First-principles prediction of potentials and space-charge layers in all-solid-state batteries

Michael W. Swift; Yue Qi

First-principles prediction of potentials and space-charge layers in all-solid-state batteries

ORAL

Abstract

As all-solid-state batteries (SSBs) develop as an alternative to traditional cells, a thorough theoretical understanding of driving forces behind battery operation is needed. We present a fully first-principles-informed model of potential profiles in SSBs and apply the model to the Li/LiPON/Li_xCoO₂ system. These profiles, especially the interface dipoles, yield valuable information about lithium distribution and transport and the nature of interfacial electrical double layers. The results suggest design rules to minimize interfacial lithium transport resistance and optimize device performance.

^*This work was supported by the Nanostructures for Electrical Energy Storage (NEES) center, an Energy Frontier Research Center funded by the U.S. Department of Energy, Office of Science, Basic Energy Sciences under Award number DESC0001160.

March 5, 2019, 8:24 AM – March 5, 2019, 8:36 AM

Presenters

Michael W. Swift
- Chemical Engineering and Materials Science, Michigan State University

Authors

Michael W. Swift
- Chemical Engineering and Materials Science, Michigan State University
Yue Qi
- Chemical Engineering and Materials Science, Michigan State University