Fingerprint oxygen redox reactions in batteries through high-efficiency mapping of resonant inelastic X-ray scattering (mRIXS)
Jinpeng Wu, Qinghao Li, Shawn Sallis, Zengqing Zhuo, William E. Gent,, William C. Chueh, Shishen Yan, Yi-de Chuang, and Wanli Yang

TL;DR
This paper introduces a high-efficiency mRIXS mapping technique to identify and analyze oxygen redox reactions in battery electrodes, providing a comprehensive benchmark for future research.
Contribution
It presents the first complete assignment of mRIXS features in battery materials, enabling precise characterization of oxygen redox states.
Findings
Two key mRIXS features correlate with critical oxygen redox states.
Features evolve consistently with electrochemical cycling.
Provides guidelines for future oxygen redox studies in batteries.
Abstract
Realizing reversible reduction-oxidation (Redox) reactions of lattice oxygen in batteries is a promising way to improve the energy and power density. However, conventional oxygen absorption spectroscopy fails to distinguish the critical oxygen chemistry in oxide-based battery electrodes. Therefore, high-efficiency full-range mapping of resonant inelastic X-ray scattering (mRIXS) has been developed as a reliable probe of oxygen redox reactions. Here, based on mRIXS results collected from a series of Li1.17Ni0.21Co0.08Mn0.54O2 electrodes at different electrochemical states and its comparison with peroxides, we provide a comprehensive analysis of five components observed in the mRIXS results. While almost all the components change upon electrochemical cycling, comparison with peroxide species show that only two evolving features correspond to the critical oxidized oxygen states. One is a…
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