材料科学
电化学
阴极
化学工程
电解
吸附
催化作用
过氧化氢
异质结
氧气
析氧
产量(工程)
电极
制氢
可持续能源
电催化剂
功率密度
电解水
氧化还原
无机化学
法拉第效率
纳米技术
动力学
氢
电流密度
氢燃料
可逆氢电极
过氧化物
阳极
作者
Lijun Yang,Sitong Liu,Weiwei He,Fengzhan Sun,Shubing Bi,Hongge Pan,Lingfeng Zhu,Tianyi Ma,Lei Zhang
摘要
ABSTRACT Facing the challenge of achieving efficient and sustainable hydrogen peroxide (H 2 O 2 ) production, a promising strategy is developing highly selective electrocatalysts with controllable synthesis, structural design and performance optimization. Herein, an interfacial acid sites‐mediated ZnSe/ZnO heterojunction is synthesized for highly selective two‐electron oxygen reduction reaction (ORR) toward H 2 O 2 production. Experimental and theoretical results reveal that surface selenization induced reconstruction, forming a synergistic interface with a built‐in electric field and tailored oxygen vacancies (Ovs), which collaboratively optimize the electronic structure and accelerate reaction kinetics of two‐electron ORR. Moreover, interfacial unsaturated Zn 2+ sites and OVs served as Lewis acids sites to enhance O 2 adsorption and activation, while Br ø nsted acids sites were liable to donate protons to promote *OOH formation. Consequently, a ZnSe/ZnO ‖ ZnO flow cell enabled paired electrolysis for concurrent H 2 O 2 production with a high H 2 O 2 yield of 754.4 M g cat −1 over 12 h. A rechargeable Zn‐H 2 O 2 cell using ZnSe/ZnO cathode delivered a power density of 11.99 mW cm −2 as a self‐sustaining process for simultaneous on‐site H 2 O 2 production and electrical energy generation. This work offers a sustainable route for on‐site H 2 O 2 synthesis with improved energy efficiency, advancing green chemistry and circular economy.
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