Interfacial Electronic Structures and the Fischer–Tropsch Synthesis Path by Electrochemical CO₂/CO Reduction for Ternary CuNiZn Alloys

Abstract: Metal alloy electrocatalysts are commonly used in electrochemical (EC) CO 2 reduction. In this study, we demonstrate the application of a ternary CuNiZn alloy as an electrocatalyst for both CO 2 and CO reductions. Our results show that formate, CO, CH 4 , and C 2−7 hydrocarbons were produced through the process of initial CO 2 adsorption followed by subsequent stepwise reactions. Interestingly, we also observed the production of CH 4 and C 2−7 hydrocarbons (C n H 2n+2 and C n H 2n ) through EC CO reduction, wh… Show more

“…The reductions in Zn and Ni were most pronounced, with Zn reduced more than 10 times in amount. This suggests that the EC CO 2 reduction process could be influenced by the altered elemental ratios …”

CuNiZn vs CuZn Electrodes: Electrochemical CO₂ Reduction, Role of Metal Elements, and Insights for C–C Coupling Chemistry

“…The reductions in Zn and Ni were most pronounced, with Zn reduced more than 10 times in amount. This suggests that the EC CO 2 reduction process could be influenced by the altered elemental ratios …”

CuNiZn vs CuZn Electrodes: Electrochemical CO₂ Reduction, Role of Metal Elements, and Insights for C–C Coupling Chemistry

“…H 2 production, a well-known path initiated from H + + e – → H*, is a common dominant route. The two-electron process for CO involves the reactions CO 2 + H + + e – → *COOH, followed by *COOH + H + + e – → *CO + H 2 O. − ,,, Similarly, the two-electron process for formate is known to occur through CO 2 + H + + e – → OCHO* and OCHO* + e – → HCOO – . − , The adsorption of two intermediate species, *COOH and *CHO*, determines the final products and is highly dependent on the nature of the developed electrodes and the experimental conditions. The initiation of C 1 products, CH 4 , and methanol appears to involve the hydrogenation of surface *CO, following reactions such as *CO + H + + e – → *CHO or *COH.…”

“…Metallic Sb appeared after sputtering for the electrode after EC (Figure 9f2). This indicates that the overlaid species were metallic Sb covered by Sb 2 O 3 .The VB profiles became broader after EC tests (Figure 9e3 [39][40][41][42][43]45,55,56 Similarly, the two-electron process for formate is known to occur through CO 2 + H + + e − → OCHO* and OCHO* + e − → HCOO − . [35][36][37][38]47 The adsorption of two intermediate species, *COOH and *CHO*, determines the final products and is highly dependent on the nature of the developed electrodes and the experimental conditions.…”

“…In the 0.5 M condition, the FEs of liquid products were significantly diminished, in good consistency with the literature. 45,47 The C 2 H 6 FE was highest in the 0.05 M condition but lower in higher concentrations (Figure 5b2). On the other hand, the C 3 H 6 FE was highest in the 0.2 M condition, similar to the C 2 H 4 FE.…”

“…Electrodes incorporating three different metals have been increasingly explored to enhance CO 2 reduction efficiency further and explore new dominant reaction pathways. − The utilization of the three metals offers increased opportunities to customize favorable adsorption sites and augment active sites for EC CO 2 reduction. This intricate interplay between multiple metals not only enhances the catalytic efficiency but also introduces a rich diversity of reaction pathways, contributing to the intricate landscape of CO 2 electroreduction.…”

Ag–Sb/Cu by Galvanic Replacement: Electrochemical CO₂ Reduction and Unveiling C₃₊ Hydrocarbon Pathways

Carbon Catalysts Empowering Sustainable Chemical Synthesis via Electrochemical CO₂ Conversion and Two‐Electron Oxygen Reduction Reaction