桥接(联网)
阴极
表征(材料科学)
材料科学
同步加速器
氧化物
纳米技术
化学物理
纳米尺度
同步辐射
热的
非平衡态热力学
电池(电)
储能
化学稳定性
电化学
热稳定性
电极
纳米结构
动能
多尺度建模
阳极
可持续能源
动力学
纳米材料
结构稳定性
工程物理
原位
化学能
纳米颗粒
微秒
作者
Sangbeom Kim,Joon Ha Chang,Beom Tak Na,Sanghyeok Moon,Seonho Kim,Seungjun Baek,Jeong-Mi Yeon,Yujin Kim,Yu-Jin Kim,Hyun-seung Kim,Min Wook Pin,Y. T. Kim,Y. T. Kim
标识
DOI:10.1021/acs.chemmater.5c02925
摘要
This review examines synchrotron-based in situ characterization studies of layered oxide cathodes for lithium-ion batteries (LIBs) and shows that kinetic phenomena, rather than thermodynamic equilibrium, govern their behavior during synthesis, operation, and degradation. Advanced X-ray techniques reveal features including nanoscale structural domains that form substantially earlier than indicated by conventional detection methods, pronounced chemical heterogeneity within individual particles that contributes to mechanical failure, and electronic destabilization that precedes thermal decomposition. Surface–bulk divergence and intraparticle heterogeneity─often regarded as undesirable artifacts─emerge as intrinsic characteristics that strongly influence electrochemical performance. Correlative analyses of diffraction, spectroscopy, and microscopy data indicate that these materials frequently exist in nonequilibrium states in which local kinetics dominate over global thermodynamics. This review suggests a shift from equilibrium-based models toward kinetically controlled frameworks for understanding battery materials, indicating that future cathode designs might benefit from accommodating rather than eliminating these inherent heterogeneities. The mechanistic insights derived from synchrotron radiation provide guidance for developing stabilization strategies to address fundamental challenges in energy storage materials that are relevant to sustainable energy systems.
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