Oxygen redox in battery cathodes: A brief overview

TL;DR

This paper reviews how oxygen redox mechanisms influence battery capacity, emphasizing computational methods like density functional theory to understand and optimize anionic redox activities in cathode materials for lithium and sodium-ion batteries.

Contribution

It provides an overview of oxygen redox in cathodes and highlights computational approaches for studying and harnessing anionic redox effects to improve battery performance.

Findings

Identification of key material systems with oxygen redox activity

Discussion of computational considerations for studying anionic redox

Insights into designing materials for higher capacity batteries

Abstract

The participation of oxygen or other anionic species in redox activities in cathode materials for lithium and sodium-ion battery systems is known to play a role in governing the useful capacity of these batteries. Directly probing anionic redox mechanisms is not possible, rather the computational analysis by density functional theory poses the main approach towards gleaning insights into anionic redox activity and harnessing these effects to maximize capacity in future electrode materials. Here we showcase material systems exhibiting this mechanism of ion insertion and removal, and present the key computational considerations in studying anionic redox activities in battery materials. Aided by new computationally derived understandings of the role of anionic redox in emerging battery materials, increasingly greater levels of useable capacities can be extracted through informed materials design.