A Critical Evaluation of Interfacial Stability in Li-excess Cation-disordered Rock-salt Oxide Cathode

Li-rich cation-disordered rock-salt oxides (DRXs) are promising candidates for next-generation Li-ion cathode materials due to the demonstrated high capacity (> 300 mAh g- 1) by utilizing both transition metal (TM) cations and oxygen anions with a much-widened material design space as compared to conventional layered cathodes, which heavily rely on Co and Ni. However, the serious performance deterioration during long-term cycling impedes their practical applications. Although oxygen loss and associated densified surface layer are responsible for the performance deterioration, these issues are part of the scope of cathode electrolyte interface (CEI) which need further study, including its chemical composition, chemical and electrochemical stability, formation mechanism as well as the effects on battery performance. Through careful monitoring of the CEI evolution of Li1.2Mn0.4Ti0.4O2 (LMTO) in conventional carbonated-based electrolyte upon charging and discharging, we identify that the continuously growing CEI layer exhibits gradually increasing LiF as the main composition. The significant change of the CEI layer is closely related to loss of lattice oxygen (O2-), the continuous over-reduction of redox-active TMs (e.g. Mn3+, Mn 4+) from the cathode surface, severe TMs dissolution, and the release of CO2/ O2, and irreversible phase transition in surface structures, which eventually cause a fast capacity degradation and voltage decay. This research provides a fundamental interpretation for understanding interfacial stability in this young class of DRX cathode materials.

Automated summary

Li-rich cation-disordered rock-salt oxides (DRXs) have high capacity but suffer from serious performance degradation due to the growth of a LiF-rich cathode electrolyte interface (CEI) layer, which is caused by oxygen loss, over-reduction of redox-active TMs, TMs dissolution, and irreversible phase transition. This research provides a fundamental understanding of interfacial stability in DRX cathode materials.