化学
协同生产
介孔材料
光催化
催化作用
过氧化氢
氢
化学工程
共价键
纳米技术
共价有机骨架
光化学
吸附
组合化学
多相催化
亚胺
合理设计
精细化工
反应中间体
苄胺
量子化学
作者
Hao Zhang,X J Li,Yi Luo,Wu Hq,Yunfei Bu,Zhengping Fu,Ye Lu,Ali Han,Gang Liu,Wei Li,Feng Li,Dongyuan Zhao
摘要
Solar-driven hydrogen cycling, which enables efficient coproduction of fine chemicals, holds significant importance for advancing the sustainable development of modern society. Here, we demonstrate the highly efficient coproduction of N-benzylidenebenzylamine (N-BBA) and hydrogen peroxide (H 2 O 2 ) from benzylamine and air on well-designed benzotrithiophene-based mesoporous covalent organic frameworks (BTT-COFs). Linkers with an intertwined spatial distribution of the highest occupied molecular orbital (HOMO) and the lowest unoccupied molecular orbital (LUMO) were carefully explored for the construction of BTT-COFs. This design inherently establishes short-range charge transfer (SRCT) states, promoting localized cooperative activation for the proposed hydrogen cycling reactions. The optimized BTT-COF exhibited exceptional photocatalytic hydrogen cycling performance, with high N-BBA and H 2 O 2 yields of approximately 20.5 and 24.4 mmol g –1 h –1, respectively, accompanied by high apparent quantum efficiencies of 9.4 and 12.6% at 450 nm. Mechanism investigations revealed that the excellent hydrogen cycling performance originated from the synergistic combination of well-designed electronic microenvironment and optimal reactant/intermediate adsorption behaviors. This work highlights the BTT-COFs as efficient photocatalysts for fine chemical coproduction, providing a molecular-level design strategy for the exploration of advanced catalysts for various photocatalytic applications.
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