Stabilization of Oxygen-Dependent Fe<SUP>3+/4+</SUP> Redox in Li-Excess DRX Cathode Exhibiting Anionic Redox via Transition Metal CombinationStabilization of Oxygen-Dependent Fe3+/4+Redox inLi-Excess DRX Cathode Exhibiting Anionic Redox viaTransition Metal Combination
- Other Titles
- Stabilization of Oxygen-Dependent Fe3+/4+Redox inLi-Excess DRX Cathode Exhibiting Anionic Redox viaTransition Metal Combination
- Authors
- Lee, Hayeon; Kim, Minji; Park, Hyunyoung; Yoo, Yiseul; Na, Sangmun; Lim, Hee-Dae; Kim, Jongsoon; Yoon, Won-Sub
- Issue Date
- Apr-2024
- Publisher
- John Wiley & Sons Ltd.
- Keywords
- Coulombic efficiency; disordered rock-salt; Fe-based cathodes; Li-ion batteries; oxygen redox; voltage hysteresis
- Citation
- Advanced Functional Materials, v.34, no.14, pp 1 - 15
- Pages
- 15
- Indexed
- SCIE
SCOPUS
- Journal Title
- Advanced Functional Materials
- Volume
- 34
- Number
- 14
- Start Page
- 1
- End Page
- 15
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/197128
- DOI
- 10.1002/adfm.202312401
- ISSN
- 1616-301X
1616-3028
- Abstract
- Developing sustainable Li-ion batteries requires high-energy cathodes based on low-cost, earth-abundant elements, moving away from low-reserve nickel and cobalt. Fe-based oxide cathodes with Fe3+/4+ and O2-/n- redox couples offer potential but face low initial Coulombic efficiency and significant voltage hysteresis. This study investigates Li-excess Fe-based disordered rock-salt (DRX) oxyfluorides (Li2Fe0.5M0.5O2F; M = Fe, Ti, Mn) using combined electrochemical/spectroscopic characterization and first-principles calculation. Oxygen-dependent Fe3+/4+ redox, related to Fe 3d-O 2p hybrid state, can be stabilized when combined with Mn3+/4+ redox in DRX structure owing to the unusual decrease in its redox potential. The moderately high charge transfer gap stabilizes Fe4+ against ligand-to-metal charge transfer (LMCT) on charge, reduces the amount of oxygen oxidation, thereby increasing Coulombic efficiency. On discharge, it allows metal-to-ligand charge transfer (MLCT) without substantial overpotential, reducing hysteresis in oxygen redox. The resulting composition exhibits high capacity (309 mAh g(-1)) and energy density (998 Wh kg(-1)), providing insights for next-generation Ni- and Co-free cathode materials.
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