乙炔
催化作用
选择性
乙烯
钴
法拉第效率
酞菁
离解(化学)
材料科学
氢
可逆氢电极
吸附
化学
无机化学
金属
电催化剂
化学工程
光化学
选择性吸附
制氢
金属有机骨架
电极
聚苯乙烯
组合化学
作者
Fengliang Cao,Wenting Feng,Debin Kong,Xiao Hai,Qingshan Zhao,Mingbo Wu,Song Xue,LinJie ZHI
标识
DOI:10.1038/s41467-026-71339-6
摘要
Electrocatalytic acetylene semi-hydrogenation is an attractive route for ethylene production, but competing side reactions like hydrogen evolution, over-hydrogenation, and C-C coupling severely compromise its industrial viability. Here, we present a carbon-nanotube-supported metal phthalocyanine platform, MPc/XCNT (M = Cu, Co, Ni, Fe; X = O, N, S), to investigate the roles of metal centers and local coordination environments. Among these catalysts, CoPc-based structures exhibit markedly enhanced water dissociation kinetics and elevated C-C coupling energy barriers compared to conventional CuPc-based catalysts, thereby effectively suppressing undesired C4 by-products. Furthermore, molecular regulation of the Co center optimizes active hydrogen adsorption and utilization, mitigating both hydrogen evolution and over-hydrogenation. As a result, the optimized CoPc/NCNT catalyst delivers competitive performance under both high current densities and ethylene-rich conditions. At an industrially relevant -500 mA cm-2 under a pure ethylene feed, it achieves 86.7% Faradaic efficiency with a turnover frequency of 7019 min-1. Under simulated industrial crude conditions, it maintains 99.7% conversion and 99.5% selectivity during 110-hour continuous operation. This work provides a well-defined molecular strategy for advancing selective electrocatalytic transformations.
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