材料科学
电极
电解质
锂(药物)
背景(考古学)
微观结构
相(物质)
电池(电)
离子
离子运输机
锂离子电池
化学工程
纳米技术
复合材料
热力学
化学
物理化学
物理
工程类
内分泌学
古生物学
功率(物理)
有机化学
生物
医学
作者
Aashutosh Mistry,Kandler Smith,Partha P. Mukherjee
标识
DOI:10.1021/acsami.7b17771
摘要
Lithium-ion battery electrodes exhibit complex interplay among multiple electrochemically coupled transport processes, which rely on the underlying functionality and relative arrangement of different constituent phases. The electrochemically inactive solid phases (e.g., conductive additive and binder, referred to as the secondary phase), while beneficial for improved electronic conductivity and mechanical integrity, may partially block the electrochemically active sites and introduce additional transport resistances in the pore (electrolyte) phase. In this work, the role of mesoscale interactions and inherent stochasticity in porous electrodes is elucidated in the context of short-range (interface) and long-range (transport) characteristics. The electrode microstructure significantly affects kinetically and transport-limiting scenarios and thereby the cell performance. The secondary-phase morphology is also found to strongly influence the microstructure-transport-kinetics interactions. Apropos, strategies have been proposed for performance improvement via electrode microstructural modifications.
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