普鲁士蓝
制氢
电解
析氧
电化学
催化作用
电解水
纳米技术
分子
氢
电子转移
组合化学
材料科学
化学
分解水
电极
光化学
物理化学
电解质
有机化学
光催化
作者
Ying Wang,Hui Ding,Changyi Deng,Tingting Huang,Juan Xiao,Mengyuan Xie,Li Zhang,Guan‐Cheng Xu
标识
DOI:10.1002/asia.202500665
摘要
Abstract In conventional water electrolysis for hydrogen generation, the four‐electron transfer mechanism of the oxygen evolution reaction (OER) induces kinetic sluggishness. This sluggishness results in substantial overpotentials and subpar energy conversion efficiencies. Electrochemical small‐molecule oxidation reactions possess inherent thermodynamic advantages, thereby effectively reducing the overall operating voltage of the electrolyzer. This voltage reduction provides a novel pathway to overcome the bottleneck imposed by OER kinetics. Prussian blue analogues and their derivatives, which feature tunable metal centers and open cubic framework structures, represent ideal platforms for constructing efficient coupled catalytic systems. This review systematically summarizes their synthetic methods, the influence of electronic structures on catalytic activity, and corresponding optimization strategies, with a specific focus on applications in small‐molecule oxidation‐assisted hydrogen production. Furthermore, an in‐depth analysis of current challenges is presented, and future research directions are outlined. The goal is to provide a theoretical foundation and technical reference for advancing green hydrogen energy technology toward practical breakthroughs.
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