Abstract
Currently, there are few analyses available to quantitatively uncover the effects of cycling-induced damage in silicon-based batteries on the stress evolution and capacity loss. We develop a comprehensive model to address this issue. The comparisons between numerical and experimental results validate the proposed model and illustrate the damage effects on the decrease of structural stiffness and the stress evolution. In contrast to the common perception that damage is unfavorable to batteries, we propose a concept of training of batteries which introduces sufficient damage to batteries to improve retention performance. The training process is implemented by electrochemical cycling under a large C-rate, and its merit is validated experimentally. We also discuss optimization of the training method.
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