Ag-Cu aerogel for electrochemical CO2 conversion to CO

The current strategy of electrocatalytic CO2 reduction reaction (eCO(2)RR) to generate useful chemicals and hydrocarbons is supposed to effectively mitigate the greenhouse effect. The practical application for eCO(2)RR in aqueous solutions, however, still was encumbered by its high overpotential, low activity and poor selectivity due to CO2 mass transfer and intermediate stability. Electrocatalytic materials with reduced overpotential and high efficiency and selectivity are exploited for further development. Herein, Ag+ and Cu2+ precursors were co-reduced to generate Ag-Cu bimetallic aerogel after further freeze drying. Compared with Ag100 aerogel, the optimal Ag88Cu12 can effectively decrease overpotential, improve selectivity and current density, and keep electrochemical stability. At -0.89 V vs. RHE, the Faraday efficiency reached 89.40% and the CO partial current density of -5.86 mA cm(-2) was obtained. The intrinsic property of metal aerogel (hydrophobic, hierarchical porous structure, conductivity), presence of rich grain boundaries and geometric effect and the introduction of Cu leading to improvement of adsorption between the catalyst and the *COOH intermediate in Ag88Cu12, contribute to the enhanced performance. Furthermore, the strategy of constructing metal aerogel will improve metal catalyst performance towards eCO(2)RR and pave way for further industrial applications. (C) 2021 Elsevier Inc. All rights reserved.

Automated summary

In this study, Ag-Cu bimetallic aerogels were prepared by co-reducing Ag+ and Cu2+ precursors, with the optimal Ag88Cu12 composition showing enhanced efficiency, selectivity, and stability for CO2 reduction reaction. The introduction of Cu and the unique properties of the metal aerogel contribute to the improved performance of the catalyst.