Highly Selective Two‐Electron Electrocatalytic CO<sub>2</sub> Reduction on Single‐Atom Cu Catalysts
Chaochen Xu, Xing Zhi, Anthony Vasileff, Dan Wang, Bo Jin, Yan Jiao, Yao Zheng, Shi‐Zhang Qiao
Abstract
Cu‐based electrocatalysts with high catalytic selectivity for the CO 2 reduction reaction present a significant technological challenge. Herein, a catalyst comprised of Cu single atoms in a nitrogen‐doped graphene matrix (Cu–N 4 –NG) is developed for highly selective electrocatalytic reduction of CO 2 to CO. The single‐atom structure and coordination environment of Cu–N 4 –NG are identified by synchrotron‐based characterization. Compared to a conventional bulk Cu catalyst, Cu–N 4 –NG achieves a Faradaic efficiency of 80.6% toward CO under a moderate applied potential of −1.0 V versus reversible hydrogen electrode (RHE). Kinetic experiments show that 1) the Cu–N 4 moiety favors the CO 2 activation step and 2) the moiety‐anchoring graphene facilitates water dissociation, which supplies protons for CO 2 reduction. Moreover, density functional theory (DFT) calculations reveal that CO 2 reduction is less hindered thermodynamically on Cu–N 4 –NG compared to the competing hydrogen evolution reaction (HER) due to their limiting potential differences. Therefore, the highest CO selectivity is observed on Cu–N 4 –NG over the bulk Cu catalyst due to more favorable kinetics and thermodynamics.