Koji Hiraoka, Kazuo Yamamoto, Takeshi Kobayashi, Tetsuo Sakamoto, Shiro Seki
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引用次数: 0
Abstract
Understanding the charge/discharge mechanism of batteries plays an important role in the development of high-performance systems, but extremely complicated reactions are involved. Because these complex phenomena are also bottlenecks for the establishment of all-solid-state batteries (ASSB), we conducted multi-scale analysis using combined multi-measurement techniques, to directly observe charge/discharge reactions at hierarchical scales for the oxide-type ASSB using Na as the carrier cation. In particular, all of measurement techniques are applied to cross-section ASSB in the same cell, to complementarily evaluate the elemental distributions and structural changes. From Operando scanning electron microscopy–energy-dispersive X-ray spectroscopy, the Na concentration in the electrode layers changes on the micrometer scale under charge/discharge reactions in the first cycle. Furthermore, Operando Raman spectroscopy reveal changes in the bonding states at the atomic scale in the active material, including changes in reversible structural changes. After cycling the ASSB, the elemental distributions are clearly observed along with the particle shapes and can reveal the Na migration mechanism at the nanometer scale, by time-of-flight secondary ion mass spectrometry. Therefore, this study can provide a fundamental and comprehensive understanding of the charge/discharge mechanism by observing reaction processes at multiple scales.
了解电池的充放电机理对开发高性能系统具有重要作用,但其中涉及极其复杂的反应。由于这些复杂的现象也是建立全固态电池(ASSB)的瓶颈,我们采用多种测量技术进行了多尺度分析,直接观察了以 Na 为载体阳离子的氧化物型 ASSB 在分层尺度上的充放电反应。特别是,所有测量技术都应用于同一电池中的横截面 ASSB,以补充评估元素分布和结构变化。通过操作扫描电子显微镜-能量色散 X 射线光谱分析,在第一个周期的充放电反应中,电极层中 Na 的浓度在微米尺度上发生了变化。此外,Operando 拉曼光谱显示了活性材料中原子尺度的键合状态变化,包括可逆结构变化。通过飞行时间二次离子质谱法,可以清晰地观察到 ASSB 循环后的元素分布和颗粒形状,并揭示纳米尺度的 Na 迁移机制。因此,这项研究可以通过观察多种尺度的反应过程,从根本上全面了解充放电机制。
期刊介绍:
Energy & Environmental Materials (EEM) is an international journal published by Zhengzhou University in collaboration with John Wiley & Sons, Inc. The journal aims to publish high quality research related to materials for energy harvesting, conversion, storage, and transport, as well as for creating a cleaner environment. EEM welcomes research work of significant general interest that has a high impact on society-relevant technological advances. The scope of the journal is intentionally broad, recognizing the complexity of issues and challenges related to energy and environmental materials. Therefore, interdisciplinary work across basic science and engineering disciplines is particularly encouraged. The areas covered by the journal include, but are not limited to, materials and composites for photovoltaics and photoelectrochemistry, bioprocessing, batteries, fuel cells, supercapacitors, clean air, and devices with multifunctionality. The readership of the journal includes chemical, physical, biological, materials, and environmental scientists and engineers from academia, industry, and policy-making.