化学
单层
共价键
产量(工程)
立体选择性
密度泛函理论
亚稳态
偶联反应
分子内力
扫描隧道显微镜
化学物理
计算化学
聚合物
有机合成
溴化物
热的
动力控制
工作(物理)
联轴节(管道)
多孔介质
多孔性
量子隧道
化学工程
纳米技术
光化学
分子
组合化学
沉积(地质)
聚合
作者
Minjie Xu,Xiushan Zhang,Yuwen Liu,Fengchao Cui,Shuying Li,Guangshan Zhu
摘要
Surface-confined precision synthesis of 2D covalent organic frameworks (COFs) represents a crucial bridge connecting molecular design with macroscopic material properties. In this work, we achieve the first surface-confined synthesis of monolayer COF via Wurtz coupling, demonstrating prominent stereoselectivity through temperature modulation. At reduced temperature (78 K), the reaction preferentially follows a trans-coupling pathway, enabling the successful synthesis of metastable COF that maintains structural integrity during thermal treatment due to surface confinement. Conversely, deposition at elevated temperature (298 K) promotes thermodynamically stable cis-coupling porous nanoribbons. Combined ultrahigh-vacuum scanning tunneling microscopy (UHV-STM) and density functional theory (DFT) calculations elucidate the fundamental thermodynamic-kinetic competition mechanism governing the C-C coupling reactions at the molecular level: while the trans-coupling pathway benefits from a lower activation barrier, the cis-coupling configuration represents the thermodynamic minimum. Notably, this synthetic approach demonstrates pronounced generality, as confirmed by its successful implementation with another triphenylbenzyl bromide precursor to yield monolayer COF. This work deepens the understanding of irreversible bond formation in on-surface synthesis and establishes kinetic trapping as a powerful strategy for achieving precise stereoselective control in Wurtz coupling.
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