Abstract
Surface ligands play an important role in dictating the structure and catalytic properties of metal nanoclusters. Recently, a novel class of Au clusters protected by N-heterocyclic carbenes (NHCs) and halogens has been synthesized; however, the dynamic stability of the Au-NHCs/Au-halogen interface in real electrochemical environments as well as the influence of the ligand layer on the catalytic process remains obscure. Herein, we combined first-principles simulations with experiments to investigate the metal-ligand interface interaction of the classical [Au(13)(NHC(Me))(9)Cl(3)](2+) cluster and its unique potential to promote electrocatalytic CO(2) reduction to syngas. Our simulations revealed the facile shedding of chlorine ligands from the surface of the Au(13) core upon electrochemical biasing, and the more negative the applied potential, the faster the kinetics of the Au-Cl bond cleavage. By contrast, the Au-NHC interface is highly stable, indicating the greater stability of Au-C bonds over the Au-Cl bonds under electrochemical conditions. Interestingly, the exposed icosahedral Au in dechlorinated [Au(13)(NHC(Me))(9)Cl(2)](3+) cluster is capable of efficiently catalyzing electrochemical CO(2) reduction to generate CO and H(2) with comparable barriers in a wide potential range, showcasing its strong potential for syngas formation. Our predictions are further corroborated by experimental electrochemical data, where X-ray photoelectron spectroscopy (XPS) verified halogen stripping under acid or neutral media, and the activated Au(13) cluster demonstrated enhanced catalytic efficacy for syngas formation with a CO : H(2) ratio of approximately 0.8 to 1.2 across a broad potential range of -0.50 to -1.20 V. This work reveals an exciting frontier in the understanding of ligand etching dynamics in NHC-protected metal nanoclusters, and particularly, the catalytic preference for syngas production is revealed for the first time in gold-based nanoclusters, which is distinctive from previously reported Au nanoclusters that mainly produce CO.