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The ab initio amorphous materials database: Empowering machine learning to decode diffusivity (2402.00177v1)

Published 31 Jan 2024 in cond-mat.mtrl-sci

Abstract: Amorphous materials exhibit unique properties that make them suitable for various applications in science and technology, ranging from optical and electronic devices and solid-state batteries to protective coatings. However, data-driven exploration and design of amorphous materials is hampered by the absence of a comprehensive database covering a broad chemical space. In this work, we present the largest computed amorphous materials database to date, generated from systematic and accurate \textit{ab initio} molecular dynamics (AIMD) calculations. We also show how the database can be used in simple machine-learning models to connect properties to composition and structure, here specifically targeting ionic conductivity. These models predict the Li-ion diffusivity with speed and accuracy, offering a cost-effective alternative to expensive density functional theory (DFT) calculations. Furthermore, the process of computational quenching amorphous materials provides a unique sampling of out-of-equilibrium structures, energies, and force landscape, and we anticipate that the corresponding trajectories will inform future work in universal machine learning potentials, impacting design beyond that of non-crystalline materials.

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References (36)
  1. Supercooled liquids and the glass transition. Nature, 410(6825):259–267, March 2001.
  2. Mariusz Najgebauer. Advances in contemporary soft magnetic materials – a review. In 2023 10th International Conference on Electrical, Electronic and Computing Engineering (IcETRAN), pages 1–10, 2023.
  3. Recent advancements in bulk metallic glasses and their applications: A review. Critical Reviews in Solid State and Materials Sciences, 43(3):233–268, 2018.
  4. A Look at the Chemical Strengthening Process: Alkali Aluminosilicate Glasses vs. Soda-Lime Glass. In Charles H. Drummond, editor, Ceramic Engineering and Science Proceedings, volume 32, pages 61–66. Wiley, 1 edition, May 2011.
  5. Ultralow-dielectric-constant amorphous boron nitride. Nature, 582(7813):511–514, June 2020.
  6. Amorphous Boron Nitride Memristive Device for High-Density Memory and Neuromorphic Computing Applications. ACS Appl. Mater. Interfaces, 14(8):10546–10557, March 2022.
  7. The Effect of the SEI Layer Mechanical Deformation on the Passivity of a Si Anode in Organic Carbonate Electrolytes. ACS Nano, 17(7):6943–6954, April 2023.
  8. Silicon-based anode materials for lithium batteries: Recent progress, new trends, and future perspectives. Critical Reviews in Solid State and Materials Sciences, pages 1–33, February 2023.
  9. Challenges and Recent Progress on Silicon-Based Anode Materials for Next-Generation Lithium-Ion Batteries. Small Structures, 2(6):2100009, June 2021.
  10. Silicon Anodes with Improved Calendar Life Enabled By Multivalent Additives. Advanced Energy Materials, 11(37):2101820, October 2021.
  11. Electrochemical Reactivity and Passivation of Silicon Thin-Film Electrodes in Organic Carbonate Electrolytes. ACS Appl. Mater. Interfaces, 12(36):40879–40890, September 2020.
  12. Reaction of Li with Alloy Thin Films Studied by In Situ AFM. J. Electrochem. Soc., 150(11):A1457, 2003.
  13. 25th Anniversary Article: Understanding the Lithiation of Silicon and Other Alloying Anodes for Lithium-Ion Batteries. Adv. Mater., 25(36):4966–4985, September 2013.
  14. Evaluation of Amorphous Oxide Coatings for High-Voltage Li-Ion Battery Applications Using a First-Principles Framework. ACS Applied Materials & Interfaces, 12(31):35748–35756, August 2020.
  15. Materials design principles of amorphous cathode coatings for lithium-ion battery applications. J. Mater. Chem. A, 10(41):22245–22256, 2022.
  16. The lithiation process and Li diffusion in amorphous SiO 2 and Si from first-principles. Electrochimica Acta, 331:135344, January 2020.
  17. Density functional theory assessment of the lithiation thermodynamics and phase evolution in si-based amorphous binary alloys. Energy Storage Materials, 53:42–50, December 2022.
  18. High electronic conductivity as the origin of lithium dendrite formation within solid electrolytes. Nature Energy, 4(3):187–196, January 2019.
  19. Emerging Role of Non-crystalline Electrolytes in Solid-State Battery Research. Frontiers in Energy Research, 8:218, September 2020.
  20. Blocking lithium dendrite growth in solid-state batteries with an ultrathin amorphous Li-La-Zr-O solid electrolyte. Communications Materials, 2(1):76, July 2021.
  21. Blocking lithium dendrite growth in solid-state batteries with an ultrathin amorphous Li-La-Zr-O solid electrolyte. Commun Mater, 2(1):76, July 2021.
  22. Structural and Compositional Factors That Control the Li-Ion Conductivity in LiPON Electrolytes. Chemistry of Materials, 30(20):7077–7090, October 2018.
  23. Emerging Role of Non-crystalline Electrolytes in Solid-State Battery Research. Front. Energy Res., 8:218, September 2020.
  24. A Database of Porous Rigid Amorphous Materials. Chemistry of Materials, 32(18):8020–8033, September 2020.
  25. Lithium Oxide Superionic Conductors Inspired by Garnet and NASICON Structures. Adv. Energy Mater., 11(37):2101437, September 2021.
  26. Holistic computational structure screening of more than 12 000 candidates for solid lithium-ion conductor materials. Energy & Environmental Science, 10(1):306–320, 2017.
  27. Tin Kam Ho. Random decision forests. In Proceedings of 3rd international conference on document analysis and recognition, volume 1, pages 278–282. IEEE, 1995.
  28. XGBoost: A scalable tree boosting system. In Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, KDD ’16, pages 785–794, New York, NY, USA, 2016. ACM.
  29. API design for machine learning software: experiences from the scikit-learn project. In ECML PKDD Workshop: Languages for Data Mining and Machine Learning, pages 108–122, 2013.
  30. SISSO: A compressed-sensing method for identifying the best low-dimensional descriptor in an immensity of offered candidates. Physical Review Materials, 2(8):083802, August 2018.
  31. A universal graph deep learning interatomic potential for the periodic table. Nature Computational Science, 2(11):718–728, November 2022.
  32. CHGNet as a pretrained universal neural network potential for charge-informed atomistic modelling. Nat Mach Intell, 5(9):1031–1041, September 2023.
  33. Thermodynamic limit for synthesis of metastable inorganic materials. Science Advances, 4(4):eaaq0148, April 2018.
  34. PACKMOL : A package for building initial configurations for molecular dynamics simulations. J Comput Chem, 30(13):2157–2164, October 2009.
  35. User applications driven by the community contribution framework MPContribs in the Materials Project. Concurrency and Computation, 28(7):1982–1993, May 2016.
  36. Patrick Huck. mpcontribs-client https://pypi.org/project/mpcontribs-client/, 2024.
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