APL Machine Learning (Jun 2023)

Materials cartography: A forward-looking perspective on materials representation and devising better maps

  • Steven B. Torrisi,
  • Martin Z. Bazant,
  • Alexander E. Cohen,
  • Min Gee Cho,
  • Jens S. Hummelshøj,
  • Linda Hung,
  • Gaurav Kamat,
  • Arash Khajeh,
  • Adeesh Kolluru,
  • Xiangyun Lei,
  • Handong Ling,
  • Joseph H. Montoya,
  • Tim Mueller,
  • Aini Palizhati,
  • Benjamin A. Paren,
  • Brandon Phan,
  • Jacob Pietryga,
  • Elodie Sandraz,
  • Daniel Schweigert,
  • Yang Shao-Horn,
  • Amalie Trewartha,
  • Ruijie Zhu,
  • Debbie Zhuang,
  • Shijing Sun

DOI
https://doi.org/10.1063/5.0149804
Journal volume & issue
Vol. 1, no. 2
pp. 020901 – 020901-11

Abstract

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Machine learning (ML) is gaining popularity as a tool for materials scientists to accelerate computation, automate data analysis, and predict materials properties. The representation of input material features is critical to the accuracy, interpretability, and generalizability of data-driven models for scientific research. In this Perspective, we discuss a few central challenges faced by ML practitioners in developing meaningful representations, including handling the complexity of real-world industry-relevant materials, combining theory and experimental data sources, and describing scientific phenomena across timescales and length scales. We present several promising directions for future research: devising representations of varied experimental conditions and observations, the need to find ways to integrate machine learning into laboratory practices, and making multi-scale informatics toolkits to bridge the gaps between atoms, materials, and devices.