过氧化氢
共价有机骨架
共价键
苄胺
化学
苯甲醇
量子产额
光化学
产量(工程)
氟
吸收(声学)
材料科学
酒
分子内力
密度泛函理论
平面的
化学工程
多孔性
制氢
组合化学
甲烷氧化偶联
光电开关
激进的
可见光谱
功能群
偶联反应
石墨烯
氢
氢燃料
分解水
半导体
光催化
能量转换效率
过氧化物
作者
Tengteng Dong,Xiaohui Xu,Li Chen,Jiani Yang,Mingru Guo,Mi Zhou,Min Xu,Weichao Xue,Xiancheng Ren,Shuang Li,Chong Cheng
标识
DOI:10.1038/s41467-026-71137-0
摘要
Abstract Covalent organic frameworks with three-dimensional networks and interconnected porous structures show promising advantages for hydrogen peroxide photocatalysis. However, 3D COFs are typically constructed from 3D-oriented knots with less conjugation and insufficient light absorption, which significantly inhibits their performance. Herein, we present a universal defect engineering approach by systematically replacing T d knots with trigonal planar ligands and modifying linear linkers with electron-withdrawing/donating groups to achieve simultaneous enhancement of light absorption and precise electronic tuning of 3D donor-acceptor structures. Experimental results and theoretical analysis reveal that the optimized 3D COF with planar ligands induced defects and fluorine functional groups (COF-300-D-F), which achieve an H 2 O 2 production rate of 19.09 mmol g −1 h −1 and apparent quantum yield of 11.95% at 400 nm with benzyl alcohol as sacrificial agent. Moreover, the material maintains long-term stability during continuous operation exceeding 96 hours and exhibits high activity in photocatalytic benzylamine coupling reactions.
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