人工光合作用
纳米技术
析氧
生化工程
光催化
催化作用
分解水
计算机科学
材料科学
共价有机骨架
共价键
氧化还原
化学
环境科学
工艺工程
太阳能燃料
光合作用
光催化
可持续能源
金属有机骨架
设计要素和原则
化学能
太阳能转换
组分(热力学)
系统工程
作者
Liangji Chen,Jier Huang
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-05-07
卷期号:20 (19): 13969-13993
标识
DOI:10.1021/acsnano.5c22772
摘要
reduction to generate chemical fuels has gained increasing attention as an attractive strategy for solar-to-fuel conversion. In these systems, the oxygen evolution reaction (OER) provides the necessary electrons and protons for driving the overall reaction but represents the rate-limiting step due to its inherently sluggish kinetics. Therefore, efficient overall artificial photosynthesis requires photocatalysts that can drive both the oxidation and reduction half-reactions, which impose stringent demands on catalyst design. Covalent organic frameworks (COFs) offer a versatile platform for designing such photocatalysts, owing to their strong light-harvesting capabilities , periodic architectures, and highly tunable frameworks that allow programmable catalytic sites and adjustable electronic band structures. While notable progress has been made in developing COF photocatalysts for the OER and overall artificial photosynthesis, these advances remain scattered across the literature and existing reviews, and a dedicated, systematic overview of the OER and its central role in integrated artificial photosynthetic processes is still lacking. This Review systematically summarizes recent advances in COF-based photocatalysts for the OER half-reaction and overall artificial photosynthesis. Our aim is to offer a comprehensive roadmap that establishes fundamental design principles for next-generation COF-based photocatalysts toward efficient and sustainable artificial photosynthesis.
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