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Continuous electroproduction of formate via CO2 reduction on local symmetry-broken single-atom catalysts

Juncai Dong, Yangyang Liu, Jiajing Pei, Haijing Li, Shufang Ji, Lei Shi, Yaning Zhang, Can Li, Cheng Tang, Jiangwen Liao, Shiqing Xu, Huabin Zhang, Qi Li, Shenlong Zhao

2023Nature Communications220 citationsDOIOpen Access PDF

Abstract

Abstract Atomic-level coordination engineering is an efficient strategy for tuning the catalytic performance of single-atom catalysts (SACs). However, their rational design has so far been plagued by the lack of a universal correlation between the coordination symmetry and catalytic properties. Herein, we synthesised planar-symmetry-broken CuN 3 (PSB-CuN 3 ) SACs through microwave heating for electrocatalytic CO 2 reduction. Remarkably, the as-prepared catalysts exhibited a selectivity of 94.3% towards formate at −0.73 V vs. RHE, surpassing the symmetrical CuN 4 catalyst (72.4% at −0.93 V vs. RHE). In a flow cell equipped with a PSB-CuN 3 electrode, over 90% formate selectivity was maintained at an average current density of 94.4 mA cm −2 during 100 h operation. By combining definitive structural identification with operando X-ray spectroscopy and theoretical calculations, we revealed that the intrinsic local symmetry breaking from planar D 4 h configuration induces an unconventional dsp hybridisation, and thus a strong correlation between the catalytic activity and microenvironment of metal centre (i.e., coordination number and distortion), with high preference for formate production in CuN 3 moiety. The finding opens an avenue for designing efficient SACs with specific local symmetries for selective electrocatalysis.

Topics & Concepts

CatalysisSelectivityFormateMoietyElectrocatalystChemistryCombinatorial chemistryMaterials scienceCrystallographyTopology (electrical circuits)NanotechnologyStereochemistryElectrodePhysical chemistryOrganic chemistryElectrochemistryMathematicsCombinatoricsCO2 Reduction Techniques and CatalystsElectrocatalysts for Energy ConversionCatalytic Processes in Materials Science
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