Oxygen Bridge Governs OER via Deep Self-Reconstruction in Fe-Co Oxyhydroxides.
Mingyu Liu, Bowen Pei, Hongyu Ba, Wei Ni, Huaheng Zhao, Shuang Chen, Jiamin Zhao, Jinsheng Zhao
Abstract
Open AccessThe oxygen evolution reaction (OER) in water splitting involves complex multi-electron-proton transfer processes and represents the rate-determining step limiting overall electrolysis efficiency. Developing non-noble-metal catalysts with high activity and stability is therefore essential. Herein, a heterogeneous synthesis strategy was employed to in situ construct an iron-rich layered sulfate precursor (Fe0.42Co0.58-SO4/NF) on nickel foam, which underwent deep self-reconstruction in alkaline electrolyte to form nanoflower-like Fe0.42Co0.58OOH/NF. The optimized catalyst maintained its iron-rich composition and hierarchical structure, delivering outstanding OER performance with an overpotential of 220 mV at 10 mA·cm-2, a Tafel slope of 31.9 mV·dec-1, and stability exceeding 12 h at 600 mA·cm-2. Synchrotron analyses revealed dynamic transitions between mono-μ-O and di-μ-O Fe-M (M = Fe, Co) oxygen bridges during reconstruction, which enhanced both structural robustness and active-site density. The Fe-rich environment promoted the formation of Fe3+-O-Fe3+ units that synergized with Co4+ species to activate the lattice oxygen mechanism (LOM), thereby accelerating OER kinetics. This work elucidates the key role of oxygen-bridge geometry in optimizing catalytic activity and durability, providing valuable insights into the rational design of Fe-Co-based non-noble-metal catalysts with high iron content for efficient water oxidation.