材料科学
阳极
阴极
电化学动力学
电化学
体积热力学
复合材料
锂(药物)
电解质
堆栈(抽象数据类型)
多物理
变形(气象学)
热力学
电极
化学
有限元法
物理化学
内分泌学
物理
程序设计语言
医学
计算机科学
作者
M.K. Han,Hua Zhang,Peng Xie,Wenjing Zhang,Chunhao Yuan
摘要
Abstract Appropriate stack pressure improves the solid-to-solid interfacial stability and prolongs cyclability of the all-solid-state lithium metal batteries (ASSLBs). A low stack pressure is required for the commercialization of ASSLBs, and the key to reduce stack pressure is to regulate the volume variation of the components during charging/discharging. This study establishes a three-dimensional electrochemical-mechanical coupled model to investigate the underlying mechanism of the volume variation of ASSLBs comprised of LiNi0.8Co0.1Mn0.1O2 cathode, Li6PS5Cl solid electrolyte and lithium metal anode, considering the electrochemical kinetics, Li diffusion, elastic-plastic deformation and their interplays. Results reveal that lithium plating at the anode surface significantly increases the volumetric strain (>60%) and dominates the overall volume expansion of ASSLBs during charging. Increasing the thickness of lithium metal anode is beneficial to accommodate the Li deposition through the deformation of soft lithium, to reduce the expansion in the thickness direction and lower the external pressure. The carbon black-binder domain (CBD) with lower Young's modulus can be used as a buffer layer to adjust the volume change in cathode domain, which can also effectively alleviate the mechanical stress to reduce possible damage. Increasing the volume fraction of NCM particles can induce larger volumetric strain of the cathode, resulting in an increase in the expansion of ASSLBs. The developed multiphysics model reveals the underlying electrochemical-mechanical coupled volume variation mechanism of the ASSLBs to provide guidance on the design and fabrication of next-generation ASSLBs under low pressure.
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