Build Status | Social |
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A package for rapid implementation and testing of new interatomic potentials and molecular simulation algorithms. There are versions for Julia v0.5.x, 0.6.x and 1.x. All development is for v1.x. Documentation is essentially non-existent but the inline documentations is reasonably complete, and there are extensive tests that can be read in the absence of examples.
The design of JuLIP
is heavily inspired by ASE.
The main motivation for JuLIP
is that, while ASE
is pure Python and hence
relies on external software to efficiently evaluate interatomic potentials,
Julia allows the implementation of fast potentials in pure Julia, often in just
a few lines of code. ASE
bindings compatible with JuLIP
are provided by
ASE.jl. There are also reverse
bindings available via pyjulip
which enable using JuLIP
models from ASE
Contributions are very welcome, especially for producing examples and tutorials. Any questions or suggestions, please ask on , or simply open an issue.
The latest versions of JuLIP are no longer installed in the General
registry.
To use these versions, you will first need to install the MolSim
registry via
] registry add https://github.com/JuliaMolSim/MolSim.git
Then, to install JuLIP
,
] add Pkg.add("JuLIP")
and run
Pkg.test("JuLIP")
to make sure the installation succeeded. If a test fails, please open an issue.
Most likely you will also want to ASE bindings; please see ASE.jl for more detail.
The following are some minimal examples to just get something to run.
using JuLIP
at = bulk(:Si, cubic=true) * 4
deleteat!(at, 1)
set_calculator!(at, StillingerWeber())
minimise!(at)
@show energy(at)
# Visualisation is current not working
# JuLIP.Visualise.draw(at) # (this will only work in a ipynb)
see the BulkSilicon.ipynb
notebook under examples
for an extended
example.
using JuLIP
r0 = rnn(:Al)
pot = let A = 4.0, r0 = r0
@analytic r -> 6.0 * exp(- A * (r/r0 - 1.0)) - A * (r0/r)^6
end
pot = pot * SplineCutoff(2.1 * r0, 3.5 * r0)
# `pot` can now be used as a calculator to do something interesting ...
# ... or something boring
at = rattle!(bulk(:Fe, cubic=true) * 4, 0.1)
energy(pot, at)
using JuLIP
# and EAM-like site potential
f(R) = sqrt( 1.0 + sum( exp(-norm(r)) for r in R ) )
# wrap it into a site potential type => can be used as AbstractCalculator
V = ADPotential(f)
# evaluate V and ∇V
R0 = [ @SVector rand(3) for n = 1:nneigs ]
@show V(R0)
@show (@D V(R0))