Electronic Trap State Engineered Covalent Organic Frameworks for Programmable Selectivity of Photocatalytic Molecular Oxygen Activation

化学 存水弯(水管) 共价键 选择性 光催化 分子氧 工作(物理) 光化学 纳米技术 氧气 化学工程 国家(计算机科学) 组合化学 能量(信号处理) 能量转换 电子结构 共价有机骨架 分子开关 可见光谱
作者
Jikuan Qiu,Baihua Liang,Hanping Zhai,Yuling Zhao,Yucheng Jin,Zhiyong Li,Zhiyong Li,Huiyong Wang,Zhongping Li,Zhongping Li,Jong-Beom Baek,Yi-Xiang Wang
出处
期刊:Journal of the American Chemical Society [American Chemical Society]
卷期号:148 (19): 20262-20274
标识
DOI:10.1021/jacs.6c06033
摘要

Covalent organic frameworks (COFs) with ordered π skeletons and aligned nanopores could be ideal photocatalytic materials for molecular oxygen activation. Achieving selective generation of specific reactive oxygen species (ROS), such as superoxide radicals (O 2 •– ) and singlet oxygen ( 1 O 2 ), has remained a challenge in precision photocatalysis. Herein, we report an electronic trap engineering strategy to control ROS selectivity in COFs. It was found that perturbation of the density of carbonyl groups and the partial linkage tautomerization can systematically tune the energy depth of electron traps. Based on this finding, a series of topologically analogous COFs have been designed and synthesized. Among these COFs, COF–HNU60, featuring shallow traps, facilitates stepwise charge separation that enables a sequential redox process to 1 O 2 . By contrast, the deep traps in COF–HNU70 and COF–HNU80 stabilize photogenerated electrons and promote selective accumulation of O 2 •– ̅ by halting further oxidation. A series of advanced photocatalytic oxidation reactions highlight distinct ROS pathways correlated with trap energy level. Mechanistic studies reveal that the energy depth of electron traps mainly dictates charge separation kinetics and carrier lifetime, thereby governing the selective evolution of O 2 •– ̅ and 1 O 2 . This work provides a new design principle for COF-based photocatalysts by highlighting the role of trap energy levels in tuning ROS selectivity.
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