Litcius/Paper detail

Atomically Precise Dinuclear Site Active toward Electrocatalytic CO<sub>2</sub> Reduction

Tao Ding, Xiaokang Liu, Zhinan Tao, Tianyang Liu, Tao Chen, Wei Zhang, Xinyi Shen, Dong Liu, Sicong Wang, Beibei Pang, Dan Wu, Linlin Cao, Lan Wang, Tong Liu, Yafei Li, Hongting Sheng, Manzhou Zhu, Tao Yao

2021Journal of the American Chemical Society275 citationsDOI

Abstract

The development of atomically precise dinuclear heterogeneous catalysts is promising to achieve efficient catalytic performance and is also helpful to the atomic-level understanding on the synergy mechanism under reaction conditions. Here, we report a Ni2(dppm)2Cl3 dinuclear-cluster-derived strategy to a uniform atomically precise Ni2 site, consisting of two Ni1–N4 moieties shared with two nitrogen atoms, anchored on a N-doped carbon. By using operando synchrotron X-ray absorption spectroscopy, we identify the dynamically catalytic dinuclear Ni2 structure under electrochemical CO2 reduction reaction, revealing an oxygen-bridge adsorption on the Ni2–N6 site to form an O–Ni2–N6 structure with enhanced Ni–Ni interaction. Theoretical simulations demonstrate that the key O–Ni2–N6 structure can significantly lower the energy barrier for CO2 activation. As a result, the dinuclear Ni2 catalyst exhibits >94% Faradaic efficiency for efficient carbon monoxide production. This work provides bottom-up target synthesis approaches and evidences the identity of dinuclear sites active toward catalytic reactions.

Topics & Concepts

ChemistryCatalysisCarbon monoxideActive siteFaraday efficiencyElectrochemistryAbsorption spectroscopyAbsorption (acoustics)AdsorptionCluster (spacecraft)CrystallographyPhotochemistryInorganic chemistryPhysical chemistryElectrodeOrganic chemistryProgramming languageAcousticsQuantum mechanicsPhysicsComputer scienceNanocluster Synthesis and ApplicationsCO2 Reduction Techniques and CatalystsCatalytic Processes in Materials Science