 0.910926 0.001 - 58 O 0.895723 0.030347 0.306649 0.001 - 59 O 0.469653 0.365376 0.276302 0.001 - 60 O 0.306649 0.910926 0.276302 0.001 - 61 O 0.365376 0.276302 0.469653 0.001 - 62 O 0.365376 0.589074 0.895723 0.001 - 63 O 0.276302 0.469653 0.365376 0.001 - 64 O 0.134624 0.030347 0.223698 0.001 - 65 O 0.604277 0.910926 0.134624 0.001 - 66 O 0.223698 0.589074 0.193351 0.001 - 67 O 0.193351 0.223698 0.589074 0.001 - 68 O 0.306649 0.895723 0.030347 0.001 - 69 O 0.030347 0.306649 0.895723 0.001 - 70 O 0.910926 0.134624 0.604277 0.001 - 71 O 0.469653 0.604277 0.193351 0.001 - 72 O 0.895723 0.365376 0.589074 0.001 - 73 O 0.910926 0.276302 0.306649 0.001 - 74 O 0.604277 0.193351 0.469653 0.001 - 75 O 0.589074 0.895723 0.365376 0.001 - 76 O 0.276302 0.306649 0.910926 0.001 - 77 O 0.223698 0.134624 0.030347 0.001 - 78 O 0.030347 0.223698 0.134624 0.001 - 79 O 0.806649 0.776302 0.410926 0.001","# generated using pymatgen -data_Zn3Ge3(SbO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.96868112 -_cell_length_b 10.96868112 -_cell_length_c 10.96868112 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Ge3(SbO6)2 -_chemical_formula_sum 'Zn12 Ge12 Sb8 O48' -_cell_volume 1015.87750240 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Sb Sb24 1 0.50000000 0.50000000 0.50000000 1 - Sb Sb25 1 0.50000000 0.00000000 0.50000000 1 - Sb Sb26 1 0.00000000 0.50000000 0.50000000 1 - Sb Sb27 1 0.50000000 0.50000000 0.00000000 1 - Sb Sb28 1 0.00000000 0.00000000 0.50000000 1 - Sb Sb29 1 0.00000000 0.50000000 0.00000000 1 - Sb Sb30 1 0.50000000 0.00000000 0.00000000 1 - Sb Sb31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.41092600 0.80664900 0.77630200 1 - O O33 1 0.86537600 0.39572300 0.08907400 1 - O O34 1 0.10427700 0.96965300 0.69335100 1 - O O35 1 0.53034700 0.63462400 0.72369800 1 - O O36 1 0.69335100 0.08907400 0.72369800 1 - O O37 1 0.63462400 0.72369800 0.53034700 1 - O O38 1 0.63462400 0.41092600 0.10427700 1 - O O39 1 0.72369800 0.53034700 0.63462400 1 - O O40 1 0.80664900 0.53034700 0.39572300 1 - O O41 1 0.96965300 0.77630200 0.86537600 1 - O O42 1 0.77630200 0.86537600 0.96965300 1 - O O43 1 0.72369800 0.69335100 0.08907400 1 - O O44 1 0.41092600 0.10427700 0.63462400 1 - O O45 1 0.39572300 0.80664900 0.53034700 1 - O O46 1 0.08907400 0.72369800 0.69335100 1 - O O47 1 0.10427700 0.63462400 0.41092600 1 - O O48 1 0.53034700 0.39572300 0.80664900 1 - O O49 1 0.08907400 0.86537600 0.39572300 1 - O O50 1 0.96965300 0.69335100 0.10427700 1 - O O51 1 0.19335100 0.46965300 0.60427700 1 - O O52 1 0.69335100 0.10427700 0.96965300 1 - O O53 1 0.77630200 0.41092600 0.80664900 1 - O O54 1 0.39572300 0.08907400 0.86537600 1 - O O55 1 0.86537600 0.96965300 0.77630200 1 - O O56 1 0.58907400 0.19335100 0.22369800 1 - O O57 1 0.13462400 0.60427700 0.91092600 1 - O O58 1 0.89572300 0.03034700 0.30664900 1 - O O59 1 0.46965300 0.36537600 0.27630200 1 - O O60 1 0.30664900 0.91092600 0.27630200 1 - O O61 1 0.36537600 0.27630200 0.46965300 1 - O O62 1 0.36537600 0.58907400 0.89572300 1 - O O63 1 0.27630200 0.46965300 0.36537600 1 - O O64 1 0.13462400 0.03034700 0.22369800 1 - O O65 1 0.60427700 0.91092600 0.13462400 1 - O O66 1 0.22369800 0.58907400 0.19335100 1 - O O67 1 0.19335100 0.22369800 0.58907400 1 - O O68 1 0.30664900 0.89572300 0.03034700 1 - O O69 1 0.03034700 0.30664900 0.89572300 1 - O O70 1 0.91092600 0.13462400 0.60427700 1 - O O71 1 0.46965300 0.60427700 0.19335100 1 - O O72 1 0.89572300 0.36537600 0.58907400 1 - O O73 1 0.91092600 0.27630200 0.30664900 1 - O O74 1 0.60427700 0.19335100 0.46965300 1 - O O75 1 0.58907400 0.89572300 0.36537600 1 - O O76 1 0.27630200 0.30664900 0.91092600 1 - O O77 1 0.22369800 0.13462400 0.03034700 1 - O O78 1 0.03034700 0.22369800 0.13462400 1 - O O79 1 0.80664900 0.77630200 0.41092600 1 -" -Ca3Sn2(GeO4)3,mvc-4258,Ia-3d,[],0.09168471937500389,{'tags': []},"Full Formula (Ca12 Sn8 Ge12 O48) -Reduced Formula: Ca3Sn2(GeO4)3 -abc : 11.186407 11.186407 11.186407 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0.001 - 1 Ca 0.75 0.625 0.875 0.001 - 2 Ca 0.625 0.875 0.75 0.002 - 3 Ca 0.875 0.625 0.25 0.002 - 4 Ca 0.625 0.25 0.875 0.002 - 5 Ca 0.875 0.75 0.625 0.002 - 6 Ca 0.75 0.125 0.375 0.001 - 7 Ca 0.25 0.375 0.125 0.001 - 8 Ca 0.375 0.125 0.25 0.002 - 9 Ca 0.125 0.375 0.75 0.002 - 10 Ca 0.375 0.75 0.125 0.002 - 11 Ca 0.125 0.25 0.375 0.002 - 12 Sn 0.5 0.5 0.5 0.123 - 13 Sn 0.5 0 0.5 0.136 - 14 Sn 0 0.5 0.5 0.136 - 15 Sn 0.5 0.5 0 0.123 - 16 Sn 0 0 0.5 0.136 - 17 Sn 0 0.5 0 0.123 - 18 Sn 0.5 0 0 0.136 - 19 Sn 0 0 0 0.123 - 20 Ge 0.125 0.75 0.875 0.017 - 21 Ge 0.875 0.25 0.125 0.017 - 22 Ge 0.625 0.375 0.25 0.017 - 23 Ge 0.75 0.875 0.125 0.019 - 24 Ge 0.875 0.125 0.75 0.017 - 25 Ge 0.25 0.625 0.375 0.019 - 26 Ge 0.75 0.375 0.625 0.019 - 27 Ge 0.25 0.125 0.875 0.019 - 28 Ge 0.125 0.875 0.25 0.017 - 29 Ge 0.375 0.625 0.75 0.017 - 30 Ge 0.625 0.75 0.375 0.017 - 31 Ge 0.375 0.25 0.625 0.017 - 32 O 0.412942 0.808377 0.788069 0.031 - 33 O 0.875127 0.395435 0.087058 0.028 - 34 O 0.104565 0.979692 0.691623 0.028 - 35 O 0.520308 0.624873 0.711931 0.029 - 36 O 0.691623 0.087058 0.711931 0.027 - 37 O 0.624873 0.711931 0.520308 0.028 - 38 O 0.624873 0.412942 0.104565 0.028 - 39 O 0.711931 0.520308 0.624873 0.026 - 40 O 0.808377 0.520308 0.395435 0.027 - 41 O 0.979692 0.788069 0.875127 0.029 - 42 O 0.788069 0.875127 0.979692 0.026 - 43 O 0.711931 0.691623 0.087058 0.026 - 44 O 0.412942 0.104565 0.624873 0.031 - 45 O 0.395435 0.808377 0.520308 0.028 - 46 O 0.087058 0.711931 0.691623 0.031 - 47 O 0.104565 0.624873 0.412942 0.028 - 48 O 0.520308 0.395435 0.808377 0.029 - 49 O 0.087058 0.875127 0.395435 0.031 - 50 O 0.979692 0.691623 0.104565 0.029 - 51 O 0.191623 0.479692 0.604565 0.027 - 52 O 0.691623 0.104565 0.979692 0.027 - 53 O 0.788069 0.412942 0.808377 0.026 - 54 O 0.395435 0.087058 0.875127 0.028 - 55 O 0.875127 0.979692 0.788069 0.028 - 56 O 0.587058 0.191623 0.211931 0.031 - 57 O 0.124873 0.604565 0.912942 0.028 - 58 O 0.895435 0.020308 0.308377 0.028 - 59 O 0.479692 0.375127 0.288069 0.029 - 60 O 0.308377 0.912942 0.288069 0.027 - 61 O 0.375127 0.288069 0.479692 0.028 - 62 O 0.375127 0.587058 0.895435 0.028 - 63 O 0.288069 0.479692 0.375127 0.026 - 64 O 0.124873 0.020308 0.211931 0.028 - 65 O 0.604565 0.912942 0.124873 0.028 - 66 O 0.211931 0.587058 0.191623 0.026 - 67 O 0.191623 0.211931 0.587058 0.027 - 68 O 0.308377 0.895435 0.020308 0.027 - 69 O 0.020308 0.308377 0.895435 0.029 - 70 O 0.912942 0.124873 0.604565 0.031 - 71 O 0.479692 0.604565 0.191623 0.029 - 72 O 0.895435 0.375127 0.587058 0.028 - 73 O 0.912942 0.288069 0.308377 0.031 - 74 O 0.604565 0.191623 0.479692 0.028 - 75 O 0.587058 0.895435 0.375127 0.031 - 76 O 0.288069 0.308377 0.912942 0.026 - 77 O 0.211931 0.124873 0.020308 0.026 - 78 O 0.020308 0.211931 0.124873 0.029 - 79 O 0.808377 0.788069 0.412942 0.027","# generated using pymatgen -data_Ca3Sn2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.18640684 -_cell_length_b 11.18640684 -_cell_length_c 11.18640684 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Sn2(GeO4)3 -_chemical_formula_sum 'Ca12 Sn8 Ge12 O48' -_cell_volume 1077.58103599 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Sn Sn12 1 0.50000000 0.50000000 0.50000000 1 - Sn Sn13 1 0.50000000 0.00000000 0.50000000 1 - Sn Sn14 1 0.00000000 0.50000000 0.50000000 1 - Sn Sn15 1 0.50000000 0.50000000 0.00000000 1 - Sn Sn16 1 0.00000000 0.00000000 0.50000000 1 - Sn Sn17 1 0.00000000 0.50000000 0.00000000 1 - Sn Sn18 1 0.50000000 0.00000000 0.00000000 1 - Sn Sn19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41294200 0.80837700 0.78806900 1 - O O33 1 0.87512700 0.39543500 0.08705800 1 - O O34 1 0.10456500 0.97969200 0.69162300 1 - O O35 1 0.52030800 0.62487300 0.71193100 1 - O O36 1 0.69162300 0.08705800 0.71193100 1 - O O37 1 0.62487300 0.71193100 0.52030800 1 - O O38 1 0.62487300 0.41294200 0.10456500 1 - O O39 1 0.71193100 0.52030800 0.62487300 1 - O O40 1 0.80837700 0.52030800 0.39543500 1 - O O41 1 0.97969200 0.78806900 0.87512700 1 - O O42 1 0.78806900 0.87512700 0.97969200 1 - O O43 1 0.71193100 0.69162300 0.08705800 1 - O O44 1 0.41294200 0.10456500 0.62487300 1 - O O45 1 0.39543500 0.80837700 0.52030800 1 - O O46 1 0.08705800 0.71193100 0.69162300 1 - O O47 1 0.10456500 0.62487300 0.41294200 1 - O O48 1 0.52030800 0.39543500 0.80837700 1 - O O49 1 0.08705800 0.87512700 0.39543500 1 - O O50 1 0.97969200 0.69162300 0.10456500 1 - O O51 1 0.19162300 0.47969200 0.60456500 1 - O O52 1 0.69162300 0.10456500 0.97969200 1 - O O53 1 0.78806900 0.41294200 0.80837700 1 - O O54 1 0.39543500 0.08705800 0.87512700 1 - O O55 1 0.87512700 0.97969200 0.78806900 1 - O O56 1 0.58705800 0.19162300 0.21193100 1 - O O57 1 0.12487300 0.60456500 0.91294200 1 - O O58 1 0.89543500 0.02030800 0.30837700 1 - O O59 1 0.47969200 0.37512700 0.28806900 1 - O O60 1 0.30837700 0.91294200 0.28806900 1 - O O61 1 0.37512700 0.28806900 0.47969200 1 - O O62 1 0.37512700 0.58705800 0.89543500 1 - O O63 1 0.28806900 0.47969200 0.37512700 1 - O O64 1 0.12487300 0.02030800 0.21193100 1 - O O65 1 0.60456500 0.91294200 0.12487300 1 - O O66 1 0.21193100 0.58705800 0.19162300 1 - O O67 1 0.19162300 0.21193100 0.58705800 1 - O O68 1 0.30837700 0.89543500 0.02030800 1 - O O69 1 0.02030800 0.30837700 0.89543500 1 - O O70 1 0.91294200 0.12487300 0.60456500 1 - O O71 1 0.47969200 0.60456500 0.19162300 1 - O O72 1 0.89543500 0.37512700 0.58705800 1 - O O73 1 0.91294200 0.28806900 0.30837700 1 - O O74 1 0.60456500 0.19162300 0.47969200 1 - O O75 1 0.58705800 0.89543500 0.37512700 1 - O O76 1 0.28806900 0.30837700 0.91294200 1 - O O77 1 0.21193100 0.12487300 0.02030800 1 - O O78 1 0.02030800 0.21193100 0.12487300 1 - O O79 1 0.80837700 0.78806900 0.41294200 1 -" -Mg3Ge3(BiO6)2,mvc-4265,Ia-3d,[],0.21018772124999963,{'tags': []},"Full Formula (Mg12 Ge12 Bi8 O48) -Reduced Formula: Mg3Ge3(BiO6)2 -abc : 11.081230 11.081230 11.081230 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0 - 1 Mg 0.75 0.625 0.875 0 - 2 Mg 0.625 0.875 0.75 0 - 3 Mg 0.875 0.625 0.25 0 - 4 Mg 0.625 0.25 0.875 0 - 5 Mg 0.875 0.75 0.625 0 - 6 Mg 0.75 0.125 0.375 0 - 7 Mg 0.25 0.375 0.125 0 - 8 Mg 0.375 0.125 0.25 0 - 9 Mg 0.125 0.375 0.75 0 - 10 Mg 0.375 0.75 0.125 0 - 11 Mg 0.125 0.25 0.375 0 - 12 Ge 0.125 0.75 0.875 0 - 13 Ge 0.875 0.25 0.125 0 - 14 Ge 0.625 0.375 0.25 0 - 15 Ge 0.75 0.875 0.125 0 - 16 Ge 0.875 0.125 0.75 0 - 17 Ge 0.25 0.625 0.375 0 - 18 Ge 0.75 0.375 0.625 0 - 19 Ge 0.25 0.125 0.875 0 - 20 Ge 0.125 0.875 0.25 0 - 21 Ge 0.375 0.625 0.75 0 - 22 Ge 0.625 0.75 0.375 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Bi 0.5 0.5 0.5 0 - 25 Bi 0.5 0 0.5 0 - 26 Bi 0 0.5 0.5 0 - 27 Bi 0.5 0.5 0 0 - 28 Bi 0 0 0.5 0 - 29 Bi 0 0.5 0 0 - 30 Bi 0.5 0 0 0 - 31 Bi 0 0 0 0 - 32 O 0.404858 0.801303 0.769349 -0 - 33 O 0.864491 0.396444 0.095142 -0 - 34 O 0.103556 0.968046 0.698697 -0 - 35 O 0.531954 0.635509 0.730651 -0 - 36 O 0.698697 0.095142 0.730651 -0 - 37 O 0.635509 0.730651 0.531954 -0 - 38 O 0.635509 0.404858 0.103556 -0 - 39 O 0.730651 0.531954 0.635509 -0 - 40 O 0.801303 0.531954 0.396444 -0 - 41 O 0.968046 0.769349 0.864491 -0 - 42 O 0.769349 0.864491 0.968046 -0 - 43 O 0.730651 0.698697 0.095142 -0 - 44 O 0.404858 0.103556 0.635509 -0 - 45 O 0.396444 0.801303 0.531954 -0 - 46 O 0.095142 0.730651 0.698697 -0 - 47 O 0.103556 0.635509 0.404858 -0 - 48 O 0.531954 0.396444 0.801303 -0 - 49 O 0.095142 0.864491 0.396444 -0 - 50 O 0.968046 0.698697 0.103556 -0 - 51 O 0.198697 0.468046 0.603556 -0 - 52 O 0.698697 0.103556 0.968046 -0 - 53 O 0.769349 0.404858 0.801303 -0 - 54 O 0.396444 0.095142 0.864491 -0 - 55 O 0.864491 0.968046 0.769349 -0 - 56 O 0.595142 0.198697 0.230651 -0 - 57 O 0.135509 0.603556 0.904858 -0 - 58 O 0.896444 0.031954 0.301303 -0 - 59 O 0.468046 0.364491 0.269349 -0 - 60 O 0.301303 0.904858 0.269349 -0 - 61 O 0.364491 0.269349 0.468046 -0 - 62 O 0.364491 0.595142 0.896444 -0 - 63 O 0.269349 0.468046 0.364491 -0 - 64 O 0.135509 0.031954 0.230651 -0 - 65 O 0.603556 0.904858 0.135509 -0 - 66 O 0.230651 0.595142 0.198697 -0 - 67 O 0.198697 0.230651 0.595142 -0 - 68 O 0.301303 0.896444 0.031954 -0 - 69 O 0.031954 0.301303 0.896444 -0 - 70 O 0.904858 0.135509 0.603556 -0 - 71 O 0.468046 0.603556 0.198697 -0 - 72 O 0.896444 0.364491 0.595142 -0 - 73 O 0.904858 0.269349 0.301303 -0 - 74 O 0.603556 0.198697 0.468046 -0 - 75 O 0.595142 0.896444 0.364491 -0 - 76 O 0.269349 0.301303 0.904858 -0 - 77 O 0.230651 0.135509 0.031954 -0 - 78 O 0.031954 0.230651 0.135509 -0 - 79 O 0.801303 0.769349 0.404858 -0","# generated using pymatgen -data_Mg3Ge3(BiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.08122979 -_cell_length_b 11.08122979 -_cell_length_c 11.08122979 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ge3(BiO6)2 -_chemical_formula_sum 'Mg12 Ge12 Bi8 O48' -_cell_volume 1047.47095993 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Bi Bi24 1 0.50000000 0.50000000 0.50000000 1 - Bi Bi25 1 0.50000000 0.00000000 0.50000000 1 - Bi Bi26 1 0.00000000 0.50000000 0.50000000 1 - Bi Bi27 1 0.50000000 0.50000000 0.00000000 1 - Bi Bi28 1 0.00000000 0.00000000 0.50000000 1 - Bi Bi29 1 0.00000000 0.50000000 0.00000000 1 - Bi Bi30 1 0.50000000 0.00000000 0.00000000 1 - Bi Bi31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.40485800 0.80130300 0.76934900 1 - O O33 1 0.86449100 0.39644400 0.09514200 1 - O O34 1 0.10355600 0.96804600 0.69869700 1 - O O35 1 0.53195400 0.63550900 0.73065100 1 - O O36 1 0.69869700 0.09514200 0.73065100 1 - O O37 1 0.63550900 0.73065100 0.53195400 1 - O O38 1 0.63550900 0.40485800 0.10355600 1 - O O39 1 0.73065100 0.53195400 0.63550900 1 - O O40 1 0.80130300 0.53195400 0.39644400 1 - O O41 1 0.96804600 0.76934900 0.86449100 1 - O O42 1 0.76934900 0.86449100 0.96804600 1 - O O43 1 0.73065100 0.69869700 0.09514200 1 - O O44 1 0.40485800 0.10355600 0.63550900 1 - O O45 1 0.39644400 0.80130300 0.53195400 1 - O O46 1 0.09514200 0.73065100 0.69869700 1 - O O47 1 0.10355600 0.63550900 0.40485800 1 - O O48 1 0.53195400 0.39644400 0.80130300 1 - O O49 1 0.09514200 0.86449100 0.39644400 1 - O O50 1 0.96804600 0.69869700 0.10355600 1 - O O51 1 0.19869700 0.46804600 0.60355600 1 - O O52 1 0.69869700 0.10355600 0.96804600 1 - O O53 1 0.76934900 0.40485800 0.80130300 1 - O O54 1 0.39644400 0.09514200 0.86449100 1 - O O55 1 0.86449100 0.96804600 0.76934900 1 - O O56 1 0.59514200 0.19869700 0.23065100 1 - O O57 1 0.13550900 0.60355600 0.90485800 1 - O O58 1 0.89644400 0.03195400 0.30130300 1 - O O59 1 0.46804600 0.36449100 0.26934900 1 - O O60 1 0.30130300 0.90485800 0.26934900 1 - O O61 1 0.36449100 0.26934900 0.46804600 1 - O O62 1 0.36449100 0.59514200 0.89644400 1 - O O63 1 0.26934900 0.46804600 0.36449100 1 - O O64 1 0.13550900 0.03195400 0.23065100 1 - O O65 1 0.60355600 0.90485800 0.13550900 1 - O O66 1 0.23065100 0.59514200 0.19869700 1 - O O67 1 0.19869700 0.23065100 0.59514200 1 - O O68 1 0.30130300 0.89644400 0.03195400 1 - O O69 1 0.03195400 0.30130300 0.89644400 1 - O O70 1 0.90485800 0.13550900 0.60355600 1 - O O71 1 0.46804600 0.60355600 0.19869700 1 - O O72 1 0.89644400 0.36449100 0.59514200 1 - O O73 1 0.90485800 0.26934900 0.30130300 1 - O O74 1 0.60355600 0.19869700 0.46804600 1 - O O75 1 0.59514200 0.89644400 0.36449100 1 - O O76 1 0.26934900 0.30130300 0.90485800 1 - O O77 1 0.23065100 0.13550900 0.03195400 1 - O O78 1 0.03195400 0.23065100 0.13550900 1 - O O79 1 0.80130300 0.76934900 0.40485800 1 -" -Ca3Ge3(BiO6)2,mvc-4268,Ia-3d,[],0.02922517824999815,{'tags': []},"Full Formula (Ca12 Ge12 Bi8 O48) -Reduced Formula: Ca3Ge3(BiO6)2 -abc : 11.373640 11.373640 11.373640 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.625 0.875 0.75 0 - 3 Ca 0.875 0.625 0.25 0 - 4 Ca 0.625 0.25 0.875 0 - 5 Ca 0.875 0.75 0.625 0 - 6 Ca 0.75 0.125 0.375 0 - 7 Ca 0.25 0.375 0.125 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.125 0.375 0.75 0 - 10 Ca 0.375 0.75 0.125 0 - 11 Ca 0.125 0.25 0.375 0 - 12 Ge 0.125 0.75 0.875 0 - 13 Ge 0.875 0.25 0.125 0 - 14 Ge 0.625 0.375 0.25 0 - 15 Ge 0.75 0.875 0.125 0 - 16 Ge 0.875 0.125 0.75 0 - 17 Ge 0.25 0.625 0.375 0 - 18 Ge 0.75 0.375 0.625 0 - 19 Ge 0.25 0.125 0.875 0 - 20 Ge 0.125 0.875 0.25 0 - 21 Ge 0.375 0.625 0.75 0 - 22 Ge 0.625 0.75 0.375 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Bi 0.5 0.5 0.5 0 - 25 Bi 0.5 0 0.5 0 - 26 Bi 0 0.5 0.5 0 - 27 Bi 0.5 0.5 0 0 - 28 Bi 0 0 0.5 0 - 29 Bi 0 0.5 0 0 - 30 Bi 0.5 0 0 0 - 31 Bi 0 0 0 0 - 32 O 0.406009 0.799411 0.776351 -0 - 33 O 0.870343 0.393403 0.093991 -0 - 34 O 0.106597 0.97694 0.700589 -0 - 35 O 0.52306 0.629657 0.723649 -0 - 36 O 0.700589 0.093991 0.723649 -0 - 37 O 0.629657 0.723649 0.52306 -0 - 38 O 0.629657 0.406009 0.106597 -0 - 39 O 0.723649 0.52306 0.629657 -0 - 40 O 0.799411 0.52306 0.393403 -0 - 41 O 0.97694 0.776351 0.870343 -0 - 42 O 0.776351 0.870343 0.97694 -0 - 43 O 0.723649 0.700589 0.093991 -0 - 44 O 0.406009 0.106597 0.629657 -0 - 45 O 0.393403 0.799411 0.52306 -0 - 46 O 0.093991 0.723649 0.700589 -0 - 47 O 0.106597 0.629657 0.406009 -0 - 48 O 0.52306 0.393403 0.799411 -0 - 49 O 0.093991 0.870343 0.393403 -0 - 50 O 0.97694 0.700589 0.106597 -0 - 51 O 0.200589 0.47694 0.606597 -0 - 52 O 0.700589 0.106597 0.97694 -0 - 53 O 0.776351 0.406009 0.799411 -0 - 54 O 0.393403 0.093991 0.870343 -0 - 55 O 0.870343 0.97694 0.776351 -0 - 56 O 0.593991 0.200589 0.223649 -0 - 57 O 0.129657 0.606597 0.906009 -0 - 58 O 0.893403 0.02306 0.299411 -0 - 59 O 0.47694 0.370343 0.276351 -0 - 60 O 0.299411 0.906009 0.276351 -0 - 61 O 0.370343 0.276351 0.47694 -0 - 62 O 0.370343 0.593991 0.893403 -0 - 63 O 0.276351 0.47694 0.370343 -0 - 64 O 0.129657 0.02306 0.223649 -0 - 65 O 0.606597 0.906009 0.129657 -0 - 66 O 0.223649 0.593991 0.200589 -0 - 67 O 0.200589 0.223649 0.593991 -0 - 68 O 0.299411 0.893403 0.02306 -0 - 69 O 0.02306 0.299411 0.893403 -0 - 70 O 0.906009 0.129657 0.606597 -0 - 71 O 0.47694 0.606597 0.200589 -0 - 72 O 0.893403 0.370343 0.593991 -0 - 73 O 0.906009 0.276351 0.299411 -0 - 74 O 0.606597 0.200589 0.47694 -0 - 75 O 0.593991 0.893403 0.370343 -0 - 76 O 0.276351 0.299411 0.906009 -0 - 77 O 0.223649 0.129657 0.02306 -0 - 78 O 0.02306 0.223649 0.129657 -0 - 79 O 0.799411 0.776351 0.406009 -0","# generated using pymatgen -data_Ca3Ge3(BiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.37363980 -_cell_length_b 11.37363980 -_cell_length_c 11.37363980 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ge3(BiO6)2 -_chemical_formula_sum 'Ca12 Ge12 Bi8 O48' -_cell_volume 1132.59990185 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Bi Bi24 1 0.50000000 0.50000000 0.50000000 1 - Bi Bi25 1 0.50000000 0.00000000 0.50000000 1 - Bi Bi26 1 0.00000000 0.50000000 0.50000000 1 - Bi Bi27 1 0.50000000 0.50000000 0.00000000 1 - Bi Bi28 1 0.00000000 0.00000000 0.50000000 1 - Bi Bi29 1 0.00000000 0.50000000 0.00000000 1 - Bi Bi30 1 0.50000000 0.00000000 0.00000000 1 - Bi Bi31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.40600900 0.79941100 0.77635100 1 - O O33 1 0.87034300 0.39340300 0.09399100 1 - O O34 1 0.10659700 0.97694000 0.70058900 1 - O O35 1 0.52306000 0.62965700 0.72364900 1 - O O36 1 0.70058900 0.09399100 0.72364900 1 - O O37 1 0.62965700 0.72364900 0.52306000 1 - O O38 1 0.62965700 0.40600900 0.10659700 1 - O O39 1 0.72364900 0.52306000 0.62965700 1 - O O40 1 0.79941100 0.52306000 0.39340300 1 - O O41 1 0.97694000 0.77635100 0.87034300 1 - O O42 1 0.77635100 0.87034300 0.97694000 1 - O O43 1 0.72364900 0.70058900 0.09399100 1 - O O44 1 0.40600900 0.10659700 0.62965700 1 - O O45 1 0.39340300 0.79941100 0.52306000 1 - O O46 1 0.09399100 0.72364900 0.70058900 1 - O O47 1 0.10659700 0.62965700 0.40600900 1 - O O48 1 0.52306000 0.39340300 0.79941100 1 - O O49 1 0.09399100 0.87034300 0.39340300 1 - O O50 1 0.97694000 0.70058900 0.10659700 1 - O O51 1 0.20058900 0.47694000 0.60659700 1 - O O52 1 0.70058900 0.10659700 0.97694000 1 - O O53 1 0.77635100 0.40600900 0.79941100 1 - O O54 1 0.39340300 0.09399100 0.87034300 1 - O O55 1 0.87034300 0.97694000 0.77635100 1 - O O56 1 0.59399100 0.20058900 0.22364900 1 - O O57 1 0.12965700 0.60659700 0.90600900 1 - O O58 1 0.89340300 0.02306000 0.29941100 1 - O O59 1 0.47694000 0.37034300 0.27635100 1 - O O60 1 0.29941100 0.90600900 0.27635100 1 - O O61 1 0.37034300 0.27635100 0.47694000 1 - O O62 1 0.37034300 0.59399100 0.89340300 1 - O O63 1 0.27635100 0.47694000 0.37034300 1 - O O64 1 0.12965700 0.02306000 0.22364900 1 - O O65 1 0.60659700 0.90600900 0.12965700 1 - O O66 1 0.22364900 0.59399100 0.20058900 1 - O O67 1 0.20058900 0.22364900 0.59399100 1 - O O68 1 0.29941100 0.89340300 0.02306000 1 - O O69 1 0.02306000 0.29941100 0.89340300 1 - O O70 1 0.90600900 0.12965700 0.60659700 1 - O O71 1 0.47694000 0.60659700 0.20058900 1 - O O72 1 0.89340300 0.37034300 0.59399100 1 - O O73 1 0.90600900 0.27635100 0.29941100 1 - O O74 1 0.60659700 0.20058900 0.47694000 1 - O O75 1 0.59399100 0.89340300 0.37034300 1 - O O76 1 0.27635100 0.29941100 0.90600900 1 - O O77 1 0.22364900 0.12965700 0.02306000 1 - O O78 1 0.02306000 0.22364900 0.12965700 1 - O O79 1 0.79941100 0.77635100 0.40600900 1 -" -Zn3Ge3(BiO6)2,mvc-4269,Ia-3d,[],0.25597934799999766,{'tags': []},"Full Formula (Zn12 Ge12 Bi8 O48) -Reduced Formula: Zn3Ge3(BiO6)2 -abc : 11.080043 11.080043 11.080043 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 0 - 1 Zn 0.75 0.625 0.875 0 - 2 Zn 0.625 0.875 0.75 0 - 3 Zn 0.875 0.625 0.25 0 - 4 Zn 0.625 0.25 0.875 0 - 5 Zn 0.875 0.75 0.625 0 - 6 Zn 0.75 0.125 0.375 0 - 7 Zn 0.25 0.375 0.125 0 - 8 Zn 0.375 0.125 0.25 0 - 9 Zn 0.125 0.375 0.75 0 - 10 Zn 0.375 0.75 0.125 0 - 11 Zn 0.125 0.25 0.375 0 - 12 Ge 0.125 0.75 0.875 -0 - 13 Ge 0.875 0.25 0.125 0 - 14 Ge 0.625 0.375 0.25 -0 - 15 Ge 0.75 0.875 0.125 0 - 16 Ge 0.875 0.125 0.75 0 - 17 Ge 0.25 0.625 0.375 -0 - 18 Ge 0.75 0.375 0.625 0 - 19 Ge 0.25 0.125 0.875 -0 - 20 Ge 0.125 0.875 0.25 0 - 21 Ge 0.375 0.625 0.75 0 - 22 Ge 0.625 0.75 0.375 -0 - 23 Ge 0.375 0.25 0.625 0 - 24 Bi 0.5 0.5 0.5 -0 - 25 Bi 0.5 0 0.5 -0 - 26 Bi 0 0.5 0.5 -0 - 27 Bi 0.5 0.5 0 -0 - 28 Bi 0 0 0.5 -0 - 29 Bi 0 0.5 0 -0 - 30 Bi 0.5 0 0 -0 - 31 Bi 0 0 0 -0 - 32 O 0.406214 0.801647 0.770316 0 - 33 O 0.864102 0.395432 0.093786 0 - 34 O 0.104568 0.96867 0.698353 0 - 35 O 0.53133 0.635898 0.729684 0 - 36 O 0.698353 0.093786 0.729684 0 - 37 O 0.635898 0.729684 0.53133 0 - 38 O 0.635898 0.406214 0.104568 0 - 39 O 0.729684 0.53133 0.635898 0 - 40 O 0.801647 0.53133 0.395432 0 - 41 O 0.96867 0.770316 0.864102 0 - 42 O 0.770316 0.864102 0.96867 0 - 43 O 0.729684 0.698353 0.093786 0 - 44 O 0.406214 0.104568 0.635898 0 - 45 O 0.395432 0.801647 0.53133 0 - 46 O 0.093786 0.729684 0.698353 0 - 47 O 0.104568 0.635898 0.406214 0 - 48 O 0.53133 0.395432 0.801647 0 - 49 O 0.093786 0.864102 0.395432 0 - 50 O 0.96867 0.698353 0.104568 0 - 51 O 0.198353 0.46867 0.604568 0 - 52 O 0.698353 0.104568 0.96867 0 - 53 O 0.770316 0.406214 0.801647 0 - 54 O 0.395432 0.093786 0.864102 0 - 55 O 0.864102 0.96867 0.770316 0 - 56 O 0.593786 0.198353 0.229684 0 - 57 O 0.135898 0.604568 0.906214 0 - 58 O 0.895432 0.03133 0.301647 0 - 59 O 0.46867 0.364102 0.270316 0 - 60 O 0.301647 0.906214 0.270316 0 - 61 O 0.364102 0.270316 0.46867 0 - 62 O 0.364102 0.593786 0.895432 0 - 63 O 0.270316 0.46867 0.364102 0 - 64 O 0.135898 0.03133 0.229684 0 - 65 O 0.604568 0.906214 0.135898 0 - 66 O 0.229684 0.593786 0.198353 0 - 67 O 0.198353 0.229684 0.593786 0 - 68 O 0.301647 0.895432 0.03133 0 - 69 O 0.03133 0.301647 0.895432 0 - 70 O 0.906214 0.135898 0.604568 0 - 71 O 0.46867 0.604568 0.198353 0 - 72 O 0.895432 0.364102 0.593786 0 - 73 O 0.906214 0.270316 0.301647 0 - 74 O 0.604568 0.198353 0.46867 0 - 75 O 0.593786 0.895432 0.364102 0 - 76 O 0.270316 0.301647 0.906214 0 - 77 O 0.229684 0.135898 0.03133 0 - 78 O 0.03133 0.229684 0.135898 0 - 79 O 0.801647 0.770316 0.406214 0","# generated using pymatgen -data_Zn3Ge3(BiO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.08004333 -_cell_length_b 11.08004333 -_cell_length_c 11.08004333 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Ge3(BiO6)2 -_chemical_formula_sum 'Zn12 Ge12 Bi8 O48' -_cell_volume 1047.13454134 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Bi Bi24 1 0.50000000 0.50000000 0.50000000 1 - Bi Bi25 1 0.50000000 0.00000000 0.50000000 1 - Bi Bi26 1 0.00000000 0.50000000 0.50000000 1 - Bi Bi27 1 0.50000000 0.50000000 0.00000000 1 - Bi Bi28 1 0.00000000 0.00000000 0.50000000 1 - Bi Bi29 1 0.00000000 0.50000000 0.00000000 1 - Bi Bi30 1 0.50000000 0.00000000 0.00000000 1 - Bi Bi31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.40621400 0.80164700 0.77031600 1 - O O33 1 0.86410200 0.39543200 0.09378600 1 - O O34 1 0.10456800 0.96867000 0.69835300 1 - O O35 1 0.53133000 0.63589800 0.72968400 1 - O O36 1 0.69835300 0.09378600 0.72968400 1 - O O37 1 0.63589800 0.72968400 0.53133000 1 - O O38 1 0.63589800 0.40621400 0.10456800 1 - O O39 1 0.72968400 0.53133000 0.63589800 1 - O O40 1 0.80164700 0.53133000 0.39543200 1 - O O41 1 0.96867000 0.77031600 0.86410200 1 - O O42 1 0.77031600 0.86410200 0.96867000 1 - O O43 1 0.72968400 0.69835300 0.09378600 1 - O O44 1 0.40621400 0.10456800 0.63589800 1 - O O45 1 0.39543200 0.80164700 0.53133000 1 - O O46 1 0.09378600 0.72968400 0.69835300 1 - O O47 1 0.10456800 0.63589800 0.40621400 1 - O O48 1 0.53133000 0.39543200 0.80164700 1 - O O49 1 0.09378600 0.86410200 0.39543200 1 - O O50 1 0.96867000 0.69835300 0.10456800 1 - O O51 1 0.19835300 0.46867000 0.60456800 1 - O O52 1 0.69835300 0.10456800 0.96867000 1 - O O53 1 0.77031600 0.40621400 0.80164700 1 - O O54 1 0.39543200 0.09378600 0.86410200 1 - O O55 1 0.86410200 0.96867000 0.77031600 1 - O O56 1 0.59378600 0.19835300 0.22968400 1 - O O57 1 0.13589800 0.60456800 0.90621400 1 - O O58 1 0.89543200 0.03133000 0.30164700 1 - O O59 1 0.46867000 0.36410200 0.27031600 1 - O O60 1 0.30164700 0.90621400 0.27031600 1 - O O61 1 0.36410200 0.27031600 0.46867000 1 - O O62 1 0.36410200 0.59378600 0.89543200 1 - O O63 1 0.27031600 0.46867000 0.36410200 1 - O O64 1 0.13589800 0.03133000 0.22968400 1 - O O65 1 0.60456800 0.90621400 0.13589800 1 - O O66 1 0.22968400 0.59378600 0.19835300 1 - O O67 1 0.19835300 0.22968400 0.59378600 1 - O O68 1 0.30164700 0.89543200 0.03133000 1 - O O69 1 0.03133000 0.30164700 0.89543200 1 - O O70 1 0.90621400 0.13589800 0.60456800 1 - O O71 1 0.46867000 0.60456800 0.19835300 1 - O O72 1 0.89543200 0.36410200 0.59378600 1 - O O73 1 0.90621400 0.27031600 0.30164700 1 - O O74 1 0.60456800 0.19835300 0.46867000 1 - O O75 1 0.59378600 0.89543200 0.36410200 1 - O O76 1 0.27031600 0.30164700 0.90621400 1 - O O77 1 0.22968400 0.13589800 0.03133000 1 - O O78 1 0.03133000 0.22968400 0.13589800 1 - O O79 1 0.80164700 0.77031600 0.40621400 1 -" -Ca3Ge3(SbO6)2,mvc-4270,Ia-3d,[],0.06657413924999833,{'tags': []},"Full Formula (Ca12 Ge12 Sb8 O48) -Reduced Formula: Ca3Ge3(SbO6)2 -abc : 11.274877 11.274877 11.274877 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.625 0.875 0.75 0 - 3 Ca 0.875 0.625 0.25 0 - 4 Ca 0.625 0.25 0.875 0 - 5 Ca 0.875 0.75 0.625 0 - 6 Ca 0.75 0.125 0.375 0 - 7 Ca 0.25 0.375 0.125 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.125 0.375 0.75 0 - 10 Ca 0.375 0.75 0.125 0 - 11 Ca 0.125 0.25 0.375 0 - 12 Ge 0.125 0.75 0.875 0 - 13 Ge 0.875 0.25 0.125 0 - 14 Ge 0.625 0.375 0.25 0 - 15 Ge 0.75 0.875 0.125 0 - 16 Ge 0.875 0.125 0.75 0 - 17 Ge 0.25 0.625 0.375 0 - 18 Ge 0.75 0.375 0.625 0 - 19 Ge 0.25 0.125 0.875 0 - 20 Ge 0.125 0.875 0.25 0 - 21 Ge 0.375 0.625 0.75 0 - 22 Ge 0.625 0.75 0.375 0 - 23 Ge 0.375 0.25 0.625 0 - 24 Sb 0.5 0.5 0.5 0 - 25 Sb 0.5 0 0.5 0 - 26 Sb 0 0.5 0.5 0 - 27 Sb 0.5 0.5 0 0 - 28 Sb 0 0 0.5 0 - 29 Sb 0 0.5 0 0 - 30 Sb 0.5 0 0 0 - 31 Sb 0 0 0 0 - 32 O 0.407966 0.80299 0.780812 -0 - 33 O 0.872847 0.395025 0.092034 -0 - 34 O 0.104975 0.977822 0.69701 -0 - 35 O 0.522178 0.627153 0.719188 -0 - 36 O 0.69701 0.092034 0.719188 -0 - 37 O 0.627153 0.719188 0.522178 -0 - 38 O 0.627153 0.407966 0.104975 -0 - 39 O 0.719188 0.522178 0.627153 -0 - 40 O 0.80299 0.522178 0.395025 -0 - 41 O 0.977822 0.780812 0.872847 -0 - 42 O 0.780812 0.872847 0.977822 -0 - 43 O 0.719188 0.69701 0.092034 -0 - 44 O 0.407966 0.104975 0.627153 -0 - 45 O 0.395025 0.80299 0.522178 -0 - 46 O 0.092034 0.719188 0.69701 -0 - 47 O 0.104975 0.627153 0.407966 -0 - 48 O 0.522178 0.395025 0.80299 -0 - 49 O 0.092034 0.872847 0.395025 -0 - 50 O 0.977822 0.69701 0.104975 -0 - 51 O 0.19701 0.477822 0.604975 -0 - 52 O 0.69701 0.104975 0.977822 -0 - 53 O 0.780812 0.407966 0.80299 -0 - 54 O 0.395025 0.092034 0.872847 -0 - 55 O 0.872847 0.977822 0.780812 -0 - 56 O 0.592034 0.19701 0.219188 -0 - 57 O 0.127153 0.604975 0.907966 -0 - 58 O 0.895025 0.022178 0.30299 -0 - 59 O 0.477822 0.372847 0.280812 -0 - 60 O 0.30299 0.907966 0.280812 -0 - 61 O 0.372847 0.280812 0.477822 -0 - 62 O 0.372847 0.592034 0.895025 -0 - 63 O 0.280812 0.477822 0.372847 -0 - 64 O 0.127153 0.022178 0.219188 -0 - 65 O 0.604975 0.907966 0.127153 -0 - 66 O 0.219188 0.592034 0.19701 -0 - 67 O 0.19701 0.219188 0.592034 -0 - 68 O 0.30299 0.895025 0.022178 -0 - 69 O 0.022178 0.30299 0.895025 -0 - 70 O 0.907966 0.127153 0.604975 -0 - 71 O 0.477822 0.604975 0.19701 -0 - 72 O 0.895025 0.372847 0.592034 -0 - 73 O 0.907966 0.280812 0.30299 -0 - 74 O 0.604975 0.19701 0.477822 -0 - 75 O 0.592034 0.895025 0.372847 -0 - 76 O 0.280812 0.30299 0.907966 -0 - 77 O 0.219188 0.127153 0.022178 -0 - 78 O 0.022178 0.219188 0.127153 -0 - 79 O 0.80299 0.780812 0.407966 -0","# generated using pymatgen -data_Ca3Ge3(SbO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.27487653 -_cell_length_b 11.27487653 -_cell_length_c 11.27487653 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ge3(SbO6)2 -_chemical_formula_sum 'Ca12 Ge12 Sb8 O48' -_cell_volume 1103.35049275 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Sb Sb24 1 0.50000000 0.50000000 0.50000000 1 - Sb Sb25 1 0.50000000 0.00000000 0.50000000 1 - Sb Sb26 1 0.00000000 0.50000000 0.50000000 1 - Sb Sb27 1 0.50000000 0.50000000 0.00000000 1 - Sb Sb28 1 0.00000000 0.00000000 0.50000000 1 - Sb Sb29 1 0.00000000 0.50000000 0.00000000 1 - Sb Sb30 1 0.50000000 0.00000000 0.00000000 1 - Sb Sb31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.40796600 0.80299000 0.78081200 1 - O O33 1 0.87284700 0.39502500 0.09203400 1 - O O34 1 0.10497500 0.97782200 0.69701000 1 - O O35 1 0.52217800 0.62715300 0.71918800 1 - O O36 1 0.69701000 0.09203400 0.71918800 1 - O O37 1 0.62715300 0.71918800 0.52217800 1 - O O38 1 0.62715300 0.40796600 0.10497500 1 - O O39 1 0.71918800 0.52217800 0.62715300 1 - O O40 1 0.80299000 0.52217800 0.39502500 1 - O O41 1 0.97782200 0.78081200 0.87284700 1 - O O42 1 0.78081200 0.87284700 0.97782200 1 - O O43 1 0.71918800 0.69701000 0.09203400 1 - O O44 1 0.40796600 0.10497500 0.62715300 1 - O O45 1 0.39502500 0.80299000 0.52217800 1 - O O46 1 0.09203400 0.71918800 0.69701000 1 - O O47 1 0.10497500 0.62715300 0.40796600 1 - O O48 1 0.52217800 0.39502500 0.80299000 1 - O O49 1 0.09203400 0.87284700 0.39502500 1 - O O50 1 0.97782200 0.69701000 0.10497500 1 - O O51 1 0.19701000 0.47782200 0.60497500 1 - O O52 1 0.69701000 0.10497500 0.97782200 1 - O O53 1 0.78081200 0.40796600 0.80299000 1 - O O54 1 0.39502500 0.09203400 0.87284700 1 - O O55 1 0.87284700 0.97782200 0.78081200 1 - O O56 1 0.59203400 0.19701000 0.21918800 1 - O O57 1 0.12715300 0.60497500 0.90796600 1 - O O58 1 0.89502500 0.02217800 0.30299000 1 - O O59 1 0.47782200 0.37284700 0.28081200 1 - O O60 1 0.30299000 0.90796600 0.28081200 1 - O O61 1 0.37284700 0.28081200 0.47782200 1 - O O62 1 0.37284700 0.59203400 0.89502500 1 - O O63 1 0.28081200 0.47782200 0.37284700 1 - O O64 1 0.12715300 0.02217800 0.21918800 1 - O O65 1 0.60497500 0.90796600 0.12715300 1 - O O66 1 0.21918800 0.59203400 0.19701000 1 - O O67 1 0.19701000 0.21918800 0.59203400 1 - O O68 1 0.30299000 0.89502500 0.02217800 1 - O O69 1 0.02217800 0.30299000 0.89502500 1 - O O70 1 0.90796600 0.12715300 0.60497500 1 - O O71 1 0.47782200 0.60497500 0.19701000 1 - O O72 1 0.89502500 0.37284700 0.59203400 1 - O O73 1 0.90796600 0.28081200 0.30299000 1 - O O74 1 0.60497500 0.19701000 0.47782200 1 - O O75 1 0.59203400 0.89502500 0.37284700 1 - O O76 1 0.28081200 0.30299000 0.90796600 1 - O O77 1 0.21918800 0.12715300 0.02217800 1 - O O78 1 0.02217800 0.21918800 0.12715300 1 - O O79 1 0.80299000 0.78081200 0.40796600 1 -" -Y2Fe3(SiO4)3,mvc-4292,Ia-3d,[],0.15148347383332528,{'tags': []},"Full Formula (Y8 Fe12 Si12 O48) -Reduced Formula: Y2Fe3(SiO4)3 -abc : 10.692497 10.692497 10.692497 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0 -0.004 - 1 Y 0.5 0 0 -0.004 - 2 Y 0.5 0.5 0 -0.004 - 3 Y 0 0.5 0.5 -0.004 - 4 Y 0 0 0.5 -0.004 - 5 Y 0.5 0.5 0.5 -0.004 - 6 Y 0 0.5 0 -0.004 - 7 Y 0.5 0 0.5 -0.004 - 8 Fe 0.875 0.75 0.625 3.788 - 9 Fe 0.875 0.625 0.25 3.788 - 10 Fe 0.625 0.875 0.75 3.788 - 11 Fe 0.25 0.875 0.625 3.788 - 12 Fe 0.75 0.625 0.875 3.788 - 13 Fe 0.625 0.25 0.875 3.788 - 14 Fe 0.125 0.25 0.375 3.788 - 15 Fe 0.125 0.375 0.75 3.788 - 16 Fe 0.375 0.125 0.25 3.788 - 17 Fe 0.75 0.125 0.375 3.788 - 18 Fe 0.25 0.375 0.125 3.788 - 19 Fe 0.375 0.75 0.125 3.788 - 20 Si 0.125 0.75 0.875 0.005 - 21 Si 0.75 0.875 0.125 0.005 - 22 Si 0.25 0.625 0.375 0.005 - 23 Si 0.625 0.75 0.375 0.005 - 24 Si 0.875 0.125 0.75 0.005 - 25 Si 0.375 0.25 0.625 0.005 - 26 Si 0.375 0.625 0.75 0.005 - 27 Si 0.25 0.125 0.875 0.005 - 28 Si 0.625 0.375 0.25 0.005 - 29 Si 0.125 0.875 0.25 0.005 - 30 Si 0.75 0.375 0.625 0.005 - 31 Si 0.875 0.25 0.125 0.005 - 32 O 0.597675 0.892919 0.371839 0.029 - 33 O 0.371839 0.597675 0.892919 0.029 - 34 O 0.274165 0.295244 0.902325 0.029 - 35 O 0.47892 0.607081 0.204756 0.029 - 36 O 0.295244 0.892919 0.02108 0.029 - 37 O 0.128161 0.02108 0.225835 0.029 - 38 O 0.371839 0.274165 0.47892 0.029 - 39 O 0.892919 0.371839 0.597675 0.029 - 40 O 0.204756 0.225835 0.597675 0.029 - 41 O 0.47892 0.371839 0.274165 0.029 - 42 O 0.892919 0.02108 0.295244 0.029 - 43 O 0.607081 0.902325 0.128161 0.029 - 44 O 0.902325 0.128161 0.607081 0.029 - 45 O 0.274165 0.47892 0.371839 0.029 - 46 O 0.597675 0.204756 0.225835 0.029 - 47 O 0.225835 0.597675 0.204756 0.029 - 48 O 0.02108 0.295244 0.892919 0.029 - 49 O 0.902325 0.274165 0.295244 0.029 - 50 O 0.02108 0.225835 0.128161 0.029 - 51 O 0.795244 0.774165 0.402325 0.029 - 52 O 0.295244 0.902325 0.274165 0.029 - 53 O 0.607081 0.204756 0.47892 0.029 - 54 O 0.225835 0.128161 0.02108 0.029 - 55 O 0.128161 0.607081 0.902325 0.029 - 56 O 0.402325 0.107081 0.628161 0.029 - 57 O 0.628161 0.402325 0.107081 0.029 - 58 O 0.725835 0.704756 0.097675 0.029 - 59 O 0.52108 0.392919 0.795244 0.029 - 60 O 0.704756 0.107081 0.97892 0.029 - 61 O 0.871839 0.97892 0.774165 0.029 - 62 O 0.628161 0.725835 0.52108 0.029 - 63 O 0.107081 0.628161 0.402325 0.029 - 64 O 0.871839 0.392919 0.097675 0.029 - 65 O 0.774165 0.871839 0.97892 0.029 - 66 O 0.392919 0.795244 0.52108 0.029 - 67 O 0.704756 0.097675 0.725835 0.029 - 68 O 0.795244 0.52108 0.392919 0.029 - 69 O 0.97892 0.774165 0.871839 0.029 - 70 O 0.097675 0.725835 0.704756 0.029 - 71 O 0.97892 0.704756 0.107081 0.029 - 72 O 0.774165 0.402325 0.795244 0.029 - 73 O 0.402325 0.795244 0.774165 0.029 - 74 O 0.725835 0.52108 0.628161 0.029 - 75 O 0.097675 0.871839 0.392919 0.029 - 76 O 0.392919 0.097675 0.871839 0.029 - 77 O 0.107081 0.97892 0.704756 0.029 - 78 O 0.52108 0.628161 0.725835 0.029 - 79 O 0.204756 0.47892 0.607081 0.029","# generated using pymatgen -data_Y2Fe3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.69249696 -_cell_length_b 10.69249696 -_cell_length_c 10.69249696 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Fe3(SiO4)3 -_chemical_formula_sum 'Y8 Fe12 Si12 O48' -_cell_volume 941.05610395 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.00000000 1 - Y Y1 1 0.50000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.50000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.50000000 1 - Y Y4 1 0.00000000 0.00000000 0.50000000 1 - Y Y5 1 0.50000000 0.50000000 0.50000000 1 - Y Y6 1 0.00000000 0.50000000 0.00000000 1 - Y Y7 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe8 1 0.87500000 0.75000000 0.62500000 1 - Fe Fe9 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe10 1 0.62500000 0.87500000 0.75000000 1 - Fe Fe11 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe12 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe13 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe14 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe15 1 0.12500000 0.37500000 0.75000000 1 - Fe Fe16 1 0.37500000 0.12500000 0.25000000 1 - Fe Fe17 1 0.75000000 0.12500000 0.37500000 1 - Fe Fe18 1 0.25000000 0.37500000 0.12500000 1 - Fe Fe19 1 0.37500000 0.75000000 0.12500000 1 - Si Si20 1 0.12500000 0.75000000 0.87500000 1 - Si Si21 1 0.75000000 0.87500000 0.12500000 1 - Si Si22 1 0.25000000 0.62500000 0.37500000 1 - Si Si23 1 0.62500000 0.75000000 0.37500000 1 - Si Si24 1 0.87500000 0.12500000 0.75000000 1 - Si Si25 1 0.37500000 0.25000000 0.62500000 1 - Si Si26 1 0.37500000 0.62500000 0.75000000 1 - Si Si27 1 0.25000000 0.12500000 0.87500000 1 - Si Si28 1 0.62500000 0.37500000 0.25000000 1 - Si Si29 1 0.12500000 0.87500000 0.25000000 1 - Si Si30 1 0.75000000 0.37500000 0.62500000 1 - Si Si31 1 0.87500000 0.25000000 0.12500000 1 - O O32 1 0.59767500 0.89291900 0.37183900 1 - O O33 1 0.37183900 0.59767500 0.89291900 1 - O O34 1 0.27416500 0.29524400 0.90232500 1 - O O35 1 0.47892000 0.60708100 0.20475600 1 - O O36 1 0.29524400 0.89291900 0.02108000 1 - O O37 1 0.12816100 0.02108000 0.22583500 1 - O O38 1 0.37183900 0.27416500 0.47892000 1 - O O39 1 0.89291900 0.37183900 0.59767500 1 - O O40 1 0.20475600 0.22583500 0.59767500 1 - O O41 1 0.47892000 0.37183900 0.27416500 1 - O O42 1 0.89291900 0.02108000 0.29524400 1 - O O43 1 0.60708100 0.90232500 0.12816100 1 - O O44 1 0.90232500 0.12816100 0.60708100 1 - O O45 1 0.27416500 0.47892000 0.37183900 1 - O O46 1 0.59767500 0.20475600 0.22583500 1 - O O47 1 0.22583500 0.59767500 0.20475600 1 - O O48 1 0.02108000 0.29524400 0.89291900 1 - O O49 1 0.90232500 0.27416500 0.29524400 1 - O O50 1 0.02108000 0.22583500 0.12816100 1 - O O51 1 0.79524400 0.77416500 0.40232500 1 - O O52 1 0.29524400 0.90232500 0.27416500 1 - O O53 1 0.60708100 0.20475600 0.47892000 1 - O O54 1 0.22583500 0.12816100 0.02108000 1 - O O55 1 0.12816100 0.60708100 0.90232500 1 - O O56 1 0.40232500 0.10708100 0.62816100 1 - O O57 1 0.62816100 0.40232500 0.10708100 1 - O O58 1 0.72583500 0.70475600 0.09767500 1 - O O59 1 0.52108000 0.39291900 0.79524400 1 - O O60 1 0.70475600 0.10708100 0.97892000 1 - O O61 1 0.87183900 0.97892000 0.77416500 1 - O O62 1 0.62816100 0.72583500 0.52108000 1 - O O63 1 0.10708100 0.62816100 0.40232500 1 - O O64 1 0.87183900 0.39291900 0.09767500 1 - O O65 1 0.77416500 0.87183900 0.97892000 1 - O O66 1 0.39291900 0.79524400 0.52108000 1 - O O67 1 0.70475600 0.09767500 0.72583500 1 - O O68 1 0.79524400 0.52108000 0.39291900 1 - O O69 1 0.97892000 0.77416500 0.87183900 1 - O O70 1 0.09767500 0.72583500 0.70475600 1 - O O71 1 0.97892000 0.70475600 0.10708100 1 - O O72 1 0.77416500 0.40232500 0.79524400 1 - O O73 1 0.40232500 0.79524400 0.77416500 1 - O O74 1 0.72583500 0.52108000 0.62816100 1 - O O75 1 0.09767500 0.87183900 0.39291900 1 - O O76 1 0.39291900 0.09767500 0.87183900 1 - O O77 1 0.10708100 0.97892000 0.70475600 1 - O O78 1 0.52108000 0.62816100 0.72583500 1 - O O79 1 0.20475600 0.47892000 0.60708100 1 -" -Y2Si3(NiO4)3,mvc-4333,Ia-3d,[],0.26693272529166556,{'tags': []},"Full Formula (Y8 Si12 Ni12 O48) -Reduced Formula: Y2Si3(NiO4)3 -abc : 10.639789 10.639789 10.639789 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0 0 0 -0.001 - 1 Y 0.5 0 0 -0.001 - 2 Y 0.5 0.5 0 -0.001 - 3 Y 0 0.5 0.5 -0.001 - 4 Y 0 0 0.5 -0.001 - 5 Y 0.5 0.5 0.5 -0.001 - 6 Y 0 0.5 0 -0.001 - 7 Y 0.5 0 0.5 -0.001 - 8 Si 0.125 0.75 0.875 0 - 9 Si 0.75 0.875 0.125 0 - 10 Si 0.25 0.625 0.375 0 - 11 Si 0.625 0.75 0.375 0 - 12 Si 0.875 0.125 0.75 0 - 13 Si 0.375 0.25 0.625 0 - 14 Si 0.375 0.625 0.75 0 - 15 Si 0.25 0.125 0.875 0 - 16 Si 0.625 0.375 0.25 0 - 17 Si 0.125 0.875 0.25 0 - 18 Si 0.75 0.375 0.625 0 - 19 Si 0.875 0.25 0.125 0 - 20 Ni 0.875 0.75 0.625 1.827 - 21 Ni 0.875 0.625 0.25 1.827 - 22 Ni 0.625 0.875 0.75 1.827 - 23 Ni 0.25 0.875 0.625 1.828 - 24 Ni 0.75 0.625 0.875 1.826 - 25 Ni 0.625 0.25 0.875 1.827 - 26 Ni 0.125 0.25 0.375 1.827 - 27 Ni 0.125 0.375 0.75 1.827 - 28 Ni 0.375 0.125 0.25 1.827 - 29 Ni 0.75 0.125 0.375 1.828 - 30 Ni 0.25 0.375 0.125 1.826 - 31 Ni 0.375 0.75 0.125 1.827 - 32 O 0.59515 0.892094 0.369291 0.032 - 33 O 0.369291 0.59515 0.892094 0.032 - 34 O 0.27414 0.296944 0.90485 0.032 - 35 O 0.477196 0.607906 0.203056 0.032 - 36 O 0.296944 0.892094 0.022804 0.032 - 37 O 0.130709 0.022804 0.22586 0.032 - 38 O 0.369291 0.27414 0.477196 0.032 - 39 O 0.892094 0.369291 0.59515 0.032 - 40 O 0.203056 0.22586 0.59515 0.032 - 41 O 0.477196 0.369291 0.27414 0.032 - 42 O 0.892094 0.022804 0.296944 0.032 - 43 O 0.607906 0.90485 0.130709 0.032 - 44 O 0.90485 0.130709 0.607906 0.032 - 45 O 0.27414 0.477196 0.369291 0.032 - 46 O 0.59515 0.203056 0.22586 0.032 - 47 O 0.22586 0.59515 0.203056 0.032 - 48 O 0.022804 0.296944 0.892094 0.032 - 49 O 0.90485 0.27414 0.296944 0.032 - 50 O 0.022804 0.22586 0.130709 0.032 - 51 O 0.796944 0.77414 0.40485 0.032 - 52 O 0.296944 0.90485 0.27414 0.032 - 53 O 0.607906 0.203056 0.477196 0.032 - 54 O 0.22586 0.130709 0.022804 0.032 - 55 O 0.130709 0.607906 0.90485 0.032 - 56 O 0.40485 0.107906 0.630709 0.032 - 57 O 0.630709 0.40485 0.107906 0.032 - 58 O 0.72586 0.703056 0.09515 0.032 - 59 O 0.522804 0.392094 0.796944 0.032 - 60 O 0.703056 0.107906 0.977196 0.032 - 61 O 0.869291 0.977196 0.77414 0.032 - 62 O 0.630709 0.72586 0.522804 0.032 - 63 O 0.107906 0.630709 0.40485 0.032 - 64 O 0.869291 0.392094 0.09515 0.032 - 65 O 0.77414 0.869291 0.977196 0.032 - 66 O 0.392094 0.796944 0.522804 0.032 - 67 O 0.703056 0.09515 0.72586 0.032 - 68 O 0.796944 0.522804 0.392094 0.032 - 69 O 0.977196 0.77414 0.869291 0.032 - 70 O 0.09515 0.72586 0.703056 0.032 - 71 O 0.977196 0.703056 0.107906 0.032 - 72 O 0.77414 0.40485 0.796944 0.032 - 73 O 0.40485 0.796944 0.77414 0.032 - 74 O 0.72586 0.522804 0.630709 0.032 - 75 O 0.09515 0.869291 0.392094 0.032 - 76 O 0.392094 0.09515 0.869291 0.032 - 77 O 0.107906 0.977196 0.703056 0.032 - 78 O 0.522804 0.630709 0.72586 0.032 - 79 O 0.203056 0.477196 0.607906 0.032","# generated using pymatgen -data_Y2Si3(NiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.63978893 -_cell_length_b 10.63978893 -_cell_length_c 10.63978893 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y2Si3(NiO4)3 -_chemical_formula_sum 'Y8 Si12 Ni12 O48' -_cell_volume 927.20794950 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.00000000 0.00000000 0.00000000 1 - Y Y1 1 0.50000000 0.00000000 0.00000000 1 - Y Y2 1 0.50000000 0.50000000 0.00000000 1 - Y Y3 1 0.00000000 0.50000000 0.50000000 1 - Y Y4 1 0.00000000 0.00000000 0.50000000 1 - Y Y5 1 0.50000000 0.50000000 0.50000000 1 - Y Y6 1 0.00000000 0.50000000 0.00000000 1 - Y Y7 1 0.50000000 0.00000000 0.50000000 1 - Si Si8 1 0.12500000 0.75000000 0.87500000 1 - Si Si9 1 0.75000000 0.87500000 0.12500000 1 - Si Si10 1 0.25000000 0.62500000 0.37500000 1 - Si Si11 1 0.62500000 0.75000000 0.37500000 1 - Si Si12 1 0.87500000 0.12500000 0.75000000 1 - Si Si13 1 0.37500000 0.25000000 0.62500000 1 - Si Si14 1 0.37500000 0.62500000 0.75000000 1 - Si Si15 1 0.25000000 0.12500000 0.87500000 1 - Si Si16 1 0.62500000 0.37500000 0.25000000 1 - Si Si17 1 0.12500000 0.87500000 0.25000000 1 - Si Si18 1 0.75000000 0.37500000 0.62500000 1 - Si Si19 1 0.87500000 0.25000000 0.12500000 1 - Ni Ni20 1 0.87500000 0.75000000 0.62500000 1 - Ni Ni21 1 0.87500000 0.62500000 0.25000000 1 - Ni Ni22 1 0.62500000 0.87500000 0.75000000 1 - Ni Ni23 1 0.25000000 0.87500000 0.62500000 1 - Ni Ni24 1 0.75000000 0.62500000 0.87500000 1 - Ni Ni25 1 0.62500000 0.25000000 0.87500000 1 - Ni Ni26 1 0.12500000 0.25000000 0.37500000 1 - Ni Ni27 1 0.12500000 0.37500000 0.75000000 1 - Ni Ni28 1 0.37500000 0.12500000 0.25000000 1 - Ni Ni29 1 0.75000000 0.12500000 0.37500000 1 - Ni Ni30 1 0.25000000 0.37500000 0.12500000 1 - Ni Ni31 1 0.37500000 0.75000000 0.12500000 1 - O O32 1 0.59515000 0.89209400 0.36929100 1 - O O33 1 0.36929100 0.59515000 0.89209400 1 - O O34 1 0.27414000 0.29694400 0.90485000 1 - O O35 1 0.47719600 0.60790600 0.20305600 1 - O O36 1 0.29694400 0.89209400 0.02280400 1 - O O37 1 0.13070900 0.02280400 0.22586000 1 - O O38 1 0.36929100 0.27414000 0.47719600 1 - O O39 1 0.89209400 0.36929100 0.59515000 1 - O O40 1 0.20305600 0.22586000 0.59515000 1 - O O41 1 0.47719600 0.36929100 0.27414000 1 - O O42 1 0.89209400 0.02280400 0.29694400 1 - O O43 1 0.60790600 0.90485000 0.13070900 1 - O O44 1 0.90485000 0.13070900 0.60790600 1 - O O45 1 0.27414000 0.47719600 0.36929100 1 - O O46 1 0.59515000 0.20305600 0.22586000 1 - O O47 1 0.22586000 0.59515000 0.20305600 1 - O O48 1 0.02280400 0.29694400 0.89209400 1 - O O49 1 0.90485000 0.27414000 0.29694400 1 - O O50 1 0.02280400 0.22586000 0.13070900 1 - O O51 1 0.79694400 0.77414000 0.40485000 1 - O O52 1 0.29694400 0.90485000 0.27414000 1 - O O53 1 0.60790600 0.20305600 0.47719600 1 - O O54 1 0.22586000 0.13070900 0.02280400 1 - O O55 1 0.13070900 0.60790600 0.90485000 1 - O O56 1 0.40485000 0.10790600 0.63070900 1 - O O57 1 0.63070900 0.40485000 0.10790600 1 - O O58 1 0.72586000 0.70305600 0.09515000 1 - O O59 1 0.52280400 0.39209400 0.79694400 1 - O O60 1 0.70305600 0.10790600 0.97719600 1 - O O61 1 0.86929100 0.97719600 0.77414000 1 - O O62 1 0.63070900 0.72586000 0.52280400 1 - O O63 1 0.10790600 0.63070900 0.40485000 1 - O O64 1 0.86929100 0.39209400 0.09515000 1 - O O65 1 0.77414000 0.86929100 0.97719600 1 - O O66 1 0.39209400 0.79694400 0.52280400 1 - O O67 1 0.70305600 0.09515000 0.72586000 1 - O O68 1 0.79694400 0.52280400 0.39209400 1 - O O69 1 0.97719600 0.77414000 0.86929100 1 - O O70 1 0.09515000 0.72586000 0.70305600 1 - O O71 1 0.97719600 0.70305600 0.10790600 1 - O O72 1 0.77414000 0.40485000 0.79694400 1 - O O73 1 0.40485000 0.79694400 0.77414000 1 - O O74 1 0.72586000 0.52280400 0.63070900 1 - O O75 1 0.09515000 0.86929100 0.39209400 1 - O O76 1 0.39209400 0.09515000 0.86929100 1 - O O77 1 0.10790600 0.97719600 0.70305600 1 - O O78 1 0.52280400 0.63070900 0.72586000 1 - O O79 1 0.20305600 0.47719600 0.60790600 1 -" -Al2Cr3(SiO4)3,mvc-4351,Ia-3d,[],0.07049527750000273,{'tags': []},"Full Formula (Al8 Cr12 Si12 O48) -Reduced Formula: Al2Cr3(SiO4)3 -abc : 10.177511 10.177511 10.177511 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0.5 0.002 - 1 Al 0 0 0 0.002 - 2 Al 0.5 0 0 0.002 - 3 Al 0 0.5 0 0.002 - 4 Al 0.5 0.5 0 0.002 - 5 Al 0 0.5 0.5 0.002 - 6 Al 0.5 0 0.5 0.002 - 7 Al 0.5 0.5 0.5 0.002 - 8 Cr 0.875 0.625 0.25 3.813 - 9 Cr 0.625 0.25 0.875 3.813 - 10 Cr 0.875 0.75 0.625 3.813 - 11 Cr 0.75 0.625 0.875 3.813 - 12 Cr 0.25 0.875 0.625 3.813 - 13 Cr 0.625 0.875 0.75 3.813 - 14 Cr 0.125 0.375 0.75 3.813 - 15 Cr 0.375 0.75 0.125 3.813 - 16 Cr 0.125 0.25 0.375 3.813 - 17 Cr 0.25 0.375 0.125 3.813 - 18 Cr 0.75 0.125 0.375 3.813 - 19 Cr 0.375 0.125 0.25 3.813 - 20 Si 0.125 0.875 0.25 0.008 - 21 Si 0.25 0.125 0.875 0.008 - 22 Si 0.75 0.375 0.625 0.008 - 23 Si 0.625 0.375 0.25 0.008 - 24 Si 0.625 0.75 0.375 0.008 - 25 Si 0.375 0.625 0.75 0.008 - 26 Si 0.125 0.75 0.875 0.008 - 27 Si 0.75 0.875 0.125 0.008 - 28 Si 0.875 0.25 0.125 0.008 - 29 Si 0.375 0.25 0.625 0.008 - 30 Si 0.25 0.625 0.375 0.008 - 31 Si 0.875 0.125 0.75 0.008 - 32 O 0.488228 0.379208 0.302355 0.005 - 33 O 0.314126 0.89098 0.011772 0.005 - 34 O 0.60902 0.923147 0.120792 0.005 - 35 O 0.576853 0.185874 0.197645 0.005 - 36 O 0.120792 0.011772 0.197645 0.005 - 37 O 0.185874 0.197645 0.576853 0.005 - 38 O 0.185874 0.488228 0.60902 0.005 - 39 O 0.197645 0.576853 0.185874 0.005 - 40 O 0.379208 0.576853 0.89098 0.005 - 41 O 0.923147 0.302355 0.314126 0.005 - 42 O 0.302355 0.314126 0.923147 0.005 - 43 O 0.197645 0.120792 0.011772 0.005 - 44 O 0.488228 0.60902 0.185874 0.005 - 45 O 0.89098 0.379208 0.576853 0.005 - 46 O 0.011772 0.197645 0.120792 0.005 - 47 O 0.60902 0.185874 0.488228 0.005 - 48 O 0.576853 0.89098 0.379208 0.005 - 49 O 0.011772 0.314126 0.89098 0.005 - 50 O 0.923147 0.120792 0.60902 0.005 - 51 O 0.620792 0.423147 0.10902 0.005 - 52 O 0.379208 0.302355 0.488228 0.005 - 53 O 0.302355 0.488228 0.379208 0.005 - 54 O 0.89098 0.011772 0.314126 0.005 - 55 O 0.314126 0.923147 0.302355 0.005 - 56 O 0.511772 0.620792 0.697645 0.005 - 57 O 0.685874 0.10902 0.988228 0.005 - 58 O 0.39098 0.076853 0.879208 0.005 - 59 O 0.423147 0.814126 0.802355 0.005 - 60 O 0.879208 0.988228 0.802355 0.005 - 61 O 0.814126 0.802355 0.423147 0.005 - 62 O 0.814126 0.511772 0.39098 0.005 - 63 O 0.802355 0.423147 0.814126 0.005 - 64 O 0.685874 0.076853 0.697645 0.005 - 65 O 0.10902 0.988228 0.685874 0.005 - 66 O 0.697645 0.511772 0.620792 0.005 - 67 O 0.620792 0.697645 0.511772 0.005 - 68 O 0.879208 0.39098 0.076853 0.005 - 69 O 0.076853 0.879208 0.39098 0.005 - 70 O 0.988228 0.685874 0.10902 0.005 - 71 O 0.423147 0.10902 0.620792 0.005 - 72 O 0.39098 0.814126 0.511772 0.005 - 73 O 0.988228 0.802355 0.879208 0.005 - 74 O 0.10902 0.620792 0.423147 0.005 - 75 O 0.511772 0.39098 0.814126 0.005 - 76 O 0.802355 0.879208 0.988228 0.005 - 77 O 0.697645 0.685874 0.076853 0.005 - 78 O 0.076853 0.697645 0.685874 0.005 - 79 O 0.120792 0.60902 0.923147 0.005","# generated using pymatgen -data_Al2Cr3(SiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.17751149 -_cell_length_b 10.17751149 -_cell_length_c 10.17751149 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Cr3(SiO4)3 -_chemical_formula_sum 'Al8 Cr12 Si12 O48' -_cell_volume 811.52688790 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.50000000 1 - Al Al1 1 0.00000000 0.00000000 0.00000000 1 - Al Al2 1 0.50000000 0.00000000 0.00000000 1 - Al Al3 1 0.00000000 0.50000000 0.00000000 1 - Al Al4 1 0.50000000 0.50000000 0.00000000 1 - Al Al5 1 0.00000000 0.50000000 0.50000000 1 - Al Al6 1 0.50000000 0.00000000 0.50000000 1 - Al Al7 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr8 1 0.87500000 0.62500000 0.25000000 1 - Cr Cr9 1 0.62500000 0.25000000 0.87500000 1 - Cr Cr10 1 0.87500000 0.75000000 0.62500000 1 - Cr Cr11 1 0.75000000 0.62500000 0.87500000 1 - Cr Cr12 1 0.25000000 0.87500000 0.62500000 1 - Cr Cr13 1 0.62500000 0.87500000 0.75000000 1 - Cr Cr14 1 0.12500000 0.37500000 0.75000000 1 - Cr Cr15 1 0.37500000 0.75000000 0.12500000 1 - Cr Cr16 1 0.12500000 0.25000000 0.37500000 1 - Cr Cr17 1 0.25000000 0.37500000 0.12500000 1 - Cr Cr18 1 0.75000000 0.12500000 0.37500000 1 - Cr Cr19 1 0.37500000 0.12500000 0.25000000 1 - Si Si20 1 0.12500000 0.87500000 0.25000000 1 - Si Si21 1 0.25000000 0.12500000 0.87500000 1 - Si Si22 1 0.75000000 0.37500000 0.62500000 1 - Si Si23 1 0.62500000 0.37500000 0.25000000 1 - Si Si24 1 0.62500000 0.75000000 0.37500000 1 - Si Si25 1 0.37500000 0.62500000 0.75000000 1 - Si Si26 1 0.12500000 0.75000000 0.87500000 1 - Si Si27 1 0.75000000 0.87500000 0.12500000 1 - Si Si28 1 0.87500000 0.25000000 0.12500000 1 - Si Si29 1 0.37500000 0.25000000 0.62500000 1 - Si Si30 1 0.25000000 0.62500000 0.37500000 1 - Si Si31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.48822800 0.37920800 0.30235500 1 - O O33 1 0.31412600 0.89098000 0.01177200 1 - O O34 1 0.60902000 0.92314700 0.12079200 1 - O O35 1 0.57685300 0.18587400 0.19764500 1 - O O36 1 0.12079200 0.01177200 0.19764500 1 - O O37 1 0.18587400 0.19764500 0.57685300 1 - O O38 1 0.18587400 0.48822800 0.60902000 1 - O O39 1 0.19764500 0.57685300 0.18587400 1 - O O40 1 0.37920800 0.57685300 0.89098000 1 - O O41 1 0.92314700 0.30235500 0.31412600 1 - O O42 1 0.30235500 0.31412600 0.92314700 1 - O O43 1 0.19764500 0.12079200 0.01177200 1 - O O44 1 0.48822800 0.60902000 0.18587400 1 - O O45 1 0.89098000 0.37920800 0.57685300 1 - O O46 1 0.01177200 0.19764500 0.12079200 1 - O O47 1 0.60902000 0.18587400 0.48822800 1 - O O48 1 0.57685300 0.89098000 0.37920800 1 - O O49 1 0.01177200 0.31412600 0.89098000 1 - O O50 1 0.92314700 0.12079200 0.60902000 1 - O O51 1 0.62079200 0.42314700 0.10902000 1 - O O52 1 0.37920800 0.30235500 0.48822800 1 - O O53 1 0.30235500 0.48822800 0.37920800 1 - O O54 1 0.89098000 0.01177200 0.31412600 1 - O O55 1 0.31412600 0.92314700 0.30235500 1 - O O56 1 0.51177200 0.62079200 0.69764500 1 - O O57 1 0.68587400 0.10902000 0.98822800 1 - O O58 1 0.39098000 0.07685300 0.87920800 1 - O O59 1 0.42314700 0.81412600 0.80235500 1 - O O60 1 0.87920800 0.98822800 0.80235500 1 - O O61 1 0.81412600 0.80235500 0.42314700 1 - O O62 1 0.81412600 0.51177200 0.39098000 1 - O O63 1 0.80235500 0.42314700 0.81412600 1 - O O64 1 0.68587400 0.07685300 0.69764500 1 - O O65 1 0.10902000 0.98822800 0.68587400 1 - O O66 1 0.69764500 0.51177200 0.62079200 1 - O O67 1 0.62079200 0.69764500 0.51177200 1 - O O68 1 0.87920800 0.39098000 0.07685300 1 - O O69 1 0.07685300 0.87920800 0.39098000 1 - O O70 1 0.98822800 0.68587400 0.10902000 1 - O O71 1 0.42314700 0.10902000 0.62079200 1 - O O72 1 0.39098000 0.81412600 0.51177200 1 - O O73 1 0.98822800 0.80235500 0.87920800 1 - O O74 1 0.10902000 0.62079200 0.42314700 1 - O O75 1 0.51177200 0.39098000 0.81412600 1 - O O76 1 0.80235500 0.87920800 0.98822800 1 - O O77 1 0.69764500 0.68587400 0.07685300 1 - O O78 1 0.07685300 0.69764500 0.68587400 1 - O O79 1 0.12079200 0.60902000 0.92314700 1 -" -Al2Si3(WO4)3,mvc-4363,Ia-3d,[],0.7101190233750003,{'tags': []},"Full Formula (Al8 Si12 W12 O48) -Reduced Formula: Al2Si3(WO4)3 -abc : 10.198914 10.198914 10.198914 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Al 0 0 0 0.008 - 1 Al 0.5 0 0 0.008 - 2 Al 0.5 0.5 0 0.008 - 3 Al 0 0.5 0.5 0.008 - 4 Al 0 0 0.5 0.008 - 5 Al 0.5 0.5 0.5 0.008 - 6 Al 0 0.5 0 0.008 - 7 Al 0.5 0 0.5 0.008 - 8 Si 0.125 0.75 0.875 0.027 - 9 Si 0.75 0.875 0.125 0.027 - 10 Si 0.25 0.625 0.375 0.027 - 11 Si 0.625 0.75 0.375 0.027 - 12 Si 0.875 0.125 0.75 0.027 - 13 Si 0.375 0.25 0.625 0.027 - 14 Si 0.375 0.625 0.75 0.027 - 15 Si 0.25 0.125 0.875 0.027 - 16 Si 0.625 0.375 0.25 0.027 - 17 Si 0.125 0.875 0.25 0.027 - 18 Si 0.75 0.375 0.625 0.027 - 19 Si 0.875 0.25 0.125 0.027 - 20 W 0.875 0.75 0.625 3.505 - 21 W 0.875 0.625 0.25 3.505 - 22 W 0.625 0.875 0.75 3.505 - 23 W 0.25 0.875 0.625 3.505 - 24 W 0.75 0.625 0.875 3.505 - 25 W 0.625 0.25 0.875 3.505 - 26 W 0.125 0.25 0.375 3.505 - 27 W 0.125 0.375 0.75 3.505 - 28 W 0.375 0.125 0.25 3.505 - 29 W 0.75 0.125 0.375 3.505 - 30 W 0.25 0.375 0.125 3.505 - 31 W 0.375 0.75 0.125 3.505 - 32 O 0.592353 0.902807 0.389271 0.038 - 33 O 0.389271 0.592353 0.902807 0.038 - 34 O 0.296918 0.310454 0.907647 0.038 - 35 O 0.486464 0.597193 0.189546 0.038 - 36 O 0.310454 0.902807 0.013536 0.038 - 37 O 0.110729 0.013536 0.203082 0.038 - 38 O 0.389271 0.296918 0.486464 0.038 - 39 O 0.902807 0.389271 0.592353 0.038 - 40 O 0.189546 0.203082 0.592353 0.038 - 41 O 0.486464 0.389271 0.296918 0.038 - 42 O 0.902807 0.013536 0.310454 0.038 - 43 O 0.597193 0.907647 0.110729 0.038 - 44 O 0.907647 0.110729 0.597193 0.038 - 45 O 0.296918 0.486464 0.389271 0.038 - 46 O 0.592353 0.189546 0.203082 0.038 - 47 O 0.203082 0.592353 0.189546 0.038 - 48 O 0.013536 0.310454 0.902807 0.038 - 49 O 0.907647 0.296918 0.310454 0.038 - 50 O 0.013536 0.203082 0.110729 0.038 - 51 O 0.810454 0.796918 0.407647 0.038 - 52 O 0.310454 0.907647 0.296918 0.038 - 53 O 0.597193 0.189546 0.486464 0.038 - 54 O 0.203082 0.110729 0.013536 0.038 - 55 O 0.110729 0.597193 0.907647 0.038 - 56 O 0.407647 0.097193 0.610729 0.038 - 57 O 0.610729 0.407647 0.097193 0.038 - 58 O 0.703082 0.689546 0.092353 0.038 - 59 O 0.513536 0.402807 0.810454 0.038 - 60 O 0.689546 0.097193 0.986464 0.038 - 61 O 0.889271 0.986464 0.796918 0.038 - 62 O 0.610729 0.703082 0.513536 0.038 - 63 O 0.097193 0.610729 0.407647 0.038 - 64 O 0.889271 0.402807 0.092353 0.038 - 65 O 0.796918 0.889271 0.986464 0.038 - 66 O 0.402807 0.810454 0.513536 0.038 - 67 O 0.689546 0.092353 0.703082 0.038 - 68 O 0.810454 0.513536 0.402807 0.038 - 69 O 0.986464 0.796918 0.889271 0.038 - 70 O 0.092353 0.703082 0.689546 0.038 - 71 O 0.986464 0.689546 0.097193 0.038 - 72 O 0.796918 0.407647 0.810454 0.038 - 73 O 0.407647 0.810454 0.796918 0.038 - 74 O 0.703082 0.513536 0.610729 0.038 - 75 O 0.092353 0.889271 0.402807 0.038 - 76 O 0.402807 0.092353 0.889271 0.038 - 77 O 0.097193 0.986464 0.689546 0.038 - 78 O 0.513536 0.610729 0.703082 0.038 - 79 O 0.189546 0.486464 0.597193 0.038","# generated using pymatgen -data_Al2Si3(WO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.19891444 -_cell_length_b 10.19891444 -_cell_length_c 10.19891444 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Al2Si3(WO4)3 -_chemical_formula_sum 'Al8 Si12 W12 O48' -_cell_volume 816.65750054 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Al Al0 1 0.00000000 0.00000000 0.00000000 1 - Al Al1 1 0.50000000 0.00000000 0.00000000 1 - Al Al2 1 0.50000000 0.50000000 0.00000000 1 - Al Al3 1 0.00000000 0.50000000 0.50000000 1 - Al Al4 1 0.00000000 0.00000000 0.50000000 1 - Al Al5 1 0.50000000 0.50000000 0.50000000 1 - Al Al6 1 0.00000000 0.50000000 0.00000000 1 - Al Al7 1 0.50000000 0.00000000 0.50000000 1 - Si Si8 1 0.12500000 0.75000000 0.87500000 1 - Si Si9 1 0.75000000 0.87500000 0.12500000 1 - Si Si10 1 0.25000000 0.62500000 0.37500000 1 - Si Si11 1 0.62500000 0.75000000 0.37500000 1 - Si Si12 1 0.87500000 0.12500000 0.75000000 1 - Si Si13 1 0.37500000 0.25000000 0.62500000 1 - Si Si14 1 0.37500000 0.62500000 0.75000000 1 - Si Si15 1 0.25000000 0.12500000 0.87500000 1 - Si Si16 1 0.62500000 0.37500000 0.25000000 1 - Si Si17 1 0.12500000 0.87500000 0.25000000 1 - Si Si18 1 0.75000000 0.37500000 0.62500000 1 - Si Si19 1 0.87500000 0.25000000 0.12500000 1 - W W20 1 0.87500000 0.75000000 0.62500000 1 - W W21 1 0.87500000 0.62500000 0.25000000 1 - W W22 1 0.62500000 0.87500000 0.75000000 1 - W W23 1 0.25000000 0.87500000 0.62500000 1 - W W24 1 0.75000000 0.62500000 0.87500000 1 - W W25 1 0.62500000 0.25000000 0.87500000 1 - W W26 1 0.12500000 0.25000000 0.37500000 1 - W W27 1 0.12500000 0.37500000 0.75000000 1 - W W28 1 0.37500000 0.12500000 0.25000000 1 - W W29 1 0.75000000 0.12500000 0.37500000 1 - W W30 1 0.25000000 0.37500000 0.12500000 1 - W W31 1 0.37500000 0.75000000 0.12500000 1 - O O32 1 0.59235300 0.90280700 0.38927100 1 - O O33 1 0.38927100 0.59235300 0.90280700 1 - O O34 1 0.29691800 0.31045400 0.90764700 1 - O O35 1 0.48646400 0.59719300 0.18954600 1 - O O36 1 0.31045400 0.90280700 0.01353600 1 - O O37 1 0.11072900 0.01353600 0.20308200 1 - O O38 1 0.38927100 0.29691800 0.48646400 1 - O O39 1 0.90280700 0.38927100 0.59235300 1 - O O40 1 0.18954600 0.20308200 0.59235300 1 - O O41 1 0.48646400 0.38927100 0.29691800 1 - O O42 1 0.90280700 0.01353600 0.31045400 1 - O O43 1 0.59719300 0.90764700 0.11072900 1 - O O44 1 0.90764700 0.11072900 0.59719300 1 - O O45 1 0.29691800 0.48646400 0.38927100 1 - O O46 1 0.59235300 0.18954600 0.20308200 1 - O O47 1 0.20308200 0.59235300 0.18954600 1 - O O48 1 0.01353600 0.31045400 0.90280700 1 - O O49 1 0.90764700 0.29691800 0.31045400 1 - O O50 1 0.01353600 0.20308200 0.11072900 1 - O O51 1 0.81045400 0.79691800 0.40764700 1 - O O52 1 0.31045400 0.90764700 0.29691800 1 - O O53 1 0.59719300 0.18954600 0.48646400 1 - O O54 1 0.20308200 0.11072900 0.01353600 1 - O O55 1 0.11072900 0.59719300 0.90764700 1 - O O56 1 0.40764700 0.09719300 0.61072900 1 - O O57 1 0.61072900 0.40764700 0.09719300 1 - O O58 1 0.70308200 0.68954600 0.09235300 1 - O O59 1 0.51353600 0.40280700 0.81045400 1 - O O60 1 0.68954600 0.09719300 0.98646400 1 - O O61 1 0.88927100 0.98646400 0.79691800 1 - O O62 1 0.61072900 0.70308200 0.51353600 1 - O O63 1 0.09719300 0.61072900 0.40764700 1 - O O64 1 0.88927100 0.40280700 0.09235300 1 - O O65 1 0.79691800 0.88927100 0.98646400 1 - O O66 1 0.40280700 0.81045400 0.51353600 1 - O O67 1 0.68954600 0.09235300 0.70308200 1 - O O68 1 0.81045400 0.51353600 0.40280700 1 - O O69 1 0.98646400 0.79691800 0.88927100 1 - O O70 1 0.09235300 0.70308200 0.68954600 1 - O O71 1 0.98646400 0.68954600 0.09719300 1 - O O72 1 0.79691800 0.40764700 0.81045400 1 - O O73 1 0.40764700 0.81045400 0.79691800 1 - O O74 1 0.70308200 0.51353600 0.61072900 1 - O O75 1 0.09235300 0.88927100 0.40280700 1 - O O76 1 0.40280700 0.09235300 0.88927100 1 - O O77 1 0.09719300 0.98646400 0.68954600 1 - O O78 1 0.51353600 0.61072900 0.70308200 1 - O O79 1 0.18954600 0.48646400 0.59719300 1 -" -Ca3V2(GeO4)3,mvc-4394,Ia-3d,[],0.02127486856250016,{'tags': ['garnet family']},"Full Formula (Ca12 V8 Ge12 O48) -Reduced Formula: Ca3V2(GeO4)3 -abc : 10.825693 10.825693 10.825693 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 -0 - 1 Ca 0.75 0.625 0.875 0.001 - 2 Ca 0.625 0.875 0.75 0 - 3 Ca 0.875 0.625 0.25 0 - 4 Ca 0.625 0.25 0.875 0 - 5 Ca 0.875 0.75 0.625 0 - 6 Ca 0.75 0.125 0.375 -0 - 7 Ca 0.25 0.375 0.125 0.001 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.125 0.375 0.75 0 - 10 Ca 0.375 0.75 0.125 0 - 11 Ca 0.125 0.25 0.375 0 - 12 V 0.5 0.5 0.5 1.956 - 13 V 0.5 0 0.5 1.934 - 14 V 0 0.5 0.5 1.934 - 15 V 0.5 0.5 0 1.956 - 16 V 0 0 0.5 1.934 - 17 V 0 0.5 0 1.956 - 18 V 0.5 0 0 1.934 - 19 V 0 0 0 1.956 - 20 Ge 0.125 0.75 0.875 0.017 - 21 Ge 0.875 0.25 0.125 0.017 - 22 Ge 0.625 0.375 0.25 0.017 - 23 Ge 0.75 0.875 0.125 0.017 - 24 Ge 0.875 0.125 0.75 0.017 - 25 Ge 0.25 0.625 0.375 0.017 - 26 Ge 0.75 0.375 0.625 0.017 - 27 Ge 0.25 0.125 0.875 0.017 - 28 Ge 0.125 0.875 0.25 0.017 - 29 Ge 0.375 0.625 0.75 0.017 - 30 Ge 0.625 0.75 0.375 0.017 - 31 Ge 0.375 0.25 0.625 0.017 - 32 O 0.41527 0.813648 0.796593 -0.018 - 33 O 0.881323 0.398378 0.08473 -0.019 - 34 O 0.101622 0.982945 0.686352 -0.016 - 35 O 0.517055 0.618677 0.703407 -0.018 - 36 O 0.686352 0.08473 0.703407 -0.015 - 37 O 0.618677 0.703407 0.517055 -0.019 - 38 O 0.618677 0.41527 0.101622 -0.019 - 39 O 0.703407 0.517055 0.618677 -0.013 - 40 O 0.813648 0.517055 0.398378 -0.015 - 41 O 0.982945 0.796593 0.881323 -0.018 - 42 O 0.796593 0.881323 0.982945 -0.013 - 43 O 0.703407 0.686352 0.08473 -0.013 - 44 O 0.41527 0.101622 0.618677 -0.018 - 45 O 0.398378 0.813648 0.517055 -0.016 - 46 O 0.08473 0.703407 0.686352 -0.018 - 47 O 0.101622 0.618677 0.41527 -0.016 - 48 O 0.517055 0.398378 0.813648 -0.018 - 49 O 0.08473 0.881323 0.398378 -0.018 - 50 O 0.982945 0.686352 0.101622 -0.018 - 51 O 0.186352 0.482945 0.601622 -0.015 - 52 O 0.686352 0.101622 0.982945 -0.015 - 53 O 0.796593 0.41527 0.813648 -0.013 - 54 O 0.398378 0.08473 0.881323 -0.016 - 55 O 0.881323 0.982945 0.796593 -0.019 - 56 O 0.58473 0.186352 0.203407 -0.018 - 57 O 0.118677 0.601622 0.91527 -0.019 - 58 O 0.898378 0.017055 0.313648 -0.016 - 59 O 0.482945 0.381323 0.296593 -0.018 - 60 O 0.313648 0.91527 0.296593 -0.015 - 61 O 0.381323 0.296593 0.482945 -0.019 - 62 O 0.381323 0.58473 0.898378 -0.019 - 63 O 0.296593 0.482945 0.381323 -0.013 - 64 O 0.118677 0.017055 0.203407 -0.019 - 65 O 0.601622 0.91527 0.118677 -0.016 - 66 O 0.203407 0.58473 0.186352 -0.013 - 67 O 0.186352 0.203407 0.58473 -0.015 - 68 O 0.313648 0.898378 0.017055 -0.015 - 69 O 0.017055 0.313648 0.898378 -0.018 - 70 O 0.91527 0.118677 0.601622 -0.018 - 71 O 0.482945 0.601622 0.186352 -0.018 - 72 O 0.898378 0.381323 0.58473 -0.016 - 73 O 0.91527 0.296593 0.313648 -0.018 - 74 O 0.601622 0.186352 0.482945 -0.016 - 75 O 0.58473 0.898378 0.381323 -0.018 - 76 O 0.296593 0.313648 0.91527 -0.013 - 77 O 0.203407 0.118677 0.017055 -0.013 - 78 O 0.017055 0.203407 0.118677 -0.018 - 79 O 0.813648 0.796593 0.41527 -0.015","# generated using pymatgen -data_Ca3V2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.82569340 -_cell_length_b 10.82569340 -_cell_length_c 10.82569340 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3V2(GeO4)3 -_chemical_formula_sum 'Ca12 V8 Ge12 O48' -_cell_volume 976.66422228 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - V V12 1 0.50000000 0.50000000 0.50000000 1 - V V13 1 0.50000000 0.00000000 0.50000000 1 - V V14 1 0.00000000 0.50000000 0.50000000 1 - V V15 1 0.50000000 0.50000000 0.00000000 1 - V V16 1 0.00000000 0.00000000 0.50000000 1 - V V17 1 0.00000000 0.50000000 0.00000000 1 - V V18 1 0.50000000 0.00000000 0.00000000 1 - V V19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41527000 0.81364800 0.79659300 1 - O O33 1 0.88132300 0.39837800 0.08473000 1 - O O34 1 0.10162200 0.98294500 0.68635200 1 - O O35 1 0.51705500 0.61867700 0.70340700 1 - O O36 1 0.68635200 0.08473000 0.70340700 1 - O O37 1 0.61867700 0.70340700 0.51705500 1 - O O38 1 0.61867700 0.41527000 0.10162200 1 - O O39 1 0.70340700 0.51705500 0.61867700 1 - O O40 1 0.81364800 0.51705500 0.39837800 1 - O O41 1 0.98294500 0.79659300 0.88132300 1 - O O42 1 0.79659300 0.88132300 0.98294500 1 - O O43 1 0.70340700 0.68635200 0.08473000 1 - O O44 1 0.41527000 0.10162200 0.61867700 1 - O O45 1 0.39837800 0.81364800 0.51705500 1 - O O46 1 0.08473000 0.70340700 0.68635200 1 - O O47 1 0.10162200 0.61867700 0.41527000 1 - O O48 1 0.51705500 0.39837800 0.81364800 1 - O O49 1 0.08473000 0.88132300 0.39837800 1 - O O50 1 0.98294500 0.68635200 0.10162200 1 - O O51 1 0.18635200 0.48294500 0.60162200 1 - O O52 1 0.68635200 0.10162200 0.98294500 1 - O O53 1 0.79659300 0.41527000 0.81364800 1 - O O54 1 0.39837800 0.08473000 0.88132300 1 - O O55 1 0.88132300 0.98294500 0.79659300 1 - O O56 1 0.58473000 0.18635200 0.20340700 1 - O O57 1 0.11867700 0.60162200 0.91527000 1 - O O58 1 0.89837800 0.01705500 0.31364800 1 - O O59 1 0.48294500 0.38132300 0.29659300 1 - O O60 1 0.31364800 0.91527000 0.29659300 1 - O O61 1 0.38132300 0.29659300 0.48294500 1 - O O62 1 0.38132300 0.58473000 0.89837800 1 - O O63 1 0.29659300 0.48294500 0.38132300 1 - O O64 1 0.11867700 0.01705500 0.20340700 1 - O O65 1 0.60162200 0.91527000 0.11867700 1 - O O66 1 0.20340700 0.58473000 0.18635200 1 - O O67 1 0.18635200 0.20340700 0.58473000 1 - O O68 1 0.31364800 0.89837800 0.01705500 1 - O O69 1 0.01705500 0.31364800 0.89837800 1 - O O70 1 0.91527000 0.11867700 0.60162200 1 - O O71 1 0.48294500 0.60162200 0.18635200 1 - O O72 1 0.89837800 0.38132300 0.58473000 1 - O O73 1 0.91527000 0.29659300 0.31364800 1 - O O74 1 0.60162200 0.18635200 0.48294500 1 - O O75 1 0.58473000 0.89837800 0.38132300 1 - O O76 1 0.29659300 0.31364800 0.91527000 1 - O O77 1 0.20340700 0.11867700 0.01705500 1 - O O78 1 0.01705500 0.20340700 0.11867700 1 - O O79 1 0.81364800 0.79659300 0.41527000 1 -" -Mg3V2(GeO4)3,mvc-4402,Ia-3d,[],0.11027363368750098,{'tags': []},"Full Formula (Mg12 V8 Ge12 O48) -Reduced Formula: Mg3V2(GeO4)3 -abc : 10.506984 10.506984 10.506984 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.004 - 1 Mg 0.75 0.625 0.875 0.004 - 2 Mg 0.625 0.875 0.75 0.004 - 3 Mg 0.875 0.625 0.25 0.004 - 4 Mg 0.625 0.25 0.875 0.004 - 5 Mg 0.875 0.75 0.625 0.004 - 6 Mg 0.75 0.125 0.375 0.004 - 7 Mg 0.25 0.375 0.125 0.004 - 8 Mg 0.375 0.125 0.25 0.004 - 9 Mg 0.125 0.375 0.75 0.004 - 10 Mg 0.375 0.75 0.125 0.004 - 11 Mg 0.125 0.25 0.375 0.004 - 12 V 0.5 0.5 0.5 1.938 - 13 V 0.5 0 0.5 1.938 - 14 V 0 0.5 0.5 1.938 - 15 V 0.5 0.5 0 1.938 - 16 V 0 0 0.5 1.938 - 17 V 0 0.5 0 1.938 - 18 V 0.5 0 0 1.938 - 19 V 0 0 0 1.938 - 20 Ge 0.125 0.75 0.875 0.016 - 21 Ge 0.875 0.25 0.125 0.016 - 22 Ge 0.625 0.375 0.25 0.016 - 23 Ge 0.75 0.875 0.125 0.016 - 24 Ge 0.875 0.125 0.75 0.016 - 25 Ge 0.25 0.625 0.375 0.016 - 26 Ge 0.75 0.375 0.625 0.016 - 27 Ge 0.25 0.125 0.875 0.016 - 28 Ge 0.125 0.875 0.25 0.016 - 29 Ge 0.375 0.625 0.75 0.016 - 30 Ge 0.625 0.75 0.375 0.016 - 31 Ge 0.375 0.25 0.625 0.016 - 32 O 0.417171 0.816882 0.789513 -0.017 - 33 O 0.872342 0.399711 0.082829 -0.017 - 34 O 0.100289 0.972631 0.683118 -0.017 - 35 O 0.527369 0.627658 0.710487 -0.017 - 36 O 0.683118 0.082829 0.710487 -0.017 - 37 O 0.627658 0.710487 0.527369 -0.017 - 38 O 0.627658 0.417171 0.100289 -0.017 - 39 O 0.710487 0.527369 0.627658 -0.017 - 40 O 0.816882 0.527369 0.399711 -0.017 - 41 O 0.972631 0.789513 0.872342 -0.017 - 42 O 0.789513 0.872342 0.972631 -0.017 - 43 O 0.710487 0.683118 0.082829 -0.017 - 44 O 0.417171 0.100289 0.627658 -0.017 - 45 O 0.399711 0.816882 0.527369 -0.017 - 46 O 0.082829 0.710487 0.683118 -0.017 - 47 O 0.100289 0.627658 0.417171 -0.017 - 48 O 0.527369 0.399711 0.816882 -0.017 - 49 O 0.082829 0.872342 0.399711 -0.017 - 50 O 0.972631 0.683118 0.100289 -0.017 - 51 O 0.183118 0.472631 0.600289 -0.017 - 52 O 0.683118 0.100289 0.972631 -0.017 - 53 O 0.789513 0.417171 0.816882 -0.017 - 54 O 0.399711 0.082829 0.872342 -0.017 - 55 O 0.872342 0.972631 0.789513 -0.017 - 56 O 0.582829 0.183118 0.210487 -0.017 - 57 O 0.127658 0.600289 0.917171 -0.017 - 58 O 0.899711 0.027369 0.316882 -0.017 - 59 O 0.472631 0.372342 0.289513 -0.017 - 60 O 0.316882 0.917171 0.289513 -0.017 - 61 O 0.372342 0.289513 0.472631 -0.017 - 62 O 0.372342 0.582829 0.899711 -0.017 - 63 O 0.289513 0.472631 0.372342 -0.017 - 64 O 0.127658 0.027369 0.210487 -0.017 - 65 O 0.600289 0.917171 0.127658 -0.017 - 66 O 0.210487 0.582829 0.183118 -0.017 - 67 O 0.183118 0.210487 0.582829 -0.017 - 68 O 0.316882 0.899711 0.027369 -0.017 - 69 O 0.027369 0.316882 0.899711 -0.017 - 70 O 0.917171 0.127658 0.600289 -0.017 - 71 O 0.472631 0.600289 0.183118 -0.017 - 72 O 0.899711 0.372342 0.582829 -0.017 - 73 O 0.917171 0.289513 0.316882 -0.017 - 74 O 0.600289 0.183118 0.472631 -0.017 - 75 O 0.582829 0.899711 0.372342 -0.017 - 76 O 0.289513 0.316882 0.917171 -0.017 - 77 O 0.210487 0.127658 0.027369 -0.017 - 78 O 0.027369 0.210487 0.127658 -0.017 - 79 O 0.816882 0.789513 0.417171 -0.017","# generated using pymatgen -data_Mg3V2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.50698393 -_cell_length_b 10.50698393 -_cell_length_c 10.50698393 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3V2(GeO4)3 -_chemical_formula_sum 'Mg12 V8 Ge12 O48' -_cell_volume 892.91951201 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - V V12 1 0.50000000 0.50000000 0.50000000 1 - V V13 1 0.50000000 0.00000000 0.50000000 1 - V V14 1 0.00000000 0.50000000 0.50000000 1 - V V15 1 0.50000000 0.50000000 0.00000000 1 - V V16 1 0.00000000 0.00000000 0.50000000 1 - V V17 1 0.00000000 0.50000000 0.00000000 1 - V V18 1 0.50000000 0.00000000 0.00000000 1 - V V19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41717100 0.81688200 0.78951300 1 - O O33 1 0.87234200 0.39971100 0.08282900 1 - O O34 1 0.10028900 0.97263100 0.68311800 1 - O O35 1 0.52736900 0.62765800 0.71048700 1 - O O36 1 0.68311800 0.08282900 0.71048700 1 - O O37 1 0.62765800 0.71048700 0.52736900 1 - O O38 1 0.62765800 0.41717100 0.10028900 1 - O O39 1 0.71048700 0.52736900 0.62765800 1 - O O40 1 0.81688200 0.52736900 0.39971100 1 - O O41 1 0.97263100 0.78951300 0.87234200 1 - O O42 1 0.78951300 0.87234200 0.97263100 1 - O O43 1 0.71048700 0.68311800 0.08282900 1 - O O44 1 0.41717100 0.10028900 0.62765800 1 - O O45 1 0.39971100 0.81688200 0.52736900 1 - O O46 1 0.08282900 0.71048700 0.68311800 1 - O O47 1 0.10028900 0.62765800 0.41717100 1 - O O48 1 0.52736900 0.39971100 0.81688200 1 - O O49 1 0.08282900 0.87234200 0.39971100 1 - O O50 1 0.97263100 0.68311800 0.10028900 1 - O O51 1 0.18311800 0.47263100 0.60028900 1 - O O52 1 0.68311800 0.10028900 0.97263100 1 - O O53 1 0.78951300 0.41717100 0.81688200 1 - O O54 1 0.39971100 0.08282900 0.87234200 1 - O O55 1 0.87234200 0.97263100 0.78951300 1 - O O56 1 0.58282900 0.18311800 0.21048700 1 - O O57 1 0.12765800 0.60028900 0.91717100 1 - O O58 1 0.89971100 0.02736900 0.31688200 1 - O O59 1 0.47263100 0.37234200 0.28951300 1 - O O60 1 0.31688200 0.91717100 0.28951300 1 - O O61 1 0.37234200 0.28951300 0.47263100 1 - O O62 1 0.37234200 0.58282900 0.89971100 1 - O O63 1 0.28951300 0.47263100 0.37234200 1 - O O64 1 0.12765800 0.02736900 0.21048700 1 - O O65 1 0.60028900 0.91717100 0.12765800 1 - O O66 1 0.21048700 0.58282900 0.18311800 1 - O O67 1 0.18311800 0.21048700 0.58282900 1 - O O68 1 0.31688200 0.89971100 0.02736900 1 - O O69 1 0.02736900 0.31688200 0.89971100 1 - O O70 1 0.91717100 0.12765800 0.60028900 1 - O O71 1 0.47263100 0.60028900 0.18311800 1 - O O72 1 0.89971100 0.37234200 0.58282900 1 - O O73 1 0.91717100 0.28951300 0.31688200 1 - O O74 1 0.60028900 0.18311800 0.47263100 1 - O O75 1 0.58282900 0.89971100 0.37234200 1 - O O76 1 0.28951300 0.31688200 0.91717100 1 - O O77 1 0.21048700 0.12765800 0.02736900 1 - O O78 1 0.02736900 0.21048700 0.12765800 1 - O O79 1 0.81688200 0.78951300 0.41717100 1 -" -Ca3Co2(GeO4)3,mvc-4409,Ia-3d,[],0.015514714455814982,{'tags': []},"Full Formula (Ca12 Co8 Ge12 O48) -Reduced Formula: Ca3Co2(GeO4)3 -abc : 10.750076 10.750076 10.750076 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0.003 - 1 Ca 0.75 0.625 0.875 0.003 - 2 Ca 0.625 0.875 0.75 0.003 - 3 Ca 0.875 0.625 0.25 0.003 - 4 Ca 0.625 0.25 0.875 0.003 - 5 Ca 0.875 0.75 0.625 0.003 - 6 Ca 0.75 0.125 0.375 0.003 - 7 Ca 0.25 0.375 0.125 0.003 - 8 Ca 0.375 0.125 0.25 0.003 - 9 Ca 0.125 0.375 0.75 0.003 - 10 Ca 0.375 0.75 0.125 0.003 - 11 Ca 0.125 0.25 0.375 0.003 - 12 Co 0.5 0.5 0.5 3.118 - 13 Co 0.5 0 0.5 3.117 - 14 Co 0 0.5 0.5 3.117 - 15 Co 0.5 0.5 0 3.119 - 16 Co 0 0 0.5 3.117 - 17 Co 0 0.5 0 3.119 - 18 Co 0.5 0 0 3.117 - 19 Co 0 0 0 3.118 - 20 Ge 0.125 0.75 0.875 0.023 - 21 Ge 0.875 0.25 0.125 0.023 - 22 Ge 0.625 0.375 0.25 0.023 - 23 Ge 0.75 0.875 0.125 0.023 - 24 Ge 0.875 0.125 0.75 0.023 - 25 Ge 0.25 0.625 0.375 0.023 - 26 Ge 0.75 0.375 0.625 0.023 - 27 Ge 0.25 0.125 0.875 0.023 - 28 Ge 0.125 0.875 0.25 0.023 - 29 Ge 0.375 0.625 0.75 0.023 - 30 Ge 0.625 0.75 0.375 0.023 - 31 Ge 0.375 0.25 0.625 0.023 - 32 O 0.415752 0.815183 0.797619 0.116 - 33 O 0.881867 0.399432 0.084248 0.118 - 34 O 0.100568 0.982435 0.684817 0.118 - 35 O 0.517565 0.618133 0.702381 0.116 - 36 O 0.684817 0.084248 0.702381 0.119 - 37 O 0.618133 0.702381 0.517565 0.118 - 38 O 0.618133 0.415752 0.100568 0.118 - 39 O 0.702381 0.517565 0.618133 0.119 - 40 O 0.815183 0.517565 0.399432 0.119 - 41 O 0.982435 0.797619 0.881867 0.116 - 42 O 0.797619 0.881867 0.982435 0.119 - 43 O 0.702381 0.684817 0.084248 0.119 - 44 O 0.415752 0.100568 0.618133 0.116 - 45 O 0.399432 0.815183 0.517565 0.118 - 46 O 0.084248 0.702381 0.684817 0.116 - 47 O 0.100568 0.618133 0.415752 0.118 - 48 O 0.517565 0.399432 0.815183 0.116 - 49 O 0.084248 0.881867 0.399432 0.116 - 50 O 0.982435 0.684817 0.100568 0.116 - 51 O 0.184817 0.482435 0.600568 0.119 - 52 O 0.684817 0.100568 0.982435 0.119 - 53 O 0.797619 0.415752 0.815183 0.119 - 54 O 0.399432 0.084248 0.881867 0.118 - 55 O 0.881867 0.982435 0.797619 0.118 - 56 O 0.584248 0.184817 0.202381 0.116 - 57 O 0.118133 0.600568 0.915752 0.118 - 58 O 0.899432 0.017565 0.315183 0.118 - 59 O 0.482435 0.381867 0.297619 0.116 - 60 O 0.315183 0.915752 0.297619 0.119 - 61 O 0.381867 0.297619 0.482435 0.118 - 62 O 0.381867 0.584248 0.899432 0.118 - 63 O 0.297619 0.482435 0.381867 0.119 - 64 O 0.118133 0.017565 0.202381 0.118 - 65 O 0.600568 0.915752 0.118133 0.118 - 66 O 0.202381 0.584248 0.184817 0.119 - 67 O 0.184817 0.202381 0.584248 0.119 - 68 O 0.315183 0.899432 0.017565 0.119 - 69 O 0.017565 0.315183 0.899432 0.116 - 70 O 0.915752 0.118133 0.600568 0.116 - 71 O 0.482435 0.600568 0.184817 0.116 - 72 O 0.899432 0.381867 0.584248 0.118 - 73 O 0.915752 0.297619 0.315183 0.116 - 74 O 0.600568 0.184817 0.482435 0.118 - 75 O 0.584248 0.899432 0.381867 0.116 - 76 O 0.297619 0.315183 0.915752 0.119 - 77 O 0.202381 0.118133 0.017565 0.119 - 78 O 0.017565 0.202381 0.118133 0.116 - 79 O 0.815183 0.797619 0.415752 0.119","# generated using pymatgen -data_Ca3Co2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.75007553 -_cell_length_b 10.75007553 -_cell_length_c 10.75007553 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Co2(GeO4)3 -_chemical_formula_sum 'Ca12 Co8 Ge12 O48' -_cell_volume 956.34073737 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Co Co12 1 0.50000000 0.50000000 0.50000000 1 - Co Co13 1 0.50000000 0.00000000 0.50000000 1 - Co Co14 1 0.00000000 0.50000000 0.50000000 1 - Co Co15 1 0.50000000 0.50000000 0.00000000 1 - Co Co16 1 0.00000000 0.00000000 0.50000000 1 - Co Co17 1 0.00000000 0.50000000 0.00000000 1 - Co Co18 1 0.50000000 0.00000000 0.00000000 1 - Co Co19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41575200 0.81518300 0.79761900 1 - O O33 1 0.88186700 0.39943200 0.08424800 1 - O O34 1 0.10056800 0.98243500 0.68481700 1 - O O35 1 0.51756500 0.61813300 0.70238100 1 - O O36 1 0.68481700 0.08424800 0.70238100 1 - O O37 1 0.61813300 0.70238100 0.51756500 1 - O O38 1 0.61813300 0.41575200 0.10056800 1 - O O39 1 0.70238100 0.51756500 0.61813300 1 - O O40 1 0.81518300 0.51756500 0.39943200 1 - O O41 1 0.98243500 0.79761900 0.88186700 1 - O O42 1 0.79761900 0.88186700 0.98243500 1 - O O43 1 0.70238100 0.68481700 0.08424800 1 - O O44 1 0.41575200 0.10056800 0.61813300 1 - O O45 1 0.39943200 0.81518300 0.51756500 1 - O O46 1 0.08424800 0.70238100 0.68481700 1 - O O47 1 0.10056800 0.61813300 0.41575200 1 - O O48 1 0.51756500 0.39943200 0.81518300 1 - O O49 1 0.08424800 0.88186700 0.39943200 1 - O O50 1 0.98243500 0.68481700 0.10056800 1 - O O51 1 0.18481700 0.48243500 0.60056800 1 - O O52 1 0.68481700 0.10056800 0.98243500 1 - O O53 1 0.79761900 0.41575200 0.81518300 1 - O O54 1 0.39943200 0.08424800 0.88186700 1 - O O55 1 0.88186700 0.98243500 0.79761900 1 - O O56 1 0.58424800 0.18481700 0.20238100 1 - O O57 1 0.11813300 0.60056800 0.91575200 1 - O O58 1 0.89943200 0.01756500 0.31518300 1 - O O59 1 0.48243500 0.38186700 0.29761900 1 - O O60 1 0.31518300 0.91575200 0.29761900 1 - O O61 1 0.38186700 0.29761900 0.48243500 1 - O O62 1 0.38186700 0.58424800 0.89943200 1 - O O63 1 0.29761900 0.48243500 0.38186700 1 - O O64 1 0.11813300 0.01756500 0.20238100 1 - O O65 1 0.60056800 0.91575200 0.11813300 1 - O O66 1 0.20238100 0.58424800 0.18481700 1 - O O67 1 0.18481700 0.20238100 0.58424800 1 - O O68 1 0.31518300 0.89943200 0.01756500 1 - O O69 1 0.01756500 0.31518300 0.89943200 1 - O O70 1 0.91575200 0.11813300 0.60056800 1 - O O71 1 0.48243500 0.60056800 0.18481700 1 - O O72 1 0.89943200 0.38186700 0.58424800 1 - O O73 1 0.91575200 0.29761900 0.31518300 1 - O O74 1 0.60056800 0.18481700 0.48243500 1 - O O75 1 0.58424800 0.89943200 0.38186700 1 - O O76 1 0.29761900 0.31518300 0.91575200 1 - O O77 1 0.20238100 0.11813300 0.01756500 1 - O O78 1 0.01756500 0.20238100 0.11813300 1 - O O79 1 0.81518300 0.79761900 0.41575200 1 -" -Mg3Ge3(MoO6)2,mvc-4434,Ia-3d,[],0.07400053317187893,{'tags': []},"Full Formula (Mg12 Ge12 Mo8 O48) -Reduced Formula: Mg3Ge3(MoO6)2 -abc : 10.705508 10.705508 10.705508 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.004 - 1 Mg 0.75 0.625 0.875 0.004 - 2 Mg 0.625 0.875 0.75 0.004 - 3 Mg 0.875 0.625 0.25 0.004 - 4 Mg 0.625 0.25 0.875 0.004 - 5 Mg 0.875 0.75 0.625 0.004 - 6 Mg 0.75 0.125 0.375 0.004 - 7 Mg 0.25 0.375 0.125 0.004 - 8 Mg 0.375 0.125 0.25 0.004 - 9 Mg 0.125 0.375 0.75 0.004 - 10 Mg 0.375 0.75 0.125 0.004 - 11 Mg 0.125 0.25 0.375 0.004 - 12 Ge 0.125 0.75 0.875 0.023 - 13 Ge 0.875 0.25 0.125 0.023 - 14 Ge 0.625 0.375 0.25 0.023 - 15 Ge 0.75 0.875 0.125 0.023 - 16 Ge 0.875 0.125 0.75 0.023 - 17 Ge 0.25 0.625 0.375 0.023 - 18 Ge 0.75 0.375 0.625 0.023 - 19 Ge 0.25 0.125 0.875 0.023 - 20 Ge 0.125 0.875 0.25 0.023 - 21 Ge 0.375 0.625 0.75 0.023 - 22 Ge 0.625 0.75 0.375 0.023 - 23 Ge 0.375 0.25 0.625 0.023 - 24 Mo 0.5 0.5 0.5 2.742 - 25 Mo 0.5 0 0.5 2.742 - 26 Mo 0 0.5 0.5 2.742 - 27 Mo 0.5 0.5 0 2.742 - 28 Mo 0 0 0.5 2.742 - 29 Mo 0 0.5 0 2.742 - 30 Mo 0.5 0 0 2.742 - 31 Mo 0 0 0 2.742 - 32 O 0.412895 0.810881 0.781216 0.011 - 33 O 0.868321 0.397987 0.087105 0.011 - 34 O 0.102013 0.970334 0.689119 0.011 - 35 O 0.529666 0.631679 0.718784 0.011 - 36 O 0.689119 0.087105 0.718784 0.011 - 37 O 0.631679 0.718784 0.529666 0.011 - 38 O 0.631679 0.412895 0.102013 0.011 - 39 O 0.718784 0.529666 0.631679 0.011 - 40 O 0.810881 0.529666 0.397987 0.011 - 41 O 0.970334 0.781216 0.868321 0.011 - 42 O 0.781216 0.868321 0.970334 0.011 - 43 O 0.718784 0.689119 0.087105 0.011 - 44 O 0.412895 0.102013 0.631679 0.011 - 45 O 0.397987 0.810881 0.529666 0.011 - 46 O 0.087105 0.718784 0.689119 0.011 - 47 O 0.102013 0.631679 0.412895 0.011 - 48 O 0.529666 0.397987 0.810881 0.011 - 49 O 0.087105 0.868321 0.397987 0.011 - 50 O 0.970334 0.689119 0.102013 0.011 - 51 O 0.189119 0.470334 0.602013 0.011 - 52 O 0.689119 0.102013 0.970334 0.011 - 53 O 0.781216 0.412895 0.810881 0.011 - 54 O 0.397987 0.087105 0.868321 0.011 - 55 O 0.868321 0.970334 0.781216 0.011 - 56 O 0.587105 0.189119 0.218784 0.011 - 57 O 0.131679 0.602013 0.912895 0.011 - 58 O 0.897987 0.029666 0.310881 0.011 - 59 O 0.470334 0.368321 0.281216 0.011 - 60 O 0.310881 0.912895 0.281216 0.011 - 61 O 0.368321 0.281216 0.470334 0.011 - 62 O 0.368321 0.587105 0.897987 0.011 - 63 O 0.281216 0.470334 0.368321 0.011 - 64 O 0.131679 0.029666 0.218784 0.011 - 65 O 0.602013 0.912895 0.131679 0.011 - 66 O 0.218784 0.587105 0.189119 0.011 - 67 O 0.189119 0.218784 0.587105 0.011 - 68 O 0.310881 0.897987 0.029666 0.011 - 69 O 0.029666 0.310881 0.897987 0.011 - 70 O 0.912895 0.131679 0.602013 0.011 - 71 O 0.470334 0.602013 0.189119 0.011 - 72 O 0.897987 0.368321 0.587105 0.011 - 73 O 0.912895 0.281216 0.310881 0.011 - 74 O 0.602013 0.189119 0.470334 0.011 - 75 O 0.587105 0.897987 0.368321 0.011 - 76 O 0.281216 0.310881 0.912895 0.011 - 77 O 0.218784 0.131679 0.029666 0.011 - 78 O 0.029666 0.218784 0.131679 0.011 - 79 O 0.810881 0.781216 0.412895 0.011","# generated using pymatgen -data_Mg3Ge3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.70550813 -_cell_length_b 10.70550813 -_cell_length_c 10.70550813 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ge3(MoO6)2 -_chemical_formula_sum 'Mg12 Ge12 Mo8 O48' -_cell_volume 944.49565853 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Mo Mo24 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo25 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo26 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo27 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo28 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo29 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo30 1 0.50000000 0.00000000 0.00000000 1 - Mo Mo31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.41289500 0.81088100 0.78121600 1 - O O33 1 0.86832100 0.39798700 0.08710500 1 - O O34 1 0.10201300 0.97033400 0.68911900 1 - O O35 1 0.52966600 0.63167900 0.71878400 1 - O O36 1 0.68911900 0.08710500 0.71878400 1 - O O37 1 0.63167900 0.71878400 0.52966600 1 - O O38 1 0.63167900 0.41289500 0.10201300 1 - O O39 1 0.71878400 0.52966600 0.63167900 1 - O O40 1 0.81088100 0.52966600 0.39798700 1 - O O41 1 0.97033400 0.78121600 0.86832100 1 - O O42 1 0.78121600 0.86832100 0.97033400 1 - O O43 1 0.71878400 0.68911900 0.08710500 1 - O O44 1 0.41289500 0.10201300 0.63167900 1 - O O45 1 0.39798700 0.81088100 0.52966600 1 - O O46 1 0.08710500 0.71878400 0.68911900 1 - O O47 1 0.10201300 0.63167900 0.41289500 1 - O O48 1 0.52966600 0.39798700 0.81088100 1 - O O49 1 0.08710500 0.86832100 0.39798700 1 - O O50 1 0.97033400 0.68911900 0.10201300 1 - O O51 1 0.18911900 0.47033400 0.60201300 1 - O O52 1 0.68911900 0.10201300 0.97033400 1 - O O53 1 0.78121600 0.41289500 0.81088100 1 - O O54 1 0.39798700 0.08710500 0.86832100 1 - O O55 1 0.86832100 0.97033400 0.78121600 1 - O O56 1 0.58710500 0.18911900 0.21878400 1 - O O57 1 0.13167900 0.60201300 0.91289500 1 - O O58 1 0.89798700 0.02966600 0.31088100 1 - O O59 1 0.47033400 0.36832100 0.28121600 1 - O O60 1 0.31088100 0.91289500 0.28121600 1 - O O61 1 0.36832100 0.28121600 0.47033400 1 - O O62 1 0.36832100 0.58710500 0.89798700 1 - O O63 1 0.28121600 0.47033400 0.36832100 1 - O O64 1 0.13167900 0.02966600 0.21878400 1 - O O65 1 0.60201300 0.91289500 0.13167900 1 - O O66 1 0.21878400 0.58710500 0.18911900 1 - O O67 1 0.18911900 0.21878400 0.58710500 1 - O O68 1 0.31088100 0.89798700 0.02966600 1 - O O69 1 0.02966600 0.31088100 0.89798700 1 - O O70 1 0.91289500 0.13167900 0.60201300 1 - O O71 1 0.47033400 0.60201300 0.18911900 1 - O O72 1 0.89798700 0.36832100 0.58710500 1 - O O73 1 0.91289500 0.28121600 0.31088100 1 - O O74 1 0.60201300 0.18911900 0.47033400 1 - O O75 1 0.58710500 0.89798700 0.36832100 1 - O O76 1 0.28121600 0.31088100 0.91289500 1 - O O77 1 0.21878400 0.13167900 0.02966600 1 - O O78 1 0.02966600 0.21878400 0.13167900 1 - O O79 1 0.81088100 0.78121600 0.41289500 1 -" -Zn3Co2(GeO4)3,mvc-4436,Ia-3d,[],0.1134282183640325,{'tags': []},"Full Formula (Zn12 Co8 Ge12 O48) -Reduced Formula: Zn3Co2(GeO4)3 -abc : 10.318203 10.318203 10.318203 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 -0 - 1 Zn 0.75 0.625 0.875 -0 - 2 Zn 0.625 0.875 0.75 -0 - 3 Zn 0.875 0.625 0.25 -0 - 4 Zn 0.625 0.25 0.875 -0 - 5 Zn 0.875 0.75 0.625 -0 - 6 Zn 0.75 0.125 0.375 -0 - 7 Zn 0.25 0.375 0.125 -0 - 8 Zn 0.375 0.125 0.25 -0 - 9 Zn 0.125 0.375 0.75 -0 - 10 Zn 0.375 0.75 0.125 -0 - 11 Zn 0.125 0.25 0.375 -0 - 12 Co 0.5 0.5 0.5 -0 - 13 Co 0.5 0 0.5 -0 - 14 Co 0 0.5 0.5 -0 - 15 Co 0.5 0.5 0 -0 - 16 Co 0 0 0.5 -0 - 17 Co 0 0.5 0 -0 - 18 Co 0.5 0 0 -0 - 19 Co 0 0 0 -0 - 20 Ge 0.125 0.75 0.875 -0 - 21 Ge 0.875 0.25 0.125 -0 - 22 Ge 0.625 0.375 0.25 -0 - 23 Ge 0.75 0.875 0.125 -0 - 24 Ge 0.875 0.125 0.75 -0 - 25 Ge 0.25 0.625 0.375 -0 - 26 Ge 0.75 0.375 0.625 -0 - 27 Ge 0.25 0.125 0.875 -0 - 28 Ge 0.125 0.875 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.625 0.75 0.375 -0 - 31 Ge 0.375 0.25 0.625 -0 - 32 O 0.423405 0.823575 0.798239 -0 - 33 O 0.874834 0.400169 0.076595 -0 - 34 O 0.099831 0.974664 0.676425 -0 - 35 O 0.525336 0.625166 0.701761 -0 - 36 O 0.676425 0.076595 0.701761 -0 - 37 O 0.625166 0.701761 0.525336 -0 - 38 O 0.625166 0.423405 0.099831 -0 - 39 O 0.701761 0.525336 0.625166 -0 - 40 O 0.823575 0.525336 0.400169 -0 - 41 O 0.974664 0.798239 0.874834 -0 - 42 O 0.798239 0.874834 0.974664 -0 - 43 O 0.701761 0.676425 0.076595 -0 - 44 O 0.423405 0.099831 0.625166 -0 - 45 O 0.400169 0.823575 0.525336 -0 - 46 O 0.076595 0.701761 0.676425 -0 - 47 O 0.099831 0.625166 0.423405 -0 - 48 O 0.525336 0.400169 0.823575 -0 - 49 O 0.076595 0.874834 0.400169 -0 - 50 O 0.974664 0.676425 0.099831 -0 - 51 O 0.176425 0.474664 0.599831 -0 - 52 O 0.676425 0.099831 0.974664 -0 - 53 O 0.798239 0.423405 0.823575 -0 - 54 O 0.400169 0.076595 0.874834 -0 - 55 O 0.874834 0.974664 0.798239 -0 - 56 O 0.576595 0.176425 0.201761 -0 - 57 O 0.125166 0.599831 0.923405 -0 - 58 O 0.900169 0.025336 0.323575 -0 - 59 O 0.474664 0.374834 0.298239 -0 - 60 O 0.323575 0.923405 0.298239 -0 - 61 O 0.374834 0.298239 0.474664 -0 - 62 O 0.374834 0.576595 0.900169 -0 - 63 O 0.298239 0.474664 0.374834 -0 - 64 O 0.125166 0.025336 0.201761 -0 - 65 O 0.599831 0.923405 0.125166 -0 - 66 O 0.201761 0.576595 0.176425 -0 - 67 O 0.176425 0.201761 0.576595 -0 - 68 O 0.323575 0.900169 0.025336 -0 - 69 O 0.025336 0.323575 0.900169 -0 - 70 O 0.923405 0.125166 0.599831 -0 - 71 O 0.474664 0.599831 0.176425 -0 - 72 O 0.900169 0.374834 0.576595 -0 - 73 O 0.923405 0.298239 0.323575 -0 - 74 O 0.599831 0.176425 0.474664 -0 - 75 O 0.576595 0.900169 0.374834 -0 - 76 O 0.298239 0.323575 0.923405 -0 - 77 O 0.201761 0.125166 0.025336 -0 - 78 O 0.025336 0.201761 0.125166 -0 - 79 O 0.823575 0.798239 0.423405 -0","# generated using pymatgen -data_Zn3Co2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.31820252 -_cell_length_b 10.31820252 -_cell_length_c 10.31820252 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Co2(GeO4)3 -_chemical_formula_sum 'Zn12 Co8 Ge12 O48' -_cell_volume 845.64921849 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Co Co12 1 0.50000000 0.50000000 0.50000000 1 - Co Co13 1 0.50000000 0.00000000 0.50000000 1 - Co Co14 1 0.00000000 0.50000000 0.50000000 1 - Co Co15 1 0.50000000 0.50000000 0.00000000 1 - Co Co16 1 0.00000000 0.00000000 0.50000000 1 - Co Co17 1 0.00000000 0.50000000 0.00000000 1 - Co Co18 1 0.50000000 0.00000000 0.00000000 1 - Co Co19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.42340500 0.82357500 0.79823900 1 - O O33 1 0.87483400 0.40016900 0.07659500 1 - O O34 1 0.09983100 0.97466400 0.67642500 1 - O O35 1 0.52533600 0.62516600 0.70176100 1 - O O36 1 0.67642500 0.07659500 0.70176100 1 - O O37 1 0.62516600 0.70176100 0.52533600 1 - O O38 1 0.62516600 0.42340500 0.09983100 1 - O O39 1 0.70176100 0.52533600 0.62516600 1 - O O40 1 0.82357500 0.52533600 0.40016900 1 - O O41 1 0.97466400 0.79823900 0.87483400 1 - O O42 1 0.79823900 0.87483400 0.97466400 1 - O O43 1 0.70176100 0.67642500 0.07659500 1 - O O44 1 0.42340500 0.09983100 0.62516600 1 - O O45 1 0.40016900 0.82357500 0.52533600 1 - O O46 1 0.07659500 0.70176100 0.67642500 1 - O O47 1 0.09983100 0.62516600 0.42340500 1 - O O48 1 0.52533600 0.40016900 0.82357500 1 - O O49 1 0.07659500 0.87483400 0.40016900 1 - O O50 1 0.97466400 0.67642500 0.09983100 1 - O O51 1 0.17642500 0.47466400 0.59983100 1 - O O52 1 0.67642500 0.09983100 0.97466400 1 - O O53 1 0.79823900 0.42340500 0.82357500 1 - O O54 1 0.40016900 0.07659500 0.87483400 1 - O O55 1 0.87483400 0.97466400 0.79823900 1 - O O56 1 0.57659500 0.17642500 0.20176100 1 - O O57 1 0.12516600 0.59983100 0.92340500 1 - O O58 1 0.90016900 0.02533600 0.32357500 1 - O O59 1 0.47466400 0.37483400 0.29823900 1 - O O60 1 0.32357500 0.92340500 0.29823900 1 - O O61 1 0.37483400 0.29823900 0.47466400 1 - O O62 1 0.37483400 0.57659500 0.90016900 1 - O O63 1 0.29823900 0.47466400 0.37483400 1 - O O64 1 0.12516600 0.02533600 0.20176100 1 - O O65 1 0.59983100 0.92340500 0.12516600 1 - O O66 1 0.20176100 0.57659500 0.17642500 1 - O O67 1 0.17642500 0.20176100 0.57659500 1 - O O68 1 0.32357500 0.90016900 0.02533600 1 - O O69 1 0.02533600 0.32357500 0.90016900 1 - O O70 1 0.92340500 0.12516600 0.59983100 1 - O O71 1 0.47466400 0.59983100 0.17642500 1 - O O72 1 0.90016900 0.37483400 0.57659500 1 - O O73 1 0.92340500 0.29823900 0.32357500 1 - O O74 1 0.59983100 0.17642500 0.47466400 1 - O O75 1 0.57659500 0.90016900 0.37483400 1 - O O76 1 0.29823900 0.32357500 0.92340500 1 - O O77 1 0.20176100 0.12516600 0.02533600 1 - O O78 1 0.02533600 0.20176100 0.12516600 1 - O O79 1 0.82357500 0.79823900 0.42340500 1 -" -Mg3Co2(GeO4)3,mvc-4438,Ia-3d,[],0.07195685041287625,{'tags': []},"Full Formula (Mg12 Co8 Ge12 O48) -Reduced Formula: Mg3Co2(GeO4)3 -abc : 10.276509 10.276509 10.276509 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 -0 - 1 Mg 0.75 0.625 0.875 -0 - 2 Mg 0.625 0.875 0.75 -0 - 3 Mg 0.875 0.625 0.25 -0 - 4 Mg 0.625 0.25 0.875 -0 - 5 Mg 0.875 0.75 0.625 -0 - 6 Mg 0.75 0.125 0.375 -0 - 7 Mg 0.25 0.375 0.125 -0 - 8 Mg 0.375 0.125 0.25 -0 - 9 Mg 0.125 0.375 0.75 -0 - 10 Mg 0.375 0.75 0.125 -0 - 11 Mg 0.125 0.25 0.375 -0 - 12 Co 0.5 0.5 0.5 -0 - 13 Co 0.5 0 0.5 -0 - 14 Co 0 0.5 0.5 -0 - 15 Co 0.5 0.5 0 -0 - 16 Co 0 0 0.5 -0 - 17 Co 0 0.5 0 -0 - 18 Co 0.5 0 0 -0 - 19 Co 0 0 0 -0 - 20 Ge 0.125 0.75 0.875 -0 - 21 Ge 0.875 0.25 0.125 -0 - 22 Ge 0.625 0.375 0.25 -0 - 23 Ge 0.75 0.875 0.125 -0 - 24 Ge 0.875 0.125 0.75 -0 - 25 Ge 0.25 0.625 0.375 -0 - 26 Ge 0.75 0.375 0.625 -0 - 27 Ge 0.25 0.125 0.875 -0 - 28 Ge 0.125 0.875 0.25 -0 - 29 Ge 0.375 0.625 0.75 -0 - 30 Ge 0.625 0.75 0.375 -0 - 31 Ge 0.375 0.25 0.625 -0 - 32 O 0.420484 0.822769 0.79521 -0 - 33 O 0.874726 0.402286 0.079516 0 - 34 O 0.097714 0.97244 0.677231 0 - 35 O 0.52756 0.625274 0.70479 -0 - 36 O 0.677231 0.079516 0.70479 0 - 37 O 0.625274 0.70479 0.52756 0 - 38 O 0.625274 0.420484 0.097714 0 - 39 O 0.70479 0.52756 0.625274 0 - 40 O 0.822769 0.52756 0.402286 -0 - 41 O 0.97244 0.79521 0.874726 0 - 42 O 0.79521 0.874726 0.97244 0 - 43 O 0.70479 0.677231 0.079516 0 - 44 O 0.420484 0.097714 0.625274 0 - 45 O 0.402286 0.822769 0.52756 0 - 46 O 0.079516 0.70479 0.677231 0 - 47 O 0.097714 0.625274 0.420484 0 - 48 O 0.52756 0.402286 0.822769 -0 - 49 O 0.079516 0.874726 0.402286 -0 - 50 O 0.97244 0.677231 0.097714 -0 - 51 O 0.177231 0.47244 0.597714 -0 - 52 O 0.677231 0.097714 0.97244 0 - 53 O 0.79521 0.420484 0.822769 0 - 54 O 0.402286 0.079516 0.874726 0 - 55 O 0.874726 0.97244 0.79521 -0 - 56 O 0.579516 0.177231 0.20479 -0 - 57 O 0.125274 0.597714 0.920484 0 - 58 O 0.902286 0.02756 0.322769 -0 - 59 O 0.47244 0.374726 0.29521 -0 - 60 O 0.322769 0.920484 0.29521 0 - 61 O 0.374726 0.29521 0.47244 0 - 62 O 0.374726 0.579516 0.902286 0 - 63 O 0.29521 0.47244 0.374726 0 - 64 O 0.125274 0.02756 0.20479 -0 - 65 O 0.597714 0.920484 0.125274 0 - 66 O 0.20479 0.579516 0.177231 0 - 67 O 0.177231 0.20479 0.579516 0 - 68 O 0.322769 0.902286 0.02756 0 - 69 O 0.02756 0.322769 0.902286 -0 - 70 O 0.920484 0.125274 0.597714 -0 - 71 O 0.47244 0.597714 0.177231 -0 - 72 O 0.902286 0.374726 0.579516 0 - 73 O 0.920484 0.29521 0.322769 0 - 74 O 0.597714 0.177231 0.47244 0 - 75 O 0.579516 0.902286 0.374726 0 - 76 O 0.29521 0.322769 0.920484 0 - 77 O 0.20479 0.125274 0.02756 0 - 78 O 0.02756 0.20479 0.125274 0 - 79 O 0.822769 0.79521 0.420484 0","# generated using pymatgen -data_Mg3Co2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.27650859 -_cell_length_b 10.27650859 -_cell_length_c 10.27650859 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Co2(GeO4)3 -_chemical_formula_sum 'Mg12 Co8 Ge12 O48' -_cell_volume 835.43925530 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Co Co12 1 0.50000000 0.50000000 0.50000000 1 - Co Co13 1 0.50000000 0.00000000 0.50000000 1 - Co Co14 1 0.00000000 0.50000000 0.50000000 1 - Co Co15 1 0.50000000 0.50000000 0.00000000 1 - Co Co16 1 0.00000000 0.00000000 0.50000000 1 - Co Co17 1 0.00000000 0.50000000 0.00000000 1 - Co Co18 1 0.50000000 0.00000000 0.00000000 1 - Co Co19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.42048400 0.82276900 0.79521000 1 - O O33 1 0.87472600 0.40228600 0.07951600 1 - O O34 1 0.09771400 0.97244000 0.67723100 1 - O O35 1 0.52756000 0.62527400 0.70479000 1 - O O36 1 0.67723100 0.07951600 0.70479000 1 - O O37 1 0.62527400 0.70479000 0.52756000 1 - O O38 1 0.62527400 0.42048400 0.09771400 1 - O O39 1 0.70479000 0.52756000 0.62527400 1 - O O40 1 0.82276900 0.52756000 0.40228600 1 - O O41 1 0.97244000 0.79521000 0.87472600 1 - O O42 1 0.79521000 0.87472600 0.97244000 1 - O O43 1 0.70479000 0.67723100 0.07951600 1 - O O44 1 0.42048400 0.09771400 0.62527400 1 - O O45 1 0.40228600 0.82276900 0.52756000 1 - O O46 1 0.07951600 0.70479000 0.67723100 1 - O O47 1 0.09771400 0.62527400 0.42048400 1 - O O48 1 0.52756000 0.40228600 0.82276900 1 - O O49 1 0.07951600 0.87472600 0.40228600 1 - O O50 1 0.97244000 0.67723100 0.09771400 1 - O O51 1 0.17723100 0.47244000 0.59771400 1 - O O52 1 0.67723100 0.09771400 0.97244000 1 - O O53 1 0.79521000 0.42048400 0.82276900 1 - O O54 1 0.40228600 0.07951600 0.87472600 1 - O O55 1 0.87472600 0.97244000 0.79521000 1 - O O56 1 0.57951600 0.17723100 0.20479000 1 - O O57 1 0.12527400 0.59771400 0.92048400 1 - O O58 1 0.90228600 0.02756000 0.32276900 1 - O O59 1 0.47244000 0.37472600 0.29521000 1 - O O60 1 0.32276900 0.92048400 0.29521000 1 - O O61 1 0.37472600 0.29521000 0.47244000 1 - O O62 1 0.37472600 0.57951600 0.90228600 1 - O O63 1 0.29521000 0.47244000 0.37472600 1 - O O64 1 0.12527400 0.02756000 0.20479000 1 - O O65 1 0.59771400 0.92048400 0.12527400 1 - O O66 1 0.20479000 0.57951600 0.17723100 1 - O O67 1 0.17723100 0.20479000 0.57951600 1 - O O68 1 0.32276900 0.90228600 0.02756000 1 - O O69 1 0.02756000 0.32276900 0.90228600 1 - O O70 1 0.92048400 0.12527400 0.59771400 1 - O O71 1 0.47244000 0.59771400 0.17723100 1 - O O72 1 0.90228600 0.37472600 0.57951600 1 - O O73 1 0.92048400 0.29521000 0.32276900 1 - O O74 1 0.59771400 0.17723100 0.47244000 1 - O O75 1 0.57951600 0.90228600 0.37472600 1 - O O76 1 0.29521000 0.32276900 0.92048400 1 - O O77 1 0.20479000 0.12527400 0.02756000 1 - O O78 1 0.02756000 0.20479000 0.12527400 1 - O O79 1 0.82276900 0.79521000 0.42048400 1 -" -Zn3Ge3(MoO6)2,mvc-4440,Ia-3d,[],0.1264588520052028,{'tags': []},"Full Formula (Zn12 Ge12 Mo8 O48) -Reduced Formula: Zn3Ge3(MoO6)2 -abc : 10.749457 10.749457 10.749457 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 0.023 - 1 Zn 0.75 0.625 0.875 0.022 - 2 Zn 0.625 0.875 0.75 0.023 - 3 Zn 0.875 0.625 0.25 0.023 - 4 Zn 0.625 0.25 0.875 0.023 - 5 Zn 0.875 0.75 0.625 0.023 - 6 Zn 0.75 0.125 0.375 0.023 - 7 Zn 0.25 0.375 0.125 0.022 - 8 Zn 0.375 0.125 0.25 0.023 - 9 Zn 0.125 0.375 0.75 0.023 - 10 Zn 0.375 0.75 0.125 0.023 - 11 Zn 0.125 0.25 0.375 0.023 - 12 Ge 0.125 0.75 0.875 0.023 - 13 Ge 0.875 0.25 0.125 0.023 - 14 Ge 0.625 0.375 0.25 0.023 - 15 Ge 0.75 0.875 0.125 0.022 - 16 Ge 0.875 0.125 0.75 0.023 - 17 Ge 0.25 0.625 0.375 0.022 - 18 Ge 0.75 0.375 0.625 0.022 - 19 Ge 0.25 0.125 0.875 0.022 - 20 Ge 0.125 0.875 0.25 0.023 - 21 Ge 0.375 0.625 0.75 0.023 - 22 Ge 0.625 0.75 0.375 0.023 - 23 Ge 0.375 0.25 0.625 0.023 - 24 Mo 0.5 0.5 0.5 2.736 - 25 Mo 0.5 0 0.5 2.735 - 26 Mo 0 0.5 0.5 2.735 - 27 Mo 0.5 0.5 0 2.736 - 28 Mo 0 0 0.5 2.735 - 29 Mo 0 0.5 0 2.736 - 30 Mo 0.5 0 0 2.735 - 31 Mo 0 0 0 2.736 - 32 O 0.415731 0.812026 0.784327 0.005 - 33 O 0.868596 0.396295 0.084269 0.006 - 34 O 0.103705 0.972301 0.687974 0.006 - 35 O 0.527699 0.631404 0.715673 0.006 - 36 O 0.687974 0.084269 0.715673 0.006 - 37 O 0.631404 0.715673 0.527699 0.006 - 38 O 0.631404 0.415731 0.103705 0.006 - 39 O 0.715673 0.527699 0.631404 0.007 - 40 O 0.812026 0.527699 0.396295 0.006 - 41 O 0.972301 0.784327 0.868596 0.006 - 42 O 0.784327 0.868596 0.972301 0.007 - 43 O 0.715673 0.687974 0.084269 0.007 - 44 O 0.415731 0.103705 0.631404 0.005 - 45 O 0.396295 0.812026 0.527699 0.006 - 46 O 0.084269 0.715673 0.687974 0.005 - 47 O 0.103705 0.631404 0.415731 0.006 - 48 O 0.527699 0.396295 0.812026 0.006 - 49 O 0.084269 0.868596 0.396295 0.005 - 50 O 0.972301 0.687974 0.103705 0.006 - 51 O 0.187974 0.472301 0.603705 0.006 - 52 O 0.687974 0.103705 0.972301 0.006 - 53 O 0.784327 0.415731 0.812026 0.007 - 54 O 0.396295 0.084269 0.868596 0.006 - 55 O 0.868596 0.972301 0.784327 0.006 - 56 O 0.584269 0.187974 0.215673 0.005 - 57 O 0.131404 0.603705 0.915731 0.006 - 58 O 0.896295 0.027699 0.312026 0.006 - 59 O 0.472301 0.368596 0.284327 0.006 - 60 O 0.312026 0.915731 0.284327 0.006 - 61 O 0.368596 0.284327 0.472301 0.006 - 62 O 0.368596 0.584269 0.896295 0.006 - 63 O 0.284327 0.472301 0.368596 0.007 - 64 O 0.131404 0.027699 0.215673 0.006 - 65 O 0.603705 0.915731 0.131404 0.006 - 66 O 0.215673 0.584269 0.187974 0.007 - 67 O 0.187974 0.215673 0.584269 0.006 - 68 O 0.312026 0.896295 0.027699 0.006 - 69 O 0.027699 0.312026 0.896295 0.006 - 70 O 0.915731 0.131404 0.603705 0.005 - 71 O 0.472301 0.603705 0.187974 0.006 - 72 O 0.896295 0.368596 0.584269 0.006 - 73 O 0.915731 0.284327 0.312026 0.005 - 74 O 0.603705 0.187974 0.472301 0.006 - 75 O 0.584269 0.896295 0.368596 0.005 - 76 O 0.284327 0.312026 0.915731 0.007 - 77 O 0.215673 0.131404 0.027699 0.007 - 78 O 0.027699 0.215673 0.131404 0.006 - 79 O 0.812026 0.784327 0.415731 0.006","# generated using pymatgen -data_Zn3Ge3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.74945719 -_cell_length_b 10.74945719 -_cell_length_c 10.74945719 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Ge3(MoO6)2 -_chemical_formula_sum 'Zn12 Ge12 Mo8 O48' -_cell_volume 956.17572130 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Mo Mo24 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo25 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo26 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo27 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo28 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo29 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo30 1 0.50000000 0.00000000 0.00000000 1 - Mo Mo31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.41573100 0.81202600 0.78432700 1 - O O33 1 0.86859600 0.39629500 0.08426900 1 - O O34 1 0.10370500 0.97230100 0.68797400 1 - O O35 1 0.52769900 0.63140400 0.71567300 1 - O O36 1 0.68797400 0.08426900 0.71567300 1 - O O37 1 0.63140400 0.71567300 0.52769900 1 - O O38 1 0.63140400 0.41573100 0.10370500 1 - O O39 1 0.71567300 0.52769900 0.63140400 1 - O O40 1 0.81202600 0.52769900 0.39629500 1 - O O41 1 0.97230100 0.78432700 0.86859600 1 - O O42 1 0.78432700 0.86859600 0.97230100 1 - O O43 1 0.71567300 0.68797400 0.08426900 1 - O O44 1 0.41573100 0.10370500 0.63140400 1 - O O45 1 0.39629500 0.81202600 0.52769900 1 - O O46 1 0.08426900 0.71567300 0.68797400 1 - O O47 1 0.10370500 0.63140400 0.41573100 1 - O O48 1 0.52769900 0.39629500 0.81202600 1 - O O49 1 0.08426900 0.86859600 0.39629500 1 - O O50 1 0.97230100 0.68797400 0.10370500 1 - O O51 1 0.18797400 0.47230100 0.60370500 1 - O O52 1 0.68797400 0.10370500 0.97230100 1 - O O53 1 0.78432700 0.41573100 0.81202600 1 - O O54 1 0.39629500 0.08426900 0.86859600 1 - O O55 1 0.86859600 0.97230100 0.78432700 1 - O O56 1 0.58426900 0.18797400 0.21567300 1 - O O57 1 0.13140400 0.60370500 0.91573100 1 - O O58 1 0.89629500 0.02769900 0.31202600 1 - O O59 1 0.47230100 0.36859600 0.28432700 1 - O O60 1 0.31202600 0.91573100 0.28432700 1 - O O61 1 0.36859600 0.28432700 0.47230100 1 - O O62 1 0.36859600 0.58426900 0.89629500 1 - O O63 1 0.28432700 0.47230100 0.36859600 1 - O O64 1 0.13140400 0.02769900 0.21567300 1 - O O65 1 0.60370500 0.91573100 0.13140400 1 - O O66 1 0.21567300 0.58426900 0.18797400 1 - O O67 1 0.18797400 0.21567300 0.58426900 1 - O O68 1 0.31202600 0.89629500 0.02769900 1 - O O69 1 0.02769900 0.31202600 0.89629500 1 - O O70 1 0.91573100 0.13140400 0.60370500 1 - O O71 1 0.47230100 0.60370500 0.18797400 1 - O O72 1 0.89629500 0.36859600 0.58426900 1 - O O73 1 0.91573100 0.28432700 0.31202600 1 - O O74 1 0.60370500 0.18797400 0.47230100 1 - O O75 1 0.58426900 0.89629500 0.36859600 1 - O O76 1 0.28432700 0.31202600 0.91573100 1 - O O77 1 0.21567300 0.13140400 0.02769900 1 - O O78 1 0.02769900 0.21567300 0.13140400 1 - O O79 1 0.81202600 0.78432700 0.41573100 1 -" -Ca3Ni2(GeO4)3,mvc-4441,Ia-3d,[],0.04859179533334412,{'tags': []},"Full Formula (Ca12 Ni8 Ge12 O48) -Reduced Formula: Ca3Ni2(GeO4)3 -abc : 10.732620 10.732620 10.732620 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0.003 - 1 Ca 0.75 0.625 0.875 0.002 - 2 Ca 0.625 0.875 0.75 0.002 - 3 Ca 0.875 0.625 0.25 0.002 - 4 Ca 0.625 0.25 0.875 0.002 - 5 Ca 0.875 0.75 0.625 0.002 - 6 Ca 0.75 0.125 0.375 0.003 - 7 Ca 0.25 0.375 0.125 0.002 - 8 Ca 0.375 0.125 0.25 0.002 - 9 Ca 0.125 0.375 0.75 0.002 - 10 Ca 0.375 0.75 0.125 0.002 - 11 Ca 0.125 0.25 0.375 0.002 - 12 Ni 0.5 0.5 0.5 1.556 - 13 Ni 0.5 0 0.5 1.572 - 14 Ni 0 0.5 0.5 1.572 - 15 Ni 0.5 0.5 0 1.555 - 16 Ni 0 0 0.5 1.572 - 17 Ni 0 0.5 0 1.555 - 18 Ni 0.5 0 0 1.572 - 19 Ni 0 0 0 1.556 - 20 Ge 0.125 0.75 0.875 0.016 - 21 Ge 0.875 0.25 0.125 0.016 - 22 Ge 0.625 0.375 0.25 0.016 - 23 Ge 0.75 0.875 0.125 0.015 - 24 Ge 0.875 0.125 0.75 0.016 - 25 Ge 0.25 0.625 0.375 0.015 - 26 Ge 0.75 0.375 0.625 0.015 - 27 Ge 0.25 0.125 0.875 0.015 - 28 Ge 0.125 0.875 0.25 0.016 - 29 Ge 0.375 0.625 0.75 0.016 - 30 Ge 0.625 0.75 0.375 0.016 - 31 Ge 0.375 0.25 0.625 0.016 - 32 O 0.415971 0.81514 0.796574 -0.087 - 33 O 0.880604 0.39917 0.084029 -0.078 - 34 O 0.10083 0.981434 0.68486 -0.078 - 35 O 0.518566 0.619396 0.703426 -0.084 - 36 O 0.68486 0.084029 0.703426 -0.083 - 37 O 0.619396 0.703426 0.518566 -0.077 - 38 O 0.619396 0.415971 0.10083 -0.078 - 39 O 0.703426 0.518566 0.619396 -0.095 - 40 O 0.81514 0.518566 0.39917 -0.083 - 41 O 0.981434 0.796574 0.880604 -0.084 - 42 O 0.796574 0.880604 0.981434 -0.095 - 43 O 0.703426 0.68486 0.084029 -0.096 - 44 O 0.415971 0.10083 0.619396 -0.087 - 45 O 0.39917 0.81514 0.518566 -0.078 - 46 O 0.084029 0.703426 0.68486 -0.087 - 47 O 0.10083 0.619396 0.415971 -0.078 - 48 O 0.518566 0.39917 0.81514 -0.084 - 49 O 0.084029 0.880604 0.39917 -0.087 - 50 O 0.981434 0.68486 0.10083 -0.084 - 51 O 0.18486 0.481434 0.60083 -0.083 - 52 O 0.68486 0.10083 0.981434 -0.083 - 53 O 0.796574 0.415971 0.81514 -0.096 - 54 O 0.39917 0.084029 0.880604 -0.078 - 55 O 0.880604 0.981434 0.796574 -0.077 - 56 O 0.584029 0.18486 0.203426 -0.087 - 57 O 0.119396 0.60083 0.915971 -0.078 - 58 O 0.89917 0.018566 0.31514 -0.078 - 59 O 0.481434 0.380604 0.296574 -0.084 - 60 O 0.31514 0.915971 0.296574 -0.083 - 61 O 0.380604 0.296574 0.481434 -0.077 - 62 O 0.380604 0.584029 0.89917 -0.078 - 63 O 0.296574 0.481434 0.380604 -0.095 - 64 O 0.119396 0.018566 0.203426 -0.077 - 65 O 0.60083 0.915971 0.119396 -0.078 - 66 O 0.203426 0.584029 0.18486 -0.096 - 67 O 0.18486 0.203426 0.584029 -0.083 - 68 O 0.31514 0.89917 0.018566 -0.083 - 69 O 0.018566 0.31514 0.89917 -0.084 - 70 O 0.915971 0.119396 0.60083 -0.087 - 71 O 0.481434 0.60083 0.18486 -0.084 - 72 O 0.89917 0.380604 0.584029 -0.078 - 73 O 0.915971 0.296574 0.31514 -0.087 - 74 O 0.60083 0.18486 0.481434 -0.078 - 75 O 0.584029 0.89917 0.380604 -0.087 - 76 O 0.296574 0.31514 0.915971 -0.096 - 77 O 0.203426 0.119396 0.018566 -0.095 - 78 O 0.018566 0.203426 0.119396 -0.084 - 79 O 0.81514 0.796574 0.415971 -0.083","# generated using pymatgen -data_Ca3Ni2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.73261992 -_cell_length_b 10.73261992 -_cell_length_c 10.73261992 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ni2(GeO4)3 -_chemical_formula_sum 'Ca12 Ni8 Ge12 O48' -_cell_volume 951.68967683 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Ni Ni12 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni13 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni14 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni15 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni16 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni17 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni18 1 0.50000000 0.00000000 0.00000000 1 - Ni Ni19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41597100 0.81514000 0.79657400 1 - O O33 1 0.88060400 0.39917000 0.08402900 1 - O O34 1 0.10083000 0.98143400 0.68486000 1 - O O35 1 0.51856600 0.61939600 0.70342600 1 - O O36 1 0.68486000 0.08402900 0.70342600 1 - O O37 1 0.61939600 0.70342600 0.51856600 1 - O O38 1 0.61939600 0.41597100 0.10083000 1 - O O39 1 0.70342600 0.51856600 0.61939600 1 - O O40 1 0.81514000 0.51856600 0.39917000 1 - O O41 1 0.98143400 0.79657400 0.88060400 1 - O O42 1 0.79657400 0.88060400 0.98143400 1 - O O43 1 0.70342600 0.68486000 0.08402900 1 - O O44 1 0.41597100 0.10083000 0.61939600 1 - O O45 1 0.39917000 0.81514000 0.51856600 1 - O O46 1 0.08402900 0.70342600 0.68486000 1 - O O47 1 0.10083000 0.61939600 0.41597100 1 - O O48 1 0.51856600 0.39917000 0.81514000 1 - O O49 1 0.08402900 0.88060400 0.39917000 1 - O O50 1 0.98143400 0.68486000 0.10083000 1 - O O51 1 0.18486000 0.48143400 0.60083000 1 - O O52 1 0.68486000 0.10083000 0.98143400 1 - O O53 1 0.79657400 0.41597100 0.81514000 1 - O O54 1 0.39917000 0.08402900 0.88060400 1 - O O55 1 0.88060400 0.98143400 0.79657400 1 - O O56 1 0.58402900 0.18486000 0.20342600 1 - O O57 1 0.11939600 0.60083000 0.91597100 1 - O O58 1 0.89917000 0.01856600 0.31514000 1 - O O59 1 0.48143400 0.38060400 0.29657400 1 - O O60 1 0.31514000 0.91597100 0.29657400 1 - O O61 1 0.38060400 0.29657400 0.48143400 1 - O O62 1 0.38060400 0.58402900 0.89917000 1 - O O63 1 0.29657400 0.48143400 0.38060400 1 - O O64 1 0.11939600 0.01856600 0.20342600 1 - O O65 1 0.60083000 0.91597100 0.11939600 1 - O O66 1 0.20342600 0.58402900 0.18486000 1 - O O67 1 0.18486000 0.20342600 0.58402900 1 - O O68 1 0.31514000 0.89917000 0.01856600 1 - O O69 1 0.01856600 0.31514000 0.89917000 1 - O O70 1 0.91597100 0.11939600 0.60083000 1 - O O71 1 0.48143400 0.60083000 0.18486000 1 - O O72 1 0.89917000 0.38060400 0.58402900 1 - O O73 1 0.91597100 0.29657400 0.31514000 1 - O O74 1 0.60083000 0.18486000 0.48143400 1 - O O75 1 0.58402900 0.89917000 0.38060400 1 - O O76 1 0.29657400 0.31514000 0.91597100 1 - O O77 1 0.20342600 0.11939600 0.01856600 1 - O O78 1 0.01856600 0.20342600 0.11939600 1 - O O79 1 0.81514000 0.79657400 0.41597100 1 -" -Mg3Ge3(WO6)2,mvc-4445,Ia-3d,[],0.18848232974999934,{'tags': []},"Full Formula (Mg12 Ge12 W8 O48) -Reduced Formula: Mg3Ge3(WO6)2 -abc : 10.733768 10.733768 10.733768 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.004 - 1 Mg 0.75 0.625 0.875 0.004 - 2 Mg 0.625 0.875 0.75 0.005 - 3 Mg 0.875 0.625 0.25 0.005 - 4 Mg 0.625 0.25 0.875 0.005 - 5 Mg 0.875 0.75 0.625 0.005 - 6 Mg 0.75 0.125 0.375 0.004 - 7 Mg 0.25 0.375 0.125 0.004 - 8 Mg 0.375 0.125 0.25 0.005 - 9 Mg 0.125 0.375 0.75 0.005 - 10 Mg 0.375 0.75 0.125 0.005 - 11 Mg 0.125 0.25 0.375 0.005 - 12 Ge 0.125 0.75 0.875 0.027 - 13 Ge 0.875 0.25 0.125 0.027 - 14 Ge 0.625 0.375 0.25 0.027 - 15 Ge 0.75 0.875 0.125 0.027 - 16 Ge 0.875 0.125 0.75 0.027 - 17 Ge 0.25 0.625 0.375 0.027 - 18 Ge 0.75 0.375 0.625 0.027 - 19 Ge 0.25 0.125 0.875 0.027 - 20 Ge 0.125 0.875 0.25 0.027 - 21 Ge 0.375 0.625 0.75 0.027 - 22 Ge 0.625 0.75 0.375 0.027 - 23 Ge 0.375 0.25 0.625 0.027 - 24 W 0.5 0.5 0.5 2.734 - 25 W 0.5 0 0.5 2.735 - 26 W 0 0.5 0.5 2.735 - 27 W 0.5 0.5 0 2.734 - 28 W 0 0 0.5 2.735 - 29 W 0 0.5 0 2.734 - 30 W 0.5 0 0 2.735 - 31 W 0 0 0 2.734 - 32 O 0.412652 0.810868 0.780477 0.012 - 33 O 0.867825 0.398216 0.087348 0.012 - 34 O 0.101784 0.969609 0.689132 0.012 - 35 O 0.530391 0.632175 0.719523 0.013 - 36 O 0.689132 0.087348 0.719523 0.013 - 37 O 0.632175 0.719523 0.530391 0.012 - 38 O 0.632175 0.412652 0.101784 0.012 - 39 O 0.719523 0.530391 0.632175 0.013 - 40 O 0.810868 0.530391 0.398216 0.013 - 41 O 0.969609 0.780477 0.867825 0.013 - 42 O 0.780477 0.867825 0.969609 0.013 - 43 O 0.719523 0.689132 0.087348 0.013 - 44 O 0.412652 0.101784 0.632175 0.012 - 45 O 0.398216 0.810868 0.530391 0.012 - 46 O 0.087348 0.719523 0.689132 0.012 - 47 O 0.101784 0.632175 0.412652 0.012 - 48 O 0.530391 0.398216 0.810868 0.013 - 49 O 0.087348 0.867825 0.398216 0.012 - 50 O 0.969609 0.689132 0.101784 0.013 - 51 O 0.189132 0.469609 0.601784 0.013 - 52 O 0.689132 0.101784 0.969609 0.013 - 53 O 0.780477 0.412652 0.810868 0.013 - 54 O 0.398216 0.087348 0.867825 0.012 - 55 O 0.867825 0.969609 0.780477 0.012 - 56 O 0.587348 0.189132 0.219523 0.012 - 57 O 0.132175 0.601784 0.912652 0.012 - 58 O 0.898216 0.030391 0.310868 0.012 - 59 O 0.469609 0.367825 0.280477 0.013 - 60 O 0.310868 0.912652 0.280477 0.013 - 61 O 0.367825 0.280477 0.469609 0.012 - 62 O 0.367825 0.587348 0.898216 0.012 - 63 O 0.280477 0.469609 0.367825 0.013 - 64 O 0.132175 0.030391 0.219523 0.012 - 65 O 0.601784 0.912652 0.132175 0.012 - 66 O 0.219523 0.587348 0.189132 0.013 - 67 O 0.189132 0.219523 0.587348 0.013 - 68 O 0.310868 0.898216 0.030391 0.013 - 69 O 0.030391 0.310868 0.898216 0.013 - 70 O 0.912652 0.132175 0.601784 0.012 - 71 O 0.469609 0.601784 0.189132 0.013 - 72 O 0.898216 0.367825 0.587348 0.012 - 73 O 0.912652 0.280477 0.310868 0.012 - 74 O 0.601784 0.189132 0.469609 0.012 - 75 O 0.587348 0.898216 0.367825 0.012 - 76 O 0.280477 0.310868 0.912652 0.013 - 77 O 0.219523 0.132175 0.030391 0.013 - 78 O 0.030391 0.219523 0.132175 0.013 - 79 O 0.810868 0.780477 0.412652 0.013","# generated using pymatgen -data_Mg3Ge3(WO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.73376827 -_cell_length_b 10.73376827 -_cell_length_c 10.73376827 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ge3(WO6)2 -_chemical_formula_sum 'Mg12 Ge12 W8 O48' -_cell_volume 951.99519109 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - W W24 1 0.50000000 0.50000000 0.50000000 1 - W W25 1 0.50000000 0.00000000 0.50000000 1 - W W26 1 0.00000000 0.50000000 0.50000000 1 - W W27 1 0.50000000 0.50000000 0.00000000 1 - W W28 1 0.00000000 0.00000000 0.50000000 1 - W W29 1 0.00000000 0.50000000 0.00000000 1 - W W30 1 0.50000000 0.00000000 0.00000000 1 - W W31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.41265200 0.81086800 0.78047700 1 - O O33 1 0.86782500 0.39821600 0.08734800 1 - O O34 1 0.10178400 0.96960900 0.68913200 1 - O O35 1 0.53039100 0.63217500 0.71952300 1 - O O36 1 0.68913200 0.08734800 0.71952300 1 - O O37 1 0.63217500 0.71952300 0.53039100 1 - O O38 1 0.63217500 0.41265200 0.10178400 1 - O O39 1 0.71952300 0.53039100 0.63217500 1 - O O40 1 0.81086800 0.53039100 0.39821600 1 - O O41 1 0.96960900 0.78047700 0.86782500 1 - O O42 1 0.78047700 0.86782500 0.96960900 1 - O O43 1 0.71952300 0.68913200 0.08734800 1 - O O44 1 0.41265200 0.10178400 0.63217500 1 - O O45 1 0.39821600 0.81086800 0.53039100 1 - O O46 1 0.08734800 0.71952300 0.68913200 1 - O O47 1 0.10178400 0.63217500 0.41265200 1 - O O48 1 0.53039100 0.39821600 0.81086800 1 - O O49 1 0.08734800 0.86782500 0.39821600 1 - O O50 1 0.96960900 0.68913200 0.10178400 1 - O O51 1 0.18913200 0.46960900 0.60178400 1 - O O52 1 0.68913200 0.10178400 0.96960900 1 - O O53 1 0.78047700 0.41265200 0.81086800 1 - O O54 1 0.39821600 0.08734800 0.86782500 1 - O O55 1 0.86782500 0.96960900 0.78047700 1 - O O56 1 0.58734800 0.18913200 0.21952300 1 - O O57 1 0.13217500 0.60178400 0.91265200 1 - O O58 1 0.89821600 0.03039100 0.31086800 1 - O O59 1 0.46960900 0.36782500 0.28047700 1 - O O60 1 0.31086800 0.91265200 0.28047700 1 - O O61 1 0.36782500 0.28047700 0.46960900 1 - O O62 1 0.36782500 0.58734800 0.89821600 1 - O O63 1 0.28047700 0.46960900 0.36782500 1 - O O64 1 0.13217500 0.03039100 0.21952300 1 - O O65 1 0.60178400 0.91265200 0.13217500 1 - O O66 1 0.21952300 0.58734800 0.18913200 1 - O O67 1 0.18913200 0.21952300 0.58734800 1 - O O68 1 0.31086800 0.89821600 0.03039100 1 - O O69 1 0.03039100 0.31086800 0.89821600 1 - O O70 1 0.91265200 0.13217500 0.60178400 1 - O O71 1 0.46960900 0.60178400 0.18913200 1 - O O72 1 0.89821600 0.36782500 0.58734800 1 - O O73 1 0.91265200 0.28047700 0.31086800 1 - O O74 1 0.60178400 0.18913200 0.46960900 1 - O O75 1 0.58734800 0.89821600 0.36782500 1 - O O76 1 0.28047700 0.31086800 0.91265200 1 - O O77 1 0.21952300 0.13217500 0.03039100 1 - O O78 1 0.03039100 0.21952300 0.13217500 1 - O O79 1 0.81086800 0.78047700 0.41265200 1 -" -V2Zn3(GeO4)3,mvc-4466,Ia-3d,[],0.0921367329375018,{'tags': []},"Full Formula (V8 Zn12 Ge12 O48) -Reduced Formula: V2Zn3(GeO4)3 -abc : 10.550755 10.550755 10.550755 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 V 0.5 0.5 0.5 1.879 - 1 V 0.5 0 0.5 1.879 - 2 V 0 0.5 0.5 1.88 - 3 V 0.5 0.5 0 1.88 - 4 V 0 0 0.5 1.88 - 5 V 0 0.5 0 1.88 - 6 V 0.5 0 0 1.88 - 7 V 0 0 0 1.879 - 8 Zn 0.25 0.875 0.625 0.01 - 9 Zn 0.75 0.625 0.875 0.01 - 10 Zn 0.625 0.875 0.75 0.015 - 11 Zn 0.875 0.625 0.25 0.013 - 12 Zn 0.625 0.25 0.875 0.013 - 13 Zn 0.875 0.75 0.625 0.015 - 14 Zn 0.75 0.125 0.375 0.01 - 15 Zn 0.25 0.375 0.125 0.01 - 16 Zn 0.375 0.125 0.25 0.015 - 17 Zn 0.125 0.375 0.75 0.013 - 18 Zn 0.375 0.75 0.125 0.013 - 19 Zn 0.125 0.25 0.375 0.015 - 20 Ge 0.125 0.75 0.875 0.013 - 21 Ge 0.875 0.25 0.125 0.013 - 22 Ge 0.625 0.375 0.25 0.011 - 23 Ge 0.75 0.875 0.125 0.014 - 24 Ge 0.875 0.125 0.75 0.01 - 25 Ge 0.25 0.625 0.375 0.015 - 26 Ge 0.75 0.375 0.625 0.015 - 27 Ge 0.25 0.125 0.875 0.014 - 28 Ge 0.125 0.875 0.25 0.01 - 29 Ge 0.375 0.625 0.75 0.011 - 30 Ge 0.625 0.75 0.375 0.013 - 31 Ge 0.375 0.25 0.625 0.013 - 32 O 0.41879 0.817229 0.791764 -0.008 - 33 O 0.872975 0.39844 0.08121 -0.008 - 34 O 0.10156 0.974535 0.682771 -0.001 - 35 O 0.525465 0.627025 0.708236 -0.008 - 36 O 0.682771 0.08121 0.708236 0 - 37 O 0.627025 0.708236 0.525465 -0 - 38 O 0.627025 0.41879 0.10156 -0 - 39 O 0.708236 0.525465 0.627025 -0.008 - 40 O 0.817229 0.525465 0.39844 -0 - 41 O 0.974535 0.791764 0.872975 -0.008 - 42 O 0.791764 0.872975 0.974535 -0.009 - 43 O 0.708236 0.682771 0.08121 -0.009 - 44 O 0.41879 0.10156 0.627025 -0.008 - 45 O 0.39844 0.817229 0.525465 -0.009 - 46 O 0.08121 0.708236 0.682771 -0.009 - 47 O 0.10156 0.627025 0.41879 -0.008 - 48 O 0.525465 0.39844 0.817229 -0.008 - 49 O 0.08121 0.872975 0.39844 -0.008 - 50 O 0.974535 0.682771 0.10156 -0.002 - 51 O 0.182771 0.474535 0.60156 -0 - 52 O 0.682771 0.10156 0.974535 -0.001 - 53 O 0.791764 0.41879 0.817229 -0.008 - 54 O 0.39844 0.08121 0.872975 -0.008 - 55 O 0.872975 0.974535 0.791764 -0 - 56 O 0.58121 0.182771 0.208236 -0.008 - 57 O 0.127025 0.60156 0.91879 -0.008 - 58 O 0.89844 0.025465 0.317229 -0.001 - 59 O 0.474535 0.372975 0.291764 -0.008 - 60 O 0.317229 0.91879 0.291764 0 - 61 O 0.372975 0.291764 0.474535 -0 - 62 O 0.372975 0.58121 0.89844 -0 - 63 O 0.291764 0.474535 0.372975 -0.008 - 64 O 0.127025 0.025465 0.208236 -0 - 65 O 0.60156 0.91879 0.127025 -0.008 - 66 O 0.208236 0.58121 0.182771 -0.008 - 67 O 0.182771 0.208236 0.58121 -0.008 - 68 O 0.317229 0.89844 0.025465 -0.001 - 69 O 0.025465 0.317229 0.89844 -0.002 - 70 O 0.91879 0.127025 0.60156 -0.008 - 71 O 0.474535 0.60156 0.182771 -0.008 - 72 O 0.89844 0.372975 0.58121 -0.008 - 73 O 0.91879 0.291764 0.317229 -0.009 - 74 O 0.60156 0.182771 0.474535 -0.009 - 75 O 0.58121 0.89844 0.372975 -0.008 - 76 O 0.291764 0.317229 0.91879 -0.009 - 77 O 0.208236 0.127025 0.025465 -0.009 - 78 O 0.025465 0.208236 0.127025 -0.008 - 79 O 0.817229 0.791764 0.41879 -0.008","# generated using pymatgen -data_V2Zn3(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.55075459 -_cell_length_b 10.55075459 -_cell_length_c 10.55075459 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural V2Zn3(GeO4)3 -_chemical_formula_sum 'V8 Zn12 Ge12 O48' -_cell_volume 904.12540602 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - V V0 1 0.50000000 0.50000000 0.50000000 1 - V V1 1 0.50000000 0.00000000 0.50000000 1 - V V2 1 0.00000000 0.50000000 0.50000000 1 - V V3 1 0.50000000 0.50000000 0.00000000 1 - V V4 1 0.00000000 0.00000000 0.50000000 1 - V V5 1 0.00000000 0.50000000 0.00000000 1 - V V6 1 0.50000000 0.00000000 0.00000000 1 - V V7 1 0.00000000 0.00000000 0.00000000 1 - Zn Zn8 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn9 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn12 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn13 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn14 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn15 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn16 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn17 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn18 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn19 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41879000 0.81722900 0.79176400 1 - O O33 1 0.87297500 0.39844000 0.08121000 1 - O O34 1 0.10156000 0.97453500 0.68277100 1 - O O35 1 0.52546500 0.62702500 0.70823600 1 - O O36 1 0.68277100 0.08121000 0.70823600 1 - O O37 1 0.62702500 0.70823600 0.52546500 1 - O O38 1 0.62702500 0.41879000 0.10156000 1 - O O39 1 0.70823600 0.52546500 0.62702500 1 - O O40 1 0.81722900 0.52546500 0.39844000 1 - O O41 1 0.97453500 0.79176400 0.87297500 1 - O O42 1 0.79176400 0.87297500 0.97453500 1 - O O43 1 0.70823600 0.68277100 0.08121000 1 - O O44 1 0.41879000 0.10156000 0.62702500 1 - O O45 1 0.39844000 0.81722900 0.52546500 1 - O O46 1 0.08121000 0.70823600 0.68277100 1 - O O47 1 0.10156000 0.62702500 0.41879000 1 - O O48 1 0.52546500 0.39844000 0.81722900 1 - O O49 1 0.08121000 0.87297500 0.39844000 1 - O O50 1 0.97453500 0.68277100 0.10156000 1 - O O51 1 0.18277100 0.47453500 0.60156000 1 - O O52 1 0.68277100 0.10156000 0.97453500 1 - O O53 1 0.79176400 0.41879000 0.81722900 1 - O O54 1 0.39844000 0.08121000 0.87297500 1 - O O55 1 0.87297500 0.97453500 0.79176400 1 - O O56 1 0.58121000 0.18277100 0.20823600 1 - O O57 1 0.12702500 0.60156000 0.91879000 1 - O O58 1 0.89844000 0.02546500 0.31722900 1 - O O59 1 0.47453500 0.37297500 0.29176400 1 - O O60 1 0.31722900 0.91879000 0.29176400 1 - O O61 1 0.37297500 0.29176400 0.47453500 1 - O O62 1 0.37297500 0.58121000 0.89844000 1 - O O63 1 0.29176400 0.47453500 0.37297500 1 - O O64 1 0.12702500 0.02546500 0.20823600 1 - O O65 1 0.60156000 0.91879000 0.12702500 1 - O O66 1 0.20823600 0.58121000 0.18277100 1 - O O67 1 0.18277100 0.20823600 0.58121000 1 - O O68 1 0.31722900 0.89844000 0.02546500 1 - O O69 1 0.02546500 0.31722900 0.89844000 1 - O O70 1 0.91879000 0.12702500 0.60156000 1 - O O71 1 0.47453500 0.60156000 0.18277100 1 - O O72 1 0.89844000 0.37297500 0.58121000 1 - O O73 1 0.91879000 0.29176400 0.31722900 1 - O O74 1 0.60156000 0.18277100 0.47453500 1 - O O75 1 0.58121000 0.89844000 0.37297500 1 - O O76 1 0.29176400 0.31722900 0.91879000 1 - O O77 1 0.20823600 0.12702500 0.02546500 1 - O O78 1 0.02546500 0.20823600 0.12702500 1 - O O79 1 0.81722900 0.79176400 0.41879000 1 -" -Ca3Ge3(MoO6)2,mvc-4467,Ia-3d,[],0.0,{'tags': []},"Full Formula (Ca12 Ge12 Mo8 O48) -Reduced Formula: Ca3Ge3(MoO6)2 -abc : 11.030954 11.030954 11.030954 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.625 0.875 0.75 0 - 3 Ca 0.875 0.625 0.25 0 - 4 Ca 0.625 0.25 0.875 0 - 5 Ca 0.875 0.75 0.625 0 - 6 Ca 0.75 0.125 0.375 0 - 7 Ca 0.25 0.375 0.125 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.125 0.375 0.75 0 - 10 Ca 0.375 0.75 0.125 0 - 11 Ca 0.125 0.25 0.375 0 - 12 Ge 0.125 0.75 0.875 0.026 - 13 Ge 0.875 0.25 0.125 0.026 - 14 Ge 0.625 0.375 0.25 0.026 - 15 Ge 0.75 0.875 0.125 0.026 - 16 Ge 0.875 0.125 0.75 0.026 - 17 Ge 0.25 0.625 0.375 0.026 - 18 Ge 0.75 0.375 0.625 0.026 - 19 Ge 0.25 0.125 0.875 0.026 - 20 Ge 0.125 0.875 0.25 0.026 - 21 Ge 0.375 0.625 0.75 0.026 - 22 Ge 0.625 0.75 0.375 0.026 - 23 Ge 0.375 0.25 0.625 0.026 - 24 Mo 0.5 0.5 0.5 2.73 - 25 Mo 0.5 0 0.5 2.73 - 26 Mo 0 0.5 0.5 2.73 - 27 Mo 0.5 0.5 0 2.73 - 28 Mo 0 0 0.5 2.73 - 29 Mo 0 0.5 0 2.73 - 30 Mo 0.5 0 0 2.73 - 31 Mo 0 0 0 2.73 - 32 O 0.412051 0.808584 0.789279 0.014 - 33 O 0.877228 0.396533 0.087949 0.014 - 34 O 0.103467 0.980695 0.691416 0.015 - 35 O 0.519305 0.622772 0.710721 0.014 - 36 O 0.691416 0.087949 0.710721 0.016 - 37 O 0.622772 0.710721 0.519305 0.014 - 38 O 0.622772 0.412051 0.103467 0.014 - 39 O 0.710721 0.519305 0.622772 0.015 - 40 O 0.808584 0.519305 0.396533 0.016 - 41 O 0.980695 0.789279 0.877228 0.014 - 42 O 0.789279 0.877228 0.980695 0.015 - 43 O 0.710721 0.691416 0.087949 0.015 - 44 O 0.412051 0.103467 0.622772 0.014 - 45 O 0.396533 0.808584 0.519305 0.015 - 46 O 0.087949 0.710721 0.691416 0.014 - 47 O 0.103467 0.622772 0.412051 0.015 - 48 O 0.519305 0.396533 0.808584 0.014 - 49 O 0.087949 0.877228 0.396533 0.014 - 50 O 0.980695 0.691416 0.103467 0.014 - 51 O 0.191416 0.480695 0.603467 0.016 - 52 O 0.691416 0.103467 0.980695 0.016 - 53 O 0.789279 0.412051 0.808584 0.015 - 54 O 0.396533 0.087949 0.877228 0.015 - 55 O 0.877228 0.980695 0.789279 0.014 - 56 O 0.587949 0.191416 0.210721 0.014 - 57 O 0.122772 0.603467 0.912051 0.014 - 58 O 0.896533 0.019305 0.308584 0.015 - 59 O 0.480695 0.377228 0.289279 0.014 - 60 O 0.308584 0.912051 0.289279 0.016 - 61 O 0.377228 0.289279 0.480695 0.014 - 62 O 0.377228 0.587949 0.896533 0.014 - 63 O 0.289279 0.480695 0.377228 0.015 - 64 O 0.122772 0.019305 0.210721 0.014 - 65 O 0.603467 0.912051 0.122772 0.015 - 66 O 0.210721 0.587949 0.191416 0.015 - 67 O 0.191416 0.210721 0.587949 0.016 - 68 O 0.308584 0.896533 0.019305 0.016 - 69 O 0.019305 0.308584 0.896533 0.014 - 70 O 0.912051 0.122772 0.603467 0.014 - 71 O 0.480695 0.603467 0.191416 0.014 - 72 O 0.896533 0.377228 0.587949 0.015 - 73 O 0.912051 0.289279 0.308584 0.014 - 74 O 0.603467 0.191416 0.480695 0.015 - 75 O 0.587949 0.896533 0.377228 0.014 - 76 O 0.289279 0.308584 0.912051 0.015 - 77 O 0.210721 0.122772 0.019305 0.015 - 78 O 0.019305 0.210721 0.122772 0.014 - 79 O 0.808584 0.789279 0.412051 0.016","# generated using pymatgen -data_Ca3Ge3(MoO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.03095355 -_cell_length_b 11.03095355 -_cell_length_c 11.03095355 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ge3(MoO6)2 -_chemical_formula_sum 'Ca12 Ge12 Mo8 O48' -_cell_volume 1033.27822296 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - Mo Mo24 1 0.50000000 0.50000000 0.50000000 1 - Mo Mo25 1 0.50000000 0.00000000 0.50000000 1 - Mo Mo26 1 0.00000000 0.50000000 0.50000000 1 - Mo Mo27 1 0.50000000 0.50000000 0.00000000 1 - Mo Mo28 1 0.00000000 0.00000000 0.50000000 1 - Mo Mo29 1 0.00000000 0.50000000 0.00000000 1 - Mo Mo30 1 0.50000000 0.00000000 0.00000000 1 - Mo Mo31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.41205100 0.80858400 0.78927900 1 - O O33 1 0.87722800 0.39653300 0.08794900 1 - O O34 1 0.10346700 0.98069500 0.69141600 1 - O O35 1 0.51930500 0.62277200 0.71072100 1 - O O36 1 0.69141600 0.08794900 0.71072100 1 - O O37 1 0.62277200 0.71072100 0.51930500 1 - O O38 1 0.62277200 0.41205100 0.10346700 1 - O O39 1 0.71072100 0.51930500 0.62277200 1 - O O40 1 0.80858400 0.51930500 0.39653300 1 - O O41 1 0.98069500 0.78927900 0.87722800 1 - O O42 1 0.78927900 0.87722800 0.98069500 1 - O O43 1 0.71072100 0.69141600 0.08794900 1 - O O44 1 0.41205100 0.10346700 0.62277200 1 - O O45 1 0.39653300 0.80858400 0.51930500 1 - O O46 1 0.08794900 0.71072100 0.69141600 1 - O O47 1 0.10346700 0.62277200 0.41205100 1 - O O48 1 0.51930500 0.39653300 0.80858400 1 - O O49 1 0.08794900 0.87722800 0.39653300 1 - O O50 1 0.98069500 0.69141600 0.10346700 1 - O O51 1 0.19141600 0.48069500 0.60346700 1 - O O52 1 0.69141600 0.10346700 0.98069500 1 - O O53 1 0.78927900 0.41205100 0.80858400 1 - O O54 1 0.39653300 0.08794900 0.87722800 1 - O O55 1 0.87722800 0.98069500 0.78927900 1 - O O56 1 0.58794900 0.19141600 0.21072100 1 - O O57 1 0.12277200 0.60346700 0.91205100 1 - O O58 1 0.89653300 0.01930500 0.30858400 1 - O O59 1 0.48069500 0.37722800 0.28927900 1 - O O60 1 0.30858400 0.91205100 0.28927900 1 - O O61 1 0.37722800 0.28927900 0.48069500 1 - O O62 1 0.37722800 0.58794900 0.89653300 1 - O O63 1 0.28927900 0.48069500 0.37722800 1 - O O64 1 0.12277200 0.01930500 0.21072100 1 - O O65 1 0.60346700 0.91205100 0.12277200 1 - O O66 1 0.21072100 0.58794900 0.19141600 1 - O O67 1 0.19141600 0.21072100 0.58794900 1 - O O68 1 0.30858400 0.89653300 0.01930500 1 - O O69 1 0.01930500 0.30858400 0.89653300 1 - O O70 1 0.91205100 0.12277200 0.60346700 1 - O O71 1 0.48069500 0.60346700 0.19141600 1 - O O72 1 0.89653300 0.37722800 0.58794900 1 - O O73 1 0.91205100 0.28927900 0.30858400 1 - O O74 1 0.60346700 0.19141600 0.48069500 1 - O O75 1 0.58794900 0.89653300 0.37722800 1 - O O76 1 0.28927900 0.30858400 0.91205100 1 - O O77 1 0.21072100 0.12277200 0.01930500 1 - O O78 1 0.01930500 0.21072100 0.12277200 1 - O O79 1 0.80858400 0.78927900 0.41205100 1 -" -Ca3Ge3(WO6)2,mvc-4469,Ia-3d,[],0.021127019000001468,{'tags': []},"Full Formula (Ca12 Ge12 W8 O48) -Reduced Formula: Ca3Ge3(WO6)2 -abc : 11.057482 11.057482 11.057482 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0 - 1 Ca 0.75 0.625 0.875 0 - 2 Ca 0.625 0.875 0.75 0 - 3 Ca 0.875 0.625 0.25 0 - 4 Ca 0.625 0.25 0.875 0 - 5 Ca 0.875 0.75 0.625 0 - 6 Ca 0.75 0.125 0.375 0 - 7 Ca 0.25 0.375 0.125 0 - 8 Ca 0.375 0.125 0.25 0 - 9 Ca 0.125 0.375 0.75 0 - 10 Ca 0.375 0.75 0.125 0 - 11 Ca 0.125 0.25 0.375 0 - 12 Ge 0.125 0.75 0.875 0.03 - 13 Ge 0.875 0.25 0.125 0.03 - 14 Ge 0.625 0.375 0.25 0.03 - 15 Ge 0.75 0.875 0.125 0.03 - 16 Ge 0.875 0.125 0.75 0.03 - 17 Ge 0.25 0.625 0.375 0.03 - 18 Ge 0.75 0.375 0.625 0.03 - 19 Ge 0.25 0.125 0.875 0.03 - 20 Ge 0.125 0.875 0.25 0.03 - 21 Ge 0.375 0.625 0.75 0.03 - 22 Ge 0.625 0.75 0.375 0.03 - 23 Ge 0.375 0.25 0.625 0.03 - 24 W 0.5 0.5 0.5 2.725 - 25 W 0.5 0 0.5 2.725 - 26 W 0 0.5 0.5 2.725 - 27 W 0.5 0.5 0 2.725 - 28 W 0 0 0.5 2.725 - 29 W 0 0.5 0 2.725 - 30 W 0.5 0 0 2.725 - 31 W 0 0 0 2.725 - 32 O 0.411993 0.808153 0.788615 0.016 - 33 O 0.876622 0.396161 0.088007 0.016 - 34 O 0.103839 0.980461 0.691847 0.016 - 35 O 0.519539 0.623378 0.711385 0.016 - 36 O 0.691847 0.088007 0.711385 0.016 - 37 O 0.623378 0.711385 0.519539 0.016 - 38 O 0.623378 0.411993 0.103839 0.016 - 39 O 0.711385 0.519539 0.623378 0.016 - 40 O 0.808153 0.519539 0.396161 0.016 - 41 O 0.980461 0.788615 0.876622 0.016 - 42 O 0.788615 0.876622 0.980461 0.016 - 43 O 0.711385 0.691847 0.088007 0.016 - 44 O 0.411993 0.103839 0.623378 0.016 - 45 O 0.396161 0.808153 0.519539 0.016 - 46 O 0.088007 0.711385 0.691847 0.016 - 47 O 0.103839 0.623378 0.411993 0.016 - 48 O 0.519539 0.396161 0.808153 0.016 - 49 O 0.088007 0.876622 0.396161 0.016 - 50 O 0.980461 0.691847 0.103839 0.016 - 51 O 0.191847 0.480461 0.603839 0.016 - 52 O 0.691847 0.103839 0.980461 0.016 - 53 O 0.788615 0.411993 0.808153 0.016 - 54 O 0.396161 0.088007 0.876622 0.016 - 55 O 0.876622 0.980461 0.788615 0.016 - 56 O 0.588007 0.191847 0.211385 0.016 - 57 O 0.123378 0.603839 0.911993 0.016 - 58 O 0.896161 0.019539 0.308153 0.016 - 59 O 0.480461 0.376622 0.288615 0.016 - 60 O 0.308153 0.911993 0.288615 0.016 - 61 O 0.376622 0.288615 0.480461 0.016 - 62 O 0.376622 0.588007 0.896161 0.016 - 63 O 0.288615 0.480461 0.376622 0.016 - 64 O 0.123378 0.019539 0.211385 0.016 - 65 O 0.603839 0.911993 0.123378 0.016 - 66 O 0.211385 0.588007 0.191847 0.016 - 67 O 0.191847 0.211385 0.588007 0.016 - 68 O 0.308153 0.896161 0.019539 0.016 - 69 O 0.019539 0.308153 0.896161 0.016 - 70 O 0.911993 0.123378 0.603839 0.016 - 71 O 0.480461 0.603839 0.191847 0.016 - 72 O 0.896161 0.376622 0.588007 0.016 - 73 O 0.911993 0.288615 0.308153 0.016 - 74 O 0.603839 0.191847 0.480461 0.016 - 75 O 0.588007 0.896161 0.376622 0.016 - 76 O 0.288615 0.308153 0.911993 0.016 - 77 O 0.211385 0.123378 0.019539 0.016 - 78 O 0.019539 0.211385 0.123378 0.016 - 79 O 0.808153 0.788615 0.411993 0.016","# generated using pymatgen -data_Ca3Ge3(WO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.05748164 -_cell_length_b 11.05748164 -_cell_length_c 11.05748164 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Ge3(WO6)2 -_chemical_formula_sum 'Ca12 Ge12 W8 O48' -_cell_volume 1040.75088716 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - W W24 1 0.50000000 0.50000000 0.50000000 1 - W W25 1 0.50000000 0.00000000 0.50000000 1 - W W26 1 0.00000000 0.50000000 0.50000000 1 - W W27 1 0.50000000 0.50000000 0.00000000 1 - W W28 1 0.00000000 0.00000000 0.50000000 1 - W W29 1 0.00000000 0.50000000 0.00000000 1 - W W30 1 0.50000000 0.00000000 0.00000000 1 - W W31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.41199300 0.80815300 0.78861500 1 - O O33 1 0.87662200 0.39616100 0.08800700 1 - O O34 1 0.10383900 0.98046100 0.69184700 1 - O O35 1 0.51953900 0.62337800 0.71138500 1 - O O36 1 0.69184700 0.08800700 0.71138500 1 - O O37 1 0.62337800 0.71138500 0.51953900 1 - O O38 1 0.62337800 0.41199300 0.10383900 1 - O O39 1 0.71138500 0.51953900 0.62337800 1 - O O40 1 0.80815300 0.51953900 0.39616100 1 - O O41 1 0.98046100 0.78861500 0.87662200 1 - O O42 1 0.78861500 0.87662200 0.98046100 1 - O O43 1 0.71138500 0.69184700 0.08800700 1 - O O44 1 0.41199300 0.10383900 0.62337800 1 - O O45 1 0.39616100 0.80815300 0.51953900 1 - O O46 1 0.08800700 0.71138500 0.69184700 1 - O O47 1 0.10383900 0.62337800 0.41199300 1 - O O48 1 0.51953900 0.39616100 0.80815300 1 - O O49 1 0.08800700 0.87662200 0.39616100 1 - O O50 1 0.98046100 0.69184700 0.10383900 1 - O O51 1 0.19184700 0.48046100 0.60383900 1 - O O52 1 0.69184700 0.10383900 0.98046100 1 - O O53 1 0.78861500 0.41199300 0.80815300 1 - O O54 1 0.39616100 0.08800700 0.87662200 1 - O O55 1 0.87662200 0.98046100 0.78861500 1 - O O56 1 0.58800700 0.19184700 0.21138500 1 - O O57 1 0.12337800 0.60383900 0.91199300 1 - O O58 1 0.89616100 0.01953900 0.30815300 1 - O O59 1 0.48046100 0.37662200 0.28861500 1 - O O60 1 0.30815300 0.91199300 0.28861500 1 - O O61 1 0.37662200 0.28861500 0.48046100 1 - O O62 1 0.37662200 0.58800700 0.89616100 1 - O O63 1 0.28861500 0.48046100 0.37662200 1 - O O64 1 0.12337800 0.01953900 0.21138500 1 - O O65 1 0.60383900 0.91199300 0.12337800 1 - O O66 1 0.21138500 0.58800700 0.19184700 1 - O O67 1 0.19184700 0.21138500 0.58800700 1 - O O68 1 0.30815300 0.89616100 0.01953900 1 - O O69 1 0.01953900 0.30815300 0.89616100 1 - O O70 1 0.91199300 0.12337800 0.60383900 1 - O O71 1 0.48046100 0.60383900 0.19184700 1 - O O72 1 0.89616100 0.37662200 0.58800700 1 - O O73 1 0.91199300 0.28861500 0.30815300 1 - O O74 1 0.60383900 0.19184700 0.48046100 1 - O O75 1 0.58800700 0.89616100 0.37662200 1 - O O76 1 0.28861500 0.30815300 0.91199300 1 - O O77 1 0.21138500 0.12337800 0.01953900 1 - O O78 1 0.01953900 0.21138500 0.12337800 1 - O O79 1 0.80815300 0.78861500 0.41199300 1 -" -Mg3Ni2(GeO4)3,mvc-4482,Ia-3d,[],0.10284764562500737,{'tags': []},"Full Formula (Mg12 Ni8 Ge12 O48) -Reduced Formula: Mg3Ni2(GeO4)3 -abc : 10.359798 10.359798 10.359798 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.002 - 1 Mg 0.75 0.625 0.875 0.002 - 2 Mg 0.625 0.875 0.75 0.002 - 3 Mg 0.875 0.625 0.25 0.002 - 4 Mg 0.625 0.25 0.875 0.002 - 5 Mg 0.875 0.75 0.625 0.002 - 6 Mg 0.75 0.125 0.375 0.002 - 7 Mg 0.25 0.375 0.125 0.002 - 8 Mg 0.375 0.125 0.25 0.002 - 9 Mg 0.125 0.375 0.75 0.002 - 10 Mg 0.375 0.75 0.125 0.002 - 11 Mg 0.125 0.25 0.375 0.002 - 12 Ni 0.5 0.5 0.5 1.492 - 13 Ni 0.5 0 0.5 1.492 - 14 Ni 0 0.5 0.5 1.492 - 15 Ni 0.5 0.5 0 1.492 - 16 Ni 0 0 0.5 1.492 - 17 Ni 0 0.5 0 1.492 - 18 Ni 0.5 0 0 1.492 - 19 Ni 0 0 0 1.492 - 20 Ge 0.125 0.75 0.875 0.014 - 21 Ge 0.875 0.25 0.125 0.014 - 22 Ge 0.625 0.375 0.25 0.014 - 23 Ge 0.75 0.875 0.125 0.014 - 24 Ge 0.875 0.125 0.75 0.014 - 25 Ge 0.25 0.625 0.375 0.014 - 26 Ge 0.75 0.375 0.625 0.014 - 27 Ge 0.25 0.125 0.875 0.014 - 28 Ge 0.125 0.875 0.25 0.014 - 29 Ge 0.375 0.625 0.75 0.014 - 30 Ge 0.625 0.75 0.375 0.014 - 31 Ge 0.375 0.25 0.625 0.014 - 32 O 0.417793 0.819856 0.789303 -0.075 - 33 O 0.87151 0.402064 0.082207 -0.075 - 34 O 0.097936 0.969446 0.680144 -0.075 - 35 O 0.530554 0.62849 0.710697 -0.075 - 36 O 0.680144 0.082207 0.710697 -0.075 - 37 O 0.62849 0.710697 0.530554 -0.075 - 38 O 0.62849 0.417793 0.097936 -0.075 - 39 O 0.710697 0.530554 0.62849 -0.075 - 40 O 0.819856 0.530554 0.402064 -0.075 - 41 O 0.969446 0.789303 0.87151 -0.075 - 42 O 0.789303 0.87151 0.969446 -0.075 - 43 O 0.710697 0.680144 0.082207 -0.075 - 44 O 0.417793 0.097936 0.62849 -0.075 - 45 O 0.402064 0.819856 0.530554 -0.075 - 46 O 0.082207 0.710697 0.680144 -0.075 - 47 O 0.097936 0.62849 0.417793 -0.075 - 48 O 0.530554 0.402064 0.819856 -0.075 - 49 O 0.082207 0.87151 0.402064 -0.075 - 50 O 0.969446 0.680144 0.097936 -0.075 - 51 O 0.180144 0.469446 0.597936 -0.075 - 52 O 0.680144 0.097936 0.969446 -0.075 - 53 O 0.789303 0.417793 0.819856 -0.075 - 54 O 0.402064 0.082207 0.87151 -0.075 - 55 O 0.87151 0.969446 0.789303 -0.075 - 56 O 0.582207 0.180144 0.210697 -0.075 - 57 O 0.12849 0.597936 0.917793 -0.075 - 58 O 0.902064 0.030554 0.319856 -0.075 - 59 O 0.469446 0.37151 0.289303 -0.075 - 60 O 0.319856 0.917793 0.289303 -0.075 - 61 O 0.37151 0.289303 0.469446 -0.075 - 62 O 0.37151 0.582207 0.902064 -0.075 - 63 O 0.289303 0.469446 0.37151 -0.075 - 64 O 0.12849 0.030554 0.210697 -0.075 - 65 O 0.597936 0.917793 0.12849 -0.075 - 66 O 0.210697 0.582207 0.180144 -0.075 - 67 O 0.180144 0.210697 0.582207 -0.075 - 68 O 0.319856 0.902064 0.030554 -0.075 - 69 O 0.030554 0.319856 0.902064 -0.075 - 70 O 0.917793 0.12849 0.597936 -0.075 - 71 O 0.469446 0.597936 0.180144 -0.075 - 72 O 0.902064 0.37151 0.582207 -0.075 - 73 O 0.917793 0.289303 0.319856 -0.075 - 74 O 0.597936 0.180144 0.469446 -0.075 - 75 O 0.582207 0.902064 0.37151 -0.075 - 76 O 0.289303 0.319856 0.917793 -0.075 - 77 O 0.210697 0.12849 0.030554 -0.075 - 78 O 0.030554 0.210697 0.12849 -0.075 - 79 O 0.819856 0.789303 0.417793 -0.075","# generated using pymatgen -data_Mg3Ni2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.35979772 -_cell_length_b 10.35979772 -_cell_length_c 10.35979772 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Ni2(GeO4)3 -_chemical_formula_sum 'Mg12 Ni8 Ge12 O48' -_cell_volume 855.91755868 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Ni Ni12 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni13 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni14 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni15 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni16 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni17 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni18 1 0.50000000 0.00000000 0.00000000 1 - Ni Ni19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41779300 0.81985600 0.78930300 1 - O O33 1 0.87151000 0.40206400 0.08220700 1 - O O34 1 0.09793600 0.96944600 0.68014400 1 - O O35 1 0.53055400 0.62849000 0.71069700 1 - O O36 1 0.68014400 0.08220700 0.71069700 1 - O O37 1 0.62849000 0.71069700 0.53055400 1 - O O38 1 0.62849000 0.41779300 0.09793600 1 - O O39 1 0.71069700 0.53055400 0.62849000 1 - O O40 1 0.81985600 0.53055400 0.40206400 1 - O O41 1 0.96944600 0.78930300 0.87151000 1 - O O42 1 0.78930300 0.87151000 0.96944600 1 - O O43 1 0.71069700 0.68014400 0.08220700 1 - O O44 1 0.41779300 0.09793600 0.62849000 1 - O O45 1 0.40206400 0.81985600 0.53055400 1 - O O46 1 0.08220700 0.71069700 0.68014400 1 - O O47 1 0.09793600 0.62849000 0.41779300 1 - O O48 1 0.53055400 0.40206400 0.81985600 1 - O O49 1 0.08220700 0.87151000 0.40206400 1 - O O50 1 0.96944600 0.68014400 0.09793600 1 - O O51 1 0.18014400 0.46944600 0.59793600 1 - O O52 1 0.68014400 0.09793600 0.96944600 1 - O O53 1 0.78930300 0.41779300 0.81985600 1 - O O54 1 0.40206400 0.08220700 0.87151000 1 - O O55 1 0.87151000 0.96944600 0.78930300 1 - O O56 1 0.58220700 0.18014400 0.21069700 1 - O O57 1 0.12849000 0.59793600 0.91779300 1 - O O58 1 0.90206400 0.03055400 0.31985600 1 - O O59 1 0.46944600 0.37151000 0.28930300 1 - O O60 1 0.31985600 0.91779300 0.28930300 1 - O O61 1 0.37151000 0.28930300 0.46944600 1 - O O62 1 0.37151000 0.58220700 0.90206400 1 - O O63 1 0.28930300 0.46944600 0.37151000 1 - O O64 1 0.12849000 0.03055400 0.21069700 1 - O O65 1 0.59793600 0.91779300 0.12849000 1 - O O66 1 0.21069700 0.58220700 0.18014400 1 - O O67 1 0.18014400 0.21069700 0.58220700 1 - O O68 1 0.31985600 0.90206400 0.03055400 1 - O O69 1 0.03055400 0.31985600 0.90206400 1 - O O70 1 0.91779300 0.12849000 0.59793600 1 - O O71 1 0.46944600 0.59793600 0.18014400 1 - O O72 1 0.90206400 0.37151000 0.58220700 1 - O O73 1 0.91779300 0.28930300 0.31985600 1 - O O74 1 0.59793600 0.18014400 0.46944600 1 - O O75 1 0.58220700 0.90206400 0.37151000 1 - O O76 1 0.28930300 0.31985600 0.91779300 1 - O O77 1 0.21069700 0.12849000 0.03055400 1 - O O78 1 0.03055400 0.21069700 0.12849000 1 - O O79 1 0.81985600 0.78930300 0.41779300 1 -" -Zn3Ni2(GeO4)3,mvc-4492,Ia-3d,[],0.15192737904166442,{'tags': []},"Full Formula (Zn12 Ni8 Ge12 O48) -Reduced Formula: Zn3Ni2(GeO4)3 -abc : 10.391687 10.391687 10.391687 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 -0.001 - 1 Zn 0.75 0.625 0.875 -0.001 - 2 Zn 0.625 0.875 0.75 -0.001 - 3 Zn 0.875 0.625 0.25 -0.001 - 4 Zn 0.625 0.25 0.875 -0.001 - 5 Zn 0.875 0.75 0.625 -0.001 - 6 Zn 0.75 0.125 0.375 -0.001 - 7 Zn 0.25 0.375 0.125 -0.001 - 8 Zn 0.375 0.125 0.25 -0.001 - 9 Zn 0.125 0.375 0.75 -0.001 - 10 Zn 0.375 0.75 0.125 -0.001 - 11 Zn 0.125 0.25 0.375 -0.001 - 12 Ni 0.5 0.5 0.5 1.495 - 13 Ni 0.5 0 0.5 1.495 - 14 Ni 0 0.5 0.5 1.495 - 15 Ni 0.5 0.5 0 1.495 - 16 Ni 0 0 0.5 1.495 - 17 Ni 0 0.5 0 1.495 - 18 Ni 0.5 0 0 1.495 - 19 Ni 0 0 0 1.495 - 20 Ge 0.125 0.75 0.875 0.015 - 21 Ge 0.875 0.25 0.125 0.015 - 22 Ge 0.625 0.375 0.25 0.015 - 23 Ge 0.75 0.875 0.125 0.015 - 24 Ge 0.875 0.125 0.75 0.015 - 25 Ge 0.25 0.625 0.375 0.015 - 26 Ge 0.75 0.375 0.625 0.015 - 27 Ge 0.25 0.125 0.875 0.015 - 28 Ge 0.125 0.875 0.25 0.015 - 29 Ge 0.375 0.625 0.75 0.015 - 30 Ge 0.625 0.75 0.375 0.015 - 31 Ge 0.375 0.25 0.625 0.015 - 32 O 0.420055 0.819935 0.792249 -0.075 - 33 O 0.872194 0.39988 0.079945 -0.075 - 34 O 0.10012 0.972314 0.680065 -0.075 - 35 O 0.527686 0.627806 0.707751 -0.075 - 36 O 0.680065 0.079945 0.707751 -0.075 - 37 O 0.627806 0.707751 0.527686 -0.075 - 38 O 0.627806 0.420055 0.10012 -0.075 - 39 O 0.707751 0.527686 0.627806 -0.075 - 40 O 0.819935 0.527686 0.39988 -0.075 - 41 O 0.972314 0.792249 0.872194 -0.075 - 42 O 0.792249 0.872194 0.972314 -0.075 - 43 O 0.707751 0.680065 0.079945 -0.075 - 44 O 0.420055 0.10012 0.627806 -0.075 - 45 O 0.39988 0.819935 0.527686 -0.075 - 46 O 0.079945 0.707751 0.680065 -0.075 - 47 O 0.10012 0.627806 0.420055 -0.075 - 48 O 0.527686 0.39988 0.819935 -0.075 - 49 O 0.079945 0.872194 0.39988 -0.075 - 50 O 0.972314 0.680065 0.10012 -0.075 - 51 O 0.180065 0.472314 0.60012 -0.075 - 52 O 0.680065 0.10012 0.972314 -0.075 - 53 O 0.792249 0.420055 0.819935 -0.075 - 54 O 0.39988 0.079945 0.872194 -0.075 - 55 O 0.872194 0.972314 0.792249 -0.075 - 56 O 0.579945 0.180065 0.207751 -0.075 - 57 O 0.127806 0.60012 0.920055 -0.075 - 58 O 0.89988 0.027686 0.319935 -0.075 - 59 O 0.472314 0.372194 0.292249 -0.075 - 60 O 0.319935 0.920055 0.292249 -0.075 - 61 O 0.372194 0.292249 0.472314 -0.075 - 62 O 0.372194 0.579945 0.89988 -0.075 - 63 O 0.292249 0.472314 0.372194 -0.075 - 64 O 0.127806 0.027686 0.207751 -0.075 - 65 O 0.60012 0.920055 0.127806 -0.075 - 66 O 0.207751 0.579945 0.180065 -0.075 - 67 O 0.180065 0.207751 0.579945 -0.075 - 68 O 0.319935 0.89988 0.027686 -0.075 - 69 O 0.027686 0.319935 0.89988 -0.075 - 70 O 0.920055 0.127806 0.60012 -0.075 - 71 O 0.472314 0.60012 0.180065 -0.075 - 72 O 0.89988 0.372194 0.579945 -0.075 - 73 O 0.920055 0.292249 0.319935 -0.075 - 74 O 0.60012 0.180065 0.472314 -0.075 - 75 O 0.579945 0.89988 0.372194 -0.075 - 76 O 0.292249 0.319935 0.920055 -0.075 - 77 O 0.207751 0.127806 0.027686 -0.075 - 78 O 0.027686 0.207751 0.127806 -0.075 - 79 O 0.819935 0.792249 0.420055 -0.075","# generated using pymatgen -data_Zn3Ni2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.39168650 -_cell_length_b 10.39168650 -_cell_length_c 10.39168650 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Ni2(GeO4)3 -_chemical_formula_sum 'Zn12 Ni8 Ge12 O48' -_cell_volume 863.84578518 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Ni Ni12 1 0.50000000 0.50000000 0.50000000 1 - Ni Ni13 1 0.50000000 0.00000000 0.50000000 1 - Ni Ni14 1 0.00000000 0.50000000 0.50000000 1 - Ni Ni15 1 0.50000000 0.50000000 0.00000000 1 - Ni Ni16 1 0.00000000 0.00000000 0.50000000 1 - Ni Ni17 1 0.00000000 0.50000000 0.00000000 1 - Ni Ni18 1 0.50000000 0.00000000 0.00000000 1 - Ni Ni19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.42005500 0.81993500 0.79224900 1 - O O33 1 0.87219400 0.39988000 0.07994500 1 - O O34 1 0.10012000 0.97231400 0.68006500 1 - O O35 1 0.52768600 0.62780600 0.70775100 1 - O O36 1 0.68006500 0.07994500 0.70775100 1 - O O37 1 0.62780600 0.70775100 0.52768600 1 - O O38 1 0.62780600 0.42005500 0.10012000 1 - O O39 1 0.70775100 0.52768600 0.62780600 1 - O O40 1 0.81993500 0.52768600 0.39988000 1 - O O41 1 0.97231400 0.79224900 0.87219400 1 - O O42 1 0.79224900 0.87219400 0.97231400 1 - O O43 1 0.70775100 0.68006500 0.07994500 1 - O O44 1 0.42005500 0.10012000 0.62780600 1 - O O45 1 0.39988000 0.81993500 0.52768600 1 - O O46 1 0.07994500 0.70775100 0.68006500 1 - O O47 1 0.10012000 0.62780600 0.42005500 1 - O O48 1 0.52768600 0.39988000 0.81993500 1 - O O49 1 0.07994500 0.87219400 0.39988000 1 - O O50 1 0.97231400 0.68006500 0.10012000 1 - O O51 1 0.18006500 0.47231400 0.60012000 1 - O O52 1 0.68006500 0.10012000 0.97231400 1 - O O53 1 0.79224900 0.42005500 0.81993500 1 - O O54 1 0.39988000 0.07994500 0.87219400 1 - O O55 1 0.87219400 0.97231400 0.79224900 1 - O O56 1 0.57994500 0.18006500 0.20775100 1 - O O57 1 0.12780600 0.60012000 0.92005500 1 - O O58 1 0.89988000 0.02768600 0.31993500 1 - O O59 1 0.47231400 0.37219400 0.29224900 1 - O O60 1 0.31993500 0.92005500 0.29224900 1 - O O61 1 0.37219400 0.29224900 0.47231400 1 - O O62 1 0.37219400 0.57994500 0.89988000 1 - O O63 1 0.29224900 0.47231400 0.37219400 1 - O O64 1 0.12780600 0.02768600 0.20775100 1 - O O65 1 0.60012000 0.92005500 0.12780600 1 - O O66 1 0.20775100 0.57994500 0.18006500 1 - O O67 1 0.18006500 0.20775100 0.57994500 1 - O O68 1 0.31993500 0.89988000 0.02768600 1 - O O69 1 0.02768600 0.31993500 0.89988000 1 - O O70 1 0.92005500 0.12780600 0.60012000 1 - O O71 1 0.47231400 0.60012000 0.18006500 1 - O O72 1 0.89988000 0.37219400 0.57994500 1 - O O73 1 0.92005500 0.29224900 0.31993500 1 - O O74 1 0.60012000 0.18006500 0.47231400 1 - O O75 1 0.57994500 0.89988000 0.37219400 1 - O O76 1 0.29224900 0.31993500 0.92005500 1 - O O77 1 0.20775100 0.12780600 0.02768600 1 - O O78 1 0.02768600 0.20775100 0.12780600 1 - O O79 1 0.81993500 0.79224900 0.42005500 1 -" -Zn3Ge3(WO6)2,mvc-4501,Ia-3d,[],0.18629037749999977,{'tags': []},"Full Formula (Zn12 Ge12 W8 O48) -Reduced Formula: Zn3Ge3(WO6)2 -abc : 10.762120 10.762120 10.762120 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 0.027 - 1 Zn 0.75 0.625 0.875 0.027 - 2 Zn 0.625 0.875 0.75 0.027 - 3 Zn 0.875 0.625 0.25 0.027 - 4 Zn 0.625 0.25 0.875 0.027 - 5 Zn 0.875 0.75 0.625 0.027 - 6 Zn 0.75 0.125 0.375 0.027 - 7 Zn 0.25 0.375 0.125 0.027 - 8 Zn 0.375 0.125 0.25 0.027 - 9 Zn 0.125 0.375 0.75 0.027 - 10 Zn 0.375 0.75 0.125 0.027 - 11 Zn 0.125 0.25 0.375 0.027 - 12 Ge 0.125 0.75 0.875 0.026 - 13 Ge 0.875 0.25 0.125 0.026 - 14 Ge 0.625 0.375 0.25 0.025 - 15 Ge 0.75 0.875 0.125 0.026 - 16 Ge 0.875 0.125 0.75 0.025 - 17 Ge 0.25 0.625 0.375 0.025 - 18 Ge 0.75 0.375 0.625 0.026 - 19 Ge 0.25 0.125 0.875 0.026 - 20 Ge 0.125 0.875 0.25 0.025 - 21 Ge 0.375 0.625 0.75 0.025 - 22 Ge 0.625 0.75 0.375 0.026 - 23 Ge 0.375 0.25 0.625 0.026 - 24 W 0.5 0.5 0.5 2.725 - 25 W 0.5 0 0.5 2.725 - 26 W 0 0.5 0.5 2.725 - 27 W 0.5 0.5 0 2.725 - 28 W 0 0 0.5 2.725 - 29 W 0 0.5 0 2.725 - 30 W 0.5 0 0 2.725 - 31 W 0 0 0 2.725 - 32 O 0.414606 0.811495 0.783061 0.007 - 33 O 0.868454 0.396888 0.085394 0.007 - 34 O 0.103112 0.971566 0.688505 0.007 - 35 O 0.528434 0.631546 0.716939 0.007 - 36 O 0.688505 0.085394 0.716939 0.007 - 37 O 0.631546 0.716939 0.528434 0.007 - 38 O 0.631546 0.414606 0.103112 0.007 - 39 O 0.716939 0.528434 0.631546 0.007 - 40 O 0.811495 0.528434 0.396888 0.007 - 41 O 0.971566 0.783061 0.868454 0.007 - 42 O 0.783061 0.868454 0.971566 0.007 - 43 O 0.716939 0.688505 0.085394 0.007 - 44 O 0.414606 0.103112 0.631546 0.007 - 45 O 0.396888 0.811495 0.528434 0.007 - 46 O 0.085394 0.716939 0.688505 0.007 - 47 O 0.103112 0.631546 0.414606 0.007 - 48 O 0.528434 0.396888 0.811495 0.007 - 49 O 0.085394 0.868454 0.396888 0.007 - 50 O 0.971566 0.688505 0.103112 0.007 - 51 O 0.188505 0.471566 0.603112 0.007 - 52 O 0.688505 0.103112 0.971566 0.007 - 53 O 0.783061 0.414606 0.811495 0.007 - 54 O 0.396888 0.085394 0.868454 0.007 - 55 O 0.868454 0.971566 0.783061 0.007 - 56 O 0.585394 0.188505 0.216939 0.007 - 57 O 0.131546 0.603112 0.914606 0.007 - 58 O 0.896888 0.028434 0.311495 0.007 - 59 O 0.471566 0.368454 0.283061 0.007 - 60 O 0.311495 0.914606 0.283061 0.007 - 61 O 0.368454 0.283061 0.471566 0.007 - 62 O 0.368454 0.585394 0.896888 0.007 - 63 O 0.283061 0.471566 0.368454 0.007 - 64 O 0.131546 0.028434 0.216939 0.007 - 65 O 0.603112 0.914606 0.131546 0.007 - 66 O 0.216939 0.585394 0.188505 0.007 - 67 O 0.188505 0.216939 0.585394 0.007 - 68 O 0.311495 0.896888 0.028434 0.007 - 69 O 0.028434 0.311495 0.896888 0.007 - 70 O 0.914606 0.131546 0.603112 0.007 - 71 O 0.471566 0.603112 0.188505 0.007 - 72 O 0.896888 0.368454 0.585394 0.007 - 73 O 0.914606 0.283061 0.311495 0.007 - 74 O 0.603112 0.188505 0.471566 0.007 - 75 O 0.585394 0.896888 0.368454 0.007 - 76 O 0.283061 0.311495 0.914606 0.007 - 77 O 0.216939 0.131546 0.028434 0.007 - 78 O 0.028434 0.216939 0.131546 0.007 - 79 O 0.811495 0.783061 0.414606 0.007","# generated using pymatgen -data_Zn3Ge3(WO6)2 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.76212021 -_cell_length_b 10.76212021 -_cell_length_c 10.76212021 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Ge3(WO6)2 -_chemical_formula_sum 'Zn12 Ge12 W8 O48' -_cell_volume 959.55887204 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge12 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge13 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge14 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge15 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge16 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge17 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge18 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge19 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge20 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge21 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge22 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge23 1 0.37500000 0.25000000 0.62500000 1 - W W24 1 0.50000000 0.50000000 0.50000000 1 - W W25 1 0.50000000 0.00000000 0.50000000 1 - W W26 1 0.00000000 0.50000000 0.50000000 1 - W W27 1 0.50000000 0.50000000 0.00000000 1 - W W28 1 0.00000000 0.00000000 0.50000000 1 - W W29 1 0.00000000 0.50000000 0.00000000 1 - W W30 1 0.50000000 0.00000000 0.00000000 1 - W W31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.41460600 0.81149500 0.78306100 1 - O O33 1 0.86845400 0.39688800 0.08539400 1 - O O34 1 0.10311200 0.97156600 0.68850500 1 - O O35 1 0.52843400 0.63154600 0.71693900 1 - O O36 1 0.68850500 0.08539400 0.71693900 1 - O O37 1 0.63154600 0.71693900 0.52843400 1 - O O38 1 0.63154600 0.41460600 0.10311200 1 - O O39 1 0.71693900 0.52843400 0.63154600 1 - O O40 1 0.81149500 0.52843400 0.39688800 1 - O O41 1 0.97156600 0.78306100 0.86845400 1 - O O42 1 0.78306100 0.86845400 0.97156600 1 - O O43 1 0.71693900 0.68850500 0.08539400 1 - O O44 1 0.41460600 0.10311200 0.63154600 1 - O O45 1 0.39688800 0.81149500 0.52843400 1 - O O46 1 0.08539400 0.71693900 0.68850500 1 - O O47 1 0.10311200 0.63154600 0.41460600 1 - O O48 1 0.52843400 0.39688800 0.81149500 1 - O O49 1 0.08539400 0.86845400 0.39688800 1 - O O50 1 0.97156600 0.68850500 0.10311200 1 - O O51 1 0.18850500 0.47156600 0.60311200 1 - O O52 1 0.68850500 0.10311200 0.97156600 1 - O O53 1 0.78306100 0.41460600 0.81149500 1 - O O54 1 0.39688800 0.08539400 0.86845400 1 - O O55 1 0.86845400 0.97156600 0.78306100 1 - O O56 1 0.58539400 0.18850500 0.21693900 1 - O O57 1 0.13154600 0.60311200 0.91460600 1 - O O58 1 0.89688800 0.02843400 0.31149500 1 - O O59 1 0.47156600 0.36845400 0.28306100 1 - O O60 1 0.31149500 0.91460600 0.28306100 1 - O O61 1 0.36845400 0.28306100 0.47156600 1 - O O62 1 0.36845400 0.58539400 0.89688800 1 - O O63 1 0.28306100 0.47156600 0.36845400 1 - O O64 1 0.13154600 0.02843400 0.21693900 1 - O O65 1 0.60311200 0.91460600 0.13154600 1 - O O66 1 0.21693900 0.58539400 0.18850500 1 - O O67 1 0.18850500 0.21693900 0.58539400 1 - O O68 1 0.31149500 0.89688800 0.02843400 1 - O O69 1 0.02843400 0.31149500 0.89688800 1 - O O70 1 0.91460600 0.13154600 0.60311200 1 - O O71 1 0.47156600 0.60311200 0.18850500 1 - O O72 1 0.89688800 0.36845400 0.58539400 1 - O O73 1 0.91460600 0.28306100 0.31149500 1 - O O74 1 0.60311200 0.18850500 0.47156600 1 - O O75 1 0.58539400 0.89688800 0.36845400 1 - O O76 1 0.28306100 0.31149500 0.91460600 1 - O O77 1 0.21693900 0.13154600 0.02843400 1 - O O78 1 0.02843400 0.21693900 0.13154600 1 - O O79 1 0.81149500 0.78306100 0.41460600 1 -" -Mg3Cr2(GeO4)3,mvc-4503,Ia-3d,[],0.6720357264583363,{'tags': []},"Full Formula (Mg12 Cr8 Ge12 O48) -Reduced Formula: Mg3Cr2(GeO4)3 -abc : 10.442619 10.442619 10.442619 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.004 - 1 Mg 0.75 0.625 0.875 0.004 - 2 Mg 0.625 0.875 0.75 0.004 - 3 Mg 0.875 0.625 0.25 0.004 - 4 Mg 0.625 0.25 0.875 0.004 - 5 Mg 0.875 0.75 0.625 0.004 - 6 Mg 0.75 0.125 0.375 0.004 - 7 Mg 0.25 0.375 0.125 0.004 - 8 Mg 0.375 0.125 0.25 0.004 - 9 Mg 0.125 0.375 0.75 0.004 - 10 Mg 0.375 0.75 0.125 0.004 - 11 Mg 0.125 0.25 0.375 0.004 - 12 Cr 0.5 0.5 0.5 2.945 - 13 Cr 0.5 0 0.5 2.945 - 14 Cr 0 0.5 0.5 2.945 - 15 Cr 0.5 0.5 0 2.945 - 16 Cr 0 0 0.5 2.945 - 17 Cr 0 0.5 0 2.945 - 18 Cr 0.5 0 0 2.945 - 19 Cr 0 0 0 2.945 - 20 Ge 0.125 0.75 0.875 0.012 - 21 Ge 0.875 0.25 0.125 0.012 - 22 Ge 0.625 0.375 0.25 0.012 - 23 Ge 0.75 0.875 0.125 0.012 - 24 Ge 0.875 0.125 0.75 0.012 - 25 Ge 0.25 0.625 0.375 0.012 - 26 Ge 0.75 0.375 0.625 0.012 - 27 Ge 0.25 0.125 0.875 0.012 - 28 Ge 0.125 0.875 0.25 0.012 - 29 Ge 0.375 0.625 0.75 0.012 - 30 Ge 0.625 0.75 0.375 0.012 - 31 Ge 0.375 0.25 0.625 0.012 - 32 O 0.418188 0.818245 0.790716 -0.009 - 33 O 0.872527 0.400056 0.081812 -0.009 - 34 O 0.099944 0.972471 0.681755 -0.009 - 35 O 0.527529 0.627473 0.709284 -0.009 - 36 O 0.681755 0.081812 0.709284 -0.009 - 37 O 0.627473 0.709284 0.527529 -0.009 - 38 O 0.627473 0.418188 0.099944 -0.009 - 39 O 0.709284 0.527529 0.627473 -0.009 - 40 O 0.818245 0.527529 0.400056 -0.009 - 41 O 0.972471 0.790716 0.872527 -0.009 - 42 O 0.790716 0.872527 0.972471 -0.009 - 43 O 0.709284 0.681755 0.081812 -0.009 - 44 O 0.418188 0.099944 0.627473 -0.009 - 45 O 0.400056 0.818245 0.527529 -0.009 - 46 O 0.081812 0.709284 0.681755 -0.009 - 47 O 0.099944 0.627473 0.418188 -0.009 - 48 O 0.527529 0.400056 0.818245 -0.009 - 49 O 0.081812 0.872527 0.400056 -0.009 - 50 O 0.972471 0.681755 0.099944 -0.009 - 51 O 0.181755 0.472471 0.599944 -0.009 - 52 O 0.681755 0.099944 0.972471 -0.009 - 53 O 0.790716 0.418188 0.818245 -0.009 - 54 O 0.400056 0.081812 0.872527 -0.009 - 55 O 0.872527 0.972471 0.790716 -0.009 - 56 O 0.581812 0.181755 0.209284 -0.009 - 57 O 0.127473 0.599944 0.918188 -0.009 - 58 O 0.900056 0.027529 0.318245 -0.009 - 59 O 0.472471 0.372527 0.290716 -0.009 - 60 O 0.318245 0.918188 0.290716 -0.009 - 61 O 0.372527 0.290716 0.472471 -0.009 - 62 O 0.372527 0.581812 0.900056 -0.009 - 63 O 0.290716 0.472471 0.372527 -0.009 - 64 O 0.127473 0.027529 0.209284 -0.009 - 65 O 0.599944 0.918188 0.127473 -0.009 - 66 O 0.209284 0.581812 0.181755 -0.009 - 67 O 0.181755 0.209284 0.581812 -0.009 - 68 O 0.318245 0.900056 0.027529 -0.009 - 69 O 0.027529 0.318245 0.900056 -0.009 - 70 O 0.918188 0.127473 0.599944 -0.009 - 71 O 0.472471 0.599944 0.181755 -0.009 - 72 O 0.900056 0.372527 0.581812 -0.009 - 73 O 0.918188 0.290716 0.318245 -0.009 - 74 O 0.599944 0.181755 0.472471 -0.009 - 75 O 0.581812 0.900056 0.372527 -0.009 - 76 O 0.290716 0.318245 0.918188 -0.009 - 77 O 0.209284 0.127473 0.027529 -0.009 - 78 O 0.027529 0.209284 0.127473 -0.009 - 79 O 0.818245 0.790716 0.418188 -0.009","# generated using pymatgen -data_Mg3Cr2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.44261919 -_cell_length_b 10.44261919 -_cell_length_c 10.44261919 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Cr2(GeO4)3 -_chemical_formula_sum 'Mg12 Cr8 Ge12 O48' -_cell_volume 876.61002285 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Cr Cr12 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr13 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr16 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr18 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41818800 0.81824500 0.79071600 1 - O O33 1 0.87252700 0.40005600 0.08181200 1 - O O34 1 0.09994400 0.97247100 0.68175500 1 - O O35 1 0.52752900 0.62747300 0.70928400 1 - O O36 1 0.68175500 0.08181200 0.70928400 1 - O O37 1 0.62747300 0.70928400 0.52752900 1 - O O38 1 0.62747300 0.41818800 0.09994400 1 - O O39 1 0.70928400 0.52752900 0.62747300 1 - O O40 1 0.81824500 0.52752900 0.40005600 1 - O O41 1 0.97247100 0.79071600 0.87252700 1 - O O42 1 0.79071600 0.87252700 0.97247100 1 - O O43 1 0.70928400 0.68175500 0.08181200 1 - O O44 1 0.41818800 0.09994400 0.62747300 1 - O O45 1 0.40005600 0.81824500 0.52752900 1 - O O46 1 0.08181200 0.70928400 0.68175500 1 - O O47 1 0.09994400 0.62747300 0.41818800 1 - O O48 1 0.52752900 0.40005600 0.81824500 1 - O O49 1 0.08181200 0.87252700 0.40005600 1 - O O50 1 0.97247100 0.68175500 0.09994400 1 - O O51 1 0.18175500 0.47247100 0.59994400 1 - O O52 1 0.68175500 0.09994400 0.97247100 1 - O O53 1 0.79071600 0.41818800 0.81824500 1 - O O54 1 0.40005600 0.08181200 0.87252700 1 - O O55 1 0.87252700 0.97247100 0.79071600 1 - O O56 1 0.58181200 0.18175500 0.20928400 1 - O O57 1 0.12747300 0.59994400 0.91818800 1 - O O58 1 0.90005600 0.02752900 0.31824500 1 - O O59 1 0.47247100 0.37252700 0.29071600 1 - O O60 1 0.31824500 0.91818800 0.29071600 1 - O O61 1 0.37252700 0.29071600 0.47247100 1 - O O62 1 0.37252700 0.58181200 0.90005600 1 - O O63 1 0.29071600 0.47247100 0.37252700 1 - O O64 1 0.12747300 0.02752900 0.20928400 1 - O O65 1 0.59994400 0.91818800 0.12747300 1 - O O66 1 0.20928400 0.58181200 0.18175500 1 - O O67 1 0.18175500 0.20928400 0.58181200 1 - O O68 1 0.31824500 0.90005600 0.02752900 1 - O O69 1 0.02752900 0.31824500 0.90005600 1 - O O70 1 0.91818800 0.12747300 0.59994400 1 - O O71 1 0.47247100 0.59994400 0.18175500 1 - O O72 1 0.90005600 0.37252700 0.58181200 1 - O O73 1 0.91818800 0.29071600 0.31824500 1 - O O74 1 0.59994400 0.18175500 0.47247100 1 - O O75 1 0.58181200 0.90005600 0.37252700 1 - O O76 1 0.29071600 0.31824500 0.91818800 1 - O O77 1 0.20928400 0.12747300 0.02752900 1 - O O78 1 0.02752900 0.20928400 0.12747300 1 - O O79 1 0.81824500 0.79071600 0.41818800 1 -" -Zn3Cr2(GeO4)3,mvc-4588,Ia-3d,[],0.0987092689166662,{'tags': []},"Full Formula (Zn12 Cr8 Ge12 O48) -Reduced Formula: Zn3Cr2(GeO4)3 -abc : 10.480574 10.480574 10.480574 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 0.014 - 1 Zn 0.75 0.625 0.875 0.014 - 2 Zn 0.625 0.875 0.75 0.014 - 3 Zn 0.875 0.625 0.25 0.014 - 4 Zn 0.625 0.25 0.875 0.014 - 5 Zn 0.875 0.75 0.625 0.014 - 6 Zn 0.75 0.125 0.375 0.014 - 7 Zn 0.25 0.375 0.125 0.014 - 8 Zn 0.375 0.125 0.25 0.014 - 9 Zn 0.125 0.375 0.75 0.014 - 10 Zn 0.375 0.75 0.125 0.014 - 11 Zn 0.125 0.25 0.375 0.014 - 12 Cr 0.5 0.5 0.5 2.944 - 13 Cr 0.5 0 0.5 2.944 - 14 Cr 0 0.5 0.5 2.944 - 15 Cr 0.5 0.5 0 2.944 - 16 Cr 0 0 0.5 2.944 - 17 Cr 0 0.5 0 2.944 - 18 Cr 0.5 0 0 2.944 - 19 Cr 0 0 0 2.944 - 20 Ge 0.125 0.75 0.875 0.012 - 21 Ge 0.875 0.25 0.125 0.012 - 22 Ge 0.625 0.375 0.25 0.012 - 23 Ge 0.75 0.875 0.125 0.012 - 24 Ge 0.875 0.125 0.75 0.012 - 25 Ge 0.25 0.625 0.375 0.012 - 26 Ge 0.75 0.375 0.625 0.012 - 27 Ge 0.25 0.125 0.875 0.012 - 28 Ge 0.125 0.875 0.25 0.012 - 29 Ge 0.375 0.625 0.75 0.012 - 30 Ge 0.625 0.75 0.375 0.012 - 31 Ge 0.375 0.25 0.625 0.012 - 32 O 0.419563 0.818466 0.79271 -0.012 - 33 O 0.873147 0.398904 0.080437 -0.012 - 34 O 0.101096 0.974244 0.681534 -0.012 - 35 O 0.525756 0.626853 0.70729 -0.012 - 36 O 0.681534 0.080437 0.70729 -0.012 - 37 O 0.626853 0.70729 0.525756 -0.012 - 38 O 0.626853 0.419563 0.101096 -0.012 - 39 O 0.70729 0.525756 0.626853 -0.012 - 40 O 0.818466 0.525756 0.398904 -0.012 - 41 O 0.974244 0.79271 0.873147 -0.012 - 42 O 0.79271 0.873147 0.974244 -0.012 - 43 O 0.70729 0.681534 0.080437 -0.012 - 44 O 0.419563 0.101096 0.626853 -0.012 - 45 O 0.398904 0.818466 0.525756 -0.012 - 46 O 0.080437 0.70729 0.681534 -0.012 - 47 O 0.101096 0.626853 0.419563 -0.012 - 48 O 0.525756 0.398904 0.818466 -0.012 - 49 O 0.080437 0.873147 0.398904 -0.012 - 50 O 0.974244 0.681534 0.101096 -0.012 - 51 O 0.181534 0.474244 0.601096 -0.012 - 52 O 0.681534 0.101096 0.974244 -0.012 - 53 O 0.79271 0.419563 0.818466 -0.012 - 54 O 0.398904 0.080437 0.873147 -0.012 - 55 O 0.873147 0.974244 0.79271 -0.012 - 56 O 0.580437 0.181534 0.20729 -0.012 - 57 O 0.126853 0.601096 0.919563 -0.012 - 58 O 0.898904 0.025756 0.318466 -0.012 - 59 O 0.474244 0.373147 0.29271 -0.012 - 60 O 0.318466 0.919563 0.29271 -0.012 - 61 O 0.373147 0.29271 0.474244 -0.012 - 62 O 0.373147 0.580437 0.898904 -0.012 - 63 O 0.29271 0.474244 0.373147 -0.012 - 64 O 0.126853 0.025756 0.20729 -0.012 - 65 O 0.601096 0.919563 0.126853 -0.012 - 66 O 0.20729 0.580437 0.181534 -0.012 - 67 O 0.181534 0.20729 0.580437 -0.012 - 68 O 0.318466 0.898904 0.025756 -0.012 - 69 O 0.025756 0.318466 0.898904 -0.012 - 70 O 0.919563 0.126853 0.601096 -0.012 - 71 O 0.474244 0.601096 0.181534 -0.012 - 72 O 0.898904 0.373147 0.580437 -0.012 - 73 O 0.919563 0.29271 0.318466 -0.012 - 74 O 0.601096 0.181534 0.474244 -0.012 - 75 O 0.580437 0.898904 0.373147 -0.012 - 76 O 0.29271 0.318466 0.919563 -0.012 - 77 O 0.20729 0.126853 0.025756 -0.012 - 78 O 0.025756 0.20729 0.126853 -0.012 - 79 O 0.818466 0.79271 0.419563 -0.012","# generated using pymatgen -data_Zn3Cr2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.48057362 -_cell_length_b 10.48057362 -_cell_length_c 10.48057362 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Cr2(GeO4)3 -_chemical_formula_sum 'Zn12 Cr8 Ge12 O48' -_cell_volume 886.20310645 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Cr Cr12 1 0.50000000 0.50000000 0.50000000 1 - Cr Cr13 1 0.50000000 0.00000000 0.50000000 1 - Cr Cr14 1 0.00000000 0.50000000 0.50000000 1 - Cr Cr15 1 0.50000000 0.50000000 0.00000000 1 - Cr Cr16 1 0.00000000 0.00000000 0.50000000 1 - Cr Cr17 1 0.00000000 0.50000000 0.00000000 1 - Cr Cr18 1 0.50000000 0.00000000 0.00000000 1 - Cr Cr19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41956300 0.81846600 0.79271000 1 - O O33 1 0.87314700 0.39890400 0.08043700 1 - O O34 1 0.10109600 0.97424400 0.68153400 1 - O O35 1 0.52575600 0.62685300 0.70729000 1 - O O36 1 0.68153400 0.08043700 0.70729000 1 - O O37 1 0.62685300 0.70729000 0.52575600 1 - O O38 1 0.62685300 0.41956300 0.10109600 1 - O O39 1 0.70729000 0.52575600 0.62685300 1 - O O40 1 0.81846600 0.52575600 0.39890400 1 - O O41 1 0.97424400 0.79271000 0.87314700 1 - O O42 1 0.79271000 0.87314700 0.97424400 1 - O O43 1 0.70729000 0.68153400 0.08043700 1 - O O44 1 0.41956300 0.10109600 0.62685300 1 - O O45 1 0.39890400 0.81846600 0.52575600 1 - O O46 1 0.08043700 0.70729000 0.68153400 1 - O O47 1 0.10109600 0.62685300 0.41956300 1 - O O48 1 0.52575600 0.39890400 0.81846600 1 - O O49 1 0.08043700 0.87314700 0.39890400 1 - O O50 1 0.97424400 0.68153400 0.10109600 1 - O O51 1 0.18153400 0.47424400 0.60109600 1 - O O52 1 0.68153400 0.10109600 0.97424400 1 - O O53 1 0.79271000 0.41956300 0.81846600 1 - O O54 1 0.39890400 0.08043700 0.87314700 1 - O O55 1 0.87314700 0.97424400 0.79271000 1 - O O56 1 0.58043700 0.18153400 0.20729000 1 - O O57 1 0.12685300 0.60109600 0.91956300 1 - O O58 1 0.89890400 0.02575600 0.31846600 1 - O O59 1 0.47424400 0.37314700 0.29271000 1 - O O60 1 0.31846600 0.91956300 0.29271000 1 - O O61 1 0.37314700 0.29271000 0.47424400 1 - O O62 1 0.37314700 0.58043700 0.89890400 1 - O O63 1 0.29271000 0.47424400 0.37314700 1 - O O64 1 0.12685300 0.02575600 0.20729000 1 - O O65 1 0.60109600 0.91956300 0.12685300 1 - O O66 1 0.20729000 0.58043700 0.18153400 1 - O O67 1 0.18153400 0.20729000 0.58043700 1 - O O68 1 0.31846600 0.89890400 0.02575600 1 - O O69 1 0.02575600 0.31846600 0.89890400 1 - O O70 1 0.91956300 0.12685300 0.60109600 1 - O O71 1 0.47424400 0.60109600 0.18153400 1 - O O72 1 0.89890400 0.37314700 0.58043700 1 - O O73 1 0.91956300 0.29271000 0.31846600 1 - O O74 1 0.60109600 0.18153400 0.47424400 1 - O O75 1 0.58043700 0.89890400 0.37314700 1 - O O76 1 0.29271000 0.31846600 0.91956300 1 - O O77 1 0.20729000 0.12685300 0.02575600 1 - O O78 1 0.02575600 0.20729000 0.12685300 1 - O O79 1 0.81846600 0.79271000 0.41956300 1 -" -Mg3Fe2(GeO4)3,mvc-4828,Ia-3d,[],0.06323790237499871,{'tags': []},"Full Formula (Mg12 Fe8 Ge12 O48) -Reduced Formula: Mg3Fe2(GeO4)3 -abc : 10.488034 10.488034 10.488034 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.002 - 1 Mg 0.75 0.625 0.875 0.002 - 2 Mg 0.625 0.875 0.75 0.002 - 3 Mg 0.875 0.625 0.25 0.002 - 4 Mg 0.625 0.25 0.875 0.002 - 5 Mg 0.875 0.75 0.625 0.002 - 6 Mg 0.75 0.125 0.375 0.002 - 7 Mg 0.25 0.375 0.125 0.002 - 8 Mg 0.375 0.125 0.25 0.002 - 9 Mg 0.125 0.375 0.75 0.002 - 10 Mg 0.375 0.75 0.125 0.002 - 11 Mg 0.125 0.25 0.375 0.002 - 12 Fe 0.5 0.5 0.5 4.37 - 13 Fe 0.5 0 0.5 4.37 - 14 Fe 0 0.5 0.5 4.37 - 15 Fe 0.5 0.5 0 4.37 - 16 Fe 0 0 0.5 4.37 - 17 Fe 0 0.5 0 4.37 - 18 Fe 0.5 0 0 4.37 - 19 Fe 0 0 0 4.37 - 20 Ge 0.125 0.75 0.875 0.023 - 21 Ge 0.875 0.25 0.125 0.023 - 22 Ge 0.625 0.375 0.25 0.023 - 23 Ge 0.75 0.875 0.125 0.023 - 24 Ge 0.875 0.125 0.75 0.023 - 25 Ge 0.25 0.625 0.375 0.023 - 26 Ge 0.75 0.375 0.625 0.023 - 27 Ge 0.25 0.125 0.875 0.023 - 28 Ge 0.125 0.875 0.25 0.023 - 29 Ge 0.375 0.625 0.75 0.023 - 30 Ge 0.625 0.75 0.375 0.023 - 31 Ge 0.375 0.25 0.625 0.023 - 32 O 0.41701 0.817341 0.789564 0.081 - 33 O 0.872554 0.40033 0.08299 0.081 - 34 O 0.09967 0.972224 0.682659 0.081 - 35 O 0.527776 0.627446 0.710436 0.081 - 36 O 0.682659 0.08299 0.710436 0.081 - 37 O 0.627446 0.710436 0.527776 0.081 - 38 O 0.627446 0.41701 0.09967 0.081 - 39 O 0.710436 0.527776 0.627446 0.081 - 40 O 0.817341 0.527776 0.40033 0.081 - 41 O 0.972224 0.789564 0.872554 0.081 - 42 O 0.789564 0.872554 0.972224 0.081 - 43 O 0.710436 0.682659 0.08299 0.081 - 44 O 0.41701 0.09967 0.627446 0.081 - 45 O 0.40033 0.817341 0.527776 0.081 - 46 O 0.08299 0.710436 0.682659 0.081 - 47 O 0.09967 0.627446 0.41701 0.081 - 48 O 0.527776 0.40033 0.817341 0.081 - 49 O 0.08299 0.872554 0.40033 0.081 - 50 O 0.972224 0.682659 0.09967 0.081 - 51 O 0.182659 0.472224 0.59967 0.081 - 52 O 0.682659 0.09967 0.972224 0.081 - 53 O 0.789564 0.41701 0.817341 0.081 - 54 O 0.40033 0.08299 0.872554 0.081 - 55 O 0.872554 0.972224 0.789564 0.081 - 56 O 0.58299 0.182659 0.210436 0.081 - 57 O 0.127446 0.59967 0.91701 0.081 - 58 O 0.90033 0.027776 0.317341 0.081 - 59 O 0.472224 0.372554 0.289564 0.081 - 60 O 0.317341 0.91701 0.289564 0.081 - 61 O 0.372554 0.289564 0.472224 0.081 - 62 O 0.372554 0.58299 0.90033 0.081 - 63 O 0.289564 0.472224 0.372554 0.081 - 64 O 0.127446 0.027776 0.210436 0.081 - 65 O 0.59967 0.91701 0.127446 0.081 - 66 O 0.210436 0.58299 0.182659 0.081 - 67 O 0.182659 0.210436 0.58299 0.081 - 68 O 0.317341 0.90033 0.027776 0.081 - 69 O 0.027776 0.317341 0.90033 0.081 - 70 O 0.91701 0.127446 0.59967 0.081 - 71 O 0.472224 0.59967 0.182659 0.081 - 72 O 0.90033 0.372554 0.58299 0.081 - 73 O 0.91701 0.289564 0.317341 0.081 - 74 O 0.59967 0.182659 0.472224 0.081 - 75 O 0.58299 0.90033 0.372554 0.081 - 76 O 0.289564 0.317341 0.91701 0.081 - 77 O 0.210436 0.127446 0.027776 0.081 - 78 O 0.027776 0.210436 0.127446 0.081 - 79 O 0.817341 0.789564 0.41701 0.081","# generated using pymatgen -data_Mg3Fe2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.48803356 -_cell_length_b 10.48803356 -_cell_length_c 10.48803356 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Fe2(GeO4)3 -_chemical_formula_sum 'Mg12 Fe8 Ge12 O48' -_cell_volume 888.09681900 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe12 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe13 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41701000 0.81734100 0.78956400 1 - O O33 1 0.87255400 0.40033000 0.08299000 1 - O O34 1 0.09967000 0.97222400 0.68265900 1 - O O35 1 0.52777600 0.62744600 0.71043600 1 - O O36 1 0.68265900 0.08299000 0.71043600 1 - O O37 1 0.62744600 0.71043600 0.52777600 1 - O O38 1 0.62744600 0.41701000 0.09967000 1 - O O39 1 0.71043600 0.52777600 0.62744600 1 - O O40 1 0.81734100 0.52777600 0.40033000 1 - O O41 1 0.97222400 0.78956400 0.87255400 1 - O O42 1 0.78956400 0.87255400 0.97222400 1 - O O43 1 0.71043600 0.68265900 0.08299000 1 - O O44 1 0.41701000 0.09967000 0.62744600 1 - O O45 1 0.40033000 0.81734100 0.52777600 1 - O O46 1 0.08299000 0.71043600 0.68265900 1 - O O47 1 0.09967000 0.62744600 0.41701000 1 - O O48 1 0.52777600 0.40033000 0.81734100 1 - O O49 1 0.08299000 0.87255400 0.40033000 1 - O O50 1 0.97222400 0.68265900 0.09967000 1 - O O51 1 0.18265900 0.47222400 0.59967000 1 - O O52 1 0.68265900 0.09967000 0.97222400 1 - O O53 1 0.78956400 0.41701000 0.81734100 1 - O O54 1 0.40033000 0.08299000 0.87255400 1 - O O55 1 0.87255400 0.97222400 0.78956400 1 - O O56 1 0.58299000 0.18265900 0.21043600 1 - O O57 1 0.12744600 0.59967000 0.91701000 1 - O O58 1 0.90033000 0.02777600 0.31734100 1 - O O59 1 0.47222400 0.37255400 0.28956400 1 - O O60 1 0.31734100 0.91701000 0.28956400 1 - O O61 1 0.37255400 0.28956400 0.47222400 1 - O O62 1 0.37255400 0.58299000 0.90033000 1 - O O63 1 0.28956400 0.47222400 0.37255400 1 - O O64 1 0.12744600 0.02777600 0.21043600 1 - O O65 1 0.59967000 0.91701000 0.12744600 1 - O O66 1 0.21043600 0.58299000 0.18265900 1 - O O67 1 0.18265900 0.21043600 0.58299000 1 - O O68 1 0.31734100 0.90033000 0.02777600 1 - O O69 1 0.02777600 0.31734100 0.90033000 1 - O O70 1 0.91701000 0.12744600 0.59967000 1 - O O71 1 0.47222400 0.59967000 0.18265900 1 - O O72 1 0.90033000 0.37255400 0.58299000 1 - O O73 1 0.91701000 0.28956400 0.31734100 1 - O O74 1 0.59967000 0.18265900 0.47222400 1 - O O75 1 0.58299000 0.90033000 0.37255400 1 - O O76 1 0.28956400 0.31734100 0.91701000 1 - O O77 1 0.21043600 0.12744600 0.02777600 1 - O O78 1 0.02777600 0.21043600 0.12744600 1 - O O79 1 0.81734100 0.78956400 0.41701000 1 -" -Zn3Fe2(GeO4)3,mvc-5144,Ia-3d,[],0.10165600624999982,{'tags': []},"Full Formula (Zn12 Fe8 Ge12 O48) -Reduced Formula: Zn3Fe2(GeO4)3 -abc : 10.522451 10.522451 10.522451 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Zn 0.25 0.875 0.625 0.007 - 1 Zn 0.75 0.625 0.875 0.007 - 2 Zn 0.625 0.875 0.75 0.007 - 3 Zn 0.875 0.625 0.25 0.007 - 4 Zn 0.625 0.25 0.875 0.007 - 5 Zn 0.875 0.75 0.625 0.007 - 6 Zn 0.75 0.125 0.375 0.007 - 7 Zn 0.25 0.375 0.125 0.007 - 8 Zn 0.375 0.125 0.25 0.007 - 9 Zn 0.125 0.375 0.75 0.007 - 10 Zn 0.375 0.75 0.125 0.007 - 11 Zn 0.125 0.25 0.375 0.007 - 12 Fe 0.5 0.5 0.5 4.369 - 13 Fe 0.5 0 0.5 4.369 - 14 Fe 0 0.5 0.5 4.369 - 15 Fe 0.5 0.5 0 4.369 - 16 Fe 0 0 0.5 4.369 - 17 Fe 0 0.5 0 4.369 - 18 Fe 0.5 0 0 4.369 - 19 Fe 0 0 0 4.369 - 20 Ge 0.125 0.75 0.875 0.023 - 21 Ge 0.875 0.25 0.125 0.023 - 22 Ge 0.625 0.375 0.25 0.023 - 23 Ge 0.75 0.875 0.125 0.023 - 24 Ge 0.875 0.125 0.75 0.023 - 25 Ge 0.25 0.625 0.375 0.023 - 26 Ge 0.75 0.375 0.625 0.023 - 27 Ge 0.25 0.125 0.875 0.023 - 28 Ge 0.125 0.875 0.25 0.023 - 29 Ge 0.375 0.625 0.75 0.023 - 30 Ge 0.625 0.75 0.375 0.023 - 31 Ge 0.375 0.25 0.625 0.023 - 32 O 0.417988 0.817442 0.791014 0.08 - 33 O 0.873026 0.399453 0.082012 0.08 - 34 O 0.100547 0.973572 0.682558 0.08 - 35 O 0.526428 0.626974 0.708986 0.08 - 36 O 0.682558 0.082012 0.708986 0.08 - 37 O 0.626974 0.708986 0.526428 0.08 - 38 O 0.626974 0.417988 0.100547 0.08 - 39 O 0.708986 0.526428 0.626974 0.08 - 40 O 0.817442 0.526428 0.399453 0.08 - 41 O 0.973572 0.791014 0.873026 0.08 - 42 O 0.791014 0.873026 0.973572 0.08 - 43 O 0.708986 0.682558 0.082012 0.08 - 44 O 0.417988 0.100547 0.626974 0.08 - 45 O 0.399453 0.817442 0.526428 0.08 - 46 O 0.082012 0.708986 0.682558 0.08 - 47 O 0.100547 0.626974 0.417988 0.08 - 48 O 0.526428 0.399453 0.817442 0.08 - 49 O 0.082012 0.873026 0.399453 0.08 - 50 O 0.973572 0.682558 0.100547 0.08 - 51 O 0.182558 0.473572 0.600547 0.08 - 52 O 0.682558 0.100547 0.973572 0.08 - 53 O 0.791014 0.417988 0.817442 0.08 - 54 O 0.399453 0.082012 0.873026 0.08 - 55 O 0.873026 0.973572 0.791014 0.08 - 56 O 0.582012 0.182558 0.208986 0.08 - 57 O 0.126974 0.600547 0.917988 0.08 - 58 O 0.899453 0.026428 0.317442 0.08 - 59 O 0.473572 0.373026 0.291014 0.08 - 60 O 0.317442 0.917988 0.291014 0.08 - 61 O 0.373026 0.291014 0.473572 0.08 - 62 O 0.373026 0.582012 0.899453 0.08 - 63 O 0.291014 0.473572 0.373026 0.08 - 64 O 0.126974 0.026428 0.208986 0.08 - 65 O 0.600547 0.917988 0.126974 0.08 - 66 O 0.208986 0.582012 0.182558 0.08 - 67 O 0.182558 0.208986 0.582012 0.08 - 68 O 0.317442 0.899453 0.026428 0.08 - 69 O 0.026428 0.317442 0.899453 0.08 - 70 O 0.917988 0.126974 0.600547 0.08 - 71 O 0.473572 0.600547 0.182558 0.08 - 72 O 0.899453 0.373026 0.582012 0.08 - 73 O 0.917988 0.291014 0.317442 0.08 - 74 O 0.600547 0.182558 0.473572 0.08 - 75 O 0.582012 0.899453 0.373026 0.08 - 76 O 0.291014 0.317442 0.917988 0.08 - 77 O 0.208986 0.126974 0.026428 0.08 - 78 O 0.026428 0.208986 0.126974 0.08 - 79 O 0.817442 0.791014 0.417988 0.08","# generated using pymatgen -data_Zn3Fe2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.52245114 -_cell_length_b 10.52245114 -_cell_length_c 10.52245114 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Zn3Fe2(GeO4)3 -_chemical_formula_sum 'Zn12 Fe8 Ge12 O48' -_cell_volume 896.86869038 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Zn Zn0 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn1 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn2 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn3 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn4 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn5 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn6 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn7 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn8 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn9 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn10 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn11 1 0.12500000 0.25000000 0.37500000 1 - Fe Fe12 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe13 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41798800 0.81744200 0.79101400 1 - O O33 1 0.87302600 0.39945300 0.08201200 1 - O O34 1 0.10054700 0.97357200 0.68255800 1 - O O35 1 0.52642800 0.62697400 0.70898600 1 - O O36 1 0.68255800 0.08201200 0.70898600 1 - O O37 1 0.62697400 0.70898600 0.52642800 1 - O O38 1 0.62697400 0.41798800 0.10054700 1 - O O39 1 0.70898600 0.52642800 0.62697400 1 - O O40 1 0.81744200 0.52642800 0.39945300 1 - O O41 1 0.97357200 0.79101400 0.87302600 1 - O O42 1 0.79101400 0.87302600 0.97357200 1 - O O43 1 0.70898600 0.68255800 0.08201200 1 - O O44 1 0.41798800 0.10054700 0.62697400 1 - O O45 1 0.39945300 0.81744200 0.52642800 1 - O O46 1 0.08201200 0.70898600 0.68255800 1 - O O47 1 0.10054700 0.62697400 0.41798800 1 - O O48 1 0.52642800 0.39945300 0.81744200 1 - O O49 1 0.08201200 0.87302600 0.39945300 1 - O O50 1 0.97357200 0.68255800 0.10054700 1 - O O51 1 0.18255800 0.47357200 0.60054700 1 - O O52 1 0.68255800 0.10054700 0.97357200 1 - O O53 1 0.79101400 0.41798800 0.81744200 1 - O O54 1 0.39945300 0.08201200 0.87302600 1 - O O55 1 0.87302600 0.97357200 0.79101400 1 - O O56 1 0.58201200 0.18255800 0.20898600 1 - O O57 1 0.12697400 0.60054700 0.91798800 1 - O O58 1 0.89945300 0.02642800 0.31744200 1 - O O59 1 0.47357200 0.37302600 0.29101400 1 - O O60 1 0.31744200 0.91798800 0.29101400 1 - O O61 1 0.37302600 0.29101400 0.47357200 1 - O O62 1 0.37302600 0.58201200 0.89945300 1 - O O63 1 0.29101400 0.47357200 0.37302600 1 - O O64 1 0.12697400 0.02642800 0.20898600 1 - O O65 1 0.60054700 0.91798800 0.12697400 1 - O O66 1 0.20898600 0.58201200 0.18255800 1 - O O67 1 0.18255800 0.20898600 0.58201200 1 - O O68 1 0.31744200 0.89945300 0.02642800 1 - O O69 1 0.02642800 0.31744200 0.89945300 1 - O O70 1 0.91798800 0.12697400 0.60054700 1 - O O71 1 0.47357200 0.60054700 0.18255800 1 - O O72 1 0.89945300 0.37302600 0.58201200 1 - O O73 1 0.91798800 0.29101400 0.31744200 1 - O O74 1 0.60054700 0.18255800 0.47357200 1 - O O75 1 0.58201200 0.89945300 0.37302600 1 - O O76 1 0.29101400 0.31744200 0.91798800 1 - O O77 1 0.20898600 0.12697400 0.02642800 1 - O O78 1 0.02642800 0.20898600 0.12697400 1 - O O79 1 0.81744200 0.79101400 0.41798800 1 -" -Mg3Mn2(GeO4)3,mvc-5151,Ia-3d,[],0.10083274684374999,{'tags': []},"Full Formula (Mg12 Mn8 Ge12 O48) -Reduced Formula: Mg3Mn2(GeO4)3 -abc : 10.474596 10.474596 10.474596 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mg 0.25 0.875 0.625 0.004 - 1 Mg 0.75 0.625 0.875 0.004 - 2 Mg 0.625 0.875 0.75 0.004 - 3 Mg 0.875 0.625 0.25 0.004 - 4 Mg 0.625 0.25 0.875 0.004 - 5 Mg 0.875 0.75 0.625 0.004 - 6 Mg 0.75 0.125 0.375 0.004 - 7 Mg 0.25 0.375 0.125 0.004 - 8 Mg 0.375 0.125 0.25 0.004 - 9 Mg 0.125 0.375 0.75 0.004 - 10 Mg 0.375 0.75 0.125 0.004 - 11 Mg 0.125 0.25 0.375 0.004 - 12 Mn 0.5 0.5 0.5 4.034 - 13 Mn 0.5 0 0.5 4.034 - 14 Mn 0 0.5 0.5 4.034 - 15 Mn 0.5 0.5 0 4.035 - 16 Mn 0 0 0.5 4.035 - 17 Mn 0 0.5 0 4.033 - 18 Mn 0.5 0 0 4.034 - 19 Mn 0 0 0 4.034 - 20 Ge 0.125 0.75 0.875 0.022 - 21 Ge 0.875 0.25 0.125 0.022 - 22 Ge 0.625 0.375 0.25 0.022 - 23 Ge 0.75 0.875 0.125 0.022 - 24 Ge 0.875 0.125 0.75 0.022 - 25 Ge 0.25 0.625 0.375 0.022 - 26 Ge 0.75 0.375 0.625 0.022 - 27 Ge 0.25 0.125 0.875 0.022 - 28 Ge 0.125 0.875 0.25 0.022 - 29 Ge 0.375 0.625 0.75 0.022 - 30 Ge 0.625 0.75 0.375 0.022 - 31 Ge 0.375 0.25 0.625 0.022 - 32 O 0.416422 0.817107 0.787748 -0.032 - 33 O 0.871327 0.400685 0.083578 -0.032 - 34 O 0.099315 0.970642 0.682893 -0.031 - 35 O 0.529358 0.628673 0.712252 -0.031 - 36 O 0.682893 0.083578 0.712252 -0.032 - 37 O 0.628673 0.712252 0.529358 -0.032 - 38 O 0.628673 0.416422 0.099315 -0.031 - 39 O 0.712252 0.529358 0.628673 -0.031 - 40 O 0.817107 0.529358 0.400685 -0.031 - 41 O 0.970642 0.787748 0.871327 -0.032 - 42 O 0.787748 0.871327 0.970642 -0.031 - 43 O 0.712252 0.682893 0.083578 -0.031 - 44 O 0.416422 0.099315 0.628673 -0.032 - 45 O 0.400685 0.817107 0.529358 -0.031 - 46 O 0.083578 0.712252 0.682893 -0.031 - 47 O 0.099315 0.628673 0.416422 -0.032 - 48 O 0.529358 0.400685 0.817107 -0.032 - 49 O 0.083578 0.871327 0.400685 -0.031 - 50 O 0.970642 0.682893 0.099315 -0.032 - 51 O 0.182893 0.470642 0.599315 -0.031 - 52 O 0.682893 0.099315 0.970642 -0.031 - 53 O 0.787748 0.416422 0.817107 -0.031 - 54 O 0.400685 0.083578 0.871327 -0.031 - 55 O 0.871327 0.970642 0.787748 -0.031 - 56 O 0.583578 0.182893 0.212252 -0.032 - 57 O 0.128673 0.599315 0.916422 -0.032 - 58 O 0.900685 0.029358 0.317107 -0.031 - 59 O 0.470642 0.371327 0.287748 -0.031 - 60 O 0.317107 0.916422 0.287748 -0.032 - 61 O 0.371327 0.287748 0.470642 -0.032 - 62 O 0.371327 0.583578 0.900685 -0.031 - 63 O 0.287748 0.470642 0.371327 -0.031 - 64 O 0.128673 0.029358 0.212252 -0.031 - 65 O 0.599315 0.916422 0.128673 -0.031 - 66 O 0.212252 0.583578 0.182893 -0.031 - 67 O 0.182893 0.212252 0.583578 -0.032 - 68 O 0.317107 0.900685 0.029358 -0.031 - 69 O 0.029358 0.317107 0.900685 -0.032 - 70 O 0.916422 0.128673 0.599315 -0.031 - 71 O 0.470642 0.599315 0.182893 -0.032 - 72 O 0.900685 0.371327 0.583578 -0.032 - 73 O 0.916422 0.287748 0.317107 -0.031 - 74 O 0.599315 0.182893 0.470642 -0.031 - 75 O 0.583578 0.900685 0.371327 -0.032 - 76 O 0.287748 0.317107 0.916422 -0.031 - 77 O 0.212252 0.128673 0.029358 -0.031 - 78 O 0.029358 0.212252 0.128673 -0.032 - 79 O 0.817107 0.787748 0.416422 -0.032","# generated using pymatgen -data_Mg3Mn2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.47459631 -_cell_length_b 10.47459631 -_cell_length_c 10.47459631 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mg3Mn2(GeO4)3 -_chemical_formula_sum 'Mg12 Mn8 Ge12 O48' -_cell_volume 884.68770623 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mg Mg0 1 0.25000000 0.87500000 0.62500000 1 - Mg Mg1 1 0.75000000 0.62500000 0.87500000 1 - Mg Mg2 1 0.62500000 0.87500000 0.75000000 1 - Mg Mg3 1 0.87500000 0.62500000 0.25000000 1 - Mg Mg4 1 0.62500000 0.25000000 0.87500000 1 - Mg Mg5 1 0.87500000 0.75000000 0.62500000 1 - Mg Mg6 1 0.75000000 0.12500000 0.37500000 1 - Mg Mg7 1 0.25000000 0.37500000 0.12500000 1 - Mg Mg8 1 0.37500000 0.12500000 0.25000000 1 - Mg Mg9 1 0.12500000 0.37500000 0.75000000 1 - Mg Mg10 1 0.37500000 0.75000000 0.12500000 1 - Mg Mg11 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn12 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn13 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn14 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn15 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn16 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn17 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn18 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41642200 0.81710700 0.78774800 1 - O O33 1 0.87132700 0.40068500 0.08357800 1 - O O34 1 0.09931500 0.97064200 0.68289300 1 - O O35 1 0.52935800 0.62867300 0.71225200 1 - O O36 1 0.68289300 0.08357800 0.71225200 1 - O O37 1 0.62867300 0.71225200 0.52935800 1 - O O38 1 0.62867300 0.41642200 0.09931500 1 - O O39 1 0.71225200 0.52935800 0.62867300 1 - O O40 1 0.81710700 0.52935800 0.40068500 1 - O O41 1 0.97064200 0.78774800 0.87132700 1 - O O42 1 0.78774800 0.87132700 0.97064200 1 - O O43 1 0.71225200 0.68289300 0.08357800 1 - O O44 1 0.41642200 0.09931500 0.62867300 1 - O O45 1 0.40068500 0.81710700 0.52935800 1 - O O46 1 0.08357800 0.71225200 0.68289300 1 - O O47 1 0.09931500 0.62867300 0.41642200 1 - O O48 1 0.52935800 0.40068500 0.81710700 1 - O O49 1 0.08357800 0.87132700 0.40068500 1 - O O50 1 0.97064200 0.68289300 0.09931500 1 - O O51 1 0.18289300 0.47064200 0.59931500 1 - O O52 1 0.68289300 0.09931500 0.97064200 1 - O O53 1 0.78774800 0.41642200 0.81710700 1 - O O54 1 0.40068500 0.08357800 0.87132700 1 - O O55 1 0.87132700 0.97064200 0.78774800 1 - O O56 1 0.58357800 0.18289300 0.21225200 1 - O O57 1 0.12867300 0.59931500 0.91642200 1 - O O58 1 0.90068500 0.02935800 0.31710700 1 - O O59 1 0.47064200 0.37132700 0.28774800 1 - O O60 1 0.31710700 0.91642200 0.28774800 1 - O O61 1 0.37132700 0.28774800 0.47064200 1 - O O62 1 0.37132700 0.58357800 0.90068500 1 - O O63 1 0.28774800 0.47064200 0.37132700 1 - O O64 1 0.12867300 0.02935800 0.21225200 1 - O O65 1 0.59931500 0.91642200 0.12867300 1 - O O66 1 0.21225200 0.58357800 0.18289300 1 - O O67 1 0.18289300 0.21225200 0.58357800 1 - O O68 1 0.31710700 0.90068500 0.02935800 1 - O O69 1 0.02935800 0.31710700 0.90068500 1 - O O70 1 0.91642200 0.12867300 0.59931500 1 - O O71 1 0.47064200 0.59931500 0.18289300 1 - O O72 1 0.90068500 0.37132700 0.58357800 1 - O O73 1 0.91642200 0.28774800 0.31710700 1 - O O74 1 0.59931500 0.18289300 0.47064200 1 - O O75 1 0.58357800 0.90068500 0.37132700 1 - O O76 1 0.28774800 0.31710700 0.91642200 1 - O O77 1 0.21225200 0.12867300 0.02935800 1 - O O78 1 0.02935800 0.21225200 0.12867300 1 - O O79 1 0.81710700 0.78774800 0.41642200 1 -" -Ca3Mn2(GeO4)3,mvc-5319,Ia-3d,[],0.04448473800000041,{'tags': []},"Full Formula (Ca12 Mn8 Ge12 O48) -Reduced Formula: Ca3Mn2(GeO4)3 -abc : 10.840386 10.840386 10.840386 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ca 0.25 0.875 0.625 0.004 - 1 Ca 0.75 0.625 0.875 0.004 - 2 Ca 0.625 0.875 0.75 0.003 - 3 Ca 0.875 0.625 0.25 0.003 - 4 Ca 0.625 0.25 0.875 0.003 - 5 Ca 0.875 0.75 0.625 0.003 - 6 Ca 0.75 0.125 0.375 0.004 - 7 Ca 0.25 0.375 0.125 0.004 - 8 Ca 0.375 0.125 0.25 0.003 - 9 Ca 0.125 0.375 0.75 0.003 - 10 Ca 0.375 0.75 0.125 0.003 - 11 Ca 0.125 0.25 0.375 0.003 - 12 Mn 0.5 0.5 0.5 4.036 - 13 Mn 0.5 0 0.5 4.078 - 14 Mn 0 0.5 0.5 4.078 - 15 Mn 0.5 0.5 0 4.036 - 16 Mn 0 0 0.5 4.078 - 17 Mn 0 0.5 0 4.036 - 18 Mn 0.5 0 0 4.078 - 19 Mn 0 0 0 4.036 - 20 Ge 0.125 0.75 0.875 0.022 - 21 Ge 0.875 0.25 0.125 0.022 - 22 Ge 0.625 0.375 0.25 0.022 - 23 Ge 0.75 0.875 0.125 0.022 - 24 Ge 0.875 0.125 0.75 0.022 - 25 Ge 0.25 0.625 0.375 0.022 - 26 Ge 0.75 0.375 0.625 0.022 - 27 Ge 0.25 0.125 0.875 0.022 - 28 Ge 0.125 0.875 0.25 0.022 - 29 Ge 0.375 0.625 0.75 0.022 - 30 Ge 0.625 0.75 0.375 0.022 - 31 Ge 0.375 0.25 0.625 0.022 - 32 O 0.414901 0.813541 0.795405 -0.034 - 33 O 0.880504 0.39864 0.085099 -0.038 - 34 O 0.10136 0.981864 0.686459 -0.032 - 35 O 0.518136 0.619496 0.704595 -0.028 - 36 O 0.686459 0.085099 0.704595 -0.033 - 37 O 0.619496 0.704595 0.518136 -0.038 - 38 O 0.619496 0.414901 0.10136 -0.038 - 39 O 0.704595 0.518136 0.619496 -0.03 - 40 O 0.813541 0.518136 0.39864 -0.033 - 41 O 0.981864 0.795405 0.880504 -0.028 - 42 O 0.795405 0.880504 0.981864 -0.03 - 43 O 0.704595 0.686459 0.085099 -0.03 - 44 O 0.414901 0.10136 0.619496 -0.034 - 45 O 0.39864 0.813541 0.518136 -0.032 - 46 O 0.085099 0.704595 0.686459 -0.034 - 47 O 0.10136 0.619496 0.414901 -0.032 - 48 O 0.518136 0.39864 0.813541 -0.028 - 49 O 0.085099 0.880504 0.39864 -0.034 - 50 O 0.981864 0.686459 0.10136 -0.028 - 51 O 0.186459 0.481864 0.60136 -0.033 - 52 O 0.686459 0.10136 0.981864 -0.033 - 53 O 0.795405 0.414901 0.813541 -0.03 - 54 O 0.39864 0.085099 0.880504 -0.032 - 55 O 0.880504 0.981864 0.795405 -0.038 - 56 O 0.585099 0.186459 0.204595 -0.034 - 57 O 0.119496 0.60136 0.914901 -0.038 - 58 O 0.89864 0.018136 0.313541 -0.032 - 59 O 0.481864 0.380504 0.295405 -0.028 - 60 O 0.313541 0.914901 0.295405 -0.033 - 61 O 0.380504 0.295405 0.481864 -0.038 - 62 O 0.380504 0.585099 0.89864 -0.038 - 63 O 0.295405 0.481864 0.380504 -0.03 - 64 O 0.119496 0.018136 0.204595 -0.038 - 65 O 0.60136 0.914901 0.119496 -0.032 - 66 O 0.204595 0.585099 0.186459 -0.03 - 67 O 0.186459 0.204595 0.585099 -0.033 - 68 O 0.313541 0.89864 0.018136 -0.033 - 69 O 0.018136 0.313541 0.89864 -0.028 - 70 O 0.914901 0.119496 0.60136 -0.034 - 71 O 0.481864 0.60136 0.186459 -0.028 - 72 O 0.89864 0.380504 0.585099 -0.032 - 73 O 0.914901 0.295405 0.313541 -0.034 - 74 O 0.60136 0.186459 0.481864 -0.032 - 75 O 0.585099 0.89864 0.380504 -0.034 - 76 O 0.295405 0.313541 0.914901 -0.03 - 77 O 0.204595 0.119496 0.018136 -0.03 - 78 O 0.018136 0.204595 0.119496 -0.028 - 79 O 0.813541 0.795405 0.414901 -0.033","# generated using pymatgen -data_Ca3Mn2(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.84038639 -_cell_length_b 10.84038639 -_cell_length_c 10.84038639 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ca3Mn2(GeO4)3 -_chemical_formula_sum 'Ca12 Mn8 Ge12 O48' -_cell_volume 980.64630438 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ca Ca0 1 0.25000000 0.87500000 0.62500000 1 - Ca Ca1 1 0.75000000 0.62500000 0.87500000 1 - Ca Ca2 1 0.62500000 0.87500000 0.75000000 1 - Ca Ca3 1 0.87500000 0.62500000 0.25000000 1 - Ca Ca4 1 0.62500000 0.25000000 0.87500000 1 - Ca Ca5 1 0.87500000 0.75000000 0.62500000 1 - Ca Ca6 1 0.75000000 0.12500000 0.37500000 1 - Ca Ca7 1 0.25000000 0.37500000 0.12500000 1 - Ca Ca8 1 0.37500000 0.12500000 0.25000000 1 - Ca Ca9 1 0.12500000 0.37500000 0.75000000 1 - Ca Ca10 1 0.37500000 0.75000000 0.12500000 1 - Ca Ca11 1 0.12500000 0.25000000 0.37500000 1 - Mn Mn12 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn13 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn14 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn15 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn16 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn17 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn18 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn19 1 0.00000000 0.00000000 0.00000000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41490100 0.81354100 0.79540500 1 - O O33 1 0.88050400 0.39864000 0.08509900 1 - O O34 1 0.10136000 0.98186400 0.68645900 1 - O O35 1 0.51813600 0.61949600 0.70459500 1 - O O36 1 0.68645900 0.08509900 0.70459500 1 - O O37 1 0.61949600 0.70459500 0.51813600 1 - O O38 1 0.61949600 0.41490100 0.10136000 1 - O O39 1 0.70459500 0.51813600 0.61949600 1 - O O40 1 0.81354100 0.51813600 0.39864000 1 - O O41 1 0.98186400 0.79540500 0.88050400 1 - O O42 1 0.79540500 0.88050400 0.98186400 1 - O O43 1 0.70459500 0.68645900 0.08509900 1 - O O44 1 0.41490100 0.10136000 0.61949600 1 - O O45 1 0.39864000 0.81354100 0.51813600 1 - O O46 1 0.08509900 0.70459500 0.68645900 1 - O O47 1 0.10136000 0.61949600 0.41490100 1 - O O48 1 0.51813600 0.39864000 0.81354100 1 - O O49 1 0.08509900 0.88050400 0.39864000 1 - O O50 1 0.98186400 0.68645900 0.10136000 1 - O O51 1 0.18645900 0.48186400 0.60136000 1 - O O52 1 0.68645900 0.10136000 0.98186400 1 - O O53 1 0.79540500 0.41490100 0.81354100 1 - O O54 1 0.39864000 0.08509900 0.88050400 1 - O O55 1 0.88050400 0.98186400 0.79540500 1 - O O56 1 0.58509900 0.18645900 0.20459500 1 - O O57 1 0.11949600 0.60136000 0.91490100 1 - O O58 1 0.89864000 0.01813600 0.31354100 1 - O O59 1 0.48186400 0.38050400 0.29540500 1 - O O60 1 0.31354100 0.91490100 0.29540500 1 - O O61 1 0.38050400 0.29540500 0.48186400 1 - O O62 1 0.38050400 0.58509900 0.89864000 1 - O O63 1 0.29540500 0.48186400 0.38050400 1 - O O64 1 0.11949600 0.01813600 0.20459500 1 - O O65 1 0.60136000 0.91490100 0.11949600 1 - O O66 1 0.20459500 0.58509900 0.18645900 1 - O O67 1 0.18645900 0.20459500 0.58509900 1 - O O68 1 0.31354100 0.89864000 0.01813600 1 - O O69 1 0.01813600 0.31354100 0.89864000 1 - O O70 1 0.91490100 0.11949600 0.60136000 1 - O O71 1 0.48186400 0.60136000 0.18645900 1 - O O72 1 0.89864000 0.38050400 0.58509900 1 - O O73 1 0.91490100 0.29540500 0.31354100 1 - O O74 1 0.60136000 0.18645900 0.48186400 1 - O O75 1 0.58509900 0.89864000 0.38050400 1 - O O76 1 0.29540500 0.31354100 0.91490100 1 - O O77 1 0.20459500 0.11949600 0.01813600 1 - O O78 1 0.01813600 0.20459500 0.11949600 1 - O O79 1 0.81354100 0.79540500 0.41490100 1 -" -Mn2Zn3(GeO4)3,mvc-5366,Ia-3d,[],0.14088613016667395,{'tags': []},"Full Formula (Mn8 Zn12 Ge12 O48) -Reduced Formula: Mn2Zn3(GeO4)3 -abc : 10.526352 10.526352 10.526352 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Mn 0.5 0.5 0.5 4.03 - 1 Mn 0.5 0 0.5 4.03 - 2 Mn 0 0.5 0.5 4.03 - 3 Mn 0.5 0.5 0 4.03 - 4 Mn 0 0 0.5 4.03 - 5 Mn 0 0.5 0 4.03 - 6 Mn 0.5 0 0 4.03 - 7 Mn 0 0 0 4.03 - 8 Zn 0.25 0.875 0.625 0.013 - 9 Zn 0.75 0.625 0.875 0.013 - 10 Zn 0.625 0.875 0.75 0.013 - 11 Zn 0.875 0.625 0.25 0.013 - 12 Zn 0.625 0.25 0.875 0.013 - 13 Zn 0.875 0.75 0.625 0.013 - 14 Zn 0.75 0.125 0.375 0.013 - 15 Zn 0.25 0.375 0.125 0.013 - 16 Zn 0.375 0.125 0.25 0.013 - 17 Zn 0.125 0.375 0.75 0.013 - 18 Zn 0.375 0.75 0.125 0.013 - 19 Zn 0.125 0.25 0.375 0.013 - 20 Ge 0.125 0.75 0.875 0.022 - 21 Ge 0.875 0.25 0.125 0.022 - 22 Ge 0.625 0.375 0.25 0.022 - 23 Ge 0.75 0.875 0.125 0.022 - 24 Ge 0.875 0.125 0.75 0.022 - 25 Ge 0.25 0.625 0.375 0.022 - 26 Ge 0.75 0.375 0.625 0.022 - 27 Ge 0.25 0.125 0.875 0.022 - 28 Ge 0.125 0.875 0.25 0.022 - 29 Ge 0.375 0.625 0.75 0.022 - 30 Ge 0.625 0.75 0.375 0.022 - 31 Ge 0.375 0.25 0.625 0.022 - 32 O 0.419268 0.817767 0.790652 -0.033 - 33 O 0.871384 0.398499 0.080732 -0.033 - 34 O 0.101501 0.972885 0.682233 -0.033 - 35 O 0.527115 0.628616 0.709348 -0.033 - 36 O 0.682233 0.080732 0.709348 -0.033 - 37 O 0.628616 0.709348 0.527115 -0.033 - 38 O 0.628616 0.419268 0.101501 -0.033 - 39 O 0.709348 0.527115 0.628616 -0.033 - 40 O 0.817767 0.527115 0.398499 -0.033 - 41 O 0.972885 0.790652 0.871384 -0.033 - 42 O 0.790652 0.871384 0.972885 -0.033 - 43 O 0.709348 0.682233 0.080732 -0.033 - 44 O 0.419268 0.101501 0.628616 -0.033 - 45 O 0.398499 0.817767 0.527115 -0.033 - 46 O 0.080732 0.709348 0.682233 -0.033 - 47 O 0.101501 0.628616 0.419268 -0.033 - 48 O 0.527115 0.398499 0.817767 -0.033 - 49 O 0.080732 0.871384 0.398499 -0.033 - 50 O 0.972885 0.682233 0.101501 -0.033 - 51 O 0.182233 0.472885 0.601501 -0.033 - 52 O 0.682233 0.101501 0.972885 -0.033 - 53 O 0.790652 0.419268 0.817767 -0.033 - 54 O 0.398499 0.080732 0.871384 -0.033 - 55 O 0.871384 0.972885 0.790652 -0.033 - 56 O 0.580732 0.182233 0.209348 -0.033 - 57 O 0.128616 0.601501 0.919268 -0.033 - 58 O 0.898499 0.027115 0.317767 -0.033 - 59 O 0.472885 0.371384 0.290652 -0.033 - 60 O 0.317767 0.919268 0.290652 -0.033 - 61 O 0.371384 0.290652 0.472885 -0.033 - 62 O 0.371384 0.580732 0.898499 -0.033 - 63 O 0.290652 0.472885 0.371384 -0.033 - 64 O 0.128616 0.027115 0.209348 -0.033 - 65 O 0.601501 0.919268 0.128616 -0.033 - 66 O 0.209348 0.580732 0.182233 -0.033 - 67 O 0.182233 0.209348 0.580732 -0.033 - 68 O 0.317767 0.898499 0.027115 -0.033 - 69 O 0.027115 0.317767 0.898499 -0.033 - 70 O 0.919268 0.128616 0.601501 -0.033 - 71 O 0.472885 0.601501 0.182233 -0.033 - 72 O 0.898499 0.371384 0.580732 -0.033 - 73 O 0.919268 0.290652 0.317767 -0.033 - 74 O 0.601501 0.182233 0.472885 -0.033 - 75 O 0.580732 0.898499 0.371384 -0.033 - 76 O 0.290652 0.317767 0.919268 -0.033 - 77 O 0.209348 0.128616 0.027115 -0.033 - 78 O 0.027115 0.209348 0.128616 -0.033 - 79 O 0.817767 0.790652 0.419268 -0.033","# generated using pymatgen -data_Mn2Zn3(GeO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.52635172 -_cell_length_b 10.52635172 -_cell_length_c 10.52635172 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Mn2Zn3(GeO4)3 -_chemical_formula_sum 'Mn8 Zn12 Ge12 O48' -_cell_volume 897.86644372 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Mn Mn0 1 0.50000000 0.50000000 0.50000000 1 - Mn Mn1 1 0.50000000 0.00000000 0.50000000 1 - Mn Mn2 1 0.00000000 0.50000000 0.50000000 1 - Mn Mn3 1 0.50000000 0.50000000 0.00000000 1 - Mn Mn4 1 0.00000000 0.00000000 0.50000000 1 - Mn Mn5 1 0.00000000 0.50000000 0.00000000 1 - Mn Mn6 1 0.50000000 0.00000000 0.00000000 1 - Mn Mn7 1 0.00000000 0.00000000 0.00000000 1 - Zn Zn8 1 0.25000000 0.87500000 0.62500000 1 - Zn Zn9 1 0.75000000 0.62500000 0.87500000 1 - Zn Zn10 1 0.62500000 0.87500000 0.75000000 1 - Zn Zn11 1 0.87500000 0.62500000 0.25000000 1 - Zn Zn12 1 0.62500000 0.25000000 0.87500000 1 - Zn Zn13 1 0.87500000 0.75000000 0.62500000 1 - Zn Zn14 1 0.75000000 0.12500000 0.37500000 1 - Zn Zn15 1 0.25000000 0.37500000 0.12500000 1 - Zn Zn16 1 0.37500000 0.12500000 0.25000000 1 - Zn Zn17 1 0.12500000 0.37500000 0.75000000 1 - Zn Zn18 1 0.37500000 0.75000000 0.12500000 1 - Zn Zn19 1 0.12500000 0.25000000 0.37500000 1 - Ge Ge20 1 0.12500000 0.75000000 0.87500000 1 - Ge Ge21 1 0.87500000 0.25000000 0.12500000 1 - Ge Ge22 1 0.62500000 0.37500000 0.25000000 1 - Ge Ge23 1 0.75000000 0.87500000 0.12500000 1 - Ge Ge24 1 0.87500000 0.12500000 0.75000000 1 - Ge Ge25 1 0.25000000 0.62500000 0.37500000 1 - Ge Ge26 1 0.75000000 0.37500000 0.62500000 1 - Ge Ge27 1 0.25000000 0.12500000 0.87500000 1 - Ge Ge28 1 0.12500000 0.87500000 0.25000000 1 - Ge Ge29 1 0.37500000 0.62500000 0.75000000 1 - Ge Ge30 1 0.62500000 0.75000000 0.37500000 1 - Ge Ge31 1 0.37500000 0.25000000 0.62500000 1 - O O32 1 0.41926800 0.81776700 0.79065200 1 - O O33 1 0.87138400 0.39849900 0.08073200 1 - O O34 1 0.10150100 0.97288500 0.68223300 1 - O O35 1 0.52711500 0.62861600 0.70934800 1 - O O36 1 0.68223300 0.08073200 0.70934800 1 - O O37 1 0.62861600 0.70934800 0.52711500 1 - O O38 1 0.62861600 0.41926800 0.10150100 1 - O O39 1 0.70934800 0.52711500 0.62861600 1 - O O40 1 0.81776700 0.52711500 0.39849900 1 - O O41 1 0.97288500 0.79065200 0.87138400 1 - O O42 1 0.79065200 0.87138400 0.97288500 1 - O O43 1 0.70934800 0.68223300 0.08073200 1 - O O44 1 0.41926800 0.10150100 0.62861600 1 - O O45 1 0.39849900 0.81776700 0.52711500 1 - O O46 1 0.08073200 0.70934800 0.68223300 1 - O O47 1 0.10150100 0.62861600 0.41926800 1 - O O48 1 0.52711500 0.39849900 0.81776700 1 - O O49 1 0.08073200 0.87138400 0.39849900 1 - O O50 1 0.97288500 0.68223300 0.10150100 1 - O O51 1 0.18223300 0.47288500 0.60150100 1 - O O52 1 0.68223300 0.10150100 0.97288500 1 - O O53 1 0.79065200 0.41926800 0.81776700 1 - O O54 1 0.39849900 0.08073200 0.87138400 1 - O O55 1 0.87138400 0.97288500 0.79065200 1 - O O56 1 0.58073200 0.18223300 0.20934800 1 - O O57 1 0.12861600 0.60150100 0.91926800 1 - O O58 1 0.89849900 0.02711500 0.31776700 1 - O O59 1 0.47288500 0.37138400 0.29065200 1 - O O60 1 0.31776700 0.91926800 0.29065200 1 - O O61 1 0.37138400 0.29065200 0.47288500 1 - O O62 1 0.37138400 0.58073200 0.89849900 1 - O O63 1 0.29065200 0.47288500 0.37138400 1 - O O64 1 0.12861600 0.02711500 0.20934800 1 - O O65 1 0.60150100 0.91926800 0.12861600 1 - O O66 1 0.20934800 0.58073200 0.18223300 1 - O O67 1 0.18223300 0.20934800 0.58073200 1 - O O68 1 0.31776700 0.89849900 0.02711500 1 - O O69 1 0.02711500 0.31776700 0.89849900 1 - O O70 1 0.91926800 0.12861600 0.60150100 1 - O O71 1 0.47288500 0.60150100 0.18223300 1 - O O72 1 0.89849900 0.37138400 0.58073200 1 - O O73 1 0.91926800 0.29065200 0.31776700 1 - O O74 1 0.60150100 0.18223300 0.47288500 1 - O O75 1 0.58073200 0.89849900 0.37138400 1 - O O76 1 0.29065200 0.31776700 0.91926800 1 - O O77 1 0.20934800 0.12861600 0.02711500 1 - O O78 1 0.02711500 0.20934800 0.12861600 1 - O O79 1 0.81776700 0.79065200 0.41926800 1 -" -Cd3Ga5O12,mp-1213947,Ia-3d,[],0.1058965293749985,"{'tags': ['garnet family', 'Cd3Ga5O12', 'Y3Al5O12']}","Full Formula (Cd12 Ga20 O48) -Reduced Formula: Cd3Ga5O12 -abc : 10.797828 10.797828 10.797828 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Cd 0.25 0.375 0.125 0.019 - 1 Cd 0.75 0.625 0.875 0.019 - 2 Cd 0.75 0.125 0.375 0.026 - 3 Cd 0.125 0.25 0.375 0.024 - 4 Cd 0.375 0.75 0.125 0.024 - 5 Cd 0.25 0.875 0.625 0.026 - 6 Cd 0.875 0.75 0.625 0.024 - 7 Cd 0.625 0.25 0.875 0.024 - 8 Cd 0.375 0.125 0.25 0.024 - 9 Cd 0.625 0.875 0.75 0.024 - 10 Cd 0.125 0.375 0.75 0.024 - 11 Cd 0.875 0.625 0.25 0.024 - 12 Ga 0.25 0.625 0.375 -0.008 - 13 Ga 0.75 0.375 0.625 -0.008 - 14 Ga 0.75 0.875 0.125 -0.008 - 15 Ga 0.375 0.25 0.625 -0.009 - 16 Ga 0.625 0.75 0.375 -0.009 - 17 Ga 0.25 0.125 0.875 -0.008 - 18 Ga 0.125 0.75 0.875 -0.009 - 19 Ga 0.875 0.25 0.125 -0.009 - 20 Ga 0.625 0.375 0.25 -0.009 - 21 Ga 0.375 0.625 0.75 -0.009 - 22 Ga 0.875 0.125 0.75 -0.009 - 23 Ga 0.125 0.875 0.25 -0.009 - 24 Ga 0 0 0 -0.015 - 25 Ga 0.5 0 0.5 -0.008 - 26 Ga 0 0.5 0.5 -0.008 - 27 Ga 0.5 0 0 -0.008 - 28 Ga 0.5 0.5 0 -0.015 - 29 Ga 0.5 0.5 0.5 -0.015 - 30 Ga 0 0 0.5 -0.008 - 31 Ga 0 0.5 0 -0.015 - 32 O 0.477008 0.380876 0.299196 0.186 - 33 O 0.522992 0.619124 0.700804 0.186 - 34 O 0.58168 0.177812 0.200804 0.238 - 35 O 0.91832 0.119124 0.596132 0.238 - 36 O 0.299196 0.477008 0.380876 0.197 - 37 O 0.322187 0.91832 0.299196 0.222 - 38 O 0.41832 0.822187 0.799196 0.238 - 39 O 0.08168 0.880876 0.403868 0.238 - 40 O 0.700804 0.522992 0.619124 0.197 - 41 O 0.677812 0.08168 0.700804 0.222 - 42 O 0.022992 0.322187 0.903868 0.186 - 43 O 0.200804 0.58168 0.177812 0.197 - 44 O 0.119124 0.022992 0.200804 0.207 - 45 O 0.977008 0.677812 0.096132 0.186 - 46 O 0.799196 0.41832 0.822187 0.197 - 47 O 0.880876 0.977008 0.799196 0.207 - 48 O 0.596132 0.91832 0.119124 0.228 - 49 O 0.177812 0.477008 0.596132 0.222 - 50 O 0.403868 0.08168 0.880876 0.228 - 51 O 0.822187 0.522992 0.403868 0.222 - 52 O 0.903868 0.022992 0.322187 0.228 - 53 O 0.380876 0.58168 0.903868 0.207 - 54 O 0.096132 0.977008 0.677813 0.228 - 55 O 0.619124 0.41832 0.096132 0.207 - 56 O 0.380876 0.299196 0.477008 0.207 - 57 O 0.58168 0.903868 0.380876 0.238 - 58 O 0.619124 0.700804 0.522992 0.207 - 59 O 0.41832 0.096132 0.619124 0.238 - 60 O 0.119124 0.596132 0.91832 0.207 - 61 O 0.022992 0.200804 0.119124 0.186 - 62 O 0.880876 0.403868 0.08168 0.207 - 63 O 0.977008 0.799196 0.880876 0.186 - 64 O 0.322187 0.903868 0.022992 0.222 - 65 O 0.91832 0.299196 0.322187 0.238 - 66 O 0.677812 0.096132 0.977008 0.222 - 67 O 0.08168 0.700804 0.677813 0.238 - 68 O 0.177812 0.200804 0.58168 0.222 - 69 O 0.477008 0.596132 0.177813 0.186 - 70 O 0.822187 0.799196 0.41832 0.222 - 71 O 0.522992 0.403868 0.822187 0.186 - 72 O 0.299196 0.322187 0.91832 0.197 - 73 O 0.700804 0.677812 0.08168 0.197 - 74 O 0.200804 0.119124 0.022992 0.197 - 75 O 0.799196 0.880876 0.977008 0.197 - 76 O 0.903868 0.380876 0.58168 0.228 - 77 O 0.096132 0.619124 0.41832 0.228 - 78 O 0.596132 0.177812 0.477008 0.228 - 79 O 0.403868 0.822187 0.522992 0.228","# generated using pymatgen -data_Cd3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.79782817 -_cell_length_b 10.79782817 -_cell_length_c 10.79782817 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Cd3Ga5O12 -_chemical_formula_sum 'Cd12 Ga20 O48' -_cell_volume 969.14184441 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Cd Cd0 1 0.25000000 0.37500000 0.12500000 1 - Cd Cd1 1 0.75000000 0.62500000 0.87500000 1 - Cd Cd2 1 0.75000000 0.12500000 0.37500000 1 - Cd Cd3 1 0.12500000 0.25000000 0.37500000 1 - Cd Cd4 1 0.37500000 0.75000000 0.12500000 1 - Cd Cd5 1 0.25000000 0.87500000 0.62500000 1 - Cd Cd6 1 0.87500000 0.75000000 0.62500000 1 - Cd Cd7 1 0.62500000 0.25000000 0.87500000 1 - Cd Cd8 1 0.37500000 0.12500000 0.25000000 1 - Cd Cd9 1 0.62500000 0.87500000 0.75000000 1 - Cd Cd10 1 0.12500000 0.37500000 0.75000000 1 - Cd Cd11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga13 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga14 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga17 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga18 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga19 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga24 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga25 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga26 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga28 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga29 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47700800 0.38087600 0.29919600 1 - O O33 1 0.52299200 0.61912400 0.70080400 1 - O O34 1 0.58168000 0.17781200 0.20080400 1 - O O35 1 0.91832000 0.11912400 0.59613200 1 - O O36 1 0.29919600 0.47700800 0.38087600 1 - O O37 1 0.32218700 0.91832000 0.29919600 1 - O O38 1 0.41832000 0.82218700 0.79919600 1 - O O39 1 0.08168000 0.88087600 0.40386800 1 - O O40 1 0.70080400 0.52299200 0.61912400 1 - O O41 1 0.67781200 0.08168000 0.70080400 1 - O O42 1 0.02299200 0.32218700 0.90386800 1 - O O43 1 0.20080400 0.58168000 0.17781200 1 - O O44 1 0.11912400 0.02299200 0.20080400 1 - O O45 1 0.97700800 0.67781200 0.09613200 1 - O O46 1 0.79919600 0.41832000 0.82218700 1 - O O47 1 0.88087600 0.97700800 0.79919600 1 - O O48 1 0.59613200 0.91832000 0.11912400 1 - O O49 1 0.17781200 0.47700800 0.59613200 1 - O O50 1 0.40386800 0.08168000 0.88087600 1 - O O51 1 0.82218700 0.52299200 0.40386800 1 - O O52 1 0.90386800 0.02299200 0.32218700 1 - O O53 1 0.38087600 0.58168000 0.90386800 1 - O O54 1 0.09613200 0.97700800 0.67781300 1 - O O55 1 0.61912400 0.41832000 0.09613200 1 - O O56 1 0.38087600 0.29919600 0.47700800 1 - O O57 1 0.58168000 0.90386800 0.38087600 1 - O O58 1 0.61912400 0.70080400 0.52299200 1 - O O59 1 0.41832000 0.09613200 0.61912400 1 - O O60 1 0.11912400 0.59613200 0.91832000 1 - O O61 1 0.02299200 0.20080400 0.11912400 1 - O O62 1 0.88087600 0.40386800 0.08168000 1 - O O63 1 0.97700800 0.79919600 0.88087600 1 - O O64 1 0.32218700 0.90386800 0.02299200 1 - O O65 1 0.91832000 0.29919600 0.32218700 1 - O O66 1 0.67781200 0.09613200 0.97700800 1 - O O67 1 0.08168000 0.70080400 0.67781300 1 - O O68 1 0.17781200 0.20080400 0.58168000 1 - O O69 1 0.47700800 0.59613200 0.17781300 1 - O O70 1 0.82218700 0.79919600 0.41832000 1 - O O71 1 0.52299200 0.40386800 0.82218700 1 - O O72 1 0.29919600 0.32218700 0.91832000 1 - O O73 1 0.70080400 0.67781200 0.08168000 1 - O O74 1 0.20080400 0.11912400 0.02299200 1 - O O75 1 0.79919600 0.88087600 0.97700800 1 - O O76 1 0.90386800 0.38087600 0.58168000 1 - O O77 1 0.09613200 0.61912400 0.41832000 1 - O O78 1 0.59613200 0.17781200 0.47700800 1 - O O79 1 0.40386800 0.82218700 0.52299200 1 -" -Dy3Al5O12,mp-772195,Ia-3d,[],0.0,{'tags': []},"Full Formula (Dy12 Al20 O48) -Reduced Formula: Dy3Al5O12 -abc : 10.492960 10.492960 10.492960 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Dy 0.875 0.625 0.25 0 - 1 Dy 0.375 0.75 0.125 0 - 2 Dy 0.25 0.375 0.125 0 - 3 Dy 0.875 0.75 0.625 0 - 4 Dy 0.75 0.125 0.375 0 - 5 Dy 0.375 0.125 0.25 0 - 6 Dy 0.625 0.875 0.75 0 - 7 Dy 0.25 0.875 0.625 0 - 8 Dy 0.125 0.25 0.375 0 - 9 Dy 0.75 0.625 0.875 0 - 10 Dy 0.625 0.25 0.875 0 - 11 Dy 0.125 0.375 0.75 0 - 12 Al 0.75 0.875 0.125 -0 - 13 Al 0.5 0.5 0 -0 - 14 Al 0.875 0.25 0.125 -0 - 15 Al 0.5 0 0 -0 - 16 Al 0 0.5 0 -0 - 17 Al 0.625 0.75 0.375 -0 - 18 Al 0.625 0.375 0.25 -0 - 19 Al 0.125 0.875 0.25 -0 - 20 Al 0 0 0 -0 - 21 Al 0.25 0.625 0.375 -0 - 22 Al 0.5 0.5 0.5 -0 - 23 Al 0.75 0.375 0.625 -0 - 24 Al 0 0.5 0.5 -0 - 25 Al 0.5 0 0.5 -0 - 26 Al 0.375 0.625 0.75 -0 - 27 Al 0.875 0.125 0.75 -0 - 28 Al 0.375 0.25 0.625 -0 - 29 Al 0 0 0.5 -0 - 30 Al 0.125 0.75 0.875 -0 - 31 Al 0.25 0.125 0.875 -0 - 32 O 0.979725 0.679491 0.098353 0 - 33 O 0.598353 0.918862 0.118628 0 - 34 O 0.320509 0.901647 0.020275 0 - 35 O 0.699766 0.679491 0.081138 0 - 36 O 0.881372 0.401647 0.081138 0 - 37 O 0.618628 0.418862 0.098353 0 - 38 O 0.479725 0.598353 0.179491 0 - 39 O 0.820509 0.800234 0.418862 0 - 40 O 0.581138 0.901647 0.381372 0 - 41 O 0.320509 0.918862 0.300234 0 - 42 O 0.918862 0.300234 0.320509 0 - 43 O 0.199766 0.118628 0.020275 0 - 44 O 0.199766 0.581138 0.179491 0 - 45 O 0.581138 0.179491 0.199766 0 - 46 O 0.820509 0.520275 0.401647 0 - 47 O 0.901647 0.020275 0.320509 0 - 48 O 0.479725 0.381372 0.300234 0 - 49 O 0.020275 0.199766 0.118628 0 - 50 O 0.618628 0.699766 0.520275 0 - 51 O 0.081138 0.881372 0.401647 0 - 52 O 0.401647 0.820509 0.520275 0 - 53 O 0.300234 0.479725 0.381372 0 - 54 O 0.901647 0.381372 0.581138 0 - 55 O 0.118628 0.020275 0.199766 0 - 56 O 0.881372 0.979725 0.800234 0 - 57 O 0.098353 0.618628 0.418862 0 - 58 O 0.699766 0.520275 0.618628 0 - 59 O 0.598353 0.179491 0.479725 0 - 60 O 0.918862 0.118628 0.598353 0 - 61 O 0.381372 0.300234 0.479725 0 - 62 O 0.979725 0.800234 0.881372 0 - 63 O 0.520275 0.618628 0.699766 0 - 64 O 0.098353 0.979725 0.679491 0 - 65 O 0.179491 0.479725 0.598353 0 - 66 O 0.418862 0.820509 0.800234 0 - 67 O 0.800234 0.418862 0.820509 0 - 68 O 0.800234 0.881372 0.979725 0 - 69 O 0.081138 0.699766 0.679491 0 - 70 O 0.679491 0.081138 0.699766 0 - 71 O 0.418862 0.098353 0.618628 0 - 72 O 0.179491 0.199766 0.581138 0 - 73 O 0.520275 0.401647 0.820509 0 - 74 O 0.381372 0.581138 0.901647 0 - 75 O 0.118628 0.598353 0.918862 0 - 76 O 0.300234 0.320509 0.918862 0 - 77 O 0.679491 0.098353 0.979725 0 - 78 O 0.401647 0.081138 0.881372 0 - 79 O 0.020275 0.320509 0.901647 0","# generated using pymatgen -data_Dy3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.49295951 -_cell_length_b 10.49295951 -_cell_length_c 10.49295951 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Dy3Al5O12 -_chemical_formula_sum 'Dy12 Al20 O48' -_cell_volume 889.34875371 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Dy Dy0 1 0.87500000 0.62500000 0.25000000 1 - Dy Dy1 1 0.37500000 0.75000000 0.12500000 1 - Dy Dy2 1 0.25000000 0.37500000 0.12500000 1 - Dy Dy3 1 0.87500000 0.75000000 0.62500000 1 - Dy Dy4 1 0.75000000 0.12500000 0.37500000 1 - Dy Dy5 1 0.37500000 0.12500000 0.25000000 1 - Dy Dy6 1 0.62500000 0.87500000 0.75000000 1 - Dy Dy7 1 0.25000000 0.87500000 0.62500000 1 - Dy Dy8 1 0.12500000 0.25000000 0.37500000 1 - Dy Dy9 1 0.75000000 0.62500000 0.87500000 1 - Dy Dy10 1 0.62500000 0.25000000 0.87500000 1 - Dy Dy11 1 0.12500000 0.37500000 0.75000000 1 - Al Al12 1 0.75000000 0.87500000 0.12500000 1 - Al Al13 1 0.50000000 0.50000000 0.00000000 1 - Al Al14 1 0.87500000 0.25000000 0.12500000 1 - Al Al15 1 0.50000000 0.00000000 0.00000000 1 - Al Al16 1 0.00000000 0.50000000 0.00000000 1 - Al Al17 1 0.62500000 0.75000000 0.37500000 1 - Al Al18 1 0.62500000 0.37500000 0.25000000 1 - Al Al19 1 0.12500000 0.87500000 0.25000000 1 - Al Al20 1 0.00000000 0.00000000 0.00000000 1 - Al Al21 1 0.25000000 0.62500000 0.37500000 1 - Al Al22 1 0.50000000 0.50000000 0.50000000 1 - Al Al23 1 0.75000000 0.37500000 0.62500000 1 - Al Al24 1 0.00000000 0.50000000 0.50000000 1 - Al Al25 1 0.50000000 0.00000000 0.50000000 1 - Al Al26 1 0.37500000 0.62500000 0.75000000 1 - Al Al27 1 0.87500000 0.12500000 0.75000000 1 - Al Al28 1 0.37500000 0.25000000 0.62500000 1 - Al Al29 1 0.00000000 0.00000000 0.50000000 1 - Al Al30 1 0.12500000 0.75000000 0.87500000 1 - Al Al31 1 0.25000000 0.12500000 0.87500000 1 - O O32 1 0.97972500 0.67949100 0.09835300 1 - O O33 1 0.59835300 0.91886200 0.11862800 1 - O O34 1 0.32050900 0.90164700 0.02027500 1 - O O35 1 0.69976600 0.67949100 0.08113800 1 - O O36 1 0.88137200 0.40164700 0.08113800 1 - O O37 1 0.61862800 0.41886200 0.09835300 1 - O O38 1 0.47972500 0.59835300 0.17949100 1 - O O39 1 0.82050900 0.80023400 0.41886200 1 - O O40 1 0.58113800 0.90164700 0.38137200 1 - O O41 1 0.32050900 0.91886200 0.30023400 1 - O O42 1 0.91886200 0.30023400 0.32050900 1 - O O43 1 0.19976600 0.11862800 0.02027500 1 - O O44 1 0.19976600 0.58113800 0.17949100 1 - O O45 1 0.58113800 0.17949100 0.19976600 1 - O O46 1 0.82050900 0.52027500 0.40164700 1 - O O47 1 0.90164700 0.02027500 0.32050900 1 - O O48 1 0.47972500 0.38137200 0.30023400 1 - O O49 1 0.02027500 0.19976600 0.11862800 1 - O O50 1 0.61862800 0.69976600 0.52027500 1 - O O51 1 0.08113800 0.88137200 0.40164700 1 - O O52 1 0.40164700 0.82050900 0.52027500 1 - O O53 1 0.30023400 0.47972500 0.38137200 1 - O O54 1 0.90164700 0.38137200 0.58113800 1 - O O55 1 0.11862800 0.02027500 0.19976600 1 - O O56 1 0.88137200 0.97972500 0.80023400 1 - O O57 1 0.09835300 0.61862800 0.41886200 1 - O O58 1 0.69976600 0.52027500 0.61862800 1 - O O59 1 0.59835300 0.17949100 0.47972500 1 - O O60 1 0.91886200 0.11862800 0.59835300 1 - O O61 1 0.38137200 0.30023400 0.47972500 1 - O O62 1 0.97972500 0.80023400 0.88137200 1 - O O63 1 0.52027500 0.61862800 0.69976600 1 - O O64 1 0.09835300 0.97972500 0.67949100 1 - O O65 1 0.17949100 0.47972500 0.59835300 1 - O O66 1 0.41886200 0.82050900 0.80023400 1 - O O67 1 0.80023400 0.41886200 0.82050900 1 - O O68 1 0.80023400 0.88137200 0.97972500 1 - O O69 1 0.08113800 0.69976600 0.67949100 1 - O O70 1 0.67949100 0.08113800 0.69976600 1 - O O71 1 0.41886200 0.09835300 0.61862800 1 - O O72 1 0.17949100 0.19976600 0.58113800 1 - O O73 1 0.52027500 0.40164700 0.82050900 1 - O O74 1 0.38137200 0.58113800 0.90164700 1 - O O75 1 0.11862800 0.59835300 0.91886200 1 - O O76 1 0.30023400 0.32050900 0.91886200 1 - O O77 1 0.67949100 0.09835300 0.97972500 1 - O O78 1 0.40164700 0.08113800 0.88137200 1 - O O79 1 0.02027500 0.32050900 0.90164700 1 -" -Dy3Fe5O12,mp-21974,Ia-3d,[23856],0.021609549749999957,{'tags': ['Pentairon(III) tridysprosium oxide']},"Full Formula (Dy12 Fe20 O48) -Reduced Formula: Dy3Fe5O12 -abc : 10.857625 10.857625 10.857625 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Dy 0.375 0.125 0.25 0.045 - 1 Dy 0.75 0.125 0.375 0.045 - 2 Dy 0.25 0.375 0.125 0.045 - 3 Dy 0.125 0.25 0.375 0.045 - 4 Dy 0.375 0.75 0.125 0.045 - 5 Dy 0.125 0.375 0.75 0.045 - 6 Dy 0.625 0.875 0.75 0.045 - 7 Dy 0.25 0.875 0.625 0.045 - 8 Dy 0.75 0.625 0.875 0.045 - 9 Dy 0.875 0.75 0.625 0.045 - 10 Dy 0.625 0.25 0.875 0.045 - 11 Dy 0.875 0.625 0.25 0.045 - 12 Fe 0 0 0 4.401 - 13 Fe 0.5 0 0 4.401 - 14 Fe 0 0.5 0 4.401 - 15 Fe 0 0 0.5 4.401 - 16 Fe 0.5 0.5 0 4.401 - 17 Fe 0 0.5 0.5 4.401 - 18 Fe 0.5 0 0.5 4.401 - 19 Fe 0.5 0.5 0.5 4.401 - 20 Fe 0.625 0.375 0.25 4.274 - 21 Fe 0.75 0.375 0.625 4.274 - 22 Fe 0.25 0.125 0.875 4.274 - 23 Fe 0.875 0.25 0.125 4.274 - 24 Fe 0.125 0.875 0.25 4.274 - 25 Fe 0.875 0.125 0.75 4.274 - 26 Fe 0.25 0.625 0.375 4.274 - 27 Fe 0.375 0.25 0.625 4.274 - 28 Fe 0.75 0.875 0.125 4.274 - 29 Fe 0.125 0.75 0.875 4.274 - 30 Fe 0.375 0.625 0.75 4.274 - 31 Fe 0.625 0.75 0.375 4.274 - 32 O 0.416336 0.822933 0.791124 0.217 - 33 O 0.874789 0.406598 0.083664 0.217 - 34 O 0.093402 0.968191 0.677067 0.217 - 35 O 0.531809 0.625211 0.708876 0.217 - 36 O 0.677067 0.083664 0.708876 0.217 - 37 O 0.625211 0.708876 0.531809 0.217 - 38 O 0.625211 0.416336 0.093402 0.217 - 39 O 0.708876 0.531809 0.625211 0.217 - 40 O 0.822933 0.531809 0.406598 0.217 - 41 O 0.968191 0.791124 0.874789 0.217 - 42 O 0.791124 0.874789 0.968191 0.217 - 43 O 0.708876 0.677067 0.083664 0.217 - 44 O 0.416336 0.093402 0.625211 0.217 - 45 O 0.406598 0.822933 0.531809 0.217 - 46 O 0.083664 0.708876 0.677067 0.217 - 47 O 0.093402 0.625211 0.416336 0.217 - 48 O 0.531809 0.406598 0.822933 0.217 - 49 O 0.083664 0.874789 0.406598 0.217 - 50 O 0.968191 0.677067 0.093402 0.217 - 51 O 0.177067 0.468191 0.593402 0.217 - 52 O 0.677067 0.093402 0.968191 0.217 - 53 O 0.791124 0.416336 0.822933 0.217 - 54 O 0.406598 0.083664 0.874789 0.217 - 55 O 0.874789 0.968191 0.791124 0.217 - 56 O 0.583664 0.177067 0.208876 0.217 - 57 O 0.125211 0.593402 0.916336 0.217 - 58 O 0.906598 0.031809 0.322933 0.217 - 59 O 0.468191 0.374789 0.291124 0.217 - 60 O 0.322933 0.916336 0.291124 0.217 - 61 O 0.374789 0.291124 0.468191 0.217 - 62 O 0.374789 0.583664 0.906598 0.217 - 63 O 0.291124 0.468191 0.374789 0.217 - 64 O 0.125211 0.031809 0.208876 0.217 - 65 O 0.593402 0.916336 0.125211 0.217 - 66 O 0.208876 0.583664 0.177067 0.217 - 67 O 0.177067 0.208876 0.583664 0.217 - 68 O 0.322933 0.906598 0.031809 0.217 - 69 O 0.031809 0.322933 0.906598 0.217 - 70 O 0.916336 0.125211 0.593402 0.217 - 71 O 0.468191 0.593402 0.177067 0.217 - 72 O 0.906598 0.374789 0.583664 0.217 - 73 O 0.916336 0.291124 0.322933 0.217 - 74 O 0.593402 0.177067 0.468191 0.217 - 75 O 0.583664 0.906598 0.374789 0.217 - 76 O 0.291124 0.322933 0.916336 0.217 - 77 O 0.208876 0.125211 0.031809 0.217 - 78 O 0.031809 0.208876 0.125211 0.217 - 79 O 0.822933 0.791124 0.416336 0.217","# generated using pymatgen -data_Dy3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.85762549 -_cell_length_b 10.85762549 -_cell_length_c 10.85762549 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Dy3Fe5O12 -_chemical_formula_sum 'Dy12 Fe20 O48' -_cell_volume 985.33221479 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Dy Dy0 1 0.37500000 0.12500000 0.25000000 1 - Dy Dy1 1 0.75000000 0.12500000 0.37500000 1 - Dy Dy2 1 0.25000000 0.37500000 0.12500000 1 - Dy Dy3 1 0.12500000 0.25000000 0.37500000 1 - Dy Dy4 1 0.37500000 0.75000000 0.12500000 1 - Dy Dy5 1 0.12500000 0.37500000 0.75000000 1 - Dy Dy6 1 0.62500000 0.87500000 0.75000000 1 - Dy Dy7 1 0.25000000 0.87500000 0.62500000 1 - Dy Dy8 1 0.75000000 0.62500000 0.87500000 1 - Dy Dy9 1 0.87500000 0.75000000 0.62500000 1 - Dy Dy10 1 0.62500000 0.25000000 0.87500000 1 - Dy Dy11 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe12 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe19 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe20 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe21 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe22 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe23 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe24 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe25 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe26 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe27 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe28 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe29 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe30 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.41633600 0.82293300 0.79112400 1 - O O33 1 0.87478900 0.40659800 0.08366400 1 - O O34 1 0.09340200 0.96819100 0.67706700 1 - O O35 1 0.53180900 0.62521100 0.70887600 1 - O O36 1 0.67706700 0.08366400 0.70887600 1 - O O37 1 0.62521100 0.70887600 0.53180900 1 - O O38 1 0.62521100 0.41633600 0.09340200 1 - O O39 1 0.70887600 0.53180900 0.62521100 1 - O O40 1 0.82293300 0.53180900 0.40659800 1 - O O41 1 0.96819100 0.79112400 0.87478900 1 - O O42 1 0.79112400 0.87478900 0.96819100 1 - O O43 1 0.70887600 0.67706700 0.08366400 1 - O O44 1 0.41633600 0.09340200 0.62521100 1 - O O45 1 0.40659800 0.82293300 0.53180900 1 - O O46 1 0.08366400 0.70887600 0.67706700 1 - O O47 1 0.09340200 0.62521100 0.41633600 1 - O O48 1 0.53180900 0.40659800 0.82293300 1 - O O49 1 0.08366400 0.87478900 0.40659800 1 - O O50 1 0.96819100 0.67706700 0.09340200 1 - O O51 1 0.17706700 0.46819100 0.59340200 1 - O O52 1 0.67706700 0.09340200 0.96819100 1 - O O53 1 0.79112400 0.41633600 0.82293300 1 - O O54 1 0.40659800 0.08366400 0.87478900 1 - O O55 1 0.87478900 0.96819100 0.79112400 1 - O O56 1 0.58366400 0.17706700 0.20887600 1 - O O57 1 0.12521100 0.59340200 0.91633600 1 - O O58 1 0.90659800 0.03180900 0.32293300 1 - O O59 1 0.46819100 0.37478900 0.29112400 1 - O O60 1 0.32293300 0.91633600 0.29112400 1 - O O61 1 0.37478900 0.29112400 0.46819100 1 - O O62 1 0.37478900 0.58366400 0.90659800 1 - O O63 1 0.29112400 0.46819100 0.37478900 1 - O O64 1 0.12521100 0.03180900 0.20887600 1 - O O65 1 0.59340200 0.91633600 0.12521100 1 - O O66 1 0.20887600 0.58366400 0.17706700 1 - O O67 1 0.17706700 0.20887600 0.58366400 1 - O O68 1 0.32293300 0.90659800 0.03180900 1 - O O69 1 0.03180900 0.32293300 0.90659800 1 - O O70 1 0.91633600 0.12521100 0.59340200 1 - O O71 1 0.46819100 0.59340200 0.17706700 1 - O O72 1 0.90659800 0.37478900 0.58366400 1 - O O73 1 0.91633600 0.29112400 0.32293300 1 - O O74 1 0.59340200 0.17706700 0.46819100 1 - O O75 1 0.58366400 0.90659800 0.37478900 1 - O O76 1 0.29112400 0.32293300 0.91633600 1 - O O77 1 0.20887600 0.12521100 0.03180900 1 - O O78 1 0.03180900 0.20887600 0.12521100 1 - O O79 1 0.82293300 0.79112400 0.41633600 1 -" -Dy3Ga5O12,mp-15576,Ia-3d,[409391],0.0,{'tags': ['Tridysprosium digallium tris(gallate)']},"Full Formula (Dy12 Ga20 O48) -Reduced Formula: Dy3Ga5O12 -abc : 10.748673 10.748673 10.748673 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Dy 0.75 0.625 0.875 -0 - 1 Dy 0.25 0.875 0.625 -0 - 2 Dy 0.625 0.25 0.875 -0 - 3 Dy 0.875 0.75 0.625 -0 - 4 Dy 0.875 0.625 0.25 -0 - 5 Dy 0.625 0.875 0.75 -0 - 6 Dy 0.25 0.375 0.125 -0 - 7 Dy 0.75 0.125 0.375 -0 - 8 Dy 0.375 0.75 0.125 -0 - 9 Dy 0.125 0.25 0.375 -0 - 10 Dy 0.125 0.375 0.75 -0 - 11 Dy 0.375 0.125 0.25 -0 - 12 Ga 0.375 0.625 0.75 -0 - 13 Ga 0.625 0.375 0.25 -0 - 14 Ga 0.625 0.75 0.375 -0 - 15 Ga 0.25 0.125 0.875 -0 - 16 Ga 0.875 0.25 0.125 -0 - 17 Ga 0.75 0.375 0.625 -0 - 18 Ga 0.25 0.625 0.375 -0 - 19 Ga 0.75 0.875 0.125 -0 - 20 Ga 0.125 0.75 0.875 -0 - 21 Ga 0.375 0.25 0.625 -0 - 22 Ga 0.875 0.125 0.75 -0 - 23 Ga 0.125 0.875 0.25 -0 - 24 Ga 0.5 0 0.5 -0 - 25 Ga 0 0.5 0 -0 - 26 Ga 0.5 0.5 0.5 -0 - 27 Ga 0 0 0.5 -0 - 28 Ga 0 0 0 -0 - 29 Ga 0 0.5 0.5 -0 - 30 Ga 0.5 0.5 0 -0 - 31 Ga 0.5 0 0 -0 - 32 O 0.528793 0.405299 0.822617 0 - 33 O 0.822617 0.528793 0.405299 0 - 34 O 0.793824 0.876506 0.971207 0 - 35 O 0.417318 0.094701 0.623494 0 - 36 O 0.876506 0.405299 0.082682 0 - 37 O 0.677383 0.082682 0.706176 0 - 38 O 0.822617 0.793824 0.417318 0 - 39 O 0.405299 0.822617 0.528793 0 - 40 O 0.623494 0.706176 0.528793 0 - 41 O 0.417318 0.822617 0.793824 0 - 42 O 0.405299 0.082682 0.876506 0 - 43 O 0.094701 0.971207 0.677383 0 - 44 O 0.971207 0.677383 0.094701 0 - 45 O 0.793824 0.417318 0.822617 0 - 46 O 0.528793 0.623494 0.706176 0 - 47 O 0.706176 0.528793 0.623494 0 - 48 O 0.082682 0.876506 0.405299 0 - 49 O 0.971207 0.793824 0.876506 0 - 50 O 0.082682 0.706176 0.677383 0 - 51 O 0.376506 0.293824 0.471207 0 - 52 O 0.623494 0.417318 0.094701 0 - 53 O 0.094701 0.623494 0.417318 0 - 54 O 0.706176 0.677383 0.082682 0 - 55 O 0.677383 0.094701 0.971207 0 - 56 O 0.471207 0.594701 0.177383 0 - 57 O 0.177383 0.471207 0.594701 0 - 58 O 0.206176 0.123494 0.028793 0 - 59 O 0.582682 0.905299 0.376506 0 - 60 O 0.123494 0.594701 0.917318 0 - 61 O 0.322617 0.917318 0.293824 0 - 62 O 0.177383 0.206176 0.582682 0 - 63 O 0.594701 0.177383 0.471207 0 - 64 O 0.322617 0.905299 0.028793 0 - 65 O 0.293824 0.322617 0.917318 0 - 66 O 0.905299 0.376506 0.582682 0 - 67 O 0.123494 0.028793 0.206176 0 - 68 O 0.376506 0.582682 0.905299 0 - 69 O 0.917318 0.293824 0.322617 0 - 70 O 0.028793 0.206176 0.123494 0 - 71 O 0.917318 0.123494 0.594701 0 - 72 O 0.293824 0.471207 0.376506 0 - 73 O 0.471207 0.376506 0.293824 0 - 74 O 0.206176 0.582682 0.177383 0 - 75 O 0.028793 0.322617 0.905299 0 - 76 O 0.905299 0.028793 0.322617 0 - 77 O 0.594701 0.917318 0.123494 0 - 78 O 0.582682 0.177383 0.206176 0 - 79 O 0.876506 0.971207 0.793824 0","# generated using pymatgen -data_Dy3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.74867257 -_cell_length_b 10.74867257 -_cell_length_c 10.74867257 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Dy3Ga5O12 -_chemical_formula_sum 'Dy12 Ga20 O48' -_cell_volume 955.96635847 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Dy Dy0 1 0.75000000 0.62500000 0.87500000 1 - Dy Dy1 1 0.25000000 0.87500000 0.62500000 1 - Dy Dy2 1 0.62500000 0.25000000 0.87500000 1 - Dy Dy3 1 0.87500000 0.75000000 0.62500000 1 - Dy Dy4 1 0.87500000 0.62500000 0.25000000 1 - Dy Dy5 1 0.62500000 0.87500000 0.75000000 1 - Dy Dy6 1 0.25000000 0.37500000 0.12500000 1 - Dy Dy7 1 0.75000000 0.12500000 0.37500000 1 - Dy Dy8 1 0.37500000 0.75000000 0.12500000 1 - Dy Dy9 1 0.12500000 0.25000000 0.37500000 1 - Dy Dy10 1 0.12500000 0.37500000 0.75000000 1 - Dy Dy11 1 0.37500000 0.12500000 0.25000000 1 - Ga Ga12 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga13 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga14 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga15 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga16 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga17 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga18 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga19 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga20 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga21 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga24 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga25 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga26 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga28 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga29 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.52879300 0.40529900 0.82261700 1 - O O33 1 0.82261700 0.52879300 0.40529900 1 - O O34 1 0.79382400 0.87650600 0.97120700 1 - O O35 1 0.41731800 0.09470100 0.62349400 1 - O O36 1 0.87650600 0.40529900 0.08268200 1 - O O37 1 0.67738300 0.08268200 0.70617600 1 - O O38 1 0.82261700 0.79382400 0.41731800 1 - O O39 1 0.40529900 0.82261700 0.52879300 1 - O O40 1 0.62349400 0.70617600 0.52879300 1 - O O41 1 0.41731800 0.82261700 0.79382400 1 - O O42 1 0.40529900 0.08268200 0.87650600 1 - O O43 1 0.09470100 0.97120700 0.67738300 1 - O O44 1 0.97120700 0.67738300 0.09470100 1 - O O45 1 0.79382400 0.41731800 0.82261700 1 - O O46 1 0.52879300 0.62349400 0.70617600 1 - O O47 1 0.70617600 0.52879300 0.62349400 1 - O O48 1 0.08268200 0.87650600 0.40529900 1 - O O49 1 0.97120700 0.79382400 0.87650600 1 - O O50 1 0.08268200 0.70617600 0.67738300 1 - O O51 1 0.37650600 0.29382400 0.47120700 1 - O O52 1 0.62349400 0.41731800 0.09470100 1 - O O53 1 0.09470100 0.62349400 0.41731800 1 - O O54 1 0.70617600 0.67738300 0.08268200 1 - O O55 1 0.67738300 0.09470100 0.97120700 1 - O O56 1 0.47120700 0.59470100 0.17738300 1 - O O57 1 0.17738300 0.47120700 0.59470100 1 - O O58 1 0.20617600 0.12349400 0.02879300 1 - O O59 1 0.58268200 0.90529900 0.37650600 1 - O O60 1 0.12349400 0.59470100 0.91731800 1 - O O61 1 0.32261700 0.91731800 0.29382400 1 - O O62 1 0.17738300 0.20617600 0.58268200 1 - O O63 1 0.59470100 0.17738300 0.47120700 1 - O O64 1 0.32261700 0.90529900 0.02879300 1 - O O65 1 0.29382400 0.32261700 0.91731800 1 - O O66 1 0.90529900 0.37650600 0.58268200 1 - O O67 1 0.12349400 0.02879300 0.20617600 1 - O O68 1 0.37650600 0.58268200 0.90529900 1 - O O69 1 0.91731800 0.29382400 0.32261700 1 - O O70 1 0.02879300 0.20617600 0.12349400 1 - O O71 1 0.91731800 0.12349400 0.59470100 1 - O O72 1 0.29382400 0.47120700 0.37650600 1 - O O73 1 0.47120700 0.37650600 0.29382400 1 - O O74 1 0.20617600 0.58268200 0.17738300 1 - O O75 1 0.02879300 0.32261700 0.90529900 1 - O O76 1 0.90529900 0.02879300 0.32261700 1 - O O77 1 0.59470100 0.91731800 0.12349400 1 - O O78 1 0.58268200 0.17738300 0.20617600 1 - O O79 1 0.87650600 0.97120700 0.79382400 1 -" -Er3Al5O12,mp-3384,Ia-3d,"[170147, 280606, 170146, 62615]",0.0,"{'tags': ['Garnet', 'Unnamed_Garnet', 'Trierbium pentaaluminium oxide', 'Trierbium pentaaluminate']}","Full Formula (Er12 Al20 O48) -Reduced Formula: Er3Al5O12 -abc : 10.435776 10.435776 10.435776 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Er 0.875 0.75 0.625 0 - 1 Er 0.875 0.625 0.25 0 - 2 Er 0.625 0.875 0.75 0 - 3 Er 0.25 0.875 0.625 0 - 4 Er 0.75 0.625 0.875 0 - 5 Er 0.625 0.25 0.875 0 - 6 Er 0.125 0.25 0.375 0 - 7 Er 0.125 0.375 0.75 0 - 8 Er 0.375 0.125 0.25 0 - 9 Er 0.75 0.125 0.375 0 - 10 Er 0.25 0.375 0.125 0 - 11 Er 0.375 0.75 0.125 0 - 12 Al 0.125 0.75 0.875 -0 - 13 Al 0.875 0.25 0.125 -0 - 14 Al 0.75 0.375 0.625 -0 - 15 Al 0.125 0.875 0.25 -0 - 16 Al 0.25 0.125 0.875 -0 - 17 Al 0.375 0.625 0.75 -0 - 18 Al 0.375 0.25 0.625 -0 - 19 Al 0.875 0.125 0.75 -0 - 20 Al 0.625 0.375 0.25 -0 - 21 Al 0.75 0.875 0.125 -0 - 22 Al 0.25 0.625 0.375 -0 - 23 Al 0.625 0.75 0.375 -0 - 24 Al 0.5 0 0.5 -0 - 25 Al 0 0.5 0 -0 - 26 Al 0.5 0.5 0.5 -0 - 27 Al 0 0 0.5 -0 - 28 Al 0 0 0 -0 - 29 Al 0 0.5 0.5 -0 - 30 Al 0.5 0.5 0 -0 - 31 Al 0.5 0 0 -0 - 32 O 0.880392 0.402013 0.081212 0 - 33 O 0.081212 0.880392 0.402013 0 - 34 O 0.700819 0.52162 0.619608 0 - 35 O 0.679199 0.097987 0.97838 0 - 36 O 0.52162 0.402013 0.820801 0 - 37 O 0.418788 0.820801 0.799181 0 - 38 O 0.081212 0.700819 0.679199 0 - 39 O 0.402013 0.081212 0.880392 0 - 40 O 0.97838 0.799181 0.880392 0 - 41 O 0.679199 0.081212 0.700819 0 - 42 O 0.402013 0.820801 0.52162 0 - 43 O 0.097987 0.619608 0.418788 0 - 44 O 0.619608 0.418788 0.097987 0 - 45 O 0.700819 0.679199 0.081212 0 - 46 O 0.880392 0.97838 0.799181 0 - 47 O 0.799181 0.880392 0.97838 0 - 48 O 0.820801 0.52162 0.402013 0 - 49 O 0.619608 0.700819 0.52162 0 - 50 O 0.820801 0.799181 0.418788 0 - 51 O 0.02162 0.200819 0.119608 0 - 52 O 0.97838 0.679199 0.097987 0 - 53 O 0.097987 0.97838 0.679199 0 - 54 O 0.799181 0.418788 0.820801 0 - 55 O 0.418788 0.097987 0.619608 0 - 56 O 0.119608 0.597987 0.918788 0 - 57 O 0.918788 0.119608 0.597987 0 - 58 O 0.299181 0.47838 0.380392 0 - 59 O 0.320801 0.902013 0.02162 0 - 60 O 0.47838 0.597987 0.179199 0 - 61 O 0.581212 0.179199 0.200819 0 - 62 O 0.918788 0.299181 0.320801 0 - 63 O 0.597987 0.918788 0.119608 0 - 64 O 0.581212 0.902013 0.380392 0 - 65 O 0.200819 0.581212 0.179199 0 - 66 O 0.902013 0.02162 0.320801 0 - 67 O 0.47838 0.380392 0.299181 0 - 68 O 0.02162 0.320801 0.902013 0 - 69 O 0.179199 0.200819 0.581212 0 - 70 O 0.380392 0.299181 0.47838 0 - 71 O 0.179199 0.47838 0.597987 0 - 72 O 0.200819 0.119608 0.02162 0 - 73 O 0.119608 0.02162 0.200819 0 - 74 O 0.299181 0.320801 0.918788 0 - 75 O 0.380392 0.581212 0.902013 0 - 76 O 0.902013 0.380392 0.581212 0 - 77 O 0.597987 0.179199 0.47838 0 - 78 O 0.320801 0.918788 0.299181 0 - 79 O 0.52162 0.619608 0.700819 0","# generated using pymatgen -data_Er3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.43577586 -_cell_length_b 10.43577586 -_cell_length_c 10.43577586 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Er3Al5O12 -_chemical_formula_sum 'Er12 Al20 O48' -_cell_volume 874.88775273 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Er Er0 1 0.87500000 0.75000000 0.62500000 1 - Er Er1 1 0.87500000 0.62500000 0.25000000 1 - Er Er2 1 0.62500000 0.87500000 0.75000000 1 - Er Er3 1 0.25000000 0.87500000 0.62500000 1 - Er Er4 1 0.75000000 0.62500000 0.87500000 1 - Er Er5 1 0.62500000 0.25000000 0.87500000 1 - Er Er6 1 0.12500000 0.25000000 0.37500000 1 - Er Er7 1 0.12500000 0.37500000 0.75000000 1 - Er Er8 1 0.37500000 0.12500000 0.25000000 1 - Er Er9 1 0.75000000 0.12500000 0.37500000 1 - Er Er10 1 0.25000000 0.37500000 0.12500000 1 - Er Er11 1 0.37500000 0.75000000 0.12500000 1 - Al Al12 1 0.12500000 0.75000000 0.87500000 1 - Al Al13 1 0.87500000 0.25000000 0.12500000 1 - Al Al14 1 0.75000000 0.37500000 0.62500000 1 - Al Al15 1 0.12500000 0.87500000 0.25000000 1 - Al Al16 1 0.25000000 0.12500000 0.87500000 1 - Al Al17 1 0.37500000 0.62500000 0.75000000 1 - Al Al18 1 0.37500000 0.25000000 0.62500000 1 - Al Al19 1 0.87500000 0.12500000 0.75000000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.75000000 0.87500000 0.12500000 1 - Al Al22 1 0.25000000 0.62500000 0.37500000 1 - Al Al23 1 0.62500000 0.75000000 0.37500000 1 - Al Al24 1 0.50000000 0.00000000 0.50000000 1 - Al Al25 1 0.00000000 0.50000000 0.00000000 1 - Al Al26 1 0.50000000 0.50000000 0.50000000 1 - Al Al27 1 0.00000000 0.00000000 0.50000000 1 - Al Al28 1 0.00000000 0.00000000 0.00000000 1 - Al Al29 1 0.00000000 0.50000000 0.50000000 1 - Al Al30 1 0.50000000 0.50000000 0.00000000 1 - Al Al31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.88039200 0.40201300 0.08121200 1 - O O33 1 0.08121200 0.88039200 0.40201300 1 - O O34 1 0.70081900 0.52162000 0.61960800 1 - O O35 1 0.67919900 0.09798700 0.97838000 1 - O O36 1 0.52162000 0.40201300 0.82080100 1 - O O37 1 0.41878800 0.82080100 0.79918100 1 - O O38 1 0.08121200 0.70081900 0.67919900 1 - O O39 1 0.40201300 0.08121200 0.88039200 1 - O O40 1 0.97838000 0.79918100 0.88039200 1 - O O41 1 0.67919900 0.08121200 0.70081900 1 - O O42 1 0.40201300 0.82080100 0.52162000 1 - O O43 1 0.09798700 0.61960800 0.41878800 1 - O O44 1 0.61960800 0.41878800 0.09798700 1 - O O45 1 0.70081900 0.67919900 0.08121200 1 - O O46 1 0.88039200 0.97838000 0.79918100 1 - O O47 1 0.79918100 0.88039200 0.97838000 1 - O O48 1 0.82080100 0.52162000 0.40201300 1 - O O49 1 0.61960800 0.70081900 0.52162000 1 - O O50 1 0.82080100 0.79918100 0.41878800 1 - O O51 1 0.02162000 0.20081900 0.11960800 1 - O O52 1 0.97838000 0.67919900 0.09798700 1 - O O53 1 0.09798700 0.97838000 0.67919900 1 - O O54 1 0.79918100 0.41878800 0.82080100 1 - O O55 1 0.41878800 0.09798700 0.61960800 1 - O O56 1 0.11960800 0.59798700 0.91878800 1 - O O57 1 0.91878800 0.11960800 0.59798700 1 - O O58 1 0.29918100 0.47838000 0.38039200 1 - O O59 1 0.32080100 0.90201300 0.02162000 1 - O O60 1 0.47838000 0.59798700 0.17919900 1 - O O61 1 0.58121200 0.17919900 0.20081900 1 - O O62 1 0.91878800 0.29918100 0.32080100 1 - O O63 1 0.59798700 0.91878800 0.11960800 1 - O O64 1 0.58121200 0.90201300 0.38039200 1 - O O65 1 0.20081900 0.58121200 0.17919900 1 - O O66 1 0.90201300 0.02162000 0.32080100 1 - O O67 1 0.47838000 0.38039200 0.29918100 1 - O O68 1 0.02162000 0.32080100 0.90201300 1 - O O69 1 0.17919900 0.20081900 0.58121200 1 - O O70 1 0.38039200 0.29918100 0.47838000 1 - O O71 1 0.17919900 0.47838000 0.59798700 1 - O O72 1 0.20081900 0.11960800 0.02162000 1 - O O73 1 0.11960800 0.02162000 0.20081900 1 - O O74 1 0.29918100 0.32080100 0.91878800 1 - O O75 1 0.38039200 0.58121200 0.90201300 1 - O O76 1 0.90201300 0.38039200 0.58121200 1 - O O77 1 0.59798700 0.17919900 0.47838000 1 - O O78 1 0.32080100 0.91878800 0.29918100 1 - O O79 1 0.52162000 0.61960800 0.70081900 1 -" -Er3Fe5O12,mp-560103,Ia-3d,[71464],0.03537093812500203,{'tags': ['Trierbium diiron(III) tris(ferrate(III))']},"Full Formula (Er12 Fe20 O48) -Reduced Formula: Er3Fe5O12 -abc : 10.806632 10.806632 10.806632 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Er 0.75 0.125 0.375 0.05 - 1 Er 0.375 0.125 0.25 0.05 - 2 Er 0.875 0.625 0.25 0.05 - 3 Er 0.25 0.875 0.625 0.05 - 4 Er 0.375 0.75 0.125 0.05 - 5 Er 0.75 0.625 0.875 0.05 - 6 Er 0.25 0.375 0.125 0.05 - 7 Er 0.125 0.25 0.375 0.05 - 8 Er 0.875 0.75 0.625 0.05 - 9 Er 0.125 0.375 0.75 0.05 - 10 Er 0.625 0.25 0.875 0.05 - 11 Er 0.625 0.875 0.75 0.05 - 12 Fe 0 0.5 0 4.4 - 13 Fe 0.125 0.75 0.875 4.274 - 14 Fe 0.5 0 0.5 4.4 - 15 Fe 0.75 0.375 0.625 4.274 - 16 Fe 0.5 0.5 0.5 4.4 - 17 Fe 0 0 0 4.4 - 18 Fe 0.5 0 0 4.4 - 19 Fe 0.625 0.375 0.25 4.274 - 20 Fe 0.75 0.875 0.125 4.274 - 21 Fe 0.5 0.5 0 4.4 - 22 Fe 0.125 0.875 0.25 4.274 - 23 Fe 0.25 0.625 0.375 4.274 - 24 Fe 0.25 0.125 0.875 4.274 - 25 Fe 0.375 0.625 0.75 4.274 - 26 Fe 0.625 0.75 0.375 4.274 - 27 Fe 0 0.5 0.5 4.4 - 28 Fe 0.375 0.25 0.625 4.274 - 29 Fe 0.875 0.125 0.75 4.274 - 30 Fe 0 0 0.5 4.4 - 31 Fe 0.875 0.25 0.125 4.274 - 32 O 0.176764 0.466848 0.593155 0.217 - 33 O 0.416392 0.093155 0.626308 0.217 - 34 O 0.966848 0.790084 0.873692 0.217 - 35 O 0.290084 0.323236 0.916392 0.217 - 36 O 0.406845 0.823236 0.533152 0.217 - 37 O 0.823236 0.790084 0.416392 0.217 - 38 O 0.323236 0.906845 0.033152 0.217 - 39 O 0.533152 0.626308 0.709916 0.217 - 40 O 0.416392 0.823236 0.790084 0.217 - 41 O 0.676764 0.093155 0.966848 0.217 - 42 O 0.373692 0.583608 0.906845 0.217 - 43 O 0.033152 0.209916 0.126308 0.217 - 44 O 0.916392 0.126308 0.593155 0.217 - 45 O 0.709916 0.533152 0.626308 0.217 - 46 O 0.593155 0.916392 0.126308 0.217 - 47 O 0.533152 0.406845 0.823236 0.217 - 48 O 0.323236 0.916392 0.290084 0.217 - 49 O 0.083608 0.873692 0.406845 0.217 - 50 O 0.676764 0.083608 0.709916 0.217 - 51 O 0.966848 0.676764 0.093155 0.217 - 52 O 0.126308 0.033152 0.209916 0.217 - 53 O 0.209916 0.583608 0.176764 0.217 - 54 O 0.093155 0.626308 0.416392 0.217 - 55 O 0.466848 0.373692 0.290084 0.217 - 56 O 0.176764 0.209916 0.583608 0.217 - 57 O 0.593155 0.176764 0.466848 0.217 - 58 O 0.126308 0.593155 0.916392 0.217 - 59 O 0.823236 0.533152 0.406845 0.217 - 60 O 0.290084 0.466848 0.373692 0.217 - 61 O 0.209916 0.126308 0.033152 0.217 - 62 O 0.873692 0.406845 0.083608 0.217 - 63 O 0.790084 0.873692 0.966848 0.217 - 64 O 0.916392 0.290084 0.323236 0.217 - 65 O 0.709916 0.676764 0.083608 0.217 - 66 O 0.406845 0.083608 0.873692 0.217 - 67 O 0.033152 0.323236 0.906845 0.217 - 68 O 0.873692 0.966848 0.790084 0.217 - 69 O 0.583608 0.176764 0.209916 0.217 - 70 O 0.906845 0.373692 0.583608 0.217 - 71 O 0.093155 0.966848 0.676764 0.217 - 72 O 0.583608 0.906845 0.373692 0.217 - 73 O 0.626308 0.416392 0.093155 0.217 - 74 O 0.906845 0.033152 0.323236 0.217 - 75 O 0.466848 0.593155 0.176764 0.217 - 76 O 0.083608 0.709916 0.676764 0.217 - 77 O 0.373692 0.290084 0.466848 0.217 - 78 O 0.626308 0.709916 0.533152 0.217 - 79 O 0.790084 0.416392 0.823236 0.217","# generated using pymatgen -data_Er3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.80663218 -_cell_length_b 10.80663218 -_cell_length_c 10.80663218 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Er3Fe5O12 -_chemical_formula_sum 'Er12 Fe20 O48' -_cell_volume 971.51434855 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Er Er0 1 0.75000000 0.12500000 0.37500000 1 - Er Er1 1 0.37500000 0.12500000 0.25000000 1 - Er Er2 1 0.87500000 0.62500000 0.25000000 1 - Er Er3 1 0.25000000 0.87500000 0.62500000 1 - Er Er4 1 0.37500000 0.75000000 0.12500000 1 - Er Er5 1 0.75000000 0.62500000 0.87500000 1 - Er Er6 1 0.25000000 0.37500000 0.12500000 1 - Er Er7 1 0.12500000 0.25000000 0.37500000 1 - Er Er8 1 0.87500000 0.75000000 0.62500000 1 - Er Er9 1 0.12500000 0.37500000 0.75000000 1 - Er Er10 1 0.62500000 0.25000000 0.87500000 1 - Er Er11 1 0.62500000 0.87500000 0.75000000 1 - Fe Fe12 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe13 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe14 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe15 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe16 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe17 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe20 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe21 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe22 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe23 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe24 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe25 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe26 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe27 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe28 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe29 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe30 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe31 1 0.87500000 0.25000000 0.12500000 1 - O O32 1 0.17676400 0.46684800 0.59315500 1 - O O33 1 0.41639200 0.09315500 0.62630800 1 - O O34 1 0.96684800 0.79008400 0.87369200 1 - O O35 1 0.29008400 0.32323600 0.91639200 1 - O O36 1 0.40684500 0.82323600 0.53315200 1 - O O37 1 0.82323600 0.79008400 0.41639200 1 - O O38 1 0.32323600 0.90684500 0.03315200 1 - O O39 1 0.53315200 0.62630800 0.70991600 1 - O O40 1 0.41639200 0.82323600 0.79008400 1 - O O41 1 0.67676400 0.09315500 0.96684800 1 - O O42 1 0.37369200 0.58360800 0.90684500 1 - O O43 1 0.03315200 0.20991600 0.12630800 1 - O O44 1 0.91639200 0.12630800 0.59315500 1 - O O45 1 0.70991600 0.53315200 0.62630800 1 - O O46 1 0.59315500 0.91639200 0.12630800 1 - O O47 1 0.53315200 0.40684500 0.82323600 1 - O O48 1 0.32323600 0.91639200 0.29008400 1 - O O49 1 0.08360800 0.87369200 0.40684500 1 - O O50 1 0.67676400 0.08360800 0.70991600 1 - O O51 1 0.96684800 0.67676400 0.09315500 1 - O O52 1 0.12630800 0.03315200 0.20991600 1 - O O53 1 0.20991600 0.58360800 0.17676400 1 - O O54 1 0.09315500 0.62630800 0.41639200 1 - O O55 1 0.46684800 0.37369200 0.29008400 1 - O O56 1 0.17676400 0.20991600 0.58360800 1 - O O57 1 0.59315500 0.17676400 0.46684800 1 - O O58 1 0.12630800 0.59315500 0.91639200 1 - O O59 1 0.82323600 0.53315200 0.40684500 1 - O O60 1 0.29008400 0.46684800 0.37369200 1 - O O61 1 0.20991600 0.12630800 0.03315200 1 - O O62 1 0.87369200 0.40684500 0.08360800 1 - O O63 1 0.79008400 0.87369200 0.96684800 1 - O O64 1 0.91639200 0.29008400 0.32323600 1 - O O65 1 0.70991600 0.67676400 0.08360800 1 - O O66 1 0.40684500 0.08360800 0.87369200 1 - O O67 1 0.03315200 0.32323600 0.90684500 1 - O O68 1 0.87369200 0.96684800 0.79008400 1 - O O69 1 0.58360800 0.17676400 0.20991600 1 - O O70 1 0.90684500 0.37369200 0.58360800 1 - O O71 1 0.09315500 0.96684800 0.67676400 1 - O O72 1 0.58360800 0.90684500 0.37369200 1 - O O73 1 0.62630800 0.41639200 0.09315500 1 - O O74 1 0.90684500 0.03315200 0.32323600 1 - O O75 1 0.46684800 0.59315500 0.17676400 1 - O O76 1 0.08360800 0.70991600 0.67676400 1 - O O77 1 0.37369200 0.29008400 0.46684800 1 - O O78 1 0.62630800 0.70991600 0.53315200 1 - O O79 1 0.79008400 0.41639200 0.82323600 1 -" -Er3Ga5O12,mp-12236,Ia-3d,[9238],0.0,{'tags': ['Trierbium pentagallium oxide']},"Full Formula (Er12 Ga20 O48) -Reduced Formula: Er3Ga5O12 -abc : 10.696945 10.696945 10.696945 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Er 0.875 0.625 0.25 -0.001 - 1 Er 0.625 0.25 0.875 -0.001 - 2 Er 0.875 0.75 0.625 -0.001 - 3 Er 0.75 0.625 0.875 -0.001 - 4 Er 0.25 0.875 0.625 -0.001 - 5 Er 0.625 0.875 0.75 -0.001 - 6 Er 0.125 0.375 0.75 -0.001 - 7 Er 0.375 0.75 0.125 -0.001 - 8 Er 0.125 0.25 0.375 -0.001 - 9 Er 0.25 0.375 0.125 -0.001 - 10 Er 0.75 0.125 0.375 -0.001 - 11 Er 0.375 0.125 0.25 -0.001 - 12 Ga 0.125 0.875 0.25 -0 - 13 Ga 0.875 0.125 0.75 -0 - 14 Ga 0.25 0.625 0.375 -0 - 15 Ga 0.375 0.25 0.625 -0 - 16 Ga 0.75 0.875 0.125 -0 - 17 Ga 0.125 0.75 0.875 -0 - 18 Ga 0.375 0.625 0.75 -0 - 19 Ga 0.625 0.75 0.375 -0 - 20 Ga 0.875 0.25 0.125 -0 - 21 Ga 0.25 0.125 0.875 -0 - 22 Ga 0.75 0.375 0.625 -0 - 23 Ga 0.625 0.375 0.25 -0 - 24 Ga 0.5 0.5 0.5 -0 - 25 Ga 0.5 0 0.5 -0 - 26 Ga 0 0.5 0.5 -0 - 27 Ga 0.5 0.5 0 -0 - 28 Ga 0 0 0.5 -0 - 29 Ga 0 0.5 0 -0 - 30 Ga 0.5 0 0 -0 - 31 Ga 0 0 0 -0 - 32 O 0.469782 0.375557 0.292626 0.001 - 33 O 0.322844 0.905775 0.030218 0.001 - 34 O 0.594225 0.917069 0.124443 0.001 - 35 O 0.582931 0.177156 0.207374 0.001 - 36 O 0.124443 0.030218 0.207374 0.001 - 37 O 0.177156 0.207374 0.582931 0.001 - 38 O 0.177156 0.469782 0.594225 0.001 - 39 O 0.207374 0.582931 0.177156 0.001 - 40 O 0.375557 0.582931 0.905775 0.001 - 41 O 0.917069 0.292626 0.322844 0.001 - 42 O 0.292626 0.322844 0.917069 0.001 - 43 O 0.207374 0.124443 0.030218 0.001 - 44 O 0.469782 0.594225 0.177156 0.001 - 45 O 0.905775 0.375557 0.582931 0.001 - 46 O 0.030218 0.207374 0.124443 0.001 - 47 O 0.594225 0.177156 0.469782 0.001 - 48 O 0.582931 0.905775 0.375557 0.001 - 49 O 0.030218 0.322844 0.905775 0.001 - 50 O 0.917069 0.124443 0.594225 0.001 - 51 O 0.624443 0.417069 0.094225 0.001 - 52 O 0.124443 0.594225 0.917069 0.001 - 53 O 0.292626 0.469782 0.375557 0.001 - 54 O 0.905775 0.030218 0.322844 0.001 - 55 O 0.322844 0.917069 0.292626 0.001 - 56 O 0.530218 0.624443 0.707374 0.001 - 57 O 0.677156 0.094225 0.969782 0.001 - 58 O 0.405775 0.082931 0.875557 0.001 - 59 O 0.417069 0.822844 0.792626 0.001 - 60 O 0.875557 0.969782 0.792626 0.001 - 61 O 0.822844 0.792626 0.417069 0.001 - 62 O 0.822844 0.530218 0.405775 0.001 - 63 O 0.792626 0.417069 0.822844 0.001 - 64 O 0.677156 0.082931 0.707374 0.001 - 65 O 0.094225 0.969782 0.677156 0.001 - 66 O 0.707374 0.530218 0.624443 0.001 - 67 O 0.624443 0.707374 0.530218 0.001 - 68 O 0.875557 0.405775 0.082931 0.001 - 69 O 0.082931 0.875557 0.405775 0.001 - 70 O 0.969782 0.677156 0.094225 0.001 - 71 O 0.417069 0.094225 0.624443 0.001 - 72 O 0.405775 0.822844 0.530218 0.001 - 73 O 0.969782 0.792626 0.875557 0.001 - 74 O 0.094225 0.624443 0.417069 0.001 - 75 O 0.530218 0.405775 0.822844 0.001 - 76 O 0.792626 0.875557 0.969782 0.001 - 77 O 0.707374 0.677156 0.082931 0.001 - 78 O 0.082931 0.707374 0.677156 0.001 - 79 O 0.375557 0.292626 0.469782 0.001","# generated using pymatgen -data_Er3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.69694487 -_cell_length_b 10.69694487 -_cell_length_c 10.69694487 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Er3Ga5O12 -_chemical_formula_sum 'Er12 Ga20 O48' -_cell_volume 942.23098508 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Er Er0 1 0.87500000 0.62500000 0.25000000 1 - Er Er1 1 0.62500000 0.25000000 0.87500000 1 - Er Er2 1 0.87500000 0.75000000 0.62500000 1 - Er Er3 1 0.75000000 0.62500000 0.87500000 1 - Er Er4 1 0.25000000 0.87500000 0.62500000 1 - Er Er5 1 0.62500000 0.87500000 0.75000000 1 - Er Er6 1 0.12500000 0.37500000 0.75000000 1 - Er Er7 1 0.37500000 0.75000000 0.12500000 1 - Er Er8 1 0.12500000 0.25000000 0.37500000 1 - Er Er9 1 0.25000000 0.37500000 0.12500000 1 - Er Er10 1 0.75000000 0.12500000 0.37500000 1 - Er Er11 1 0.37500000 0.12500000 0.25000000 1 - Ga Ga12 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga13 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga14 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga17 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga18 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga19 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga20 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga21 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga22 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga23 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga24 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga25 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga26 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga28 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga29 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga30 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.46978200 0.37555700 0.29262600 1 - O O33 1 0.32284400 0.90577500 0.03021800 1 - O O34 1 0.59422500 0.91706900 0.12444300 1 - O O35 1 0.58293100 0.17715600 0.20737400 1 - O O36 1 0.12444300 0.03021800 0.20737400 1 - O O37 1 0.17715600 0.20737400 0.58293100 1 - O O38 1 0.17715600 0.46978200 0.59422500 1 - O O39 1 0.20737400 0.58293100 0.17715600 1 - O O40 1 0.37555700 0.58293100 0.90577500 1 - O O41 1 0.91706900 0.29262600 0.32284400 1 - O O42 1 0.29262600 0.32284400 0.91706900 1 - O O43 1 0.20737400 0.12444300 0.03021800 1 - O O44 1 0.46978200 0.59422500 0.17715600 1 - O O45 1 0.90577500 0.37555700 0.58293100 1 - O O46 1 0.03021800 0.20737400 0.12444300 1 - O O47 1 0.59422500 0.17715600 0.46978200 1 - O O48 1 0.58293100 0.90577500 0.37555700 1 - O O49 1 0.03021800 0.32284400 0.90577500 1 - O O50 1 0.91706900 0.12444300 0.59422500 1 - O O51 1 0.62444300 0.41706900 0.09422500 1 - O O52 1 0.12444300 0.59422500 0.91706900 1 - O O53 1 0.29262600 0.46978200 0.37555700 1 - O O54 1 0.90577500 0.03021800 0.32284400 1 - O O55 1 0.32284400 0.91706900 0.29262600 1 - O O56 1 0.53021800 0.62444300 0.70737400 1 - O O57 1 0.67715600 0.09422500 0.96978200 1 - O O58 1 0.40577500 0.08293100 0.87555700 1 - O O59 1 0.41706900 0.82284400 0.79262600 1 - O O60 1 0.87555700 0.96978200 0.79262600 1 - O O61 1 0.82284400 0.79262600 0.41706900 1 - O O62 1 0.82284400 0.53021800 0.40577500 1 - O O63 1 0.79262600 0.41706900 0.82284400 1 - O O64 1 0.67715600 0.08293100 0.70737400 1 - O O65 1 0.09422500 0.96978200 0.67715600 1 - O O66 1 0.70737400 0.53021800 0.62444300 1 - O O67 1 0.62444300 0.70737400 0.53021800 1 - O O68 1 0.87555700 0.40577500 0.08293100 1 - O O69 1 0.08293100 0.87555700 0.40577500 1 - O O70 1 0.96978200 0.67715600 0.09422500 1 - O O71 1 0.41706900 0.09422500 0.62444300 1 - O O72 1 0.40577500 0.82284400 0.53021800 1 - O O73 1 0.96978200 0.79262600 0.87555700 1 - O O74 1 0.09422500 0.62444300 0.41706900 1 - O O75 1 0.53021800 0.40577500 0.82284400 1 - O O76 1 0.79262600 0.87555700 0.96978200 1 - O O77 1 0.70737400 0.67715600 0.08293100 1 - O O78 1 0.08293100 0.70737400 0.67715600 1 - O O79 1 0.37555700 0.29262600 0.46978200 1 -" -Eu3Al5O12,mp-21757,Ia-3d,[245326],0.0,"{'tags': ['Garnet, (Eu,Al-containg)', 'Trieuropium pentaaluminium oxide']}","Full Formula (Eu12 Al20 O48) -Reduced Formula: Eu3Al5O12 -abc : 10.632667 10.632667 10.632667 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Eu 0.875 0.625 0.25 6.215 - 1 Eu 0.625 0.25 0.875 6.215 - 2 Eu 0.875 0.75 0.625 6.215 - 3 Eu 0.75 0.625 0.875 6.202 - 4 Eu 0.25 0.875 0.625 6.212 - 5 Eu 0.625 0.875 0.75 6.215 - 6 Eu 0.125 0.375 0.75 6.215 - 7 Eu 0.375 0.75 0.125 6.215 - 8 Eu 0.125 0.25 0.375 6.215 - 9 Eu 0.25 0.375 0.125 6.202 - 10 Eu 0.75 0.125 0.375 6.212 - 11 Eu 0.375 0.125 0.25 6.215 - 12 Al 0.125 0.875 0.25 0.001 - 13 Al 0.875 0.125 0.75 0.001 - 14 Al 0.25 0.625 0.375 0.001 - 15 Al 0.375 0.25 0.625 0.001 - 16 Al 0.75 0.875 0.125 0.001 - 17 Al 0.125 0.75 0.875 0.001 - 18 Al 0.375 0.625 0.75 0.001 - 19 Al 0.625 0.75 0.375 0.001 - 20 Al 0.875 0.25 0.125 0.001 - 21 Al 0.25 0.125 0.875 0.001 - 22 Al 0.75 0.375 0.625 0.001 - 23 Al 0.625 0.375 0.25 0.001 - 24 Al 0.5 0.5 0.5 0.001 - 25 Al 0.5 0 0.5 0.001 - 26 Al 0 0.5 0.5 0.001 - 27 Al 0.5 0.5 0 0.001 - 28 Al 0 0 0.5 0.001 - 29 Al 0 0.5 0 0.001 - 30 Al 0.5 0 0 0.001 - 31 Al 0 0 0 0.001 - 32 O 0.92019 0.115472 0.600491 -0.06 - 33 O 0.180301 0.195282 0.57981 -0.06 - 34 O 0.304718 0.485019 0.384528 -0.061 - 35 O 0.014981 0.319699 0.899509 -0.062 - 36 O 0.384528 0.57981 0.899509 -0.06 - 37 O 0.319699 0.899509 0.014981 -0.06 - 38 O 0.319699 0.92019 0.304718 -0.06 - 39 O 0.899509 0.014981 0.319699 -0.06 - 40 O 0.115472 0.014981 0.195282 -0.06 - 41 O 0.485019 0.600491 0.180301 -0.062 - 42 O 0.600491 0.180301 0.485019 -0.06 - 43 O 0.899509 0.384528 0.57981 -0.06 - 44 O 0.92019 0.304718 0.319699 -0.06 - 45 O 0.195282 0.115472 0.014981 -0.061 - 46 O 0.57981 0.899509 0.384528 -0.06 - 47 O 0.304718 0.319699 0.92019 -0.061 - 48 O 0.014981 0.195282 0.115472 -0.062 - 49 O 0.57981 0.180301 0.195282 -0.06 - 50 O 0.485019 0.384528 0.304718 -0.062 - 51 O 0.884528 0.985019 0.804718 -0.06 - 52 O 0.384528 0.304718 0.485019 -0.06 - 53 O 0.600491 0.92019 0.115472 -0.06 - 54 O 0.195282 0.57981 0.180301 -0.061 - 55 O 0.180301 0.485019 0.600491 -0.06 - 56 O 0.07981 0.884528 0.399509 -0.06 - 57 O 0.819699 0.804718 0.42019 -0.06 - 58 O 0.695282 0.514981 0.615472 -0.061 - 59 O 0.985019 0.680301 0.100491 -0.062 - 60 O 0.615472 0.42019 0.100491 -0.06 - 61 O 0.680301 0.100491 0.985019 -0.06 - 62 O 0.680301 0.07981 0.695282 -0.06 - 63 O 0.100491 0.985019 0.680301 -0.06 - 64 O 0.819699 0.514981 0.399509 -0.06 - 65 O 0.804718 0.42019 0.819699 -0.061 - 66 O 0.399509 0.07981 0.884528 -0.06 - 67 O 0.884528 0.399509 0.07981 -0.06 - 68 O 0.615472 0.695282 0.514981 -0.06 - 69 O 0.514981 0.615472 0.695282 -0.062 - 70 O 0.42019 0.819699 0.804718 -0.06 - 71 O 0.985019 0.804718 0.884528 -0.062 - 72 O 0.695282 0.680301 0.07981 -0.061 - 73 O 0.42019 0.100491 0.615472 -0.06 - 74 O 0.804718 0.884528 0.985019 -0.061 - 75 O 0.07981 0.695282 0.680301 -0.06 - 76 O 0.100491 0.615472 0.42019 -0.06 - 77 O 0.399509 0.819699 0.514981 -0.06 - 78 O 0.514981 0.399509 0.819699 -0.062 - 79 O 0.115472 0.600491 0.92019 -0.06","# generated using pymatgen -data_Eu3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.63266673 -_cell_length_b 10.63266673 -_cell_length_c 10.63266673 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Eu3Al5O12 -_chemical_formula_sum 'Eu12 Al20 O48' -_cell_volume 925.34719801 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Eu Eu0 1 0.87500000 0.62500000 0.25000000 1 - Eu Eu1 1 0.62500000 0.25000000 0.87500000 1 - Eu Eu2 1 0.87500000 0.75000000 0.62500000 1 - Eu Eu3 1 0.75000000 0.62500000 0.87500000 1 - Eu Eu4 1 0.25000000 0.87500000 0.62500000 1 - Eu Eu5 1 0.62500000 0.87500000 0.75000000 1 - Eu Eu6 1 0.12500000 0.37500000 0.75000000 1 - Eu Eu7 1 0.37500000 0.75000000 0.12500000 1 - Eu Eu8 1 0.12500000 0.25000000 0.37500000 1 - Eu Eu9 1 0.25000000 0.37500000 0.12500000 1 - Eu Eu10 1 0.75000000 0.12500000 0.37500000 1 - Eu Eu11 1 0.37500000 0.12500000 0.25000000 1 - Al Al12 1 0.12500000 0.87500000 0.25000000 1 - Al Al13 1 0.87500000 0.12500000 0.75000000 1 - Al Al14 1 0.25000000 0.62500000 0.37500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.75000000 0.87500000 0.12500000 1 - Al Al17 1 0.12500000 0.75000000 0.87500000 1 - Al Al18 1 0.37500000 0.62500000 0.75000000 1 - Al Al19 1 0.62500000 0.75000000 0.37500000 1 - Al Al20 1 0.87500000 0.25000000 0.12500000 1 - Al Al21 1 0.25000000 0.12500000 0.87500000 1 - Al Al22 1 0.75000000 0.37500000 0.62500000 1 - Al Al23 1 0.62500000 0.37500000 0.25000000 1 - Al Al24 1 0.50000000 0.50000000 0.50000000 1 - Al Al25 1 0.50000000 0.00000000 0.50000000 1 - Al Al26 1 0.00000000 0.50000000 0.50000000 1 - Al Al27 1 0.50000000 0.50000000 0.00000000 1 - Al Al28 1 0.00000000 0.00000000 0.50000000 1 - Al Al29 1 0.00000000 0.50000000 0.00000000 1 - Al Al30 1 0.50000000 0.00000000 0.00000000 1 - Al Al31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.92019000 0.11547200 0.60049100 1 - O O33 1 0.18030100 0.19528200 0.57981000 1 - O O34 1 0.30471800 0.48501900 0.38452800 1 - O O35 1 0.01498100 0.31969900 0.89950900 1 - O O36 1 0.38452800 0.57981000 0.89950900 1 - O O37 1 0.31969900 0.89950900 0.01498100 1 - O O38 1 0.31969900 0.92019000 0.30471800 1 - O O39 1 0.89950900 0.01498100 0.31969900 1 - O O40 1 0.11547200 0.01498100 0.19528200 1 - O O41 1 0.48501900 0.60049100 0.18030100 1 - O O42 1 0.60049100 0.18030100 0.48501900 1 - O O43 1 0.89950900 0.38452800 0.57981000 1 - O O44 1 0.92019000 0.30471800 0.31969900 1 - O O45 1 0.19528200 0.11547200 0.01498100 1 - O O46 1 0.57981000 0.89950900 0.38452800 1 - O O47 1 0.30471800 0.31969900 0.92019000 1 - O O48 1 0.01498100 0.19528200 0.11547200 1 - O O49 1 0.57981000 0.18030100 0.19528200 1 - O O50 1 0.48501900 0.38452800 0.30471800 1 - O O51 1 0.88452800 0.98501900 0.80471800 1 - O O52 1 0.38452800 0.30471800 0.48501900 1 - O O53 1 0.60049100 0.92019000 0.11547200 1 - O O54 1 0.19528200 0.57981000 0.18030100 1 - O O55 1 0.18030100 0.48501900 0.60049100 1 - O O56 1 0.07981000 0.88452800 0.39950900 1 - O O57 1 0.81969900 0.80471800 0.42019000 1 - O O58 1 0.69528200 0.51498100 0.61547200 1 - O O59 1 0.98501900 0.68030100 0.10049100 1 - O O60 1 0.61547200 0.42019000 0.10049100 1 - O O61 1 0.68030100 0.10049100 0.98501900 1 - O O62 1 0.68030100 0.07981000 0.69528200 1 - O O63 1 0.10049100 0.98501900 0.68030100 1 - O O64 1 0.81969900 0.51498100 0.39950900 1 - O O65 1 0.80471800 0.42019000 0.81969900 1 - O O66 1 0.39950900 0.07981000 0.88452800 1 - O O67 1 0.88452800 0.39950900 0.07981000 1 - O O68 1 0.61547200 0.69528200 0.51498100 1 - O O69 1 0.51498100 0.61547200 0.69528200 1 - O O70 1 0.42019000 0.81969900 0.80471800 1 - O O71 1 0.98501900 0.80471800 0.88452800 1 - O O72 1 0.69528200 0.68030100 0.07981000 1 - O O73 1 0.42019000 0.10049100 0.61547200 1 - O O74 1 0.80471800 0.88452800 0.98501900 1 - O O75 1 0.07981000 0.69528200 0.68030100 1 - O O76 1 0.10049100 0.61547200 0.42019000 1 - O O77 1 0.39950900 0.81969900 0.51498100 1 - O O78 1 0.51498100 0.39950900 0.81969900 1 - O O79 1 0.11547200 0.60049100 0.92019000 1 -" -Eu3Fe5O12,mp-555758,Ia-3d,[9232],0.0,{'tags': ['Trieuropium pentairon(III) oxide']},"Full Formula (Eu12 Fe20 O48) -Reduced Formula: Eu3Fe5O12 -abc : 11.012952 11.012952 11.012952 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Eu 0.625 0.875 0.75 6.293 - 1 Eu 0.75 0.125 0.375 6.263 - 2 Eu 0.625 0.25 0.875 6.293 - 3 Eu 0.125 0.25 0.375 6.293 - 4 Eu 0.25 0.375 0.125 6.27 - 5 Eu 0.875 0.75 0.625 6.293 - 6 Eu 0.875 0.625 0.25 6.293 - 7 Eu 0.125 0.375 0.75 6.293 - 8 Eu 0.375 0.125 0.25 6.293 - 9 Eu 0.25 0.875 0.625 6.263 - 10 Eu 0.75 0.625 0.875 6.27 - 11 Eu 0.375 0.75 0.125 6.293 - 12 Fe 0.875 0.25 0.125 4.252 - 13 Fe 0.75 0.875 0.125 4.252 - 14 Fe 0.125 0.75 0.875 4.252 - 15 Fe 0 0.5 0.5 4.38 - 16 Fe 0 0.5 0 4.382 - 17 Fe 0.5 0.5 0.5 4.382 - 18 Fe 0 0 0 4.382 - 19 Fe 0.375 0.625 0.75 4.252 - 20 Fe 0.625 0.75 0.375 4.252 - 21 Fe 0.625 0.375 0.25 4.252 - 22 Fe 0.5 0.5 0 4.382 - 23 Fe 0.75 0.375 0.625 4.252 - 24 Fe 0.25 0.625 0.375 4.252 - 25 Fe 0.25 0.125 0.875 4.252 - 26 Fe 0.5 0 0.5 4.38 - 27 Fe 0.375 0.25 0.625 4.252 - 28 Fe 0.125 0.875 0.25 4.252 - 29 Fe 0 0 0.5 4.38 - 30 Fe 0.875 0.125 0.75 4.252 - 31 Fe 0.5 0 0 4.38 - 32 O 0.524956 0.404071 0.821982 0.153 - 33 O 0.297026 0.475044 0.379114 0.15 - 34 O 0.379114 0.582089 0.904071 0.156 - 35 O 0.821982 0.524956 0.404071 0.152 - 36 O 0.178018 0.475044 0.595929 0.152 - 37 O 0.678018 0.082089 0.702974 0.152 - 38 O 0.975044 0.678018 0.095929 0.153 - 39 O 0.321982 0.917911 0.297026 0.152 - 40 O 0.024956 0.202974 0.120886 0.153 - 41 O 0.082089 0.879114 0.404071 0.151 - 42 O 0.082089 0.702974 0.678018 0.151 - 43 O 0.702974 0.524956 0.620886 0.15 - 44 O 0.620886 0.702974 0.524956 0.156 - 45 O 0.404071 0.821982 0.524956 0.152 - 46 O 0.904071 0.024956 0.321982 0.152 - 47 O 0.202974 0.120886 0.024956 0.15 - 48 O 0.595929 0.917911 0.120886 0.152 - 49 O 0.178018 0.202974 0.582089 0.152 - 50 O 0.379114 0.297026 0.475044 0.156 - 51 O 0.582089 0.904071 0.379114 0.151 - 52 O 0.404071 0.082089 0.879114 0.152 - 53 O 0.595929 0.178018 0.475044 0.152 - 54 O 0.095929 0.975044 0.678018 0.152 - 55 O 0.202974 0.582089 0.178018 0.15 - 56 O 0.797026 0.879114 0.975044 0.15 - 57 O 0.917911 0.120886 0.595929 0.151 - 58 O 0.879114 0.404071 0.082089 0.156 - 59 O 0.975044 0.797026 0.879114 0.153 - 60 O 0.917911 0.297026 0.321982 0.151 - 61 O 0.120886 0.595929 0.917911 0.156 - 62 O 0.702974 0.678018 0.082089 0.15 - 63 O 0.417911 0.821982 0.797026 0.151 - 64 O 0.620886 0.417911 0.095929 0.156 - 65 O 0.904071 0.379114 0.582089 0.152 - 66 O 0.797026 0.417911 0.821982 0.15 - 67 O 0.821982 0.797026 0.417911 0.152 - 68 O 0.678018 0.095929 0.975044 0.152 - 69 O 0.524956 0.620886 0.702974 0.153 - 70 O 0.417911 0.095929 0.620886 0.151 - 71 O 0.297026 0.321982 0.917911 0.15 - 72 O 0.120886 0.024956 0.202974 0.156 - 73 O 0.321982 0.904071 0.024956 0.152 - 74 O 0.475044 0.379114 0.297026 0.153 - 75 O 0.582089 0.178018 0.202974 0.151 - 76 O 0.024956 0.321982 0.904071 0.153 - 77 O 0.879114 0.975044 0.797026 0.156 - 78 O 0.475044 0.595929 0.178018 0.153 - 79 O 0.095929 0.620886 0.417911 0.152","# generated using pymatgen -data_Eu3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.01295234 -_cell_length_b 11.01295234 -_cell_length_c 11.01295234 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Eu3Fe5O12 -_chemical_formula_sum 'Eu12 Fe20 O48' -_cell_volume 1028.22791199 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Eu Eu0 1 0.62500000 0.87500000 0.75000000 1 - Eu Eu1 1 0.75000000 0.12500000 0.37500000 1 - Eu Eu2 1 0.62500000 0.25000000 0.87500000 1 - Eu Eu3 1 0.12500000 0.25000000 0.37500000 1 - Eu Eu4 1 0.25000000 0.37500000 0.12500000 1 - Eu Eu5 1 0.87500000 0.75000000 0.62500000 1 - Eu Eu6 1 0.87500000 0.62500000 0.25000000 1 - Eu Eu7 1 0.12500000 0.37500000 0.75000000 1 - Eu Eu8 1 0.37500000 0.12500000 0.25000000 1 - Eu Eu9 1 0.25000000 0.87500000 0.62500000 1 - Eu Eu10 1 0.75000000 0.62500000 0.87500000 1 - Eu Eu11 1 0.37500000 0.75000000 0.12500000 1 - Fe Fe12 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe13 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe14 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe15 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe16 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe18 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe20 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe21 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe22 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe23 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe24 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe25 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe26 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe27 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe28 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe29 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe30 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.52495600 0.40407100 0.82198200 1 - O O33 1 0.29702600 0.47504400 0.37911400 1 - O O34 1 0.37911400 0.58208900 0.90407100 1 - O O35 1 0.82198200 0.52495600 0.40407100 1 - O O36 1 0.17801800 0.47504400 0.59592900 1 - O O37 1 0.67801800 0.08208900 0.70297400 1 - O O38 1 0.97504400 0.67801800 0.09592900 1 - O O39 1 0.32198200 0.91791100 0.29702600 1 - O O40 1 0.02495600 0.20297400 0.12088600 1 - O O41 1 0.08208900 0.87911400 0.40407100 1 - O O42 1 0.08208900 0.70297400 0.67801800 1 - O O43 1 0.70297400 0.52495600 0.62088600 1 - O O44 1 0.62088600 0.70297400 0.52495600 1 - O O45 1 0.40407100 0.82198200 0.52495600 1 - O O46 1 0.90407100 0.02495600 0.32198200 1 - O O47 1 0.20297400 0.12088600 0.02495600 1 - O O48 1 0.59592900 0.91791100 0.12088600 1 - O O49 1 0.17801800 0.20297400 0.58208900 1 - O O50 1 0.37911400 0.29702600 0.47504400 1 - O O51 1 0.58208900 0.90407100 0.37911400 1 - O O52 1 0.40407100 0.08208900 0.87911400 1 - O O53 1 0.59592900 0.17801800 0.47504400 1 - O O54 1 0.09592900 0.97504400 0.67801800 1 - O O55 1 0.20297400 0.58208900 0.17801800 1 - O O56 1 0.79702600 0.87911400 0.97504400 1 - O O57 1 0.91791100 0.12088600 0.59592900 1 - O O58 1 0.87911400 0.40407100 0.08208900 1 - O O59 1 0.97504400 0.79702600 0.87911400 1 - O O60 1 0.91791100 0.29702600 0.32198200 1 - O O61 1 0.12088600 0.59592900 0.91791100 1 - O O62 1 0.70297400 0.67801800 0.08208900 1 - O O63 1 0.41791100 0.82198200 0.79702600 1 - O O64 1 0.62088600 0.41791100 0.09592900 1 - O O65 1 0.90407100 0.37911400 0.58208900 1 - O O66 1 0.79702600 0.41791100 0.82198200 1 - O O67 1 0.82198200 0.79702600 0.41791100 1 - O O68 1 0.67801800 0.09592900 0.97504400 1 - O O69 1 0.52495600 0.62088600 0.70297400 1 - O O70 1 0.41791100 0.09592900 0.62088600 1 - O O71 1 0.29702600 0.32198200 0.91791100 1 - O O72 1 0.12088600 0.02495600 0.20297400 1 - O O73 1 0.32198200 0.90407100 0.02495600 1 - O O74 1 0.47504400 0.37911400 0.29702600 1 - O O75 1 0.58208900 0.17801800 0.20297400 1 - O O76 1 0.02495600 0.32198200 0.90407100 1 - O O77 1 0.87911400 0.97504400 0.79702600 1 - O O78 1 0.47504400 0.59592900 0.17801800 1 - O O79 1 0.09592900 0.62088600 0.41791100 1 -" -Eu3Ga5O12,mp-1213411,Ia-3d,[],0.0,"{'tags': ['Eu3Ga5O12', 'Y3Al5O12', 'garnet family']}","Full Formula (Eu12 Ga20 O48) -Reduced Formula: Eu3Ga5O12 -abc : 10.943010 10.943010 10.943010 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Eu 0.25 0.375 0.125 6.208 - 1 Eu 0.75 0.625 0.875 6.208 - 2 Eu 0.75 0.125 0.375 6.22 - 3 Eu 0.125 0.25 0.375 6.229 - 4 Eu 0.375 0.75 0.125 6.229 - 5 Eu 0.25 0.875 0.625 6.22 - 6 Eu 0.875 0.75 0.625 6.229 - 7 Eu 0.625 0.25 0.875 6.229 - 8 Eu 0.375 0.125 0.25 6.229 - 9 Eu 0.625 0.875 0.75 6.229 - 10 Eu 0.125 0.375 0.75 6.229 - 11 Eu 0.875 0.625 0.25 6.229 - 12 Ga 0.25 0.625 0.375 0.002 - 13 Ga 0.75 0.375 0.625 0.002 - 14 Ga 0.75 0.875 0.125 0.002 - 15 Ga 0.375 0.25 0.625 0.002 - 16 Ga 0.625 0.75 0.375 0.002 - 17 Ga 0.25 0.125 0.875 0.002 - 18 Ga 0.125 0.75 0.875 0.002 - 19 Ga 0.875 0.25 0.125 0.002 - 20 Ga 0.625 0.375 0.25 0.002 - 21 Ga 0.375 0.625 0.75 0.002 - 22 Ga 0.875 0.125 0.75 0.002 - 23 Ga 0.125 0.875 0.25 0.002 - 24 Ga 0 0 0 0.002 - 25 Ga 0.5 0 0.5 0.002 - 26 Ga 0 0.5 0.5 0.002 - 27 Ga 0.5 0 0 0.002 - 28 Ga 0.5 0.5 0 0.002 - 29 Ga 0.5 0.5 0.5 0.002 - 30 Ga 0 0 0.5 0.002 - 31 Ga 0 0.5 0 0.002 - 32 O 0.476244 0.380129 0.298113 -0.065 - 33 O 0.523756 0.619871 0.701887 -0.065 - 34 O 0.582017 0.178131 0.201887 -0.064 - 35 O 0.917983 0.119871 0.596114 -0.064 - 36 O 0.298113 0.476244 0.380129 -0.065 - 37 O 0.321869 0.917983 0.298113 -0.066 - 38 O 0.417983 0.821869 0.798113 -0.064 - 39 O 0.082017 0.880129 0.403886 -0.064 - 40 O 0.701887 0.523756 0.619871 -0.065 - 41 O 0.678131 0.082017 0.701887 -0.066 - 42 O 0.023756 0.321869 0.903886 -0.065 - 43 O 0.201887 0.582017 0.178131 -0.065 - 44 O 0.119871 0.023756 0.201887 -0.062 - 45 O 0.976244 0.678131 0.096114 -0.065 - 46 O 0.798113 0.417983 0.821869 -0.065 - 47 O 0.880129 0.976244 0.798113 -0.062 - 48 O 0.596114 0.917983 0.119871 -0.064 - 49 O 0.178131 0.476244 0.596114 -0.066 - 50 O 0.403886 0.082017 0.880129 -0.064 - 51 O 0.821869 0.523756 0.403886 -0.066 - 52 O 0.903886 0.023756 0.321869 -0.064 - 53 O 0.380129 0.582017 0.903886 -0.062 - 54 O 0.096114 0.976244 0.678131 -0.064 - 55 O 0.619871 0.417983 0.096114 -0.062 - 56 O 0.380129 0.298113 0.476244 -0.062 - 57 O 0.582017 0.903886 0.380129 -0.064 - 58 O 0.619871 0.701887 0.523756 -0.062 - 59 O 0.417983 0.096114 0.619871 -0.064 - 60 O 0.119871 0.596114 0.917983 -0.062 - 61 O 0.023756 0.201887 0.119871 -0.065 - 62 O 0.880129 0.403886 0.082017 -0.062 - 63 O 0.976244 0.798113 0.880129 -0.065 - 64 O 0.321869 0.903886 0.023756 -0.066 - 65 O 0.917983 0.298113 0.321869 -0.064 - 66 O 0.678131 0.096114 0.976244 -0.066 - 67 O 0.082017 0.701887 0.678131 -0.064 - 68 O 0.178131 0.201887 0.582017 -0.066 - 69 O 0.476244 0.596114 0.178131 -0.065 - 70 O 0.821869 0.798113 0.417983 -0.066 - 71 O 0.523756 0.403886 0.821869 -0.065 - 72 O 0.298113 0.321869 0.917983 -0.065 - 73 O 0.701887 0.678131 0.082017 -0.065 - 74 O 0.201887 0.119871 0.023756 -0.065 - 75 O 0.798113 0.880129 0.976244 -0.065 - 76 O 0.903886 0.380129 0.582017 -0.064 - 77 O 0.096114 0.619871 0.417983 -0.064 - 78 O 0.596114 0.178131 0.476244 -0.064 - 79 O 0.403886 0.821869 0.523756 -0.064","# generated using pymatgen -data_Eu3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.94301040 -_cell_length_b 10.94301040 -_cell_length_c 10.94301040 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Eu3Ga5O12 -_chemical_formula_sum 'Eu12 Ga20 O48' -_cell_volume 1008.76160764 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Eu Eu0 1 0.25000000 0.37500000 0.12500000 1 - Eu Eu1 1 0.75000000 0.62500000 0.87500000 1 - Eu Eu2 1 0.75000000 0.12500000 0.37500000 1 - Eu Eu3 1 0.12500000 0.25000000 0.37500000 1 - Eu Eu4 1 0.37500000 0.75000000 0.12500000 1 - Eu Eu5 1 0.25000000 0.87500000 0.62500000 1 - Eu Eu6 1 0.87500000 0.75000000 0.62500000 1 - Eu Eu7 1 0.62500000 0.25000000 0.87500000 1 - Eu Eu8 1 0.37500000 0.12500000 0.25000000 1 - Eu Eu9 1 0.62500000 0.87500000 0.75000000 1 - Eu Eu10 1 0.12500000 0.37500000 0.75000000 1 - Eu Eu11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga13 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga14 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga17 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga18 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga19 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga24 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga25 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga26 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga28 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga29 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47624400 0.38012900 0.29811300 1 - O O33 1 0.52375600 0.61987100 0.70188700 1 - O O34 1 0.58201700 0.17813100 0.20188700 1 - O O35 1 0.91798300 0.11987100 0.59611400 1 - O O36 1 0.29811300 0.47624400 0.38012900 1 - O O37 1 0.32186900 0.91798300 0.29811300 1 - O O38 1 0.41798300 0.82186900 0.79811300 1 - O O39 1 0.08201700 0.88012900 0.40388600 1 - O O40 1 0.70188700 0.52375600 0.61987100 1 - O O41 1 0.67813100 0.08201700 0.70188700 1 - O O42 1 0.02375600 0.32186900 0.90388600 1 - O O43 1 0.20188700 0.58201700 0.17813100 1 - O O44 1 0.11987100 0.02375600 0.20188700 1 - O O45 1 0.97624400 0.67813100 0.09611400 1 - O O46 1 0.79811300 0.41798300 0.82186900 1 - O O47 1 0.88012900 0.97624400 0.79811300 1 - O O48 1 0.59611400 0.91798300 0.11987100 1 - O O49 1 0.17813100 0.47624400 0.59611400 1 - O O50 1 0.40388600 0.08201700 0.88012900 1 - O O51 1 0.82186900 0.52375600 0.40388600 1 - O O52 1 0.90388600 0.02375600 0.32186900 1 - O O53 1 0.38012900 0.58201700 0.90388600 1 - O O54 1 0.09611400 0.97624400 0.67813100 1 - O O55 1 0.61987100 0.41798300 0.09611400 1 - O O56 1 0.38012900 0.29811300 0.47624400 1 - O O57 1 0.58201700 0.90388600 0.38012900 1 - O O58 1 0.61987100 0.70188700 0.52375600 1 - O O59 1 0.41798300 0.09611400 0.61987100 1 - O O60 1 0.11987100 0.59611400 0.91798300 1 - O O61 1 0.02375600 0.20188700 0.11987100 1 - O O62 1 0.88012900 0.40388600 0.08201700 1 - O O63 1 0.97624400 0.79811300 0.88012900 1 - O O64 1 0.32186900 0.90388600 0.02375600 1 - O O65 1 0.91798300 0.29811300 0.32186900 1 - O O66 1 0.67813100 0.09611400 0.97624400 1 - O O67 1 0.08201700 0.70188700 0.67813100 1 - O O68 1 0.17813100 0.20188700 0.58201700 1 - O O69 1 0.47624400 0.59611400 0.17813100 1 - O O70 1 0.82186900 0.79811300 0.41798300 1 - O O71 1 0.52375600 0.40388600 0.82186900 1 - O O72 1 0.29811300 0.32186900 0.91798300 1 - O O73 1 0.70188700 0.67813100 0.08201700 1 - O O74 1 0.20188700 0.11987100 0.02375600 1 - O O75 1 0.79811300 0.88012900 0.97624400 1 - O O76 1 0.90388600 0.38012900 0.58201700 1 - O O77 1 0.09611400 0.61987100 0.41798300 1 - O O78 1 0.59611400 0.17813100 0.47624400 1 - O O79 1 0.40388600 0.82186900 0.52375600 1 -" -Fe5(BiO4)3,mp-531715,Ia-3d,[],0.1079236918749995,{'tags': []},"Full Formula (Fe20 Bi12 O48) -Reduced Formula: Fe5(BiO4)3 -abc : 10.941652 10.941652 10.941652 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Fe 0.75 0.375 0.625 4.282 - 1 Fe 0.875 0.125 0.75 4.282 - 2 Fe 0 0.5 0.5 4.41 - 3 Fe 0.875 0.25 0.125 4.282 - 4 Fe 0 0 0.5 4.41 - 5 Fe 0 0.5 0 4.409 - 6 Fe 0.25 0.625 0.375 4.282 - 7 Fe 0 0 0 4.409 - 8 Fe 0.375 0.25 0.625 4.282 - 9 Fe 0.125 0.875 0.25 4.282 - 10 Fe 0.5 0.5 0.5 4.409 - 11 Fe 0.625 0.75 0.375 4.282 - 12 Fe 0.375 0.625 0.75 4.282 - 13 Fe 0.125 0.75 0.875 4.282 - 14 Fe 0.25 0.125 0.875 4.282 - 15 Fe 0.5 0 0.5 4.41 - 16 Fe 0.5 0.5 0 4.409 - 17 Fe 0.625 0.375 0.25 4.282 - 18 Fe 0.5 0 0 4.41 - 19 Fe 0.75 0.875 0.125 4.282 - 20 Bi 0.125 0.375 0.75 0.043 - 21 Bi 0.25 0.875 0.625 0.042 - 22 Bi 0.125 0.25 0.375 0.043 - 23 Bi 0.375 0.75 0.125 0.043 - 24 Bi 0.625 0.875 0.75 0.043 - 25 Bi 0.25 0.375 0.125 0.044 - 26 Bi 0.625 0.25 0.875 0.043 - 27 Bi 0.75 0.625 0.875 0.044 - 28 Bi 0.375 0.125 0.25 0.043 - 29 Bi 0.875 0.75 0.625 0.043 - 30 Bi 0.75 0.125 0.375 0.042 - 31 Bi 0.875 0.625 0.25 0.043 - 32 O 0.405276 0.078289 0.886692 0.213 - 33 O 0.421711 0.094724 0.613308 0.213 - 34 O 0.421711 0.826987 0.808403 0.213 - 35 O 0.905276 0.386692 0.578289 0.213 - 36 O 0.405276 0.826987 0.518584 0.213 - 37 O 0.673013 0.094724 0.981416 0.213 - 38 O 0.921711 0.113308 0.594724 0.213 - 39 O 0.921711 0.308403 0.326987 0.213 - 40 O 0.518584 0.613308 0.691597 0.213 - 41 O 0.673013 0.078289 0.691597 0.213 - 42 O 0.905276 0.018584 0.326987 0.213 - 43 O 0.518584 0.405276 0.826987 0.213 - 44 O 0.691597 0.673013 0.078289 0.212 - 45 O 0.613308 0.421711 0.094724 0.213 - 46 O 0.173013 0.481416 0.594724 0.212 - 47 O 0.808403 0.886692 0.981416 0.212 - 48 O 0.613308 0.691597 0.518584 0.213 - 49 O 0.018584 0.191597 0.113308 0.212 - 50 O 0.173013 0.191597 0.578289 0.212 - 51 O 0.886692 0.981416 0.808403 0.213 - 52 O 0.191597 0.578289 0.173013 0.212 - 53 O 0.113308 0.594724 0.921711 0.213 - 54 O 0.018584 0.326987 0.905276 0.212 - 55 O 0.691597 0.518584 0.613308 0.212 - 56 O 0.308403 0.481416 0.386692 0.212 - 57 O 0.981416 0.673013 0.094724 0.212 - 58 O 0.886692 0.405276 0.078289 0.213 - 59 O 0.808403 0.421711 0.826987 0.212 - 60 O 0.113308 0.018584 0.191597 0.213 - 61 O 0.826987 0.808403 0.421711 0.212 - 62 O 0.981416 0.808403 0.886692 0.212 - 63 O 0.386692 0.308403 0.481416 0.213 - 64 O 0.191597 0.113308 0.018584 0.212 - 65 O 0.826987 0.518584 0.405276 0.212 - 66 O 0.386692 0.578289 0.905276 0.213 - 67 O 0.308403 0.326987 0.921711 0.212 - 68 O 0.481416 0.594724 0.173013 0.213 - 69 O 0.094724 0.981416 0.673013 0.213 - 70 O 0.326987 0.921711 0.308403 0.213 - 71 O 0.481416 0.386692 0.308403 0.213 - 72 O 0.078289 0.691597 0.673013 0.213 - 73 O 0.078289 0.886692 0.405276 0.213 - 74 O 0.326987 0.905276 0.018584 0.213 - 75 O 0.594724 0.173013 0.481416 0.213 - 76 O 0.094724 0.613308 0.421711 0.213 - 77 O 0.578289 0.173013 0.191597 0.213 - 78 O 0.578289 0.905276 0.386692 0.213 - 79 O 0.594724 0.921711 0.113308 0.213","# generated using pymatgen -data_Fe5(BiO4)3 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.94165247 -_cell_length_b 10.94165247 -_cell_length_c 10.94165247 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Fe5(BiO4)3 -_chemical_formula_sum 'Fe20 Bi12 O48' -_cell_volume 1008.38611988 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Fe Fe0 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe1 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe2 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe3 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe4 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe5 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe6 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe7 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe8 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe9 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe10 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe11 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe12 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe13 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe14 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe15 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.75000000 0.87500000 0.12500000 1 - Bi Bi20 1 0.12500000 0.37500000 0.75000000 1 - Bi Bi21 1 0.25000000 0.87500000 0.62500000 1 - Bi Bi22 1 0.12500000 0.25000000 0.37500000 1 - Bi Bi23 1 0.37500000 0.75000000 0.12500000 1 - Bi Bi24 1 0.62500000 0.87500000 0.75000000 1 - Bi Bi25 1 0.25000000 0.37500000 0.12500000 1 - Bi Bi26 1 0.62500000 0.25000000 0.87500000 1 - Bi Bi27 1 0.75000000 0.62500000 0.87500000 1 - Bi Bi28 1 0.37500000 0.12500000 0.25000000 1 - Bi Bi29 1 0.87500000 0.75000000 0.62500000 1 - Bi Bi30 1 0.75000000 0.12500000 0.37500000 1 - Bi Bi31 1 0.87500000 0.62500000 0.25000000 1 - O O32 1 0.40527600 0.07828900 0.88669200 1 - O O33 1 0.42171100 0.09472400 0.61330800 1 - O O34 1 0.42171100 0.82698700 0.80840300 1 - O O35 1 0.90527600 0.38669200 0.57828900 1 - O O36 1 0.40527600 0.82698700 0.51858400 1 - O O37 1 0.67301300 0.09472400 0.98141600 1 - O O38 1 0.92171100 0.11330800 0.59472400 1 - O O39 1 0.92171100 0.30840300 0.32698700 1 - O O40 1 0.51858400 0.61330800 0.69159700 1 - O O41 1 0.67301300 0.07828900 0.69159700 1 - O O42 1 0.90527600 0.01858400 0.32698700 1 - O O43 1 0.51858400 0.40527600 0.82698700 1 - O O44 1 0.69159700 0.67301300 0.07828900 1 - O O45 1 0.61330800 0.42171100 0.09472400 1 - O O46 1 0.17301300 0.48141600 0.59472400 1 - O O47 1 0.80840300 0.88669200 0.98141600 1 - O O48 1 0.61330800 0.69159700 0.51858400 1 - O O49 1 0.01858400 0.19159700 0.11330800 1 - O O50 1 0.17301300 0.19159700 0.57828900 1 - O O51 1 0.88669200 0.98141600 0.80840300 1 - O O52 1 0.19159700 0.57828900 0.17301300 1 - O O53 1 0.11330800 0.59472400 0.92171100 1 - O O54 1 0.01858400 0.32698700 0.90527600 1 - O O55 1 0.69159700 0.51858400 0.61330800 1 - O O56 1 0.30840300 0.48141600 0.38669200 1 - O O57 1 0.98141600 0.67301300 0.09472400 1 - O O58 1 0.88669200 0.40527600 0.07828900 1 - O O59 1 0.80840300 0.42171100 0.82698700 1 - O O60 1 0.11330800 0.01858400 0.19159700 1 - O O61 1 0.82698700 0.80840300 0.42171100 1 - O O62 1 0.98141600 0.80840300 0.88669200 1 - O O63 1 0.38669200 0.30840300 0.48141600 1 - O O64 1 0.19159700 0.11330800 0.01858400 1 - O O65 1 0.82698700 0.51858400 0.40527600 1 - O O66 1 0.38669200 0.57828900 0.90527600 1 - O O67 1 0.30840300 0.32698700 0.92171100 1 - O O68 1 0.48141600 0.59472400 0.17301300 1 - O O69 1 0.09472400 0.98141600 0.67301300 1 - O O70 1 0.32698700 0.92171100 0.30840300 1 - O O71 1 0.48141600 0.38669200 0.30840300 1 - O O72 1 0.07828900 0.69159700 0.67301300 1 - O O73 1 0.07828900 0.88669200 0.40527600 1 - O O74 1 0.32698700 0.90527600 0.01858400 1 - O O75 1 0.59472400 0.17301300 0.48141600 1 - O O76 1 0.09472400 0.61330800 0.42171100 1 - O O77 1 0.57828900 0.17301300 0.19159700 1 - O O78 1 0.57828900 0.90527600 0.38669200 1 - O O79 1 0.59472400 0.92171100 0.11330800 1 -" -Gd3Al5O12,mp-14133,Ia-3d,"[23849, 192184]",0.0,"{'tags': ['Trigadolinium pentaaluminium dodecaoxide', 'Pentaaluminium trigadolinium oxide']}","Full Formula (Gd12 Al20 O48) -Reduced Formula: Gd3Al5O12 -abc : 10.574875 10.574875 10.574875 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Gd 0.375 0.75 0.125 6.887 - 1 Gd 0.25 0.375 0.125 6.887 - 2 Gd 0.75 0.125 0.375 6.887 - 3 Gd 0.375 0.125 0.25 6.887 - 4 Gd 0.125 0.375 0.75 6.887 - 5 Gd 0.125 0.25 0.375 6.887 - 6 Gd 0.625 0.25 0.875 6.887 - 7 Gd 0.75 0.625 0.875 6.887 - 8 Gd 0.25 0.875 0.625 6.887 - 9 Gd 0.625 0.875 0.75 6.887 - 10 Gd 0.875 0.625 0.25 6.887 - 11 Gd 0.875 0.75 0.625 6.887 - 12 Al 0.5 0 0 0.002 - 13 Al 0.5 0.5 0 0.002 - 14 Al 0 0.5 0.5 0.002 - 15 Al 0 0 0 0.002 - 16 Al 0 0 0.5 0.002 - 17 Al 0.5 0.5 0.5 0.002 - 18 Al 0 0.5 0 0.002 - 19 Al 0.5 0 0.5 0.002 - 20 Al 0.625 0.75 0.375 0.001 - 21 Al 0.25 0.625 0.375 0.001 - 22 Al 0.75 0.875 0.125 0.001 - 23 Al 0.625 0.375 0.25 0.001 - 24 Al 0.125 0.75 0.875 0.001 - 25 Al 0.875 0.25 0.125 0.001 - 26 Al 0.75 0.375 0.625 0.001 - 27 Al 0.125 0.875 0.25 0.001 - 28 Al 0.25 0.125 0.875 0.001 - 29 Al 0.375 0.625 0.75 0.001 - 30 Al 0.375 0.25 0.625 0.001 - 31 Al 0.875 0.125 0.75 0.001 - 32 O 0.517584 0.400423 0.820151 0 - 33 O 0.820151 0.517584 0.400423 0 - 34 O 0.802568 0.88284 0.982416 0 - 35 O 0.419728 0.099577 0.61716 0 - 36 O 0.88284 0.400423 0.080272 0.001 - 37 O 0.679849 0.080272 0.697432 0 - 38 O 0.820151 0.802568 0.419728 0 - 39 O 0.400423 0.820151 0.517584 0 - 40 O 0.61716 0.697432 0.517584 0.001 - 41 O 0.419728 0.820151 0.802568 0 - 42 O 0.400423 0.080272 0.88284 0 - 43 O 0.099577 0.982416 0.679849 0 - 44 O 0.982416 0.679849 0.099577 0 - 45 O 0.802568 0.419728 0.820151 0 - 46 O 0.517584 0.61716 0.697432 0 - 47 O 0.697432 0.517584 0.61716 0 - 48 O 0.080272 0.88284 0.400423 0 - 49 O 0.982416 0.802568 0.88284 0 - 50 O 0.080272 0.697432 0.679849 0 - 51 O 0.38284 0.302568 0.482416 0.001 - 52 O 0.61716 0.419728 0.099577 0.001 - 53 O 0.099577 0.61716 0.419728 0 - 54 O 0.697432 0.679849 0.080272 0 - 55 O 0.679849 0.099577 0.982416 0 - 56 O 0.482416 0.599577 0.179849 0 - 57 O 0.179849 0.482416 0.599577 0 - 58 O 0.197432 0.11716 0.017584 0 - 59 O 0.580272 0.900423 0.38284 0 - 60 O 0.11716 0.599577 0.919728 0.001 - 61 O 0.320151 0.919728 0.302568 0 - 62 O 0.179849 0.197432 0.580272 0 - 63 O 0.599577 0.179849 0.482416 0 - 64 O 0.320151 0.900423 0.017584 0 - 65 O 0.302568 0.320151 0.919728 0 - 66 O 0.900423 0.38284 0.580272 0 - 67 O 0.11716 0.017584 0.197432 0.001 - 68 O 0.38284 0.580272 0.900423 0.001 - 69 O 0.919728 0.302568 0.320151 0 - 70 O 0.017584 0.197432 0.11716 0 - 71 O 0.919728 0.11716 0.599577 0 - 72 O 0.302568 0.482416 0.38284 0 - 73 O 0.482416 0.38284 0.302568 0 - 74 O 0.197432 0.580272 0.179849 0 - 75 O 0.017584 0.320151 0.900423 0 - 76 O 0.900423 0.017584 0.320151 0 - 77 O 0.599577 0.919728 0.11716 0 - 78 O 0.580272 0.179849 0.197432 0 - 79 O 0.88284 0.982416 0.802568 0.001","# generated using pymatgen -data_Gd3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.57487512 -_cell_length_b 10.57487512 -_cell_length_c 10.57487512 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Gd3Al5O12 -_chemical_formula_sum 'Gd12 Al20 O48' -_cell_volume 910.34047432 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Gd Gd0 1 0.37500000 0.75000000 0.12500000 1 - Gd Gd1 1 0.25000000 0.37500000 0.12500000 1 - Gd Gd2 1 0.75000000 0.12500000 0.37500000 1 - Gd Gd3 1 0.37500000 0.12500000 0.25000000 1 - Gd Gd4 1 0.12500000 0.37500000 0.75000000 1 - Gd Gd5 1 0.12500000 0.25000000 0.37500000 1 - Gd Gd6 1 0.62500000 0.25000000 0.87500000 1 - Gd Gd7 1 0.75000000 0.62500000 0.87500000 1 - Gd Gd8 1 0.25000000 0.87500000 0.62500000 1 - Gd Gd9 1 0.62500000 0.87500000 0.75000000 1 - Gd Gd10 1 0.87500000 0.62500000 0.25000000 1 - Gd Gd11 1 0.87500000 0.75000000 0.62500000 1 - Al Al12 1 0.50000000 0.00000000 0.00000000 1 - Al Al13 1 0.50000000 0.50000000 0.00000000 1 - Al Al14 1 0.00000000 0.50000000 0.50000000 1 - Al Al15 1 0.00000000 0.00000000 0.00000000 1 - Al Al16 1 0.00000000 0.00000000 0.50000000 1 - Al Al17 1 0.50000000 0.50000000 0.50000000 1 - Al Al18 1 0.00000000 0.50000000 0.00000000 1 - Al Al19 1 0.50000000 0.00000000 0.50000000 1 - Al Al20 1 0.62500000 0.75000000 0.37500000 1 - Al Al21 1 0.25000000 0.62500000 0.37500000 1 - Al Al22 1 0.75000000 0.87500000 0.12500000 1 - Al Al23 1 0.62500000 0.37500000 0.25000000 1 - Al Al24 1 0.12500000 0.75000000 0.87500000 1 - Al Al25 1 0.87500000 0.25000000 0.12500000 1 - Al Al26 1 0.75000000 0.37500000 0.62500000 1 - Al Al27 1 0.12500000 0.87500000 0.25000000 1 - Al Al28 1 0.25000000 0.12500000 0.87500000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.37500000 0.25000000 0.62500000 1 - Al Al31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.51758400 0.40042300 0.82015100 1 - O O33 1 0.82015100 0.51758400 0.40042300 1 - O O34 1 0.80256800 0.88284000 0.98241600 1 - O O35 1 0.41972800 0.09957700 0.61716000 1 - O O36 1 0.88284000 0.40042300 0.08027200 1 - O O37 1 0.67984900 0.08027200 0.69743200 1 - O O38 1 0.82015100 0.80256800 0.41972800 1 - O O39 1 0.40042300 0.82015100 0.51758400 1 - O O40 1 0.61716000 0.69743200 0.51758400 1 - O O41 1 0.41972800 0.82015100 0.80256800 1 - O O42 1 0.40042300 0.08027200 0.88284000 1 - O O43 1 0.09957700 0.98241600 0.67984900 1 - O O44 1 0.98241600 0.67984900 0.09957700 1 - O O45 1 0.80256800 0.41972800 0.82015100 1 - O O46 1 0.51758400 0.61716000 0.69743200 1 - O O47 1 0.69743200 0.51758400 0.61716000 1 - O O48 1 0.08027200 0.88284000 0.40042300 1 - O O49 1 0.98241600 0.80256800 0.88284000 1 - O O50 1 0.08027200 0.69743200 0.67984900 1 - O O51 1 0.38284000 0.30256800 0.48241600 1 - O O52 1 0.61716000 0.41972800 0.09957700 1 - O O53 1 0.09957700 0.61716000 0.41972800 1 - O O54 1 0.69743200 0.67984900 0.08027200 1 - O O55 1 0.67984900 0.09957700 0.98241600 1 - O O56 1 0.48241600 0.59957700 0.17984900 1 - O O57 1 0.17984900 0.48241600 0.59957700 1 - O O58 1 0.19743200 0.11716000 0.01758400 1 - O O59 1 0.58027200 0.90042300 0.38284000 1 - O O60 1 0.11716000 0.59957700 0.91972800 1 - O O61 1 0.32015100 0.91972800 0.30256800 1 - O O62 1 0.17984900 0.19743200 0.58027200 1 - O O63 1 0.59957700 0.17984900 0.48241600 1 - O O64 1 0.32015100 0.90042300 0.01758400 1 - O O65 1 0.30256800 0.32015100 0.91972800 1 - O O66 1 0.90042300 0.38284000 0.58027200 1 - O O67 1 0.11716000 0.01758400 0.19743200 1 - O O68 1 0.38284000 0.58027200 0.90042300 1 - O O69 1 0.91972800 0.30256800 0.32015100 1 - O O70 1 0.01758400 0.19743200 0.11716000 1 - O O71 1 0.91972800 0.11716000 0.59957700 1 - O O72 1 0.30256800 0.48241600 0.38284000 1 - O O73 1 0.48241600 0.38284000 0.30256800 1 - O O74 1 0.19743200 0.58027200 0.17984900 1 - O O75 1 0.01758400 0.32015100 0.90042300 1 - O O76 1 0.90042300 0.01758400 0.32015100 1 - O O77 1 0.59957700 0.91972800 0.11716000 1 - O O78 1 0.58027200 0.17984900 0.19743200 1 - O O79 1 0.88284000 0.98241600 0.80256800 1 -" -Gd3Fe5O12,mp-557370,Ia-3d,"[27127, 15456]",1.9629092448749983,"{'tags': ['Pentairon(III) trigadolinium oxide', 'Trigadolinium pentairon(III) oxide']}","Full Formula (Gd12 Fe20 O48) -Reduced Formula: Gd3Fe5O12 -abc : 10.935143 10.935144 10.935143 -angles: 109.471220 109.471222 109.471218 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Gd 0.375 0.75 0.125 0.151 - 1 Gd 0.875 0.625 0.25 -0.021 - 2 Gd 0.375 0.125 0.25 -0.025 - 3 Gd 0.625 0.25 0.875 0.023 - 4 Gd 0.125 0.375 0.75 0.366 - 5 Gd 0.25 0.875 0.625 -0.813 - 6 Gd 0.875 0.75 0.625 -0.085 - 7 Gd 0.125 0.25 0.375 0.016 - 8 Gd 0.25 0.375 0.125 -0.165 - 9 Gd 0.625 0.875 0.75 -2.459 - 10 Gd 0.75 0.125 0.375 0.032 - 11 Gd 0.75 0.625 0.875 -0.058 - 12 Fe 0 0 0.5 0.268 - 13 Fe 0.125 0.75 0.875 -0.122 - 14 Fe 0.875 0.125 0.75 -0.139 - 15 Fe 0.5 0 0.5 0.233 - 16 Fe 0.5 0 0 2.455 - 17 Fe 0.625 0.75 0.375 0.047 - 18 Fe 0 0 0 0.244 - 19 Fe 0 0.5 0 2.873 - 20 Fe 0.25 0.625 0.375 0.09 - 21 Fe 0 0.5 0.5 -2.189 - 22 Fe 0.25 0.125 0.875 0.219 - 23 Fe 0.375 0.25 0.625 0.241 - 24 Fe 0.875 0.25 0.125 -0.133 - 25 Fe 0.75 0.375 0.625 -0.621 - 26 Fe 0.375 0.625 0.75 -0.012 - 27 Fe 0.5 0.5 0.5 -2.213 - 28 Fe 0.625 0.375 0.25 -0.584 - 29 Fe 0.75 0.875 0.125 0.131 - 30 Fe 0.5 0.5 0 0.148 - 31 Fe 0.125 0.875 0.25 0.083 - 32 O 0.125105 0.595727 0.916624 0.019 - 33 O 0.529378 0.625105 0.708481 -0.048 - 34 O 0.874895 0.970622 0.791519 -0.013 - 35 O 0.904273 0.374895 0.583376 -0.056 - 36 O 0.125105 0.029378 0.208481 0.005 - 37 O 0.291519 0.320896 0.916624 0.02 - 38 O 0.083376 0.708481 0.679104 -0.03 - 39 O 0.820896 0.791519 0.416624 0.004 - 40 O 0.529378 0.404273 0.820896 0.013 - 41 O 0.179104 0.470622 0.595727 -0.018 - 42 O 0.095727 0.970622 0.679104 0.003 - 43 O 0.179104 0.208481 0.583376 0.012 - 44 O 0.416624 0.095727 0.625105 0.004 - 45 O 0.416624 0.820896 0.791519 0.02 - 46 O 0.029378 0.208481 0.125105 -0.011 - 47 O 0.625105 0.416624 0.095727 -0.013 - 48 O 0.791519 0.416624 0.820896 0.009 - 49 O 0.208481 0.125105 0.029378 0.005 - 50 O 0.970622 0.791519 0.874895 -0.007 - 51 O 0.595727 0.179104 0.470622 -0.022 - 52 O 0.208481 0.583376 0.179104 0.02 - 53 O 0.029378 0.320896 0.904273 0.031 - 54 O 0.679104 0.095727 0.970622 0.038 - 55 O 0.583376 0.179104 0.208481 0 - 56 O 0.374895 0.291519 0.470622 -0.013 - 57 O 0.083376 0.874895 0.404273 0.018 - 58 O 0.583376 0.904273 0.374895 0.004 - 59 O 0.916624 0.125105 0.595727 0.015 - 60 O 0.404273 0.083376 0.874895 0.044 - 61 O 0.820896 0.529378 0.404273 -0.055 - 62 O 0.625105 0.708481 0.529378 -0.037 - 63 O 0.904273 0.029378 0.320896 0.01 - 64 O 0.291519 0.470622 0.374895 -0.026 - 65 O 0.095727 0.625105 0.416624 -0.026 - 66 O 0.374895 0.583376 0.904273 0.013 - 67 O 0.320896 0.916624 0.291519 0.019 - 68 O 0.708481 0.679104 0.083376 0.005 - 69 O 0.970622 0.679104 0.095727 0.034 - 70 O 0.679104 0.083376 0.708481 -0.004 - 71 O 0.470622 0.595727 0.179104 0.009 - 72 O 0.595727 0.916624 0.125105 0.033 - 73 O 0.791519 0.874895 0.970622 -0.002 - 74 O 0.404273 0.820896 0.529378 -0.009 - 75 O 0.320896 0.904273 0.029378 0.041 - 76 O 0.916624 0.291519 0.320896 -0.031 - 77 O 0.470622 0.374895 0.291519 -0.04 - 78 O 0.874895 0.404273 0.083376 0.015 - 79 O 0.708481 0.529378 0.625105 -0.053","# generated using pymatgen -data_Gd3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.93514340 -_cell_length_b 10.93514411 -_cell_length_c 10.93514300 -_cell_angle_alpha 109.47122044 -_cell_angle_beta 109.47122174 -_cell_angle_gamma 109.47121822 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Gd3Fe5O12 -_chemical_formula_sum 'Gd12 Fe20 O48' -_cell_volume 1006.58760285 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Gd Gd0 1 0.37500000 0.75000000 0.12500000 1 - Gd Gd1 1 0.87500000 0.62500000 0.25000000 1 - Gd Gd2 1 0.37500000 0.12500000 0.25000000 1 - Gd Gd3 1 0.62500000 0.25000000 0.87500000 1 - Gd Gd4 1 0.12500000 0.37500000 0.75000000 1 - Gd Gd5 1 0.25000000 0.87500000 0.62500000 1 - Gd Gd6 1 0.87500000 0.75000000 0.62500000 1 - Gd Gd7 1 0.12500000 0.25000000 0.37500000 1 - Gd Gd8 1 0.25000000 0.37500000 0.12500000 1 - Gd Gd9 1 0.62500000 0.87500000 0.75000000 1 - Gd Gd10 1 0.75000000 0.12500000 0.37500000 1 - Gd Gd11 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe12 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe13 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe14 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe15 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe17 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe18 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe21 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe22 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe23 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe24 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe25 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe26 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe27 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe28 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe29 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe30 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe31 1 0.12500000 0.87500000 0.25000000 1 - O O32 1 0.12510500 0.59572700 0.91662400 1 - O O33 1 0.52937800 0.62510500 0.70848100 1 - O O34 1 0.87489500 0.97062200 0.79151900 1 - O O35 1 0.90427300 0.37489500 0.58337600 1 - O O36 1 0.12510500 0.02937800 0.20848100 1 - O O37 1 0.29151900 0.32089600 0.91662400 1 - O O38 1 0.08337600 0.70848100 0.67910400 1 - O O39 1 0.82089600 0.79151900 0.41662400 1 - O O40 1 0.52937800 0.40427300 0.82089600 1 - O O41 1 0.17910400 0.47062200 0.59572700 1 - O O42 1 0.09572700 0.97062200 0.67910400 1 - O O43 1 0.17910400 0.20848100 0.58337600 1 - O O44 1 0.41662400 0.09572700 0.62510500 1 - O O45 1 0.41662400 0.82089600 0.79151900 1 - O O46 1 0.02937800 0.20848100 0.12510500 1 - O O47 1 0.62510500 0.41662400 0.09572700 1 - O O48 1 0.79151900 0.41662400 0.82089600 1 - O O49 1 0.20848100 0.12510500 0.02937800 1 - O O50 1 0.97062200 0.79151900 0.87489500 1 - O O51 1 0.59572700 0.17910400 0.47062200 1 - O O52 1 0.20848100 0.58337600 0.17910400 1 - O O53 1 0.02937800 0.32089600 0.90427300 1 - O O54 1 0.67910400 0.09572700 0.97062200 1 - O O55 1 0.58337600 0.17910400 0.20848100 1 - O O56 1 0.37489500 0.29151900 0.47062200 1 - O O57 1 0.08337600 0.87489500 0.40427300 1 - O O58 1 0.58337600 0.90427300 0.37489500 1 - O O59 1 0.91662400 0.12510500 0.59572700 1 - O O60 1 0.40427300 0.08337600 0.87489500 1 - O O61 1 0.82089600 0.52937800 0.40427300 1 - O O62 1 0.62510500 0.70848100 0.52937800 1 - O O63 1 0.90427300 0.02937800 0.32089600 1 - O O64 1 0.29151900 0.47062200 0.37489500 1 - O O65 1 0.09572700 0.62510500 0.41662400 1 - O O66 1 0.37489500 0.58337600 0.90427300 1 - O O67 1 0.32089600 0.91662400 0.29151900 1 - O O68 1 0.70848100 0.67910400 0.08337600 1 - O O69 1 0.97062200 0.67910400 0.09572700 1 - O O70 1 0.67910400 0.08337600 0.70848100 1 - O O71 1 0.47062200 0.59572700 0.17910400 1 - O O72 1 0.59572700 0.91662400 0.12510500 1 - O O73 1 0.79151900 0.87489500 0.97062200 1 - O O74 1 0.40427300 0.82089600 0.52937800 1 - O O75 1 0.32089600 0.90427300 0.02937800 1 - O O76 1 0.91662400 0.29151900 0.32089600 1 - O O77 1 0.47062200 0.37489500 0.29151900 1 - O O78 1 0.87489500 0.40427300 0.08337600 1 - O O79 1 0.70848100 0.52937800 0.62510500 1 -" -Gd3Ga5O12,mp-2921,Ia-3d,"[184931, 84874, 192181, 9237, 37145]",0.0,"{'tags': ['Trigadolinium pentagallium oxide', 'Trigadolinium pentagallium dodecaoxide', 'Unnamed_Garnet', 'Trigadolinium gallium dodecaoxide']}","Full Formula (Gd12 Ga20 O48) -Reduced Formula: Gd3Ga5O12 -abc : 10.869963 10.869963 10.869963 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Gd 0.125 0.375 0.75 6.888 - 1 Gd 0.375 0.125 0.25 6.888 - 2 Gd 0.375 0.75 0.125 6.888 - 3 Gd 0.125 0.25 0.375 6.888 - 4 Gd 0.75 0.125 0.375 6.887 - 5 Gd 0.25 0.375 0.125 6.888 - 6 Gd 0.875 0.625 0.25 6.888 - 7 Gd 0.625 0.875 0.75 6.888 - 8 Gd 0.625 0.25 0.875 6.888 - 9 Gd 0.875 0.75 0.625 6.888 - 10 Gd 0.25 0.875 0.625 6.887 - 11 Gd 0.75 0.625 0.875 6.888 - 12 Ga 0 0.5 0 0.003 - 13 Ga 0 0 0.5 0.003 - 14 Ga 0.5 0 0 0.003 - 15 Ga 0.5 0.5 0.5 0.003 - 16 Ga 0.5 0.5 0 0.003 - 17 Ga 0.5 0 0.5 0.003 - 18 Ga 0 0.5 0.5 0.003 - 19 Ga 0 0 0 0.003 - 20 Ga 0.375 0.625 0.75 0.002 - 21 Ga 0.125 0.875 0.25 0.002 - 22 Ga 0.625 0.75 0.375 0.002 - 23 Ga 0.875 0.25 0.125 0.002 - 24 Ga 0.75 0.375 0.625 0.002 - 25 Ga 0.25 0.125 0.875 0.002 - 26 Ga 0.625 0.375 0.25 0.002 - 27 Ga 0.875 0.125 0.75 0.002 - 28 Ga 0.375 0.25 0.625 0.002 - 29 Ga 0.125 0.75 0.875 0.002 - 30 Ga 0.25 0.625 0.375 0.002 - 31 Ga 0.75 0.875 0.125 0.002 - 32 O 0.025335 0.322437 0.902595 0.001 - 33 O 0.919842 0.122741 0.597405 0.001 - 34 O 0.580158 0.177563 0.202898 0.001 - 35 O 0.474665 0.377259 0.297102 0.001 - 36 O 0.322437 0.902595 0.025335 0.001 - 37 O 0.122741 0.597405 0.919842 0.001 - 38 O 0.177563 0.202898 0.580158 0.001 - 39 O 0.377259 0.297102 0.474665 0.001 - 40 O 0.902595 0.025335 0.322437 0.001 - 41 O 0.597405 0.919842 0.122741 0.001 - 42 O 0.202898 0.580158 0.177563 0.001 - 43 O 0.297102 0.474665 0.377259 0.001 - 44 O 0.974665 0.677563 0.097405 0.001 - 45 O 0.080158 0.877259 0.402595 0.001 - 46 O 0.419842 0.822437 0.797102 0.001 - 47 O 0.525335 0.622741 0.702898 0.001 - 48 O 0.677563 0.097405 0.974665 0.001 - 49 O 0.877259 0.402595 0.080158 0.001 - 50 O 0.822437 0.797102 0.419842 0.001 - 51 O 0.622741 0.702898 0.525335 0.001 - 52 O 0.097405 0.974665 0.677563 0.001 - 53 O 0.402595 0.080158 0.877259 0.001 - 54 O 0.797102 0.419842 0.822437 0.001 - 55 O 0.702898 0.525335 0.622741 0.001 - 56 O 0.525335 0.402595 0.822437 0.001 - 57 O 0.419842 0.097405 0.622741 0.001 - 58 O 0.080158 0.702898 0.677563 0.001 - 59 O 0.974665 0.797102 0.877259 0.001 - 60 O 0.822437 0.525335 0.402595 0.001 - 61 O 0.622741 0.419842 0.097405 0.001 - 62 O 0.677563 0.080158 0.702898 0.001 - 63 O 0.877259 0.974665 0.797102 0.001 - 64 O 0.402595 0.822437 0.525335 0.001 - 65 O 0.097405 0.622741 0.419842 0.001 - 66 O 0.702898 0.677563 0.080158 0.001 - 67 O 0.797102 0.877259 0.974665 0.001 - 68 O 0.474665 0.597405 0.177563 0.001 - 69 O 0.580158 0.902595 0.377259 0.001 - 70 O 0.919842 0.297102 0.322437 0.001 - 71 O 0.025335 0.202898 0.122741 0.001 - 72 O 0.177563 0.474665 0.597405 0.001 - 73 O 0.377259 0.580158 0.902595 0.001 - 74 O 0.322437 0.919842 0.297102 0.001 - 75 O 0.122741 0.025335 0.202898 0.001 - 76 O 0.597405 0.177563 0.474665 0.001 - 77 O 0.902595 0.377259 0.580158 0.001 - 78 O 0.297102 0.322437 0.919842 0.001 - 79 O 0.202898 0.122741 0.025335 0.001","# generated using pymatgen -data_Gd3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.86996289 -_cell_length_b 10.86996289 -_cell_length_c 10.86996289 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Gd3Ga5O12 -_chemical_formula_sum 'Gd12 Ga20 O48' -_cell_volume 988.69489867 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Gd Gd0 1 0.12500000 0.37500000 0.75000000 1 - Gd Gd1 1 0.37500000 0.12500000 0.25000000 1 - Gd Gd2 1 0.37500000 0.75000000 0.12500000 1 - Gd Gd3 1 0.12500000 0.25000000 0.37500000 1 - Gd Gd4 1 0.75000000 0.12500000 0.37500000 1 - Gd Gd5 1 0.25000000 0.37500000 0.12500000 1 - Gd Gd6 1 0.87500000 0.62500000 0.25000000 1 - Gd Gd7 1 0.62500000 0.87500000 0.75000000 1 - Gd Gd8 1 0.62500000 0.25000000 0.87500000 1 - Gd Gd9 1 0.87500000 0.75000000 0.62500000 1 - Gd Gd10 1 0.25000000 0.87500000 0.62500000 1 - Gd Gd11 1 0.75000000 0.62500000 0.87500000 1 - Ga Ga12 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga13 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga14 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga15 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga16 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga18 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga19 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga20 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga21 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga22 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga23 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga24 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga25 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga26 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga27 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga28 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga29 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga30 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga31 1 0.75000000 0.87500000 0.12500000 1 - O O32 1 0.02533500 0.32243700 0.90259500 1 - O O33 1 0.91984200 0.12274100 0.59740500 1 - O O34 1 0.58015800 0.17756300 0.20289800 1 - O O35 1 0.47466500 0.37725900 0.29710200 1 - O O36 1 0.32243700 0.90259500 0.02533500 1 - O O37 1 0.12274100 0.59740500 0.91984200 1 - O O38 1 0.17756300 0.20289800 0.58015800 1 - O O39 1 0.37725900 0.29710200 0.47466500 1 - O O40 1 0.90259500 0.02533500 0.32243700 1 - O O41 1 0.59740500 0.91984200 0.12274100 1 - O O42 1 0.20289800 0.58015800 0.17756300 1 - O O43 1 0.29710200 0.47466500 0.37725900 1 - O O44 1 0.97466500 0.67756300 0.09740500 1 - O O45 1 0.08015800 0.87725900 0.40259500 1 - O O46 1 0.41984200 0.82243700 0.79710200 1 - O O47 1 0.52533500 0.62274100 0.70289800 1 - O O48 1 0.67756300 0.09740500 0.97466500 1 - O O49 1 0.87725900 0.40259500 0.08015800 1 - O O50 1 0.82243700 0.79710200 0.41984200 1 - O O51 1 0.62274100 0.70289800 0.52533500 1 - O O52 1 0.09740500 0.97466500 0.67756300 1 - O O53 1 0.40259500 0.08015800 0.87725900 1 - O O54 1 0.79710200 0.41984200 0.82243700 1 - O O55 1 0.70289800 0.52533500 0.62274100 1 - O O56 1 0.52533500 0.40259500 0.82243700 1 - O O57 1 0.41984200 0.09740500 0.62274100 1 - O O58 1 0.08015800 0.70289800 0.67756300 1 - O O59 1 0.97466500 0.79710200 0.87725900 1 - O O60 1 0.82243700 0.52533500 0.40259500 1 - O O61 1 0.62274100 0.41984200 0.09740500 1 - O O62 1 0.67756300 0.08015800 0.70289800 1 - O O63 1 0.87725900 0.97466500 0.79710200 1 - O O64 1 0.40259500 0.82243700 0.52533500 1 - O O65 1 0.09740500 0.62274100 0.41984200 1 - O O66 1 0.70289800 0.67756300 0.08015800 1 - O O67 1 0.79710200 0.87725900 0.97466500 1 - O O68 1 0.47466500 0.59740500 0.17756300 1 - O O69 1 0.58015800 0.90259500 0.37725900 1 - O O70 1 0.91984200 0.29710200 0.32243700 1 - O O71 1 0.02533500 0.20289800 0.12274100 1 - O O72 1 0.17756300 0.47466500 0.59740500 1 - O O73 1 0.37725900 0.58015800 0.90259500 1 - O O74 1 0.32243700 0.91984200 0.29710200 1 - O O75 1 0.12274100 0.02533500 0.20289800 1 - O O76 1 0.59740500 0.17756300 0.47466500 1 - O O77 1 0.90259500 0.37725900 0.58015800 1 - O O78 1 0.29710200 0.32243700 0.91984200 1 - O O79 1 0.20289800 0.12274100 0.02533500 1 -" -Ho3Al5O12,mp-14388,Ia-3d,[33603],0.0,{'tags': ['Triholmium pentaaluminium oxide']},"Full Formula (Ho12 Al20 O48) -Reduced Formula: Ho3Al5O12 -abc : 10.460953 10.460953 10.460953 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ho 0.875 0.625 0.25 -0 - 1 Ho 0.625 0.25 0.875 -0 - 2 Ho 0.875 0.75 0.625 -0 - 3 Ho 0.75 0.625 0.875 -0 - 4 Ho 0.25 0.875 0.625 -0 - 5 Ho 0.625 0.875 0.75 -0 - 6 Ho 0.125 0.375 0.75 -0 - 7 Ho 0.375 0.75 0.125 -0 - 8 Ho 0.125 0.25 0.375 -0 - 9 Ho 0.25 0.375 0.125 -0 - 10 Ho 0.75 0.125 0.375 -0 - 11 Ho 0.375 0.125 0.25 -0 - 12 Al 0.125 0.875 0.25 -0 - 13 Al 0.875 0.125 0.75 -0 - 14 Al 0.25 0.625 0.375 -0 - 15 Al 0.375 0.25 0.625 -0 - 16 Al 0.75 0.875 0.125 -0 - 17 Al 0.125 0.75 0.875 -0 - 18 Al 0.375 0.625 0.75 -0 - 19 Al 0.625 0.75 0.375 -0 - 20 Al 0.875 0.25 0.125 -0 - 21 Al 0.25 0.125 0.875 -0 - 22 Al 0.75 0.375 0.625 -0 - 23 Al 0.625 0.375 0.25 -0 - 24 Al 0.5 0.5 0.5 -0 - 25 Al 0.5 0 0.5 -0 - 26 Al 0 0.5 0.5 -0 - 27 Al 0.5 0.5 0 -0 - 28 Al 0 0 0.5 -0 - 29 Al 0 0.5 0 -0 - 30 Al 0.5 0 0 -0 - 31 Al 0 0 0 -0 - 32 O 0.679305 0.09827 0.979089 0 - 33 O 0.799785 0.418965 0.820695 0 - 34 O 0.081035 0.880819 0.40173 0 - 35 O 0.619181 0.700215 0.520911 0 - 36 O 0.40173 0.820695 0.520911 0 - 37 O 0.700215 0.520911 0.619181 0 - 38 O 0.700215 0.679305 0.081035 0 - 39 O 0.520911 0.619181 0.700215 0 - 40 O 0.09827 0.619181 0.418965 0 - 41 O 0.880819 0.979089 0.799785 0 - 42 O 0.979089 0.799785 0.880819 0 - 43 O 0.520911 0.40173 0.820695 0 - 44 O 0.679305 0.081035 0.700215 0 - 45 O 0.418965 0.09827 0.619181 0 - 46 O 0.820695 0.520911 0.40173 0 - 47 O 0.081035 0.700215 0.679305 0 - 48 O 0.619181 0.418965 0.09827 0 - 49 O 0.820695 0.799785 0.418965 0 - 50 O 0.880819 0.40173 0.081035 0 - 51 O 0.90173 0.380819 0.581035 0 - 52 O 0.40173 0.081035 0.880819 0 - 53 O 0.979089 0.679305 0.09827 0 - 54 O 0.418965 0.820695 0.799785 0 - 55 O 0.799785 0.880819 0.979089 0 - 56 O 0.320695 0.90173 0.020911 0 - 57 O 0.200215 0.581035 0.179305 0 - 58 O 0.918965 0.119181 0.59827 0 - 59 O 0.380819 0.299785 0.479089 0 - 60 O 0.59827 0.179305 0.479089 0 - 61 O 0.299785 0.479089 0.380819 0 - 62 O 0.299785 0.320695 0.918965 0 - 63 O 0.479089 0.380819 0.299785 0 - 64 O 0.200215 0.119181 0.020911 0 - 65 O 0.581035 0.179305 0.200215 0 - 66 O 0.020911 0.320695 0.90173 0 - 67 O 0.90173 0.020911 0.320695 0 - 68 O 0.59827 0.918965 0.119181 0 - 69 O 0.119181 0.59827 0.918965 0 - 70 O 0.179305 0.200215 0.581035 0 - 71 O 0.380819 0.581035 0.90173 0 - 72 O 0.918965 0.299785 0.320695 0 - 73 O 0.179305 0.479089 0.59827 0 - 74 O 0.581035 0.90173 0.380819 0 - 75 O 0.320695 0.918965 0.299785 0 - 76 O 0.479089 0.59827 0.179305 0 - 77 O 0.020911 0.200215 0.119181 0 - 78 O 0.119181 0.020911 0.200215 0 - 79 O 0.09827 0.979089 0.679305 0","# generated using pymatgen -data_Ho3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.46095295 -_cell_length_b 10.46095295 -_cell_length_c 10.46095295 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ho3Al5O12 -_chemical_formula_sum 'Ho12 Al20 O48' -_cell_volume 881.23523852 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ho Ho0 1 0.87500000 0.62500000 0.25000000 1 - Ho Ho1 1 0.62500000 0.25000000 0.87500000 1 - Ho Ho2 1 0.87500000 0.75000000 0.62500000 1 - Ho Ho3 1 0.75000000 0.62500000 0.87500000 1 - Ho Ho4 1 0.25000000 0.87500000 0.62500000 1 - Ho Ho5 1 0.62500000 0.87500000 0.75000000 1 - Ho Ho6 1 0.12500000 0.37500000 0.75000000 1 - Ho Ho7 1 0.37500000 0.75000000 0.12500000 1 - Ho Ho8 1 0.12500000 0.25000000 0.37500000 1 - Ho Ho9 1 0.25000000 0.37500000 0.12500000 1 - Ho Ho10 1 0.75000000 0.12500000 0.37500000 1 - Ho Ho11 1 0.37500000 0.12500000 0.25000000 1 - Al Al12 1 0.12500000 0.87500000 0.25000000 1 - Al Al13 1 0.87500000 0.12500000 0.75000000 1 - Al Al14 1 0.25000000 0.62500000 0.37500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.75000000 0.87500000 0.12500000 1 - Al Al17 1 0.12500000 0.75000000 0.87500000 1 - Al Al18 1 0.37500000 0.62500000 0.75000000 1 - Al Al19 1 0.62500000 0.75000000 0.37500000 1 - Al Al20 1 0.87500000 0.25000000 0.12500000 1 - Al Al21 1 0.25000000 0.12500000 0.87500000 1 - Al Al22 1 0.75000000 0.37500000 0.62500000 1 - Al Al23 1 0.62500000 0.37500000 0.25000000 1 - Al Al24 1 0.50000000 0.50000000 0.50000000 1 - Al Al25 1 0.50000000 0.00000000 0.50000000 1 - Al Al26 1 0.00000000 0.50000000 0.50000000 1 - Al Al27 1 0.50000000 0.50000000 0.00000000 1 - Al Al28 1 0.00000000 0.00000000 0.50000000 1 - Al Al29 1 0.00000000 0.50000000 0.00000000 1 - Al Al30 1 0.50000000 0.00000000 0.00000000 1 - Al Al31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.67930500 0.09827000 0.97908900 1 - O O33 1 0.79978500 0.41896500 0.82069500 1 - O O34 1 0.08103500 0.88081900 0.40173000 1 - O O35 1 0.61918100 0.70021500 0.52091100 1 - O O36 1 0.40173000 0.82069500 0.52091100 1 - O O37 1 0.70021500 0.52091100 0.61918100 1 - O O38 1 0.70021500 0.67930500 0.08103500 1 - O O39 1 0.52091100 0.61918100 0.70021500 1 - O O40 1 0.09827000 0.61918100 0.41896500 1 - O O41 1 0.88081900 0.97908900 0.79978500 1 - O O42 1 0.97908900 0.79978500 0.88081900 1 - O O43 1 0.52091100 0.40173000 0.82069500 1 - O O44 1 0.67930500 0.08103500 0.70021500 1 - O O45 1 0.41896500 0.09827000 0.61918100 1 - O O46 1 0.82069500 0.52091100 0.40173000 1 - O O47 1 0.08103500 0.70021500 0.67930500 1 - O O48 1 0.61918100 0.41896500 0.09827000 1 - O O49 1 0.82069500 0.79978500 0.41896500 1 - O O50 1 0.88081900 0.40173000 0.08103500 1 - O O51 1 0.90173000 0.38081900 0.58103500 1 - O O52 1 0.40173000 0.08103500 0.88081900 1 - O O53 1 0.97908900 0.67930500 0.09827000 1 - O O54 1 0.41896500 0.82069500 0.79978500 1 - O O55 1 0.79978500 0.88081900 0.97908900 1 - O O56 1 0.32069500 0.90173000 0.02091100 1 - O O57 1 0.20021500 0.58103500 0.17930500 1 - O O58 1 0.91896500 0.11918100 0.59827000 1 - O O59 1 0.38081900 0.29978500 0.47908900 1 - O O60 1 0.59827000 0.17930500 0.47908900 1 - O O61 1 0.29978500 0.47908900 0.38081900 1 - O O62 1 0.29978500 0.32069500 0.91896500 1 - O O63 1 0.47908900 0.38081900 0.29978500 1 - O O64 1 0.20021500 0.11918100 0.02091100 1 - O O65 1 0.58103500 0.17930500 0.20021500 1 - O O66 1 0.02091100 0.32069500 0.90173000 1 - O O67 1 0.90173000 0.02091100 0.32069500 1 - O O68 1 0.59827000 0.91896500 0.11918100 1 - O O69 1 0.11918100 0.59827000 0.91896500 1 - O O70 1 0.17930500 0.20021500 0.58103500 1 - O O71 1 0.38081900 0.58103500 0.90173000 1 - O O72 1 0.91896500 0.29978500 0.32069500 1 - O O73 1 0.17930500 0.47908900 0.59827000 1 - O O74 1 0.58103500 0.90173000 0.38081900 1 - O O75 1 0.32069500 0.91896500 0.29978500 1 - O O76 1 0.47908900 0.59827000 0.17930500 1 - O O77 1 0.02091100 0.20021500 0.11918100 1 - O O78 1 0.11918100 0.02091100 0.20021500 1 - O O79 1 0.09827000 0.97908900 0.67930500 1 -" -Ho3Fe5O12,mp-781609,Ia-3d,[],0.028790174031250615,{'tags': []},"Full Formula (Ho12 Fe20 O48) -Reduced Formula: Ho3Fe5O12 -abc : 10.816860 10.816860 10.816860 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ho 0.75 0.125 0.375 0.048 - 1 Ho 0.375 0.125 0.25 0.048 - 2 Ho 0.875 0.625 0.25 0.048 - 3 Ho 0.25 0.375 0.125 0.048 - 4 Ho 0.625 0.25 0.875 0.048 - 5 Ho 0.375 0.75 0.125 0.048 - 6 Ho 0.125 0.25 0.375 0.048 - 7 Ho 0.875 0.75 0.625 0.048 - 8 Ho 0.75 0.625 0.875 0.048 - 9 Ho 0.625 0.875 0.75 0.048 - 10 Ho 0.125 0.375 0.75 0.048 - 11 Ho 0.25 0.875 0.625 0.048 - 12 Fe 0.875 0.25 0.125 4.274 - 13 Fe 0.5 0 0 4.401 - 14 Fe 0 0 0 4.401 - 15 Fe 0.625 0.375 0.25 4.274 - 16 Fe 0.5 0 0.5 4.401 - 17 Fe 0.5 0.5 0 4.401 - 18 Fe 0.875 0.125 0.75 4.274 - 19 Fe 0.75 0.875 0.125 4.274 - 20 Fe 0.75 0.375 0.625 4.274 - 21 Fe 0.625 0.75 0.375 4.274 - 22 Fe 0.5 0.5 0.5 4.401 - 23 Fe 0 0.5 0 4.401 - 24 Fe 0 0 0.5 4.401 - 25 Fe 0.375 0.25 0.625 4.274 - 26 Fe 0.25 0.625 0.375 4.274 - 27 Fe 0.25 0.125 0.875 4.274 - 28 Fe 0.375 0.625 0.75 4.274 - 29 Fe 0.125 0.875 0.25 4.274 - 30 Fe 0 0.5 0.5 4.401 - 31 Fe 0.125 0.75 0.875 4.274 - 32 O 0.907035 0.032614 0.323033 0.217 - 33 O 0.874421 0.407035 0.084003 0.217 - 34 O 0.915997 0.290418 0.323033 0.217 - 35 O 0.915997 0.125579 0.592965 0.217 - 36 O 0.967386 0.676967 0.092965 0.217 - 37 O 0.584003 0.176967 0.209582 0.217 - 38 O 0.625579 0.415997 0.092965 0.217 - 39 O 0.209582 0.125579 0.032614 0.217 - 40 O 0.709582 0.676967 0.084003 0.217 - 41 O 0.592965 0.176967 0.467386 0.217 - 42 O 0.907035 0.374421 0.584003 0.217 - 43 O 0.125579 0.032614 0.209582 0.217 - 44 O 0.823032 0.532614 0.407035 0.217 - 45 O 0.676967 0.084003 0.709582 0.217 - 46 O 0.467386 0.374421 0.290418 0.217 - 47 O 0.467386 0.592965 0.176968 0.217 - 48 O 0.415997 0.092965 0.625579 0.217 - 49 O 0.032614 0.209582 0.125579 0.217 - 50 O 0.823032 0.790418 0.415997 0.217 - 51 O 0.374421 0.290418 0.467386 0.217 - 52 O 0.676967 0.092965 0.967386 0.217 - 53 O 0.709582 0.532614 0.625579 0.217 - 54 O 0.790418 0.415997 0.823033 0.217 - 55 O 0.592965 0.915997 0.125579 0.217 - 56 O 0.290418 0.467386 0.374421 0.217 - 57 O 0.407035 0.084003 0.874421 0.217 - 58 O 0.209582 0.584003 0.176967 0.217 - 59 O 0.176967 0.209582 0.584003 0.217 - 60 O 0.625579 0.709582 0.532614 0.217 - 61 O 0.323032 0.907035 0.032614 0.217 - 62 O 0.584003 0.907035 0.374421 0.217 - 63 O 0.532614 0.407035 0.823033 0.217 - 64 O 0.967386 0.790418 0.874421 0.217 - 65 O 0.532614 0.625579 0.709582 0.217 - 66 O 0.323032 0.915997 0.290418 0.217 - 67 O 0.176967 0.467386 0.592965 0.217 - 68 O 0.874421 0.967386 0.790418 0.217 - 69 O 0.407035 0.823032 0.532614 0.217 - 70 O 0.290418 0.323032 0.915997 0.217 - 71 O 0.092965 0.625579 0.415997 0.217 - 72 O 0.790418 0.874421 0.967386 0.217 - 73 O 0.374421 0.584003 0.907035 0.217 - 74 O 0.415997 0.823032 0.790418 0.217 - 75 O 0.032614 0.323032 0.907035 0.217 - 76 O 0.084003 0.874421 0.407035 0.217 - 77 O 0.084003 0.709582 0.676967 0.217 - 78 O 0.125579 0.592965 0.915997 0.217 - 79 O 0.092965 0.967386 0.676967 0.217","# generated using pymatgen -data_Ho3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.81685994 -_cell_length_b 10.81685994 -_cell_length_c 10.81685994 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ho3Fe5O12 -_chemical_formula_sum 'Ho12 Fe20 O48' -_cell_volume 974.27538156 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ho Ho0 1 0.75000000 0.12500000 0.37500000 1 - Ho Ho1 1 0.37500000 0.12500000 0.25000000 1 - Ho Ho2 1 0.87500000 0.62500000 0.25000000 1 - Ho Ho3 1 0.25000000 0.37500000 0.12500000 1 - Ho Ho4 1 0.62500000 0.25000000 0.87500000 1 - Ho Ho5 1 0.37500000 0.75000000 0.12500000 1 - Ho Ho6 1 0.12500000 0.25000000 0.37500000 1 - Ho Ho7 1 0.87500000 0.75000000 0.62500000 1 - Ho Ho8 1 0.75000000 0.62500000 0.87500000 1 - Ho Ho9 1 0.62500000 0.87500000 0.75000000 1 - Ho Ho10 1 0.12500000 0.37500000 0.75000000 1 - Ho Ho11 1 0.25000000 0.87500000 0.62500000 1 - Fe Fe12 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe13 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe14 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe15 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe16 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe19 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe20 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe21 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe22 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe23 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe24 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe25 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe26 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe27 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe28 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe29 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe30 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.90703500 0.03261400 0.32303300 1 - O O33 1 0.87442100 0.40703500 0.08400300 1 - O O34 1 0.91599700 0.29041800 0.32303300 1 - O O35 1 0.91599700 0.12557900 0.59296500 1 - O O36 1 0.96738600 0.67696700 0.09296500 1 - O O37 1 0.58400300 0.17696700 0.20958200 1 - O O38 1 0.62557900 0.41599700 0.09296500 1 - O O39 1 0.20958200 0.12557900 0.03261400 1 - O O40 1 0.70958200 0.67696700 0.08400300 1 - O O41 1 0.59296500 0.17696700 0.46738600 1 - O O42 1 0.90703500 0.37442100 0.58400300 1 - O O43 1 0.12557900 0.03261400 0.20958200 1 - O O44 1 0.82303200 0.53261400 0.40703500 1 - O O45 1 0.67696700 0.08400300 0.70958200 1 - O O46 1 0.46738600 0.37442100 0.29041800 1 - O O47 1 0.46738600 0.59296500 0.17696800 1 - O O48 1 0.41599700 0.09296500 0.62557900 1 - O O49 1 0.03261400 0.20958200 0.12557900 1 - O O50 1 0.82303200 0.79041800 0.41599700 1 - O O51 1 0.37442100 0.29041800 0.46738600 1 - O O52 1 0.67696700 0.09296500 0.96738600 1 - O O53 1 0.70958200 0.53261400 0.62557900 1 - O O54 1 0.79041800 0.41599700 0.82303300 1 - O O55 1 0.59296500 0.91599700 0.12557900 1 - O O56 1 0.29041800 0.46738600 0.37442100 1 - O O57 1 0.40703500 0.08400300 0.87442100 1 - O O58 1 0.20958200 0.58400300 0.17696700 1 - O O59 1 0.17696700 0.20958200 0.58400300 1 - O O60 1 0.62557900 0.70958200 0.53261400 1 - O O61 1 0.32303200 0.90703500 0.03261400 1 - O O62 1 0.58400300 0.90703500 0.37442100 1 - O O63 1 0.53261400 0.40703500 0.82303300 1 - O O64 1 0.96738600 0.79041800 0.87442100 1 - O O65 1 0.53261400 0.62557900 0.70958200 1 - O O66 1 0.32303200 0.91599700 0.29041800 1 - O O67 1 0.17696700 0.46738600 0.59296500 1 - O O68 1 0.87442100 0.96738600 0.79041800 1 - O O69 1 0.40703500 0.82303200 0.53261400 1 - O O70 1 0.29041800 0.32303200 0.91599700 1 - O O71 1 0.09296500 0.62557900 0.41599700 1 - O O72 1 0.79041800 0.87442100 0.96738600 1 - O O73 1 0.37442100 0.58400300 0.90703500 1 - O O74 1 0.41599700 0.82303200 0.79041800 1 - O O75 1 0.03261400 0.32303200 0.90703500 1 - O O76 1 0.08400300 0.87442100 0.40703500 1 - O O77 1 0.08400300 0.70958200 0.67696700 1 - O O78 1 0.12557900 0.59296500 0.91599700 1 - O O79 1 0.09296500 0.96738600 0.67696700 1 -" -Ho3Ga5O12,mp-15575,Ia-3d,[409390],0.0,{'tags': ['Triholmium digallium tris(gallate)']},"Full Formula (Ho12 Ga20 O48) -Reduced Formula: Ho3Ga5O12 -abc : 10.722276 10.722276 10.722276 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Ho 0.75 0.625 0.875 -0.001 - 1 Ho 0.25 0.875 0.625 -0.001 - 2 Ho 0.625 0.25 0.875 -0.001 - 3 Ho 0.875 0.75 0.625 -0.001 - 4 Ho 0.875 0.625 0.25 -0.001 - 5 Ho 0.625 0.875 0.75 -0.001 - 6 Ho 0.25 0.375 0.125 -0.001 - 7 Ho 0.75 0.125 0.375 -0.001 - 8 Ho 0.375 0.75 0.125 -0.001 - 9 Ho 0.125 0.25 0.375 -0.001 - 10 Ho 0.125 0.375 0.75 -0.001 - 11 Ho 0.375 0.125 0.25 -0.001 - 12 Ga 0.375 0.625 0.75 -0 - 13 Ga 0.625 0.375 0.25 -0 - 14 Ga 0.625 0.75 0.375 -0 - 15 Ga 0.25 0.125 0.875 -0 - 16 Ga 0.875 0.25 0.125 -0 - 17 Ga 0.75 0.375 0.625 -0 - 18 Ga 0.25 0.625 0.375 -0 - 19 Ga 0.75 0.875 0.125 -0 - 20 Ga 0.125 0.75 0.875 -0 - 21 Ga 0.375 0.25 0.625 -0 - 22 Ga 0.875 0.125 0.75 -0 - 23 Ga 0.125 0.875 0.25 -0 - 24 Ga 0.5 0 0.5 -0 - 25 Ga 0 0.5 0 -0 - 26 Ga 0.5 0.5 0.5 -0 - 27 Ga 0 0 0.5 -0 - 28 Ga 0 0 0 -0 - 29 Ga 0 0.5 0.5 -0 - 30 Ga 0.5 0.5 0 -0 - 31 Ga 0.5 0 0 -0 - 32 O 0.529517 0.405528 0.822738 0.001 - 33 O 0.822738 0.529517 0.405528 0 - 34 O 0.793221 0.876011 0.970483 0.001 - 35 O 0.41721 0.094472 0.623989 0.001 - 36 O 0.876011 0.405528 0.08279 0.001 - 37 O 0.677262 0.08279 0.706779 0.001 - 38 O 0.822738 0.793221 0.41721 0.001 - 39 O 0.405528 0.822738 0.529517 0.001 - 40 O 0.623989 0.706779 0.529517 0.001 - 41 O 0.41721 0.822738 0.793221 0.001 - 42 O 0.405528 0.08279 0.876011 0 - 43 O 0.094472 0.970483 0.677262 0.001 - 44 O 0.970483 0.677262 0.094472 0.001 - 45 O 0.793221 0.41721 0.822738 0.001 - 46 O 0.529517 0.623989 0.706779 0.001 - 47 O 0.706779 0.529517 0.623989 0.001 - 48 O 0.08279 0.876011 0.405528 0.001 - 49 O 0.970483 0.793221 0.876011 0.001 - 50 O 0.08279 0.706779 0.677262 0.001 - 51 O 0.376011 0.293221 0.470483 0.001 - 52 O 0.623989 0.41721 0.094472 0.001 - 53 O 0.094472 0.623989 0.41721 0.001 - 54 O 0.706779 0.677262 0.08279 0.001 - 55 O 0.677262 0.094472 0.970483 0.001 - 56 O 0.470483 0.594472 0.177262 0.001 - 57 O 0.177262 0.470483 0.594472 0.001 - 58 O 0.206779 0.123989 0.029517 0.001 - 59 O 0.58279 0.905528 0.376011 0.001 - 60 O 0.123989 0.594472 0.91721 0.001 - 61 O 0.322738 0.91721 0.293221 0.001 - 62 O 0.177262 0.206779 0.58279 0 - 63 O 0.594472 0.177262 0.470483 0.001 - 64 O 0.322738 0.905528 0.029517 0.001 - 65 O 0.293221 0.322738 0.91721 0.001 - 66 O 0.905528 0.376011 0.58279 0.001 - 67 O 0.123989 0.029517 0.206779 0.001 - 68 O 0.376011 0.58279 0.905528 0.001 - 69 O 0.91721 0.293221 0.322738 0.001 - 70 O 0.029517 0.206779 0.123989 0.001 - 71 O 0.91721 0.123989 0.594472 0.001 - 72 O 0.293221 0.470483 0.376011 0.001 - 73 O 0.470483 0.376011 0.293221 0.001 - 74 O 0.206779 0.58279 0.177262 0.001 - 75 O 0.029517 0.322738 0.905528 0.001 - 76 O 0.905528 0.029517 0.322738 0.001 - 77 O 0.594472 0.91721 0.123989 0.001 - 78 O 0.58279 0.177262 0.206779 0.001 - 79 O 0.876011 0.970483 0.793221 0.001","# generated using pymatgen -data_Ho3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.72227611 -_cell_length_b 10.72227611 -_cell_length_c 10.72227611 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Ho3Ga5O12 -_chemical_formula_sum 'Ho12 Ga20 O48' -_cell_volume 948.94068998 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Ho Ho0 1 0.75000000 0.62500000 0.87500000 1 - Ho Ho1 1 0.25000000 0.87500000 0.62500000 1 - Ho Ho2 1 0.62500000 0.25000000 0.87500000 1 - Ho Ho3 1 0.87500000 0.75000000 0.62500000 1 - Ho Ho4 1 0.87500000 0.62500000 0.25000000 1 - Ho Ho5 1 0.62500000 0.87500000 0.75000000 1 - Ho Ho6 1 0.25000000 0.37500000 0.12500000 1 - Ho Ho7 1 0.75000000 0.12500000 0.37500000 1 - Ho Ho8 1 0.37500000 0.75000000 0.12500000 1 - Ho Ho9 1 0.12500000 0.25000000 0.37500000 1 - Ho Ho10 1 0.12500000 0.37500000 0.75000000 1 - Ho Ho11 1 0.37500000 0.12500000 0.25000000 1 - Ga Ga12 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga13 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga14 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga15 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga16 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga17 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga18 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga19 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga20 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga21 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga24 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga25 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga26 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga28 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga29 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.52951700 0.40552800 0.82273800 1 - O O33 1 0.82273800 0.52951700 0.40552800 1 - O O34 1 0.79322100 0.87601100 0.97048300 1 - O O35 1 0.41721000 0.09447200 0.62398900 1 - O O36 1 0.87601100 0.40552800 0.08279000 1 - O O37 1 0.67726200 0.08279000 0.70677900 1 - O O38 1 0.82273800 0.79322100 0.41721000 1 - O O39 1 0.40552800 0.82273800 0.52951700 1 - O O40 1 0.62398900 0.70677900 0.52951700 1 - O O41 1 0.41721000 0.82273800 0.79322100 1 - O O42 1 0.40552800 0.08279000 0.87601100 1 - O O43 1 0.09447200 0.97048300 0.67726200 1 - O O44 1 0.97048300 0.67726200 0.09447200 1 - O O45 1 0.79322100 0.41721000 0.82273800 1 - O O46 1 0.52951700 0.62398900 0.70677900 1 - O O47 1 0.70677900 0.52951700 0.62398900 1 - O O48 1 0.08279000 0.87601100 0.40552800 1 - O O49 1 0.97048300 0.79322100 0.87601100 1 - O O50 1 0.08279000 0.70677900 0.67726200 1 - O O51 1 0.37601100 0.29322100 0.47048300 1 - O O52 1 0.62398900 0.41721000 0.09447200 1 - O O53 1 0.09447200 0.62398900 0.41721000 1 - O O54 1 0.70677900 0.67726200 0.08279000 1 - O O55 1 0.67726200 0.09447200 0.97048300 1 - O O56 1 0.47048300 0.59447200 0.17726200 1 - O O57 1 0.17726200 0.47048300 0.59447200 1 - O O58 1 0.20677900 0.12398900 0.02951700 1 - O O59 1 0.58279000 0.90552800 0.37601100 1 - O O60 1 0.12398900 0.59447200 0.91721000 1 - O O61 1 0.32273800 0.91721000 0.29322100 1 - O O62 1 0.17726200 0.20677900 0.58279000 1 - O O63 1 0.59447200 0.17726200 0.47048300 1 - O O64 1 0.32273800 0.90552800 0.02951700 1 - O O65 1 0.29322100 0.32273800 0.91721000 1 - O O66 1 0.90552800 0.37601100 0.58279000 1 - O O67 1 0.12398900 0.02951700 0.20677900 1 - O O68 1 0.37601100 0.58279000 0.90552800 1 - O O69 1 0.91721000 0.29322100 0.32273800 1 - O O70 1 0.02951700 0.20677900 0.12398900 1 - O O71 1 0.91721000 0.12398900 0.59447200 1 - O O72 1 0.29322100 0.47048300 0.37601100 1 - O O73 1 0.47048300 0.37601100 0.29322100 1 - O O74 1 0.20677900 0.58279000 0.17726200 1 - O O75 1 0.02951700 0.32273800 0.90552800 1 - O O76 1 0.90552800 0.02951700 0.32273800 1 - O O77 1 0.59447200 0.91721000 0.12398900 1 - O O78 1 0.58279000 0.17726200 0.20677900 1 - O O79 1 0.87601100 0.97048300 0.79322100 1 -" -La3Al5O12,mp-780432,Ia-3d,[],0.033431806624999894,{'tags': []},"Full Formula (La12 Al20 O48) -Reduced Formula: La3Al5O12 -abc : 10.832847 10.832847 10.832847 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.75 0.125 0.375 0 - 1 La 0.375 0.125 0.25 0 - 2 La 0.875 0.625 0.25 0 - 3 La 0.25 0.375 0.125 0 - 4 La 0.125 0.25 0.375 0 - 5 La 0.625 0.25 0.875 0 - 6 La 0.375 0.75 0.125 0 - 7 La 0.875 0.75 0.625 0 - 8 La 0.75 0.625 0.875 0 - 9 La 0.125 0.375 0.75 0 - 10 La 0.625 0.875 0.75 0 - 11 La 0.25 0.875 0.625 0 - 12 Al 0.875 0.25 0.125 -0 - 13 Al 0.5 0 0 0 - 14 Al 0 0 0 0 - 15 Al 0.875 0.125 0.75 -0 - 16 Al 0.5 0.5 0 0 - 17 Al 0.5 0 0.5 0 - 18 Al 0.625 0.375 0.25 -0 - 19 Al 0.75 0.875 0.125 -0 - 20 Al 0.75 0.375 0.625 -0 - 21 Al 0.625 0.75 0.375 -0 - 22 Al 0.375 0.25 0.625 -0 - 23 Al 0 0.5 0 0 - 24 Al 0 0 0.5 0 - 25 Al 0.5 0.5 0.5 0 - 26 Al 0.25 0.625 0.375 -0 - 27 Al 0.25 0.125 0.875 -0 - 28 Al 0 0.5 0.5 0 - 29 Al 0.375 0.625 0.75 -0 - 30 Al 0.125 0.875 0.25 -0 - 31 Al 0.125 0.75 0.875 -0 - 32 O 0.89818 0.011608 0.318692 -0 - 33 O 0.886572 0.39818 0.079488 -0 - 34 O 0.920512 0.307084 0.318692 -0 - 35 O 0.920512 0.113428 0.60182 -0 - 36 O 0.988392 0.681308 0.10182 -0 - 37 O 0.579488 0.181308 0.192916 -0 - 38 O 0.613428 0.420512 0.10182 -0 - 39 O 0.192916 0.113428 0.011608 -0 - 40 O 0.692916 0.681308 0.079488 -0 - 41 O 0.60182 0.181308 0.488392 -0 - 42 O 0.89818 0.386572 0.579488 -0 - 43 O 0.113428 0.011608 0.192916 -0 - 44 O 0.818692 0.511608 0.39818 -0 - 45 O 0.681308 0.079488 0.692916 -0 - 46 O 0.488392 0.386572 0.307084 -0 - 47 O 0.488392 0.60182 0.181308 -0 - 48 O 0.011608 0.192916 0.113428 -0 - 49 O 0.420512 0.10182 0.613428 -0 - 50 O 0.386572 0.307084 0.488392 -0 - 51 O 0.681308 0.10182 0.988392 -0 - 52 O 0.818692 0.807084 0.420512 -0 - 53 O 0.807084 0.420512 0.818692 -0 - 54 O 0.692916 0.511608 0.613428 -0 - 55 O 0.60182 0.920512 0.113428 -0 - 56 O 0.192916 0.579488 0.181308 -0 - 57 O 0.307084 0.488392 0.386572 -0 - 58 O 0.39818 0.079488 0.886572 -0 - 59 O 0.613428 0.692916 0.511608 -0 - 60 O 0.181308 0.192916 0.579488 -0 - 61 O 0.318692 0.89818 0.011608 -0 - 62 O 0.579488 0.89818 0.386572 -0 - 63 O 0.511608 0.39818 0.818692 -0 - 64 O 0.988392 0.807084 0.886572 -0 - 65 O 0.511608 0.613428 0.692916 -0 - 66 O 0.181308 0.488392 0.60182 -0 - 67 O 0.886572 0.988392 0.807084 -0 - 68 O 0.318692 0.920512 0.307084 -0 - 69 O 0.307084 0.318692 0.920512 -0 - 70 O 0.39818 0.818692 0.511608 -0 - 71 O 0.10182 0.613428 0.420512 -0 - 72 O 0.807084 0.886572 0.988392 -0 - 73 O 0.386572 0.579488 0.89818 -0 - 74 O 0.079488 0.886572 0.39818 -0 - 75 O 0.420512 0.818692 0.807084 -0 - 76 O 0.011608 0.318692 0.89818 -0 - 77 O 0.079488 0.692916 0.681308 -0 - 78 O 0.113428 0.60182 0.920512 -0 - 79 O 0.10182 0.988392 0.681308 -0","# generated using pymatgen -data_La3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.83284677 -_cell_length_b 10.83284677 -_cell_length_c 10.83284677 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3Al5O12 -_chemical_formula_sum 'La12 Al20 O48' -_cell_volume 978.60157381 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.75000000 0.12500000 0.37500000 1 - La La1 1 0.37500000 0.12500000 0.25000000 1 - La La2 1 0.87500000 0.62500000 0.25000000 1 - La La3 1 0.25000000 0.37500000 0.12500000 1 - La La4 1 0.12500000 0.25000000 0.37500000 1 - La La5 1 0.62500000 0.25000000 0.87500000 1 - La La6 1 0.37500000 0.75000000 0.12500000 1 - La La7 1 0.87500000 0.75000000 0.62500000 1 - La La8 1 0.75000000 0.62500000 0.87500000 1 - La La9 1 0.12500000 0.37500000 0.75000000 1 - La La10 1 0.62500000 0.87500000 0.75000000 1 - La La11 1 0.25000000 0.87500000 0.62500000 1 - Al Al12 1 0.87500000 0.25000000 0.12500000 1 - Al Al13 1 0.50000000 0.00000000 0.00000000 1 - Al Al14 1 0.00000000 0.00000000 0.00000000 1 - Al Al15 1 0.87500000 0.12500000 0.75000000 1 - Al Al16 1 0.50000000 0.50000000 0.00000000 1 - Al Al17 1 0.50000000 0.00000000 0.50000000 1 - Al Al18 1 0.62500000 0.37500000 0.25000000 1 - Al Al19 1 0.75000000 0.87500000 0.12500000 1 - Al Al20 1 0.75000000 0.37500000 0.62500000 1 - Al Al21 1 0.62500000 0.75000000 0.37500000 1 - Al Al22 1 0.37500000 0.25000000 0.62500000 1 - Al Al23 1 0.00000000 0.50000000 0.00000000 1 - Al Al24 1 0.00000000 0.00000000 0.50000000 1 - Al Al25 1 0.50000000 0.50000000 0.50000000 1 - Al Al26 1 0.25000000 0.62500000 0.37500000 1 - Al Al27 1 0.25000000 0.12500000 0.87500000 1 - Al Al28 1 0.00000000 0.50000000 0.50000000 1 - Al Al29 1 0.37500000 0.62500000 0.75000000 1 - Al Al30 1 0.12500000 0.87500000 0.25000000 1 - Al Al31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.89818000 0.01160800 0.31869200 1 - O O33 1 0.88657200 0.39818000 0.07948800 1 - O O34 1 0.92051200 0.30708400 0.31869200 1 - O O35 1 0.92051200 0.11342800 0.60182000 1 - O O36 1 0.98839200 0.68130800 0.10182000 1 - O O37 1 0.57948800 0.18130800 0.19291600 1 - O O38 1 0.61342800 0.42051200 0.10182000 1 - O O39 1 0.19291600 0.11342800 0.01160800 1 - O O40 1 0.69291600 0.68130800 0.07948800 1 - O O41 1 0.60182000 0.18130800 0.48839200 1 - O O42 1 0.89818000 0.38657200 0.57948800 1 - O O43 1 0.11342800 0.01160800 0.19291600 1 - O O44 1 0.81869200 0.51160800 0.39818000 1 - O O45 1 0.68130800 0.07948800 0.69291600 1 - O O46 1 0.48839200 0.38657200 0.30708400 1 - O O47 1 0.48839200 0.60182000 0.18130800 1 - O O48 1 0.01160800 0.19291600 0.11342800 1 - O O49 1 0.42051200 0.10182000 0.61342800 1 - O O50 1 0.38657200 0.30708400 0.48839200 1 - O O51 1 0.68130800 0.10182000 0.98839200 1 - O O52 1 0.81869200 0.80708400 0.42051200 1 - O O53 1 0.80708400 0.42051200 0.81869200 1 - O O54 1 0.69291600 0.51160800 0.61342800 1 - O O55 1 0.60182000 0.92051200 0.11342800 1 - O O56 1 0.19291600 0.57948800 0.18130800 1 - O O57 1 0.30708400 0.48839200 0.38657200 1 - O O58 1 0.39818000 0.07948800 0.88657200 1 - O O59 1 0.61342800 0.69291600 0.51160800 1 - O O60 1 0.18130800 0.19291600 0.57948800 1 - O O61 1 0.31869200 0.89818000 0.01160800 1 - O O62 1 0.57948800 0.89818000 0.38657200 1 - O O63 1 0.51160800 0.39818000 0.81869200 1 - O O64 1 0.98839200 0.80708400 0.88657200 1 - O O65 1 0.51160800 0.61342800 0.69291600 1 - O O66 1 0.18130800 0.48839200 0.60182000 1 - O O67 1 0.88657200 0.98839200 0.80708400 1 - O O68 1 0.31869200 0.92051200 0.30708400 1 - O O69 1 0.30708400 0.31869200 0.92051200 1 - O O70 1 0.39818000 0.81869200 0.51160800 1 - O O71 1 0.10182000 0.61342800 0.42051200 1 - O O72 1 0.80708400 0.88657200 0.98839200 1 - O O73 1 0.38657200 0.57948800 0.89818000 1 - O O74 1 0.07948800 0.88657200 0.39818000 1 - O O75 1 0.42051200 0.81869200 0.80708400 1 - O O76 1 0.01160800 0.31869200 0.89818000 1 - O O77 1 0.07948800 0.69291600 0.68130800 1 - O O78 1 0.11342800 0.60182000 0.92051200 1 - O O79 1 0.10182000 0.98839200 0.68130800 1 -" -La3Fe5O12,mp-1212003,Ia-3d,[],0.039770601875000366,"{'tags': ['garnet family', 'La3Fe5O12 hyp', 'Y3Al5O12']}","Full Formula (La12 Fe20 O48) -Reduced Formula: La3Fe5O12 -abc : 11.167077 11.167077 11.167077 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.25 0.375 0.125 0.03 - 1 La 0.75 0.625 0.875 0.03 - 2 La 0.75 0.125 0.375 0.03 - 3 La 0.125 0.25 0.375 0.03 - 4 La 0.375 0.75 0.125 0.03 - 5 La 0.25 0.875 0.625 0.03 - 6 La 0.875 0.75 0.625 0.03 - 7 La 0.625 0.25 0.875 0.03 - 8 La 0.375 0.125 0.25 0.03 - 9 La 0.625 0.875 0.75 0.03 - 10 La 0.125 0.375 0.75 0.03 - 11 La 0.875 0.625 0.25 0.03 - 12 Fe 0.25 0.625 0.375 4.27 - 13 Fe 0.75 0.375 0.625 4.27 - 14 Fe 0.75 0.875 0.125 4.27 - 15 Fe 0.375 0.25 0.625 4.27 - 16 Fe 0.625 0.75 0.375 4.27 - 17 Fe 0.25 0.125 0.875 4.27 - 18 Fe 0.125 0.75 0.875 4.27 - 19 Fe 0.875 0.25 0.125 4.27 - 20 Fe 0.625 0.375 0.25 4.27 - 21 Fe 0.375 0.625 0.75 4.27 - 22 Fe 0.875 0.125 0.75 4.27 - 23 Fe 0.125 0.875 0.25 4.27 - 24 Fe 0 0 0 4.399 - 25 Fe 0.5 0 0.5 4.399 - 26 Fe 0 0.5 0.5 4.399 - 27 Fe 0.5 0 0 4.399 - 28 Fe 0.5 0.5 0 4.399 - 29 Fe 0.5 0.5 0.5 4.399 - 30 Fe 0 0 0.5 4.399 - 31 Fe 0 0.5 0 4.399 - 32 O 0.477378 0.380138 0.299013 0.215 - 33 O 0.522622 0.619862 0.700987 0.215 - 34 O 0.581125 0.178365 0.200987 0.215 - 35 O 0.918875 0.119862 0.59724 0.215 - 36 O 0.299013 0.477378 0.380138 0.216 - 37 O 0.321635 0.918875 0.299013 0.215 - 38 O 0.418875 0.821635 0.799013 0.215 - 39 O 0.081125 0.880138 0.40276 0.215 - 40 O 0.700987 0.522622 0.619862 0.216 - 41 O 0.678365 0.081125 0.700987 0.215 - 42 O 0.022622 0.321635 0.90276 0.215 - 43 O 0.200987 0.581125 0.178365 0.216 - 44 O 0.119862 0.022622 0.200987 0.216 - 45 O 0.977378 0.678365 0.09724 0.215 - 46 O 0.799013 0.418875 0.821635 0.216 - 47 O 0.880138 0.977378 0.799013 0.216 - 48 O 0.59724 0.918875 0.119862 0.216 - 49 O 0.178365 0.477378 0.59724 0.215 - 50 O 0.40276 0.081125 0.880138 0.216 - 51 O 0.821635 0.522622 0.40276 0.215 - 52 O 0.90276 0.022622 0.321635 0.216 - 53 O 0.380138 0.581125 0.90276 0.216 - 54 O 0.09724 0.977378 0.678365 0.216 - 55 O 0.619862 0.418875 0.09724 0.216 - 56 O 0.380138 0.299013 0.477378 0.216 - 57 O 0.581125 0.90276 0.380138 0.215 - 58 O 0.619862 0.700987 0.522622 0.216 - 59 O 0.418875 0.09724 0.619862 0.215 - 60 O 0.119862 0.59724 0.918875 0.216 - 61 O 0.022622 0.200987 0.119862 0.215 - 62 O 0.880138 0.40276 0.081125 0.216 - 63 O 0.977378 0.799013 0.880138 0.215 - 64 O 0.321635 0.90276 0.022622 0.216 - 65 O 0.918875 0.299013 0.321635 0.215 - 66 O 0.678365 0.09724 0.977378 0.215 - 67 O 0.081125 0.700987 0.678365 0.215 - 68 O 0.178365 0.200987 0.581125 0.215 - 69 O 0.477378 0.59724 0.178365 0.215 - 70 O 0.821635 0.799013 0.418875 0.215 - 71 O 0.522622 0.40276 0.821635 0.215 - 72 O 0.299013 0.321635 0.918875 0.216 - 73 O 0.700987 0.678365 0.081125 0.216 - 74 O 0.200987 0.119862 0.022622 0.216 - 75 O 0.799013 0.880138 0.977378 0.216 - 76 O 0.90276 0.380138 0.581125 0.216 - 77 O 0.09724 0.619862 0.418875 0.216 - 78 O 0.59724 0.178365 0.477378 0.216 - 79 O 0.40276 0.821635 0.522622 0.216","# generated using pymatgen -data_La3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.16707715 -_cell_length_b 11.16707715 -_cell_length_c 11.16707715 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3Fe5O12 -_chemical_formula_sum 'La12 Fe20 O48' -_cell_volume 1072.00462537 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.25000000 0.37500000 0.12500000 1 - La La1 1 0.75000000 0.62500000 0.87500000 1 - La La2 1 0.75000000 0.12500000 0.37500000 1 - La La3 1 0.12500000 0.25000000 0.37500000 1 - La La4 1 0.37500000 0.75000000 0.12500000 1 - La La5 1 0.25000000 0.87500000 0.62500000 1 - La La6 1 0.87500000 0.75000000 0.62500000 1 - La La7 1 0.62500000 0.25000000 0.87500000 1 - La La8 1 0.37500000 0.12500000 0.25000000 1 - La La9 1 0.62500000 0.87500000 0.75000000 1 - La La10 1 0.12500000 0.37500000 0.75000000 1 - La La11 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe12 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe13 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe14 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe15 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe16 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe17 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe18 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe19 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe20 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe21 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe22 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe23 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe24 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe25 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe26 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe27 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe28 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe29 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe30 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47737800 0.38013800 0.29901300 1 - O O33 1 0.52262200 0.61986200 0.70098700 1 - O O34 1 0.58112500 0.17836500 0.20098700 1 - O O35 1 0.91887500 0.11986200 0.59724000 1 - O O36 1 0.29901300 0.47737800 0.38013800 1 - O O37 1 0.32163500 0.91887500 0.29901300 1 - O O38 1 0.41887500 0.82163500 0.79901300 1 - O O39 1 0.08112500 0.88013800 0.40276000 1 - O O40 1 0.70098700 0.52262200 0.61986200 1 - O O41 1 0.67836500 0.08112500 0.70098700 1 - O O42 1 0.02262200 0.32163500 0.90276000 1 - O O43 1 0.20098700 0.58112500 0.17836500 1 - O O44 1 0.11986200 0.02262200 0.20098700 1 - O O45 1 0.97737800 0.67836500 0.09724000 1 - O O46 1 0.79901300 0.41887500 0.82163500 1 - O O47 1 0.88013800 0.97737800 0.79901300 1 - O O48 1 0.59724000 0.91887500 0.11986200 1 - O O49 1 0.17836500 0.47737800 0.59724000 1 - O O50 1 0.40276000 0.08112500 0.88013800 1 - O O51 1 0.82163500 0.52262200 0.40276000 1 - O O52 1 0.90276000 0.02262200 0.32163500 1 - O O53 1 0.38013800 0.58112500 0.90276000 1 - O O54 1 0.09724000 0.97737800 0.67836500 1 - O O55 1 0.61986200 0.41887500 0.09724000 1 - O O56 1 0.38013800 0.29901300 0.47737800 1 - O O57 1 0.58112500 0.90276000 0.38013800 1 - O O58 1 0.61986200 0.70098700 0.52262200 1 - O O59 1 0.41887500 0.09724000 0.61986200 1 - O O60 1 0.11986200 0.59724000 0.91887500 1 - O O61 1 0.02262200 0.20098700 0.11986200 1 - O O62 1 0.88013800 0.40276000 0.08112500 1 - O O63 1 0.97737800 0.79901300 0.88013800 1 - O O64 1 0.32163500 0.90276000 0.02262200 1 - O O65 1 0.91887500 0.29901300 0.32163500 1 - O O66 1 0.67836500 0.09724000 0.97737800 1 - O O67 1 0.08112500 0.70098700 0.67836500 1 - O O68 1 0.17836500 0.20098700 0.58112500 1 - O O69 1 0.47737800 0.59724000 0.17836500 1 - O O70 1 0.82163500 0.79901300 0.41887500 1 - O O71 1 0.52262200 0.40276000 0.82163500 1 - O O72 1 0.29901300 0.32163500 0.91887500 1 - O O73 1 0.70098700 0.67836500 0.08112500 1 - O O74 1 0.20098700 0.11986200 0.02262200 1 - O O75 1 0.79901300 0.88013800 0.97737800 1 - O O76 1 0.90276000 0.38013800 0.58112500 1 - O O77 1 0.09724000 0.61986200 0.41887500 1 - O O78 1 0.59724000 0.17836500 0.47737800 1 - O O79 1 0.40276000 0.82163500 0.52262200 1 -" -La3Ga5O12,mp-780561,Ia-3d,[],0.0,{'tags': []},"Full Formula (La12 Ga20 O48) -Reduced Formula: La3Ga5O12 -abc : 11.066824 11.066824 11.066824 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 La 0.75 0.125 0.375 0 - 1 La 0.875 0.625 0.25 0 - 2 La 0.375 0.125 0.25 0 - 3 La 0.25 0.375 0.125 0 - 4 La 0.125 0.25 0.375 0 - 5 La 0.625 0.25 0.875 0 - 6 La 0.375 0.75 0.125 0 - 7 La 0.875 0.75 0.625 0 - 8 La 0.75 0.625 0.875 0 - 9 La 0.125 0.375 0.75 0 - 10 La 0.625 0.875 0.75 0 - 11 La 0.25 0.875 0.625 0 - 12 Ga 0.875 0.25 0.125 0 - 13 Ga 0.5 0 0 -0 - 14 Ga 0 0 0 -0 - 15 Ga 0.875 0.125 0.75 0 - 16 Ga 0.5 0.5 0 -0 - 17 Ga 0.5 0 0.5 -0 - 18 Ga 0.625 0.375 0.25 0 - 19 Ga 0.75 0.875 0.125 -0 - 20 Ga 0.75 0.375 0.625 -0 - 21 Ga 0.375 0.25 0.625 0 - 22 Ga 0 0.5 0 -0 - 23 Ga 0 0 0.5 0 - 24 Ga 0.5 0.5 0.5 0 - 25 Ga 0.625 0.75 0.375 -0 - 26 Ga 0.25 0.625 0.375 -0 - 27 Ga 0.25 0.125 0.875 0 - 28 Ga 0 0.5 0.5 -0 - 29 Ga 0.375 0.625 0.75 0 - 30 Ga 0.125 0.875 0.25 -0 - 31 Ga 0.125 0.75 0.875 -0 - 32 O 0.903261 0.021006 0.320903 0 - 33 O 0.882255 0.403261 0.082359 -0 - 34 O 0.917641 0.299897 0.320903 -0 - 35 O 0.978994 0.679097 0.096739 0 - 36 O 0.917641 0.117745 0.596739 -0 - 37 O 0.582359 0.179097 0.200103 -0 - 38 O 0.617745 0.417641 0.096739 0 - 39 O 0.200103 0.117745 0.021006 -0 - 40 O 0.596739 0.179097 0.478994 0 - 41 O 0.700103 0.679097 0.082359 -0 - 42 O 0.903261 0.382255 0.582359 0 - 43 O 0.679097 0.082359 0.700103 0 - 44 O 0.117745 0.021006 0.200103 0 - 45 O 0.820903 0.521006 0.403261 -0 - 46 O 0.478994 0.382255 0.299897 -0 - 47 O 0.478994 0.596739 0.179097 -0 - 48 O 0.021006 0.200103 0.117745 0 - 49 O 0.417641 0.096739 0.617745 0 - 50 O 0.820903 0.799897 0.417641 0 - 51 O 0.382255 0.299897 0.478994 -0 - 52 O 0.679097 0.096739 0.978994 -0 - 53 O 0.799897 0.417641 0.820903 -0 - 54 O 0.700103 0.521006 0.617745 0 - 55 O 0.596739 0.917641 0.117745 0 - 56 O 0.299897 0.478994 0.382255 0 - 57 O 0.200103 0.582359 0.179097 0 - 58 O 0.403261 0.082359 0.882255 0 - 59 O 0.617745 0.700103 0.521006 0 - 60 O 0.320903 0.903261 0.021006 -0 - 61 O 0.179097 0.200103 0.582359 -0 - 62 O 0.521006 0.403261 0.820903 0 - 63 O 0.582359 0.903261 0.382255 -0 - 64 O 0.978994 0.799897 0.882255 -0 - 65 O 0.521006 0.617745 0.700103 -0 - 66 O 0.882255 0.978994 0.799897 0 - 67 O 0.320903 0.917641 0.299897 0 - 68 O 0.179097 0.478994 0.596739 -0 - 69 O 0.403261 0.820903 0.521006 -0 - 70 O 0.299897 0.320903 0.917641 -0 - 71 O 0.096739 0.617745 0.417641 -0 - 72 O 0.799897 0.882255 0.978994 -0 - 73 O 0.382255 0.582359 0.903261 -0 - 74 O 0.417641 0.820903 0.799897 0 - 75 O 0.082359 0.882255 0.403261 -0 - 76 O 0.021006 0.320903 0.903261 -0 - 77 O 0.082359 0.700103 0.679097 0 - 78 O 0.117745 0.596739 0.917641 0 - 79 O 0.096739 0.978994 0.679097 -0","# generated using pymatgen -data_La3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.06682432 -_cell_length_b 11.06682432 -_cell_length_c 11.06682432 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural La3Ga5O12 -_chemical_formula_sum 'La12 Ga20 O48' -_cell_volume 1043.39116894 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - La La0 1 0.75000000 0.12500000 0.37500000 1 - La La1 1 0.87500000 0.62500000 0.25000000 1 - La La2 1 0.37500000 0.12500000 0.25000000 1 - La La3 1 0.25000000 0.37500000 0.12500000 1 - La La4 1 0.12500000 0.25000000 0.37500000 1 - La La5 1 0.62500000 0.25000000 0.87500000 1 - La La6 1 0.37500000 0.75000000 0.12500000 1 - La La7 1 0.87500000 0.75000000 0.62500000 1 - La La8 1 0.75000000 0.62500000 0.87500000 1 - La La9 1 0.12500000 0.37500000 0.75000000 1 - La La10 1 0.62500000 0.87500000 0.75000000 1 - La La11 1 0.25000000 0.87500000 0.62500000 1 - Ga Ga12 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga13 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga14 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga15 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga16 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga18 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga19 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga20 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga21 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga22 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga23 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga24 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga25 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga26 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga27 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga28 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga29 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga30 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.90326100 0.02100600 0.32090300 1 - O O33 1 0.88225500 0.40326100 0.08235900 1 - O O34 1 0.91764100 0.29989700 0.32090300 1 - O O35 1 0.97899400 0.67909700 0.09673900 1 - O O36 1 0.91764100 0.11774500 0.59673900 1 - O O37 1 0.58235900 0.17909700 0.20010300 1 - O O38 1 0.61774500 0.41764100 0.09673900 1 - O O39 1 0.20010300 0.11774500 0.02100600 1 - O O40 1 0.59673900 0.17909700 0.47899400 1 - O O41 1 0.70010300 0.67909700 0.08235900 1 - O O42 1 0.90326100 0.38225500 0.58235900 1 - O O43 1 0.67909700 0.08235900 0.70010300 1 - O O44 1 0.11774500 0.02100600 0.20010300 1 - O O45 1 0.82090300 0.52100600 0.40326100 1 - O O46 1 0.47899400 0.38225500 0.29989700 1 - O O47 1 0.47899400 0.59673900 0.17909700 1 - O O48 1 0.02100600 0.20010300 0.11774500 1 - O O49 1 0.41764100 0.09673900 0.61774500 1 - O O50 1 0.82090300 0.79989700 0.41764100 1 - O O51 1 0.38225500 0.29989700 0.47899400 1 - O O52 1 0.67909700 0.09673900 0.97899400 1 - O O53 1 0.79989700 0.41764100 0.82090300 1 - O O54 1 0.70010300 0.52100600 0.61774500 1 - O O55 1 0.59673900 0.91764100 0.11774500 1 - O O56 1 0.29989700 0.47899400 0.38225500 1 - O O57 1 0.20010300 0.58235900 0.17909700 1 - O O58 1 0.40326100 0.08235900 0.88225500 1 - O O59 1 0.61774500 0.70010300 0.52100600 1 - O O60 1 0.32090300 0.90326100 0.02100600 1 - O O61 1 0.17909700 0.20010300 0.58235900 1 - O O62 1 0.52100600 0.40326100 0.82090300 1 - O O63 1 0.58235900 0.90326100 0.38225500 1 - O O64 1 0.97899400 0.79989700 0.88225500 1 - O O65 1 0.52100600 0.61774500 0.70010300 1 - O O66 1 0.88225500 0.97899400 0.79989700 1 - O O67 1 0.32090300 0.91764100 0.29989700 1 - O O68 1 0.17909700 0.47899400 0.59673900 1 - O O69 1 0.40326100 0.82090300 0.52100600 1 - O O70 1 0.29989700 0.32090300 0.91764100 1 - O O71 1 0.09673900 0.61774500 0.41764100 1 - O O72 1 0.79989700 0.88225500 0.97899400 1 - O O73 1 0.38225500 0.58235900 0.90326100 1 - O O74 1 0.41764100 0.82090300 0.79989700 1 - O O75 1 0.08235900 0.88225500 0.40326100 1 - O O76 1 0.02100600 0.32090300 0.90326100 1 - O O77 1 0.08235900 0.70010300 0.67909700 1 - O O78 1 0.11774500 0.59673900 0.91764100 1 - O O79 1 0.09673900 0.97899400 0.67909700 1 -" -Lu3Al5O12,mp-14132,Ia-3d,"[182354, 23846]",0.0,{'tags': ['Pentaaluminium trilutetium oxide']},"Full Formula (Lu12 Al20 O48) -Reduced Formula: Lu3Al5O12 -abc : 10.362230 10.362230 10.362230 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Lu 0.375 0.125 0.25 0 - 1 Lu 0.75 0.125 0.375 0 - 2 Lu 0.25 0.375 0.125 0 - 3 Lu 0.125 0.25 0.375 0 - 4 Lu 0.375 0.75 0.125 0 - 5 Lu 0.125 0.375 0.75 0 - 6 Lu 0.625 0.875 0.75 0 - 7 Lu 0.25 0.875 0.625 0 - 8 Lu 0.75 0.625 0.875 0 - 9 Lu 0.875 0.75 0.625 0 - 10 Lu 0.625 0.25 0.875 0 - 11 Lu 0.875 0.625 0.25 0 - 12 Al 0 0 0 0 - 13 Al 0.5 0 0 0 - 14 Al 0 0.5 0 0 - 15 Al 0 0 0.5 0 - 16 Al 0.5 0.5 0 0 - 17 Al 0 0.5 0.5 0 - 18 Al 0.5 0 0.5 0 - 19 Al 0.5 0.5 0.5 0 - 20 Al 0.625 0.375 0.25 0 - 21 Al 0.75 0.375 0.625 0 - 22 Al 0.25 0.125 0.875 0 - 23 Al 0.875 0.25 0.125 0 - 24 Al 0.125 0.875 0.25 0 - 25 Al 0.875 0.125 0.75 0 - 26 Al 0.25 0.625 0.375 0 - 27 Al 0.375 0.25 0.625 0 - 28 Al 0.75 0.875 0.125 0 - 29 Al 0.125 0.75 0.875 0 - 30 Al 0.375 0.625 0.75 0 - 31 Al 0.625 0.75 0.375 0 - 32 O 0.418428 0.821156 0.797445 0 - 33 O 0.879017 0.402729 0.081572 0 - 34 O 0.097271 0.976289 0.678844 0 - 35 O 0.523711 0.620983 0.702555 0 - 36 O 0.678844 0.081572 0.702555 0 - 37 O 0.620983 0.702555 0.523711 0 - 38 O 0.620983 0.418428 0.097271 0 - 39 O 0.702555 0.523711 0.620983 0 - 40 O 0.821156 0.523711 0.402729 0 - 41 O 0.976289 0.797445 0.879017 0 - 42 O 0.797445 0.879017 0.976289 0 - 43 O 0.702555 0.678844 0.081572 0 - 44 O 0.418428 0.097271 0.620983 0 - 45 O 0.402729 0.821156 0.523711 0 - 46 O 0.081572 0.702555 0.678844 0 - 47 O 0.097271 0.620983 0.418428 0 - 48 O 0.523711 0.402729 0.821156 0 - 49 O 0.081572 0.879017 0.402729 0 - 50 O 0.976289 0.678844 0.097271 0 - 51 O 0.178844 0.476289 0.597271 0 - 52 O 0.678844 0.097271 0.976289 0 - 53 O 0.797445 0.418428 0.821156 0 - 54 O 0.402729 0.081572 0.879017 0 - 55 O 0.879017 0.976289 0.797445 0 - 56 O 0.581572 0.178844 0.202555 0 - 57 O 0.120983 0.597271 0.918428 0 - 58 O 0.902729 0.023711 0.321156 0 - 59 O 0.476289 0.379017 0.297445 0 - 60 O 0.321156 0.918428 0.297445 0 - 61 O 0.379017 0.297445 0.476289 0 - 62 O 0.379017 0.581572 0.902729 0 - 63 O 0.297445 0.476289 0.379017 0 - 64 O 0.120983 0.023711 0.202555 0 - 65 O 0.597271 0.918428 0.120983 0 - 66 O 0.202555 0.581572 0.178844 0 - 67 O 0.178844 0.202555 0.581572 0 - 68 O 0.321156 0.902729 0.023711 0 - 69 O 0.023711 0.321156 0.902729 0 - 70 O 0.918428 0.120983 0.597271 0 - 71 O 0.476289 0.597271 0.178844 0 - 72 O 0.902729 0.379017 0.581572 0 - 73 O 0.918428 0.297445 0.321156 0 - 74 O 0.597271 0.178844 0.476289 0 - 75 O 0.581572 0.902729 0.379017 0 - 76 O 0.297445 0.321156 0.918428 0 - 77 O 0.202555 0.120983 0.023711 0 - 78 O 0.023711 0.202555 0.120983 0 - 79 O 0.821156 0.797445 0.418428 0","# generated using pymatgen -data_Lu3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.36222952 -_cell_length_b 10.36222952 -_cell_length_c 10.36222952 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Lu3Al5O12 -_chemical_formula_sum 'Lu12 Al20 O48' -_cell_volume 856.52043967 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Lu Lu0 1 0.37500000 0.12500000 0.25000000 1 - Lu Lu1 1 0.75000000 0.12500000 0.37500000 1 - Lu Lu2 1 0.25000000 0.37500000 0.12500000 1 - Lu Lu3 1 0.12500000 0.25000000 0.37500000 1 - Lu Lu4 1 0.37500000 0.75000000 0.12500000 1 - Lu Lu5 1 0.12500000 0.37500000 0.75000000 1 - Lu Lu6 1 0.62500000 0.87500000 0.75000000 1 - Lu Lu7 1 0.25000000 0.87500000 0.62500000 1 - Lu Lu8 1 0.75000000 0.62500000 0.87500000 1 - Lu Lu9 1 0.87500000 0.75000000 0.62500000 1 - Lu Lu10 1 0.62500000 0.25000000 0.87500000 1 - Lu Lu11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.00000000 0.00000000 0.00000000 1 - Al Al13 1 0.50000000 0.00000000 0.00000000 1 - Al Al14 1 0.00000000 0.50000000 0.00000000 1 - Al Al15 1 0.00000000 0.00000000 0.50000000 1 - Al Al16 1 0.50000000 0.50000000 0.00000000 1 - Al Al17 1 0.00000000 0.50000000 0.50000000 1 - Al Al18 1 0.50000000 0.00000000 0.50000000 1 - Al Al19 1 0.50000000 0.50000000 0.50000000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.75000000 0.37500000 0.62500000 1 - Al Al22 1 0.25000000 0.12500000 0.87500000 1 - Al Al23 1 0.87500000 0.25000000 0.12500000 1 - Al Al24 1 0.12500000 0.87500000 0.25000000 1 - Al Al25 1 0.87500000 0.12500000 0.75000000 1 - Al Al26 1 0.25000000 0.62500000 0.37500000 1 - Al Al27 1 0.37500000 0.25000000 0.62500000 1 - Al Al28 1 0.75000000 0.87500000 0.12500000 1 - Al Al29 1 0.12500000 0.75000000 0.87500000 1 - Al Al30 1 0.37500000 0.62500000 0.75000000 1 - Al Al31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.41842800 0.82115600 0.79744500 1 - O O33 1 0.87901700 0.40272900 0.08157200 1 - O O34 1 0.09727100 0.97628900 0.67884400 1 - O O35 1 0.52371100 0.62098300 0.70255500 1 - O O36 1 0.67884400 0.08157200 0.70255500 1 - O O37 1 0.62098300 0.70255500 0.52371100 1 - O O38 1 0.62098300 0.41842800 0.09727100 1 - O O39 1 0.70255500 0.52371100 0.62098300 1 - O O40 1 0.82115600 0.52371100 0.40272900 1 - O O41 1 0.97628900 0.79744500 0.87901700 1 - O O42 1 0.79744500 0.87901700 0.97628900 1 - O O43 1 0.70255500 0.67884400 0.08157200 1 - O O44 1 0.41842800 0.09727100 0.62098300 1 - O O45 1 0.40272900 0.82115600 0.52371100 1 - O O46 1 0.08157200 0.70255500 0.67884400 1 - O O47 1 0.09727100 0.62098300 0.41842800 1 - O O48 1 0.52371100 0.40272900 0.82115600 1 - O O49 1 0.08157200 0.87901700 0.40272900 1 - O O50 1 0.97628900 0.67884400 0.09727100 1 - O O51 1 0.17884400 0.47628900 0.59727100 1 - O O52 1 0.67884400 0.09727100 0.97628900 1 - O O53 1 0.79744500 0.41842800 0.82115600 1 - O O54 1 0.40272900 0.08157200 0.87901700 1 - O O55 1 0.87901700 0.97628900 0.79744500 1 - O O56 1 0.58157200 0.17884400 0.20255500 1 - O O57 1 0.12098300 0.59727100 0.91842800 1 - O O58 1 0.90272900 0.02371100 0.32115600 1 - O O59 1 0.47628900 0.37901700 0.29744500 1 - O O60 1 0.32115600 0.91842800 0.29744500 1 - O O61 1 0.37901700 0.29744500 0.47628900 1 - O O62 1 0.37901700 0.58157200 0.90272900 1 - O O63 1 0.29744500 0.47628900 0.37901700 1 - O O64 1 0.12098300 0.02371100 0.20255500 1 - O O65 1 0.59727100 0.91842800 0.12098300 1 - O O66 1 0.20255500 0.58157200 0.17884400 1 - O O67 1 0.17884400 0.20255500 0.58157200 1 - O O68 1 0.32115600 0.90272900 0.02371100 1 - O O69 1 0.02371100 0.32115600 0.90272900 1 - O O70 1 0.91842800 0.12098300 0.59727100 1 - O O71 1 0.47628900 0.59727100 0.17884400 1 - O O72 1 0.90272900 0.37901700 0.58157200 1 - O O73 1 0.91842800 0.29744500 0.32115600 1 - O O74 1 0.59727100 0.17884400 0.47628900 1 - O O75 1 0.58157200 0.90272900 0.37901700 1 - O O76 1 0.29744500 0.32115600 0.91842800 1 - O O77 1 0.20255500 0.12098300 0.02371100 1 - O O78 1 0.02371100 0.20255500 0.12098300 1 - O O79 1 0.82115600 0.79744500 0.41842800 1 -" -Lu3Fe5O12,mp-559750,Ia-3d,[23853],0.06029020821875086,{'tags': ['Pentairon(III) trilutetium oxide']},"Full Formula (Lu12 Fe20 O48) -Reduced Formula: Lu3Fe5O12 -abc : 10.736954 10.736954 10.736954 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Lu 0.25 0.375 0.125 0.043 - 1 Lu 0.875 0.625 0.25 0.043 - 2 Lu 0.375 0.125 0.25 0.043 - 3 Lu 0.75 0.625 0.875 0.043 - 4 Lu 0.125 0.375 0.75 0.043 - 5 Lu 0.875 0.75 0.625 0.043 - 6 Lu 0.25 0.875 0.625 0.043 - 7 Lu 0.75 0.125 0.375 0.043 - 8 Lu 0.375 0.75 0.125 0.043 - 9 Lu 0.625 0.875 0.75 0.043 - 10 Lu 0.125 0.25 0.375 0.043 - 11 Lu 0.625 0.25 0.875 0.043 - 12 Fe 0 0.5 0.5 4.401 - 13 Fe 0.25 0.125 0.875 4.275 - 14 Fe 0.375 0.625 0.75 4.275 - 15 Fe 0.5 0.5 0.5 4.398 - 16 Fe 0 0 0 4.398 - 17 Fe 0.25 0.625 0.375 4.275 - 18 Fe 0.5 0 0 4.401 - 19 Fe 0.5 0.5 0 4.398 - 20 Fe 0.625 0.75 0.375 4.275 - 21 Fe 0 0 0.5 4.401 - 22 Fe 0.125 0.75 0.875 4.275 - 23 Fe 0.75 0.375 0.625 4.275 - 24 Fe 0.75 0.875 0.125 4.275 - 25 Fe 0.375 0.25 0.625 4.275 - 26 Fe 0.875 0.125 0.75 4.275 - 27 Fe 0.5 0 0.5 4.401 - 28 Fe 0.125 0.875 0.25 4.275 - 29 Fe 0.875 0.25 0.125 4.275 - 30 Fe 0 0.5 0 4.398 - 31 Fe 0.625 0.375 0.25 4.275 - 32 O 0.464761 0.592467 0.176401 0.218 - 33 O 0.964761 0.676401 0.092467 0.218 - 34 O 0.407533 0.083934 0.872294 0.218 - 35 O 0.035239 0.21164 0.127706 0.218 - 36 O 0.407533 0.823599 0.535239 0.218 - 37 O 0.127706 0.592467 0.916066 0.219 - 38 O 0.083934 0.71164 0.676401 0.218 - 39 O 0.092467 0.964761 0.676401 0.218 - 40 O 0.676401 0.092467 0.964761 0.218 - 41 O 0.823599 0.535239 0.407533 0.218 - 42 O 0.464761 0.372294 0.28836 0.218 - 43 O 0.71164 0.535239 0.627706 0.218 - 44 O 0.28836 0.464761 0.372294 0.218 - 45 O 0.535239 0.627706 0.71164 0.218 - 46 O 0.28836 0.323599 0.916066 0.218 - 47 O 0.416066 0.823599 0.78836 0.218 - 48 O 0.823599 0.78836 0.416066 0.218 - 49 O 0.964761 0.78836 0.872294 0.218 - 50 O 0.092467 0.627706 0.416066 0.218 - 51 O 0.323599 0.916066 0.28836 0.218 - 52 O 0.21164 0.127706 0.035239 0.218 - 53 O 0.083934 0.872294 0.407533 0.218 - 54 O 0.176401 0.464761 0.592467 0.218 - 55 O 0.872294 0.407533 0.083934 0.219 - 56 O 0.127706 0.035239 0.21164 0.219 - 57 O 0.916066 0.28836 0.323599 0.218 - 58 O 0.176401 0.21164 0.583934 0.218 - 59 O 0.416066 0.092467 0.627706 0.218 - 60 O 0.372294 0.28836 0.464761 0.219 - 61 O 0.872294 0.964761 0.78836 0.219 - 62 O 0.592467 0.916066 0.127706 0.218 - 63 O 0.627706 0.71164 0.535239 0.219 - 64 O 0.78836 0.416066 0.823599 0.218 - 65 O 0.592467 0.176401 0.464761 0.218 - 66 O 0.907533 0.372294 0.583934 0.218 - 67 O 0.535239 0.407533 0.823599 0.218 - 68 O 0.372294 0.583934 0.907533 0.219 - 69 O 0.583934 0.907533 0.372294 0.218 - 70 O 0.035239 0.323599 0.907533 0.218 - 71 O 0.627706 0.416066 0.092467 0.219 - 72 O 0.676401 0.083934 0.71164 0.218 - 73 O 0.78836 0.872294 0.964761 0.218 - 74 O 0.21164 0.583934 0.176401 0.218 - 75 O 0.583934 0.176401 0.21164 0.218 - 76 O 0.916066 0.127706 0.592467 0.218 - 77 O 0.71164 0.676401 0.083934 0.218 - 78 O 0.323599 0.907533 0.035239 0.218 - 79 O 0.907533 0.035239 0.323599 0.218","# generated using pymatgen -data_Lu3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.73695351 -_cell_length_b 10.73695351 -_cell_length_c 10.73695351 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Lu3Fe5O12 -_chemical_formula_sum 'Lu12 Fe20 O48' -_cell_volume 952.84295519 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Lu Lu0 1 0.25000000 0.37500000 0.12500000 1 - Lu Lu1 1 0.87500000 0.62500000 0.25000000 1 - Lu Lu2 1 0.37500000 0.12500000 0.25000000 1 - Lu Lu3 1 0.75000000 0.62500000 0.87500000 1 - Lu Lu4 1 0.12500000 0.37500000 0.75000000 1 - Lu Lu5 1 0.87500000 0.75000000 0.62500000 1 - Lu Lu6 1 0.25000000 0.87500000 0.62500000 1 - Lu Lu7 1 0.75000000 0.12500000 0.37500000 1 - Lu Lu8 1 0.37500000 0.75000000 0.12500000 1 - Lu Lu9 1 0.62500000 0.87500000 0.75000000 1 - Lu Lu10 1 0.12500000 0.25000000 0.37500000 1 - Lu Lu11 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe12 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe13 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe14 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe17 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe21 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe22 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe23 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe24 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe25 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe26 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe27 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe28 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe29 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe30 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.46476100 0.59246700 0.17640100 1 - O O33 1 0.96476100 0.67640100 0.09246700 1 - O O34 1 0.40753300 0.08393400 0.87229400 1 - O O35 1 0.03523900 0.21164000 0.12770600 1 - O O36 1 0.40753300 0.82359900 0.53523900 1 - O O37 1 0.12770600 0.59246700 0.91606600 1 - O O38 1 0.08393400 0.71164000 0.67640100 1 - O O39 1 0.09246700 0.96476100 0.67640100 1 - O O40 1 0.67640100 0.09246700 0.96476100 1 - O O41 1 0.82359900 0.53523900 0.40753300 1 - O O42 1 0.46476100 0.37229400 0.28836000 1 - O O43 1 0.71164000 0.53523900 0.62770600 1 - O O44 1 0.28836000 0.46476100 0.37229400 1 - O O45 1 0.53523900 0.62770600 0.71164000 1 - O O46 1 0.28836000 0.32359900 0.91606600 1 - O O47 1 0.41606600 0.82359900 0.78836000 1 - O O48 1 0.82359900 0.78836000 0.41606600 1 - O O49 1 0.96476100 0.78836000 0.87229400 1 - O O50 1 0.09246700 0.62770600 0.41606600 1 - O O51 1 0.32359900 0.91606600 0.28836000 1 - O O52 1 0.21164000 0.12770600 0.03523900 1 - O O53 1 0.08393400 0.87229400 0.40753300 1 - O O54 1 0.17640100 0.46476100 0.59246700 1 - O O55 1 0.87229400 0.40753300 0.08393400 1 - O O56 1 0.12770600 0.03523900 0.21164000 1 - O O57 1 0.91606600 0.28836000 0.32359900 1 - O O58 1 0.17640100 0.21164000 0.58393400 1 - O O59 1 0.41606600 0.09246700 0.62770600 1 - O O60 1 0.37229400 0.28836000 0.46476100 1 - O O61 1 0.87229400 0.96476100 0.78836000 1 - O O62 1 0.59246700 0.91606600 0.12770600 1 - O O63 1 0.62770600 0.71164000 0.53523900 1 - O O64 1 0.78836000 0.41606600 0.82359900 1 - O O65 1 0.59246700 0.17640100 0.46476100 1 - O O66 1 0.90753300 0.37229400 0.58393400 1 - O O67 1 0.53523900 0.40753300 0.82359900 1 - O O68 1 0.37229400 0.58393400 0.90753300 1 - O O69 1 0.58393400 0.90753300 0.37229400 1 - O O70 1 0.03523900 0.32359900 0.90753300 1 - O O71 1 0.62770600 0.41606600 0.09246700 1 - O O72 1 0.67640100 0.08393400 0.71164000 1 - O O73 1 0.78836000 0.87229400 0.96476100 1 - O O74 1 0.21164000 0.58393400 0.17640100 1 - O O75 1 0.58393400 0.17640100 0.21164000 1 - O O76 1 0.91606600 0.12770600 0.59246700 1 - O O77 1 0.71164000 0.67640100 0.08393400 1 - O O78 1 0.32359900 0.90753300 0.03523900 1 - O O79 1 0.90753300 0.03523900 0.32359900 1 -" -Lu3Ga5O12,mp-14134,Ia-3d,[23850],0.0,{'tags': ['Pentagallium trilutetium oxide']},"Full Formula (Lu12 Ga20 O48) -Reduced Formula: Lu3Ga5O12 -abc : 10.623861 10.623861 10.623861 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Lu 0.375 0.125 0.25 0 - 1 Lu 0.75 0.125 0.375 0 - 2 Lu 0.25 0.375 0.125 0 - 3 Lu 0.125 0.25 0.375 0 - 4 Lu 0.375 0.75 0.125 0 - 5 Lu 0.125 0.375 0.75 0 - 6 Lu 0.625 0.875 0.75 0 - 7 Lu 0.25 0.875 0.625 0 - 8 Lu 0.75 0.625 0.875 0 - 9 Lu 0.875 0.75 0.625 0 - 10 Lu 0.625 0.25 0.875 0 - 11 Lu 0.875 0.625 0.25 0 - 12 Ga 0 0 0 0 - 13 Ga 0.5 0 0 0 - 14 Ga 0 0.5 0 0 - 15 Ga 0 0 0.5 0 - 16 Ga 0.5 0.5 0 0 - 17 Ga 0 0.5 0.5 0 - 18 Ga 0.5 0 0.5 0 - 19 Ga 0.5 0.5 0.5 0 - 20 Ga 0.625 0.375 0.25 0 - 21 Ga 0.75 0.375 0.625 0 - 22 Ga 0.25 0.125 0.875 0 - 23 Ga 0.875 0.25 0.125 0 - 24 Ga 0.125 0.875 0.25 0 - 25 Ga 0.875 0.125 0.75 0 - 26 Ga 0.25 0.625 0.375 0 - 27 Ga 0.375 0.25 0.625 0 - 28 Ga 0.75 0.875 0.125 0 - 29 Ga 0.125 0.75 0.875 0 - 30 Ga 0.375 0.625 0.75 0 - 31 Ga 0.625 0.75 0.375 0 - 32 O 0.416787 0.823178 0.790931 -0 - 33 O 0.874145 0.406391 0.083214 -0 - 34 O 0.093609 0.967754 0.676822 -0 - 35 O 0.532246 0.625855 0.709069 -0 - 36 O 0.676822 0.083213 0.709069 -0 - 37 O 0.625855 0.709069 0.532246 -0 - 38 O 0.625855 0.416786 0.093609 -0 - 39 O 0.709069 0.532246 0.625855 -0 - 40 O 0.823178 0.532246 0.406391 -0 - 41 O 0.967754 0.790931 0.874145 -0 - 42 O 0.790931 0.874145 0.967754 -0 - 43 O 0.709069 0.676822 0.083213 -0 - 44 O 0.416786 0.093609 0.625855 -0 - 45 O 0.406391 0.823178 0.532246 -0 - 46 O 0.083214 0.709069 0.676822 -0 - 47 O 0.093609 0.625855 0.416786 -0 - 48 O 0.532246 0.406391 0.823178 -0 - 49 O 0.083214 0.874145 0.406391 -0 - 50 O 0.967754 0.676822 0.093609 -0 - 51 O 0.176822 0.467754 0.593609 -0 - 52 O 0.676822 0.093609 0.967754 -0 - 53 O 0.790931 0.416786 0.823178 -0 - 54 O 0.406391 0.083213 0.874145 -0 - 55 O 0.874145 0.967754 0.790931 -0 - 56 O 0.583214 0.176822 0.209069 -0 - 57 O 0.125855 0.593609 0.916787 -0 - 58 O 0.906391 0.032246 0.323178 -0 - 59 O 0.467754 0.374145 0.290931 -0 - 60 O 0.323178 0.916786 0.290931 -0 - 61 O 0.374145 0.290931 0.467754 -0 - 62 O 0.374145 0.583213 0.906391 -0 - 63 O 0.290931 0.467754 0.374145 -0 - 64 O 0.125855 0.032246 0.209069 -0 - 65 O 0.593609 0.916786 0.125855 -0 - 66 O 0.209069 0.583214 0.176822 -0 - 67 O 0.176822 0.209069 0.583214 -0 - 68 O 0.323178 0.906391 0.032246 -0 - 69 O 0.032246 0.323178 0.906391 -0 - 70 O 0.916786 0.125855 0.593609 -0 - 71 O 0.467754 0.593609 0.176822 -0 - 72 O 0.906391 0.374145 0.583214 -0 - 73 O 0.916786 0.290931 0.323178 -0 - 74 O 0.593609 0.176822 0.467754 -0 - 75 O 0.583214 0.906391 0.374145 -0 - 76 O 0.290931 0.323178 0.916786 -0 - 77 O 0.209069 0.125855 0.032246 -0 - 78 O 0.032246 0.209069 0.125855 -0 - 79 O 0.823178 0.790931 0.416787 -0","# generated using pymatgen -data_Lu3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.62386099 -_cell_length_b 10.62386099 -_cell_length_c 10.62386099 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Lu3Ga5O12 -_chemical_formula_sum 'Lu12 Ga20 O48' -_cell_volume 923.05004347 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Lu Lu0 1 0.37500000 0.12500000 0.25000000 1 - Lu Lu1 1 0.75000000 0.12500000 0.37500000 1 - Lu Lu2 1 0.25000000 0.37500000 0.12500000 1 - Lu Lu3 1 0.12500000 0.25000000 0.37500000 1 - Lu Lu4 1 0.37500000 0.75000000 0.12500000 1 - Lu Lu5 1 0.12500000 0.37500000 0.75000000 1 - Lu Lu6 1 0.62500000 0.87500000 0.75000000 1 - Lu Lu7 1 0.25000000 0.87500000 0.62500000 1 - Lu Lu8 1 0.75000000 0.62500000 0.87500000 1 - Lu Lu9 1 0.87500000 0.75000000 0.62500000 1 - Lu Lu10 1 0.62500000 0.25000000 0.87500000 1 - Lu Lu11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga13 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga14 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga15 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga16 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga17 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga18 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga19 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga22 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga23 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga24 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga25 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga26 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga27 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga28 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga29 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga30 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga31 1 0.62500000 0.75000000 0.37500000 1 - O O32 1 0.41678700 0.82317800 0.79093100 1 - O O33 1 0.87414500 0.40639100 0.08321400 1 - O O34 1 0.09360900 0.96775400 0.67682200 1 - O O35 1 0.53224600 0.62585500 0.70906900 1 - O O36 1 0.67682200 0.08321300 0.70906900 1 - O O37 1 0.62585500 0.70906900 0.53224600 1 - O O38 1 0.62585500 0.41678600 0.09360900 1 - O O39 1 0.70906900 0.53224600 0.62585500 1 - O O40 1 0.82317800 0.53224600 0.40639100 1 - O O41 1 0.96775400 0.79093100 0.87414500 1 - O O42 1 0.79093100 0.87414500 0.96775400 1 - O O43 1 0.70906900 0.67682200 0.08321300 1 - O O44 1 0.41678600 0.09360900 0.62585500 1 - O O45 1 0.40639100 0.82317800 0.53224600 1 - O O46 1 0.08321400 0.70906900 0.67682200 1 - O O47 1 0.09360900 0.62585500 0.41678600 1 - O O48 1 0.53224600 0.40639100 0.82317800 1 - O O49 1 0.08321400 0.87414500 0.40639100 1 - O O50 1 0.96775400 0.67682200 0.09360900 1 - O O51 1 0.17682200 0.46775400 0.59360900 1 - O O52 1 0.67682200 0.09360900 0.96775400 1 - O O53 1 0.79093100 0.41678600 0.82317800 1 - O O54 1 0.40639100 0.08321300 0.87414500 1 - O O55 1 0.87414500 0.96775400 0.79093100 1 - O O56 1 0.58321400 0.17682200 0.20906900 1 - O O57 1 0.12585500 0.59360900 0.91678700 1 - O O58 1 0.90639100 0.03224600 0.32317800 1 - O O59 1 0.46775400 0.37414500 0.29093100 1 - O O60 1 0.32317800 0.91678600 0.29093100 1 - O O61 1 0.37414500 0.29093100 0.46775400 1 - O O62 1 0.37414500 0.58321300 0.90639100 1 - O O63 1 0.29093100 0.46775400 0.37414500 1 - O O64 1 0.12585500 0.03224600 0.20906900 1 - O O65 1 0.59360900 0.91678600 0.12585500 1 - O O66 1 0.20906900 0.58321400 0.17682200 1 - O O67 1 0.17682200 0.20906900 0.58321400 1 - O O68 1 0.32317800 0.90639100 0.03224600 1 - O O69 1 0.03224600 0.32317800 0.90639100 1 - O O70 1 0.91678600 0.12585500 0.59360900 1 - O O71 1 0.46775400 0.59360900 0.17682200 1 - O O72 1 0.90639100 0.37414500 0.58321400 1 - O O73 1 0.91678600 0.29093100 0.32317800 1 - O O74 1 0.59360900 0.17682200 0.46775400 1 - O O75 1 0.58321400 0.90639100 0.37414500 1 - O O76 1 0.29093100 0.32317800 0.91678600 1 - O O77 1 0.20906900 0.12585500 0.03224600 1 - O O78 1 0.03224600 0.20906900 0.12585500 1 - O O79 1 0.82317800 0.79093100 0.41678700 1 -" -Nd3Fe5O12,mp-1201849,Ia-3d,"[422691, 260556]",0.012552430499999545,"{'tags': ['Trineodymium(III) pentairon(III) dodecaoxide', 'Y3Al5O12', 'Nd3Fe5O12', 'garnet family', 'Garnet', 'Pentairon trineodymium dodecaoxide']}","Full Formula (Nd12 Fe20 O48) -Reduced Formula: Nd3Fe5O12 -abc : 11.069000 11.069000 11.069000 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Nd 0.125 0.375 0.75 0.02 - 1 Nd 0.375 0.125 0.25 0.02 - 2 Nd 0.375 0.75 0.125 0.02 - 3 Nd 0.125 0.25 0.375 0.02 - 4 Nd 0.75 0.125 0.375 0.02 - 5 Nd 0.25 0.375 0.125 0.02 - 6 Nd 0.875 0.625 0.25 0.02 - 7 Nd 0.625 0.875 0.75 0.02 - 8 Nd 0.625 0.25 0.875 0.02 - 9 Nd 0.875 0.75 0.625 0.02 - 10 Nd 0.25 0.875 0.625 0.02 - 11 Nd 0.75 0.625 0.875 0.02 - 12 Fe 0 0.5 0 4.4 - 13 Fe 0 0 0.5 4.401 - 14 Fe 0.5 0 0 4.401 - 15 Fe 0.5 0.5 0.5 4.4 - 16 Fe 0.5 0.5 0 4.4 - 17 Fe 0.5 0 0.5 4.401 - 18 Fe 0 0.5 0.5 4.401 - 19 Fe 0 0 0 4.4 - 20 Fe 0.375 0.625 0.75 4.273 - 21 Fe 0.125 0.875 0.25 4.273 - 22 Fe 0.625 0.75 0.375 4.273 - 23 Fe 0.875 0.25 0.125 4.273 - 24 Fe 0.75 0.375 0.625 4.273 - 25 Fe 0.25 0.125 0.875 4.273 - 26 Fe 0.625 0.375 0.25 4.273 - 27 Fe 0.875 0.125 0.75 4.273 - 28 Fe 0.375 0.25 0.625 4.273 - 29 Fe 0.125 0.75 0.875 4.273 - 30 Fe 0.25 0.625 0.375 4.273 - 31 Fe 0.75 0.875 0.125 4.273 - 32 O 0.025967 0.322034 0.90479 0.217 - 33 O 0.917244 0.121177 0.59521 0.217 - 34 O 0.582756 0.177966 0.203933 0.217 - 35 O 0.474033 0.378823 0.296067 0.217 - 36 O 0.322034 0.90479 0.025967 0.217 - 37 O 0.121177 0.59521 0.917244 0.217 - 38 O 0.177966 0.203933 0.582756 0.217 - 39 O 0.378823 0.296067 0.474033 0.217 - 40 O 0.90479 0.025967 0.322034 0.217 - 41 O 0.59521 0.917244 0.121177 0.217 - 42 O 0.203933 0.582756 0.177966 0.217 - 43 O 0.296067 0.474033 0.378823 0.217 - 44 O 0.974033 0.677966 0.09521 0.217 - 45 O 0.082756 0.878823 0.40479 0.217 - 46 O 0.417244 0.822034 0.796067 0.217 - 47 O 0.525967 0.621177 0.703933 0.217 - 48 O 0.677966 0.09521 0.974033 0.217 - 49 O 0.878823 0.40479 0.082756 0.217 - 50 O 0.822034 0.796067 0.417244 0.217 - 51 O 0.621177 0.703933 0.525967 0.217 - 52 O 0.09521 0.974033 0.677966 0.217 - 53 O 0.40479 0.082756 0.878823 0.217 - 54 O 0.796067 0.417244 0.822034 0.217 - 55 O 0.703933 0.525967 0.621177 0.217 - 56 O 0.525967 0.40479 0.822034 0.217 - 57 O 0.417244 0.09521 0.621177 0.217 - 58 O 0.082756 0.703933 0.677966 0.217 - 59 O 0.974033 0.796067 0.878823 0.217 - 60 O 0.822034 0.525967 0.40479 0.217 - 61 O 0.621177 0.417244 0.09521 0.217 - 62 O 0.677966 0.082756 0.703933 0.217 - 63 O 0.878823 0.974033 0.796067 0.217 - 64 O 0.40479 0.822034 0.525967 0.217 - 65 O 0.09521 0.621177 0.417244 0.217 - 66 O 0.703933 0.677966 0.082756 0.217 - 67 O 0.796067 0.878823 0.974033 0.217 - 68 O 0.474033 0.59521 0.177966 0.217 - 69 O 0.582756 0.90479 0.378823 0.217 - 70 O 0.917244 0.296067 0.322034 0.217 - 71 O 0.025967 0.203933 0.121177 0.217 - 72 O 0.177966 0.474033 0.59521 0.217 - 73 O 0.378823 0.582756 0.90479 0.217 - 74 O 0.322034 0.917244 0.296067 0.217 - 75 O 0.121177 0.025967 0.203933 0.217 - 76 O 0.59521 0.177966 0.474033 0.217 - 77 O 0.90479 0.378823 0.582756 0.217 - 78 O 0.296067 0.322034 0.917244 0.217 - 79 O 0.203933 0.121177 0.025967 0.217","# generated using pymatgen -data_Nd3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.06899978 -_cell_length_b 11.06899978 -_cell_length_c 11.06899978 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Nd3Fe5O12 -_chemical_formula_sum 'Nd12 Fe20 O48' -_cell_volume 1044.00660230 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Nd Nd0 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd1 1 0.37500000 0.12500000 0.25000000 1 - Nd Nd2 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd3 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd4 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd5 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd6 1 0.87500000 0.62500000 0.25000000 1 - Nd Nd7 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd8 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd9 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd10 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd11 1 0.75000000 0.62500000 0.87500000 1 - Fe Fe12 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe13 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe18 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe20 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe21 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe22 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe23 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe24 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe25 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe26 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe27 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe28 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe29 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe30 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe31 1 0.75000000 0.87500000 0.12500000 1 - O O32 1 0.02596700 0.32203400 0.90479000 1 - O O33 1 0.91724400 0.12117700 0.59521000 1 - O O34 1 0.58275600 0.17796600 0.20393300 1 - O O35 1 0.47403300 0.37882300 0.29606700 1 - O O36 1 0.32203400 0.90479000 0.02596700 1 - O O37 1 0.12117700 0.59521000 0.91724400 1 - O O38 1 0.17796600 0.20393300 0.58275600 1 - O O39 1 0.37882300 0.29606700 0.47403300 1 - O O40 1 0.90479000 0.02596700 0.32203400 1 - O O41 1 0.59521000 0.91724400 0.12117700 1 - O O42 1 0.20393300 0.58275600 0.17796600 1 - O O43 1 0.29606700 0.47403300 0.37882300 1 - O O44 1 0.97403300 0.67796600 0.09521000 1 - O O45 1 0.08275600 0.87882300 0.40479000 1 - O O46 1 0.41724400 0.82203400 0.79606700 1 - O O47 1 0.52596700 0.62117700 0.70393300 1 - O O48 1 0.67796600 0.09521000 0.97403300 1 - O O49 1 0.87882300 0.40479000 0.08275600 1 - O O50 1 0.82203400 0.79606700 0.41724400 1 - O O51 1 0.62117700 0.70393300 0.52596700 1 - O O52 1 0.09521000 0.97403300 0.67796600 1 - O O53 1 0.40479000 0.08275600 0.87882300 1 - O O54 1 0.79606700 0.41724400 0.82203400 1 - O O55 1 0.70393300 0.52596700 0.62117700 1 - O O56 1 0.52596700 0.40479000 0.82203400 1 - O O57 1 0.41724400 0.09521000 0.62117700 1 - O O58 1 0.08275600 0.70393300 0.67796600 1 - O O59 1 0.97403300 0.79606700 0.87882300 1 - O O60 1 0.82203400 0.52596700 0.40479000 1 - O O61 1 0.62117700 0.41724400 0.09521000 1 - O O62 1 0.67796600 0.08275600 0.70393300 1 - O O63 1 0.87882300 0.97403300 0.79606700 1 - O O64 1 0.40479000 0.82203400 0.52596700 1 - O O65 1 0.09521000 0.62117700 0.41724400 1 - O O66 1 0.70393300 0.67796600 0.08275600 1 - O O67 1 0.79606700 0.87882300 0.97403300 1 - O O68 1 0.47403300 0.59521000 0.17796600 1 - O O69 1 0.58275600 0.90479000 0.37882300 1 - O O70 1 0.91724400 0.29606700 0.32203400 1 - O O71 1 0.02596700 0.20393300 0.12117700 1 - O O72 1 0.17796600 0.47403300 0.59521000 1 - O O73 1 0.37882300 0.58275600 0.90479000 1 - O O74 1 0.32203400 0.91724400 0.29606700 1 - O O75 1 0.12117700 0.02596700 0.20393300 1 - O O76 1 0.59521000 0.17796600 0.47403300 1 - O O77 1 0.90479000 0.37882300 0.58275600 1 - O O78 1 0.29606700 0.32203400 0.91724400 1 - O O79 1 0.20393300 0.12117700 0.02596700 1 -" -Nd3Ga5O12,mp-15239,Ia-3d,[84872],0.0,"{'tags': ['Trineodymium pentagallium oxide', 'Unnamed_Garnet']}","Full Formula (Nd12 Ga20 O48) -Reduced Formula: Nd3Ga5O12 -abc : 10.961136 10.961136 10.961136 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Nd 0.875 0.625 0.25 -0 - 1 Nd 0.625 0.25 0.875 -0 - 2 Nd 0.875 0.75 0.625 -0 - 3 Nd 0.75 0.625 0.875 -0 - 4 Nd 0.25 0.875 0.625 -0 - 5 Nd 0.625 0.875 0.75 -0 - 6 Nd 0.125 0.375 0.75 -0 - 7 Nd 0.375 0.75 0.125 -0 - 8 Nd 0.125 0.25 0.375 -0 - 9 Nd 0.25 0.375 0.125 -0 - 10 Nd 0.75 0.125 0.375 -0 - 11 Nd 0.375 0.125 0.25 -0 - 12 Ga 0.125 0.875 0.25 0 - 13 Ga 0.875 0.125 0.75 0 - 14 Ga 0.25 0.625 0.375 0 - 15 Ga 0.375 0.25 0.625 0 - 16 Ga 0.75 0.875 0.125 0 - 17 Ga 0.125 0.75 0.875 0 - 18 Ga 0.375 0.625 0.75 0 - 19 Ga 0.625 0.75 0.375 0 - 20 Ga 0.875 0.25 0.125 0 - 21 Ga 0.25 0.125 0.875 0 - 22 Ga 0.75 0.375 0.625 0 - 23 Ga 0.625 0.375 0.25 0 - 24 Ga 0.5 0.5 0.5 0 - 25 Ga 0.5 0 0.5 0 - 26 Ga 0 0.5 0.5 0 - 27 Ga 0.5 0.5 0 0 - 28 Ga 0 0 0.5 0 - 29 Ga 0 0.5 0 0 - 30 Ga 0.5 0 0 0 - 31 Ga 0 0 0 0 - 32 O 0.477016 0.380523 0.298564 -0 - 33 O 0.321548 0.903506 0.022984 -0 - 34 O 0.596494 0.918042 0.119477 -0 - 35 O 0.581958 0.178452 0.201436 -0 - 36 O 0.119477 0.022984 0.201436 -0 - 37 O 0.178452 0.201436 0.581958 -0 - 38 O 0.178452 0.477016 0.596494 -0 - 39 O 0.201436 0.581958 0.178452 -0 - 40 O 0.380523 0.581958 0.903506 -0 - 41 O 0.918042 0.298564 0.321548 -0 - 42 O 0.298564 0.321548 0.918042 -0 - 43 O 0.201436 0.119477 0.022984 -0 - 44 O 0.477016 0.596494 0.178452 -0 - 45 O 0.903506 0.380523 0.581958 -0 - 46 O 0.022984 0.201436 0.119477 -0 - 47 O 0.596494 0.178452 0.477016 0 - 48 O 0.581958 0.903506 0.380523 -0 - 49 O 0.022984 0.321548 0.903506 -0 - 50 O 0.918042 0.119477 0.596494 -0 - 51 O 0.619477 0.418042 0.096494 0 - 52 O 0.119477 0.596494 0.918042 -0 - 53 O 0.298564 0.477016 0.380523 -0 - 54 O 0.903506 0.022984 0.321548 -0 - 55 O 0.321548 0.918042 0.298564 -0 - 56 O 0.522984 0.619477 0.701436 -0 - 57 O 0.678452 0.096494 0.977016 -0 - 58 O 0.403506 0.081958 0.880523 -0 - 59 O 0.418042 0.821548 0.798564 -0 - 60 O 0.880523 0.977016 0.798564 -0 - 61 O 0.821548 0.798564 0.418042 0 - 62 O 0.821548 0.522984 0.403506 -0 - 63 O 0.798564 0.418042 0.821548 -0 - 64 O 0.678452 0.081958 0.701436 -0 - 65 O 0.096494 0.977016 0.678452 -0 - 66 O 0.701436 0.522984 0.619477 -0 - 67 O 0.619477 0.701436 0.522984 -0 - 68 O 0.880523 0.403506 0.081958 -0 - 69 O 0.081958 0.880523 0.403506 -0 - 70 O 0.977016 0.678452 0.096494 -0 - 71 O 0.418042 0.096494 0.619477 0 - 72 O 0.403506 0.821548 0.522984 0 - 73 O 0.977016 0.798564 0.880523 -0 - 74 O 0.096494 0.619477 0.418042 -0 - 75 O 0.522984 0.403506 0.821548 -0 - 76 O 0.798564 0.880523 0.977016 -0 - 77 O 0.701436 0.678452 0.081958 -0 - 78 O 0.081958 0.701436 0.678452 0 - 79 O 0.380523 0.298564 0.477016 -0","# generated using pymatgen -data_Nd3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.96113631 -_cell_length_b 10.96113631 -_cell_length_c 10.96113631 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Nd3Ga5O12 -_chemical_formula_sum 'Nd12 Ga20 O48' -_cell_volume 1013.78262833 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Nd Nd0 1 0.87500000 0.62500000 0.25000000 1 - Nd Nd1 1 0.62500000 0.25000000 0.87500000 1 - Nd Nd2 1 0.87500000 0.75000000 0.62500000 1 - Nd Nd3 1 0.75000000 0.62500000 0.87500000 1 - Nd Nd4 1 0.25000000 0.87500000 0.62500000 1 - Nd Nd5 1 0.62500000 0.87500000 0.75000000 1 - Nd Nd6 1 0.12500000 0.37500000 0.75000000 1 - Nd Nd7 1 0.37500000 0.75000000 0.12500000 1 - Nd Nd8 1 0.12500000 0.25000000 0.37500000 1 - Nd Nd9 1 0.25000000 0.37500000 0.12500000 1 - Nd Nd10 1 0.75000000 0.12500000 0.37500000 1 - Nd Nd11 1 0.37500000 0.12500000 0.25000000 1 - Ga Ga12 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga13 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga14 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga17 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga18 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga19 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga20 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga21 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga22 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga23 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga24 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga25 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga26 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga28 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga29 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga30 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.47701600 0.38052300 0.29856400 1 - O O33 1 0.32154800 0.90350600 0.02298400 1 - O O34 1 0.59649400 0.91804200 0.11947700 1 - O O35 1 0.58195800 0.17845200 0.20143600 1 - O O36 1 0.11947700 0.02298400 0.20143600 1 - O O37 1 0.17845200 0.20143600 0.58195800 1 - O O38 1 0.17845200 0.47701600 0.59649400 1 - O O39 1 0.20143600 0.58195800 0.17845200 1 - O O40 1 0.38052300 0.58195800 0.90350600 1 - O O41 1 0.91804200 0.29856400 0.32154800 1 - O O42 1 0.29856400 0.32154800 0.91804200 1 - O O43 1 0.20143600 0.11947700 0.02298400 1 - O O44 1 0.47701600 0.59649400 0.17845200 1 - O O45 1 0.90350600 0.38052300 0.58195800 1 - O O46 1 0.02298400 0.20143600 0.11947700 1 - O O47 1 0.59649400 0.17845200 0.47701600 1 - O O48 1 0.58195800 0.90350600 0.38052300 1 - O O49 1 0.02298400 0.32154800 0.90350600 1 - O O50 1 0.91804200 0.11947700 0.59649400 1 - O O51 1 0.61947700 0.41804200 0.09649400 1 - O O52 1 0.11947700 0.59649400 0.91804200 1 - O O53 1 0.29856400 0.47701600 0.38052300 1 - O O54 1 0.90350600 0.02298400 0.32154800 1 - O O55 1 0.32154800 0.91804200 0.29856400 1 - O O56 1 0.52298400 0.61947700 0.70143600 1 - O O57 1 0.67845200 0.09649400 0.97701600 1 - O O58 1 0.40350600 0.08195800 0.88052300 1 - O O59 1 0.41804200 0.82154800 0.79856400 1 - O O60 1 0.88052300 0.97701600 0.79856400 1 - O O61 1 0.82154800 0.79856400 0.41804200 1 - O O62 1 0.82154800 0.52298400 0.40350600 1 - O O63 1 0.79856400 0.41804200 0.82154800 1 - O O64 1 0.67845200 0.08195800 0.70143600 1 - O O65 1 0.09649400 0.97701600 0.67845200 1 - O O66 1 0.70143600 0.52298400 0.61947700 1 - O O67 1 0.61947700 0.70143600 0.52298400 1 - O O68 1 0.88052300 0.40350600 0.08195800 1 - O O69 1 0.08195800 0.88052300 0.40350600 1 - O O70 1 0.97701600 0.67845200 0.09649400 1 - O O71 1 0.41804200 0.09649400 0.61947700 1 - O O72 1 0.40350600 0.82154800 0.52298400 1 - O O73 1 0.97701600 0.79856400 0.88052300 1 - O O74 1 0.09649400 0.61947700 0.41804200 1 - O O75 1 0.52298400 0.40350600 0.82154800 1 - O O76 1 0.79856400 0.88052300 0.97701600 1 - O O77 1 0.70143600 0.67845200 0.08195800 1 - O O78 1 0.08195800 0.70143600 0.67845200 1 - O O79 1 0.38052300 0.29856400 0.47701600 1 -" -Pr3Fe5O12,mp-1197438,Ia-3d,"[248013, 422690]",0.015331011500000713,"{'tags': ['Y3Al5O12', 'garnet family', 'Tripraseodymium pentairon(III) dodecaoxide', 'Garnet', 'Pr3Fe5O12', 'Pentairon tripraseodymium dodecaoxide']}","Full Formula (Pr12 Fe20 O48) -Reduced Formula: Pr3Fe5O12 -abc : 11.097620 11.097620 11.097620 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Pr 0.875 0.625 0.25 0.02 - 1 Pr 0.625 0.875 0.75 0.02 - 2 Pr 0.625 0.25 0.875 0.02 - 3 Pr 0.875 0.75 0.625 0.02 - 4 Pr 0.25 0.875 0.625 0.019 - 5 Pr 0.75 0.625 0.875 0.02 - 6 Pr 0.125 0.375 0.75 0.02 - 7 Pr 0.375 0.125 0.25 0.02 - 8 Pr 0.375 0.75 0.125 0.02 - 9 Pr 0.125 0.25 0.375 0.02 - 10 Pr 0.75 0.125 0.375 0.019 - 11 Pr 0.25 0.375 0.125 0.02 - 12 Fe 0 0.5 0 4.399 - 13 Fe 0 0 0.5 4.4 - 14 Fe 0.5 0 0 4.4 - 15 Fe 0.5 0.5 0.5 4.399 - 16 Fe 0.5 0.5 0 4.399 - 17 Fe 0.5 0 0.5 4.4 - 18 Fe 0 0.5 0.5 4.4 - 19 Fe 0 0 0 4.399 - 20 Fe 0.875 0.125 0.75 4.271 - 21 Fe 0.625 0.375 0.25 4.271 - 22 Fe 0.125 0.75 0.875 4.271 - 23 Fe 0.375 0.25 0.625 4.271 - 24 Fe 0.75 0.875 0.125 4.272 - 25 Fe 0.25 0.625 0.375 4.272 - 26 Fe 0.125 0.875 0.25 4.271 - 27 Fe 0.375 0.625 0.75 4.271 - 28 Fe 0.875 0.25 0.125 4.271 - 29 Fe 0.625 0.75 0.375 4.271 - 30 Fe 0.25 0.125 0.875 4.272 - 31 Fe 0.75 0.375 0.625 4.272 - 32 O 0.02511 0.321533 0.904978 0.217 - 33 O 0.916555 0.120132 0.595022 0.217 - 34 O 0.583445 0.178467 0.203577 0.217 - 35 O 0.47489 0.379868 0.296423 0.217 - 36 O 0.321533 0.904978 0.02511 0.217 - 37 O 0.120132 0.595022 0.916555 0.218 - 38 O 0.178467 0.203577 0.583445 0.217 - 39 O 0.379868 0.296423 0.47489 0.218 - 40 O 0.904978 0.02511 0.321533 0.218 - 41 O 0.595022 0.916555 0.120132 0.218 - 42 O 0.203577 0.583445 0.178467 0.217 - 43 O 0.296423 0.47489 0.379868 0.217 - 44 O 0.97489 0.678467 0.095022 0.217 - 45 O 0.083445 0.879868 0.404978 0.217 - 46 O 0.416555 0.821533 0.796423 0.217 - 47 O 0.52511 0.620132 0.703577 0.217 - 48 O 0.678467 0.095022 0.97489 0.217 - 49 O 0.879868 0.404978 0.083445 0.218 - 50 O 0.821533 0.796423 0.416555 0.217 - 51 O 0.620132 0.703577 0.52511 0.218 - 52 O 0.095022 0.97489 0.678467 0.218 - 53 O 0.404978 0.083445 0.879868 0.218 - 54 O 0.796423 0.416555 0.821533 0.217 - 55 O 0.703577 0.52511 0.620132 0.217 - 56 O 0.52511 0.404978 0.821533 0.217 - 57 O 0.416555 0.095022 0.620132 0.217 - 58 O 0.083445 0.703577 0.678467 0.217 - 59 O 0.97489 0.796423 0.879868 0.217 - 60 O 0.821533 0.52511 0.404978 0.217 - 61 O 0.620132 0.416555 0.095022 0.218 - 62 O 0.678467 0.083445 0.703577 0.217 - 63 O 0.879868 0.97489 0.796423 0.218 - 64 O 0.404978 0.821533 0.52511 0.218 - 65 O 0.095022 0.620132 0.416555 0.218 - 66 O 0.703577 0.678467 0.083445 0.217 - 67 O 0.796423 0.879868 0.97489 0.217 - 68 O 0.47489 0.595022 0.178467 0.217 - 69 O 0.583445 0.904978 0.379868 0.217 - 70 O 0.916555 0.296423 0.321533 0.217 - 71 O 0.02511 0.203577 0.120132 0.217 - 72 O 0.178467 0.47489 0.595022 0.217 - 73 O 0.379868 0.583445 0.904978 0.218 - 74 O 0.321533 0.916555 0.296423 0.217 - 75 O 0.120132 0.02511 0.203577 0.218 - 76 O 0.595022 0.178467 0.47489 0.218 - 77 O 0.904978 0.379868 0.583445 0.218 - 78 O 0.296423 0.321533 0.916555 0.217 - 79 O 0.203577 0.120132 0.02511 0.217","# generated using pymatgen -data_Pr3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.09762018 -_cell_length_b 11.09762018 -_cell_length_c 11.09762018 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Pr3Fe5O12 -_chemical_formula_sum 'Pr12 Fe20 O48' -_cell_volume 1052.12582359 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Pr Pr0 1 0.87500000 0.62500000 0.25000000 1 - Pr Pr1 1 0.62500000 0.87500000 0.75000000 1 - Pr Pr2 1 0.62500000 0.25000000 0.87500000 1 - Pr Pr3 1 0.87500000 0.75000000 0.62500000 1 - Pr Pr4 1 0.25000000 0.87500000 0.62500000 1 - Pr Pr5 1 0.75000000 0.62500000 0.87500000 1 - Pr Pr6 1 0.12500000 0.37500000 0.75000000 1 - Pr Pr7 1 0.37500000 0.12500000 0.25000000 1 - Pr Pr8 1 0.37500000 0.75000000 0.12500000 1 - Pr Pr9 1 0.12500000 0.25000000 0.37500000 1 - Pr Pr10 1 0.75000000 0.12500000 0.37500000 1 - Pr Pr11 1 0.25000000 0.37500000 0.12500000 1 - Fe Fe12 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe13 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe16 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe17 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe18 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe20 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe21 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe22 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe23 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe24 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe25 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe26 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe27 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe28 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe29 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe30 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe31 1 0.75000000 0.37500000 0.62500000 1 - O O32 1 0.02511000 0.32153300 0.90497800 1 - O O33 1 0.91655500 0.12013200 0.59502200 1 - O O34 1 0.58344500 0.17846700 0.20357700 1 - O O35 1 0.47489000 0.37986800 0.29642300 1 - O O36 1 0.32153300 0.90497800 0.02511000 1 - O O37 1 0.12013200 0.59502200 0.91655500 1 - O O38 1 0.17846700 0.20357700 0.58344500 1 - O O39 1 0.37986800 0.29642300 0.47489000 1 - O O40 1 0.90497800 0.02511000 0.32153300 1 - O O41 1 0.59502200 0.91655500 0.12013200 1 - O O42 1 0.20357700 0.58344500 0.17846700 1 - O O43 1 0.29642300 0.47489000 0.37986800 1 - O O44 1 0.97489000 0.67846700 0.09502200 1 - O O45 1 0.08344500 0.87986800 0.40497800 1 - O O46 1 0.41655500 0.82153300 0.79642300 1 - O O47 1 0.52511000 0.62013200 0.70357700 1 - O O48 1 0.67846700 0.09502200 0.97489000 1 - O O49 1 0.87986800 0.40497800 0.08344500 1 - O O50 1 0.82153300 0.79642300 0.41655500 1 - O O51 1 0.62013200 0.70357700 0.52511000 1 - O O52 1 0.09502200 0.97489000 0.67846700 1 - O O53 1 0.40497800 0.08344500 0.87986800 1 - O O54 1 0.79642300 0.41655500 0.82153300 1 - O O55 1 0.70357700 0.52511000 0.62013200 1 - O O56 1 0.52511000 0.40497800 0.82153300 1 - O O57 1 0.41655500 0.09502200 0.62013200 1 - O O58 1 0.08344500 0.70357700 0.67846700 1 - O O59 1 0.97489000 0.79642300 0.87986800 1 - O O60 1 0.82153300 0.52511000 0.40497800 1 - O O61 1 0.62013200 0.41655500 0.09502200 1 - O O62 1 0.67846700 0.08344500 0.70357700 1 - O O63 1 0.87986800 0.97489000 0.79642300 1 - O O64 1 0.40497800 0.82153300 0.52511000 1 - O O65 1 0.09502200 0.62013200 0.41655500 1 - O O66 1 0.70357700 0.67846700 0.08344500 1 - O O67 1 0.79642300 0.87986800 0.97489000 1 - O O68 1 0.47489000 0.59502200 0.17846700 1 - O O69 1 0.58344500 0.90497800 0.37986800 1 - O O70 1 0.91655500 0.29642300 0.32153300 1 - O O71 1 0.02511000 0.20357700 0.12013200 1 - O O72 1 0.17846700 0.47489000 0.59502200 1 - O O73 1 0.37986800 0.58344500 0.90497800 1 - O O74 1 0.32153300 0.91655500 0.29642300 1 - O O75 1 0.12013200 0.02511000 0.20357700 1 - O O76 1 0.59502200 0.17846700 0.47489000 1 - O O77 1 0.90497800 0.37986800 0.58344500 1 - O O78 1 0.29642300 0.32153300 0.91655500 1 - O O79 1 0.20357700 0.12013200 0.02511000 1 -" -Pr3Ga5O12,mp-1210032,Ia-3d,[],0.0,"{'tags': ['Y3Al5O12', 'garnet family', 'Pr3Ga5O12']}","Full Formula (Pr12 Ga20 O48) -Reduced Formula: Pr3Ga5O12 -abc : 11.000398 11.000398 11.000398 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Pr 0.25 0.375 0.125 -0 - 1 Pr 0.75 0.625 0.875 -0 - 2 Pr 0.75 0.125 0.375 -0 - 3 Pr 0.125 0.25 0.375 -0 - 4 Pr 0.375 0.75 0.125 -0 - 5 Pr 0.25 0.875 0.625 -0 - 6 Pr 0.875 0.75 0.625 -0 - 7 Pr 0.625 0.25 0.875 -0 - 8 Pr 0.375 0.125 0.25 -0 - 9 Pr 0.625 0.875 0.75 -0 - 10 Pr 0.125 0.375 0.75 -0 - 11 Pr 0.875 0.625 0.25 -0 - 12 Ga 0.25 0.625 0.375 0 - 13 Ga 0.75 0.375 0.625 0 - 14 Ga 0.75 0.875 0.125 0 - 15 Ga 0.375 0.25 0.625 0 - 16 Ga 0.625 0.75 0.375 0 - 17 Ga 0.25 0.125 0.875 0 - 18 Ga 0.125 0.75 0.875 0 - 19 Ga 0.875 0.25 0.125 0 - 20 Ga 0.625 0.375 0.25 0 - 21 Ga 0.375 0.625 0.75 0 - 22 Ga 0.875 0.125 0.75 0 - 23 Ga 0.125 0.875 0.25 0 - 24 Ga 0 0 0 0 - 25 Ga 0.5 0 0.5 0 - 26 Ga 0 0.5 0.5 0 - 27 Ga 0.5 0 0 0 - 28 Ga 0.5 0.5 0 0 - 29 Ga 0.5 0.5 0.5 0 - 30 Ga 0 0 0.5 0 - 31 Ga 0 0.5 0 0 - 32 O 0.478257 0.38182 0.299359 -0 - 33 O 0.521743 0.61818 0.700641 -0 - 34 O 0.582461 0.178899 0.200641 -0 - 35 O 0.917539 0.11818 0.596437 -0 - 36 O 0.299359 0.478257 0.38182 -0 - 37 O 0.321101 0.917539 0.299359 -0 - 38 O 0.417539 0.821101 0.799359 -0 - 39 O 0.082461 0.88182 0.403563 -0 - 40 O 0.700641 0.521743 0.61818 -0 - 41 O 0.678899 0.082461 0.700641 -0 - 42 O 0.021743 0.321101 0.903563 0 - 43 O 0.200641 0.582461 0.178899 -0 - 44 O 0.11818 0.021743 0.200641 -0 - 45 O 0.978257 0.678899 0.096437 -0 - 46 O 0.799359 0.417539 0.821101 -0 - 47 O 0.88182 0.978257 0.799359 -0 - 48 O 0.596437 0.917539 0.11818 -0 - 49 O 0.178899 0.478257 0.596437 -0 - 50 O 0.403563 0.082461 0.88182 -0 - 51 O 0.821101 0.521743 0.403563 -0 - 52 O 0.903563 0.021743 0.321101 -0 - 53 O 0.38182 0.582461 0.903563 0 - 54 O 0.096437 0.978257 0.678899 -0 - 55 O 0.61818 0.417539 0.096437 0 - 56 O 0.38182 0.299359 0.478257 -0 - 57 O 0.582461 0.903563 0.38182 -0 - 58 O 0.61818 0.700641 0.521743 -0 - 59 O 0.417539 0.096437 0.61818 -0 - 60 O 0.11818 0.596437 0.917539 -0 - 61 O 0.021743 0.200641 0.11818 0 - 62 O 0.88182 0.403563 0.082461 -0 - 63 O 0.978257 0.799359 0.88182 -0 - 64 O 0.321101 0.903563 0.021743 -0 - 65 O 0.917539 0.299359 0.321101 -0 - 66 O 0.678899 0.096437 0.978257 -0 - 67 O 0.082461 0.700641 0.678899 0 - 68 O 0.178899 0.200641 0.582461 -0 - 69 O 0.478257 0.596437 0.178899 -0 - 70 O 0.821101 0.799359 0.417539 -0 - 71 O 0.521743 0.403563 0.821101 -0 - 72 O 0.299359 0.321101 0.917539 -0 - 73 O 0.700641 0.678899 0.082461 -0 - 74 O 0.200641 0.11818 0.021743 -0 - 75 O 0.799359 0.88182 0.978257 -0 - 76 O 0.903563 0.38182 0.582461 -0 - 77 O 0.096437 0.61818 0.417539 0 - 78 O 0.596437 0.178899 0.478257 -0 - 79 O 0.403563 0.821101 0.521743 -0","# generated using pymatgen -data_Pr3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 11.00039844 -_cell_length_b 11.00039844 -_cell_length_c 11.00039844 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Pr3Ga5O12 -_chemical_formula_sum 'Pr12 Ga20 O48' -_cell_volume 1024.71562059 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Pr Pr0 1 0.25000000 0.37500000 0.12500000 1 - Pr Pr1 1 0.75000000 0.62500000 0.87500000 1 - Pr Pr2 1 0.75000000 0.12500000 0.37500000 1 - Pr Pr3 1 0.12500000 0.25000000 0.37500000 1 - Pr Pr4 1 0.37500000 0.75000000 0.12500000 1 - Pr Pr5 1 0.25000000 0.87500000 0.62500000 1 - Pr Pr6 1 0.87500000 0.75000000 0.62500000 1 - Pr Pr7 1 0.62500000 0.25000000 0.87500000 1 - Pr Pr8 1 0.37500000 0.12500000 0.25000000 1 - Pr Pr9 1 0.62500000 0.87500000 0.75000000 1 - Pr Pr10 1 0.12500000 0.37500000 0.75000000 1 - Pr Pr11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga13 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga14 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga17 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga18 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga19 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga24 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga25 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga26 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga28 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga29 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47825700 0.38182000 0.29935900 1 - O O33 1 0.52174300 0.61818000 0.70064100 1 - O O34 1 0.58246100 0.17889900 0.20064100 1 - O O35 1 0.91753900 0.11818000 0.59643700 1 - O O36 1 0.29935900 0.47825700 0.38182000 1 - O O37 1 0.32110100 0.91753900 0.29935900 1 - O O38 1 0.41753900 0.82110100 0.79935900 1 - O O39 1 0.08246100 0.88182000 0.40356300 1 - O O40 1 0.70064100 0.52174300 0.61818000 1 - O O41 1 0.67889900 0.08246100 0.70064100 1 - O O42 1 0.02174300 0.32110100 0.90356300 1 - O O43 1 0.20064100 0.58246100 0.17889900 1 - O O44 1 0.11818000 0.02174300 0.20064100 1 - O O45 1 0.97825700 0.67889900 0.09643700 1 - O O46 1 0.79935900 0.41753900 0.82110100 1 - O O47 1 0.88182000 0.97825700 0.79935900 1 - O O48 1 0.59643700 0.91753900 0.11818000 1 - O O49 1 0.17889900 0.47825700 0.59643700 1 - O O50 1 0.40356300 0.08246100 0.88182000 1 - O O51 1 0.82110100 0.52174300 0.40356300 1 - O O52 1 0.90356300 0.02174300 0.32110100 1 - O O53 1 0.38182000 0.58246100 0.90356300 1 - O O54 1 0.09643700 0.97825700 0.67889900 1 - O O55 1 0.61818000 0.41753900 0.09643700 1 - O O56 1 0.38182000 0.29935900 0.47825700 1 - O O57 1 0.58246100 0.90356300 0.38182000 1 - O O58 1 0.61818000 0.70064100 0.52174300 1 - O O59 1 0.41753900 0.09643700 0.61818000 1 - O O60 1 0.11818000 0.59643700 0.91753900 1 - O O61 1 0.02174300 0.20064100 0.11818000 1 - O O62 1 0.88182000 0.40356300 0.08246100 1 - O O63 1 0.97825700 0.79935900 0.88182000 1 - O O64 1 0.32110100 0.90356300 0.02174300 1 - O O65 1 0.91753900 0.29935900 0.32110100 1 - O O66 1 0.67889900 0.09643700 0.97825700 1 - O O67 1 0.08246100 0.70064100 0.67889900 1 - O O68 1 0.17889900 0.20064100 0.58246100 1 - O O69 1 0.47825700 0.59643700 0.17889900 1 - O O70 1 0.82110100 0.79935900 0.41753900 1 - O O71 1 0.52174300 0.40356300 0.82110100 1 - O O72 1 0.29935900 0.32110100 0.91753900 1 - O O73 1 0.70064100 0.67889900 0.08246100 1 - O O74 1 0.20064100 0.11818000 0.02174300 1 - O O75 1 0.79935900 0.88182000 0.97825700 1 - O O76 1 0.90356300 0.38182000 0.58246100 1 - O O77 1 0.09643700 0.61818000 0.41753900 1 - O O78 1 0.59643700 0.17889900 0.47825700 1 - O O79 1 0.40356300 0.82110100 0.52174300 1 -" -Sm3Al5O12,mp-780370,Ia-3d,[],0.0,{'tags': []},"Full Formula (Sm12 Al20 O48) -Reduced Formula: Sm3Al5O12 -abc : 10.622423 10.622423 10.622423 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sm 0.75 0.125 0.375 -0 - 1 Sm 0.375 0.125 0.25 -0 - 2 Sm 0.875 0.625 0.25 -0 - 3 Sm 0.25 0.375 0.125 -0 - 4 Sm 0.375 0.75 0.125 -0 - 5 Sm 0.125 0.25 0.375 -0 - 6 Sm 0.875 0.75 0.625 -0 - 7 Sm 0.625 0.25 0.875 -0 - 8 Sm 0.75 0.625 0.875 -0 - 9 Sm 0.625 0.875 0.75 -0 - 10 Sm 0.125 0.375 0.75 -0 - 11 Sm 0.25 0.875 0.625 -0 - 12 Al 0.875 0.25 0.125 -0 - 13 Al 0.5 0 0 0 - 14 Al 0 0 0 0 - 15 Al 0.625 0.375 0.25 -0 - 16 Al 0.5 0 0.5 0 - 17 Al 0.5 0.5 0 0 - 18 Al 0.875 0.125 0.75 -0 - 19 Al 0.75 0.875 0.125 -0 - 20 Al 0.75 0.375 0.625 -0 - 21 Al 0.625 0.75 0.375 -0 - 22 Al 0.5 0.5 0.5 0 - 23 Al 0 0.5 0 0 - 24 Al 0 0 0.5 0 - 25 Al 0.375 0.25 0.625 -0 - 26 Al 0.25 0.625 0.375 -0 - 27 Al 0.25 0.125 0.875 -0 - 28 Al 0.375 0.625 0.75 -0 - 29 Al 0.125 0.875 0.25 -0 - 30 Al 0 0.5 0.5 0 - 31 Al 0.125 0.75 0.875 -0 - 32 O 0.900022 0.016374 0.31984 -0 - 33 O 0.883648 0.400022 0.080182 -0 - 34 O 0.919818 0.303466 0.31984 -0 - 35 O 0.983626 0.68016 0.099978 -0 - 36 O 0.919818 0.116352 0.599978 -0 - 37 O 0.580182 0.18016 0.196534 -0 - 38 O 0.616352 0.419818 0.099978 -0 - 39 O 0.196534 0.116352 0.016374 -0 - 40 O 0.696534 0.68016 0.080182 -0 - 41 O 0.599978 0.18016 0.483626 -0 - 42 O 0.900022 0.383648 0.580182 -0 - 43 O 0.116352 0.016374 0.196534 -0 - 44 O 0.81984 0.516374 0.400022 -0 - 45 O 0.68016 0.080182 0.696534 -0 - 46 O 0.483626 0.383648 0.303466 -0 - 47 O 0.483626 0.599978 0.18016 -0 - 48 O 0.419818 0.099978 0.616352 -0 - 49 O 0.016374 0.196534 0.116352 -0 - 50 O 0.81984 0.803466 0.419818 -0 - 51 O 0.383648 0.303466 0.483626 -0 - 52 O 0.68016 0.099978 0.983626 -0 - 53 O 0.696534 0.516374 0.616352 -0 - 54 O 0.803466 0.419818 0.81984 -0 - 55 O 0.599978 0.919818 0.116352 -0 - 56 O 0.303466 0.483626 0.383648 -0 - 57 O 0.400022 0.080182 0.883648 -0 - 58 O 0.196534 0.580182 0.18016 -0 - 59 O 0.18016 0.196534 0.580182 -0 - 60 O 0.616352 0.696534 0.516374 -0 - 61 O 0.31984 0.900022 0.016374 -0 - 62 O 0.580182 0.900022 0.383648 -0 - 63 O 0.516374 0.400022 0.81984 -0 - 64 O 0.983626 0.803466 0.883648 -0 - 65 O 0.516374 0.616352 0.696534 -0 - 66 O 0.31984 0.919818 0.303466 -0 - 67 O 0.18016 0.483626 0.599978 -0 - 68 O 0.883648 0.983626 0.803466 -0 - 69 O 0.400022 0.81984 0.516374 -0 - 70 O 0.303466 0.31984 0.919818 -0 - 71 O 0.099978 0.616352 0.419818 -0 - 72 O 0.803466 0.883648 0.983626 -0 - 73 O 0.383648 0.580182 0.900022 -0 - 74 O 0.419818 0.81984 0.803466 -0 - 75 O 0.016374 0.31984 0.900022 -0 - 76 O 0.080182 0.883648 0.400022 -0 - 77 O 0.080182 0.696534 0.68016 -0 - 78 O 0.116352 0.599978 0.919818 -0 - 79 O 0.099978 0.983626 0.68016 -0","# generated using pymatgen -data_Sm3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.62242338 -_cell_length_b 10.62242338 -_cell_length_c 10.62242338 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sm3Al5O12 -_chemical_formula_sum 'Sm12 Al20 O48' -_cell_volume 922.67537765 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sm Sm0 1 0.75000000 0.12500000 0.37500000 1 - Sm Sm1 1 0.37500000 0.12500000 0.25000000 1 - Sm Sm2 1 0.87500000 0.62500000 0.25000000 1 - Sm Sm3 1 0.25000000 0.37500000 0.12500000 1 - Sm Sm4 1 0.37500000 0.75000000 0.12500000 1 - Sm Sm5 1 0.12500000 0.25000000 0.37500000 1 - Sm Sm6 1 0.87500000 0.75000000 0.62500000 1 - Sm Sm7 1 0.62500000 0.25000000 0.87500000 1 - Sm Sm8 1 0.75000000 0.62500000 0.87500000 1 - Sm Sm9 1 0.62500000 0.87500000 0.75000000 1 - Sm Sm10 1 0.12500000 0.37500000 0.75000000 1 - Sm Sm11 1 0.25000000 0.87500000 0.62500000 1 - Al Al12 1 0.87500000 0.25000000 0.12500000 1 - Al Al13 1 0.50000000 0.00000000 0.00000000 1 - Al Al14 1 0.00000000 0.00000000 0.00000000 1 - Al Al15 1 0.62500000 0.37500000 0.25000000 1 - Al Al16 1 0.50000000 0.00000000 0.50000000 1 - Al Al17 1 0.50000000 0.50000000 0.00000000 1 - Al Al18 1 0.87500000 0.12500000 0.75000000 1 - Al Al19 1 0.75000000 0.87500000 0.12500000 1 - Al Al20 1 0.75000000 0.37500000 0.62500000 1 - Al Al21 1 0.62500000 0.75000000 0.37500000 1 - Al Al22 1 0.50000000 0.50000000 0.50000000 1 - Al Al23 1 0.00000000 0.50000000 0.00000000 1 - Al Al24 1 0.00000000 0.00000000 0.50000000 1 - Al Al25 1 0.37500000 0.25000000 0.62500000 1 - Al Al26 1 0.25000000 0.62500000 0.37500000 1 - Al Al27 1 0.25000000 0.12500000 0.87500000 1 - Al Al28 1 0.37500000 0.62500000 0.75000000 1 - Al Al29 1 0.12500000 0.87500000 0.25000000 1 - Al Al30 1 0.00000000 0.50000000 0.50000000 1 - Al Al31 1 0.12500000 0.75000000 0.87500000 1 - O O32 1 0.90002200 0.01637400 0.31984000 1 - O O33 1 0.88364800 0.40002200 0.08018200 1 - O O34 1 0.91981800 0.30346600 0.31984000 1 - O O35 1 0.98362600 0.68016000 0.09997800 1 - O O36 1 0.91981800 0.11635200 0.59997800 1 - O O37 1 0.58018200 0.18016000 0.19653400 1 - O O38 1 0.61635200 0.41981800 0.09997800 1 - O O39 1 0.19653400 0.11635200 0.01637400 1 - O O40 1 0.69653400 0.68016000 0.08018200 1 - O O41 1 0.59997800 0.18016000 0.48362600 1 - O O42 1 0.90002200 0.38364800 0.58018200 1 - O O43 1 0.11635200 0.01637400 0.19653400 1 - O O44 1 0.81984000 0.51637400 0.40002200 1 - O O45 1 0.68016000 0.08018200 0.69653400 1 - O O46 1 0.48362600 0.38364800 0.30346600 1 - O O47 1 0.48362600 0.59997800 0.18016000 1 - O O48 1 0.41981800 0.09997800 0.61635200 1 - O O49 1 0.01637400 0.19653400 0.11635200 1 - O O50 1 0.81984000 0.80346600 0.41981800 1 - O O51 1 0.38364800 0.30346600 0.48362600 1 - O O52 1 0.68016000 0.09997800 0.98362600 1 - O O53 1 0.69653400 0.51637400 0.61635200 1 - O O54 1 0.80346600 0.41981800 0.81984000 1 - O O55 1 0.59997800 0.91981800 0.11635200 1 - O O56 1 0.30346600 0.48362600 0.38364800 1 - O O57 1 0.40002200 0.08018200 0.88364800 1 - O O58 1 0.19653400 0.58018200 0.18016000 1 - O O59 1 0.18016000 0.19653400 0.58018200 1 - O O60 1 0.61635200 0.69653400 0.51637400 1 - O O61 1 0.31984000 0.90002200 0.01637400 1 - O O62 1 0.58018200 0.90002200 0.38364800 1 - O O63 1 0.51637400 0.40002200 0.81984000 1 - O O64 1 0.98362600 0.80346600 0.88364800 1 - O O65 1 0.51637400 0.61635200 0.69653400 1 - O O66 1 0.31984000 0.91981800 0.30346600 1 - O O67 1 0.18016000 0.48362600 0.59997800 1 - O O68 1 0.88364800 0.98362600 0.80346600 1 - O O69 1 0.40002200 0.81984000 0.51637400 1 - O O70 1 0.30346600 0.31984000 0.91981800 1 - O O71 1 0.09997800 0.61635200 0.41981800 1 - O O72 1 0.80346600 0.88364800 0.98362600 1 - O O73 1 0.38364800 0.58018200 0.90002200 1 - O O74 1 0.41981800 0.81984000 0.80346600 1 - O O75 1 0.01637400 0.31984000 0.90002200 1 - O O76 1 0.08018200 0.88364800 0.40002200 1 - O O77 1 0.08018200 0.69653400 0.68016000 1 - O O78 1 0.11635200 0.59997800 0.91981800 1 - O O79 1 0.09997800 0.98362600 0.68016000 1 -" -Sm3Fe5O12,mp-14139,Ia-3d,[23857],0.01953419799999523,{'tags': ['Pentairon(III) trisamarium oxide']},"Full Formula (Sm12 Fe20 O48) -Reduced Formula: Sm3Fe5O12 -abc : 10.991932 10.991932 10.991932 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sm 0.375 0.75 0.125 0.023 - 1 Sm 0.25 0.375 0.125 0.023 - 2 Sm 0.75 0.125 0.375 0.023 - 3 Sm 0.375 0.125 0.25 0.023 - 4 Sm 0.125 0.375 0.75 0.023 - 5 Sm 0.125 0.25 0.375 0.023 - 6 Sm 0.625 0.25 0.875 0.023 - 7 Sm 0.75 0.625 0.875 0.023 - 8 Sm 0.25 0.875 0.625 0.023 - 9 Sm 0.625 0.875 0.75 0.023 - 10 Sm 0.875 0.625 0.25 0.023 - 11 Sm 0.875 0.75 0.625 0.023 - 12 Fe 0.5 0 0 4.402 - 13 Fe 0.5 0.5 0 4.4 - 14 Fe 0 0.5 0.5 4.402 - 15 Fe 0 0 0 4.4 - 16 Fe 0 0 0.5 4.402 - 17 Fe 0.5 0.5 0.5 4.4 - 18 Fe 0 0.5 0 4.4 - 19 Fe 0.5 0 0.5 4.402 - 20 Fe 0.625 0.75 0.375 4.273 - 21 Fe 0.25 0.625 0.375 4.274 - 22 Fe 0.75 0.875 0.125 4.274 - 23 Fe 0.625 0.375 0.25 4.273 - 24 Fe 0.125 0.75 0.875 4.273 - 25 Fe 0.875 0.25 0.125 4.273 - 26 Fe 0.75 0.375 0.625 4.274 - 27 Fe 0.125 0.875 0.25 4.273 - 28 Fe 0.25 0.125 0.875 4.274 - 29 Fe 0.375 0.625 0.75 4.273 - 30 Fe 0.375 0.25 0.625 4.273 - 31 Fe 0.875 0.125 0.75 4.273 - 32 O 0.527924 0.405173 0.822334 0.217 - 33 O 0.822334 0.527924 0.405173 0.217 - 34 O 0.79441 0.877249 0.972076 0.217 - 35 O 0.417161 0.094827 0.622751 0.217 - 36 O 0.877249 0.405173 0.082839 0.217 - 37 O 0.677666 0.082839 0.70559 0.217 - 38 O 0.822334 0.79441 0.417161 0.217 - 39 O 0.405173 0.822334 0.527924 0.217 - 40 O 0.622751 0.70559 0.527924 0.217 - 41 O 0.417161 0.822334 0.79441 0.217 - 42 O 0.405173 0.082839 0.877249 0.217 - 43 O 0.094827 0.972076 0.677666 0.217 - 44 O 0.972076 0.677666 0.094827 0.217 - 45 O 0.79441 0.417161 0.822334 0.217 - 46 O 0.527924 0.622751 0.70559 0.217 - 47 O 0.70559 0.527924 0.622751 0.217 - 48 O 0.082839 0.877249 0.405173 0.217 - 49 O 0.972076 0.79441 0.877249 0.217 - 50 O 0.082839 0.70559 0.677666 0.217 - 51 O 0.377249 0.29441 0.472076 0.217 - 52 O 0.622751 0.417161 0.094827 0.217 - 53 O 0.094827 0.622751 0.417161 0.217 - 54 O 0.70559 0.677666 0.082839 0.217 - 55 O 0.677666 0.094827 0.972076 0.217 - 56 O 0.472076 0.594827 0.177666 0.217 - 57 O 0.177666 0.472076 0.594827 0.217 - 58 O 0.20559 0.122751 0.027924 0.217 - 59 O 0.582839 0.905173 0.377249 0.217 - 60 O 0.122751 0.594827 0.917161 0.217 - 61 O 0.322334 0.917161 0.29441 0.217 - 62 O 0.177666 0.20559 0.582839 0.217 - 63 O 0.594827 0.177666 0.472076 0.217 - 64 O 0.322334 0.905173 0.027924 0.217 - 65 O 0.29441 0.322334 0.917161 0.217 - 66 O 0.905173 0.377249 0.582839 0.217 - 67 O 0.122751 0.027924 0.20559 0.217 - 68 O 0.377249 0.582839 0.905173 0.217 - 69 O 0.917161 0.29441 0.322334 0.217 - 70 O 0.027924 0.20559 0.122751 0.217 - 71 O 0.917161 0.122751 0.594827 0.217 - 72 O 0.29441 0.472076 0.377249 0.217 - 73 O 0.472076 0.377249 0.29441 0.217 - 74 O 0.20559 0.582839 0.177666 0.217 - 75 O 0.027924 0.322334 0.905173 0.217 - 76 O 0.905173 0.027924 0.322334 0.217 - 77 O 0.594827 0.917161 0.122751 0.217 - 78 O 0.582839 0.177666 0.20559 0.217 - 79 O 0.877249 0.972076 0.79441 0.217","# generated using pymatgen -data_Sm3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.99193217 -_cell_length_b 10.99193217 -_cell_length_c 10.99193217 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sm3Fe5O12 -_chemical_formula_sum 'Sm12 Fe20 O48' -_cell_volume 1022.35147766 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sm Sm0 1 0.37500000 0.75000000 0.12500000 1 - Sm Sm1 1 0.25000000 0.37500000 0.12500000 1 - Sm Sm2 1 0.75000000 0.12500000 0.37500000 1 - Sm Sm3 1 0.37500000 0.12500000 0.25000000 1 - Sm Sm4 1 0.12500000 0.37500000 0.75000000 1 - Sm Sm5 1 0.12500000 0.25000000 0.37500000 1 - Sm Sm6 1 0.62500000 0.25000000 0.87500000 1 - Sm Sm7 1 0.75000000 0.62500000 0.87500000 1 - Sm Sm8 1 0.25000000 0.87500000 0.62500000 1 - Sm Sm9 1 0.62500000 0.87500000 0.75000000 1 - Sm Sm10 1 0.87500000 0.62500000 0.25000000 1 - Sm Sm11 1 0.87500000 0.75000000 0.62500000 1 - Fe Fe12 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe18 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe19 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe20 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe21 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe22 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe23 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe24 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe25 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe26 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe27 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe28 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe29 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe30 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe31 1 0.87500000 0.12500000 0.75000000 1 - O O32 1 0.52792400 0.40517300 0.82233400 1 - O O33 1 0.82233400 0.52792400 0.40517300 1 - O O34 1 0.79441000 0.87724900 0.97207600 1 - O O35 1 0.41716100 0.09482700 0.62275100 1 - O O36 1 0.87724900 0.40517300 0.08283900 1 - O O37 1 0.67766600 0.08283900 0.70559000 1 - O O38 1 0.82233400 0.79441000 0.41716100 1 - O O39 1 0.40517300 0.82233400 0.52792400 1 - O O40 1 0.62275100 0.70559000 0.52792400 1 - O O41 1 0.41716100 0.82233400 0.79441000 1 - O O42 1 0.40517300 0.08283900 0.87724900 1 - O O43 1 0.09482700 0.97207600 0.67766600 1 - O O44 1 0.97207600 0.67766600 0.09482700 1 - O O45 1 0.79441000 0.41716100 0.82233400 1 - O O46 1 0.52792400 0.62275100 0.70559000 1 - O O47 1 0.70559000 0.52792400 0.62275100 1 - O O48 1 0.08283900 0.87724900 0.40517300 1 - O O49 1 0.97207600 0.79441000 0.87724900 1 - O O50 1 0.08283900 0.70559000 0.67766600 1 - O O51 1 0.37724900 0.29441000 0.47207600 1 - O O52 1 0.62275100 0.41716100 0.09482700 1 - O O53 1 0.09482700 0.62275100 0.41716100 1 - O O54 1 0.70559000 0.67766600 0.08283900 1 - O O55 1 0.67766600 0.09482700 0.97207600 1 - O O56 1 0.47207600 0.59482700 0.17766600 1 - O O57 1 0.17766600 0.47207600 0.59482700 1 - O O58 1 0.20559000 0.12275100 0.02792400 1 - O O59 1 0.58283900 0.90517300 0.37724900 1 - O O60 1 0.12275100 0.59482700 0.91716100 1 - O O61 1 0.32233400 0.91716100 0.29441000 1 - O O62 1 0.17766600 0.20559000 0.58283900 1 - O O63 1 0.59482700 0.17766600 0.47207600 1 - O O64 1 0.32233400 0.90517300 0.02792400 1 - O O65 1 0.29441000 0.32233400 0.91716100 1 - O O66 1 0.90517300 0.37724900 0.58283900 1 - O O67 1 0.12275100 0.02792400 0.20559000 1 - O O68 1 0.37724900 0.58283900 0.90517300 1 - O O69 1 0.91716100 0.29441000 0.32233400 1 - O O70 1 0.02792400 0.20559000 0.12275100 1 - O O71 1 0.91716100 0.12275100 0.59482700 1 - O O72 1 0.29441000 0.47207600 0.37724900 1 - O O73 1 0.47207600 0.37724900 0.29441000 1 - O O74 1 0.20559000 0.58283900 0.17766600 1 - O O75 1 0.02792400 0.32233400 0.90517300 1 - O O76 1 0.90517300 0.02792400 0.32233400 1 - O O77 1 0.59482700 0.91716100 0.12275100 1 - O O78 1 0.58283900 0.17766600 0.20559000 1 - O O79 1 0.87724900 0.97207600 0.79441000 1 -" -Sm3Ga5O12,mp-5800,Ia-3d,"[291192, 9236, 84873]",0.0,"{'tags': ['Garnet', 'Unnamed_Garnet', 'Trisamarium gallium dodecaoxide', 'Trisamarium pentagallium oxide']}","Full Formula (Sm12 Ga20 O48) -Reduced Formula: Sm3Ga5O12 -abc : 10.882991 10.882991 10.882991 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Sm 0.875 0.75 0.625 -0 - 1 Sm 0.875 0.625 0.25 -0 - 2 Sm 0.625 0.875 0.75 -0 - 3 Sm 0.25 0.875 0.625 -0 - 4 Sm 0.75 0.625 0.875 -0 - 5 Sm 0.625 0.25 0.875 -0 - 6 Sm 0.125 0.25 0.375 -0 - 7 Sm 0.125 0.375 0.75 -0 - 8 Sm 0.375 0.125 0.25 -0 - 9 Sm 0.75 0.125 0.375 -0 - 10 Sm 0.25 0.375 0.125 -0 - 11 Sm 0.375 0.75 0.125 -0 - 12 Ga 0.125 0.75 0.875 -0 - 13 Ga 0.875 0.25 0.125 -0 - 14 Ga 0.75 0.375 0.625 -0 - 15 Ga 0.125 0.875 0.25 -0 - 16 Ga 0.25 0.125 0.875 -0 - 17 Ga 0.375 0.625 0.75 -0 - 18 Ga 0.375 0.25 0.625 -0 - 19 Ga 0.875 0.125 0.75 -0 - 20 Ga 0.625 0.375 0.25 -0 - 21 Ga 0.75 0.875 0.125 -0 - 22 Ga 0.25 0.625 0.375 -0 - 23 Ga 0.625 0.75 0.375 -0 - 24 Ga 0.5 0 0.5 -0 - 25 Ga 0 0.5 0 -0 - 26 Ga 0.5 0.5 0.5 -0 - 27 Ga 0 0 0.5 -0 - 28 Ga 0 0 0 -0 - 29 Ga 0 0.5 0.5 -0 - 30 Ga 0.5 0.5 0 -0 - 31 Ga 0.5 0 0 -0 - 32 O 0.582231 0.904182 0.379071 0 - 33 O 0.379071 0.582231 0.904182 0 - 34 O 0.29684 0.321951 0.917769 0 - 35 O 0.474889 0.595818 0.178049 0 - 36 O 0.321951 0.904182 0.025111 0 - 37 O 0.120929 0.025111 0.20316 0 - 38 O 0.379071 0.29684 0.474889 0 - 39 O 0.904182 0.379071 0.582231 0 - 40 O 0.178049 0.20316 0.582231 0 - 41 O 0.474889 0.379071 0.29684 0 - 42 O 0.904182 0.025111 0.321951 0 - 43 O 0.595818 0.917769 0.120929 0 - 44 O 0.917769 0.120929 0.595818 0 - 45 O 0.29684 0.474889 0.379071 0 - 46 O 0.582231 0.178049 0.20316 0 - 47 O 0.20316 0.582231 0.178049 0 - 48 O 0.025111 0.321951 0.904182 0 - 49 O 0.917769 0.29684 0.321951 0 - 50 O 0.025111 0.20316 0.120929 0 - 51 O 0.821951 0.79684 0.417769 0 - 52 O 0.178049 0.474889 0.595818 0 - 53 O 0.595818 0.178049 0.474889 0 - 54 O 0.20316 0.120929 0.025111 0 - 55 O 0.120929 0.595818 0.917769 0 - 56 O 0.417769 0.095818 0.620929 0 - 57 O 0.620929 0.417769 0.095818 0 - 58 O 0.70316 0.678049 0.082231 0 - 59 O 0.525111 0.404182 0.821951 0 - 60 O 0.678049 0.095818 0.974889 0 - 61 O 0.879071 0.974889 0.79684 0 - 62 O 0.620929 0.70316 0.525111 0 - 63 O 0.095818 0.620929 0.417769 0 - 64 O 0.879071 0.404182 0.082231 0 - 65 O 0.79684 0.879071 0.974889 0 - 66 O 0.404182 0.821951 0.525111 0 - 67 O 0.678049 0.082231 0.70316 0 - 68 O 0.821951 0.525111 0.404182 0 - 69 O 0.974889 0.79684 0.879071 0 - 70 O 0.082231 0.70316 0.678049 0 - 71 O 0.974889 0.678049 0.095818 0 - 72 O 0.79684 0.417769 0.821951 0 - 73 O 0.417769 0.821951 0.79684 0 - 74 O 0.70316 0.525111 0.620929 0 - 75 O 0.082231 0.879071 0.404182 0 - 76 O 0.404182 0.082231 0.879071 0 - 77 O 0.095818 0.974889 0.678049 0 - 78 O 0.525111 0.620929 0.70316 0 - 79 O 0.321951 0.917769 0.29684 0","# generated using pymatgen -data_Sm3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.88299138 -_cell_length_b 10.88299138 -_cell_length_c 10.88299138 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Sm3Ga5O12 -_chemical_formula_sum 'Sm12 Ga20 O48' -_cell_volume 992.25424194 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Sm Sm0 1 0.87500000 0.75000000 0.62500000 1 - Sm Sm1 1 0.87500000 0.62500000 0.25000000 1 - Sm Sm2 1 0.62500000 0.87500000 0.75000000 1 - Sm Sm3 1 0.25000000 0.87500000 0.62500000 1 - Sm Sm4 1 0.75000000 0.62500000 0.87500000 1 - Sm Sm5 1 0.62500000 0.25000000 0.87500000 1 - Sm Sm6 1 0.12500000 0.25000000 0.37500000 1 - Sm Sm7 1 0.12500000 0.37500000 0.75000000 1 - Sm Sm8 1 0.37500000 0.12500000 0.25000000 1 - Sm Sm9 1 0.75000000 0.12500000 0.37500000 1 - Sm Sm10 1 0.25000000 0.37500000 0.12500000 1 - Sm Sm11 1 0.37500000 0.75000000 0.12500000 1 - Ga Ga12 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga13 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga14 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga15 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga16 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga17 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga18 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga19 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga22 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga23 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga24 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga25 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga26 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga28 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga29 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.58223100 0.90418200 0.37907100 1 - O O33 1 0.37907100 0.58223100 0.90418200 1 - O O34 1 0.29684000 0.32195100 0.91776900 1 - O O35 1 0.47488900 0.59581800 0.17804900 1 - O O36 1 0.32195100 0.90418200 0.02511100 1 - O O37 1 0.12092900 0.02511100 0.20316000 1 - O O38 1 0.37907100 0.29684000 0.47488900 1 - O O39 1 0.90418200 0.37907100 0.58223100 1 - O O40 1 0.17804900 0.20316000 0.58223100 1 - O O41 1 0.47488900 0.37907100 0.29684000 1 - O O42 1 0.90418200 0.02511100 0.32195100 1 - O O43 1 0.59581800 0.91776900 0.12092900 1 - O O44 1 0.91776900 0.12092900 0.59581800 1 - O O45 1 0.29684000 0.47488900 0.37907100 1 - O O46 1 0.58223100 0.17804900 0.20316000 1 - O O47 1 0.20316000 0.58223100 0.17804900 1 - O O48 1 0.02511100 0.32195100 0.90418200 1 - O O49 1 0.91776900 0.29684000 0.32195100 1 - O O50 1 0.02511100 0.20316000 0.12092900 1 - O O51 1 0.82195100 0.79684000 0.41776900 1 - O O52 1 0.17804900 0.47488900 0.59581800 1 - O O53 1 0.59581800 0.17804900 0.47488900 1 - O O54 1 0.20316000 0.12092900 0.02511100 1 - O O55 1 0.12092900 0.59581800 0.91776900 1 - O O56 1 0.41776900 0.09581800 0.62092900 1 - O O57 1 0.62092900 0.41776900 0.09581800 1 - O O58 1 0.70316000 0.67804900 0.08223100 1 - O O59 1 0.52511100 0.40418200 0.82195100 1 - O O60 1 0.67804900 0.09581800 0.97488900 1 - O O61 1 0.87907100 0.97488900 0.79684000 1 - O O62 1 0.62092900 0.70316000 0.52511100 1 - O O63 1 0.09581800 0.62092900 0.41776900 1 - O O64 1 0.87907100 0.40418200 0.08223100 1 - O O65 1 0.79684000 0.87907100 0.97488900 1 - O O66 1 0.40418200 0.82195100 0.52511100 1 - O O67 1 0.67804900 0.08223100 0.70316000 1 - O O68 1 0.82195100 0.52511100 0.40418200 1 - O O69 1 0.97488900 0.79684000 0.87907100 1 - O O70 1 0.08223100 0.70316000 0.67804900 1 - O O71 1 0.97488900 0.67804900 0.09581800 1 - O O72 1 0.79684000 0.41776900 0.82195100 1 - O O73 1 0.41776900 0.82195100 0.79684000 1 - O O74 1 0.70316000 0.52511100 0.62092900 1 - O O75 1 0.08223100 0.87907100 0.40418200 1 - O O76 1 0.40418200 0.08223100 0.87907100 1 - O O77 1 0.09581800 0.97488900 0.67804900 1 - O O78 1 0.52511100 0.62092900 0.70316000 1 - O O79 1 0.32195100 0.91776900 0.29684000 1 -" -Tb3Al5O12,mp-14387,Ia-3d,[33602],0.0,{'tags': ['Triterbium pentaaluminium oxide']},"Full Formula (Tb12 Al20 O48) -Reduced Formula: Tb3Al5O12 -abc : 10.516006 10.516006 10.516006 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tb 0.875 0.625 0.25 -0 - 1 Tb 0.625 0.25 0.875 -0 - 2 Tb 0.875 0.75 0.625 -0 - 3 Tb 0.75 0.625 0.875 -0 - 4 Tb 0.25 0.875 0.625 -0 - 5 Tb 0.625 0.875 0.75 -0 - 6 Tb 0.125 0.375 0.75 -0 - 7 Tb 0.375 0.75 0.125 -0 - 8 Tb 0.125 0.25 0.375 -0 - 9 Tb 0.25 0.375 0.125 -0 - 10 Tb 0.75 0.125 0.375 -0 - 11 Tb 0.375 0.125 0.25 -0 - 12 Al 0.125 0.875 0.25 -0 - 13 Al 0.875 0.125 0.75 -0 - 14 Al 0.25 0.625 0.375 -0 - 15 Al 0.375 0.25 0.625 -0 - 16 Al 0.75 0.875 0.125 -0 - 17 Al 0.125 0.75 0.875 -0 - 18 Al 0.375 0.625 0.75 -0 - 19 Al 0.625 0.75 0.375 -0 - 20 Al 0.875 0.25 0.125 -0 - 21 Al 0.25 0.125 0.875 -0 - 22 Al 0.75 0.375 0.625 -0 - 23 Al 0.625 0.375 0.25 -0 - 24 Al 0.5 0.5 0.5 -0 - 25 Al 0.5 0 0.5 -0 - 26 Al 0 0.5 0.5 -0 - 27 Al 0.5 0.5 0 -0 - 28 Al 0 0 0.5 -0 - 29 Al 0 0.5 0 -0 - 30 Al 0.5 0 0 -0 - 31 Al 0 0 0 -0 - 32 O 0.679588 0.09878 0.980595 0 - 33 O 0.801008 0.419192 0.820412 0 - 34 O 0.080808 0.881815 0.40122 0 - 35 O 0.618185 0.698992 0.519405 0 - 36 O 0.40122 0.820412 0.519405 0 - 37 O 0.698992 0.519405 0.618185 0 - 38 O 0.698992 0.679588 0.080808 0 - 39 O 0.519405 0.618185 0.698992 0 - 40 O 0.09878 0.618185 0.419192 0 - 41 O 0.881815 0.980595 0.801008 0 - 42 O 0.980595 0.801008 0.881815 0 - 43 O 0.519405 0.40122 0.820412 0 - 44 O 0.679588 0.080808 0.698992 0 - 45 O 0.419192 0.09878 0.618185 0 - 46 O 0.820412 0.519405 0.40122 0 - 47 O 0.080808 0.698992 0.679588 0 - 48 O 0.618185 0.419192 0.09878 0 - 49 O 0.820412 0.801008 0.419192 0 - 50 O 0.881815 0.40122 0.080808 0 - 51 O 0.90122 0.381815 0.580808 0 - 52 O 0.40122 0.080808 0.881815 0 - 53 O 0.980595 0.679588 0.09878 0 - 54 O 0.419192 0.820412 0.801008 0 - 55 O 0.801008 0.881815 0.980595 0 - 56 O 0.320412 0.90122 0.019405 0 - 57 O 0.198992 0.580808 0.179588 0 - 58 O 0.919192 0.118185 0.59878 0 - 59 O 0.381815 0.301008 0.480595 0 - 60 O 0.59878 0.179588 0.480595 0 - 61 O 0.301008 0.480595 0.381815 0 - 62 O 0.301008 0.320412 0.919192 0 - 63 O 0.480595 0.381815 0.301008 0 - 64 O 0.198992 0.118185 0.019405 0 - 65 O 0.580808 0.179588 0.198992 0 - 66 O 0.019405 0.320412 0.90122 0 - 67 O 0.90122 0.019405 0.320412 0 - 68 O 0.59878 0.919192 0.118185 0 - 69 O 0.118185 0.59878 0.919192 0 - 70 O 0.179588 0.198992 0.580808 0 - 71 O 0.381815 0.580808 0.90122 0 - 72 O 0.919192 0.301008 0.320412 0 - 73 O 0.179588 0.480595 0.59878 0 - 74 O 0.580808 0.90122 0.381815 0 - 75 O 0.320412 0.919192 0.301008 0 - 76 O 0.480595 0.59878 0.179588 0 - 77 O 0.019405 0.198992 0.118185 0 - 78 O 0.118185 0.019405 0.198992 0 - 79 O 0.09878 0.980595 0.679588 0","# generated using pymatgen -data_Tb3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.51600618 -_cell_length_b 10.51600618 -_cell_length_c 10.51600618 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tb3Al5O12 -_chemical_formula_sum 'Tb12 Al20 O48' -_cell_volume 895.22171364 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tb Tb0 1 0.87500000 0.62500000 0.25000000 1 - Tb Tb1 1 0.62500000 0.25000000 0.87500000 1 - Tb Tb2 1 0.87500000 0.75000000 0.62500000 1 - Tb Tb3 1 0.75000000 0.62500000 0.87500000 1 - Tb Tb4 1 0.25000000 0.87500000 0.62500000 1 - Tb Tb5 1 0.62500000 0.87500000 0.75000000 1 - Tb Tb6 1 0.12500000 0.37500000 0.75000000 1 - Tb Tb7 1 0.37500000 0.75000000 0.12500000 1 - Tb Tb8 1 0.12500000 0.25000000 0.37500000 1 - Tb Tb9 1 0.25000000 0.37500000 0.12500000 1 - Tb Tb10 1 0.75000000 0.12500000 0.37500000 1 - Tb Tb11 1 0.37500000 0.12500000 0.25000000 1 - Al Al12 1 0.12500000 0.87500000 0.25000000 1 - Al Al13 1 0.87500000 0.12500000 0.75000000 1 - Al Al14 1 0.25000000 0.62500000 0.37500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.75000000 0.87500000 0.12500000 1 - Al Al17 1 0.12500000 0.75000000 0.87500000 1 - Al Al18 1 0.37500000 0.62500000 0.75000000 1 - Al Al19 1 0.62500000 0.75000000 0.37500000 1 - Al Al20 1 0.87500000 0.25000000 0.12500000 1 - Al Al21 1 0.25000000 0.12500000 0.87500000 1 - Al Al22 1 0.75000000 0.37500000 0.62500000 1 - Al Al23 1 0.62500000 0.37500000 0.25000000 1 - Al Al24 1 0.50000000 0.50000000 0.50000000 1 - Al Al25 1 0.50000000 0.00000000 0.50000000 1 - Al Al26 1 0.00000000 0.50000000 0.50000000 1 - Al Al27 1 0.50000000 0.50000000 0.00000000 1 - Al Al28 1 0.00000000 0.00000000 0.50000000 1 - Al Al29 1 0.00000000 0.50000000 0.00000000 1 - Al Al30 1 0.50000000 0.00000000 0.00000000 1 - Al Al31 1 0.00000000 0.00000000 0.00000000 1 - O O32 1 0.67958800 0.09878000 0.98059500 1 - O O33 1 0.80100800 0.41919200 0.82041200 1 - O O34 1 0.08080800 0.88181500 0.40122000 1 - O O35 1 0.61818500 0.69899200 0.51940500 1 - O O36 1 0.40122000 0.82041200 0.51940500 1 - O O37 1 0.69899200 0.51940500 0.61818500 1 - O O38 1 0.69899200 0.67958800 0.08080800 1 - O O39 1 0.51940500 0.61818500 0.69899200 1 - O O40 1 0.09878000 0.61818500 0.41919200 1 - O O41 1 0.88181500 0.98059500 0.80100800 1 - O O42 1 0.98059500 0.80100800 0.88181500 1 - O O43 1 0.51940500 0.40122000 0.82041200 1 - O O44 1 0.67958800 0.08080800 0.69899200 1 - O O45 1 0.41919200 0.09878000 0.61818500 1 - O O46 1 0.82041200 0.51940500 0.40122000 1 - O O47 1 0.08080800 0.69899200 0.67958800 1 - O O48 1 0.61818500 0.41919200 0.09878000 1 - O O49 1 0.82041200 0.80100800 0.41919200 1 - O O50 1 0.88181500 0.40122000 0.08080800 1 - O O51 1 0.90122000 0.38181500 0.58080800 1 - O O52 1 0.40122000 0.08080800 0.88181500 1 - O O53 1 0.98059500 0.67958800 0.09878000 1 - O O54 1 0.41919200 0.82041200 0.80100800 1 - O O55 1 0.80100800 0.88181500 0.98059500 1 - O O56 1 0.32041200 0.90122000 0.01940500 1 - O O57 1 0.19899200 0.58080800 0.17958800 1 - O O58 1 0.91919200 0.11818500 0.59878000 1 - O O59 1 0.38181500 0.30100800 0.48059500 1 - O O60 1 0.59878000 0.17958800 0.48059500 1 - O O61 1 0.30100800 0.48059500 0.38181500 1 - O O62 1 0.30100800 0.32041200 0.91919200 1 - O O63 1 0.48059500 0.38181500 0.30100800 1 - O O64 1 0.19899200 0.11818500 0.01940500 1 - O O65 1 0.58080800 0.17958800 0.19899200 1 - O O66 1 0.01940500 0.32041200 0.90122000 1 - O O67 1 0.90122000 0.01940500 0.32041200 1 - O O68 1 0.59878000 0.91919200 0.11818500 1 - O O69 1 0.11818500 0.59878000 0.91919200 1 - O O70 1 0.17958800 0.19899200 0.58080800 1 - O O71 1 0.38181500 0.58080800 0.90122000 1 - O O72 1 0.91919200 0.30100800 0.32041200 1 - O O73 1 0.17958800 0.48059500 0.59878000 1 - O O74 1 0.58080800 0.90122000 0.38181500 1 - O O75 1 0.32041200 0.91919200 0.30100800 1 - O O76 1 0.48059500 0.59878000 0.17958800 1 - O O77 1 0.01940500 0.19899200 0.11818500 1 - O O78 1 0.11818500 0.01940500 0.19899200 1 - O O79 1 0.09878000 0.98059500 0.67958800 1 -" -Tb3Fe5O12,mp-3282,R-3,"[80549, 80548, 80550]",0.024208728781250244,{'tags': ['Triterbium pentairon(III) oxide']},"Full Formula (Tb12 Fe20 O48) -Reduced Formula: Tb3Fe5O12 -abc : 10.822147 10.822147 10.822147 -angles: 109.453370 109.453370 109.453365 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tb 0.624359 0.749492 0.875696 0.043 - 1 Tb 0.749492 0.875696 0.624359 0.043 - 2 Tb 0.875696 0.624359 0.749492 0.043 - 3 Tb 0.375641 0.250508 0.124304 0.043 - 4 Tb 0.250508 0.124304 0.375641 0.043 - 5 Tb 0.124304 0.375641 0.250508 0.043 - 6 Tb 0.123014 0.749692 0.376924 0.045 - 7 Tb 0.749692 0.376924 0.123014 0.045 - 8 Tb 0.376924 0.123014 0.749692 0.045 - 9 Tb 0.876986 0.250308 0.623076 0.045 - 10 Tb 0.250308 0.623076 0.876986 0.045 - 11 Tb 0.623076 0.876986 0.250308 0.045 - 12 Fe 0 0 0 4.409 - 13 Fe 0.5 0.5 0.5 4.404 - 14 Fe 0 0.5 0.5 4.413 - 15 Fe 0.5 0.5 0 4.412 - 16 Fe 0.5 0 0.5 4.412 - 17 Fe 0.5 0 0 4.406 - 18 Fe 0 0 0.5 4.405 - 19 Fe 0 0.5 0 4.407 - 20 Fe 0.374477 0.752738 0.626677 4.277 - 21 Fe 0.752738 0.626677 0.374477 4.277 - 22 Fe 0.626677 0.374477 0.752738 4.277 - 23 Fe 0.625523 0.247262 0.373323 4.277 - 24 Fe 0.247262 0.373323 0.625523 4.277 - 25 Fe 0.373323 0.625523 0.247262 4.277 - 26 Fe 0.126971 0.249293 0.872832 4.274 - 27 Fe 0.249293 0.872832 0.126971 4.274 - 28 Fe 0.872832 0.126971 0.249293 4.274 - 29 Fe 0.873029 0.750707 0.127168 4.274 - 30 Fe 0.750707 0.127168 0.873029 4.274 - 31 Fe 0.127168 0.873029 0.750707 4.274 - 32 O 0.793935 0.972497 0.876785 0.218 - 33 O 0.972497 0.876785 0.793935 0.218 - 34 O 0.876785 0.793935 0.972497 0.218 - 35 O 0.206065 0.027503 0.123215 0.218 - 36 O 0.027503 0.123215 0.206065 0.218 - 37 O 0.123215 0.206065 0.027503 0.218 - 38 O 0.417891 0.797326 0.826607 0.217 - 39 O 0.797326 0.826607 0.417891 0.217 - 40 O 0.826607 0.417891 0.797326 0.217 - 41 O 0.582109 0.202674 0.173393 0.217 - 42 O 0.202674 0.173393 0.582109 0.217 - 43 O 0.173393 0.582109 0.202674 0.217 - 44 O 0.871428 0.085386 0.403619 0.214 - 45 O 0.085386 0.403619 0.871428 0.214 - 46 O 0.403619 0.871428 0.085386 0.214 - 47 O 0.128572 0.914614 0.596381 0.214 - 48 O 0.914614 0.596381 0.128572 0.214 - 49 O 0.596381 0.128572 0.914614 0.214 - 50 O 0.090915 0.672253 0.970595 0.214 - 51 O 0.672253 0.970595 0.090915 0.214 - 52 O 0.970595 0.090915 0.672253 0.214 - 53 O 0.909085 0.327747 0.029405 0.214 - 54 O 0.327747 0.029405 0.909085 0.214 - 55 O 0.029405 0.909085 0.327747 0.214 - 56 O 0.626234 0.529769 0.707965 0.218 - 57 O 0.529769 0.707965 0.626234 0.217 - 58 O 0.707965 0.626234 0.529769 0.217 - 59 O 0.373766 0.470231 0.292035 0.218 - 60 O 0.470231 0.292035 0.373766 0.217 - 61 O 0.292035 0.373766 0.470231 0.217 - 62 O 0.672933 0.704922 0.081456 0.216 - 63 O 0.704922 0.081456 0.672933 0.216 - 64 O 0.081456 0.672933 0.704922 0.216 - 65 O 0.327067 0.295078 0.918544 0.216 - 66 O 0.295078 0.918544 0.327067 0.216 - 67 O 0.918544 0.327067 0.295078 0.216 - 68 O 0.093177 0.419775 0.621376 0.219 - 69 O 0.419775 0.621376 0.093177 0.219 - 70 O 0.621376 0.093177 0.419775 0.22 - 71 O 0.906823 0.580225 0.378624 0.219 - 72 O 0.580225 0.378624 0.906823 0.219 - 73 O 0.378624 0.906823 0.580225 0.22 - 74 O 0.528724 0.824883 0.404828 0.214 - 75 O 0.824883 0.404828 0.528724 0.214 - 76 O 0.404828 0.528724 0.824883 0.214 - 77 O 0.471276 0.175117 0.595172 0.214 - 78 O 0.175117 0.595172 0.471276 0.214 - 79 O 0.595172 0.471276 0.175117 0.214","# generated using pymatgen -data_Tb3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.82214658 -_cell_length_b 10.82214658 -_cell_length_c 10.82214704 -_cell_angle_alpha 109.45336983 -_cell_angle_beta 109.45336983 -_cell_angle_gamma 109.45336533 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tb3Fe5O12 -_chemical_formula_sum 'Tb12 Fe20 O48' -_cell_volume 976.34899737 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tb Tb0 1 0.62435900 0.74949200 0.87569600 1 - Tb Tb1 1 0.74949200 0.87569600 0.62435900 1 - Tb Tb2 1 0.87569600 0.62435900 0.74949200 1 - Tb Tb3 1 0.37564100 0.25050800 0.12430400 1 - Tb Tb4 1 0.25050800 0.12430400 0.37564100 1 - Tb Tb5 1 0.12430400 0.37564100 0.25050800 1 - Tb Tb6 1 0.12301400 0.74969200 0.37692400 1 - Tb Tb7 1 0.74969200 0.37692400 0.12301400 1 - Tb Tb8 1 0.37692400 0.12301400 0.74969200 1 - Tb Tb9 1 0.87698600 0.25030800 0.62307600 1 - Tb Tb10 1 0.25030800 0.62307600 0.87698600 1 - Tb Tb11 1 0.62307600 0.87698600 0.25030800 1 - Fe Fe12 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe14 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe16 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe18 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.37447700 0.75273800 0.62667700 1 - Fe Fe21 1 0.75273800 0.62667700 0.37447700 1 - Fe Fe22 1 0.62667700 0.37447700 0.75273800 1 - Fe Fe23 1 0.62552300 0.24726200 0.37332300 1 - Fe Fe24 1 0.24726200 0.37332300 0.62552300 1 - Fe Fe25 1 0.37332300 0.62552300 0.24726200 1 - Fe Fe26 1 0.12697100 0.24929300 0.87283200 1 - Fe Fe27 1 0.24929300 0.87283200 0.12697100 1 - Fe Fe28 1 0.87283200 0.12697100 0.24929300 1 - Fe Fe29 1 0.87302900 0.75070700 0.12716800 1 - Fe Fe30 1 0.75070700 0.12716800 0.87302900 1 - Fe Fe31 1 0.12716800 0.87302900 0.75070700 1 - O O32 1 0.79393500 0.97249700 0.87678500 1 - O O33 1 0.97249700 0.87678500 0.79393500 1 - O O34 1 0.87678500 0.79393500 0.97249700 1 - O O35 1 0.20606500 0.02750300 0.12321500 1 - O O36 1 0.02750300 0.12321500 0.20606500 1 - O O37 1 0.12321500 0.20606500 0.02750300 1 - O O38 1 0.41789100 0.79732600 0.82660700 1 - O O39 1 0.79732600 0.82660700 0.41789100 1 - O O40 1 0.82660700 0.41789100 0.79732600 1 - O O41 1 0.58210900 0.20267400 0.17339300 1 - O O42 1 0.20267400 0.17339300 0.58210900 1 - O O43 1 0.17339300 0.58210900 0.20267400 1 - O O44 1 0.87142800 0.08538600 0.40361900 1 - O O45 1 0.08538600 0.40361900 0.87142800 1 - O O46 1 0.40361900 0.87142800 0.08538600 1 - O O47 1 0.12857200 0.91461400 0.59638100 1 - O O48 1 0.91461400 0.59638100 0.12857200 1 - O O49 1 0.59638100 0.12857200 0.91461400 1 - O O50 1 0.09091500 0.67225300 0.97059500 1 - O O51 1 0.67225300 0.97059500 0.09091500 1 - O O52 1 0.97059500 0.09091500 0.67225300 1 - O O53 1 0.90908500 0.32774700 0.02940500 1 - O O54 1 0.32774700 0.02940500 0.90908500 1 - O O55 1 0.02940500 0.90908500 0.32774700 1 - O O56 1 0.62623400 0.52976900 0.70796500 1 - O O57 1 0.52976900 0.70796500 0.62623400 1 - O O58 1 0.70796500 0.62623400 0.52976900 1 - O O59 1 0.37376600 0.47023100 0.29203500 1 - O O60 1 0.47023100 0.29203500 0.37376600 1 - O O61 1 0.29203500 0.37376600 0.47023100 1 - O O62 1 0.67293300 0.70492200 0.08145600 1 - O O63 1 0.70492200 0.08145600 0.67293300 1 - O O64 1 0.08145600 0.67293300 0.70492200 1 - O O65 1 0.32706700 0.29507800 0.91854400 1 - O O66 1 0.29507800 0.91854400 0.32706700 1 - O O67 1 0.91854400 0.32706700 0.29507800 1 - O O68 1 0.09317700 0.41977500 0.62137600 1 - O O69 1 0.41977500 0.62137600 0.09317700 1 - O O70 1 0.62137600 0.09317700 0.41977500 1 - O O71 1 0.90682300 0.58022500 0.37862400 1 - O O72 1 0.58022500 0.37862400 0.90682300 1 - O O73 1 0.37862400 0.90682300 0.58022500 1 - O O74 1 0.52872400 0.82488300 0.40482800 1 - O O75 1 0.82488300 0.40482800 0.52872400 1 - O O76 1 0.40482800 0.52872400 0.82488300 1 - O O77 1 0.47127600 0.17511700 0.59517200 1 - O O78 1 0.17511700 0.59517200 0.47127600 1 - O O79 1 0.59517200 0.47127600 0.17511700 1 -" -Tb3Fe5O12,mp-19710,Ia-3d,"[80547, 9233, 22320]",0.017940010781250848,{'tags': ['Triterbium pentairon(III) oxide']},"Full Formula (Tb12 Fe20 O48) -Reduced Formula: Tb3Fe5O12 -abc : 10.888146 10.888146 10.888146 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tb 0.625 0.25 0.875 0.041 - 1 Tb 0.25 0.875 0.625 0.041 - 2 Tb 0.625 0.875 0.75 0.041 - 3 Tb 0.375 0.75 0.125 0.041 - 4 Tb 0.75 0.125 0.375 0.041 - 5 Tb 0.375 0.125 0.25 0.041 - 6 Tb 0.125 0.25 0.375 0.041 - 7 Tb 0.25 0.375 0.125 0.042 - 8 Tb 0.125 0.375 0.75 0.041 - 9 Tb 0.875 0.75 0.625 0.041 - 10 Tb 0.75 0.625 0.875 0.042 - 11 Tb 0.875 0.625 0.25 0.041 - 12 Fe 0.5 0 0 4.408 - 13 Fe 0.5 0 0.5 4.408 - 14 Fe 0.5 0.5 0.5 4.407 - 15 Fe 0 0.5 0 4.407 - 16 Fe 0 0 0.5 4.408 - 17 Fe 0.5 0.5 0 4.407 - 18 Fe 0 0.5 0.5 4.408 - 19 Fe 0 0 0 4.407 - 20 Fe 0.375 0.25 0.625 4.275 - 21 Fe 0.25 0.625 0.375 4.275 - 22 Fe 0.875 0.125 0.75 4.275 - 23 Fe 0.625 0.75 0.375 4.275 - 24 Fe 0.75 0.375 0.625 4.275 - 25 Fe 0.125 0.875 0.25 4.275 - 26 Fe 0.125 0.75 0.875 4.275 - 27 Fe 0.75 0.875 0.125 4.275 - 28 Fe 0.625 0.375 0.25 4.275 - 29 Fe 0.875 0.25 0.125 4.275 - 30 Fe 0.25 0.125 0.875 4.275 - 31 Fe 0.375 0.625 0.75 4.275 - 32 O 0.405511 0.083302 0.877411 0.216 - 33 O 0.416698 0.822209 0.794109 0.216 - 34 O 0.677791 0.094489 0.9719 0.216 - 35 O 0.594489 0.916698 0.122589 0.216 - 36 O 0.583302 0.177791 0.205891 0.216 - 37 O 0.322209 0.905511 0.0281 0.216 - 38 O 0.5281 0.405511 0.822209 0.216 - 39 O 0.094489 0.622589 0.416698 0.216 - 40 O 0.877411 0.9719 0.794109 0.216 - 41 O 0.4719 0.594489 0.177791 0.216 - 42 O 0.905511 0.377411 0.583302 0.216 - 43 O 0.122589 0.0281 0.205891 0.216 - 44 O 0.822209 0.5281 0.405511 0.216 - 45 O 0.9719 0.794109 0.877411 0.216 - 46 O 0.705891 0.677791 0.083302 0.216 - 47 O 0.177791 0.4719 0.594489 0.216 - 48 O 0.0281 0.205891 0.122589 0.216 - 49 O 0.294109 0.322209 0.916698 0.216 - 50 O 0.794109 0.877411 0.9719 0.216 - 51 O 0.622589 0.416698 0.094489 0.216 - 52 O 0.083302 0.705891 0.677791 0.216 - 53 O 0.205891 0.122589 0.0281 0.216 - 54 O 0.377411 0.583302 0.905511 0.216 - 55 O 0.916698 0.294109 0.322209 0.216 - 56 O 0.677791 0.083302 0.705891 0.216 - 57 O 0.416698 0.094489 0.622589 0.216 - 58 O 0.405511 0.822209 0.5281 0.216 - 59 O 0.322209 0.916698 0.294109 0.216 - 60 O 0.583302 0.905511 0.377411 0.216 - 61 O 0.594489 0.177791 0.4719 0.216 - 62 O 0.877411 0.405511 0.083302 0.216 - 63 O 0.094489 0.9719 0.677791 0.216 - 64 O 0.5281 0.622589 0.705891 0.216 - 65 O 0.122589 0.594489 0.916698 0.216 - 66 O 0.905511 0.0281 0.322209 0.216 - 67 O 0.4719 0.377411 0.294109 0.216 - 68 O 0.705891 0.5281 0.622589 0.216 - 69 O 0.9719 0.677791 0.094489 0.216 - 70 O 0.822209 0.794109 0.416698 0.216 - 71 O 0.294109 0.4719 0.377411 0.216 - 72 O 0.0281 0.322209 0.905511 0.216 - 73 O 0.177791 0.205891 0.583302 0.216 - 74 O 0.083302 0.877411 0.405511 0.216 - 75 O 0.622589 0.705891 0.5281 0.216 - 76 O 0.794109 0.416698 0.822209 0.216 - 77 O 0.916698 0.122589 0.594489 0.216 - 78 O 0.377411 0.294109 0.4719 0.216 - 79 O 0.205891 0.583302 0.177791 0.216","# generated using pymatgen -data_Tb3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.88814596 -_cell_length_b 10.88814596 -_cell_length_c 10.88814596 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tb3Fe5O12 -_chemical_formula_sum 'Tb12 Fe20 O48' -_cell_volume 993.66481365 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tb Tb0 1 0.62500000 0.25000000 0.87500000 1 - Tb Tb1 1 0.25000000 0.87500000 0.62500000 1 - Tb Tb2 1 0.62500000 0.87500000 0.75000000 1 - Tb Tb3 1 0.37500000 0.75000000 0.12500000 1 - Tb Tb4 1 0.75000000 0.12500000 0.37500000 1 - Tb Tb5 1 0.37500000 0.12500000 0.25000000 1 - Tb Tb6 1 0.12500000 0.25000000 0.37500000 1 - Tb Tb7 1 0.25000000 0.37500000 0.12500000 1 - Tb Tb8 1 0.12500000 0.37500000 0.75000000 1 - Tb Tb9 1 0.87500000 0.75000000 0.62500000 1 - Tb Tb10 1 0.75000000 0.62500000 0.87500000 1 - Tb Tb11 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe12 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe13 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe14 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe15 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe18 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe19 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe20 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe21 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe22 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe23 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe24 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe25 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe26 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe27 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe28 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe29 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe30 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe31 1 0.37500000 0.62500000 0.75000000 1 - O O32 1 0.40551100 0.08330200 0.87741100 1 - O O33 1 0.41669800 0.82220900 0.79410900 1 - O O34 1 0.67779100 0.09448900 0.97190000 1 - O O35 1 0.59448900 0.91669800 0.12258900 1 - O O36 1 0.58330200 0.17779100 0.20589100 1 - O O37 1 0.32220900 0.90551100 0.02810000 1 - O O38 1 0.52810000 0.40551100 0.82220900 1 - O O39 1 0.09448900 0.62258900 0.41669800 1 - O O40 1 0.87741100 0.97190000 0.79410900 1 - O O41 1 0.47190000 0.59448900 0.17779100 1 - O O42 1 0.90551100 0.37741100 0.58330200 1 - O O43 1 0.12258900 0.02810000 0.20589100 1 - O O44 1 0.82220900 0.52810000 0.40551100 1 - O O45 1 0.97190000 0.79410900 0.87741100 1 - O O46 1 0.70589100 0.67779100 0.08330200 1 - O O47 1 0.17779100 0.47190000 0.59448900 1 - O O48 1 0.02810000 0.20589100 0.12258900 1 - O O49 1 0.29410900 0.32220900 0.91669800 1 - O O50 1 0.79410900 0.87741100 0.97190000 1 - O O51 1 0.62258900 0.41669800 0.09448900 1 - O O52 1 0.08330200 0.70589100 0.67779100 1 - O O53 1 0.20589100 0.12258900 0.02810000 1 - O O54 1 0.37741100 0.58330200 0.90551100 1 - O O55 1 0.91669800 0.29410900 0.32220900 1 - O O56 1 0.67779100 0.08330200 0.70589100 1 - O O57 1 0.41669800 0.09448900 0.62258900 1 - O O58 1 0.40551100 0.82220900 0.52810000 1 - O O59 1 0.32220900 0.91669800 0.29410900 1 - O O60 1 0.58330200 0.90551100 0.37741100 1 - O O61 1 0.59448900 0.17779100 0.47190000 1 - O O62 1 0.87741100 0.40551100 0.08330200 1 - O O63 1 0.09448900 0.97190000 0.67779100 1 - O O64 1 0.52810000 0.62258900 0.70589100 1 - O O65 1 0.12258900 0.59448900 0.91669800 1 - O O66 1 0.90551100 0.02810000 0.32220900 1 - O O67 1 0.47190000 0.37741100 0.29410900 1 - O O68 1 0.70589100 0.52810000 0.62258900 1 - O O69 1 0.97190000 0.67779100 0.09448900 1 - O O70 1 0.82220900 0.79410900 0.41669800 1 - O O71 1 0.29410900 0.47190000 0.37741100 1 - O O72 1 0.02810000 0.32220900 0.90551100 1 - O O73 1 0.17779100 0.20589100 0.58330200 1 - O O74 1 0.08330200 0.87741100 0.40551100 1 - O O75 1 0.62258900 0.70589100 0.52810000 1 - O O76 1 0.79410900 0.41669800 0.82220900 1 - O O77 1 0.91669800 0.12258900 0.59448900 1 - O O78 1 0.37741100 0.29410900 0.47190000 1 - O O79 1 0.20589100 0.58330200 0.17779100 1 -" -Tb3Ga5O12,mp-5965,Ia-3d,"[20831, 84875, 184934]",0.0,"{'tags': ['Triterbium pentagallium oxide', 'Triterbium pentagallium dodecaoxide', 'Unnamed_Garnet']}","Full Formula (Tb12 Ga20 O48) -Reduced Formula: Tb3Ga5O12 -abc : 10.776233 10.776233 10.776233 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tb 0.875 0.75 0.625 -0 - 1 Tb 0.875 0.625 0.25 -0 - 2 Tb 0.625 0.875 0.75 -0 - 3 Tb 0.25 0.875 0.625 -0 - 4 Tb 0.75 0.625 0.875 -0 - 5 Tb 0.625 0.25 0.875 -0 - 6 Tb 0.125 0.25 0.375 -0 - 7 Tb 0.125 0.375 0.75 -0 - 8 Tb 0.375 0.125 0.25 -0 - 9 Tb 0.75 0.125 0.375 -0 - 10 Tb 0.25 0.375 0.125 -0 - 11 Tb 0.375 0.75 0.125 -0 - 12 Ga 0.125 0.75 0.875 -0 - 13 Ga 0.875 0.25 0.125 -0 - 14 Ga 0.75 0.375 0.625 -0 - 15 Ga 0.125 0.875 0.25 -0 - 16 Ga 0.25 0.125 0.875 -0 - 17 Ga 0.375 0.625 0.75 -0 - 18 Ga 0.375 0.25 0.625 -0 - 19 Ga 0.875 0.125 0.75 -0 - 20 Ga 0.625 0.375 0.25 -0 - 21 Ga 0.75 0.875 0.125 -0 - 22 Ga 0.25 0.625 0.375 -0 - 23 Ga 0.625 0.75 0.375 -0 - 24 Ga 0.5 0 0.5 -0 - 25 Ga 0 0.5 0 -0 - 26 Ga 0.5 0.5 0.5 -0 - 27 Ga 0 0 0.5 -0 - 28 Ga 0 0 0 -0 - 29 Ga 0 0.5 0.5 -0 - 30 Ga 0.5 0.5 0 -0 - 31 Ga 0.5 0 0 -0 - 32 O 0.582615 0.905093 0.377053 0 - 33 O 0.377053 0.582615 0.905093 0 - 34 O 0.294438 0.322478 0.917385 0 - 35 O 0.47196 0.594907 0.177522 0 - 36 O 0.322478 0.905093 0.02804 0 - 37 O 0.122947 0.02804 0.205562 0 - 38 O 0.377053 0.294438 0.47196 0 - 39 O 0.905093 0.377053 0.582615 0 - 40 O 0.177522 0.205562 0.582615 0 - 41 O 0.47196 0.377053 0.294438 0 - 42 O 0.905093 0.02804 0.322478 0 - 43 O 0.594907 0.917385 0.122947 0 - 44 O 0.917385 0.122947 0.594907 0 - 45 O 0.294438 0.47196 0.377053 0 - 46 O 0.582615 0.177522 0.205562 0 - 47 O 0.205562 0.582615 0.177522 0 - 48 O 0.02804 0.322478 0.905093 0 - 49 O 0.917385 0.294438 0.322478 0 - 50 O 0.02804 0.205562 0.122947 0 - 51 O 0.822478 0.794438 0.417385 0 - 52 O 0.177522 0.47196 0.594907 0 - 53 O 0.594907 0.177522 0.47196 0 - 54 O 0.205562 0.122947 0.02804 0 - 55 O 0.122947 0.594907 0.917385 0 - 56 O 0.417385 0.094907 0.622947 0 - 57 O 0.622947 0.417385 0.094907 0 - 58 O 0.705562 0.677522 0.082615 0 - 59 O 0.52804 0.405093 0.822478 0 - 60 O 0.677522 0.094907 0.97196 0 - 61 O 0.877053 0.97196 0.794438 0 - 62 O 0.622947 0.705562 0.52804 0 - 63 O 0.094907 0.622947 0.417385 0 - 64 O 0.877053 0.405093 0.082615 0 - 65 O 0.794438 0.877053 0.97196 0 - 66 O 0.405093 0.822478 0.52804 0 - 67 O 0.677522 0.082615 0.705562 0 - 68 O 0.822478 0.52804 0.405093 0 - 69 O 0.97196 0.794438 0.877053 0 - 70 O 0.082615 0.705562 0.677522 0 - 71 O 0.97196 0.677522 0.094907 0 - 72 O 0.794438 0.417385 0.822478 0 - 73 O 0.417385 0.822478 0.794438 0 - 74 O 0.705562 0.52804 0.622947 0 - 75 O 0.082615 0.877053 0.405093 0 - 76 O 0.405093 0.082615 0.877053 0 - 77 O 0.094907 0.97196 0.677522 0 - 78 O 0.52804 0.622947 0.705562 0 - 79 O 0.322478 0.917385 0.294438 0","# generated using pymatgen -data_Tb3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.77623296 -_cell_length_b 10.77623296 -_cell_length_c 10.77623296 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tb3Ga5O12 -_chemical_formula_sum 'Tb12 Ga20 O48' -_cell_volume 963.33873513 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tb Tb0 1 0.87500000 0.75000000 0.62500000 1 - Tb Tb1 1 0.87500000 0.62500000 0.25000000 1 - Tb Tb2 1 0.62500000 0.87500000 0.75000000 1 - Tb Tb3 1 0.25000000 0.87500000 0.62500000 1 - Tb Tb4 1 0.75000000 0.62500000 0.87500000 1 - Tb Tb5 1 0.62500000 0.25000000 0.87500000 1 - Tb Tb6 1 0.12500000 0.25000000 0.37500000 1 - Tb Tb7 1 0.12500000 0.37500000 0.75000000 1 - Tb Tb8 1 0.37500000 0.12500000 0.25000000 1 - Tb Tb9 1 0.75000000 0.12500000 0.37500000 1 - Tb Tb10 1 0.25000000 0.37500000 0.12500000 1 - Tb Tb11 1 0.37500000 0.75000000 0.12500000 1 - Ga Ga12 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga13 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga14 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga15 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga16 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga17 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga18 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga19 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga22 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga23 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga24 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga25 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga26 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga28 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga29 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.58261500 0.90509300 0.37705300 1 - O O33 1 0.37705300 0.58261500 0.90509300 1 - O O34 1 0.29443800 0.32247800 0.91738500 1 - O O35 1 0.47196000 0.59490700 0.17752200 1 - O O36 1 0.32247800 0.90509300 0.02804000 1 - O O37 1 0.12294700 0.02804000 0.20556200 1 - O O38 1 0.37705300 0.29443800 0.47196000 1 - O O39 1 0.90509300 0.37705300 0.58261500 1 - O O40 1 0.17752200 0.20556200 0.58261500 1 - O O41 1 0.47196000 0.37705300 0.29443800 1 - O O42 1 0.90509300 0.02804000 0.32247800 1 - O O43 1 0.59490700 0.91738500 0.12294700 1 - O O44 1 0.91738500 0.12294700 0.59490700 1 - O O45 1 0.29443800 0.47196000 0.37705300 1 - O O46 1 0.58261500 0.17752200 0.20556200 1 - O O47 1 0.20556200 0.58261500 0.17752200 1 - O O48 1 0.02804000 0.32247800 0.90509300 1 - O O49 1 0.91738500 0.29443800 0.32247800 1 - O O50 1 0.02804000 0.20556200 0.12294700 1 - O O51 1 0.82247800 0.79443800 0.41738500 1 - O O52 1 0.17752200 0.47196000 0.59490700 1 - O O53 1 0.59490700 0.17752200 0.47196000 1 - O O54 1 0.20556200 0.12294700 0.02804000 1 - O O55 1 0.12294700 0.59490700 0.91738500 1 - O O56 1 0.41738500 0.09490700 0.62294700 1 - O O57 1 0.62294700 0.41738500 0.09490700 1 - O O58 1 0.70556200 0.67752200 0.08261500 1 - O O59 1 0.52804000 0.40509300 0.82247800 1 - O O60 1 0.67752200 0.09490700 0.97196000 1 - O O61 1 0.87705300 0.97196000 0.79443800 1 - O O62 1 0.62294700 0.70556200 0.52804000 1 - O O63 1 0.09490700 0.62294700 0.41738500 1 - O O64 1 0.87705300 0.40509300 0.08261500 1 - O O65 1 0.79443800 0.87705300 0.97196000 1 - O O66 1 0.40509300 0.82247800 0.52804000 1 - O O67 1 0.67752200 0.08261500 0.70556200 1 - O O68 1 0.82247800 0.52804000 0.40509300 1 - O O69 1 0.97196000 0.79443800 0.87705300 1 - O O70 1 0.08261500 0.70556200 0.67752200 1 - O O71 1 0.97196000 0.67752200 0.09490700 1 - O O72 1 0.79443800 0.41738500 0.82247800 1 - O O73 1 0.41738500 0.82247800 0.79443800 1 - O O74 1 0.70556200 0.52804000 0.62294700 1 - O O75 1 0.08261500 0.87705300 0.40509300 1 - O O76 1 0.40509300 0.08261500 0.87705300 1 - O O77 1 0.09490700 0.97196000 0.67752200 1 - O O78 1 0.52804000 0.62294700 0.70556200 1 - O O79 1 0.32247800 0.91738500 0.29443800 1 -" -Tm3Al5O12,mp-1208102,Ia-3d,[],0.0,"{'tags': ['Y3Al5O12', 'garnet family', 'Tm3Al5O12']}","Full Formula (Tm12 Al20 O48) -Reduced Formula: Tm3Al5O12 -abc : 10.410415 10.410415 10.410415 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tm 0.25 0.375 0.125 -0 - 1 Tm 0.75 0.625 0.875 0 - 2 Tm 0.75 0.125 0.375 -0 - 3 Tm 0.125 0.25 0.375 -0 - 4 Tm 0.375 0.75 0.125 0 - 5 Tm 0.25 0.875 0.625 0 - 6 Tm 0.875 0.75 0.625 0 - 7 Tm 0.625 0.25 0.875 0 - 8 Tm 0.375 0.125 0.25 0 - 9 Tm 0.625 0.875 0.75 0 - 10 Tm 0.125 0.375 0.75 -0 - 11 Tm 0.875 0.625 0.25 0 - 12 Al 0.25 0.625 0.375 -0 - 13 Al 0.75 0.375 0.625 -0 - 14 Al 0.75 0.875 0.125 -0 - 15 Al 0.375 0.25 0.625 -0 - 16 Al 0.625 0.75 0.375 -0 - 17 Al 0.25 0.125 0.875 -0 - 18 Al 0.125 0.75 0.875 -0 - 19 Al 0.875 0.25 0.125 -0 - 20 Al 0.625 0.375 0.25 -0 - 21 Al 0.375 0.625 0.75 -0 - 22 Al 0.875 0.125 0.75 -0 - 23 Al 0.125 0.875 0.25 -0 - 24 Al 0 0 0 -0 - 25 Al 0.5 0 0.5 0 - 26 Al 0 0.5 0.5 0 - 27 Al 0.5 0 0 0 - 28 Al 0.5 0.5 0 -0 - 29 Al 0.5 0.5 0.5 -0 - 30 Al 0 0 0.5 -0 - 31 Al 0 0.5 0 -0 - 32 O 0.477324 0.379862 0.298266 -0 - 33 O 0.522676 0.620138 0.701734 -0 - 34 O 0.581596 0.179059 0.201734 -0 - 35 O 0.918404 0.120138 0.597463 -0 - 36 O 0.298266 0.477324 0.379862 -0 - 37 O 0.320941 0.918404 0.298266 -0 - 38 O 0.418404 0.820941 0.798266 -0 - 39 O 0.081596 0.879862 0.402537 -0 - 40 O 0.701734 0.522676 0.620138 -0 - 41 O 0.679059 0.081596 0.701734 -0 - 42 O 0.022676 0.320941 0.902537 -0 - 43 O 0.201734 0.581596 0.179059 -0 - 44 O 0.120138 0.022676 0.201734 -0 - 45 O 0.977324 0.679059 0.097463 -0 - 46 O 0.798266 0.418404 0.820941 -0 - 47 O 0.879862 0.977324 0.798266 0 - 48 O 0.597463 0.918404 0.120138 -0 - 49 O 0.179059 0.477324 0.597463 -0 - 50 O 0.402537 0.081596 0.879862 -0 - 51 O 0.820941 0.522676 0.402537 -0 - 52 O 0.902537 0.022676 0.320941 -0 - 53 O 0.379862 0.581596 0.902537 -0 - 54 O 0.097463 0.977324 0.679059 -0 - 55 O 0.620138 0.418404 0.097463 -0 - 56 O 0.379862 0.298266 0.477324 -0 - 57 O 0.581596 0.902537 0.379862 -0 - 58 O 0.620138 0.701734 0.522676 -0 - 59 O 0.418404 0.097463 0.620138 -0 - 60 O 0.120138 0.597463 0.918404 -0 - 61 O 0.022676 0.201734 0.120138 -0 - 62 O 0.879862 0.402537 0.081596 -0 - 63 O 0.977324 0.798266 0.879862 -0 - 64 O 0.320941 0.902537 0.022676 -0 - 65 O 0.918404 0.298266 0.320941 -0 - 66 O 0.679059 0.097463 0.977324 -0 - 67 O 0.081596 0.701734 0.679059 -0 - 68 O 0.179059 0.201734 0.581596 -0 - 69 O 0.477324 0.597463 0.179059 -0 - 70 O 0.820941 0.798266 0.418404 -0 - 71 O 0.522676 0.402537 0.820941 -0 - 72 O 0.298266 0.320941 0.918404 -0 - 73 O 0.701734 0.679059 0.081596 -0 - 74 O 0.201734 0.120138 0.022676 -0 - 75 O 0.798266 0.879862 0.977324 -0 - 76 O 0.902537 0.379862 0.581596 -0 - 77 O 0.097463 0.620138 0.418404 -0 - 78 O 0.597463 0.179059 0.477324 -0 - 79 O 0.402537 0.820941 0.522676 -0","# generated using pymatgen -data_Tm3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.41041517 -_cell_length_b 10.41041517 -_cell_length_c 10.41041517 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tm3Al5O12 -_chemical_formula_sum 'Tm12 Al20 O48' -_cell_volume 868.52486818 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tm Tm0 1 0.25000000 0.37500000 0.12500000 1 - Tm Tm1 1 0.75000000 0.62500000 0.87500000 1 - Tm Tm2 1 0.75000000 0.12500000 0.37500000 1 - Tm Tm3 1 0.12500000 0.25000000 0.37500000 1 - Tm Tm4 1 0.37500000 0.75000000 0.12500000 1 - Tm Tm5 1 0.25000000 0.87500000 0.62500000 1 - Tm Tm6 1 0.87500000 0.75000000 0.62500000 1 - Tm Tm7 1 0.62500000 0.25000000 0.87500000 1 - Tm Tm8 1 0.37500000 0.12500000 0.25000000 1 - Tm Tm9 1 0.62500000 0.87500000 0.75000000 1 - Tm Tm10 1 0.12500000 0.37500000 0.75000000 1 - Tm Tm11 1 0.87500000 0.62500000 0.25000000 1 - Al Al12 1 0.25000000 0.62500000 0.37500000 1 - Al Al13 1 0.75000000 0.37500000 0.62500000 1 - Al Al14 1 0.75000000 0.87500000 0.12500000 1 - Al Al15 1 0.37500000 0.25000000 0.62500000 1 - Al Al16 1 0.62500000 0.75000000 0.37500000 1 - Al Al17 1 0.25000000 0.12500000 0.87500000 1 - Al Al18 1 0.12500000 0.75000000 0.87500000 1 - Al Al19 1 0.87500000 0.25000000 0.12500000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.37500000 0.62500000 0.75000000 1 - Al Al22 1 0.87500000 0.12500000 0.75000000 1 - Al Al23 1 0.12500000 0.87500000 0.25000000 1 - Al Al24 1 0.00000000 0.00000000 0.00000000 1 - Al Al25 1 0.50000000 0.00000000 0.50000000 1 - Al Al26 1 0.00000000 0.50000000 0.50000000 1 - Al Al27 1 0.50000000 0.00000000 0.00000000 1 - Al Al28 1 0.50000000 0.50000000 0.00000000 1 - Al Al29 1 0.50000000 0.50000000 0.50000000 1 - Al Al30 1 0.00000000 0.00000000 0.50000000 1 - Al Al31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.47732400 0.37986200 0.29826600 1 - O O33 1 0.52267600 0.62013800 0.70173400 1 - O O34 1 0.58159600 0.17905900 0.20173400 1 - O O35 1 0.91840400 0.12013800 0.59746300 1 - O O36 1 0.29826600 0.47732400 0.37986200 1 - O O37 1 0.32094100 0.91840400 0.29826600 1 - O O38 1 0.41840400 0.82094100 0.79826600 1 - O O39 1 0.08159600 0.87986200 0.40253700 1 - O O40 1 0.70173400 0.52267600 0.62013800 1 - O O41 1 0.67905900 0.08159600 0.70173400 1 - O O42 1 0.02267600 0.32094100 0.90253700 1 - O O43 1 0.20173400 0.58159600 0.17905900 1 - O O44 1 0.12013800 0.02267600 0.20173400 1 - O O45 1 0.97732400 0.67905900 0.09746300 1 - O O46 1 0.79826600 0.41840400 0.82094100 1 - O O47 1 0.87986200 0.97732400 0.79826600 1 - O O48 1 0.59746300 0.91840400 0.12013800 1 - O O49 1 0.17905900 0.47732400 0.59746300 1 - O O50 1 0.40253700 0.08159600 0.87986200 1 - O O51 1 0.82094100 0.52267600 0.40253700 1 - O O52 1 0.90253700 0.02267600 0.32094100 1 - O O53 1 0.37986200 0.58159600 0.90253700 1 - O O54 1 0.09746300 0.97732400 0.67905900 1 - O O55 1 0.62013800 0.41840400 0.09746300 1 - O O56 1 0.37986200 0.29826600 0.47732400 1 - O O57 1 0.58159600 0.90253700 0.37986200 1 - O O58 1 0.62013800 0.70173400 0.52267600 1 - O O59 1 0.41840400 0.09746300 0.62013800 1 - O O60 1 0.12013800 0.59746300 0.91840400 1 - O O61 1 0.02267600 0.20173400 0.12013800 1 - O O62 1 0.87986200 0.40253700 0.08159600 1 - O O63 1 0.97732400 0.79826600 0.87986200 1 - O O64 1 0.32094100 0.90253700 0.02267600 1 - O O65 1 0.91840400 0.29826600 0.32094100 1 - O O66 1 0.67905900 0.09746300 0.97732400 1 - O O67 1 0.08159600 0.70173400 0.67905900 1 - O O68 1 0.17905900 0.20173400 0.58159600 1 - O O69 1 0.47732400 0.59746300 0.17905900 1 - O O70 1 0.82094100 0.79826600 0.41840400 1 - O O71 1 0.52267600 0.40253700 0.82094100 1 - O O72 1 0.29826600 0.32094100 0.91840400 1 - O O73 1 0.70173400 0.67905900 0.08159600 1 - O O74 1 0.20173400 0.12013800 0.02267600 1 - O O75 1 0.79826600 0.87986200 0.97732400 1 - O O76 1 0.90253700 0.37986200 0.58159600 1 - O O77 1 0.09746300 0.62013800 0.41840400 1 - O O78 1 0.59746300 0.17905900 0.47732400 1 - O O79 1 0.40253700 0.82094100 0.52267600 1 -" -Tm3Fe5O12,mp-1208209,Ia-3d,[],0.04404173168749814,"{'tags': ['Y3Al5O12', 'garnet family', 'Tm3Fe5O12']}","Full Formula (Tm12 Fe20 O48) -Reduced Formula: Tm3Fe5O12 -abc : 10.784497 10.784497 10.784497 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tm 0.25 0.375 0.125 0.052 - 1 Tm 0.75 0.625 0.875 0.052 - 2 Tm 0.75 0.125 0.375 0.051 - 3 Tm 0.125 0.25 0.375 0.051 - 4 Tm 0.375 0.75 0.125 0.051 - 5 Tm 0.25 0.875 0.625 0.051 - 6 Tm 0.875 0.75 0.625 0.051 - 7 Tm 0.625 0.25 0.875 0.051 - 8 Tm 0.375 0.125 0.25 0.051 - 9 Tm 0.625 0.875 0.75 0.051 - 10 Tm 0.125 0.375 0.75 0.051 - 11 Tm 0.875 0.625 0.25 0.051 - 12 Fe 0.25 0.625 0.375 4.275 - 13 Fe 0.75 0.375 0.625 4.275 - 14 Fe 0.75 0.875 0.125 4.275 - 15 Fe 0.375 0.25 0.625 4.274 - 16 Fe 0.625 0.75 0.375 4.274 - 17 Fe 0.25 0.125 0.875 4.275 - 18 Fe 0.125 0.75 0.875 4.274 - 19 Fe 0.875 0.25 0.125 4.274 - 20 Fe 0.625 0.375 0.25 4.274 - 21 Fe 0.375 0.625 0.75 4.274 - 22 Fe 0.875 0.125 0.75 4.274 - 23 Fe 0.125 0.875 0.25 4.274 - 24 Fe 0 0 0 4.399 - 25 Fe 0.5 0 0.5 4.401 - 26 Fe 0 0.5 0.5 4.401 - 27 Fe 0.5 0 0 4.401 - 28 Fe 0.5 0.5 0 4.399 - 29 Fe 0.5 0.5 0.5 4.399 - 30 Fe 0 0 0.5 4.401 - 31 Fe 0 0.5 0 4.399 - 32 O 0.465978 0.372919 0.289414 0.218 - 33 O 0.534022 0.627081 0.710586 0.218 - 34 O 0.583505 0.176564 0.210586 0.217 - 35 O 0.916495 0.127081 0.593059 0.217 - 36 O 0.289414 0.465978 0.372919 0.218 - 37 O 0.323436 0.916495 0.289414 0.218 - 38 O 0.416495 0.823436 0.789414 0.217 - 39 O 0.083505 0.872919 0.406941 0.217 - 40 O 0.710586 0.534022 0.627081 0.218 - 41 O 0.676564 0.083505 0.710586 0.218 - 42 O 0.034022 0.323436 0.906941 0.218 - 43 O 0.210586 0.583505 0.176564 0.218 - 44 O 0.127081 0.034022 0.210586 0.218 - 45 O 0.965978 0.676564 0.093059 0.218 - 46 O 0.789414 0.416495 0.823436 0.218 - 47 O 0.872919 0.965978 0.789414 0.218 - 48 O 0.593059 0.916495 0.127081 0.218 - 49 O 0.176564 0.465978 0.593059 0.218 - 50 O 0.406941 0.083505 0.872919 0.218 - 51 O 0.823436 0.534022 0.406941 0.218 - 52 O 0.906941 0.034022 0.323436 0.218 - 53 O 0.372919 0.583505 0.906941 0.218 - 54 O 0.093059 0.965978 0.676564 0.218 - 55 O 0.627081 0.416495 0.093059 0.218 - 56 O 0.372919 0.289414 0.465978 0.218 - 57 O 0.583505 0.906941 0.372919 0.217 - 58 O 0.627081 0.710586 0.534022 0.218 - 59 O 0.416495 0.093059 0.627081 0.217 - 60 O 0.127081 0.593059 0.916495 0.218 - 61 O 0.034022 0.210586 0.127081 0.218 - 62 O 0.872919 0.406941 0.083505 0.218 - 63 O 0.965978 0.789414 0.872919 0.218 - 64 O 0.323436 0.906941 0.034022 0.218 - 65 O 0.916495 0.289414 0.323436 0.217 - 66 O 0.676564 0.093059 0.965978 0.218 - 67 O 0.083505 0.710586 0.676564 0.217 - 68 O 0.176564 0.210586 0.583505 0.218 - 69 O 0.465978 0.593059 0.176564 0.218 - 70 O 0.823436 0.789414 0.416495 0.218 - 71 O 0.534022 0.406941 0.823436 0.218 - 72 O 0.289414 0.323436 0.916495 0.218 - 73 O 0.710586 0.676564 0.083505 0.218 - 74 O 0.210586 0.127081 0.034022 0.218 - 75 O 0.789414 0.872919 0.965978 0.218 - 76 O 0.906941 0.372919 0.583505 0.218 - 77 O 0.093059 0.627081 0.416495 0.218 - 78 O 0.593059 0.176564 0.465978 0.218 - 79 O 0.406941 0.823436 0.534022 0.218","# generated using pymatgen -data_Tm3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.78449657 -_cell_length_b 10.78449657 -_cell_length_c 10.78449657 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tm3Fe5O12 -_chemical_formula_sum 'Tm12 Fe20 O48' -_cell_volume 965.55660643 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tm Tm0 1 0.25000000 0.37500000 0.12500000 1 - Tm Tm1 1 0.75000000 0.62500000 0.87500000 1 - Tm Tm2 1 0.75000000 0.12500000 0.37500000 1 - Tm Tm3 1 0.12500000 0.25000000 0.37500000 1 - Tm Tm4 1 0.37500000 0.75000000 0.12500000 1 - Tm Tm5 1 0.25000000 0.87500000 0.62500000 1 - Tm Tm6 1 0.87500000 0.75000000 0.62500000 1 - Tm Tm7 1 0.62500000 0.25000000 0.87500000 1 - Tm Tm8 1 0.37500000 0.12500000 0.25000000 1 - Tm Tm9 1 0.62500000 0.87500000 0.75000000 1 - Tm Tm10 1 0.12500000 0.37500000 0.75000000 1 - Tm Tm11 1 0.87500000 0.62500000 0.25000000 1 - Fe Fe12 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe13 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe14 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe15 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe16 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe17 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe18 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe19 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe20 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe21 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe22 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe23 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe24 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe25 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe26 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe27 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe28 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe29 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe30 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.46597800 0.37291900 0.28941400 1 - O O33 1 0.53402200 0.62708100 0.71058600 1 - O O34 1 0.58350500 0.17656400 0.21058600 1 - O O35 1 0.91649500 0.12708100 0.59305900 1 - O O36 1 0.28941400 0.46597800 0.37291900 1 - O O37 1 0.32343600 0.91649500 0.28941400 1 - O O38 1 0.41649500 0.82343600 0.78941400 1 - O O39 1 0.08350500 0.87291900 0.40694100 1 - O O40 1 0.71058600 0.53402200 0.62708100 1 - O O41 1 0.67656400 0.08350500 0.71058600 1 - O O42 1 0.03402200 0.32343600 0.90694100 1 - O O43 1 0.21058600 0.58350500 0.17656400 1 - O O44 1 0.12708100 0.03402200 0.21058600 1 - O O45 1 0.96597800 0.67656400 0.09305900 1 - O O46 1 0.78941400 0.41649500 0.82343600 1 - O O47 1 0.87291900 0.96597800 0.78941400 1 - O O48 1 0.59305900 0.91649500 0.12708100 1 - O O49 1 0.17656400 0.46597800 0.59305900 1 - O O50 1 0.40694100 0.08350500 0.87291900 1 - O O51 1 0.82343600 0.53402200 0.40694100 1 - O O52 1 0.90694100 0.03402200 0.32343600 1 - O O53 1 0.37291900 0.58350500 0.90694100 1 - O O54 1 0.09305900 0.96597800 0.67656400 1 - O O55 1 0.62708100 0.41649500 0.09305900 1 - O O56 1 0.37291900 0.28941400 0.46597800 1 - O O57 1 0.58350500 0.90694100 0.37291900 1 - O O58 1 0.62708100 0.71058600 0.53402200 1 - O O59 1 0.41649500 0.09305900 0.62708100 1 - O O60 1 0.12708100 0.59305900 0.91649500 1 - O O61 1 0.03402200 0.21058600 0.12708100 1 - O O62 1 0.87291900 0.40694100 0.08350500 1 - O O63 1 0.96597800 0.78941400 0.87291900 1 - O O64 1 0.32343600 0.90694100 0.03402200 1 - O O65 1 0.91649500 0.28941400 0.32343600 1 - O O66 1 0.67656400 0.09305900 0.96597800 1 - O O67 1 0.08350500 0.71058600 0.67656400 1 - O O68 1 0.17656400 0.21058600 0.58350500 1 - O O69 1 0.46597800 0.59305900 0.17656400 1 - O O70 1 0.82343600 0.78941400 0.41649500 1 - O O71 1 0.53402200 0.40694100 0.82343600 1 - O O72 1 0.28941400 0.32343600 0.91649500 1 - O O73 1 0.71058600 0.67656400 0.08350500 1 - O O74 1 0.21058600 0.12708100 0.03402200 1 - O O75 1 0.78941400 0.87291900 0.96597800 1 - O O76 1 0.90694100 0.37291900 0.58350500 1 - O O77 1 0.09305900 0.62708100 0.41649500 1 - O O78 1 0.59305900 0.17656400 0.46597800 1 - O O79 1 0.40694100 0.82343600 0.53402200 1 -" -Tm3Ga5O12,mp-1208125,Ia-3d,[],0.0,"{'tags': ['Tm3Ga5O12', 'Y3Al5O12', 'garnet family']}","Full Formula (Tm12 Ga20 O48) -Reduced Formula: Tm3Ga5O12 -abc : 10.663035 10.663035 10.663035 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Tm 0.25 0.375 0.125 0 - 1 Tm 0.75 0.625 0.875 0 - 2 Tm 0.75 0.125 0.375 0 - 3 Tm 0.125 0.25 0.375 0 - 4 Tm 0.375 0.75 0.125 0 - 5 Tm 0.25 0.875 0.625 0 - 6 Tm 0.875 0.75 0.625 0 - 7 Tm 0.625 0.25 0.875 0 - 8 Tm 0.375 0.125 0.25 0 - 9 Tm 0.625 0.875 0.75 0 - 10 Tm 0.125 0.375 0.75 0 - 11 Tm 0.875 0.625 0.25 0 - 12 Ga 0.25 0.625 0.375 0 - 13 Ga 0.75 0.375 0.625 0 - 14 Ga 0.75 0.875 0.125 0 - 15 Ga 0.375 0.25 0.625 0 - 16 Ga 0.625 0.75 0.375 0 - 17 Ga 0.25 0.125 0.875 0 - 18 Ga 0.125 0.75 0.875 0 - 19 Ga 0.875 0.25 0.125 0 - 20 Ga 0.625 0.375 0.25 0 - 21 Ga 0.375 0.625 0.75 0 - 22 Ga 0.875 0.125 0.75 0 - 23 Ga 0.125 0.875 0.25 0 - 24 Ga 0 0 0 0 - 25 Ga 0.5 0 0.5 0 - 26 Ga 0 0.5 0.5 0 - 27 Ga 0.5 0 0 0 - 28 Ga 0.5 0.5 0 0 - 29 Ga 0.5 0.5 0.5 0 - 30 Ga 0 0 0.5 0 - 31 Ga 0 0.5 0 0 - 32 O 0.469374 0.374559 0.292613 -0 - 33 O 0.530626 0.625441 0.707387 -0 - 34 O 0.581946 0.17676 0.207387 -0 - 35 O 0.918054 0.125441 0.594815 -0 - 36 O 0.292613 0.469374 0.374559 -0 - 37 O 0.32324 0.918054 0.292613 -0 - 38 O 0.418054 0.82324 0.792613 -0 - 39 O 0.081946 0.874559 0.405185 -0 - 40 O 0.707387 0.530626 0.625441 -0 - 41 O 0.67676 0.081946 0.707387 -0 - 42 O 0.030626 0.32324 0.905185 -0 - 43 O 0.207387 0.581946 0.17676 -0 - 44 O 0.125441 0.030626 0.207387 -0 - 45 O 0.969374 0.67676 0.094815 -0 - 46 O 0.792613 0.418054 0.82324 -0 - 47 O 0.874559 0.969374 0.792613 -0 - 48 O 0.594815 0.918054 0.125441 -0 - 49 O 0.17676 0.469374 0.594815 -0 - 50 O 0.405185 0.081946 0.874559 -0 - 51 O 0.82324 0.530626 0.405185 -0 - 52 O 0.905185 0.030626 0.32324 -0 - 53 O 0.374559 0.581946 0.905185 -0 - 54 O 0.094815 0.969374 0.67676 -0 - 55 O 0.625441 0.418054 0.094815 -0 - 56 O 0.374559 0.292613 0.469374 -0 - 57 O 0.581946 0.905185 0.374559 -0 - 58 O 0.625441 0.707387 0.530626 -0 - 59 O 0.418054 0.094815 0.625441 -0 - 60 O 0.125441 0.594815 0.918054 -0 - 61 O 0.030626 0.207387 0.125441 -0 - 62 O 0.874559 0.405185 0.081946 -0 - 63 O 0.969374 0.792613 0.874559 -0 - 64 O 0.32324 0.905185 0.030626 -0 - 65 O 0.918054 0.292613 0.32324 -0 - 66 O 0.67676 0.094815 0.969374 -0 - 67 O 0.081946 0.707387 0.67676 -0 - 68 O 0.17676 0.207387 0.581946 -0 - 69 O 0.469374 0.594815 0.17676 -0 - 70 O 0.82324 0.792613 0.418054 -0 - 71 O 0.530626 0.405185 0.82324 -0 - 72 O 0.292613 0.32324 0.918054 -0 - 73 O 0.707387 0.67676 0.081946 -0 - 74 O 0.207387 0.125441 0.030626 -0 - 75 O 0.792613 0.874559 0.969374 -0 - 76 O 0.905185 0.374559 0.581946 -0 - 77 O 0.094815 0.625441 0.418054 -0 - 78 O 0.594815 0.17676 0.469374 -0 - 79 O 0.405185 0.82324 0.530626 -0","# generated using pymatgen -data_Tm3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.66303478 -_cell_length_b 10.66303478 -_cell_length_c 10.66303478 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Tm3Ga5O12 -_chemical_formula_sum 'Tm12 Ga20 O48' -_cell_volume 933.29853993 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Tm Tm0 1 0.25000000 0.37500000 0.12500000 1 - Tm Tm1 1 0.75000000 0.62500000 0.87500000 1 - Tm Tm2 1 0.75000000 0.12500000 0.37500000 1 - Tm Tm3 1 0.12500000 0.25000000 0.37500000 1 - Tm Tm4 1 0.37500000 0.75000000 0.12500000 1 - Tm Tm5 1 0.25000000 0.87500000 0.62500000 1 - Tm Tm6 1 0.87500000 0.75000000 0.62500000 1 - Tm Tm7 1 0.62500000 0.25000000 0.87500000 1 - Tm Tm8 1 0.37500000 0.12500000 0.25000000 1 - Tm Tm9 1 0.62500000 0.87500000 0.75000000 1 - Tm Tm10 1 0.12500000 0.37500000 0.75000000 1 - Tm Tm11 1 0.87500000 0.62500000 0.25000000 1 - Ga Ga12 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga13 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga14 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga15 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga16 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga17 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga18 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga19 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga22 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga23 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga24 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga25 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga26 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga28 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga29 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga31 1 0.00000000 0.50000000 0.00000000 1 - O O32 1 0.46937400 0.37455900 0.29261300 1 - O O33 1 0.53062600 0.62544100 0.70738700 1 - O O34 1 0.58194600 0.17676000 0.20738700 1 - O O35 1 0.91805400 0.12544100 0.59481500 1 - O O36 1 0.29261300 0.46937400 0.37455900 1 - O O37 1 0.32324000 0.91805400 0.29261300 1 - O O38 1 0.41805400 0.82324000 0.79261300 1 - O O39 1 0.08194600 0.87455900 0.40518500 1 - O O40 1 0.70738700 0.53062600 0.62544100 1 - O O41 1 0.67676000 0.08194600 0.70738700 1 - O O42 1 0.03062600 0.32324000 0.90518500 1 - O O43 1 0.20738700 0.58194600 0.17676000 1 - O O44 1 0.12544100 0.03062600 0.20738700 1 - O O45 1 0.96937400 0.67676000 0.09481500 1 - O O46 1 0.79261300 0.41805400 0.82324000 1 - O O47 1 0.87455900 0.96937400 0.79261300 1 - O O48 1 0.59481500 0.91805400 0.12544100 1 - O O49 1 0.17676000 0.46937400 0.59481500 1 - O O50 1 0.40518500 0.08194600 0.87455900 1 - O O51 1 0.82324000 0.53062600 0.40518500 1 - O O52 1 0.90518500 0.03062600 0.32324000 1 - O O53 1 0.37455900 0.58194600 0.90518500 1 - O O54 1 0.09481500 0.96937400 0.67676000 1 - O O55 1 0.62544100 0.41805400 0.09481500 1 - O O56 1 0.37455900 0.29261300 0.46937400 1 - O O57 1 0.58194600 0.90518500 0.37455900 1 - O O58 1 0.62544100 0.70738700 0.53062600 1 - O O59 1 0.41805400 0.09481500 0.62544100 1 - O O60 1 0.12544100 0.59481500 0.91805400 1 - O O61 1 0.03062600 0.20738700 0.12544100 1 - O O62 1 0.87455900 0.40518500 0.08194600 1 - O O63 1 0.96937400 0.79261300 0.87455900 1 - O O64 1 0.32324000 0.90518500 0.03062600 1 - O O65 1 0.91805400 0.29261300 0.32324000 1 - O O66 1 0.67676000 0.09481500 0.96937400 1 - O O67 1 0.08194600 0.70738700 0.67676000 1 - O O68 1 0.17676000 0.20738700 0.58194600 1 - O O69 1 0.46937400 0.59481500 0.17676000 1 - O O70 1 0.82324000 0.79261300 0.41805400 1 - O O71 1 0.53062600 0.40518500 0.82324000 1 - O O72 1 0.29261300 0.32324000 0.91805400 1 - O O73 1 0.70738700 0.67676000 0.08194600 1 - O O74 1 0.20738700 0.12544100 0.03062600 1 - O O75 1 0.79261300 0.87455900 0.96937400 1 - O O76 1 0.90518500 0.37455900 0.58194600 1 - O O77 1 0.09481500 0.62544100 0.41805400 1 - O O78 1 0.59481500 0.17676000 0.46937400 1 - O O79 1 0.40518500 0.82324000 0.53062600 1 -" -Y3Al5O12,mp-3050,Ia-3d,"[41144, 67102, 31496, 23848, 41145, 93635, 16825, 20090, 170158, 236589, 93634, 67103, 74607, 170157, 280104]",0.0,"{'tags': ['Triyttrium aluminium oxide', 'Garnet (YAG)', 'Garnet', 'Triyttrium dialuminium tris(aluminate)', 'Triyttrium pentaaluminium dodecaoxide', 'Unnamed_Garnet', 'Pentaaluminium Triyttrium oxide', 'Pentaaluminium triyttrium oxide', 'Triyttrium pentaaluminium oxide']}","Full Formula (Y12 Al20 O48) -Reduced Formula: Y3Al5O12 -abc : 10.503302 10.503302 10.503302 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.875 0.75 0.625 0 - 1 Y 0.875 0.625 0.25 0 - 2 Y 0.625 0.875 0.75 0 - 3 Y 0.25 0.875 0.625 0 - 4 Y 0.75 0.625 0.875 0 - 5 Y 0.625 0.25 0.875 0 - 6 Y 0.125 0.25 0.375 0 - 7 Y 0.125 0.375 0.75 0 - 8 Y 0.375 0.125 0.25 0 - 9 Y 0.75 0.125 0.375 0 - 10 Y 0.25 0.375 0.125 0 - 11 Y 0.375 0.75 0.125 0 - 12 Al 0.125 0.75 0.875 0 - 13 Al 0.875 0.25 0.125 0 - 14 Al 0.75 0.375 0.625 0 - 15 Al 0.125 0.875 0.25 0 - 16 Al 0.25 0.125 0.875 0 - 17 Al 0.375 0.625 0.75 0 - 18 Al 0.375 0.25 0.625 0 - 19 Al 0.875 0.125 0.75 0 - 20 Al 0.625 0.375 0.25 0 - 21 Al 0.75 0.875 0.125 0 - 22 Al 0.25 0.625 0.375 0 - 23 Al 0.625 0.75 0.375 0 - 24 Al 0.5 0 0.5 0 - 25 Al 0 0.5 0 0 - 26 Al 0.5 0.5 0.5 0 - 27 Al 0 0 0.5 0 - 28 Al 0 0 0 0 - 29 Al 0 0.5 0.5 0 - 30 Al 0.5 0.5 0 0 - 31 Al 0.5 0 0 0 - 32 O 0.881486 0.401147 0.080629 0 - 33 O 0.080629 0.881486 0.401147 0 - 34 O 0.699143 0.519661 0.618514 0 - 35 O 0.679482 0.098853 0.980339 0 - 36 O 0.519661 0.401147 0.820518 0 - 37 O 0.419371 0.820518 0.800857 0 - 38 O 0.080629 0.699143 0.679482 0 - 39 O 0.401147 0.080629 0.881486 0 - 40 O 0.980339 0.800857 0.881486 0 - 41 O 0.679482 0.080629 0.699143 0 - 42 O 0.401147 0.820518 0.519661 0 - 43 O 0.098853 0.618514 0.419371 0 - 44 O 0.618514 0.419371 0.098853 0 - 45 O 0.699143 0.679482 0.080629 0 - 46 O 0.881486 0.980339 0.800857 0 - 47 O 0.800857 0.881486 0.980339 0 - 48 O 0.820518 0.519661 0.401147 0 - 49 O 0.618514 0.699143 0.519661 0 - 50 O 0.820518 0.800857 0.419371 0 - 51 O 0.019661 0.199143 0.118514 0 - 52 O 0.980339 0.679482 0.098853 0 - 53 O 0.098853 0.980339 0.679482 0 - 54 O 0.800857 0.419371 0.820518 0 - 55 O 0.419371 0.098853 0.618514 0 - 56 O 0.118514 0.598853 0.919371 0 - 57 O 0.919371 0.118514 0.598853 0 - 58 O 0.300857 0.480339 0.381486 0 - 59 O 0.320518 0.901147 0.019661 0 - 60 O 0.480339 0.598853 0.179482 0 - 61 O 0.580629 0.179482 0.199143 0 - 62 O 0.919371 0.300857 0.320518 0 - 63 O 0.598853 0.919371 0.118514 0 - 64 O 0.580629 0.901147 0.381486 0 - 65 O 0.199143 0.580629 0.179482 0 - 66 O 0.901147 0.019661 0.320518 0 - 67 O 0.480339 0.381486 0.300857 0 - 68 O 0.019661 0.320518 0.901147 0 - 69 O 0.179482 0.199143 0.580629 0 - 70 O 0.381486 0.300857 0.480339 0 - 71 O 0.179482 0.480339 0.598853 0 - 72 O 0.199143 0.118514 0.019661 0 - 73 O 0.118514 0.019661 0.199143 0 - 74 O 0.300857 0.320518 0.919371 0 - 75 O 0.381486 0.580629 0.901147 0 - 76 O 0.901147 0.381486 0.580629 0 - 77 O 0.598853 0.179482 0.480339 0 - 78 O 0.320518 0.919371 0.300857 0 - 79 O 0.519661 0.618514 0.699143 0","# generated using pymatgen -data_Y3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.50330159 -_cell_length_b 10.50330159 -_cell_length_c 10.50330159 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Al5O12 -_chemical_formula_sum 'Y12 Al20 O48' -_cell_volume 891.98102736 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.87500000 0.75000000 0.62500000 1 - Y Y1 1 0.87500000 0.62500000 0.25000000 1 - Y Y2 1 0.62500000 0.87500000 0.75000000 1 - Y Y3 1 0.25000000 0.87500000 0.62500000 1 - Y Y4 1 0.75000000 0.62500000 0.87500000 1 - Y Y5 1 0.62500000 0.25000000 0.87500000 1 - Y Y6 1 0.12500000 0.25000000 0.37500000 1 - Y Y7 1 0.12500000 0.37500000 0.75000000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.75000000 0.12500000 0.37500000 1 - Y Y10 1 0.25000000 0.37500000 0.12500000 1 - Y Y11 1 0.37500000 0.75000000 0.12500000 1 - Al Al12 1 0.12500000 0.75000000 0.87500000 1 - Al Al13 1 0.87500000 0.25000000 0.12500000 1 - Al Al14 1 0.75000000 0.37500000 0.62500000 1 - Al Al15 1 0.12500000 0.87500000 0.25000000 1 - Al Al16 1 0.25000000 0.12500000 0.87500000 1 - Al Al17 1 0.37500000 0.62500000 0.75000000 1 - Al Al18 1 0.37500000 0.25000000 0.62500000 1 - Al Al19 1 0.87500000 0.12500000 0.75000000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.75000000 0.87500000 0.12500000 1 - Al Al22 1 0.25000000 0.62500000 0.37500000 1 - Al Al23 1 0.62500000 0.75000000 0.37500000 1 - Al Al24 1 0.50000000 0.00000000 0.50000000 1 - Al Al25 1 0.00000000 0.50000000 0.00000000 1 - Al Al26 1 0.50000000 0.50000000 0.50000000 1 - Al Al27 1 0.00000000 0.00000000 0.50000000 1 - Al Al28 1 0.00000000 0.00000000 0.00000000 1 - Al Al29 1 0.00000000 0.50000000 0.50000000 1 - Al Al30 1 0.50000000 0.50000000 0.00000000 1 - Al Al31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.88148600 0.40114700 0.08062900 1 - O O33 1 0.08062900 0.88148600 0.40114700 1 - O O34 1 0.69914300 0.51966100 0.61851400 1 - O O35 1 0.67948200 0.09885300 0.98033900 1 - O O36 1 0.51966100 0.40114700 0.82051800 1 - O O37 1 0.41937100 0.82051800 0.80085700 1 - O O38 1 0.08062900 0.69914300 0.67948200 1 - O O39 1 0.40114700 0.08062900 0.88148600 1 - O O40 1 0.98033900 0.80085700 0.88148600 1 - O O41 1 0.67948200 0.08062900 0.69914300 1 - O O42 1 0.40114700 0.82051800 0.51966100 1 - O O43 1 0.09885300 0.61851400 0.41937100 1 - O O44 1 0.61851400 0.41937100 0.09885300 1 - O O45 1 0.69914300 0.67948200 0.08062900 1 - O O46 1 0.88148600 0.98033900 0.80085700 1 - O O47 1 0.80085700 0.88148600 0.98033900 1 - O O48 1 0.82051800 0.51966100 0.40114700 1 - O O49 1 0.61851400 0.69914300 0.51966100 1 - O O50 1 0.82051800 0.80085700 0.41937100 1 - O O51 1 0.01966100 0.19914300 0.11851400 1 - O O52 1 0.98033900 0.67948200 0.09885300 1 - O O53 1 0.09885300 0.98033900 0.67948200 1 - O O54 1 0.80085700 0.41937100 0.82051800 1 - O O55 1 0.41937100 0.09885300 0.61851400 1 - O O56 1 0.11851400 0.59885300 0.91937100 1 - O O57 1 0.91937100 0.11851400 0.59885300 1 - O O58 1 0.30085700 0.48033900 0.38148600 1 - O O59 1 0.32051800 0.90114700 0.01966100 1 - O O60 1 0.48033900 0.59885300 0.17948200 1 - O O61 1 0.58062900 0.17948200 0.19914300 1 - O O62 1 0.91937100 0.30085700 0.32051800 1 - O O63 1 0.59885300 0.91937100 0.11851400 1 - O O64 1 0.58062900 0.90114700 0.38148600 1 - O O65 1 0.19914300 0.58062900 0.17948200 1 - O O66 1 0.90114700 0.01966100 0.32051800 1 - O O67 1 0.48033900 0.38148600 0.30085700 1 - O O68 1 0.01966100 0.32051800 0.90114700 1 - O O69 1 0.17948200 0.19914300 0.58062900 1 - O O70 1 0.38148600 0.30085700 0.48033900 1 - O O71 1 0.17948200 0.48033900 0.59885300 1 - O O72 1 0.19914300 0.11851400 0.01966100 1 - O O73 1 0.11851400 0.01966100 0.19914300 1 - O O74 1 0.30085700 0.32051800 0.91937100 1 - O O75 1 0.38148600 0.58062900 0.90114700 1 - O O76 1 0.90114700 0.38148600 0.58062900 1 - O O77 1 0.59885300 0.17948200 0.48033900 1 - O O78 1 0.32051800 0.91937100 0.30085700 1 - O O79 1 0.51966100 0.61851400 0.69914300 1 -" -Y3Fe5O12,mp-4704,Ia-3d,"[60167, 88502, 2012, 29222, 14342, 23855, 88506, 173997, 29235, 80139, 28561, 88504]",0.023515586406247735,"{'tags': ['Triyttrium diiron(III) tris(ferrate(III))', 'Triyttrium pentairon(III) oxide', 'Garnet', 'Triyttrium pentaferrate(III)', 'Pentairon(III) triyttrium oxide']}","Full Formula (Y12 Fe20 O48) -Reduced Formula: Y3Fe5O12 -abc : 10.877243 10.877243 10.877243 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.375 0.125 0.25 0.027 - 1 Y 0.25 0.875 0.625 0.027 - 2 Y 0.625 0.875 0.75 0.027 - 3 Y 0.125 0.375 0.75 0.027 - 4 Y 0.75 0.625 0.875 0.027 - 5 Y 0.875 0.625 0.25 0.027 - 6 Y 0.875 0.75 0.625 0.027 - 7 Y 0.375 0.75 0.125 0.027 - 8 Y 0.75 0.125 0.375 0.027 - 9 Y 0.125 0.25 0.375 0.027 - 10 Y 0.625 0.25 0.875 0.027 - 11 Y 0.25 0.375 0.125 0.027 - 12 Fe 0.25 0.125 0.875 4.275 - 13 Fe 0.625 0.375 0.25 4.275 - 14 Fe 0.5 0.5 0 4.402 - 15 Fe 0.125 0.875 0.25 4.275 - 16 Fe 0 0 0.5 4.402 - 17 Fe 0.375 0.25 0.625 4.275 - 18 Fe 0 0.5 0.5 4.402 - 19 Fe 0.625 0.75 0.375 4.275 - 20 Fe 0.75 0.375 0.625 4.275 - 21 Fe 0.125 0.75 0.875 4.275 - 22 Fe 0.5 0 0 4.402 - 23 Fe 0.875 0.25 0.125 4.275 - 24 Fe 0 0 0 4.402 - 25 Fe 0.875 0.125 0.75 4.275 - 26 Fe 0.25 0.625 0.375 4.275 - 27 Fe 0 0.5 0 4.402 - 28 Fe 0.75 0.875 0.125 4.275 - 29 Fe 0.375 0.625 0.75 4.275 - 30 Fe 0.5 0.5 0.5 4.402 - 31 Fe 0.5 0 0.5 4.402 - 32 O 0.416949 0.094127 0.625104 0.216 - 33 O 0.594127 0.177179 0.469024 0.216 - 34 O 0.030976 0.322821 0.905873 0.216 - 35 O 0.177179 0.469024 0.594127 0.216 - 36 O 0.625104 0.708155 0.530976 0.216 - 37 O 0.874896 0.405873 0.083051 0.216 - 38 O 0.791845 0.874896 0.969024 0.216 - 39 O 0.125104 0.594127 0.916949 0.216 - 40 O 0.905873 0.374896 0.583051 0.216 - 41 O 0.094127 0.969024 0.677179 0.216 - 42 O 0.030976 0.208155 0.125104 0.216 - 43 O 0.677179 0.094127 0.969024 0.216 - 44 O 0.374896 0.583051 0.905873 0.216 - 45 O 0.083051 0.708155 0.677179 0.216 - 46 O 0.625104 0.416949 0.094127 0.216 - 47 O 0.530976 0.405873 0.822821 0.216 - 48 O 0.791845 0.416949 0.822821 0.216 - 49 O 0.677179 0.083051 0.708155 0.216 - 50 O 0.708155 0.530976 0.625104 0.216 - 51 O 0.916949 0.291845 0.322821 0.216 - 52 O 0.969024 0.677179 0.094127 0.216 - 53 O 0.594127 0.916949 0.125104 0.216 - 54 O 0.405873 0.083051 0.874896 0.216 - 55 O 0.822821 0.530976 0.405873 0.216 - 56 O 0.969024 0.791845 0.874896 0.216 - 57 O 0.469024 0.374896 0.291845 0.216 - 58 O 0.322821 0.916949 0.291845 0.216 - 59 O 0.874896 0.969024 0.791845 0.216 - 60 O 0.208155 0.583051 0.177179 0.216 - 61 O 0.322821 0.905873 0.030976 0.216 - 62 O 0.177179 0.208155 0.583051 0.216 - 63 O 0.905873 0.030976 0.322821 0.216 - 64 O 0.405873 0.822821 0.530976 0.216 - 65 O 0.291845 0.469024 0.374896 0.216 - 66 O 0.208155 0.125104 0.030976 0.216 - 67 O 0.125104 0.030976 0.208155 0.216 - 68 O 0.094127 0.625104 0.416949 0.216 - 69 O 0.416949 0.822821 0.791845 0.216 - 70 O 0.583051 0.177179 0.208155 0.216 - 71 O 0.469024 0.594127 0.177179 0.216 - 72 O 0.374896 0.291845 0.469024 0.216 - 73 O 0.083051 0.874896 0.405873 0.216 - 74 O 0.583051 0.905873 0.374896 0.216 - 75 O 0.291845 0.322821 0.916949 0.216 - 76 O 0.822821 0.791845 0.416949 0.216 - 77 O 0.708155 0.677179 0.083051 0.216 - 78 O 0.530976 0.625104 0.708155 0.216 - 79 O 0.916949 0.125104 0.594127 0.216","# generated using pymatgen -data_Y3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.87724270 -_cell_length_b 10.87724270 -_cell_length_c 10.87724270 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Fe5O12 -_chemical_formula_sum 'Y12 Fe20 O48' -_cell_volume 990.68266956 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.37500000 0.12500000 0.25000000 1 - Y Y1 1 0.25000000 0.87500000 0.62500000 1 - Y Y2 1 0.62500000 0.87500000 0.75000000 1 - Y Y3 1 0.12500000 0.37500000 0.75000000 1 - Y Y4 1 0.75000000 0.62500000 0.87500000 1 - Y Y5 1 0.87500000 0.62500000 0.25000000 1 - Y Y6 1 0.87500000 0.75000000 0.62500000 1 - Y Y7 1 0.37500000 0.75000000 0.12500000 1 - Y Y8 1 0.75000000 0.12500000 0.37500000 1 - Y Y9 1 0.12500000 0.25000000 0.37500000 1 - Y Y10 1 0.62500000 0.25000000 0.87500000 1 - Y Y11 1 0.25000000 0.37500000 0.12500000 1 - Fe Fe12 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe13 1 0.62500000 0.37500000 0.25000000 1 - Fe Fe14 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe15 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe17 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe18 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe19 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe20 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe21 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe22 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe23 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe24 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe25 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe26 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe27 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe28 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe29 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe30 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe31 1 0.50000000 0.00000000 0.50000000 1 - O O32 1 0.41694900 0.09412700 0.62510400 1 - O O33 1 0.59412700 0.17717900 0.46902400 1 - O O34 1 0.03097600 0.32282100 0.90587300 1 - O O35 1 0.17717900 0.46902400 0.59412700 1 - O O36 1 0.62510400 0.70815500 0.53097600 1 - O O37 1 0.87489600 0.40587300 0.08305100 1 - O O38 1 0.79184500 0.87489600 0.96902400 1 - O O39 1 0.12510400 0.59412700 0.91694900 1 - O O40 1 0.90587300 0.37489600 0.58305100 1 - O O41 1 0.09412700 0.96902400 0.67717900 1 - O O42 1 0.03097600 0.20815500 0.12510400 1 - O O43 1 0.67717900 0.09412700 0.96902400 1 - O O44 1 0.37489600 0.58305100 0.90587300 1 - O O45 1 0.08305100 0.70815500 0.67717900 1 - O O46 1 0.62510400 0.41694900 0.09412700 1 - O O47 1 0.53097600 0.40587300 0.82282100 1 - O O48 1 0.79184500 0.41694900 0.82282100 1 - O O49 1 0.67717900 0.08305100 0.70815500 1 - O O50 1 0.70815500 0.53097600 0.62510400 1 - O O51 1 0.91694900 0.29184500 0.32282100 1 - O O52 1 0.96902400 0.67717900 0.09412700 1 - O O53 1 0.59412700 0.91694900 0.12510400 1 - O O54 1 0.40587300 0.08305100 0.87489600 1 - O O55 1 0.82282100 0.53097600 0.40587300 1 - O O56 1 0.96902400 0.79184500 0.87489600 1 - O O57 1 0.46902400 0.37489600 0.29184500 1 - O O58 1 0.32282100 0.91694900 0.29184500 1 - O O59 1 0.87489600 0.96902400 0.79184500 1 - O O60 1 0.20815500 0.58305100 0.17717900 1 - O O61 1 0.32282100 0.90587300 0.03097600 1 - O O62 1 0.17717900 0.20815500 0.58305100 1 - O O63 1 0.90587300 0.03097600 0.32282100 1 - O O64 1 0.40587300 0.82282100 0.53097600 1 - O O65 1 0.29184500 0.46902400 0.37489600 1 - O O66 1 0.20815500 0.12510400 0.03097600 1 - O O67 1 0.12510400 0.03097600 0.20815500 1 - O O68 1 0.09412700 0.62510400 0.41694900 1 - O O69 1 0.41694900 0.82282100 0.79184500 1 - O O70 1 0.58305100 0.17717900 0.20815500 1 - O O71 1 0.46902400 0.59412700 0.17717900 1 - O O72 1 0.37489600 0.29184500 0.46902400 1 - O O73 1 0.08305100 0.87489600 0.40587300 1 - O O74 1 0.58305100 0.90587300 0.37489600 1 - O O75 1 0.29184500 0.32282100 0.91694900 1 - O O76 1 0.82282100 0.79184500 0.41694900 1 - O O77 1 0.70815500 0.67717900 0.08305100 1 - O O78 1 0.53097600 0.62510400 0.70815500 1 - O O79 1 0.91694900 0.12510400 0.59412700 1 -" -Y3Ga5O12,mp-5444,Ia-3d,"[185862, 23852, 80148, 14343]",0.0,"{'tags': ['Triyum pentagallium oxide', 'Triyttrium pentagallium oxide', 'Pentagallium triyttrium oxide', 'Yttrium gallium oxide (3/5/12)']}","Full Formula (Y12 Ga20 O48) -Reduced Formula: Y3Ga5O12 -abc : 10.765655 10.765655 10.765655 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Y 0.875 0.75 0.625 0 - 1 Y 0.875 0.625 0.25 0 - 2 Y 0.625 0.875 0.75 0 - 3 Y 0.25 0.875 0.625 0 - 4 Y 0.75 0.625 0.875 0 - 5 Y 0.625 0.25 0.875 0 - 6 Y 0.125 0.25 0.375 0 - 7 Y 0.125 0.375 0.75 0 - 8 Y 0.375 0.125 0.25 0 - 9 Y 0.75 0.125 0.375 0 - 10 Y 0.25 0.375 0.125 0 - 11 Y 0.375 0.75 0.125 0 - 12 Ga 0.125 0.75 0.875 -0 - 13 Ga 0.875 0.25 0.125 -0 - 14 Ga 0.75 0.375 0.625 -0 - 15 Ga 0.125 0.875 0.25 -0 - 16 Ga 0.25 0.125 0.875 -0 - 17 Ga 0.375 0.625 0.75 -0 - 18 Ga 0.375 0.25 0.625 -0 - 19 Ga 0.875 0.125 0.75 -0 - 20 Ga 0.625 0.375 0.25 -0 - 21 Ga 0.75 0.875 0.125 -0 - 22 Ga 0.25 0.625 0.375 -0 - 23 Ga 0.625 0.75 0.375 -0 - 24 Ga 0.5 0 0.5 0 - 25 Ga 0 0.5 0 0 - 26 Ga 0.5 0.5 0.5 0 - 27 Ga 0 0 0.5 0 - 28 Ga 0 0 0 0 - 29 Ga 0 0.5 0.5 0 - 30 Ga 0.5 0.5 0 0 - 31 Ga 0.5 0 0 0 - 32 O 0.528276 0.404963 0.822585 -0 - 33 O 0.822584 0.528276 0.404963 -0 - 34 O 0.794309 0.876688 0.971724 -0 - 35 O 0.417621 0.095037 0.623312 -0 - 36 O 0.876688 0.404963 0.082379 -0 - 37 O 0.677415 0.082379 0.705691 -0 - 38 O 0.822584 0.794309 0.417621 -0 - 39 O 0.404963 0.822584 0.528276 -0 - 40 O 0.623312 0.705691 0.528276 -0 - 41 O 0.417621 0.822584 0.794309 -0 - 42 O 0.404963 0.082379 0.876688 -0 - 43 O 0.095037 0.971724 0.677415 -0 - 44 O 0.971724 0.677415 0.095037 -0 - 45 O 0.794309 0.417621 0.822585 -0 - 46 O 0.528276 0.623312 0.705691 -0 - 47 O 0.705691 0.528276 0.623312 -0 - 48 O 0.082379 0.876688 0.404963 -0 - 49 O 0.971724 0.794309 0.876688 -0 - 50 O 0.082379 0.705691 0.677415 -0 - 51 O 0.376688 0.294309 0.471724 -0 - 52 O 0.623312 0.417621 0.095037 0 - 53 O 0.095037 0.623312 0.417621 -0 - 54 O 0.705691 0.677415 0.082379 -0 - 55 O 0.677415 0.095037 0.971724 -0 - 56 O 0.471724 0.595037 0.177415 -0 - 57 O 0.177415 0.471724 0.595037 -0 - 58 O 0.205691 0.123312 0.028276 -0 - 59 O 0.582379 0.904963 0.376688 0 - 60 O 0.123312 0.595037 0.917621 0 - 61 O 0.322584 0.917621 0.294309 -0 - 62 O 0.177415 0.205691 0.582379 -0 - 63 O 0.595037 0.177415 0.471724 -0 - 64 O 0.322585 0.904963 0.028276 0 - 65 O 0.294309 0.322584 0.917621 -0 - 66 O 0.904963 0.376688 0.582379 -0 - 67 O 0.123312 0.028276 0.205691 -0 - 68 O 0.376688 0.582379 0.904963 -0 - 69 O 0.917621 0.294309 0.322585 -0 - 70 O 0.028276 0.205691 0.123312 -0 - 71 O 0.917621 0.123312 0.595037 -0 - 72 O 0.294309 0.471724 0.376688 -0 - 73 O 0.471724 0.376688 0.294309 -0 - 74 O 0.205691 0.582379 0.177415 -0 - 75 O 0.028276 0.322584 0.904963 -0 - 76 O 0.904963 0.028276 0.322585 -0 - 77 O 0.595037 0.917621 0.123312 -0 - 78 O 0.582379 0.177415 0.205691 -0 - 79 O 0.876688 0.971724 0.794309 -0","# generated using pymatgen -data_Y3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.76565533 -_cell_length_b 10.76565533 -_cell_length_c 10.76565533 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Y3Ga5O12 -_chemical_formula_sum 'Y12 Ga20 O48' -_cell_volume 960.50476353 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Y Y0 1 0.87500000 0.75000000 0.62500000 1 - Y Y1 1 0.87500000 0.62500000 0.25000000 1 - Y Y2 1 0.62500000 0.87500000 0.75000000 1 - Y Y3 1 0.25000000 0.87500000 0.62500000 1 - Y Y4 1 0.75000000 0.62500000 0.87500000 1 - Y Y5 1 0.62500000 0.25000000 0.87500000 1 - Y Y6 1 0.12500000 0.25000000 0.37500000 1 - Y Y7 1 0.12500000 0.37500000 0.75000000 1 - Y Y8 1 0.37500000 0.12500000 0.25000000 1 - Y Y9 1 0.75000000 0.12500000 0.37500000 1 - Y Y10 1 0.25000000 0.37500000 0.12500000 1 - Y Y11 1 0.37500000 0.75000000 0.12500000 1 - Ga Ga12 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga13 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga14 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga15 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga16 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga17 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga18 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga19 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga20 1 0.62500000 0.37500000 0.25000000 1 - Ga Ga21 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga22 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga23 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga24 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga25 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga26 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga27 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga28 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga29 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga30 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.52827600 0.40496300 0.82258500 1 - O O33 1 0.82258400 0.52827600 0.40496300 1 - O O34 1 0.79430900 0.87668800 0.97172400 1 - O O35 1 0.41762100 0.09503700 0.62331200 1 - O O36 1 0.87668800 0.40496300 0.08237900 1 - O O37 1 0.67741500 0.08237900 0.70569100 1 - O O38 1 0.82258400 0.79430900 0.41762100 1 - O O39 1 0.40496300 0.82258400 0.52827600 1 - O O40 1 0.62331200 0.70569100 0.52827600 1 - O O41 1 0.41762100 0.82258400 0.79430900 1 - O O42 1 0.40496300 0.08237900 0.87668800 1 - O O43 1 0.09503700 0.97172400 0.67741500 1 - O O44 1 0.97172400 0.67741500 0.09503700 1 - O O45 1 0.79430900 0.41762100 0.82258500 1 - O O46 1 0.52827600 0.62331200 0.70569100 1 - O O47 1 0.70569100 0.52827600 0.62331200 1 - O O48 1 0.08237900 0.87668800 0.40496300 1 - O O49 1 0.97172400 0.79430900 0.87668800 1 - O O50 1 0.08237900 0.70569100 0.67741500 1 - O O51 1 0.37668800 0.29430900 0.47172400 1 - O O52 1 0.62331200 0.41762100 0.09503700 1 - O O53 1 0.09503700 0.62331200 0.41762100 1 - O O54 1 0.70569100 0.67741500 0.08237900 1 - O O55 1 0.67741500 0.09503700 0.97172400 1 - O O56 1 0.47172400 0.59503700 0.17741500 1 - O O57 1 0.17741500 0.47172400 0.59503700 1 - O O58 1 0.20569100 0.12331200 0.02827600 1 - O O59 1 0.58237900 0.90496300 0.37668800 1 - O O60 1 0.12331200 0.59503700 0.91762100 1 - O O61 1 0.32258400 0.91762100 0.29430900 1 - O O62 1 0.17741500 0.20569100 0.58237900 1 - O O63 1 0.59503700 0.17741500 0.47172400 1 - O O64 1 0.32258500 0.90496300 0.02827600 1 - O O65 1 0.29430900 0.32258400 0.91762100 1 - O O66 1 0.90496300 0.37668800 0.58237900 1 - O O67 1 0.12331200 0.02827600 0.20569100 1 - O O68 1 0.37668800 0.58237900 0.90496300 1 - O O69 1 0.91762100 0.29430900 0.32258500 1 - O O70 1 0.02827600 0.20569100 0.12331200 1 - O O71 1 0.91762100 0.12331200 0.59503700 1 - O O72 1 0.29430900 0.47172400 0.37668800 1 - O O73 1 0.47172400 0.37668800 0.29430900 1 - O O74 1 0.20569100 0.58237900 0.17741500 1 - O O75 1 0.02827600 0.32258400 0.90496300 1 - O O76 1 0.90496300 0.02827600 0.32258500 1 - O O77 1 0.59503700 0.91762100 0.12331200 1 - O O78 1 0.58237900 0.17741500 0.20569100 1 - O O79 1 0.87668800 0.97172400 0.79430900 1 -" -Yb3Al5O12,mp-3800,Ia-3d,"[280607, 23847, 170159, 170160]",0.03688165275000088,"{'tags': ['Pentaaluminium triytterbium oxide', 'Garnet', 'Triytterbium aluminium oxide', 'Unnamed_Garnet', 'Triytterbium pentaaluminium oxide']}","Full Formula (Yb12 Al20 O48) -Reduced Formula: Yb3Al5O12 -abc : 10.486657 10.486657 10.486657 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Yb 0.875 0.75 0.625 0.031 - 1 Yb 0.875 0.625 0.25 0.031 - 2 Yb 0.625 0.875 0.75 0.031 - 3 Yb 0.25 0.875 0.625 0.031 - 4 Yb 0.75 0.625 0.875 0.031 - 5 Yb 0.625 0.25 0.875 0.031 - 6 Yb 0.125 0.25 0.375 0.031 - 7 Yb 0.125 0.375 0.75 0.031 - 8 Yb 0.375 0.125 0.25 0.031 - 9 Yb 0.75 0.125 0.375 0.031 - 10 Yb 0.25 0.375 0.125 0.031 - 11 Yb 0.375 0.75 0.125 0.031 - 12 Al 0.125 0.75 0.875 -0.006 - 13 Al 0.875 0.25 0.125 -0.006 - 14 Al 0.75 0.375 0.625 -0.006 - 15 Al 0.125 0.875 0.25 -0.006 - 16 Al 0.25 0.125 0.875 -0.006 - 17 Al 0.375 0.625 0.75 -0.006 - 18 Al 0.375 0.25 0.625 -0.006 - 19 Al 0.875 0.125 0.75 -0.006 - 20 Al 0.625 0.375 0.25 -0.006 - 21 Al 0.75 0.875 0.125 -0.006 - 22 Al 0.25 0.625 0.375 -0.006 - 23 Al 0.625 0.75 0.375 -0.006 - 24 Al 0.5 0 0.5 -0.006 - 25 Al 0 0.5 0 -0.006 - 26 Al 0.5 0.5 0.5 -0.006 - 27 Al 0 0 0.5 -0.006 - 28 Al 0 0 0 -0.006 - 29 Al 0 0.5 0.5 -0.006 - 30 Al 0.5 0.5 0 -0.006 - 31 Al 0.5 0 0 -0.006 - 32 O 0.885606 0.402208 0.082197 0.21 - 33 O 0.082197 0.885606 0.402208 0.21 - 34 O 0.696591 0.516602 0.614394 0.21 - 35 O 0.679989 0.097792 0.983398 0.21 - 36 O 0.516602 0.402208 0.820011 0.21 - 37 O 0.417803 0.820011 0.803409 0.21 - 38 O 0.082197 0.696591 0.679989 0.21 - 39 O 0.402208 0.082197 0.885606 0.21 - 40 O 0.983398 0.803409 0.885606 0.21 - 41 O 0.679989 0.082197 0.696591 0.21 - 42 O 0.402208 0.820011 0.516602 0.21 - 43 O 0.097792 0.614394 0.417803 0.21 - 44 O 0.614394 0.417803 0.097792 0.21 - 45 O 0.696591 0.679989 0.082197 0.21 - 46 O 0.885606 0.983398 0.803409 0.21 - 47 O 0.803409 0.885606 0.983398 0.21 - 48 O 0.820011 0.516602 0.402208 0.21 - 49 O 0.614394 0.696591 0.516602 0.21 - 50 O 0.820011 0.803409 0.417803 0.21 - 51 O 0.016602 0.196591 0.114394 0.21 - 52 O 0.983398 0.679989 0.097792 0.21 - 53 O 0.097792 0.983398 0.679989 0.21 - 54 O 0.803409 0.417803 0.820011 0.21 - 55 O 0.417803 0.097792 0.614394 0.21 - 56 O 0.114394 0.597792 0.917803 0.21 - 57 O 0.917803 0.114394 0.597792 0.21 - 58 O 0.303409 0.483398 0.385606 0.21 - 59 O 0.320011 0.902208 0.016602 0.21 - 60 O 0.483398 0.597792 0.179989 0.21 - 61 O 0.582197 0.179989 0.196591 0.21 - 62 O 0.917803 0.303409 0.320011 0.21 - 63 O 0.597792 0.917803 0.114394 0.21 - 64 O 0.582197 0.902208 0.385606 0.21 - 65 O 0.196591 0.582197 0.179989 0.21 - 66 O 0.902208 0.016602 0.320011 0.21 - 67 O 0.483398 0.385606 0.303409 0.21 - 68 O 0.016602 0.320011 0.902208 0.21 - 69 O 0.179989 0.196591 0.582197 0.21 - 70 O 0.385606 0.303409 0.483398 0.21 - 71 O 0.179989 0.483398 0.597792 0.21 - 72 O 0.196591 0.114394 0.016602 0.21 - 73 O 0.114394 0.016602 0.196591 0.21 - 74 O 0.303409 0.320011 0.917803 0.21 - 75 O 0.385606 0.582197 0.902208 0.21 - 76 O 0.902208 0.385606 0.582197 0.21 - 77 O 0.597792 0.179989 0.483398 0.21 - 78 O 0.320011 0.917803 0.303409 0.21 - 79 O 0.516602 0.614394 0.696591 0.21","# generated using pymatgen -data_Yb3Al5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.48665658 -_cell_length_b 10.48665658 -_cell_length_c 10.48665658 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Yb3Al5O12 -_chemical_formula_sum 'Yb12 Al20 O48' -_cell_volume 887.74706859 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Yb Yb0 1 0.87500000 0.75000000 0.62500000 1 - Yb Yb1 1 0.87500000 0.62500000 0.25000000 1 - Yb Yb2 1 0.62500000 0.87500000 0.75000000 1 - Yb Yb3 1 0.25000000 0.87500000 0.62500000 1 - Yb Yb4 1 0.75000000 0.62500000 0.87500000 1 - Yb Yb5 1 0.62500000 0.25000000 0.87500000 1 - Yb Yb6 1 0.12500000 0.25000000 0.37500000 1 - Yb Yb7 1 0.12500000 0.37500000 0.75000000 1 - Yb Yb8 1 0.37500000 0.12500000 0.25000000 1 - Yb Yb9 1 0.75000000 0.12500000 0.37500000 1 - Yb Yb10 1 0.25000000 0.37500000 0.12500000 1 - Yb Yb11 1 0.37500000 0.75000000 0.12500000 1 - Al Al12 1 0.12500000 0.75000000 0.87500000 1 - Al Al13 1 0.87500000 0.25000000 0.12500000 1 - Al Al14 1 0.75000000 0.37500000 0.62500000 1 - Al Al15 1 0.12500000 0.87500000 0.25000000 1 - Al Al16 1 0.25000000 0.12500000 0.87500000 1 - Al Al17 1 0.37500000 0.62500000 0.75000000 1 - Al Al18 1 0.37500000 0.25000000 0.62500000 1 - Al Al19 1 0.87500000 0.12500000 0.75000000 1 - Al Al20 1 0.62500000 0.37500000 0.25000000 1 - Al Al21 1 0.75000000 0.87500000 0.12500000 1 - Al Al22 1 0.25000000 0.62500000 0.37500000 1 - Al Al23 1 0.62500000 0.75000000 0.37500000 1 - Al Al24 1 0.50000000 0.00000000 0.50000000 1 - Al Al25 1 0.00000000 0.50000000 0.00000000 1 - Al Al26 1 0.50000000 0.50000000 0.50000000 1 - Al Al27 1 0.00000000 0.00000000 0.50000000 1 - Al Al28 1 0.00000000 0.00000000 0.00000000 1 - Al Al29 1 0.00000000 0.50000000 0.50000000 1 - Al Al30 1 0.50000000 0.50000000 0.00000000 1 - Al Al31 1 0.50000000 0.00000000 0.00000000 1 - O O32 1 0.88560600 0.40220800 0.08219700 1 - O O33 1 0.08219700 0.88560600 0.40220800 1 - O O34 1 0.69659100 0.51660200 0.61439400 1 - O O35 1 0.67998900 0.09779200 0.98339800 1 - O O36 1 0.51660200 0.40220800 0.82001100 1 - O O37 1 0.41780300 0.82001100 0.80340900 1 - O O38 1 0.08219700 0.69659100 0.67998900 1 - O O39 1 0.40220800 0.08219700 0.88560600 1 - O O40 1 0.98339800 0.80340900 0.88560600 1 - O O41 1 0.67998900 0.08219700 0.69659100 1 - O O42 1 0.40220800 0.82001100 0.51660200 1 - O O43 1 0.09779200 0.61439400 0.41780300 1 - O O44 1 0.61439400 0.41780300 0.09779200 1 - O O45 1 0.69659100 0.67998900 0.08219700 1 - O O46 1 0.88560600 0.98339800 0.80340900 1 - O O47 1 0.80340900 0.88560600 0.98339800 1 - O O48 1 0.82001100 0.51660200 0.40220800 1 - O O49 1 0.61439400 0.69659100 0.51660200 1 - O O50 1 0.82001100 0.80340900 0.41780300 1 - O O51 1 0.01660200 0.19659100 0.11439400 1 - O O52 1 0.98339800 0.67998900 0.09779200 1 - O O53 1 0.09779200 0.98339800 0.67998900 1 - O O54 1 0.80340900 0.41780300 0.82001100 1 - O O55 1 0.41780300 0.09779200 0.61439400 1 - O O56 1 0.11439400 0.59779200 0.91780300 1 - O O57 1 0.91780300 0.11439400 0.59779200 1 - O O58 1 0.30340900 0.48339800 0.38560600 1 - O O59 1 0.32001100 0.90220800 0.01660200 1 - O O60 1 0.48339800 0.59779200 0.17998900 1 - O O61 1 0.58219700 0.17998900 0.19659100 1 - O O62 1 0.91780300 0.30340900 0.32001100 1 - O O63 1 0.59779200 0.91780300 0.11439400 1 - O O64 1 0.58219700 0.90220800 0.38560600 1 - O O65 1 0.19659100 0.58219700 0.17998900 1 - O O66 1 0.90220800 0.01660200 0.32001100 1 - O O67 1 0.48339800 0.38560600 0.30340900 1 - O O68 1 0.01660200 0.32001100 0.90220800 1 - O O69 1 0.17998900 0.19659100 0.58219700 1 - O O70 1 0.38560600 0.30340900 0.48339800 1 - O O71 1 0.17998900 0.48339800 0.59779200 1 - O O72 1 0.19659100 0.11439400 0.01660200 1 - O O73 1 0.11439400 0.01660200 0.19659100 1 - O O74 1 0.30340900 0.32001100 0.91780300 1 - O O75 1 0.38560600 0.58219700 0.90220800 1 - O O76 1 0.90220800 0.38560600 0.58219700 1 - O O77 1 0.59779200 0.17998900 0.48339800 1 - O O78 1 0.32001100 0.91780300 0.30340900 1 - O O79 1 0.51660200 0.61439400 0.69659100 1 -" -Yb3Fe5O12,mp-562055,Ia-3d,[23854],0.054532167249997876,{'tags': ['Pentairon(III) triytterbium oxide']},"Full Formula (Yb12 Fe20 O48) -Reduced Formula: Yb3Fe5O12 -abc : 10.763447 10.763447 10.763447 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Yb 0.25 0.375 0.125 0.051 - 1 Yb 0.875 0.625 0.25 0.051 - 2 Yb 0.375 0.125 0.25 0.051 - 3 Yb 0.75 0.625 0.875 0.051 - 4 Yb 0.125 0.375 0.75 0.051 - 5 Yb 0.875 0.75 0.625 0.051 - 6 Yb 0.25 0.875 0.625 0.053 - 7 Yb 0.75 0.125 0.375 0.053 - 8 Yb 0.375 0.75 0.125 0.051 - 9 Yb 0.625 0.875 0.75 0.051 - 10 Yb 0.125 0.25 0.375 0.051 - 11 Yb 0.625 0.25 0.875 0.051 - 12 Fe 0 0.5 0.5 4.082 - 13 Fe 0.25 0.125 0.875 4.076 - 14 Fe 0.375 0.625 0.75 4.089 - 15 Fe 0.5 0.5 0.5 4.078 - 16 Fe 0 0 0 4.078 - 17 Fe 0.25 0.625 0.375 4.076 - 18 Fe 0.5 0 0 4.082 - 19 Fe 0.5 0.5 0 4.078 - 20 Fe 0.625 0.75 0.375 4.089 - 21 Fe 0 0 0.5 4.082 - 22 Fe 0.125 0.75 0.875 4.089 - 23 Fe 0.75 0.375 0.625 4.076 - 24 Fe 0.75 0.875 0.125 4.076 - 25 Fe 0.375 0.25 0.625 4.089 - 26 Fe 0.875 0.125 0.75 4.089 - 27 Fe 0.5 0 0.5 4.082 - 28 Fe 0.125 0.875 0.25 4.089 - 29 Fe 0.875 0.25 0.125 4.089 - 30 Fe 0 0.5 0 4.078 - 31 Fe 0.625 0.375 0.25 4.089 - 32 O 0.800045 0.87921 0.976206 0.087 - 33 O 0.87921 0.976206 0.800045 0.081 - 34 O 0.096996 0.976206 0.676161 0.072 - 35 O 0.523794 0.403004 0.823839 0.107 - 36 O 0.699955 0.523794 0.62079 0.087 - 37 O 0.676161 0.079165 0.699955 0.087 - 38 O 0.023794 0.199955 0.12079 0.107 - 39 O 0.579165 0.176161 0.199955 0.105 - 40 O 0.176161 0.199955 0.579165 0.087 - 41 O 0.903004 0.023794 0.323839 0.072 - 42 O 0.823839 0.800045 0.420835 0.087 - 43 O 0.976206 0.800045 0.87921 0.107 - 44 O 0.37921 0.300045 0.476206 0.081 - 45 O 0.976206 0.676161 0.096996 0.107 - 46 O 0.096996 0.62079 0.420835 0.072 - 47 O 0.596996 0.920835 0.12079 0.072 - 48 O 0.62079 0.420835 0.096996 0.081 - 49 O 0.523794 0.62079 0.699955 0.107 - 50 O 0.596996 0.176161 0.476206 0.072 - 51 O 0.176161 0.476206 0.596996 0.087 - 52 O 0.12079 0.596996 0.920835 0.081 - 53 O 0.199955 0.12079 0.023794 0.087 - 54 O 0.079165 0.87921 0.403004 0.105 - 55 O 0.420835 0.096996 0.62079 0.105 - 56 O 0.476206 0.37921 0.300045 0.107 - 57 O 0.800045 0.420835 0.823839 0.087 - 58 O 0.476206 0.596996 0.176161 0.107 - 59 O 0.676161 0.096996 0.976206 0.087 - 60 O 0.079165 0.699955 0.676161 0.105 - 61 O 0.12079 0.023794 0.199955 0.081 - 62 O 0.300045 0.323839 0.920835 0.087 - 63 O 0.87921 0.403004 0.079165 0.081 - 64 O 0.420835 0.823839 0.800045 0.105 - 65 O 0.579165 0.903004 0.37921 0.105 - 66 O 0.903004 0.37921 0.579165 0.072 - 67 O 0.323839 0.920835 0.300045 0.087 - 68 O 0.403004 0.823839 0.523794 0.072 - 69 O 0.323839 0.903004 0.023794 0.087 - 70 O 0.403004 0.079165 0.87921 0.072 - 71 O 0.023794 0.323839 0.903004 0.107 - 72 O 0.823839 0.523794 0.403004 0.087 - 73 O 0.699955 0.676161 0.079165 0.087 - 74 O 0.920835 0.300045 0.323839 0.105 - 75 O 0.62079 0.699955 0.523794 0.081 - 76 O 0.199955 0.579165 0.176161 0.087 - 77 O 0.300045 0.476206 0.37921 0.087 - 78 O 0.37921 0.579165 0.903004 0.081 - 79 O 0.920835 0.12079 0.596996 0.105","# generated using pymatgen -data_Yb3Fe5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.76344696 -_cell_length_b 10.76344696 -_cell_length_c 10.76344696 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Yb3Fe5O12 -_chemical_formula_sum 'Yb12 Fe20 O48' -_cell_volume 959.91379817 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Yb Yb0 1 0.25000000 0.37500000 0.12500000 1 - Yb Yb1 1 0.87500000 0.62500000 0.25000000 1 - Yb Yb2 1 0.37500000 0.12500000 0.25000000 1 - Yb Yb3 1 0.75000000 0.62500000 0.87500000 1 - Yb Yb4 1 0.12500000 0.37500000 0.75000000 1 - Yb Yb5 1 0.87500000 0.75000000 0.62500000 1 - Yb Yb6 1 0.25000000 0.87500000 0.62500000 1 - Yb Yb7 1 0.75000000 0.12500000 0.37500000 1 - Yb Yb8 1 0.37500000 0.75000000 0.12500000 1 - Yb Yb9 1 0.62500000 0.87500000 0.75000000 1 - Yb Yb10 1 0.12500000 0.25000000 0.37500000 1 - Yb Yb11 1 0.62500000 0.25000000 0.87500000 1 - Fe Fe12 1 0.00000000 0.50000000 0.50000000 1 - Fe Fe13 1 0.25000000 0.12500000 0.87500000 1 - Fe Fe14 1 0.37500000 0.62500000 0.75000000 1 - Fe Fe15 1 0.50000000 0.50000000 0.50000000 1 - Fe Fe16 1 0.00000000 0.00000000 0.00000000 1 - Fe Fe17 1 0.25000000 0.62500000 0.37500000 1 - Fe Fe18 1 0.50000000 0.00000000 0.00000000 1 - Fe Fe19 1 0.50000000 0.50000000 0.00000000 1 - Fe Fe20 1 0.62500000 0.75000000 0.37500000 1 - Fe Fe21 1 0.00000000 0.00000000 0.50000000 1 - Fe Fe22 1 0.12500000 0.75000000 0.87500000 1 - Fe Fe23 1 0.75000000 0.37500000 0.62500000 1 - Fe Fe24 1 0.75000000 0.87500000 0.12500000 1 - Fe Fe25 1 0.37500000 0.25000000 0.62500000 1 - Fe Fe26 1 0.87500000 0.12500000 0.75000000 1 - Fe Fe27 1 0.50000000 0.00000000 0.50000000 1 - Fe Fe28 1 0.12500000 0.87500000 0.25000000 1 - Fe Fe29 1 0.87500000 0.25000000 0.12500000 1 - Fe Fe30 1 0.00000000 0.50000000 0.00000000 1 - Fe Fe31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.80004500 0.87921000 0.97620600 1 - O O33 1 0.87921000 0.97620600 0.80004500 1 - O O34 1 0.09699600 0.97620600 0.67616100 1 - O O35 1 0.52379400 0.40300400 0.82383900 1 - O O36 1 0.69995500 0.52379400 0.62079000 1 - O O37 1 0.67616100 0.07916500 0.69995500 1 - O O38 1 0.02379400 0.19995500 0.12079000 1 - O O39 1 0.57916500 0.17616100 0.19995500 1 - O O40 1 0.17616100 0.19995500 0.57916500 1 - O O41 1 0.90300400 0.02379400 0.32383900 1 - O O42 1 0.82383900 0.80004500 0.42083500 1 - O O43 1 0.97620600 0.80004500 0.87921000 1 - O O44 1 0.37921000 0.30004500 0.47620600 1 - O O45 1 0.97620600 0.67616100 0.09699600 1 - O O46 1 0.09699600 0.62079000 0.42083500 1 - O O47 1 0.59699600 0.92083500 0.12079000 1 - O O48 1 0.62079000 0.42083500 0.09699600 1 - O O49 1 0.52379400 0.62079000 0.69995500 1 - O O50 1 0.59699600 0.17616100 0.47620600 1 - O O51 1 0.17616100 0.47620600 0.59699600 1 - O O52 1 0.12079000 0.59699600 0.92083500 1 - O O53 1 0.19995500 0.12079000 0.02379400 1 - O O54 1 0.07916500 0.87921000 0.40300400 1 - O O55 1 0.42083500 0.09699600 0.62079000 1 - O O56 1 0.47620600 0.37921000 0.30004500 1 - O O57 1 0.80004500 0.42083500 0.82383900 1 - O O58 1 0.47620600 0.59699600 0.17616100 1 - O O59 1 0.67616100 0.09699600 0.97620600 1 - O O60 1 0.07916500 0.69995500 0.67616100 1 - O O61 1 0.12079000 0.02379400 0.19995500 1 - O O62 1 0.30004500 0.32383900 0.92083500 1 - O O63 1 0.87921000 0.40300400 0.07916500 1 - O O64 1 0.42083500 0.82383900 0.80004500 1 - O O65 1 0.57916500 0.90300400 0.37921000 1 - O O66 1 0.90300400 0.37921000 0.57916500 1 - O O67 1 0.32383900 0.92083500 0.30004500 1 - O O68 1 0.40300400 0.82383900 0.52379400 1 - O O69 1 0.32383900 0.90300400 0.02379400 1 - O O70 1 0.40300400 0.07916500 0.87921000 1 - O O71 1 0.02379400 0.32383900 0.90300400 1 - O O72 1 0.82383900 0.52379400 0.40300400 1 - O O73 1 0.69995500 0.67616100 0.07916500 1 - O O74 1 0.92083500 0.30004500 0.32383900 1 - O O75 1 0.62079000 0.69995500 0.52379400 1 - O O76 1 0.19995500 0.57916500 0.17616100 1 - O O77 1 0.30004500 0.47620600 0.37921000 1 - O O78 1 0.37921000 0.57916500 0.90300400 1 - O O79 1 0.92083500 0.12079000 0.59699600 1 -" -Yb3Ga5O12,mp-562499,Ia-3d,[23851],0.0,{'tags': ['Pentagallium triytterbium oxide']},"Full Formula (Yb12 Ga20 O48) -Reduced Formula: Yb3Ga5O12 -abc : 10.735126 10.735126 10.735126 -angles: 109.471221 109.471221 109.471221 -Sites (80) - # SP a b c magmom ---- ---- -------- -------- -------- -------- - 0 Yb 0.25 0.375 0.125 0.007 - 1 Yb 0.875 0.625 0.25 0.014 - 2 Yb 0.375 0.125 0.25 0.014 - 3 Yb 0.75 0.625 0.875 0.007 - 4 Yb 0.125 0.375 0.75 0.014 - 5 Yb 0.875 0.75 0.625 0.014 - 6 Yb 0.25 0.875 0.625 0.017 - 7 Yb 0.75 0.125 0.375 0.017 - 8 Yb 0.375 0.75 0.125 0.014 - 9 Yb 0.625 0.875 0.75 0.014 - 10 Yb 0.125 0.25 0.375 0.014 - 11 Yb 0.625 0.25 0.875 0.014 - 12 Ga 0 0.5 0.5 0.005 - 13 Ga 0.25 0.125 0.875 -0.002 - 14 Ga 0.375 0.625 0.75 -0.002 - 15 Ga 0.5 0.5 0.5 -0.014 - 16 Ga 0 0 0 -0.014 - 17 Ga 0.25 0.625 0.375 -0.002 - 18 Ga 0.5 0 0 0.005 - 19 Ga 0.5 0.5 0 -0.014 - 20 Ga 0.625 0.75 0.375 -0.002 - 21 Ga 0 0 0.5 0.005 - 22 Ga 0.125 0.75 0.875 -0.002 - 23 Ga 0.75 0.375 0.625 -0.002 - 24 Ga 0.75 0.875 0.125 -0.002 - 25 Ga 0.375 0.25 0.625 -0.002 - 26 Ga 0.875 0.125 0.75 -0.002 - 27 Ga 0.5 0 0.5 0.005 - 28 Ga 0.125 0.875 0.25 -0.002 - 29 Ga 0.875 0.25 0.125 -0.002 - 30 Ga 0 0.5 0 -0.014 - 31 Ga 0.625 0.375 0.25 -0.002 - 32 O 0.88068 0.973793 0.795593 0.183 - 33 O 0.906887 0.38068 0.585086 0.245 - 34 O 0.585086 0.906887 0.38068 0.241 - 35 O 0.6782 0.093113 0.973793 0.236 - 36 O 0.6782 0.085086 0.704407 0.236 - 37 O 0.88068 0.406887 0.085086 0.183 - 38 O 0.914914 0.11932 0.593113 0.241 - 39 O 0.085086 0.704407 0.6782 0.241 - 40 O 0.38068 0.295593 0.473793 0.183 - 41 O 0.526207 0.406887 0.8218 0.188 - 42 O 0.295593 0.473793 0.38068 0.182 - 43 O 0.406887 0.8218 0.526207 0.245 - 44 O 0.795593 0.88068 0.973793 0.182 - 45 O 0.3218 0.906887 0.026207 0.236 - 46 O 0.973793 0.6782 0.093113 0.188 - 47 O 0.295593 0.3218 0.914914 0.182 - 48 O 0.526207 0.61932 0.704407 0.188 - 49 O 0.973793 0.795593 0.88068 0.188 - 50 O 0.1782 0.204407 0.585086 0.236 - 51 O 0.085086 0.88068 0.406887 0.241 - 52 O 0.3218 0.914914 0.295593 0.236 - 53 O 0.704407 0.6782 0.085086 0.182 - 54 O 0.906887 0.026207 0.3218 0.245 - 55 O 0.11932 0.026207 0.204407 0.183 - 56 O 0.8218 0.795593 0.414914 0.236 - 57 O 0.585086 0.1782 0.204407 0.241 - 58 O 0.473793 0.38068 0.295593 0.188 - 59 O 0.38068 0.585086 0.906887 0.183 - 60 O 0.704407 0.526207 0.61932 0.182 - 61 O 0.026207 0.3218 0.906887 0.188 - 62 O 0.593113 0.1782 0.473793 0.245 - 63 O 0.914914 0.295593 0.3218 0.241 - 64 O 0.61932 0.414914 0.093113 0.183 - 65 O 0.204407 0.11932 0.026207 0.182 - 66 O 0.093113 0.973793 0.6782 0.245 - 67 O 0.8218 0.526207 0.406887 0.236 - 68 O 0.406887 0.085086 0.88068 0.245 - 69 O 0.026207 0.204407 0.11932 0.188 - 70 O 0.1782 0.473793 0.593113 0.236 - 71 O 0.414914 0.8218 0.795593 0.241 - 72 O 0.473793 0.593113 0.1782 0.188 - 73 O 0.11932 0.593113 0.914914 0.183 - 74 O 0.795593 0.414914 0.8218 0.182 - 75 O 0.61932 0.704407 0.526207 0.183 - 76 O 0.204407 0.585086 0.1782 0.182 - 77 O 0.414914 0.093113 0.61932 0.241 - 78 O 0.593113 0.914914 0.11932 0.245 - 79 O 0.093113 0.61932 0.414914 0.245","# generated using pymatgen -data_Yb3Ga5O12 -_symmetry_space_group_name_H-M 'P 1' -_cell_length_a 10.73512620 -_cell_length_b 10.73512620 -_cell_length_c 10.73512620 -_cell_angle_alpha 109.47122063 -_cell_angle_beta 109.47122063 -_cell_angle_gamma 109.47122063 -_symmetry_Int_Tables_number 1 -_chemical_formula_structural Yb3Ga5O12 -_chemical_formula_sum 'Yb12 Ga20 O48' -_cell_volume 952.35654722 -_cell_formula_units_Z 4 -loop_ - _symmetry_equiv_pos_site_id - _symmetry_equiv_pos_as_xyz - 1 'x, y, z' -loop_ - _atom_site_type_symbol - _atom_site_label - _atom_site_symmetry_multiplicity - _atom_site_fract_x - _atom_site_fract_y - _atom_site_fract_z - _atom_site_occupancy - Yb Yb0 1 0.25000000 0.37500000 0.12500000 1 - Yb Yb1 1 0.87500000 0.62500000 0.25000000 1 - Yb Yb2 1 0.37500000 0.12500000 0.25000000 1 - Yb Yb3 1 0.75000000 0.62500000 0.87500000 1 - Yb Yb4 1 0.12500000 0.37500000 0.75000000 1 - Yb Yb5 1 0.87500000 0.75000000 0.62500000 1 - Yb Yb6 1 0.25000000 0.87500000 0.62500000 1 - Yb Yb7 1 0.75000000 0.12500000 0.37500000 1 - Yb Yb8 1 0.37500000 0.75000000 0.12500000 1 - Yb Yb9 1 0.62500000 0.87500000 0.75000000 1 - Yb Yb10 1 0.12500000 0.25000000 0.37500000 1 - Yb Yb11 1 0.62500000 0.25000000 0.87500000 1 - Ga Ga12 1 0.00000000 0.50000000 0.50000000 1 - Ga Ga13 1 0.25000000 0.12500000 0.87500000 1 - Ga Ga14 1 0.37500000 0.62500000 0.75000000 1 - Ga Ga15 1 0.50000000 0.50000000 0.50000000 1 - Ga Ga16 1 0.00000000 0.00000000 0.00000000 1 - Ga Ga17 1 0.25000000 0.62500000 0.37500000 1 - Ga Ga18 1 0.50000000 0.00000000 0.00000000 1 - Ga Ga19 1 0.50000000 0.50000000 0.00000000 1 - Ga Ga20 1 0.62500000 0.75000000 0.37500000 1 - Ga Ga21 1 0.00000000 0.00000000 0.50000000 1 - Ga Ga22 1 0.12500000 0.75000000 0.87500000 1 - Ga Ga23 1 0.75000000 0.37500000 0.62500000 1 - Ga Ga24 1 0.75000000 0.87500000 0.12500000 1 - Ga Ga25 1 0.37500000 0.25000000 0.62500000 1 - Ga Ga26 1 0.87500000 0.12500000 0.75000000 1 - Ga Ga27 1 0.50000000 0.00000000 0.50000000 1 - Ga Ga28 1 0.12500000 0.87500000 0.25000000 1 - Ga Ga29 1 0.87500000 0.25000000 0.12500000 1 - Ga Ga30 1 0.00000000 0.50000000 0.00000000 1 - Ga Ga31 1 0.62500000 0.37500000 0.25000000 1 - O O32 1 0.88068000 0.97379300 0.79559300 1 - O O33 1 0.90688700 0.38068000 0.58508600 1 - O O34 1 0.58508600 0.90688700 0.38068000 1 - O O35 1 0.67820000 0.09311300 0.97379300 1 - O O36 1 0.67820000 0.08508600 0.70440700 1 - O O37 1 0.88068000 0.40688700 0.08508600 1 - O O38 1 0.91491400 0.11932000 0.59311300 1 - O O39 1 0.08508600 0.70440700 0.67820000 1 - O O40 1 0.38068000 0.29559300 0.47379300 1 - O O41 1 0.52620700 0.40688700 0.82180000 1 - O O42 1 0.29559300 0.47379300 0.38068000 1 - O O43 1 0.40688700 0.82180000 0.52620700 1 - O O44 1 0.79559300 0.88068000 0.97379300 1 - O O45 1 0.32180000 0.90688700 0.02620700 1 - O O46 1 0.97379300 0.67820000 0.09311300 1 - O O47 1 0.29559300 0.32180000 0.91491400 1 - O O48 1 0.52620700 0.61932000 0.70440700 1 - O O49 1 0.97379300 0.79559300 0.88068000 1 - O O50 1 0.17820000 0.20440700 0.58508600 1 - O O51 1 0.08508600 0.88068000 0.40688700 1 - O O52 1 0.32180000 0.91491400 0.29559300 1 - O O53 1 0.70440700 0.67820000 0.08508600 1 - O O54 1 0.90688700 0.02620700 0.32180000 1 - O O55 1 0.11932000 0.02620700 0.20440700 1 - O O56 1 0.82180000 0.79559300 0.41491400 1 - O O57 1 0.58508600 0.17820000 0.20440700 1 - O O58 1 0.47379300 0.38068000 0.29559300 1 - O O59 1 0.38068000 0.58508600 0.90688700 1 - O O60 1 0.70440700 0.52620700 0.61932000 1 - O O61 1 0.02620700 0.32180000 0.90688700 1 - O O62 1 0.59311300 0.17820000 0.47379300 1 - O O63 1 0.91491400 0.29559300 0.32180000 1 - O O64 1 0.61932000 0.41491400 0.09311300 1 - O O65 1 0.20440700 0.11932000 0.02620700 1 - O O66 1 0.09311300 0.97379300 0.67820000 1 - O O67 1 0.82180000 0.52620700 0.40688700 1 - O O68 1 0.40688700 0.08508600 0.88068000 1 - O O69 1 0.02620700 0.20440700 0.11932000 1 - O O70 1 0.17820000 0.47379300 0.59311300 1 - O O71 1 0.41491400 0.82180000 0.79559300 1 - O O72 1 0.47379300 0.59311300 0.17820000 1 - O O73 1 0.11932000 0.59311300 0.91491400 1 - O O74 1 0.79559300 0.41491400 0.82180000 1 - O O75 1 0.61932000 0.70440700 0.52620700 1 - O O76 1 0.20440700 0.58508600 0.17820000 1 - O O77 1 0.41491400 0.09311300 0.61932000 1 - O O78 1 0.59311300 0.91491400 0.11932000 1 - O O79 1 0.09311300 0.61932000 0.41491400 1 -" diff --git a/examples/Structure_Prediction/_Materials Project .csv b/examples/Structure_Prediction/_Materials Project .csv deleted file mode 100644 index 093e2785..00000000 --- a/examples/Structure_Prediction/_Materials Project .csv +++ /dev/null @@ -1,483 +0,0 @@ -"Materials Id","Formula","Spacegroup","Formation Energy (eV)","E Above Hull (eV)","Band Gap (eV)","Has Bandstructure","Volume","Nsites","Theoretical","Count","Density (gm/cc)","Crystal System","" -"mp-1207933","Y3Sc2(GaO4)3","Ia3d","-3.393","0","3.595","false","1003.325","80","true","482","5.017","cubic","" -"mp-1208208","Y3Ga3(FeO6)2","Ia3d","-2.878","0","2.630","false","971.32","80","true","","5.331","cubic","" -"mp-1211646","Li3Lu3(TeO6)2","Ia3d","-2.798","0","3.112","false","918.323","80","true","","7.182","cubic","" -"mp-6527","Na3Li3In2F12","Ia3d","-3.046","0","5.290","true","1072.334","80","false","","3.391","cubic","" -"mp-556723","Na3Fe2(AsO4)3","Ia3d","-1.952","0","2.186","true","959.363","80","false","","4.136","cubic","" -"mp-6247","Na3Li3Fe2F12","Ia3d","-3.036","0","4.068","true","995.938","80","false","","2.864","cubic","" -"mp-15103","Sr3Y2(GeO4)3","Ia3d","-3.07","0","3.136","true","1165.601","80","false","","4.847","cubic","" 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-"mp-14049","Ba3Al2(SiO4)3","Ia3d","-3.165","0.272","3.293","true","1017.496","80","false","","4.845","cubic","" -"mvc-4269","Zn3Ge3(BiO6)2","Ia3d","-1.687","0.274","1.504","false","1047.135","80","true","","6.496","cubic","" -"mvc-3630","Mg3Si3(SnO6)2","Ia3d","-2.643","0.275","0.197","false","915.357","80","true","","4.256","cubic","" -"mp-1163940","Mg3Si3(SbO6)2","Ia3d","-2.598","0.279","2.807","false","937.5","80","true","","4.199","cubic","" -"mvc-4256","Zn3Ge3(SbO6)2","Ia3d","-1.677","0.285","1.279","false","1015.878","80","true","","5.555","cubic","" -"mp-775234","Li3V3(FeO6)2","P21/c","-2.291","0.287","0.143","false","1021.299","80","true","","3.104","monoclinic","" -"mp-1157822","Zn3Si3(BiO6)2","Ia3d","-2.173","0.292","1.872","false","976.091","80","true","","6.059","cubic","" -"mvc-3700","Zn3Si3(SnO6)2","Ia3d","-2.203","0.307","0.000","false","943.905","80","true","","4.995","cubic","" -"mp-1013808","Na3Ni2(GeO4)3","Ia3d","-1.367","0.308","0.000","false","892.169","80","true","","4.439","cubic","" -"mp-1154534","Zn3Si3(SbO6)2","Ia3d","-2.157","0.311","1.621","false","950.706","80","true","","5.002","cubic","" -"mp-1261874","Y2Cu3(SiO4)3","Ia3d","-2.489","0.317","0.124","false","960.892","80","true","","4.456","cubic","" -"mp-1163922","Y2Ti3(SiO4)3","Ia3d","-3.081","0.327","0.000","false","938.87","80","true","","4.228","cubic","" -"mp-1264115","Be3Fe2(SiO4)3","P21/c","-2.549","0.338","1.485","true","837.209","80","true","","3.292","monoclinic","" -"mvc-4466","V2Zn3(GeO4)3","Ia3d","-1.8","0.341","0.000","false","904.125","80","true","","5.201","cubic","" -"mp-1250945","Mn2Be3(SiO4)3","P21/c","-2.762","0.347","0.193","false","836.993","80","true","","3.279","monoclinic","" -"mp-759875","Na3Fe2(PO4)3","P21/c","-2.473","0.369","0.210","false","1014.683","80","true","","3.048","monoclinic","" -"mp-780661","Li3Fe3(WO6)2","P21/c","-2.085","0.411","0.040","false","1060.401","80","true","","4.686","monoclinic","" -"mvc-4351","Al2Cr3(SiO4)3","Ia3d","-2.855","0.445","0.037","false","811.527","80","true","","3.979","cubic","" -"mp-1210501","Na2Mn3(PO4)3","C2/c","-2.554","0.47","0.031","false","470.701","40","true","","3.498","monoclinic","" -"mp-6172","Al2Fe3(SiO4)3","Ia3d","-2.852","0.518","3.642","true","793.848","80","false","","4.165","cubic","" -"mp-1157227","Y2Si3(WO4)3","Ia3d","-2.36","0.6","0.690","false","1054.699","80","true","","6.333","cubic","" -"mp-555835","Gd3Sc2(GaO4)3","Ia3d","-2.661","0.688","0.493","true","1037.761","80","false","","6.163","cubic","" -"mp-6700","Mg3Cr2(SiO4)3","Ia3d","-2.967","0.699","3.455","true","813.106","80","false","","3.702","cubic","" -"mvc-4363","Al2Si3(WO4)3","Ia3d","-2.075","0.71","0.116","false","816.658","80","true","","7.171","cubic","" -"mp-694966","Li3V2(PO4)3","P2","-1.694","1.036","0.000","false","1097.299","80","true","","2.467","monoclinic","" -"mp-1202926","Au3N3(Cl6O)2","C2/c","0.452","1.038","0.000","false","1220.656","40","false","","2.967","monoclinic","" From b081e37063e05d5ed93d1abc8f9ddc30753b2984 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:03:18 -0500 Subject: [PATCH 17/62] Add error handling for missing API key --- smact/structure_prediction/database.py | 2 ++ 1 file changed, 2 insertions(+) diff --git a/smact/structure_prediction/database.py b/smact/structure_prediction/database.py index 3e245632..66c6e530 100644 --- a/smact/structure_prediction/database.py +++ b/smact/structure_prediction/database.py @@ -136,6 +136,8 @@ def add_mp_icsd( if mp_api_key is None: # Try to get the API key from the environment mp_api_key = SETTINGS.get("PMG_MAPI_KEY") or os.environ.get("MP_API_KEY") + if mp_api_key is None: + raise ValueError("No Materials Project API key provided.") if mp_data is None: # pragma: no cover if len(mp_api_key) != 32: From e247e830019b725159f1c128bdf5ba2b6b824b95 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:05:53 -0500 Subject: [PATCH 18/62] Standardise API key retrieval to use PMG_MAPI_KEY consistently --- smact/tests/test_structure.py | 4 ++-- 1 file changed, 2 insertions(+), 2 deletions(-) diff --git a/smact/tests/test_structure.py b/smact/tests/test_structure.py index bb6ca48f..bdf6940a 100644 --- a/smact/tests/test_structure.py +++ b/smact/tests/test_structure.py @@ -217,14 +217,14 @@ def test_ele_stoics(self): self.assertEqual(SmactStructure._get_ele_stoics(test.species), expected) @unittest.skipUnless( - (os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_API_KEY")), "requires MP API key to be set." + (os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_MAPI_KEY")), "requires MP API key to be set." ) def test_from_mp(self): """Test downloading structures from materialsproject.org.""" # TODO Needs ensuring that the structure query gets the same # structure as we have downloaded. - api_key = os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_API_KEY") + api_key = os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_MAPI_KEY") for comp, species in self.TEST_SPECIES.items(): with self.subTest(comp=comp): From 30d7f8b262926937b15153b39afc0b31e3d59bd2 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:13:21 -0500 Subject: [PATCH 19/62] Add test for `as_py_struct` method in `SmactStructure` --- smact/tests/test_structure.py | 9 +++++++++ 1 file changed, 9 insertions(+) diff --git a/smact/tests/test_structure.py b/smact/tests/test_structure.py index bdf6940a..694fd44b 100644 --- a/smact/tests/test_structure.py +++ b/smact/tests/test_structure.py @@ -233,6 +233,15 @@ def test_from_mp(self): mp_struct = SmactStructure.from_mp(species, api_key) self.assertEqual(local_struct, mp_struct) + def test_as_py_struct(self): + s1 = SmactStructure.from_file(os.path.join(files_dir, "CaTiO3.txt")) + s1_pym = s1.as_py_struct() + with open(TEST_PY_STRUCT) as f: + d = json.load(f) + py_structure = pymatgen.core.Structure.from_dict(d) + + self.assertEqual(s1_pym, py_structure) + class StructureDBTest(unittest.TestCase): """Test StructureDB interface.""" From 1805282a99aecb0aef46211f85be8e080644a7fa Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sat, 30 Nov 2024 16:15:57 -0500 Subject: [PATCH 20/62] Add test for reduced formula --- smact/tests/test_structure.py | 8 ++++++++ 1 file changed, 8 insertions(+) diff --git a/smact/tests/test_structure.py b/smact/tests/test_structure.py index 694fd44b..31ce7040 100644 --- a/smact/tests/test_structure.py +++ b/smact/tests/test_structure.py @@ -242,6 +242,14 @@ def test_as_py_struct(self): self.assertEqual(s1_pym, py_structure) + def test_reduced_formula(self): + """Test the reduced formula method.""" + s1 = SmactStructure.from_file(os.path.join(files_dir, "CaTiO3.txt")) + s2 = SmactStructure.from_file(os.path.join(files_dir, "NaCl.txt")) + + self.assertEqual(s1.reduced_formula(), "CaTiO3") + self.assertEqual(s2.reduced_formula(), "NaCl") + class StructureDBTest(unittest.TestCase): """Test StructureDB interface.""" From b615bf09d670609daf5ac3718d30874ea0985aea Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:17:11 -0500 Subject: [PATCH 21/62] Update mock modules in conf.py --- docs/conf.py | 3 +++ 1 file changed, 3 insertions(+) diff --git a/docs/conf.py b/docs/conf.py index 5a220172..9d4a434d 100644 --- a/docs/conf.py +++ b/docs/conf.py @@ -418,5 +418,8 @@ def __getattr__(cls, name): "pymatgen.analysis.structure_prediction", "pymatgen.transformations.standard_transformations", "tabulate", + "mp_api", + "mp_api.client", + "emmet", ] sys.modules.update((mod_name, Mock()) for mod_name in MOCK_MODULES) From 402c9433591172628150c440895b424e60a9d134 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:19:22 -0500 Subject: [PATCH 22/62] Update composition import --- .../download_compounds_with_mp_api.py | 2 +- .../generate_composition_with_smact.py | 16 +++++++--------- 2 files changed, 8 insertions(+), 10 deletions(-) diff --git a/smact/utils/crystal_space/download_compounds_with_mp_api.py b/smact/utils/crystal_space/download_compounds_with_mp_api.py index 1e93e57e..f0e783d4 100644 --- a/smact/utils/crystal_space/download_compounds_with_mp_api.py +++ b/smact/utils/crystal_space/download_compounds_with_mp_api.py @@ -10,7 +10,7 @@ from pathlib import Path from mp_api.client import MPRester -from pymatgen.core.composition import Composition +from pymatgen.core import Composition from tqdm import tqdm diff --git a/smact/utils/crystal_space/generate_composition_with_smact.py b/smact/utils/crystal_space/generate_composition_with_smact.py index 9b68b238..81c43e15 100644 --- a/smact/utils/crystal_space/generate_composition_with_smact.py +++ b/smact/utils/crystal_space/generate_composition_with_smact.py @@ -9,7 +9,7 @@ from pathlib import Path import pandas as pd -from pymatgen.core.composition import Composition +from pymatgen.core import Composition from tqdm import tqdm from smact import Element, ordered_elements @@ -50,16 +50,14 @@ def generate_composition_with_smact( filter them with SMACT. Args: - ---- - num_elements: the number of elements in a compound. Defaults to 2. - max_stoich: the maximum stoichiometric coefficient. Defaults to 8. - max_atomic_num: the maximum atomic number. Defaults to 103. - num_processes: the number of processes to use. Defaults to None. - save_path: the path to save the results. Defaults to None. + num_elements (int): the number of elements in a compound. Defaults to 2. + max_stoich (int): the maximum stoichiometric coefficient. Defaults to 8. + max_atomic_num (int): the maximum atomic number. Defaults to 103. + num_processes (int): the number of processes to use. Defaults to None. + save_path (str): the path to save the results. Defaults to None. Returns: - ------- - _description_ + df (pd.DataFrame): A DataFrame of SMACT-generated compositions with boolean smact_allowed column. """ # 1. generate all possible combinations of elements From 751db6e772d825745eca67274b961deb461cf46b Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:19:45 -0500 Subject: [PATCH 23/62] Update crystal space documentation --- docs/smact.utils.crystal_space.rst | 14 ++++++++++++++ docs/smact.utils.rst | 6 ++---- 2 files changed, 16 insertions(+), 4 deletions(-) create mode 100644 docs/smact.utils.crystal_space.rst diff --git a/docs/smact.utils.crystal_space.rst b/docs/smact.utils.crystal_space.rst new file mode 100644 index 00000000..e99a82d0 --- /dev/null +++ b/docs/smact.utils.crystal_space.rst @@ -0,0 +1,14 @@ +SMACT Utilities Crystal Space Module +=========================== + +Utility functions associated with our `Faraday Dicussions publication 'Mapping Inorganic Crystal Space' `_ using SMACT + + +Submodules +---------- + +.. toctree:: + + smact.utils.crystal_space.download_compounds_with_mp_api + smact.utils.crystal_space.generate_composition_with_smact + smact.utils.crystal_space.plot_embedding diff --git a/docs/smact.utils.rst b/docs/smact.utils.rst index 4128fe28..05cf5efd 100644 --- a/docs/smact.utils.rst +++ b/docs/smact.utils.rst @@ -9,7 +9,5 @@ Submodules .. toctree:: smact.utils.composition - smact.utils.band_gap_simple - smact.utils.download_compounds_with_mp_api - smact.utils.generate_composition_with_smact - smact.utils.plot_embeddings + smact.utils.crystal_space + smact.utils.oxidation From 69ac485fca50e72ea15a762b04379e1adc2cc935 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:19:57 -0500 Subject: [PATCH 24/62] Add documentation for oxidation utitilies --- docs/smact.utils.oxidation.rst | 9 +++++++++ 1 file changed, 9 insertions(+) create mode 100644 docs/smact.utils.oxidation.rst diff --git a/docs/smact.utils.oxidation.rst b/docs/smact.utils.oxidation.rst new file mode 100644 index 00000000..2020f530 --- /dev/null +++ b/docs/smact.utils.oxidation.rst @@ -0,0 +1,9 @@ +SMACT Utilities Oxidation Module +===================================== + +Miscellaneous utilities for creating SMACT compatible oxidation states list + +.. automodule:: smact.utils.oxidation + :members: + :undoc-members: + :show-inheritance: From 2e0a13bed46dc23a0f5e595c4b7d8aec644c37d6 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:20:15 -0500 Subject: [PATCH 25/62] Add documentation for crystal space submodules --- ...utils.crystal_space.download_compounds_with_mp_api.rst | 8 ++++++++ ...tils.crystal_space.generate_composition_with_smact.rst | 7 +++++++ docs/smact.utils.crystal_space.plot_embedding.rst | 8 ++++++++ 3 files changed, 23 insertions(+) create mode 100644 docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst create mode 100644 docs/smact.utils.crystal_space.generate_composition_with_smact.rst create mode 100644 docs/smact.utils.crystal_space.plot_embedding.rst diff --git a/docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst b/docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst new file mode 100644 index 00000000..d930a731 --- /dev/null +++ b/docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst @@ -0,0 +1,8 @@ +Crystal Space Materials Project Data Retrieval Module +=========================== + + +.. automodule:: smact.utils.crystal_space.download_compounds_with_mp_api + :members: + :undoc-members: + :show-inheritance: diff --git a/docs/smact.utils.crystal_space.generate_composition_with_smact.rst b/docs/smact.utils.crystal_space.generate_composition_with_smact.rst new file mode 100644 index 00000000..949b0ed5 --- /dev/null +++ b/docs/smact.utils.crystal_space.generate_composition_with_smact.rst @@ -0,0 +1,7 @@ +Crystal Space SMACT Generation Module +=========================== + +.. automodule:: smact.utils.crystal_space.generate_composition_with_smact + :members: + :undoc-members: + :show-inheritance: diff --git a/docs/smact.utils.crystal_space.plot_embedding.rst b/docs/smact.utils.crystal_space.plot_embedding.rst new file mode 100644 index 00000000..47d34d47 --- /dev/null +++ b/docs/smact.utils.crystal_space.plot_embedding.rst @@ -0,0 +1,8 @@ +Crystal Space Embedding Module +=========================== + + +.. automodule:: smact.utils.crystal_space.plot_embedding + :members: + :undoc-members: + :show-inheritance: From 994bfcd66ca7aa747845fc61d4116876b5dc1ec7 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:23:29 -0500 Subject: [PATCH 26/62] Include extras in requirements.txt to make binder notebooks work --- requirements.txt | 307 ++++++++++++++++++++++++++++++++++++++++++----- 1 file changed, 280 insertions(+), 27 deletions(-) diff --git a/requirements.txt b/requirements.txt index dd917b7c..7fc8f33a 100644 --- a/requirements.txt +++ b/requirements.txt @@ -2,121 +2,374 @@ # This file is autogenerated by pip-compile with Python 3.10 # by the following command: # -# pip-compile --output-file=requirements.txt --strip-extras pyproject.toml +# pip-compile --extra=strict --output-file=requirements.txt # +adjusttext==1.3.0 + # via elementembeddings +aioitertools==0.12.0 + # via maggma +annotated-types==0.7.0 + # via pydantic ase==3.23.0 - # via SMACT (pyproject.toml) + # via SMACT (setup.py) +attrs==24.2.0 + # via + # jsonlines + # jsonschema + # referencing +bcrypt==4.2.1 + # via paramiko +blinker==1.9.0 + # via flask +boto3==1.35.71 + # via maggma +botocore==1.35.71 + # via + # boto3 + # s3transfer certifi==2024.7.4 # via requests +cffi==1.17.1 + # via + # cryptography + # pynacl charset-normalizer==3.3.2 # via requests +click==8.1.7 + # via flask contourpy==1.2.0 # via matplotlib +cryptography==44.0.0 + # via paramiko cycler==0.12.1 # via matplotlib +dash==2.18.2 + # via SMACT (setup.py) +dash-core-components==2.0.0 + # via dash +dash-html-components==2.0.0 + # via dash +dash-table==5.0.0 + # via dash dill==0.3.8 # via # multiprocess # pathos +dnspython==2.7.0 + # via + # maggma + # pymongo +elementembeddings==0.6.1 + # via SMACT (setup.py) +emmet-core==0.84.3rc4 + # via mp-api +flask==3.0.3 + # via dash fonttools==4.53.0 # via matplotlib idna==3.7 # via requests +importlib-metadata==8.5.0 + # via dash +itsdangerous==2.2.0 + # via flask +jinja2==3.1.4 + # via + # flask + # pandas +jmespath==1.0.1 + # via + # boto3 + # botocore joblib==1.4.2 - # via pymatgen + # via + # pymatgen + # pynndescent + # scikit-learn +jsonlines==4.0.0 + # via maggma +jsonschema==4.23.0 + # via maggma +jsonschema-specifications==2024.10.1 + # via jsonschema +kaleido==0.2.1 + # via SMACT (setup.py) kiwisolver==1.4.5 # via matplotlib latexcodec==2.0.1 # via pybtex -matplotlib==3.8.2 +llvmlite==0.43.0 + # via + # numba + # pynndescent +maggma==0.70.0 + # via mp-api +markupsafe==3.0.2 # via + # jinja2 + # werkzeug +matminer==0.9.2 + # via SMACT (setup.py) +matplotlib==3.9.3 + # via + # adjusttext # ase + # elementembeddings # pymatgen -monty==2024.7.30 - # via pymatgen + # pymatviz + # seaborn +mongomock==4.3.0 + # via maggma +monty==2024.10.21 + # via + # emmet-core + # maggma + # matminer + # mp-api + # pymatgen +mp-api==0.42.2 + # via SMACT (setup.py) mpmath==1.3.0 # via sympy +msgpack==1.1.0 + # via + # maggma + # mp-api multiprocess==0.70.16 # via pathos +nest-asyncio==1.6.0 + # via dash networkx==3.2.1 # via pymatgen +numba==0.60.0 + # via + # pynndescent + # umap-learn numpy==1.26.2 # via - # SMACT (pyproject.toml) + # SMACT (setup.py) + # adjusttext # ase # contourpy + # elementembeddings + # emmet-core + # maggma + # matminer # matplotlib + # monty + # numba + # opentsne # pandas # pymatgen + # pymatviz + # scikit-learn # scipy + # seaborn # spglib + # umap-learn +opentsne==1.0.2 + # via elementembeddings +orjson==3.10.12 + # via maggma packaging==24.0 # via # matplotlib + # mongomock # plotly palettable==3.3.3 # via pymatgen -pandas==2.1.3 +pandas[output-formatting]==2.2.3 # via - # SMACT (pyproject.toml) + # SMACT (setup.py) + # maggma + # matminer # pymatgen + # pymatviz + # seaborn +paramiko==3.5.0 + # via sshtunnel pathos==0.3.2 - # via SMACT (pyproject.toml) + # via SMACT (setup.py) pillow==10.4.0 # via matplotlib -plotly==5.22.0 - # via pymatgen +plotly==5.24.1 + # via + # dash + # pymatgen + # pymatviz pox==0.3.4 # via pathos ppft==1.7.6.8 # via pathos pybtex==0.24.0 - # via pymatgen -pymatgen==2024.5.1 - # via SMACT (pyproject.toml) + # via + # emmet-core + # pymatgen +pycparser==2.22 + # via cffi +pydantic==2.9.2 + # via + # SMACT (setup.py) + # emmet-core + # maggma + # pydantic-settings +pydantic-core==2.23.4 + # via pydantic +pydantic-settings==2.6.1 + # via + # emmet-core + # maggma +pydash==8.0.4 + # via maggma +pymatgen==2024.11.13 + # via + # SMACT (setup.py) + # elementembeddings + # emmet-core + # matminer + # mp-api + # pymatviz +pymatviz==0.14.0 + # via SMACT (setup.py) +pymongo==4.10.1 + # via + # maggma + # matminer +pynacl==1.5.0 + # via paramiko +pynndescent==0.5.13 + # via umap-learn pyparsing==3.1.1 # via matplotlib python-dateutil==2.9.0.post0 # via + # botocore + # maggma # matplotlib # pandas +python-dotenv==1.0.1 + # via pydantic-settings pytz==2024.1 - # via pandas + # via + # mongomock + # pandas pyyaml==6.0.1 # via pybtex +pyzmq==26.2.0 + # via maggma +referencing==0.35.1 + # via + # jsonschema + # jsonschema-specifications requests==2.32.3 - # via pymatgen + # via + # dash + # matminer + # mp-api + # pymatgen +retrying==1.3.4 + # via dash +rpds-py==0.21.0 + # via + # jsonschema + # referencing ruamel-yaml==0.18.6 - # via pymatgen + # via + # maggma + # monty + # pymatgen ruamel-yaml-clib==0.2.8 # via ruamel-yaml -scipy==1.11.4 +s3transfer==0.10.4 + # via boto3 +scikit-learn==1.5.2 + # via + # elementembeddings + # matminer + # opentsne + # pymatviz + # pynndescent + # umap-learn +scipy==1.14.1 # via - # SMACT (pyproject.toml) + # SMACT (setup.py) + # adjusttext # ase + # elementembeddings + # opentsne # pymatgen + # pymatviz + # pynndescent + # scikit-learn + # umap-learn +seaborn==0.13.2 + # via + # SMACT (setup.py) + # elementembeddings +sentinels==1.0.0 + # via mongomock six==1.16.0 # via # latexcodec # pybtex # python-dateutil -spglib==2.3.1 + # retrying +smart-open==7.0.5 + # via mp-api +spglib==2.5.0 # via - # SMACT (pyproject.toml) + # SMACT (setup.py) # pymatgen +sshtunnel==0.4.0 + # via maggma sympy==1.12 - # via pymatgen + # via + # matminer + # pymatgen tabulate==0.9.0 - # via pymatgen + # via + # pandas + # pymatgen tenacity==8.2.3 # via plotly +threadpoolctl==3.5.0 + # via scikit-learn tqdm==4.66.4 - # via pymatgen + # via + # maggma + # matminer + # pymatgen + # umap-learn typing-extensions==4.12.2 - # via SMACT (pyproject.toml) + # via + # SMACT (setup.py) + # dash + # elementembeddings + # emmet-core + # mp-api + # pydantic + # pydantic-core + # pydash tzdata==2024.1 # via pandas +umap-learn==0.5.3 + # via + # SMACT (setup.py) + # elementembeddings uncertainties==3.2.2 # via pymatgen urllib3==2.2.2 - # via requests + # via + # botocore + # requests +werkzeug==3.0.6 + # via + # dash + # flask +wrapt==1.17.0 + # via smart-open +zipp==3.21.0 + # via importlib-metadata + +# The following packages are considered to be unsafe in a requirements file: +# setuptools From b5b58c1e62e138b5602d44760bc8cd628df6947f Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:59:28 -0500 Subject: [PATCH 27/62] Remove os.PathLike type in docstrings --- smact/utils/oxidation.py | 5 ++--- 1 file changed, 2 insertions(+), 3 deletions(-) diff --git a/smact/utils/oxidation.py b/smact/utils/oxidation.py index b5cbae74..405a3893 100644 --- a/smact/utils/oxidation.py +++ b/smact/utils/oxidation.py @@ -2,7 +2,6 @@ from __future__ import annotations -import os from os import path import pandas as pd @@ -112,7 +111,7 @@ def get_species_occurrences_df( def write( self, - filename: str | os.PathLike, + filename: str, threshold: int, include_zero: bool = False, comment: str | None = None, @@ -120,7 +119,7 @@ def write( """Write the filtered ICSD 24 oxidation states list to a SMACT-compatible oxidation states txt file. Args: - filename (str | os.PathLike): The filename to write the filtered oxidation states list to. + filename (str): The filename to write the filtered oxidation states list to. threshold (int): The threshold for filtering the oxidation states list. include_zero (bool): Include oxidation state of zero in the filtered list. Default is False. comment (str): A comment to include in the txt file. Default is None. From 961bdf6f00451ec927ecbbcec8eb5c489487e002 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 09:59:43 -0500 Subject: [PATCH 28/62] Add return type hinting --- smact/utils/crystal_space/generate_composition_with_smact.py | 4 ++-- 1 file changed, 2 insertions(+), 2 deletions(-) diff --git a/smact/utils/crystal_space/generate_composition_with_smact.py b/smact/utils/crystal_space/generate_composition_with_smact.py index 81c43e15..690b6292 100644 --- a/smact/utils/crystal_space/generate_composition_with_smact.py +++ b/smact/utils/crystal_space/generate_composition_with_smact.py @@ -18,7 +18,7 @@ warnings.simplefilter(action="ignore", category=UserWarning) -def convert_formula(combinations: list, num_elements: int, max_stoich: int): +def convert_formula(combinations: list, num_elements: int, max_stoich: int) -> list: """Convert combinations into chemical formula. Args: @@ -44,7 +44,7 @@ def generate_composition_with_smact( max_atomic_num: int = 103, num_processes: int | None = None, save_path: str | None = None, -): +) -> pd.DataFrame: """ Generate all possible compositions of a given number of elements and filter them with SMACT. From d2b0d6e03566fed1e2ec2d317d9849effc5a3ee0 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:00:14 -0500 Subject: [PATCH 29/62] Add links in tutorial notebooks --- docs/tutorials/crystal_space.ipynb | 4 ++-- docs/tutorials/crystal_space_visualisation.ipynb | 2 +- 2 files changed, 3 insertions(+), 3 deletions(-) diff --git a/docs/tutorials/crystal_space.ipynb b/docs/tutorials/crystal_space.ipynb index a924d0f0..76de9f28 100644 --- a/docs/tutorials/crystal_space.ipynb +++ b/docs/tutorials/crystal_space.ipynb @@ -44,7 +44,7 @@ "\n", "First, we'll create binary chemical compositions using the SMACT filter. The SMACT filter is a smart tool that helps us select compositions based on important chemical rules, such as oxidation states and electronegativity.\n", "\n", - "To generate these compositions, we'll use a function called [`generate_composition_with_smact`](../smact/utils/generate_composition_with_smact.py). This function allows us to enumerate all possible binary compositions and filter them based on the SMACT rules. \n", + "To generate these compositions, we'll use a function called [`generate_composition_with_smact`](../../smact/utils/crystal_space/generate_composition_with_smact.py). This function allows us to enumerate all possible binary compositions and filter them based on the SMACT rules. \n", "\n", "### Key parameters:\n", "- `num_elements`: Number of elements in the composition (e.g., 2 for binary).\n", @@ -127,7 +127,7 @@ "source": [ "Next, we download data from the `Materials Project api` using the `download_mp_data` function. This function allows us to download data for a given number of elements and maximum stoichiometry. The data includes the chemical formula, energy, and other properties of the compounds.\n", "\n", - "[`download_mp_data`](../smact/utils/download_compounds_with_mp_api.py) function takes in the following parameters:\n", + "[`download_mp_data`](../../smact/utils/crystal_space/download_compounds_with_mp_api.py) function takes in the following parameters:\n", "\n", "### Key parameters:\n", "- `mp_api_key`: your Materials Project API key\n", diff --git a/docs/tutorials/crystal_space_visualisation.ipynb b/docs/tutorials/crystal_space_visualisation.ipynb index 57001929..19cab5f0 100644 --- a/docs/tutorials/crystal_space_visualisation.ipynb +++ b/docs/tutorials/crystal_space_visualisation.ipynb @@ -11,7 +11,7 @@ "cell_type": "markdown", "metadata": {}, "source": [ - "(prerequisite: [crystal_space_with_smact.ipynb](./crystal_space_with_smact.ipynb))\n", + "(prerequisite: [crystal_space.ipynb](./crystal_space.ipynb))\n", "\n", "In this tutorial, we will use the dimension reduction techniques to visualise a large crystal space. We will use the following techniques:\n", "\n", From 10a1f1dc1ea184a22bc6ee5531f0a0d29218c6c5 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:03:56 -0500 Subject: [PATCH 30/62] Update deprecated jupyter_execute_notebooks to nb_execution_mode --- docs/conf.py | 4 ++-- 1 file changed, 2 insertions(+), 2 deletions(-) diff --git a/docs/conf.py b/docs/conf.py index 9d4a434d..31ddd512 100644 --- a/docs/conf.py +++ b/docs/conf.py @@ -45,7 +45,7 @@ "html_image", ] myst_url_schemes = ("http", "https", "mailto") -jupyter_execute_notebooks = "off" +nb_execution_mode = "off" # Add any paths that contain templates here, relative to this directory. templates_path = ["_templates"] @@ -154,7 +154,7 @@ # Add any paths that contain custom static files (such as style sheets) here, # relative to this directory. They are copied after the builtin static files, # so a file named "default.css" will overwrite the builtin "default.css". -html_static_path = ["_static"] +# html_static_path = ["_static"] # Add any extra paths that contain custom files (such as robots.txt or # .htaccess) here, relative to this directory. These files are copied From 79e896c37c30151007c3708b951770e9113983bf Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:04:36 -0500 Subject: [PATCH 31/62] Render plotly figs as png to show on GitHub and the Documentation site --- .../filtering_icsd_oxidation_states.ipynb | 3803 +---------------- 1 file changed, 18 insertions(+), 3785 deletions(-) diff --git a/docs/tutorials/filtering_icsd_oxidation_states.ipynb b/docs/tutorials/filtering_icsd_oxidation_states.ipynb index 00187916..49edf5e5 100644 --- a/docs/tutorials/filtering_icsd_oxidation_states.ipynb +++ b/docs/tutorials/filtering_icsd_oxidation_states.ipynb @@ -66,6 +66,7 @@ "import matplotlib.pyplot as plt\n", "import dash\n", "import plotly.graph_objects as go\n", + "import plotly.io as pio\n", "from dash.dependencies import Input, Output\n", "from mpl_toolkits.axes_grid1.inset_locator import inset_axes\n", "import pymatviz as pmv\n", @@ -77,6 +78,11 @@ "import pandas as pd\n", "from pandarallel import pandarallel\n", "from pprint import pprint\n", + "# Interactive plotly figures don't show up on GitHub.\n", + "# https://github.com/plotly/plotly.py/issues/931\n", + "# change renderer from \"svg\" to \"notebook\" to get hover tooltips back\n", + "# (but blank plots on GitHub!)\n", + "pio.renderers.default = \"png\"\n", "sns.set_theme(context=\"notebook\", style=\"ticks\", palette=\"colorblind\")" ] }, @@ -1007,11 +1013,11 @@ "name": "stderr", "output_type": "stream", "text": [ - "/var/folders/rl/kjl1r2w97zs97xjkrgqz3lmh0000gp/T/ipykernel_71248/3393384947.py:43: UserWarning:\n", + "/var/folders/rl/kjl1r2w97zs97xjkrgqz3lmh0000gp/T/ipykernel_83064/3393384947.py:43: UserWarning:\n", "\n", "This figure includes Axes that are not compatible with tight_layout, so results might be incorrect.\n", "\n", - "/var/folders/rl/kjl1r2w97zs97xjkrgqz3lmh0000gp/T/ipykernel_71248/3393384947.py:43: UserWarning:\n", + "/var/folders/rl/kjl1r2w97zs97xjkrgqz3lmh0000gp/T/ipykernel_83064/3393384947.py:43: UserWarning:\n", "\n", "The figure layout has changed to tight\n", "\n" @@ -1094,7 +1100,7 @@ "name": "stderr", "output_type": "stream", "text": [ - "/var/folders/rl/kjl1r2w97zs97xjkrgqz3lmh0000gp/T/ipykernel_71248/2663350812.py:15: FutureWarning:\n", + "/var/folders/rl/kjl1r2w97zs97xjkrgqz3lmh0000gp/T/ipykernel_83064/2663350812.py:15: FutureWarning:\n", "\n", "We return_type='figure' over return_type='axes' for more consistent results.\n", "This will become the default after 2025-07.\n", @@ -1156,3780 +1162,7 @@ "outputs": [ { "data": { - 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Oxidation states: ", - "Thorium (Th)
Value: 1 (0.54%)
Oxidation states: 4", - "Protactinium (Pa)
Oxidation states: ", - "Uranium (U)
Value: 4 (2.15%)
Oxidation states: 3 4 5 6", - "Neptunium (Np)
Value: 1 (0.54%)
Oxidation states: 6", - "Plutonium (Pu)
Oxidation states: ", - "Americium (Am)
Oxidation states: ", - "Curium (Cm)
Oxidation states: ", - "Berkelium (Bk)
Oxidation states: ", - "Californium (Cf)
Oxidation states: ", - "Einsteinium (Es)
Oxidation states: ", - "Fermium (Fm)", - "Mendelevium (Md)", - "Nobelium (No)", - "Lawrencium (Lr)", - "" - ], - [ - "", - "", - "Lanthanum (La)
Value: 1 (0.54%)
Oxidation states: 3", - "Cerium (Ce)
Value: 2 (1.08%)
Oxidation states: 3 4", - "Praseodymium (Pr)
Value: 2 (1.08%)
Oxidation states: 3 4", - "Neodymium (Nd)
Value: 1 (0.54%)
Oxidation states: 3", - "Promethium (Pm)
Oxidation states: ", - "Samarium (Sm)
Value: 2 (1.08%)
Oxidation states: 2 3", - "Europium (Eu)
Value: 2 (1.08%)
Oxidation states: 2 3", - "Gadolinium (Gd)
Value: 1 (0.54%)
Oxidation states: 3", - "Terbium (Tb)
Value: 2 (1.08%)
Oxidation states: 3 4", - "Dysprosium (Dy)
Value: 1 (0.54%)
Oxidation states: 3", - "Holmium (Ho)
Value: 1 (0.54%)
Oxidation states: 3", - "Erbium (Er)
Value: 1 (0.54%)
Oxidation states: 3", - "Thulium (Tm)
Value: 1 (0.54%)
Oxidation states: 3", - "Ytterbium (Yb)
Value: 2 (1.08%)
Oxidation states: 2 3", - "Lutetium (Lu)
Value: 1 (0.54%)
Oxidation states: 3", - "" - ], - [ - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "", - "" - ], - [ - "Francium (Fr)", - "Radium (Ra)
Oxidation states: ", - "", - "Rutherfordium (Rf)", - "Dubnium (Db)", - "Seaborgium (Sg)", - "Bohrium (Bh)", - "Hassium (Hs)", - "Meitnerium (Mt)", - "Darmstadtium (Ds)", - "Roentgenium (Rg)", - "Copernicium (Cn)", - "Nihonium (Nh)", - "Flerovium (Fl)", - "Moscovium (Mc)", - "Livermorium (Lv)", - "Tennessine (Ts)", - "Oganesson (Og)" - ], - [ - "Cesium (Cs)
Value: 1 (0.54%)
Oxidation states: 1", - "Barium (Ba)
Value: 1 (0.54%)
Oxidation states: 2", - "", - "Hafnium (Hf)
Value: 1 (0.54%)
Oxidation states: 4", - "Tantalum (Ta)
Value: 2 (1.08%)
Oxidation states: 4 5", - "Tungsten (W)
Value: 3 (1.61%)
Oxidation states: 4 5 6", - "Rhenium (Re)
Value: 5 (2.69%)
Oxidation states: 3 4 5 6 7", - "Osmium (Os)
Value: 1 (0.54%)
Oxidation states: 5", - "Iridium (Ir)
Value: 3 (1.61%)
Oxidation states: 3 4 5", - "Platinum (Pt)
Value: 2 (1.08%)
Oxidation states: 2 4", - "Gold (Au)
Value: 2 (1.08%)
Oxidation states: 1 3", - "Mercury (Hg)
Value: 2 (1.08%)
Oxidation states: 1 2", - "Thallium (Tl)
Value: 2 (1.08%)
Oxidation states: 1 3", - "Lead (Pb)
Value: 2 (1.08%)
Oxidation states: 2 4", - "Bismuth (Bi)
Value: 3 (1.61%)
Oxidation states: -3 3 5", - "Polonium (Po)
Oxidation states: ", - "Astatine (At)", - "Radon (Rn)" - ], - [ - "Rubidium (Rb)
Value: 1 (0.54%)
Oxidation states: 1", - "Strontium (Sr)
Value: 1 (0.54%)
Oxidation states: 2", - "Yttrium (Y)
Value: 1 (0.54%)
Oxidation states: 3", - "Zirconium (Zr)
Value: 1 (0.54%)
Oxidation states: 4", - "Niobium (Nb)
Value: 3 (1.61%)
Oxidation states: 3 4 5", - "Molybdenum (Mo)
Value: 5 (2.69%)
Oxidation states: 2 3 4 5 6", - "Technetium (Tc)
Oxidation states: ", - "Ruthenium (Ru)
Value: 4 (2.15%)
Oxidation states: 2 3 4 5", - "Rhodium (Rh)
Value: 2 (1.08%)
Oxidation states: 3 4", - "Palladium (Pd)
Value: 2 (1.08%)
Oxidation states: 2 4", - "Silver (Ag)
Value: 2 (1.08%)
Oxidation states: 1 2", - "Cadmium (Cd)
Value: 1 (0.54%)
Oxidation states: 2", - "Indium (In)
Value: 3 (1.61%)
Oxidation states: 1 2 3", - "Tin (Sn)
Value: 2 (1.08%)
Oxidation states: 2 4", - "Antimony (Sb)
Value: 5 (2.69%)
Oxidation states: -3 -2 -1 3 5", - "Tellurium (Te)
Value: 4 (2.15%)
Oxidation states: -2 -1 4 6", - "Iodine (I)
Value: 3 (1.61%)
Oxidation states: -1 5 7", - "Xenon (Xe)
Oxidation states: " - ], - [ - "Potassium (K)
Value: 1 (0.54%)
Oxidation states: 1", - "Calcium (Ca)
Value: 1 (0.54%)
Oxidation states: 2", - "Scandium (Sc)
Value: 1 (0.54%)
Oxidation states: 3", - "Titanium (Ti)
Value: 3 (1.61%)
Oxidation states: 2 3 4", - "Vanadium (V)
Value: 4 (2.15%)
Oxidation states: 2 3 4 5", - "Chromium (Cr)
Value: 5 (2.69%)
Oxidation states: 2 3 4 5 6", - "Manganese (Mn)
Value: 3 (1.61%)
Oxidation states: 2 3 4", - "Iron (Fe)
Value: 3 (1.61%)
Oxidation states: 2 3 4", - "Cobalt (Co)
Value: 3 (1.61%)
Oxidation states: 2 3 4", - "Nickel (Ni)
Value: 3 (1.61%)
Oxidation states: 1 2 3", - "Copper (Cu)
Value: 3 (1.61%)
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Value: 1 (0.54%)
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Value: 1 (0.54%)
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Value: 3 (1.61%)
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Value: 6 (3.23%)
Oxidation states: -3 -2 -1 2 3 5", - "Selenium (Se)
Value: 4 (2.15%)
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Value: 2 (1.08%)
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Value: 1 (0.54%)
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Value: 1 (0.54%)
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Value: 1 (0.54%)
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Value: 2 (1.08%)
Oxidation states: -4 4", - "Phosphorus (P)
Value: 6 (3.23%)
Oxidation states: -3 -2 -1 3 4 5", - "Sulfur (S)
Value: 5 (2.69%)
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Value: 2 (1.08%)
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Value: 8 (4.30%)
Oxidation states: -4 -3 -2 -1 1 2 3 4", - "Nitrogen (N)
Value: 7 (3.76%)
Oxidation states: -3 -2 -1 1 2 3 5", - "Oxygen (O)
Value: 2 (1.08%)
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Value: 1 (0.54%)
Oxidation states: -1", - "Neon (Ne)" - ], - [ - "Hydrogen (H)
Value: 2 (1.08%)
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" }, "metadata": {}, "output_type": "display_data" @@ -5012,7 +1245,7 @@ " " + "" ] }, "metadata": {}, @@ -5220,7 +1453,7 @@ { "data": { "application/vnd.jupyter.widget-view+json": { - "model_id": "22bd02a63acd4621a55982e66730de47", + "model_id": "36868fbeb12e459bab9ade3d9a62ed8a", "version_major": 2, "version_minor": 0 }, @@ -5506,7 +1739,7 @@ { "data": { "application/vnd.jupyter.widget-view+json": { - "model_id": "d7ea7ffeff4e4466ac621cdead12bbab", + "model_id": "bea10270b98341d6afda4fc7cac3cc34", "version_major": 2, "version_minor": 0 }, @@ -5520,7 +1753,7 @@ { "data": { "application/vnd.jupyter.widget-view+json": { - "model_id": "7f94c5ee182c4eb5832edef0a3fb5e99", + "model_id": "5098ee9775134d2f8612805d6c1f5f31", "version_major": 2, "version_minor": 0 }, @@ -5534,7 +1767,7 @@ { "data": { "application/vnd.jupyter.widget-view+json": { - "model_id": "f1563c536eb44fc5810d7dee31bde0b9", + "model_id": "ccc75dce04e84b69acc88bd8048db1c2", "version_major": 2, "version_minor": 0 }, @@ -5548,7 +1781,7 @@ { "data": { "application/vnd.jupyter.widget-view+json": { - "model_id": "cb9175626b6a4bdc967cb3780372a420", + "model_id": "c0bb7f1befd84a9fa6764c198133f491", "version_major": 2, "version_minor": 0 }, @@ -5562,7 +1795,7 @@ { "data": { "application/vnd.jupyter.widget-view+json": { - "model_id": "569fabfb8889499cbb5856d93c2335e4", + "model_id": "3861e36673d543378b20f9ed9ee18fe3", "version_major": 2, "version_minor": 0 }, From ef0a41b3e8826f16f3256870c67520034c60b4ba Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:04:55 -0500 Subject: [PATCH 32/62] Fix typo --- docs/smact.utils.crystal_space.rst | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/docs/smact.utils.crystal_space.rst b/docs/smact.utils.crystal_space.rst index e99a82d0..14905cec 100644 --- a/docs/smact.utils.crystal_space.rst +++ b/docs/smact.utils.crystal_space.rst @@ -1,7 +1,7 @@ SMACT Utilities Crystal Space Module =========================== -Utility functions associated with our `Faraday Dicussions publication 'Mapping Inorganic Crystal Space' `_ using SMACT +Utility functions associated with our `Faraday Discussions publication 'Mapping Inorganic Crystal Space' `_ using SMACT Submodules From 2a511e547b6cc84bf53f1acbbb70e5db3a05915e Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:05:08 -0500 Subject: [PATCH 33/62] Update docs --- docs/examples.rst | 1 - ...smact.utils.crystal_space.download_compounds_with_mp_api.rst | 2 +- 2 files changed, 1 insertion(+), 2 deletions(-) diff --git a/docs/examples.rst b/docs/examples.rst index 2cbc9cd8..52954a7f 100644 --- a/docs/examples.rst +++ b/docs/examples.rst @@ -15,7 +15,6 @@ For workflows that have been used in real examples and in published work, visit examples/filter examples/validity examples/lists - examples/neutral_combos examples/oxidation_states examples/compound_electroneg examples/valence_electron_count diff --git a/docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst b/docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst index d930a731..192ad9e9 100644 --- a/docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst +++ b/docs/smact.utils.crystal_space.download_compounds_with_mp_api.rst @@ -1,4 +1,4 @@ -Crystal Space Materials Project Data Retrieval Module +Crystal Space Materials Project Data Retrieval Module =========================== From 39b21e05638c9cf08e2005cff0c0bbe2329ea027 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:09:32 -0500 Subject: [PATCH 34/62] Fix headers --- docs/examples/doper.ipynb | 3 ++- docs/tutorials/oxidation_states.ipynb | 2 +- 2 files changed, 3 insertions(+), 2 deletions(-) diff --git a/docs/examples/doper.ipynb b/docs/examples/doper.ipynb index ab1d06db..6eeb2cc5 100644 --- a/docs/examples/doper.ipynb +++ b/docs/examples/doper.ipynb @@ -11,7 +11,8 @@ "\n", "By default, the top five p-type and n-type candidates are reported. Use the `num_dopants` input to modify the number of outputs.\n", "\n", - "### Output Format\n", + "**Output Format**\n", + "\n", "The output is a dictionary with keys:\n", "- \"n_type_cation\"\n", "- \"p_type_cation\"\n", diff --git a/docs/tutorials/oxidation_states.ipynb b/docs/tutorials/oxidation_states.ipynb index b567b088..b3602dd4 100644 --- a/docs/tutorials/oxidation_states.ipynb +++ b/docs/tutorials/oxidation_states.ipynb @@ -4,7 +4,7 @@ "cell_type": "markdown", "metadata": {}, "source": [ - "## Filtering a search space using oxidation states\n", + "# Filtering a search space using oxidation states\n", "\n", "Let's attempt to perform the first steps in a high-throughput compound design workflow which involves:\n", "\n", From ac6604f59c9e2d4046962bc4a954cad136bc02b7 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:09:42 -0500 Subject: [PATCH 35/62] Fix comment --- docs/tutorials/filtering_icsd_oxidation_states.ipynb | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/docs/tutorials/filtering_icsd_oxidation_states.ipynb b/docs/tutorials/filtering_icsd_oxidation_states.ipynb index 49edf5e5..2e225c5d 100644 --- a/docs/tutorials/filtering_icsd_oxidation_states.ipynb +++ b/docs/tutorials/filtering_icsd_oxidation_states.ipynb @@ -80,7 +80,7 @@ "from pprint import pprint\n", "# Interactive plotly figures don't show up on GitHub.\n", "# https://github.com/plotly/plotly.py/issues/931\n", - "# change renderer from \"svg\" to \"notebook\" to get hover tooltips back\n", + "# change renderer from \"png\" to \"notebook\" to get hover tooltips back\n", "# (but blank plots on GitHub!)\n", "pio.renderers.default = \"png\"\n", "sns.set_theme(context=\"notebook\", style=\"ticks\", palette=\"colorblind\")" From 08f5d2692fb7645fd58c2eff6893a2fa2dd46f50 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:42:09 -0500 Subject: [PATCH 36/62] Update link to examples in README --- README.md | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/README.md b/README.md index 1377584e..496c4d1b 100644 --- a/README.md +++ b/README.md @@ -17,7 +17,7 @@ **Semiconducting Materials from Analogy and Chemical Theory** (SMACT) is a collection of rapid screening and informatics tools that uses data about chemical elements. - **Documentation:** -- **Examples:** +- **Examples:** ![A blue interface with the text "SMACT v3" at the top. Below that, there is a label "Materials Search" followed by two radio buttons: "Hi-fi" and "Lo-fi". The "Lo-fi" button is currently selected](SMACT.png) From 9c823f4417f35cef1deea1f4631e14afa7f50c36 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 10:42:23 -0500 Subject: [PATCH 37/62] Update readthedocs config file --- .readthedocs.yaml | 1 + 1 file changed, 1 insertion(+) diff --git a/.readthedocs.yaml b/.readthedocs.yaml index 51fa3128..2d3a3a7a 100644 --- a/.readthedocs.yaml +++ b/.readthedocs.yaml @@ -13,3 +13,4 @@ sphinx: python: install: - requirements: docs/requirements.txt + - requirements: requirements.txt From e48be492d0403b7a297669d50e588635dc7d9cdf Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 11:16:36 -0500 Subject: [PATCH 38/62] Add optional extras --- pyproject.toml | 15 +++++++++++++++ 1 file changed, 15 insertions(+) diff --git a/pyproject.toml b/pyproject.toml index 0d118ac9..5f0d4101 100644 --- a/pyproject.toml +++ b/pyproject.toml @@ -92,6 +92,21 @@ visualisation = [ "dash", ] +optional = [ + "pydantic>=2.9.2", + "mp-api>=0.42.2", + "pymatviz>=0.14", + "seaborn>=0.13.2", + "pymatgen>=2024.2.20", + "matminer>=0.9.2", + "umap-learn>=0.5.3", + "kaleido>=0.2.1", + "ase>=3.22.0", + "numpy", + "ElementEmbeddings>=0.4", + "dash>=2.18.2", + +] strict = [ "pydantic==2.9.2", "mp-api==0.42.2", From 2377b158b941910032f72a1ed5b350a3ee26342c Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 11:16:45 -0500 Subject: [PATCH 39/62] Update ci --- .github/workflows/ci.yml | 29 ++++++++++++++++++++--------- 1 file changed, 20 insertions(+), 9 deletions(-) diff --git a/.github/workflows/ci.yml b/.github/workflows/ci.yml index 88ae0fec..9d22ebed 100644 --- a/.github/workflows/ci.yml +++ b/.github/workflows/ci.yml @@ -23,20 +23,31 @@ jobs: runs-on: ${{matrix.os}} steps: - - uses: actions/checkout@v4 - - name: Set up Python ${{ matrix.python-version }} - uses: actions/setup-python@v5 - with: - python-version: ${{ matrix.python-version }} + - name: Checkout repository + uses: actions/checkout@v4 + + - name: Set up micromamba + uses: mamba-org/setup-micromamba@main + + - name: Create mamba environment + run: | + micromamba create -n smact_env python=${{ matrix.python-version }} --yes + - name: Install dependencies run: | - python -m pip install --upgrade pip wheel setuptools - pip install -e ".[crystal_space,dev]" - pip install pytest-cov + micromamba activate smact_env + pip install uv + uv pip install build + python -m build --wheel + uv pip install dist/*.whl + uv pip install smact[dev,optional] + - name: Run tests and collect coverage env: MP_API_KEY: ${{ secrets.MP_API_KEY }} - run: python -m pytest --cov=smact --cov-report=xml -v + run: | + micromamba activate smact_env + python -m pytest --cov=smact --cov-report=xml -v - name: Upload coverage reports to CodeCov uses: codecov/codecov-action@v4 with: From 734b84736b9ad5fe203ff3f9e844ff2420648968 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 11:24:14 -0500 Subject: [PATCH 40/62] Revert "Update ci" This reverts commit 2377b158b941910032f72a1ed5b350a3ee26342c. --- .github/workflows/ci.yml | 29 +++++++++-------------------- 1 file changed, 9 insertions(+), 20 deletions(-) diff --git a/.github/workflows/ci.yml b/.github/workflows/ci.yml index 9d22ebed..88ae0fec 100644 --- a/.github/workflows/ci.yml +++ b/.github/workflows/ci.yml @@ -23,31 +23,20 @@ jobs: runs-on: ${{matrix.os}} steps: - - name: Checkout repository - uses: actions/checkout@v4 - - - name: Set up micromamba - uses: mamba-org/setup-micromamba@main - - - name: Create mamba environment - run: | - micromamba create -n smact_env python=${{ matrix.python-version }} --yes - + - uses: actions/checkout@v4 + - name: Set up Python ${{ matrix.python-version }} + uses: actions/setup-python@v5 + with: + python-version: ${{ matrix.python-version }} - name: Install dependencies run: | - micromamba activate smact_env - pip install uv - uv pip install build - python -m build --wheel - uv pip install dist/*.whl - uv pip install smact[dev,optional] - + python -m pip install --upgrade pip wheel setuptools + pip install -e ".[crystal_space,dev]" + pip install pytest-cov - name: Run tests and collect coverage env: MP_API_KEY: ${{ secrets.MP_API_KEY }} - run: | - micromamba activate smact_env - python -m pytest --cov=smact --cov-report=xml -v + run: python -m pytest --cov=smact --cov-report=xml -v - name: Upload coverage reports to CodeCov uses: codecov/codecov-action@v4 with: From a2ca9183dd2f824f84bd969913726e6b407ff600 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 11:26:58 -0500 Subject: [PATCH 41/62] Add UV to CI --- .github/workflows/ci.yml | 14 ++++++++++---- 1 file changed, 10 insertions(+), 4 deletions(-) diff --git a/.github/workflows/ci.yml b/.github/workflows/ci.yml index 88ae0fec..4db0b967 100644 --- a/.github/workflows/ci.yml +++ b/.github/workflows/ci.yml @@ -23,16 +23,22 @@ jobs: runs-on: ${{matrix.os}} steps: - - uses: actions/checkout@v4 + - name: Checkout repository + uses: actions/checkout@v4 + - name: Set up Python ${{ matrix.python-version }} uses: actions/setup-python@v5 with: python-version: ${{ matrix.python-version }} + cache: pip + cache-dependency-path: pyproject.toml + + - name: Install dependencies run: | - python -m pip install --upgrade pip wheel setuptools - pip install -e ".[crystal_space,dev]" - pip install pytest-cov + pip install uv + uv pip install -e ".[optional,dev]" --system + - name: Run tests and collect coverage env: MP_API_KEY: ${{ secrets.MP_API_KEY }} From f59baf817732fcd3cf1fb2650ec7c7348d9896f1 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 11:53:38 -0500 Subject: [PATCH 42/62] Run pre-commit --- .github/workflows/ci.yml | 3 +-- 1 file changed, 1 insertion(+), 2 deletions(-) diff --git a/.github/workflows/ci.yml b/.github/workflows/ci.yml index 4db0b967..68f03e6e 100644 --- a/.github/workflows/ci.yml +++ b/.github/workflows/ci.yml @@ -33,12 +33,11 @@ jobs: cache: pip cache-dependency-path: pyproject.toml - - name: Install dependencies run: | pip install uv uv pip install -e ".[optional,dev]" --system - + - name: Run tests and collect coverage env: MP_API_KEY: ${{ secrets.MP_API_KEY }} From d5afb0687893adfa2d46af8475b99c8a811a4cb2 Mon Sep 17 00:00:00 2001 From: "dependabot[bot]" <49699333+dependabot[bot]@users.noreply.github.com> Date: Sun, 1 Dec 2024 17:21:50 +0000 Subject: [PATCH 43/62] Bump numpy from 1.26.2 to 2.1.3 Bumps [numpy](https://github.com/numpy/numpy) from 1.26.2 to 2.1.3. - [Release notes](https://github.com/numpy/numpy/releases) - [Changelog](https://github.com/numpy/numpy/blob/main/doc/RELEASE_WALKTHROUGH.rst) - [Commits](https://github.com/numpy/numpy/compare/v1.26.2...v2.1.3) --- updated-dependencies: - dependency-name: numpy dependency-type: direct:production update-type: version-update:semver-major ... Signed-off-by: dependabot[bot] --- pyproject.toml | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/pyproject.toml b/pyproject.toml index 5f0d4101..2f1bdc7d 100644 --- a/pyproject.toml +++ b/pyproject.toml @@ -39,7 +39,7 @@ keywords = [ ] dependencies = [ "ase", - "numpy<2", + "numpy<3", "pandas", "pathos", "pymatgen>=2024.2.20", From 940808807bc49805d4d273b65d803a53f23625ac Mon Sep 17 00:00:00 2001 From: "dependabot[bot]" <49699333+dependabot[bot]@users.noreply.github.com> Date: Sun, 1 Dec 2024 17:21:56 +0000 Subject: [PATCH 44/62] Bump myst-nb from 1.1.1 to 1.1.2 Bumps [myst-nb](https://github.com/executablebooks/myst-nb) from 1.1.1 to 1.1.2. - [Release notes](https://github.com/executablebooks/myst-nb/releases) - [Changelog](https://github.com/executablebooks/MyST-NB/blob/master/CHANGELOG.md) - [Commits](https://github.com/executablebooks/myst-nb/compare/v1.1.1...v1.1.2) --- updated-dependencies: - dependency-name: myst-nb dependency-type: direct:production update-type: version-update:semver-patch ... Signed-off-by: dependabot[bot] --- docs/requirements.in | 2 +- pyproject.toml | 2 +- 2 files changed, 2 insertions(+), 2 deletions(-) diff --git a/docs/requirements.in b/docs/requirements.in index 7ccc64b1..4baccf92 100644 --- a/docs/requirements.in +++ b/docs/requirements.in @@ -3,4 +3,4 @@ sphinx==5.3.0 sphinx_rtd_theme==2.0.0 readthedocs-sphinx-search==0.3.2 sphinx-book-theme==1.1.3 -myst-nb==1.1.1 +myst-nb==1.1.2 diff --git a/pyproject.toml b/pyproject.toml index 5f0d4101..acf75f79 100644 --- a/pyproject.toml +++ b/pyproject.toml @@ -71,7 +71,7 @@ docs = [ "sphinx_rtd_theme==2.0.0", "readthedocs-sphinx-search==0.3.2", "sphinx-book-theme==1.1.3", - "myst-nb==1.1.1" + "myst-nb==1.1.2" ] mp = ["mp-api"] From 29b0088d5c271ae901e50c685458d0893537a8ec Mon Sep 17 00:00:00 2001 From: "dependabot[bot]" <49699333+dependabot[bot]@users.noreply.github.com> Date: Sun, 1 Dec 2024 17:22:15 +0000 Subject: [PATCH 45/62] Bump pytest from 8.3.2 to 8.3.4 Bumps [pytest](https://github.com/pytest-dev/pytest) from 8.3.2 to 8.3.4. - [Release notes](https://github.com/pytest-dev/pytest/releases) - [Changelog](https://github.com/pytest-dev/pytest/blob/main/CHANGELOG.rst) - [Commits](https://github.com/pytest-dev/pytest/compare/8.3.2...8.3.4) --- updated-dependencies: - dependency-name: pytest dependency-type: direct:development update-type: version-update:semver-patch ... Signed-off-by: dependabot[bot] --- requirements-dev.txt | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/requirements-dev.txt b/requirements-dev.txt index 5c40b667..04840857 100644 --- a/requirements-dev.txt +++ b/requirements-dev.txt @@ -1,5 +1,5 @@ pre-commit ==3.3.3 -pytest ==8.3.2 +pytest ==8.3.4 pytest-cov ==5.0.0 ruff pyright From 6c63631ffeab34d9d4f2669be5f1013f73d7ae5c Mon Sep 17 00:00:00 2001 From: "dependabot[bot]" <49699333+dependabot[bot]@users.noreply.github.com> Date: Sun, 1 Dec 2024 17:22:20 +0000 Subject: [PATCH 46/62] Bump sphinx-rtd-theme from 2.0.0 to 3.0.2 Bumps [sphinx-rtd-theme](https://github.com/readthedocs/sphinx_rtd_theme) from 2.0.0 to 3.0.2. - [Changelog](https://github.com/readthedocs/sphinx_rtd_theme/blob/master/docs/changelog.rst) - [Commits](https://github.com/readthedocs/sphinx_rtd_theme/compare/2.0.0...3.0.2) --- updated-dependencies: - dependency-name: sphinx-rtd-theme dependency-type: direct:production update-type: version-update:semver-major ... Signed-off-by: dependabot[bot] --- docs/requirements.in | 2 +- pyproject.toml | 2 +- 2 files changed, 2 insertions(+), 2 deletions(-) diff --git a/docs/requirements.in b/docs/requirements.in index 7ccc64b1..e4c16055 100644 --- a/docs/requirements.in +++ b/docs/requirements.in @@ -1,6 +1,6 @@ # Defining the exact version will make sure things don't break sphinx==5.3.0 -sphinx_rtd_theme==2.0.0 +sphinx_rtd_theme==3.0.2 readthedocs-sphinx-search==0.3.2 sphinx-book-theme==1.1.3 myst-nb==1.1.1 diff --git a/pyproject.toml b/pyproject.toml index 5f0d4101..23bd6adf 100644 --- a/pyproject.toml +++ b/pyproject.toml @@ -68,7 +68,7 @@ dev = [ ] docs = [ "sphinx==5.3.0", - "sphinx_rtd_theme==2.0.0", + "sphinx_rtd_theme==3.0.2", "readthedocs-sphinx-search==0.3.2", "sphinx-book-theme==1.1.3", "myst-nb==1.1.1" From e1f31c520e8a1d3c67abeb04a1759aa8d41512f4 Mon Sep 17 00:00:00 2001 From: "dependabot[bot]" <49699333+dependabot[bot]@users.noreply.github.com> Date: Sun, 1 Dec 2024 17:39:25 +0000 Subject: [PATCH 47/62] Bump codecov/codecov-action from 4 to 5 Bumps [codecov/codecov-action](https://github.com/codecov/codecov-action) from 4 to 5. - [Release notes](https://github.com/codecov/codecov-action/releases) - [Changelog](https://github.com/codecov/codecov-action/blob/main/CHANGELOG.md) - [Commits](https://github.com/codecov/codecov-action/compare/v4...v5) --- updated-dependencies: - dependency-name: codecov/codecov-action dependency-type: direct:production update-type: version-update:semver-major ... Signed-off-by: dependabot[bot] --- .github/workflows/ci.yml | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/.github/workflows/ci.yml b/.github/workflows/ci.yml index 68f03e6e..d28d3936 100644 --- a/.github/workflows/ci.yml +++ b/.github/workflows/ci.yml @@ -43,7 +43,7 @@ jobs: MP_API_KEY: ${{ secrets.MP_API_KEY }} run: python -m pytest --cov=smact --cov-report=xml -v - name: Upload coverage reports to CodeCov - uses: codecov/codecov-action@v4 + uses: codecov/codecov-action@v5 with: token: ${{ secrets.CODECOV_TOKEN }} #files: ./coverage.xml From 62f43dbcb0e1320985e2f82ce5d89ee9438e8bd5 Mon Sep 17 00:00:00 2001 From: "dependabot[bot]" <49699333+dependabot[bot]@users.noreply.github.com> Date: Sun, 1 Dec 2024 18:09:23 +0000 Subject: [PATCH 48/62] Bump sphinx from 5.3.0 to 8.1.3 Bumps [sphinx](https://github.com/sphinx-doc/sphinx) from 5.3.0 to 8.1.3. - [Release notes](https://github.com/sphinx-doc/sphinx/releases) - [Changelog](https://github.com/sphinx-doc/sphinx/blob/v8.1.3/CHANGES.rst) - [Commits](https://github.com/sphinx-doc/sphinx/compare/v5.3.0...v8.1.3) --- updated-dependencies: - dependency-name: sphinx dependency-type: direct:production update-type: version-update:semver-major ... Signed-off-by: dependabot[bot] --- docs/requirements.in | 2 +- pyproject.toml | 2 +- 2 files changed, 2 insertions(+), 2 deletions(-) diff --git a/docs/requirements.in b/docs/requirements.in index 856132b5..21c20309 100644 --- a/docs/requirements.in +++ b/docs/requirements.in @@ -1,5 +1,5 @@ # Defining the exact version will make sure things don't break -sphinx==5.3.0 +sphinx==8.1.3 sphinx_rtd_theme==3.0.2 readthedocs-sphinx-search==0.3.2 sphinx-book-theme==1.1.3 diff --git a/pyproject.toml b/pyproject.toml index 35b9c2d4..418324c9 100644 --- a/pyproject.toml +++ b/pyproject.toml @@ -67,7 +67,7 @@ dev = [ "nbstripout" ] docs = [ - "sphinx==5.3.0", + "sphinx==8.1.3", "sphinx_rtd_theme==3.0.2", "readthedocs-sphinx-search==0.3.2", "sphinx-book-theme==1.1.3", From 40d6f37a5a4633b8f1a95ea31af853535d0f49f5 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 14:57:32 -0500 Subject: [PATCH 49/62] Change oxidation state defaults to icsd24 --- smact/screening.py | 8 ++++---- 1 file changed, 4 insertions(+), 4 deletions(-) diff --git a/smact/screening.py b/smact/screening.py index 65332afe..05a5511d 100644 --- a/smact/screening.py +++ b/smact/screening.py @@ -335,7 +335,7 @@ def smact_filter( threshold: int | None = 8, stoichs: list[list[int]] | None = None, species_unique: bool = True, - oxidation_states_set: str = "smact14", + oxidation_states_set: str = "icsd24", comp_tuple: bool = False, ) -> list[tuple[str, int, int]] | list[tuple[str, int]]: """Function that applies the charge neutrality and electronegativity @@ -438,7 +438,7 @@ def smact_validity( composition: pymatgen.core.Composition | str, use_pauling_test: bool = True, include_alloys: bool = True, - oxidation_states_set: str | bytes | os.PathLike = "smact14", + oxidation_states_set: str | bytes | os.PathLike = "icsd24", ) -> bool: """ Check if a composition is valid according to the SMACT rules. @@ -486,13 +486,13 @@ def smact_validity( smact_elems = [e[1] for e in space.items()] electronegs = [e.pauling_eneg for e in smact_elems] - if oxidation_states_set == "smact14" or oxidation_states_set is None: + if oxidation_states_set == "smact14": ox_combos = [e.oxidation_states_smact14 for e in smact_elems] elif oxidation_states_set == "icsd16": ox_combos = [e.oxidation_states_icsd16 for e in smact_elems] elif oxidation_states_set == "pymatgen_sp": ox_combos = [e.oxidation_states_sp for e in smact_elems] - elif oxidation_states_set == "icsd24": + elif oxidation_states_set == "icsd24" or oxidation_states_set is None: # Default ox_combos = [e.oxidation_states_icsd24 for e in smact_elems] elif os.path.exists(oxidation_states_set): ox_combos = [oxi_custom(e.symbol, oxidation_states_set) for e in smact_elems] From eeb4ba995716240e35aca73c7b62220fea1a45d4 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 14:57:50 -0500 Subject: [PATCH 50/62] Update smact_validity and smact_filter functions --- smact/tests/test_core.py | 49 ++++++++++++++++++++++++++++------------ 1 file changed, 34 insertions(+), 15 deletions(-) diff --git a/smact/tests/test_core.py b/smact/tests/test_core.py index b99209f9..74cad9da 100755 --- a/smact/tests/test_core.py +++ b/smact/tests/test_core.py @@ -335,31 +335,50 @@ def test_ml_rep_generator(self): self.assertEqual(smact.screening.ml_rep_generator([Pb, O], [1, 2]), PbO2_ml) def test_smact_filter(self): + oxidation_states_sets = ["smact14", "icsd24"] + oxidation_states_sets_results = { + "smact14": { + "thresh_2": [ + (("Na", "Fe", "Cl"), (1, -1, -1), (2, 1, 1)), + (("Na", "Fe", "Cl"), (1, 1, -1), (1, 1, 2)), + ] + }, + "icsd24": {"thresh_2": [(("Na", "Fe", "Cl"), (1, 1, -1), (1, 1, 2))]}, + } + Na, Fe, Cl = (smact.Element(label) for label in ("Na", "Fe", "Cl")) - result = smact.screening.smact_filter([Na, Fe, Cl], threshold=2) - self.assertEqual( - [(r[0], r[1], r[2]) for r in result], - [ - (("Na", "Fe", "Cl"), (1, -1, -1), (2, 1, 1)), - (("Na", "Fe", "Cl"), (1, 1, -1), (1, 1, 2)), - ], - ) + + for ox_state_set in oxidation_states_sets: + with self.subTest(ox_state_set=ox_state_set): + output = smact.screening.smact_filter([Na, Fe, Cl], threshold=2, oxidation_states_set=ox_state_set) + self.assertEqual( + [(r[0], r[1], r[2]) for r in output], + oxidation_states_sets_results[ox_state_set]["thresh_2"], + ) + + # Test that reading the oxidation states from a file produces the same results self.assertEqual( - result, + smact.screening.smact_filter([Na, Fe, Cl], threshold=2, oxidation_states_set="smact14"), smact.screening.smact_filter([Na, Fe, Cl], threshold=2, oxidation_states_set=TEST_OX_STATES), ) self.assertEqual( - set(smact.screening.smact_filter([Na, Fe, Cl], threshold=2, species_unique=False)), + set( + smact.screening.smact_filter( + [Na, Fe, Cl], threshold=2, species_unique=False, oxidation_states_set="smact14" + ) + ), { (("Na", "Fe", "Cl"), (2, 1, 1)), (("Na", "Fe", "Cl"), (1, 1, 2)), }, ) - self.assertEqual(len(smact.screening.smact_filter([Na, Fe, Cl], threshold=8)), 77) + self.assertEqual( + len(smact.screening.smact_filter([Na, Fe, Cl], threshold=8, oxidation_states_set="smact14")), 77 + ) - result = smact.screening.smact_filter([Na, Fe, Cl], stoichs=[[1], [1], [4]]) + result = smact.screening.smact_filter([Na, Fe, Cl], stoichs=[[1], [1], [4]], oxidation_states_set="smact14") self.assertEqual( [(r[0], r[1], r[2]) for r in result], [ @@ -368,7 +387,7 @@ def test_smact_filter(self): ) stoichs = [list(range(1, 5)), list(range(1, 5)), list(range(1, 10))] self.assertEqual( - len(smact.screening.smact_filter([Na, Fe, Cl], stoichs=stoichs)), + len(smact.screening.smact_filter([Na, Fe, Cl], stoichs=stoichs, oxidation_states_set="smact14")), 45, ) @@ -380,8 +399,8 @@ def test_smact_validity(self): # Test for single element self.assertTrue(smact.screening.smact_validity("Al")) - # Test for MgB2 which is invalid for the default oxi states but valid for the icsd states - self.assertFalse(smact.screening.smact_validity("MgB2")) + # Test for MgB2 which is invalid for the smact14 oxi states but valid for the icsd states + self.assertFalse(smact.screening.smact_validity("MgB2", oxidation_states_set="smact14")) self.assertTrue(smact.screening.smact_validity("MgB2", oxidation_states_set="icsd16")) self.assertFalse(smact.screening.smact_validity("MgB2", oxidation_states_set="pymatgen_sp")) self.assertTrue(smact.screening.smact_validity("MgB2", oxidation_states_set="wiki")) From aa57941568386d0d72f68bcb71655b7cbfe06cab Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 16:15:50 -0500 Subject: [PATCH 51/62] Add option to select oxidation states list in crystal space --- .../utils/crystal_space/generate_composition_with_smact.py | 7 ++++++- 1 file changed, 6 insertions(+), 1 deletion(-) diff --git a/smact/utils/crystal_space/generate_composition_with_smact.py b/smact/utils/crystal_space/generate_composition_with_smact.py index 690b6292..d22bf99b 100644 --- a/smact/utils/crystal_space/generate_composition_with_smact.py +++ b/smact/utils/crystal_space/generate_composition_with_smact.py @@ -44,6 +44,7 @@ def generate_composition_with_smact( max_atomic_num: int = 103, num_processes: int | None = None, save_path: str | None = None, + oxidation_states_set: str = "icsd24", ) -> pd.DataFrame: """ Generate all possible compositions of a given number of elements and @@ -55,6 +56,7 @@ def generate_composition_with_smact( max_atomic_num (int): the maximum atomic number. Defaults to 103. num_processes (int): the number of processes to use. Defaults to None. save_path (str): the path to save the results. Defaults to None. + oxidation_states_set (str): the oxidation states set to use. Options are "smact14", "icsd16", "icsd24", "pymatgen_sp" or a filepath to a custom oxidation states list. For reproducing the Faraday Discussions results, use "smact14". Returns: df (pd.DataFrame): A DataFrame of SMACT-generated compositions with boolean smact_allowed column. @@ -104,7 +106,10 @@ def generate_composition_with_smact( pool = multiprocessing.Pool(processes=multiprocessing.cpu_count() if num_processes is None else num_processes) results = list( tqdm( - pool.imap_unordered(partial(smact_filter, threshold=max_stoich), compounds_pauling), + pool.imap_unordered( + partial(smact_filter, threshold=max_stoich, oxidation_states_set=oxidation_states_set), + compounds_pauling, + ), total=len(compounds_pauling), ) ) From 62a8ff9e1efb4cd4e5dc01be0171c20082376e8e Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 16:16:23 -0500 Subject: [PATCH 52/62] Set oxidation states to smact14 for reproducibility with FD publication --- docs/tutorials/crystal_space.ipynb | 1 + 1 file changed, 1 insertion(+) diff --git a/docs/tutorials/crystal_space.ipynb b/docs/tutorials/crystal_space.ipynb index 76de9f28..d61b3315 100644 --- a/docs/tutorials/crystal_space.ipynb +++ b/docs/tutorials/crystal_space.ipynb @@ -102,6 +102,7 @@ " max_atomic_num=103,\n", " num_processes=8,\n", " save_path=\"data/binary/df_binary_label.pkl\",\n", + " oxidation_states_set=\"smact14\"\n", ")" ] }, From 56a3ef22e01ad205eba718bb5ef7b330cd9fbe7a Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 16:17:01 -0500 Subject: [PATCH 53/62] Use smact14 oxidation states for consistency in GNoME example --- docs/tutorials/smact_validity_of_GNoMe.ipynb | 6 +++--- 1 file changed, 3 insertions(+), 3 deletions(-) diff --git a/docs/tutorials/smact_validity_of_GNoMe.ipynb b/docs/tutorials/smact_validity_of_GNoMe.ipynb index e87a6808..eae40341 100644 --- a/docs/tutorials/smact_validity_of_GNoMe.ipynb +++ b/docs/tutorials/smact_validity_of_GNoMe.ipynb @@ -237,7 +237,7 @@ { "data": { "application/vnd.jupyter.widget-view+json": { - "model_id": "16fd0c26938f4483abee04fbcb7fe750", + "model_id": "15bda5d7186b4c3aaf19ea3fa7e51d7e", "version_major": 2, "version_minor": 0 }, @@ -344,7 +344,7 @@ ], "source": [ "# Run the SMACT validity test on the GNoME materials\n", - "df[\"smact_valid\"] = df[\"Composition\"].parallel_apply(smact_validity) # Alloys will pass the test\n", + "df[\"smact_valid\"] = df[\"Composition\"].parallel_apply(smact_validity,**{\"oxidation_states_set\":\"smact14\"}) # Alloys will pass the test\n", "df.head()" ] }, @@ -370,7 +370,7 @@ "outputs": [ { "data": { - "image/png": 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", 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", 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" ] From d8f74fac0834fd5ade06f1ef8b2365100a21db60 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Sun, 1 Dec 2024 16:19:23 -0500 Subject: [PATCH 54/62] Test `generate_composition_with_smact` with smact14 and icsd24 ox states --- smact/tests/test_utils.py | 38 ++++++++++++++++++++++++-------------- 1 file changed, 24 insertions(+), 14 deletions(-) diff --git a/smact/tests/test_utils.py b/smact/tests/test_utils.py index 7d3dea22..056c9356 100644 --- a/smact/tests/test_utils.py +++ b/smact/tests/test_utils.py @@ -96,20 +96,30 @@ def test_convert_formula(self): def test_generate_composition_with_smact(self): save_dir = "data/binary/df_binary_label.pkl" - smact_df = generate_composition_with_smact.generate_composition_with_smact( - num_elements=2, - max_stoich=1, - max_atomic_num=10, - save_path=save_dir, - ) - self.assertIsInstance(smact_df, pd.DataFrame) - self.assertTrue(len(smact_df) > 0) - - # Check if the data was saved to disk - self.assertTrue(os.path.exists(save_dir)) - - # Clean up - shutil.rmtree("data") + oxidation_states_sets = ["smact14", "icsd24"] + oxidation_states_sets_dict = { + "smact14": {"smact_allowed": 388}, + "icsd24": {"smact_allowed": 342}, + } + for ox_states in oxidation_states_sets: + with self.subTest(ox_states=ox_states): + smact_df = generate_composition_with_smact.generate_composition_with_smact( + num_elements=2, + max_stoich=3, + max_atomic_num=20, + save_path=save_dir, + oxidation_states_set=ox_states, + ) + self.assertIsInstance(smact_df, pd.DataFrame) + self.assertTrue(len(smact_df) == 1330) + self.assertTrue( + smact_df["smact_allowed"].sum() == oxidation_states_sets_dict[ox_states]["smact_allowed"] + ) + # Check if the data was saved to disk + self.assertTrue(os.path.exists(save_dir)) + + # Clean up + shutil.rmtree("data") @pytest.mark.skipif( sys.platform == "win32" or not (os.environ.get("MP_API_KEY") or SETTINGS.get("PMG_MAPI_KEY")), From ce1dd9907173f5cbc498b3538a9aef40441cc486 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:22:27 -0500 Subject: [PATCH 55/62] Remove unused argument --- smact/screening.py | 10 ++++------ 1 file changed, 4 insertions(+), 6 deletions(-) diff --git a/smact/screening.py b/smact/screening.py index 05a5511d..a95d2d16 100644 --- a/smact/screening.py +++ b/smact/screening.py @@ -336,7 +336,6 @@ def smact_filter( stoichs: list[list[int]] | None = None, species_unique: bool = True, oxidation_states_set: str = "icsd24", - comp_tuple: bool = False, ) -> list[tuple[str, int, int]] | list[tuple[str, int]]: """Function that applies the charge neutrality and electronegativity tests in one go for simple application in external scripts that @@ -348,12 +347,11 @@ def smact_filter( Args: ---- - els (tuple/list): A list of smact.Element objects - threshold (int): Threshold for stoichiometry limit, default = 8 + els (tuple/list): A list of smact.Element objects. + threshold (int): Threshold for stoichiometry limit, default = 8. stoichs (list[int]): A selection of valid stoichiometric ratios for each site. species_unique (bool): Whether or not to consider elements in different oxidation states as unique in the results. oxidation_states_set (string): A string to choose which set of oxidation states should be chosen. Options are 'smact14', 'icsd16',"icsd24", 'pymatgen_sp' and 'wiki' for the 2014 SMACT default, 2016 ICSD, 2024 ICSD, pymatgen structure predictor and Wikipedia (https://en.wikipedia.org/wiki/Template:List_of_oxidation_states_of_the_elements) oxidation states respectively. A filepath to an oxidation states text file can also be supplied as well. - comp_tuple (bool): Whether or not to return the results as a named tuple of elements and stoichiometries (True) or as a normal tuple of elements and stoichiometries (False). Returns: ------- @@ -438,7 +436,7 @@ def smact_validity( composition: pymatgen.core.Composition | str, use_pauling_test: bool = True, include_alloys: bool = True, - oxidation_states_set: str | bytes | os.PathLike = "icsd24", + oxidation_states_set: str = "icsd24", ) -> bool: """ Check if a composition is valid according to the SMACT rules. @@ -454,7 +452,7 @@ def smact_validity( composition (Union[pymatgen.core.Composition, str]): Composition/formula to check. This can be a pymatgen Composition object or a string. use_pauling_test (bool): Whether to use the Pauling electronegativity test include_alloys (bool): If True, compositions which only contain metal elements will be considered valid without further checks. - oxidation_states_set (Union[str, bytes, os.PathLike]): A string to choose which set of + oxidation_states_set (str): A string to choose which set of oxidation states should be chosen for charge-balancing. Options are 'smact14', 'icsd14', 'icsd24', 'pymatgen_sp' and 'wiki' for the 2014 SMACT default, 2016 ICSD, 2024 ICSD, pymatgen structure predictor and Wikipedia (https://en.wikipedia.org/wiki/Template:List_of_oxidation_states_of_the_elements) oxidation states respectively. From 7d7459d71f4ea98e2ecbcc4ba8650af3c3451d8a Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:22:45 -0500 Subject: [PATCH 56/62] Use ICSD24 as the default oxidation states --- smact/__init__.py | 4 ++-- 1 file changed, 2 insertions(+), 2 deletions(-) diff --git a/smact/__init__.py b/smact/__init__.py index 43713eb6..097b42a1 100644 --- a/smact/__init__.py +++ b/smact/__init__.py @@ -58,7 +58,7 @@ class Element: Element.SSEPauling (float) : SSE based on regression fit with Pauling electronegativity - Element.oxidation_states (list) : Default list of allowed oxidation states for use in SMACT + Element.oxidation_states (list) : Default list of allowed oxidation states for use in SMACT. In >3.0, these are the ICSD24 set. In <3.0, these are the SMACT14 set. Element.oxidation_states_smact14 (list): Original list of oxidation states that were manually compiled for SMACT in 2014 (default in SMACT < 3.0) @@ -179,7 +179,7 @@ def __init__(self, symbol: str, oxi_states_custom_filepath: str | None = None): ("number", dataset["Z"]), ( "oxidation_states", - data_loader.lookup_element_oxidation_states(symbol), + data_loader.lookup_element_oxidation_states_icsd24(symbol), ), ( "oxidation_states_smact14", From 59bf75c7865ab910efa4eabe1bb54af4ef516136 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:26:19 -0500 Subject: [PATCH 57/62] Update test_core.py to reflect change to default oxidation states --- smact/tests/test_core.py | 3 ++- 1 file changed, 2 insertions(+), 1 deletion(-) diff --git a/smact/tests/test_core.py b/smact/tests/test_core.py index 74cad9da..176ba6c5 100755 --- a/smact/tests/test_core.py +++ b/smact/tests/test_core.py @@ -47,7 +47,8 @@ def test_element_dictionary(self): newlist = ["O", "Rb", "W"] dictionary = smact.element_dictionary(newlist, TEST_OX_STATES) self.assertEqual(dictionary["O"].crustal_abundance, 461000.0) - self.assertEqual(dictionary["Rb"].oxidation_states, [-1, 1]) + self.assertEqual(dictionary["Rb"].oxidation_states_smact14, [-1, 1]) + self.assertEqual(dictionary["Rb"].oxidation_states, [1]) self.assertEqual(dictionary["Rb"].oxidation_states_custom, [-1, 1]) self.assertEqual(dictionary["W"].name, "Tungsten") self.assertTrue("Rn" in smact.element_dictionary()) From c375652731a912b47ea634af09ace286cbe1a490 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:37:10 -0500 Subject: [PATCH 58/62] Bump version number to 3.0 --- docs/conf.py | 4 ++-- pyproject.toml | 2 +- setup.py | 4 ++-- 3 files changed, 5 insertions(+), 5 deletions(-) diff --git a/docs/conf.py b/docs/conf.py index 31ddd512..39382b8d 100644 --- a/docs/conf.py +++ b/docs/conf.py @@ -71,9 +71,9 @@ # built documents. # # The short X.Y version. -version = "2.8" +version = "3.0" # The full version, including alpha/beta/rc tags. -release = "2.8.0" +release = "3.0.0" # The language for content autogenerated by Sphinx. Refer to documentation # for a list of supported languages. diff --git a/pyproject.toml b/pyproject.toml index 418324c9..13d79126 100644 --- a/pyproject.toml +++ b/pyproject.toml @@ -5,7 +5,7 @@ build-backend = "setuptools.build_meta" [project] name = "SMACT" -version = "2.8" +version = "3.0" description = "Semiconducting Materials by Analogy and Chemical Theory" readme = "README.md" authors = [ diff --git a/setup.py b/setup.py index fb98918c..89de27e5 100755 --- a/setup.py +++ b/setup.py @@ -7,10 +7,10 @@ __author__ = "The SMACT Developers" __author_email__ = "a.walsh@imperial.ac.uk" __copyright__ = "Copyright Daniel W. Davies, Adam J. Jackson, Keith T. Butler (2019)" -__version__ = "2.8" +__version__ = "3.0" __maintainer__ = "Anthony O. Onwuli" __maintainer_email__ = "anthony.onwuli16@imperial.ac.uk" -__date__ = "September 26 2024" +__date__ = "December 2 2024" import os From 3848780d61534b22bfa1d6bbea2fdd12489212cb Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:52:22 -0500 Subject: [PATCH 59/62] Update links in the README --- README.md | 12 +++++++++--- 1 file changed, 9 insertions(+), 3 deletions(-) diff --git a/README.md b/README.md index 496c4d1b..d27d89e4 100644 --- a/README.md +++ b/README.md @@ -33,7 +33,7 @@ There is a strong demand for functional materials across a wide range of technol Features are accessed through Python scripts, importing classes and functions as needed. The best place to start is looking at [the docs](https://smact.readthedocs.io/en/latest/), which highlight some simple examples of how these classes and functions can be usede -Use cases are available in our [examples](https://github.com/WMD-group/SMACT/tree/master/examples) and [tutorials](https://github.com/WMD-group/SMACT/tree/master/tutorials) folders. +Use cases are available in our [examples](https://smact.readthedocs.io/en/latest/examples.html) and [tutorials](https://smact.readthedocs.io/en/latest/tutorials.html) folders. ## Code features @@ -41,7 +41,7 @@ Use cases are available in our [examples](https://github.com/WMD-group/SMACT/tre - Oxidation states that are accessible to each element are included in their properties. -- Element compositions can be screened through based on the heuristic filters of charge neutrality and electronegativity order. This is handled using the [screening module](https://smact.readthedocs.io/en/latest/smact.screening.html) and [this publication]() describes the underlying theory. An example procedure is [outlined in the docs](https://smact.readthedocs.io/en/latest/examples.html#neutral-combinations) and more examples can be found in the [counting examples subfolder](https://github.com/WMD-group/SMACT/tree/master/examples/Counting). +- Element compositions can be screened through based on the heuristic filters of charge neutrality and electronegativity order. This is handled using the [screening module](https://smact.readthedocs.io/en/latest/smact.screening.html) and [this publication]() describes the underlying theory. An example procedure is [outlined in the docs](https://smact.readthedocs.io/en/latest/examples/filter.html). - Further filters can be applied to generated lists of compositions in order to screen for particular properties. These properties are either intrinsic properties of elements or are calculated for compositions using the [properties module](https://smact.readthedocs.io/en/latest/smact.properties.html). For example: @@ -50,7 +50,7 @@ Use cases are available in our [examples](https://github.com/WMD-group/SMACT/tre - Compositions can also be filtered based on sustainability via the abundance of elements in the Earth's crust or via the [HHI scale](https://pubs.acs.org/doi/10.1021/cm400893e). -- Compositions can be converted for use in Pymatgen or for representation to machine learning algorithms ([see "next steps" in this example](https://github.com/WMD-group/SMACT/blob/master/examples/Counting/Generate_compositions_lists.ipynb)) and the related [ElementEmbeddings](https://github.com/WMD-group/ElementEmbeddings) package. +- Compositions can be converted for use in Pymatgen or for representation to machine learning algorithms ([see this example](https://smact.readthedocs.io/en/latest/tutorials/smact_generation_of_solar_oxides.html)) and the related [ElementEmbeddings](https://github.com/WMD-group/ElementEmbeddings) package. - The code also has tools for manipulating common crystal lattice types: - Certain structure types can be built using the [builder module](https://smact.readthedocs.io/en/latest/smact.builder.html) @@ -77,6 +77,8 @@ Use cases are available in our [examples](https://github.com/WMD-group/SMACT/tre - **oxidation_states.py**: Used for predicting the likelihood of species coexisting in a compound based on a statistical model. - **structure_prediction**: A submodule which contains a collection of tools for facilitating crystal structure predictions via ionic substitutions - **dopant_prediction**: A submodule which contains a collections of tools for predicting dopants. + - **utils.py** A collection of utility functions used throughout the codebase. + ## Requirements @@ -90,6 +92,10 @@ The latest stable release can be installed via pip which will automatically set pip install smact +Optional dependencies can also be installed. These enable full replication of the examples and tutorials + + pip install "smact[optional]" + SMACT is also available via conda through the conda-forge channel on Anaconda Cloud: conda install -c conda-forge smact From 5e77193e3e4eedbc6c707c0edf0b023d1468de76 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:52:31 -0500 Subject: [PATCH 60/62] Update contributing guide --- CONTRIBUTING.md | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/CONTRIBUTING.md b/CONTRIBUTING.md index 3c620271..b2496191 100644 --- a/CONTRIBUTING.md +++ b/CONTRIBUTING.md @@ -35,7 +35,7 @@ Recommended reading: [How to Write the Perfect Pull Request](https://github.blog When developing locally, it is recommended to install the python packages in `requirements-dev.txt`. ```bash -pip install -r requirements-dev.txt +pip install -e ".[dev,docs]" ``` This will allow you to run the tests locally with pytest as described in the main README, From 0594cc49dc34d3b86f4fb8a1d1d66ddb7c0fdaff Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:52:43 -0500 Subject: [PATCH 61/62] Add new workflow to check links in Markdown --- .github/workflows/check-live-links.yml | 16 ++++++++++++++++ 1 file changed, 16 insertions(+) create mode 100644 .github/workflows/check-live-links.yml diff --git a/.github/workflows/check-live-links.yml b/.github/workflows/check-live-links.yml new file mode 100644 index 00000000..e82f6f34 --- /dev/null +++ b/.github/workflows/check-live-links.yml @@ -0,0 +1,16 @@ +name: Check Markdown links + +on: + push: + branches: + - master + schedule: + # Every Monday at 00:00 UTC + - cron: "0 0 * * 1" + +jobs: + markdown-link-check: + runs-on: ubuntu-latest + steps: + - uses: actions/checkout@master + - uses: gaurav-nelson/github-action-markdown-link-check@v1 \ No newline at end of file From 9fa4e5649445985bdb2c5cd76f75261fc6890855 Mon Sep 17 00:00:00 2001 From: Anthony Onwuli Date: Mon, 2 Dec 2024 12:58:26 -0500 Subject: [PATCH 62/62] Run pre-commit --- .github/workflows/check-live-links.yml | 18 +++++++++--------- README.md | 1 - 2 files changed, 9 insertions(+), 10 deletions(-) diff --git a/.github/workflows/check-live-links.yml b/.github/workflows/check-live-links.yml index e82f6f34..2e210ad2 100644 --- a/.github/workflows/check-live-links.yml +++ b/.github/workflows/check-live-links.yml @@ -1,16 +1,16 @@ name: Check Markdown links -on: - push: - branches: - - master - schedule: - # Every Monday at 00:00 UTC - - cron: "0 0 * * 1" +on: + push: + branches: + - master + schedule: + # Every Monday at 00:00 UTC + - cron: "0 0 * * 1" jobs: markdown-link-check: runs-on: ubuntu-latest steps: - - uses: actions/checkout@master - - uses: gaurav-nelson/github-action-markdown-link-check@v1 \ No newline at end of file + - uses: actions/checkout@master + - uses: gaurav-nelson/github-action-markdown-link-check@v1 diff --git a/README.md b/README.md index d27d89e4..45971949 100644 --- a/README.md +++ b/README.md @@ -78,7 +78,6 @@ Use cases are available in our [examples](https://smact.readthedocs.io/en/latest - **structure_prediction**: A submodule which contains a collection of tools for facilitating crystal structure predictions via ionic substitutions - **dopant_prediction**: A submodule which contains a collections of tools for predicting dopants. - **utils.py** A collection of utility functions used throughout the codebase. - ## Requirements