堆栈(抽象数据类型)
降级(电信)
材料科学
电极
电池(电)
阴极
电化学
石墨
锂(药物)
恒流
环境压力
光电子学
高压
储能
纳米技术
化学工程
阳极
作者
Heng Wang,Rui Wang,Christopher A. O’Keefe,Erik Björklund,Daniela Proprentner,Joe C. Stallard,Hwee Jien Tan,Wesley M. Dose,Louis F. J. Piper,Robert S. Weatherup,Angkur J. D. Shaikeea,Clare P. Grey,Michaël De Volder
标识
DOI:10.1038/s41560-026-02087-6
摘要
Abstract While electrochemical degradation mechanisms in lithium-ion batteries are well studied, the influence of mechanical factors remains poorly understood. Here we introduce a high-precision stack-pressure control and dilatometry tool to apply a uniform and constant stack pressure on electrodes independent of electrode swelling. By increasing stack pressure fourfold over typical initial values, we double the lifetime of graphite ‖ LiNi 0.8 Mn 0.1 Co 0.1 O 2 cells, an industrially relevant battery chemistry, without altering active materials or electrolytes. This suggests that many lithium-ion batteries operate under sub-optimal stack-pressure conditions, leading to curtailed lifetimes. We demonstrate that different degradation mechanisms emerge outside the optimal pressure window: low stack pressure accelerates cathode cracking, whereas high pressure promotes lithium plating. Our findings highlight coupled mechanical–electrochemical degradation mechanisms and identify stack-pressure optimization as a practical solution for increasing cycling stability.
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