Continuous CO2 electrolysis using a CO2 exsolution-induced flow cell
Guobin Wen,
Bohua Ren,
Xin Wang (),
Dan Luo,
Haozhen Dou,
Yun Zheng,
Rui Gao,
Jeff Gostick,
Aiping Yu () and
Zhongwei Chen ()
Additional contact information
Guobin Wen: University of Waterloo
Bohua Ren: University of Waterloo
Xin Wang: South China Normal University
Dan Luo: University of Waterloo
Haozhen Dou: University of Waterloo
Yun Zheng: University of Waterloo
Rui Gao: University of Waterloo
Jeff Gostick: University of Waterloo
Aiping Yu: University of Waterloo
Zhongwei Chen: University of Waterloo
Nature Energy, 2022, vol. 7, issue 10, 978-988
Abstract:
Abstract CO2 electrolysis promises a route to carbon-based chemicals and fuels using renewable energy and resources. However, industrial application is limited by the transfer of CO2, electrons, protons and products (CEPP) at high current densities. Here we present an electrolyser that uses the forced convection of an aqueous CO2-saturated catholyte throughout a porous electrode and exploits the in situ formation of CO2(g)–liquid–catalyst interfaces to improve the CEPP transfer and reach high current densities. The CO2 supply is expedited by an increased exsolution of gaseous CO2 from dissolved CO2 and bicarbonate due to the effect of local pressure decreases; simultaneous CEPP transfer is promoted with a tenfold decrease in the diffusion layer thickness. This system also enables catalyst synthesis by in situ electrodeposition and ligand modification. We achieved a maximum current density of 3.37 A cm–2 with a Ag-based catalyst, and assemble a scaled-up 4 × 100 cm2 electrolyser stack that produces CO at a rate of 90.6 l h–1.
Date: 2022
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DOI: 10.1038/s41560-022-01130-6
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