电池(电)
电化学储能
储能
多尺度建模
纳米技术
钥匙(锁)
计算机科学
中尺度气象学
化学
计算模型
生化工程
路径(计算)
公共记录
系统工程
电极
光学(聚焦)
能量(信号处理)
合理设计
电化学
荷电状态
还原(数学)
蓄电池储能
作者
Suyue Yuan,Stephen E. Weitzner,Wonseok Jeong,Shenli Zhang,Bo Wang,Longsheng Feng,Jonas L. Kaufman,Kwangnam Kim,Yue Qi,Liwen F. Wan
出处
期刊:Chemical Reviews
[American Chemical Society]
日期:2026-01-05
卷期号:126 (1): 80-148
被引量:1
标识
DOI:10.1021/acs.chemrev.5c00360
摘要
The performance of rechargeable batteries is fundamentally influenced by the physicochemical properties and microstructural features of their key material components. Recent experimental advancements have highlighted the potential of single-crystal (SC) morphologies to address inherent limitations of polycrystalline (PC) electrodes and solid-state electrolytes, offering tunable charge transport kinetics and improved cell cycling performance. This review examines how state-of-the-art computational modeling, from atomistic and mesoscale to continuum-level approaches, including machine learning methodologies, has been utilized to investigate the critical factors governing the electrochemical behavior of SC battery materials. We explore how predictive modeling can elucidate the processing-structure-property-performance relationships of SC cathodes, anodes, and solid-state electrolytes, with a focus on unique SC characteristics such as crystallographic anisotropy, size effects, and facet-dependent properties. Additionally, we identify limitations in commonly used modeling techniques and discuss strategies to address these challenges. By integrating high-fidelity simulations with experimental insights, this review aims to outline a clear path for the rational design and optimization of SC battery components, paving the way for accelerated advancements in energy storage technologies.
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