Ferroelastic toughening: can it solve the mechanics challenges of solid electrolytes?

TL;DR

This paper explores the potential of ferroelastic toughening mechanisms, inspired by aerospace materials, to enhance the mechanical durability of solid electrolytes in all-solid-state lithium batteries.

Contribution

It proposes fundamental design principles for developing ferroelastically toughened ceramics to address mechanical challenges in solid electrolytes.

Findings

Ferroelastic toughening can improve electrolyte toughness.

Design principles can guide new electrolyte development.

Potential to mitigate crack propagation and interface debonding.

Abstract

The most promising solid electrolytes for all-solid-state Li batteries are oxide and sulfide ceramics. Current ceramic solid electrolytes are brittle and lack the toughness to withstand the mechanical stresses of repeated charge and discharge cycles. Solid electrolytes are susceptible to crack propagation due to dendrite growth from Li metal anodes and to debonding processes at the cathode/electrolyte interface due to cyclic variations in the cathode lattice parameters. In this perspective, we argue that solutions to the mechanics challenges of all-solid-state batteries can be borrowed from the aerospace industry, which successfully overcame similar hurdles in the development of thermal barrier coatings of superalloy turbine blades. Their solution was to exploit ferroelastic and transformation toughening mechanisms to develop ceramics that can withstand cyclic stresses due to large variations in temperature. This perspective describes fundamental materials design principles with which to search for solid electrolytes that are ferroelastically toughened.