Zhao Peng, Jiang Hao, Shen Haidong, Yang Shaowei, Gao Runze, Guo Ying, Zhang Qiuyu, Zhang Hepeng
Xi'an Key Laboratory of Functional Organic Porous Materials, School of Chemistry and Chemical Engineering, Northwestern Polytechnical University, Xi'an, 710129, P. R. China.
Research & Development Institute of, Northwestern Polytechnical University in Shenzhen, Shenzhen, 518057, P. R. China.
Angew Chem Int Ed Engl. 2023 Dec 4;62(49):e202314121. doi: 10.1002/anie.202314121. Epub 2023 Nov 7.
Constructing Cu single-atoms (SAs) catalysts is considered as one of the most effective strategies to enhance the performance of electrochemical reduction of CO (e-CO RR) towards CH , however there are challenges with activity, selectivity, and a cumbersome fabrication process. Herein, by virtue of the meta-position structure of alkynyl in 1,3,5-triethynylbenzene and the interaction between Cu and -C≡C-, a Cu SAs electrocatalyst (Cu-SAs/HGDY), containing low-coordination Cu-C active sites, was synthesized through a simple and efficient one-step method. Notably, this represents the first achievement of preparing Cu SAs catalysts with Cu-C coordination structure, which exhibited high CO -to-CH selectivity (72.1 %) with a high CH partial current density of 230.7 mA cm , and a turnover frequency as high as 2756 h , dramatically outperforming currently reported catalysts. Comprehensive experiments and calculations verified the low-coordination Cu-C structure not only endowed the Cu SAs center more positive electricity but also promoted the formation of H•, which contributed to the outstanding e-CO RR to CH electrocatalytic performance of Cu-SAs/HGDY. Our work provides a novel H⋅-transferring mechanism for e-CO RR to CH and offers a protocol for the preparation of two-coordinated Cu SAs catalysts.
构建铜单原子(SAs)催化剂被认为是提高电化学还原CO(e-CO RR)生成CH性能的最有效策略之一,然而在活性、选择性和繁琐的制备过程方面存在挑战。在此,借助1,3,5-三乙炔基苯中炔基的间位结构以及Cu与-C≡C-之间的相互作用,通过一种简单高效的一步法合成了一种含有低配位Cu-C活性位点的Cu SAs电催化剂(Cu-SAs/HGDY)。值得注意的是,这是首次制备出具有Cu-C配位结构的Cu SAs催化剂,其表现出72.1%的高CO-to-CH选择性,CH分电流密度高达230.7 mA cm ,周转频率高达2756 h ,显著优于目前报道的催化剂。综合实验和计算表明,低配位Cu-C结构不仅使Cu SAs中心带更多正电,还促进了H•的形成,这有助于Cu-SAs/HGDY在e-CO RR生成CH方面具有出色的电催化性能。我们的工作为e-CO RR生成CH提供了一种新的H⋅转移机制,并为制备双配位Cu SAs催化剂提供了一种方案。
