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From Qiskit Metal to pattern generation to real nanofabrication demo. Here, quantum devices on a chip are patterned via direct-write electron-beam lithography in a nanofabrication facility. Written & patterned by Onri Jay Benally, an Indigenous American quantum hardware engineer.

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Qiskit-Metal-to-Litho

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On the use of Qiskit Metal coded in Python to generate design files for building quantum devices on a chip, performed via direct-write lithography. Depending on the resolution of desired quantum device features, LASER, scanning thermal probe, and electron-beam techniques are applicable options for patterning your design. - Onri Jay Benally

(Note: in the patterned 400-transmon example below, the ground contacts were excluded from layout as the design was to demonstrate process feasibility from Qiskit Metal design-to-real-chip. However, the main features are clearly visible under optical microscopy. Also, I included a DXF/GDS design output for a full quantum chip, ready for fabrication [electrodes, ground, and all], available to download in the file directories above).

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It Is Important to Know That There Are 2 Main Types of Patterning With the E-Beam Writer (EBPG) Equipment: Description
Marker-based using "rp" commands This is used if your sample has pre-existing markers patterned on it already [ex. sample WITH purposely-designed reference points that can be automatically located by the EBPG's built-in SEM tool].
Marker-free-based using "joyplus" commands This is used if your sample has no pre-existing referencing patterns [ex. bare substrate or other sample WITHOUT purposely-designed reference points].
Terms To Be Aware Of: Description
BEAMER Desktop software for importing GDSII or GDS files stored on WinSCP, beam step, size, and error correction (heal) paramters are set here and subsequently exported as GPF files that can be read by the EBPG equipment. Additionally the parameters can be downloaded as a Python script (.py). An example of a Python script used in BEAMER is available for reference in the file directory above.
CJOB Software tool that is accessed on the EBPG equipment itself using the EBPG's terminal. From here, the GPF files can be uploaded and programmed with virtual alignment marker locations based on the uploaded design. Once the file is ready, it will export as a JOB file (.job). The JOB file name is what gets copied into the EBPG's terminal along with 4 coordinates validated by the built-in SEM.
Marker The use of reference points on a coordinate plane that are assigned to a pre-existing, detectable pattern on a chip sample. Detection is performed automatically by the lithography equipment using commands such as "rp20".
Marker-free The use of virtual reference points assigned to the region of interest to be patterned on a bare chip sample, wafer substrate, or other sample with without detectable markers.

If You Need to Install pip Through Python, Follow These Steps:
• First, install an EXE file of Python from: https://www.python.org/downloads
• Then, install pip by entering the following command into local terminal:
curl https://bootstrap.pypa.io/get-pip.py -o get-pip.py
• Now, pip is ready for use!
Installation Steps for Qiskit Metal:
Installing Qiskit Metal Using Git+URL_by Onri Jay Benally
Quantum Chip Rendering Steps:
Qiskit Metal + KLayout + Blender

Required Software (Some Open-Source, Free Versions Are Linked Below):
Qiskit Metal
2D CAD program
Pattern layout viewer & editor (GDS-to-DXF/DXF-to-GDS converter)
Electron- & LASER-beam lithography software (GDS-to-GPF converter for equipment)
2D CAD Programs Available: Description
AutoCAD or AutoCAD Web Cost effective alternative to locally-installed AutoCAD: https://www.autodesk.com/products/autocad-web/overview?term=1-YEAR&tab=subscription&plc=A360PP
QCAD Open-sourced & simple: https://qcad.org/en
LibreCAD Open-sourced & feature-packed: https://librecad.org
FreeCAD Open-sourced & feature-packed: https://www.freecad.org
Salome Open-sourced & feature-packed: https://www.salome-platform.org/?page_id=2430
Pattern Layout Viewers & Editors: Description
KLayout Open-sourced & feature-packed: https://www.klayout.de/build.html
LinkCAD Paid version: https://www.linkcad.com/download.php [usually purchased by your lab]
Raith_GDSII MATLAB Toolbox Public licensed: https://github.com/ahryciw/Raith_GDSII
Octave/ MATLAB Toolbox for GDSII Public domain: https://github.com/ulfgri/gdsii-toolbox
Free or Open-Source Software for Design, Analysis, or Large Data Visualization:
https://dev.opencascade.org/about/projects_and_products
https://www.paraview.org/download
Open-Source Finite Element Method Software (Alternative to Ansys):
https://github.com/ElmerCSC/elmerfem
Open-Source Mesh Generators (To Prepare Design for Use in Finite Element Method Software):
https://gmsh.info/#Download
https://www.salome-platform.org/?page_id=2430
Open-Source Device Simulation Tools:
https://gdsfactory.github.io/gdsfactory/plugins_process.html
Electron- & LASER-Beam Lithography Software:
BEAMER (from GenIsys: https://www.genisys-gmbh.com/beamer.html [usually purchased by your lab])
Slides & Webinars for Using Electron-Beam Lithography Software:
https://www.genisys-gmbh.com/webinar-series-beamer-training.html
General Overview of Electron-Beam Lithography:
https://nano.yale.edu/book/export/html/213
https://lab.kni.caltech.edu/EBPG_5000%2B:_100_kV_Electron_Beam_Lithography
Open-Source Computational Lithography Tools:
https://github.com/looninho/CUDAEBL
https://github.com/pierremifasol/Lithography-Simulation
https://github.com/lani5677/Computational-lithography
Examples of Green [Sustainable] Lithography-Based Direct-Write Patterning:
https://onlinelibrary.wiley.com/doi/full/10.1002/admi.201601223
https://onlinelibrary.wiley.com/doi/10.1002/adfm.202101533
List of Standard Negative/ Positive Tone Resist Materials:
https://www.microresist.de/en/products/?jet-smart-filters=jet-engine/products&_tax_query_pa_resist-alliance=534
https://www.epfl.ch/about/campus/neuchatel-en/daily-life/page-119059-en-html/page-126398-en-html
List of Available Process Recipes:
https://lab.kni.caltech.edu/Process_Recipe_Library
List of Open-Source Process Development Kits & More (Optional):
SiEPIC Ebeam PDK: https://gdsfactory.github.io/ubc
Skywater 130 PDK: https://gdsfactory.github.io/skywater130
GlobalFoundries 180 PDK: https://gdsfactory.github.io/gf180
Python library to design chips [Photonics, Analog, Quantum, MEMs, etc.]: https://github.com/gdsfactory/gdsfactory

Some of the Code Used Here are Borrowed or Inspired From the Qiskit Metal Page:
https://github.com/qiskit-community/qiskit-metal

To create the chip below, follow tutorials from the folder called "Python Code_Qiskit Metal_Designs" on main branch in this repository. Afterwards, proceed to a file called "Transmon Chip Fabrication Process Flow", also on the main branch. (Optionally, click on both hyperlinks to find the tutorials).


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From Qiskit Metal to pattern generation to real nanofabrication demo. Here, quantum devices on a chip are patterned via direct-write electron-beam lithography in a nanofabrication facility. Written & patterned by Onri Jay Benally, an Indigenous American quantum hardware engineer.

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