基于机器学习大材料数据的钼的精确力场

Chi Chen, Z. Deng, Richard Tran, Hanmei Tang, I. Chu, S. Ong
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引用次数: 94

摘要

在这项工作中,我们提出了一个高精度的钼(Mo)光谱邻近分析电位(SNAP)模型,该模型是通过严格应用机器学习技术在大型材料数据集上开发的。尽管Mo作为一种结构金属具有重要意义,但现有的基于嵌入原子和改进的嵌入原子方法的Mo力场在许多性质上仍然不能提供令人满意的精度。我们将证明,通过拟合不同Mo结构上的大密度泛函理论(DFT)计算数据集的能量、力和应力张量,可以开发出一个Mo SNAP模型,该模型在预测广泛的性能方面达到接近DFT的精度,包括能量、力、应力、弹性常数、熔点、声子谱、表面能、晶界能等。我们将概述一个系统的模型开发过程,其中包括基于主成分分析的严格结构选择方法,以及优化模型拟合中的超参数的微分进化算法,以便同时降低模型误差和属性预测误差。我们期望这个新开发的Mo SNAP模型在大规模、长尺度的模拟中得到广泛的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Accurate Force Field for Molybdenum by Machine Learning Large Materials Data
In this work, we present a highly accurate spectral neighbor analysis potential (SNAP) model for molybdenum (Mo) developed through the rigorous application of machine learning techniques on large materials data sets. Despite Mo's importance as a structural metal, existing force fields for Mo based on the embedded atom and modified embedded atom methods still do not provide satisfactory accuracy on many properties. We will show that by fitting to the energies, forces and stress tensors of a large density functional theory (DFT)-computed dataset on a diverse set of Mo structures, a Mo SNAP model can be developed that achieves close to DFT accuracy in the prediction of a broad range of properties, including energies, forces, stresses, elastic constants, melting point, phonon spectra, surface energies, grain boundary energies, etc. We will outline a systematic model development process, which includes a rigorous approach to structural selection based on principal component analysis, as well as a differential evolution algorithm for optimizing the hyperparameters in the model fitting so that both the model error and the property prediction error can be simultaneously lowered. We expect that this newly developed Mo SNAP model will find broad applications in large-scale, long-time scale simulations.
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