Layer-Resolved Mechanical Degradation of a Ni-Rich Positive Electrode

IF 4.6 4区 化学 Q2 ELECTROCHEMISTRY
Batteries Pub Date : 2023-11-28 DOI:10.3390/batteries9120575
Priyank Gupta, Moritz Streb, Aamer Siddiqui, M. Klett, Göran Lindbergh, Peter Gudmundson
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Abstract

The effects of electrochemical aging on the mechanical properties of electrodes in lithium-ion batteries are challenging to measure and are largely unknown. Mechanochemical degradation processes occur at different scales within an electrode and understanding the correlation between the degradation of mechanical properties, electrochemical aging, and morphological changes is crucial for mitigating battery performance degradation. This paper explores the evolution of mechanical and electrochemical properties at the layer level in a Ni-rich positive electrode during the initial stages of electrochemical cycling. The investigation involves complementary cross-section analyses aimed at unraveling the connection between observed changes on both macroscopic and microscopic scales. The macroscopic constitutive properties were assessed using a U-shaped bending test method that had been previously developed. The compressive modulus exhibited substantial dependency on both the porous structure and binder properties. It experienced a notable reduction with electrolyte wetting but demonstrated an increase with cycling and aging. During the initial stages of aging, electrochemical impedance spectra revealed increased local resistance near the particle–electrolyte interface. This is likely attributable to factors such as secondary particle grain separation and the redistribution of carbon black. The swelling of particles, compression of the binder phase, and enhanced particle contact were identified as probable factors adding to the elevation of the elastic modulus within the porous layer as a result of cycling.
层解析富镍正极的机械降解
测量电化学老化对锂离子电池电极机械性能的影响具有挑战性,并且在很大程度上是未知的。机械化学降解过程发生在电极内部的不同尺度上,了解机械性能退化、电化学老化和形态变化之间的相关性对于缓解电池性能退化至关重要。本文探讨了富镍正极在电化学循环初始阶段层级机械和电化学特性的演变。研究涉及互补的横截面分析,旨在揭示在宏观和微观尺度上观察到的变化之间的联系。我们使用之前开发的 U 形弯曲测试方法对宏观构成特性进行了评估。压缩模量与多孔结构和粘合剂特性都有很大关系。它在电解质润湿时显著降低,但在循环和老化时又有所增加。在老化的初始阶段,电化学阻抗谱显示颗粒-电解质界面附近的局部电阻增加。这可能是由于二次颗粒晶粒分离和炭黑重新分布等因素造成的。颗粒的膨胀、粘合剂相的压缩和颗粒接触的增强被认为是循环导致多孔层内弹性模量增加的可能因素。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Batteries
Batteries Energy-Energy Engineering and Power Technology
CiteScore
4.00
自引率
15.00%
发文量
217
审稿时长
7 weeks
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