Fully Conjugated Sp <sup>2</sup> Carbon‐Linked Covalent Organic Frameworks Enables Accelerated Exciton Process for Superior Singlet Oxygen Photosynthesis for Water Remediation
Siyuan Guo, Kun Zhao, Luwen Liang, Zifan Li, Bin Han, Xinwen Ou, Shan Yao, Zhiqing Lin, Zhimin Dong, Yunhai Liu, Liqun Ye, Bo Weng, Yanpeng Cai, Zhifeng Yang
Abstract
Abstract Photocatalytic oxygen (O 2 ) activation via energy transfer offers a sustainable approach for singlet oxygen ( 1 O 2 ) synthesis, while its performance suffers from the ultrafast exciton dissociation and sluggish intersystem crossing (ISC) process. Up to date, exciton regulation is still in its infancy. Here, via linkage engineering of covalent organic frameworks (COFs), we propose a fully conjugated sp 2 carbon‐linked COFs (sp 2 c‐Py‐Bpy COFs) with strong exciton interaction and fast ISC for boosted 1 O 2 photosynthesis. The sp 2 c‐Py‐Bpy COFs delivers a record‐high 1 O 2 yield (624 µM min −1 ) with 100% selectivity, which is ca. eight times that of the traditional imine‐bridged COFs (Im‐Py‐Bpy COFs, ca. 95.8% selectivity), outperforming documented systems. Transient absorption spectroscopy and theoretical investigations demonstrate that the fully conjugated sp 2 carbon linkage of sp 2 c‐Py‐Bpy COFs can enhance Coulomb interaction, promote ISC and push forward the transfer of triplet exciton to the O 2 adsorption sites throughout the COFs matrix, jointly facilitating the energy transfer process for efficient 1 O 2 photosynthesis and bypassing the traditional electron transfer process. Hence, sp 2 c‐Py‐Bpy COFs can selectively degrade acetaminophen within minutes under visible light irradiation and enables stable degradation of emerging pollutants in a continuous flow membrane reactor (20 × 30 × 2 cm) utilizing natural sunlight and dissolved O 2 .