继电器
催化作用
电解水
离解(化学)
吸附
合理设计
氢
密度泛函理论
化学
分解水
再分配(选举)
电解
制氢
化学物理
膜
纳米技术
活化能
化学工程
工作(物理)
无机化学
氢燃料
析氧
活动站点
离子
光化学
作者
Bowei Liu,Chaoyu You,Zizheng Fang,Menglu Li,Xiaojun Wang,Lijun Qu,Lei Yang,Lifang Jiao
出处
期刊:Angewandte Chemie
[Wiley]
日期:2025-10-28
卷期号:64 (52): e202517861-e202517861
被引量:18
标识
DOI:10.1002/anie.202517861
摘要
Abstract Ruthenium is emerging as a promising catalyst for the hydrogen evolution reaction (HER) in alkaline water electrolysis. However, the high energy barrier for water dissociation and inappropriate hydrogen adsorption energy often hinders their catalytic efficiency. To address these challenges, Ru‐Fe 7 C 3 @CNF with abundant twin boundaries has been rationally designed based on synergistic relay catalysis principles. Experimental results combined with mechanistic analysis demonstrate that the electron‐deficient Fe 7 C 3 can accelerate water dissociation, and the resulting protons can rapidly spill over to Ru due to a smaller work function difference, subsequently, the Ru with moderate ΔG H* facilitates hydrogen evolution. Notably, Ru‐Fe 7 C 3 @CNF with twin‐boundary defects and charge redistribution induced by the heterointerface optimizes the adsorption energy and enhances the intrinsic activity of each functional site. As expected, this catalyst exhibits enhanced HER performance that is superior to commercial Pt/C. Moreover, the assembled anion exchange membrane water electrolysis utilizing Ru‐Fe 7 C 3 @CNF//NiFe LDH operates at a voltage of 1.67 V at a current density of 0.5 A cm − 2 and maintains remarkable stability over 300 h. This work offers a valuable strategy for the rational design of multisite electrocatalysts.
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