Electron energy levels determining cathode electrolyte interphase formation

Electron Pub Date : 2023-10-10 DOI:10.1002/elt2.9
Zhengfeng Zhang, Changdong Qin, Xiaopeng Cheng, Jinhui Li, Yuefei Zhang, Wengao Zhao, Le Wang, Yingge Du, Manling Sui, Pengfei Yan
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引用次数: 1

Abstract

Cathode electrolyte interphase (CEI) has a significant impact on the performance of rechargeable batteries and is gaining increasing attention. Understanding the fundamental and detailed CEI formation mechanism is of critical importance for battery chemistry. Herein, a diverse of characterization tools are utilized to comprehensively analyze the composition of the CEI layer as well as its formation mechanism by LiCoO2 (LCO) cathode. We reveal that CEI is mainly composed of the reduction products of electrolyte and it only parasitizes the degraded LCO surface which has transformed into a disordered spinel structure due to oxygen loss and lithium depletion. Based on the energy diagram and the chemical potential analysis, the CEI formation process has been well explained, and the proposed CEI formation mechanism is further experimentally validated. This work highlights that the CEI formation process is nearly identical to that of the anode-electrolyte-interphase, both of which are generated due to the electrolyte directly in contact with the low chemical potential electrode material. This work can deepen and refresh our understanding of CEI.

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决定阴极电解质间相形成的电子能级
阴极电解质界面(CEI)对可充电电池的性能有重要影响,越来越受到人们的关注。了解基本和详细的CEI形成机制对电池化学至关重要。本文利用多种表征工具综合分析了licoo2 (LCO)阴极CEI层的组成及其形成机理。我们发现CEI主要由电解质的还原产物组成,它只寄生在降解的LCO表面,而LCO由于氧损失和锂耗尽而转变为无序尖晶石结构。基于能量图和化学势分析,很好地解释了CEI的形成过程,并进一步实验验证了所提出的CEI形成机理。这项工作强调了CEI的形成过程几乎与阳极-电解质-界面的形成过程相同,两者都是由于电解质直接与低化学势电极材料接触而产生的。这项工作可以加深和更新我们对CEI的理解。
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