Abstract
The excessive concentration of anthropogenic CO2 continuously harms the atmosphere. Consequently, deploying CO2 via the electrochemical reduction approach has become a highly sought-after research thrust area. In this study, a facile, one-pot solution combustion synthesis method (SCSM) was employed for the synthesis of various mixed-metal oxides supported on porous activated carbon (SnO2-CuO@AC). The prepared materials are characterized by analytical and spectroscopic techniques. Electrochemical studies were performed for the SnO2-CuO@AC catalyst to reduce CO2 into formic acid via an electrochemical approach. The in-depth properties of the designed catalysts were analysed by theoretical calculations using FT-IR and XRD data. The SnO2-CuO@AC exhibited improved electrochemical performance with a high current density of −10.77 mAcm−2, a low overpotential of −1.29 V, a lower Tafel slope value of 100 mV/dec. The faradaic efficiency for formic acid was 78.8 % at 1.3 V vs. RHE, with high stability for 9 h. The presence of coordinated active sites and oxygen vacancies, and a lower Tafel slope, also endorses CO2 adsorption and activation, faster electron transfer and boosts CO2 reduction. The significant reactivity toward CO2 reduction is attributed to the intensity of interaction between CO2∗- and the electrocatalyst, followed by kinetic activation toward protonation to obtain the desired product.
Published Version
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