Dual-Channel Regulation of Spin Polarization Achieves 1 + 1 > 2 Electrocatalytic Performance in Spinel Ferrites
Jinli Zhu, Xuebing Peng, Pinxian Xi, Chenglong Jia, Daqiang Gao
Abstract
Electron spin polarization enhances the kinetics of the oxygen evolution reaction (OER), a rate-limiting step that restricts the energy efficiency of water splitting. Here, a dual-channel spin-regulated strategy combining chiral-induced spin selectivity (CISS) and external magnetic field ( M H )-induced spin polarization synergistically reduces the overpotential and enhances durability in spinel-based ferromagnetic materials. Chiral molecule-modified CoFe 2 O 4 under M H (CFO-L-M) achieves a 90 mV reduction in overpotential compared to unmodified CFO, which is primarily ascribed to the synergistic “1 + 1 > 2” effect arising from the dual-spin channel mechanism. Theoretical calculations show that surface spin states critically influence adsorbate binding, with spin selectivity and polarization being activated during the first electron transfer step, ultimately producing triplet O 2 . This study elucidates spin-related OER kinetics, offering a foundation for designing advanced spin-dependent electrocatalysts.