过电位
材料科学
催化作用
氢
氢溢流
分解水
电解
电解水
制氢
溢出效应
化学工程
阴极
无机化学
异质结
化学物理
纳米技术
氢燃料
法拉第效率
电催化剂
星团(航天器)
膜
作者
Deli Tian,Junlin Yan,Lingfeng Yang,Tingting Liu,Zitao Ni,Shaodong Sun,Anran Chen,Hua Zhang
摘要
ABSTRACT The rational construction of a reverse hydrogen spillover channel within the catalyst effectively accelerates hydrogen evolution reaction (HER) kinetics, whereas the driving forces and mechanisms that control hydrogen surface migration remain insufficiently investigated. Therefore, we constructed a strongly coupled RuO x ‐Mo 2 C cluster‐cluster heterostructure catalyst to effectively induce the reverse hydrogen spillover effect. Owing to the high‐density accessible active sites and efficient mass transport pathways provided by the strongly coupled cluster structure, hydrogen can migrate directionally and rapidly from Mo 2 C sites to RuO x sites via the reverse hydrogen spillover effect. This well‐defined interfacial coupling and functional partitioning substantially reduce the integrated energy barrier for water dissociation, H * transport, and H‐H coupling, leading to drastically accelerated HER kinetics and excellent electrocatalytic activity toward hydrogen evolution. It exhibits an overpotential of only 15 mV at 10 mA cm −2 . Moreover, the catalyst maintains stable performance for up to 1000 h under continuous electrolysis without significant degradation, demonstrating outstanding structural and catalytic stability. Furthermore, an anion exchange membrane water electrolyzer with RuO x ‐Mo 2 C as the cathode delivers superior catalytic activity, exhibiting a cell voltage of 1.76 V at 1.0 A cm −2 and long‐term stability over 1500 h, holding great promise for industrial high‐current applications.
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