质子
膜
过氧化氢
光催化
材料科学
质子耦合电子转移
质子输运
共价有机骨架
光化学
电子转移
电子供体
电子传输链
化学工程
氢
制氢
催化作用
氧气
共价键
电子
工作(物理)
分解水
辐照
降级(电信)
氧化还原
纳米技术
电荷(物理)
膜反应器
活性氧
化学
聚合
作者
Zhiwei Xing,Chi Qiao,Kunkun Ren,Haitao Su,S Hui Wang,Zhifeng Dai,Yuanyuan Xiong,Xiangju Meng,Shengqian Ma,Qi Sun
摘要
ABSTRACT Coordinating proton and electron transport remains a central challenge in photocatalysis, particularly for H 2 O 2 synthesis, where two‐electron oxygen reduction requires synchronized proton delivery and charge transfer. Here, we report hydroxyl‐functionalized three‐dimensional covalent organic framework (COF) membranes that regulate proton‐coupled electron transfer within ordered nanochannels. Phenolic hydroxyl groups are precisely embedded in the membrane pores as internal proton reservoirs, while the continuous COF framework provides pathways for photogenerated electron transport. By tuning hydroxyl density, the dihydroxylated COF‐2OH membrane establishes an optimal proton‐management microenvironment, promoting O 2 adsorption, charge separation, superoxide/*OOH intermediate formation, and dynamic proton recycling. Under one‐sun irradiation in pure water and ambient air, COF‐2OH achieves an H 2 O 2 production rate of 21.79 mmol g – 1 h – 1 without sacrificial agents or cocatalysts, greatly outperforming the corresponding powder catalyst. Mechanistic experiments and simulations reveal that membrane confinement and hydroxyl‐mediated proton buffering jointly synchronize proton and electron fluxes during continuous photocatalysis. The free‐standing membrane can also be integrated into a tubular Al 2 O 3 ‐supported reactor for in situ H 2 O 2 ‐driven photo‐Fenton degradation of organic pollutants. This work establishes proton‐managing COF membranes as programmable reaction interfaces for efficient solar H 2 O 2 production and integrated water treatment.
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