Machine learning interatomic potential with DFT accuracy for general grain boundaries in α-Fe

IF 9.4 1区 材料科学 Q1 CHEMISTRY, PHYSICAL
Kazuma Ito, Tatsuya Yokoi, Katsutoshi Hyodo, Hideki Mori
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Abstract

To advance the development of high-strength polycrystalline metallic materials towards achieving carbon neutrality, it is essential to design materials in which the atomic level control of general grain boundaries (GGBs), which govern the material properties, is achieved. However, owing to the complex and diverse structures of GGBs, there have been no reports on interatomic potentials capable of reproducing them. This accuracy is essential for conducting molecular dynamics analyses to derive material design guidelines. In this study, we constructed a machine learning interatomic potential (MLIP) with density functional theory (DFT) accuracy to model the energy, atomic structure, and dynamics of arbitrary grain boundaries (GBs), including GGBs, in α-Fe. Specifically, we employed a training dataset comprising diverse atomic structures generated based on crystal space groups. The GGB accuracy was evaluated by directly comparing with DFT calculations performed on cells cut near GBs from nano-polycrystals, and extrapolation grades of the local atomic environment based on active learning methods for the entire nano-polycrystal. Furthermore, we analyzed the GB energy and atomic structure in α-Fe polycrystals through large-scale molecular dynamics analysis using the constructed MLIP. The average GB energy of α-Fe polycrystals calculated by the constructed MLIP is 1.57 J/m2, exhibiting good agreement with experimental predictions. Our findings demonstrate the methodology for constructing an MLIP capable of representing GGBs with high accuracy, thereby paving the way for materials design based on computational materials science for polycrystalline materials.

Abstract Image

针对Œ±-Fe 中一般晶界的具有 DFT 精确度的机器学习原子间势
为了推动高强度多晶金属材料的发展,实现碳中和,必须设计出能在原子水平上控制一般晶界(GGBs)的材料,因为一般晶界决定着材料的性能。然而,由于 GGBs 结构复杂多样,目前还没有关于原子间势能能够再现 GGBs 的报道。这种精确性对于进行分子动力学分析以得出材料设计准则至关重要。在本研究中,我们构建了具有密度泛函理论(DFT)精度的机器学习原子间势(MLIP),以模拟Œ±-Fe 中包括 GGB 在内的任意晶界(GB)的能量、原子结构和动力学。具体来说,我们采用了一个训练数据集,其中包括根据晶体空间群生成的各种原子结构。通过直接与在纳米多晶体的 GB 附近切割的单元上进行的 DFT 计算以及基于主动学习方法对整个纳米多晶体的局部原子环境进行的外推等级进行比较,评估了 GGB 的准确性。此外,我们利用构建的 MLIP,通过大规模分子动力学分析,分析了 Œ±-Fe 多晶体中的 GB 能量和原子结构。构建的 MLIP 计算出的Œ±-Fe 多晶体的平均 GB 能量为 1.57'ÄâJ/m2,与实验预测结果吻合。我们的研究结果证明了构建能够高精度表示 GGB 的 MLIP 的方法,从而为基于计算材料科学的多晶材料设计铺平了道路。
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来源期刊
npj Computational Materials
npj Computational Materials Mathematics-Modeling and Simulation
CiteScore
15.30
自引率
5.20%
发文量
229
审稿时长
6 weeks
期刊介绍: npj Computational Materials is a high-quality open access journal from Nature Research that publishes research papers applying computational approaches for the design of new materials and enhancing our understanding of existing ones. The journal also welcomes papers on new computational techniques and the refinement of current approaches that support these aims, as well as experimental papers that complement computational findings. Some key features of npj Computational Materials include a 2-year impact factor of 12.241 (2021), article downloads of 1,138,590 (2021), and a fast turnaround time of 11 days from submission to the first editorial decision. The journal is indexed in various databases and services, including Chemical Abstracts Service (ACS), Astrophysics Data System (ADS), Current Contents/Physical, Chemical and Earth Sciences, Journal Citation Reports/Science Edition, SCOPUS, EI Compendex, INSPEC, Google Scholar, SCImago, DOAJ, CNKI, and Science Citation Index Expanded (SCIE), among others.
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