Journal
ACS APPLIED MATERIALS & INTERFACES
Volume 14, Issue 3, Pages 4155-4162Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acsami.1c21386
Keywords
carbon dioxide; reduction; electrocatalysis; ethanol; concentrated; hydrophobic; adlayer; porous
Funding
- Suncor Energy Ltd
- National Research Council
- University of Toronto Collaboration Centre Program in Green Energy Materials (CC-GEM) [GEM-PRJ-01]
- Ontario Research Fund Research-Excellence Program
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Electrochemical CO2 reduction can convert waste emissions into dense liquid fuels, but current methods result in low ethanol concentrations. This study presents a porous catalyst adlayer that reduces water transport and facilitates the evaporation of ethanol, leading to a recoverable stream of concentrated ethanol.
Electrochemical CO2 reduction can convert waste emissions into dense liquid fuels compatible with existing energy infrastructure. High-rate electrocatalytic conversion of CO2 to ethanol has been achieved in membrane electrode assembly (MEA) electrolyzers; however, ethanol produced at the cathode is transported, via electroosmotic drag and diffusion, to the anode, where it is diluted and may be oxidized. The ethanol concentrations that result on both the cathodic and anodic sides are too low to justify the energetic and financial cost of downstream separation. Here, we present a porous catalyst adlayer that facilitates the evaporation of ethanol into the cathode gas stream and reduces the water transport, leading to a recoverable stream of concentrated ethanol. The adlayer is comprised of ethylcellulose-bonded carbon nanoparticles and forms a porous, electrically conductive network on the surface of the copper catalyst that slows the transport of water to the gas channel. We achieve the direct production of an ethanol stream of 12.4 wt %, competitive with the concentration of current industrial ethanol production processes.
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