Interactions are important: Linking multi-physics mechanisms to the performance and degradation of solid-state batteries

The behaviour of solid-state batteries to many application-relevant operating conditions is intrinsically multiphysical and multiscale, involving the electrochemical performance and chemical stability coupled with the thermal and mechanical properties of multiple components. This review presents a h...

Full description

Saved in:
Bibliographic Details
Published in:Materials today (Kidlington, England) England), 2021-10, Vol.49, p.145-183
Main Authors: Pang, Mei-Chin, Yang, Kai, Brugge, Rowena, Zhang, Teng, Liu, Xinhua, Pan, Feng, Yang, Shichun, Aguadero, Ainara, Wu, Billy, Marinescu, Monica, Wang, Huizhi, Offer, Gregory J.
Format: Article
Language:English
Subjects:
Characterization
Interaction
Multi-physics mechanisms
Simulation
Solid-state battery
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The behaviour of solid-state batteries to many application-relevant operating conditions is intrinsically multiphysical and multiscale, involving the electrochemical performance and chemical stability coupled with the thermal and mechanical properties of multiple components. This review presents a holistic approach to discussing the multiscale physical-electro-chemical interactions and degradation mechanisms in solid-state batteries. While the propagation of lithium filaments depends strongly on the critical current densities, we show that effective prevention of excessive Li plating and stripping requires a combined understanding of solid-state electrochemistry, microstructure, mechanics, operating conditions, and their interactions. A review of how multiphysical interactions affect the optimum design of thin-film, three-dimensional and composite solid-state cell architectures is also included. Although the use of lithium metal as negative electrodes could improve the energy densities of solid-state batteries, we show that its high homologous temperature could cause cell failure during manufacturing. By comparing published model predictions with experimental observations, we present a critical analysis of the strengths and limitations of state-of-the-art models and characterisation techniques in solid-state battery research. This comprehensive mechanistic analysis provides an insight into the interplay among the multiple complex multiphysical mechanisms, shedding light on the process of cell design for next-generation solid-state batteries.
ISSN:1369-7021
1873-4103
DOI:10.1016/j.mattod.2021.02.011