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Beyond Order: Partial Site Occupancies-Informed Machine Learning for Solid-State Electrolytes Design

Qian Zhao, Yuxiao Lin, Maxim Avdeev, Yurong Ren, Lin Shi, Shoukun Xu, Siqi Shi

2025Chemistry of Materials7 citationsDOI

Abstract

Crystal structures with partial site occupancies (PSO), a common feature in disordered materials where ions fractionally occupy lattice sites, are crucial for designing solid-state electrolytes (SSEs) with a low activation energy ( E a ). However, deciphering the underlying structure–property relationships remains challenging, as traditional ordered-assumption models cannot fully explain PSO effects. Herein, we propose a PSO-informed machine learning (PSO-ML) method for SSEs design, in which PSO knowledge is leveraged by identifying crystal structures from the literature based on identical ionic species and Wyckoff sites criteria, enabling a quantitative correlation between PSO effects and E a . Applied to trigonal halides Li 3 YCl 6, an E a prediction model with a determination coefficient ( R 2 ) of 93.18% is obtained by partial least-squares analysis with leave-one-out cross-validation. The variable importance in projection analysis identifies the configurational entropy and interlayer distance as key descriptors, both dominated by Y 3+ occupancy effects. By optimizing Y 3+ occupancy, promising candidates Li 3 Y 4 x –3 M 3–3 x Cl 6 ( M: tetravalent cations, 0.75 < x ≤ 0.888) are suggested, where Li 3 Y 0.2 Zr 0.6 Cl 6 (room-temperature ionic conductivity of 1.19 mS cm –1 ) has been experimentally evaluated as an excellent candidate, and other promising compositions are waiting for validation. With high accuracy and interpretability, the PSO-ML method enables the accelerated discovery and design of SSEs and broader disordered materials.

Topics & Concepts

Crystal structureIonic bondingIonic conductivityElectrolyteLattice (music)Lattice energyComputer scienceProjection (relational algebra)Materials scienceIonFast ion conductorPartial chargeArtificial intelligenceConfiguration entropyEntropy (arrow of time)Crystal (programming language)Key (lock)Thermal conductionAlgorithmMachine learningElectrical conductorCrystal structure predictionStatistical physicsBoosting (machine learning)Principal component analysisBinary numberThermodynamicsChemistryChemical physicsData miningFeature (linguistics)Advanced Battery Materials and TechnologiesMachine Learning in Materials ScienceThermal Expansion and Ionic Conductivity
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