Implementation of Atomic Stress Calculations with Artificial Neural Network Potentials

IF 1.2 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Transactions Pub Date : 2023-10-01 DOI:10.2320/matertrans.mt-m2023093

Ivan Lobzenko, Tomohito Tsuru, Hideki Mori, Daisuke Matsunaka, Yoshinori Shiihara

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Abstract

Atomic stress, utilized in molecular mechanics and molecular dynamics, is valuable in analyzing complex phenomena such as heat transfer, crack propagation and void growth. However, traditional modeling techniques designed for large-scale systems may lack the precision achievable through first-principles calculations. To overcome this limitation, we propose an approach based on artificial neural network (ANN) potentials to compute atomic stress. A crucial aspect of this method is the use of central force decomposition to derive the atomic stress tensor of the ANN potential, ensuring compliance with the balance between linear and angular momentum. By comparing atomic stress calculations for surface systems in Fe and Al using the ANN and embedded-atom (EAM) potentials, we demonstrate that the ANN potential accurately reproduces the stress oscillations near the surface layer predicted by first-principles calculations. This scheme allows us to evaluate atomic stress with nearly the same accuracy as first-principles calculations, even in large-scale models with complex geometries and defect structures.

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用人工神经网络电位实现原子应力计算

原子应力在分子力学和分子动力学中的应用，对于分析复杂的传热、裂纹扩展和孔洞生长等现象具有重要的意义。然而，为大型系统设计的传统建模技术可能缺乏通过第一性原理计算实现的精度。为了克服这一限制，我们提出了一种基于人工神经网络(ANN)电位的原子应力计算方法。该方法的一个关键方面是使用中心力分解来推导神经网络势的原子应力张量，确保符合线动量和角动量之间的平衡。通过比较使用人工神经网络和嵌入原子(EAM)电位计算Fe和Al表面系统的原子应力，我们证明人工神经网络电位准确地再现了第一性原理计算预测的表面层附近的应力振荡。该方案使我们能够以几乎与第一性原理计算相同的精度评估原子应力，即使在具有复杂几何形状和缺陷结构的大型模型中也是如此。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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