Electroreduction of CO 2 in Ionic Liquid-Aqueous Mixtures on Cu Catalysts

Electrochemical reduction of CO 2 (CO2ER) has attracted increasing attention due to its potential to mitigate the CO 2 level in the atmosphere as well as generating valuable chemicals and fuels. Among many catalysts used for CO 2 reduction, Cu is the only metal catalyst able to produce hydrocarbons and oxygenates. However, CO 2 reduction on Cu in aqueous electrolytes suffers from poor selectivity. Recently, ionic liquids (ILs) have been reported to enhance the product selectivity. ILs can stabilize the intermediates on the surface and enhance CO 2 reduction. Many factors such as basicity, hydrophilicity, size, and CO 2 absorption capacity of the ILs affect their performance in the electrochemical systems. In this work, a range of ILs were used to study the effect of anion in diluted IL/buffer mixtures on product selectivity and activity in CO2ER over Cu. Electrolysis experiments were performed on the Cu electrodes in a mixture of 0.1 M KHCO 3 and 10 mM of an IL. ILs with same cation (1-butyl-3-methylimidazolium ([BMIM] + )) and different anions (bis(trifluoromethylsulfonyl)imide ([NTF 2 ] - ), triflate ([OTF] - ), dicyanamide ([DCA] - ), acetate ([Ac] - ), and chloride ([Cl] - )) were used for this study. A positive shift for the onset potential in cyclic voltammetry (CVs) was observed after addingILs (except for [BMIM][DCA]) to the buffer electrolyte. Moreover, alower charge transfer resistance for all ILs (except for [BMIM][DCA])compared to IL-free electrolyte at -0.92 V was observed in electrochemical impedance spectroscopy (EIS). The presence of ILs in the electrolyte also influenced the product selectivity. Faradaic efficiency (FE%) toward formate for all ILs increased (except for [BMIM][DCA]) compared to IL-free electrolyte. [BMIM][NTF 2 ] showed the maximum FE% for formate (39%) at -0.92 V probably due to its high CO 2 absorption capacity and high hydrophobicity which could attract more CO 2 molecules to the surface. The results also showed that adding ILs decreased the FE% toward the C 2 products compared to IL-free electrolyte. This observation can be attributed to the presence of adsorbed [BMIM] + cations on the surface which prevent CO 2 molecules approach to each other and do dimerization. [BMIM][Ac] had the maximum FE% for CO (a 211% increase in FE CO % compared to IL-free electrolyte at -1.02V) and C 2 products (a 27% increase in FE C2 % compared to IL-free electrolyte at -1.12V) compared to other ILs studied. [BMIM][Ac] has been reported to