English

Deep Potential generation scheme and simulation protocol for the Li10GeP2S12-type superionic conductors

Computational Physics 2021-03-17 v3 Materials Science Chemical Physics

Abstract

It has been a challenge to accurately simulate Li-ion diffusion processes in battery materials at room temperature using {\it ab initio} molecular dynamics (AIMD) due to its high computational cost. This situation has changed drastically in recent years due to the advances in machine learning-based interatomic potentials. Here we implement the Deep Potential Generator scheme to \textit{automatically} generate interatomic potentials for LiGePS-type solid-state electrolyte materials. This increases our ability to simulate such materials by several orders of magnitude without sacrificing {\it ab initio} accuracy. Important technical aspects like the statistical error and size effects are carefully investigated. We further establish a reliable protocol for accurate computation of Li-ion diffusion processes at experimental conditions, by investigating important technical aspects like the statistical error and size effects. Such a protocol and the automated workflow allow us to screen materials for their relevant properties with much-improved efficiency. By using the protocol and automated workflow developed here, we obtain the diffusivity data and activation energies of Li-ion diffusion that agree well with the experiment. Our work paves the way for future investigation of Li-ion diffusion mechanisms and optimization of Li-ion conductivity of solid-state electrolyte materials.

Keywords

Cite

@article{arxiv.2006.03320,
  title  = {Deep Potential generation scheme and simulation protocol for the Li10GeP2S12-type superionic conductors},
  author = {Jianxing Huang and Linfeng Zhang and Han Wang and Jinbao Zhao and Jun Cheng and Weinan E},
  journal= {arXiv preprint arXiv:2006.03320},
  year   = {2021}
}
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