Tailoring of Grain Boundary Structure and Chemistry of Cathode Particles for Enhanced Cycle Stability of Lithium Ion Battery

TL;DR

This paper introduces a novel grain boundary engineering approach using solid electrolyte infusion to significantly improve cycle stability and voltage retention in lithium-ion battery cathodes, addressing capacity fading issues.

Contribution

It demonstrates that infusing solid electrolyte into cathode grain boundaries enhances ion transport and prevents detrimental reactions, offering a new design strategy for durable batteries.

Findings

Solid electrolyte infusion improves capacity retention.

Prevents liquid electrolyte penetration and related degradation.

Enhances voltage stability at various temperatures.

Abstract

The biggest challenge for the commercialization of layered structured nickel rich lithium transition metal oxide cathode is the capacity and voltage fading. Resolving this problem over the years follows an incremental progress. In this work, we report our finding of totally a new approach to revolutionize the cycle stability of aggregated cathode particles for lithium ion battery at both room and elevated temperatures. We discover that infusion of a solid electrolyte into the grain boundaries of the cathode secondary particles can dramatically enhance the capacity retention and voltage stability of the battery. We find that the solid electrolyte infused in the boundaries not only acts as a fast channel for Li ion transport, but also most importantly prevents penetration of the liquid electrolyte into the boundaries, consequently eliminating the detrimental factors that include solid-liquid interfacial reaction, intergranular cracking, and layer to spinel phase transformation. The present work, for the first time, reveals unprecedented insight as how the cathode behaves in the case of not contacting with the liquid electrolyte, ultimately points toward a general new route, via grain boundary engineering, for designing of better batteries of both solid-liquid and solid state systems.