过电位
铁磁性
材料科学
析氧
分解水
磁性
电化学
阳极
钌
极化(电化学)
催化作用
氢
未成对电子
自旋极化
电子
电解水
电子转移
电催化剂
自旋(空气动力学)
无机化学
化学物理
自旋电子学
基质(水族馆)
氧气
电解质
旋转阀
自旋态
磁电阻
交换偏差
凝聚态物理
结晶学
纳米技术
作者
Jing Jin,Yifan Liu,Zhihang Liu,Xing Peng,Yingqiang Li,Libin Hao,Chao Liu,Wenyao Zhang,Yongsheng Fu,Xiaohong Jiang,Pan Xiong,Junwu Zhu
标识
DOI:10.1002/adfm.202525644
摘要
Abstract Oxygen evolution reaction (OER) is essential for electrochemical water splitting and renewable hydrogen production. Ruthenium‐based catalysts exhibit excellent performance but suffer from insufficient stability to practical application. Herein, a spin‐state engineering strategy is explored to modulate the spin‐electron distribution of Ru single atoms via the intrinsic magnetism of Mn 5 O 8 substrate for efficient acidic OER. In Ru─Mn 5 O 8 system, the favorable Ru 4+ ‐O‐Mn 2+ configuration facilitates Ru‐site spin polarization and drives Ru 4+ from low‐spin to high‐spin through strong ferromagnetic coupling, whereas Ru 4+ remains low‐spin in nonferromagnetic Ru─MnO 2 . Unpaired d π electrons of high‐spin Ru 4+ enhance π‐donation to coordinated O 2− , optimizing Ru─O orbital overlap. Moreover, the interaction between high‐spin Ru 4+ and key intermediates is strengthened. Consequently, Ru─Mn 5 O 8 achieves a low overpotential of 186 mV at 10 mA cm −2 and sustains stability over 160 h at 100 mA cm −2 in acidic medium, outperforming Ru─MnO 2 (440 mV, 30 h) and commercial RuO 2 (250 mV, 40 h). When applied as an anode in a proton exchange membrane water electrolyzer, Ru─Mn 5 O 8 realizes 1 A cm −2 at 1.68 V and maintains stable operation for over 50 h. This work proposes a ferromagnetic interaction‐driven spin modulation strategy, offering a robust pathway for designing high‐performance electrocatalysts for acidic water oxidation.
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