Photocatalytic conversion of carbon dioxide to value-added chemicals, particularly multi-carbon products, offers a promising route toward carbon-neutral cycles. However, achieving high activity and selectivity remains extremely challenging due to the instability of key reaction intermediates and limited C-C coupling efficiency. Herein, we report a low-coordination manganese single-atom catalyst embedded in zinc sulfide (Mn1-ZnSv) that enables efficient and selective CO2-to-C2+ conversion. In-situ spectroscopic analyses and density functional theory calculations reveal that sulfur vacancies are created at the Mn single-atom coordination sites and induce the formation of coordination-unsaturated Mn-S2 configuration. The asymmetric coordination environment of Mn modulates local charge distribution, strengthens *CO adsorption, and promotes *CO and *CHO coupling to form the *COCHO intermediate for efficient C-C coupling. As a result, the Mn1-ZnSv catalyst achieved 99.1% selectivity for ethylene with a formation rate of 76.6 μmol g-1 h-1. This study highlights the critical role of atomic-level coordination engineering in advancing photocatalytic CO2-to-C2+ conversion.
Tang et al. (Tue,) studied this question.