催化作用
单体
路易斯酸
共价键
材料科学
化学
纳米技术
组合化学
分子动力学
航程(航空)
合理设计
多相催化
催化效率
化学工程
反应条件
工作(物理)
计算化学
反应机理
金属有机骨架
有机合成
化学物理
化学反应工程
聚合物
作者
Mengshuai Liu,Hailong Zhang,Shangqing Chen,A M Zhang,兰东辉,Mingbo Wu
摘要
Abstract Heterogeneous catalytic conversion of CO 2 into high‐value 2‐oxazolidinones remains challenging due to intrinsically low activity, often necessitating corrosive superbases as co‐catalysts that compromise sustainability. Herein, we present a rational defect‐engineering strategy for constructing cyclic trinuclear Cu(I)‐based covalent organic frameworks (dCOF‐Cu 3 TG‐ x %Im), which feature integrated triple active sites and optimized mass transfer channels. By strategically introducing imidazole‐2‐carboxaldehyde as a truncated monomer during synthesis, missing‐linker defects are created to concurrently accommodate Lewis acidic Cu(I) centers and Lewis basic moieties (imidazole and –NH 2 groups), thereby eliminating the requirement for external superbases. The optimized dCOF‐Cu 3 TG‐10%Im catalyst exhibits exceptional activity, achieving 2‐oxazolidinone yields up to 92% for a wide range of propargylamine substrates under mild (80°C, 0.1 MPa CO 2 ) and superbase‐free conditions. The catalyst also demonstrates robust recyclability and prolonged stability. Insights into the synergistic catalytic mechanism are elucidated through combined theoretical calculations and molecular dynamics simulations, providing an important theoretical foundation for efficient CO 2 valorization.
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