共价键
催化作用
材料科学
之字形的
聚合物
溶剂
氢键
纳米技术
吡啶
光催化
化学
四硫富瓦烯
光化学
氧化还原
吸收(声学)
过氧化氢
化学工程
组合化学
涂层
结构母题
单体
结晶学
吸收光谱法
作者
Lei Zhang,Xin Wang,Xiao‐Xin Li,Xiang Wang,Zihao Chen,Jinglun Yang,Qianfeng Gu,Dong‐Sheng LI,Chun‐Sing Lee,Ya‐Qian Lan,Qichun Zhang
摘要
ABSTRACT Recently, growing single crystals of covalent organic polymers (COPs) through dative B←N bonds has been proven to be a promising strategy. Despite these developments, constructing diverse COP structures using identical structural motifs to investigate the variations in their performance remains a significant but challenging task. In this paper, we introduce a strategy aimed at reducing the symmetry of structural units to achieve this target. By employing the 3‐pyridyl‐based tetrathiafulvalene motif (labeled as TTF‐(3‐py) 4 ), a series of single‐crystal COP structures sharing the same motifs, including one‐dimensional (1D) zigzag chains ( CityU‐61 ), 1D nanobelt ( CityU‐62 ), and 2D layer ( CityU‐63 ) structures, are constructed under different solvent conditions. The rotatability of the carbon‐carbon single bond, coupled with the deviation of nitrogen in pyridine from the symmetry axis, endows TTF‐(3‐py) 4 with a diverse range of configurations. These COP compounds exhibit excellent light absorption properties and redox activities, facilitating efficient photocatalytic synthesis of hydrogen peroxide (H 2 O 2 ) from water and air. Notably, CityU‐63 exhibits the highest catalytic activity, with an H 2 O 2 production rate of 10 488.9 µmol g −1 h −1 , positioning it among the most effective photocatalysts currently employed for H 2 O 2 photosynthesis.
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