能量(信号处理)
可扩展性
密度泛函理论
Atom(片上系统)
方案(数学)
人工智能
计算机科学
试验装置
算法
材料科学
晶界
机器学习
统计物理学
物理
数学
量子力学
数学分析
嵌入式系统
微观结构
数据库
冶金
作者
Tomoyuki Tamura,Masayuki Karasuyama,Ryo Kobayashi,Ryuichi Arakawa,Yoshinori Shiihara,Ichiro Takeuchi
标识
DOI:10.1088/1361-651x/aa8276
摘要
We propose a new scheme based on machine learning for the efficient screening in grain-boundary (GB) engineering. A set of results obtained from first-principles calculations based on density functional theory (DFT) for a small number of GB systems is used as a training data set. In our scheme, by partitioning the total energy into atomic energies using a local-energy analysis scheme, we can increase the training data set significantly. We use atomic radial distribution functions and additional structural features as atom descriptors to predict atomic energies and GB energies simultaneously using the least absolute shrinkage and selection operator, which is a recent standard regression technique in statistical machine learning. In the test study with fcc-Al [110] symmetric tilt GBs, we could achieve enough predictive accuracy to understand energy changes at and near GBs at a glance, even if we collected training data from only 10 GB systems. The present scheme can emulate time-consuming DFT calculations for large GB systems with negligible computational costs, and thus enable the fast screening of possible alternative GB systems.
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