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Main Authors: Fu, Xiao, Xu, Jing, Yang, Qifan, Gong, Xuhe, Lian, Jingchen, Wang, Liqi, Wang, Zibin, Xiao, Ruijuan, Li, Hong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.18571
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author Fu, Xiao
Xu, Jing
Yang, Qifan
Gong, Xuhe
Lian, Jingchen
Wang, Liqi
Wang, Zibin
Xiao, Ruijuan
Li, Hong
author_facet Fu, Xiao
Xu, Jing
Yang, Qifan
Gong, Xuhe
Lian, Jingchen
Wang, Liqi
Wang, Zibin
Xiao, Ruijuan
Li, Hong
contents The rapid development of computational materials science powered by machine learning (ML) is gradually leading to solutions to several previously intractable scientific problems. One of the most prominent is machine learning interatomic potentials (MLIPs), which expedites the study of dynamical methods for large-scale systems. However, a promising field, high-entropy (HE) solid-state electrolytes (SEs) remain constrained by trial-and-error paradigms, lacking systematic computational strategies to address their huge and high-dimensional composition space. In this work, we establish a dual-stage ML framework that combines fine-tuned MLIPs with interpretable feature-property mapping to accelerate the high-entropy SEs discovery. Using Li$_3$Zr$_2$Si$_2$PO$_{12}$ (LZSP) as a prototype, the fine-tuned CHGNet-based relaxation provides atomic structure for each configuration, the structure features - mean squared displacement (SF-MSD) model predicts the ionic transport properties and identifies critical descriptors. The theoretical studies indicate that the framework can satisfy the multiple requirements including computational efficiency, generalization reliability and prediction accuracy. One of the most promising element combinations in the quinary HE-LZSP space containing 4575 compositions is identified with a high ionic conductivity of 4.53 mS/cm as an application example. The framework contains generalizability and extensibility to other SE families.
format Preprint
id arxiv_https___arxiv_org_abs_2505_18571
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High-Entropy Solid Electrolytes Discovery: A Dual-Stage Machine Learning Framework Bridging Atomic Configurations and Ionic Transport Properties
Fu, Xiao
Xu, Jing
Yang, Qifan
Gong, Xuhe
Lian, Jingchen
Wang, Liqi
Wang, Zibin
Xiao, Ruijuan
Li, Hong
Materials Science
The rapid development of computational materials science powered by machine learning (ML) is gradually leading to solutions to several previously intractable scientific problems. One of the most prominent is machine learning interatomic potentials (MLIPs), which expedites the study of dynamical methods for large-scale systems. However, a promising field, high-entropy (HE) solid-state electrolytes (SEs) remain constrained by trial-and-error paradigms, lacking systematic computational strategies to address their huge and high-dimensional composition space. In this work, we establish a dual-stage ML framework that combines fine-tuned MLIPs with interpretable feature-property mapping to accelerate the high-entropy SEs discovery. Using Li$_3$Zr$_2$Si$_2$PO$_{12}$ (LZSP) as a prototype, the fine-tuned CHGNet-based relaxation provides atomic structure for each configuration, the structure features - mean squared displacement (SF-MSD) model predicts the ionic transport properties and identifies critical descriptors. The theoretical studies indicate that the framework can satisfy the multiple requirements including computational efficiency, generalization reliability and prediction accuracy. One of the most promising element combinations in the quinary HE-LZSP space containing 4575 compositions is identified with a high ionic conductivity of 4.53 mS/cm as an application example. The framework contains generalizability and extensibility to other SE families.
title High-Entropy Solid Electrolytes Discovery: A Dual-Stage Machine Learning Framework Bridging Atomic Configurations and Ionic Transport Properties
topic Materials Science
url https://arxiv.org/abs/2505.18571