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近年来, 可移动消费电子与电动汽车等产业发展迅速, 迫切需要发展高能量密度与高安全稳定性的锂电池, 以提高这些设备的长续航与长期稳定运行的能力. 这使得全固态锂电池极具潜力, 并获得迅速发展. 然而, 高性能全固态锂电池的发展需要对其充放电机制与性能衰减机理等有深入的认识, 对电池内部及界面的微观结构、物相组成、化学成分及局域化学环境等动态演变规律有系统深入的理解. 基于此, 本文总结归纳了典型原位表征技术, 包括原位显微技术 (原位扫描电子显微镜 (SEM), 原位透射电子显微镜 (TEM))、原位X射线技术 (原位X射线衍射 (XRD)、原位X射线光电子能谱 (XPS)、原位近边结构X射线吸收光谱 (XANES)、原位X射线层析成像等)、原位中子技术 (原位中子衍射 (ND)、原位中子深度剖析 (NDP))以及原位波谱技术 (原位拉曼光谱、原位核磁共振 (NMR)与原位核磁共振成像 (MRI)) 等的基本原理、功能、及其应用于研究固态锂电池中电极材料与界面在服役状态下、真实电化学过程中的动态过程与失效机制的代表性研究进展, 并对未来先进原位表征技术在全固态锂电池研究中的应用进行了探讨和展望.In recent years, mobile consumer electronics and electric vehicles have been developing rapidly, and they have been hunting for lithium batteries with high energy density, high safety and stability, to alleviate the range anxiety and improve their stability over long term operations. These make all-solid-state lithium batteries very attractive and they have been under intense investigations. However, the development of high-performance all-solid-state lithium batteries requires an in-depth understanding of their charge and discharge mechanism, their degradation process, along with the evolution of the microstructures, phase compositions, chemical states and their distributions, etc., inside the battery and at the interface. This paper summarizes the basic principles, functions, and the representative advances in investigation of the dynamics and failure mechanism of electrode materials and interfaces in solid-state lithium batteries under working conditions, with typical in-situcharacterization techniques, including in-situ microscopy (in-situ scanning electron microscopy (SEM), in-situ transmission electron microscopy (TEM)), in-situ X-ray techniques ( in-situX-ray diffraction (XRD)), in-situ X-ray photoelectron spectroscopy (XPS), in-situnear-edge structure X-ray absorption spectroscopy (XANES), in-situX-ray tomography), in-situneutron techniques ( in-situneutron diffraction (ND), in-situneutron depth profiling (NDP)) and in-situspectroscopies ( in-situRaman spectroscopy, in-situnuclear magnetic resonance (NMR) and in-situnuclear magnetic resonance imaging (MRI)), etc. We also discussed the application of future advanced in-situ characterization techniques in the investigation of all-solid-state lithium batteries.
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