氢
化学物理
电解质
离解(化学)
材料科学
催化作用
制氢
拉曼光谱
氢经济
吸附
自行车
分解水
电化学
纳米技术
化学
氢的自旋异构体
无机化学
化学工程
氢气储存
离子
质子
电解水
作者
Yan Zhang,Biao Feng,Jingyi Tian,Shiqi Zhou,Changkai Zhou,Yiqun Chen,Xiaoli Xia,Xizhang Wang,Lijun Yang,Luming Peng,Qiang Wu,Hongwen Huang,Zheng Hu
标识
DOI:10.1038/s41467-025-65909-3
摘要
Controllable supply of hydrogen intermediate across a wide pH range is crucial for electroreduction reactions, but is hindered by pH-dependent hydrogen species formation on conventional catalysts. We report a lattice-hydrogen cycling mechanism that dissociates hydrogen intermediate availability from electrolyte pH. By integrating proton-blocking Ru with thermally-hydrogenated HxWO3, we create a dynamic hydrogen reservoir, enabling efficient hydrogen supply. In-situ Raman spectroscopy, isotopic labeling, and theoretical simulations reveal the lattice hydrogen in HxWO3 migrates swiftly to Ru active sites via low-energy-barrier pathways, while consumed hydrogen is spontaneously replenished via proton adsorption (acidic) or water dissociation (alkaline/neutral). Consequently, this catalyst achieves a competitive pH-universal performance for hydrogen evolution reaction, with low overpotentials (125 mV acidic, 142 mV alkaline, 219 mV neutral @1 A cm-2) alongside 500-hour stability.
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