Roadmap for the development of machine learning-based interatomic potentials

材料科学 开发(拓扑) 原子间势 人工智能 机器学习 工程物理 计算机科学 计算化学 分子动力学 数学分析 物理 数学 化学
作者
Yong‐Wei Zhang,V. Sorkin,Zachary H. Aitken,Antonio Politano,Jörg Behler,Aidan P. Thompson,Tsz Wai Ko,Shyue Ping Ong,Olga Chalykh,Dmitry Korogod,Evgeny V. Podryabinkin,Alexander V. Shapeev,Ju Li,Y. Mishin,Zongrui Pei,Xianglin Liu,Jaesun Kim,Yutack Park,Seungwoo Hwang,Seungwu Han
出处
期刊:Modelling and Simulation in Materials Science and Engineering [IOP Publishing]
卷期号:33 (2): 023301-023301 被引量:21
标识
DOI:10.1088/1361-651x/ad9d63
摘要

Abstract An interatomic potential, traditionally regarded as a mathematical function, serves to depict atomic interactions within molecules or solids by expressing potential energy concerning atom positions. These potentials are pivotal in materials science and engineering, facilitating atomic-scale simulations, predictive material behavior, accelerated discovery, and property optimization. Notably, the landscape is evolving with machine learning transcending conventional mathematical models. Various machine learning-based interatomic potentials, such as artificial neural networks, kernel-based methods, deep learning, and physics-informed models, have emerged, each wielding unique strengths and limitations. These methods decode the intricate connection between atomic configurations and potential energies, offering advantages like precision, adaptability, insights, and seamless integration. The transformative potential of machine learning-based interatomic potentials looms large in materials science and engineering. They promise tailor-made materials discovery and optimized properties for specific applications. Yet, formidable challenges persist, encompassing data quality, computational demands, transferability, interpretability, and robustness. Tackling these hurdles is imperative for nurturing accurate, efficient, and dependable machine learning-based interatomic potentials primed for widespread adoption in materials science and engineering. This roadmap offers an appraisal of the current machine learning-based interatomic potential landscape, delineates the associated challenges, and envisages how progress in this domain can empower atomic-scale modeling of the composition-processing-microstructure-property relationship, underscoring its significance in materials science and engineering.
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