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Direct low concentration CO2 electroreduction to multicarbon products via rate-determining step tuning

Liangyiqun Xie, Yanming Cai, Yujing Jiang, Meikun Shen, Jason Chun‐Ho Lam, Jun‐Jie Zhu, Wenlei Zhu

2024Nature Communications75 citationsDOIOpen Access PDF

Abstract

Direct converting low concentration CO2 in industrial exhaust gases to high-value multi-carbon products via renewable-energy-powered electrochemical catalysis provides a sustainable strategy for CO2 utilization with minimized CO2 separation and purification capital and energy cost. Nonetheless, the electrocatalytic conversion of dilute CO2 into value-added chemicals (C2+ products, e.g., ethylene) is frequently impeded by low CO2 conversion rate and weak carbon intermediates’ surface adsorption strength. Here, we fabricate a range of Cu catalysts comprising fine-tuned Cu(111)/Cu2O(111) interface boundary density crystal structures aimed at optimizing rate-determining step and decreasing the thermodynamic barriers of intermediates’ adsorption. Utilizing interface boundary engineering, we attain a Faradaic efficiency of (51.9 ± 2.8) % and a partial current density of (34.5 ± 6.4) mA·cm−2 for C2+ products at a dilute CO2 feed condition (5% CO2 v/v), comparing to the state-of-art low concentration CO2 electrolysis. In contrast to the prevailing belief that the CO2 activation step ( $${{CO}}_{2}+{e}^{-}+\, * \,\to {}^{ * }{CO}_{2}^{-}$$ ) governs the reaction rate, we discover that, under dilute CO2 feed conditions, the rate-determining step shifts to the generation of *COOH ( $${}^{ * } {{CO}}_{2}^{-}+{H}_{2}O\to {}^{ * } {COOH}+{{OH}}^{-}({aq})$$ ) at the Cu0/Cu1+ interface boundary, resulting in a better C2+ production performance. The development of catalysts that operate under low concentration CO2 resembling industrial waste gases holds promise for CO2 reduction. Here, the authors report a vacuum calcination approach for regulating the Cu0/Cu1+ density on Cu-based catalysts that can electro-catalyze low-concentration CO2.

Topics & Concepts

CatalysisFaraday efficiencyAdsorptionCalcinationElectrochemistryChemical engineeringElectrolysisMaterials scienceChemistryInorganic chemistryPhysical chemistryOrganic chemistryElectrodeEngineeringElectrolyteCO2 Reduction Techniques and CatalystsIonic liquids properties and applicationsAdvanced battery technologies research