Litcius/Paper detail

Microstructure and Pressure-Driven Electrodeposition Stability in Solid-State Batteries

Ankit Verma, Hiroki Kawakami, Hiroyuki Wada, Anna Hirowatari, Nobuhisa Ikeda, Yoshifumi Mizuno, Toshikazu Kotaka, Koichiro Aotani, Yuichiro Tabuchi, Partha P. Mukherjee

2021Cell Reports Physical Science47 citationsDOIOpen Access PDF

Abstract

Interfacial deposition stability at the Li-metal-solid electrolyte interface in all solid-state batteries is governed by the stress-transport-electrochemistry coupling in conjunction with the polycrystalline/amorphous solid electrolyte architecture. In this work, we delineate the optimal solid electrolyte microstructure comprising grains, grain boundaries, and voids possessing desirable ionic conductivity and elastic modulus for superior transport and strength. An analytical formalism is provided to discern the impact of external “stack” pressure-induced mechanical stress on electrodeposition stability; the stress magnitudes obtained are in the megapascal range, considerably diminishing the stress-kinetics effects. For experimental stack pressures ranging up to 10 MPa, the impact of stress on reaction kinetics is negligibly small, and electrolyte transport overpotentials dictate electrodeposition stability. High current density operation with stable deposition can be ensured with ample external pressure, high temperature, and low surface roughness operation for a low shear modulus ratio of the solid electrolyte to Li-metal.

Topics & Concepts

Materials scienceElectrolyteMicrostructureAmorphous solidComposite materialElastic modulusGrain sizeFast ion conductorIonic conductivityChemistryElectrodePhysical chemistryOrganic chemistryAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research