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Calendar aging of silicon-containing batteries

Authors :
Marco-Tulio F. Rodrigues
Nathan R. Neale
Shelley D. Minteer
Brian Cunningham
Christopher A. Apblett
Gerard M. Carroll
Gabriel M. Veith
Andrew M. Colclasure
Anthony K. Burrell
Maxwell C. Schulze
John T. Vaughey
Josefine McBrayer
Chen Fang
Daniel P. Abraham
Gao Liu
Christopher S. Johnson
Katharine L. Harrison
Ira Bloom
Source :
Nature Energy. 6:866-872
Publication Year :
2021
Publisher :
Springer Science and Business Media LLC, 2021.

Abstract

High-energy batteries for automotive applications require cells to endure well over a decade of constant use, making their long-term stability paramount. This is particularly challenging for emerging cell chemistries containing silicon, for which extended testing information is scarce. While much of the research on silicon anodes has focused on mitigating the consequences of volume changes during cycling, comparatively little is known about the time-dependent degradation of silicon-containing batteries. Here we discuss a series of studies on the reactivity of silicon that, collectively, paint a picture of how the chemistry of silicon exacerbates the calendar aging of lithium-ion cells. Assessing and mitigating this shortcoming should be the focus of future research to fully realize the benefits of this battery technology. Silicon-containing batteries are increasingly becoming a reality in the mass market, but their calendar aging behaviours have received comparatively little attention. Researchers from the Silicon Consortium Project discuss the issues surrounding the calendar lifetime of silicon anodes for lithium-ion batteries.

Details

ISSN :
20587546
Volume :
6
Database :
OpenAIRE
Journal :
Nature Energy
Accession number :
edsair.doi...........a7767badb7683665222b3fc55b000164