Title: Promoting Water Activation via Molecular Engineering Enables Efficient Asymmetric C–C Coupling during CO2 Electroreduction
Authors: Zi-Yu Du, Si-Bo Li, Ge-Hao Liang, Yi-Meng Xie, Yao-Lin A, Yi Zhang, Hua Zhang*, Jing-Hua Tian, Shisheng Zheng*, Qing-Na Zheng, Zhou Chen*, Weng Fai Ip, Jinxuan Liu* and Jian-Feng Li*
Abstract: Water activation plays a crucial role in CO2 reduction, but improving the electrocatalytic performance through controlled water activation presents a significant challenge. Herein, we achieved electrochemical CO2 reduction to ethene and ethanol with high selectivity by promoting water dissociation and asymmetric C–C coupling by engineering Cu surfaces with N–H-rich molecules. Direct spectroscopic evidence, coupled with density functional theory calculations, demonstrates that the N–H-rich molecules accelerate interfacial water dissociation via hydrogen-bond interactions, and the generated hydrogen species facilitate the conversion of *CO to *CHO. This enables the efficient asymmetric *CHO–*CO coupling to C2 products with a faradaic efficiency (FE) ∼ 30% higher than that of the unmodified catalyst. Moreover, by adjustment of the relative *CHO/*CO coverage via Cu surface facet regulation, the selectivity can be entirely switched between C2 products and CH4. These mechanistic insights further guided the development of a more efficient catalyst by directly modifying Cu2O nanocubes with the N–H-rich molecule, achieving remarkable C2 product (mainly ethene and ethanol) FEs of 85.7% at a current density of 800 mA cm–2 and excellent stability under nearing industrial conditions. This study advances our understanding of the CO2 reduction mechanisms and offers an effective and general strategy for enhancing electrocatalytic performance by accelerating water dissociation.
Full-Link: https://pubs.acs.org/doi/10.1021/jacs.4c14299