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Strain-optimized copper dual-atom sites for selective electroreduction of carbon dioxide to ethylene

Xuewei Huang, Xinwei Li, Shuhao Yan, Dawei Wang, Chang Long, Ying Yue, Pengfei An, Zhiyu Guo, Qun Li, Caoyu Yang, Sheng Chen, Jianyu Han, Lin Chang, Siyu Lu, Yin Zhang

2025Science Advances33 citationsDOIOpen Access PDF

Abstract

Electrocatalytic carbon dioxide (CO 2 ) reduction holds the great potential to convert excess emissions of carbon footprint into high value-added chemicals, but its activity, selectivity, stability, and reproducibility are still far away from satisfactory. The molecular catalysts with precise structures are unique platform to decipher the electrocatalytic mechanism, but they usually suffer from low performance. Herein, we report a strain-optimized dual copper complex immobilized in mesoporous carbon, which exhibits remarkable ethylene (C 2 H 4 ) Faradaic efficiency (FE) up to 49.9% along with a multicarbon (C 2+ ) product’s FE up to 65.2% at −1.19 volts versus reversible hydrogen electrode. Concurrently, the catalyst displays considerable stability for 15 hours at a full cell potential of −3.1 volts. The density functional theory calculation reveals that the strain effect imposed by mesoporous carbon regulates the neighboring dual copper sites in the electrocatalyst to decrease the energy barrier of rate-determining step (*COCO → *COCOH), thus significantly promoting ethylene production.

Topics & Concepts

ElectrocatalystCopperEthyleneCarbon dioxideFaraday efficiencyCatalysisElectrochemical reduction of carbon dioxideInorganic chemistryMesoporous materialChemistryCarbon fibersMaterials scienceChemical engineeringDensity functional theoryElectrodeReversible hydrogen electrodeHydrogenCO2 Reduction Techniques and CatalystsAdvanced battery technologies researchIonic liquids properties and applications