Electrolyte Effects on the Faradaic Efficiency of CO 2 Reduction to CO on a Gold Electrode

The electrochemical reduction of CO 2 aims to be a central technology to store excess electricity generated by wind and solar energy. However, the reaction is hindered by the competition with the hydrogen evolution reaction. In this paper, we present a detailed quantitative study of the Faradaic eff...

Full description

Bibliographic Details
Main Authors: Giulia Marcandalli (4560070), Akansha Goyal (8469546), Marc T. M. Koper (7288163)
Format: Other Non-Article Part of Journal/Newspaper
Language:unknown
Published: 2021
Subjects:
Biochemistry
Evolutionary Biology
Ecology
Space Science
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
electrolyte composition
rotation rates
gold electrode
electrolyte effects
electrolyte cation
FE
carbonic acid
CO 2 Reduction
hydrogen evolution reaction
mass-transport conditions
Faradaic Efficiency
hydrogen evolution
bicarbonate concentrations
optimized electrolyte conditions
CO 2
proton donor
mass transport
electrochemical reduction
ring-disk electrode voltammetry
Carbonic acid
Online Access:https://doi.org/10.1021/acscatal.1c00272.s001
Description
Summary:The electrochemical reduction of CO 2 aims to be a central technology to store excess electricity generated by wind and solar energy. However, the reaction is hindered by the competition with the hydrogen evolution reaction. In this paper, we present a detailed quantitative study of the Faradaic efficiency (FE) to CO on a gold electrode under well-defined mass-transport conditions using rotating ring-disk electrode voltammetry. Varying the concentration of the bicarbonate and the electrolyte cation employing different rotation rates, we map out how these parameters affect the FE­(CO). We identify two different potential regimes for the electrolyte effects, characterized by a different dependence on the cation and bicarbonate concentrations. For hydrogen evolution, we analyze the nature of the proton donor for an increasingly negative potential, showing how it changes from carbonic acid to bicarbonate and to water. Our study gives detailed insights into the role of electrolyte composition and mass transport, and helps defining optimized electrolyte conditions for a high FE­(CO).

Similar Items