Zhong Yang, Liu Shixu, Zhang Binhua, Tao Zhiguo, Sun Yuting, Chu Weibin, Gong Xin-Gao, Yang Ji-Hui, Xiang Hongjun
Key Laboratory of Computational Physical Sciences (Ministry of Education), Institute of Computational Physical Sciences, State Key Laboratory of Surface Physics, and Department of Physics, Fudan University, Shanghai, China.
Shanghai Qi Zhi Institute, Shanghai, China.
Nat Comput Sci. 2024 Aug;4(8):615-625. doi: 10.1038/s43588-024-00668-7. Epub 2024 Aug 8.
The calculation of electron-phonon couplings (EPCs) is essential for understanding various fundamental physical properties, including electrical transport, optical and superconducting behaviors in materials. However, obtaining EPCs through fully first-principles methods is notably challenging, particularly for large systems or when employing advanced functionals. Here we introduce a machine learning framework to accelerate EPC calculations by utilizing atomic orbital-based Hamiltonian matrices and gradients predicted by an equivariant graph neural network. We demonstrate that our method not only yields EPC values in close agreement with first-principles results but also enhances calculation efficiency by several orders of magnitude. Application to GaAs using the Heyd-Scuseria-Ernzerhof functional reveals the necessity of advanced functionals for accurate carrier mobility predictions, while for the large Kagome crystal CsVSb, our framework reproduces the experimentally observed double domes in pressure-induced superconducting phase diagrams. This machine learning framework offers a powerful and efficient tool for the investigation of diverse EPC-related phenomena in complex materials.
电子 - 声子耦合(EPC)的计算对于理解各种基本物理性质至关重要,这些性质包括材料中的电输运、光学和超导行为。然而,通过完全第一性原理方法获得EPC极具挑战性,特别是对于大型系统或采用先进泛函时。在此,我们引入一个机器学习框架,通过利用由等变图神经网络预测的基于原子轨道的哈密顿矩阵和梯度来加速EPC计算。我们证明,我们的方法不仅能产生与第一性原理结果非常吻合的EPC值,还能将计算效率提高几个数量级。使用Heyd-Scuseria-Ernzerhof泛函对砷化镓的应用表明,对于准确预测载流子迁移率,先进泛函是必要的,而对于大型 Kagome 晶体 CsVSb,我们的框架再现了压力诱导超导相图中实验观察到的双穹顶现象。这个机器学习框架为研究复杂材料中各种与EPC相关的现象提供了一个强大而有效的工具。
