Abstract Molecular electrocatalysts for CO2‐to‐CO conversion often operate at large overpotentials, due to the large barrier for C−O bond cleavage. Illustrated with ruthenium polypyridyl catalysts, we herein propose a mechanistic route that involves one metal center that acts as both Lewis base and Lewis acid at different stages of the catalytic cycle, by density functional theory in corroboration with experimental FTIR. The nucleophilic character of the Ru center manifests itself in the initial attack on CO2 to form Ru‐CO20, while its electrophilic character allows for the formation of a 5‐membered metallacyclic intermediate, Ru‐CO2CO20,c, by addition of a second CO2 molecule and intramolecular cyclization. The calculated activation barrier for C−O bond cleavage via the metallacycle is decreased by 34.9 kcal mol−1 as compared to the non‐cyclic adduct in the two electron reduced state of complex 1. Such metallacyclic intermediates in electrocatalytic CO2 reduction offer a new design feature that can be implemented consciously in future catalyst designs.
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机译:摘要 CO2-CO转化分子电催化剂由于C−O键断裂势垒大,常在较大的过电位下工作。本文以聚吡啶钌催化剂为例,通过密度泛函理论与实验FTIR的佐证,提出了一种涉及一个金属中心的机理路线,该金属中心在催化循环的不同阶段同时充当路易斯碱和路易斯酸。Ru 中心的亲核特性表现为对 CO2 的初始攻击形成 [Ru-CO2]0,而其亲电特性允许通过添加第二个 CO2 分子和分子内环化形成 5 元金属环中间体 [Ru-CO2CO2]0,c。与配合物 1 的双电子还原态中的非环加合物相比,通过金属循环断裂的 C−O 键的计算活化势垒降低了 34.9 kcal mol−1。这种用于电催化CO2还原的金属环中间体提供了一种新的设计特征,可以在未来的催化剂设计中有意识地实现。
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