Porous metal electrodes enable efficient electrolysis of carbon capture solutions

Bicarbonate electrolysers convert aqueous carbon capture solutions enriched with bicarbonate into carbon products ( e.g. , CO), and generate hydroxide for further reaction with waste CO 2 . These electrolysers link upstream carbon capture to electrochemical CO 2 utilization without high temperature...

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Bibliographic Details
Published in:Energy & environmental science 2022-02, Vol.15 (2), p.75-713
Main Authors: Zhang, Zishuai, Lees, Eric W, Habibzadeh, Faezeh, Salvatore, Danielle A, Ren, Shaoxuan, Simpson, Grace L, Wheeler, Danika G, Liu, Alyssa, Berlinguette, Curtis P
Format: Article
Language:English
Subjects:
Atmospheric pressure
Bicarbonates
Carbon dioxide
Carbon sequestration
Electrochemistry
Electrodes
Electrolysis
Heat resistance
High temperature
Impurities
Metals
Performance measurement
Pressure
Silver
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Summary:Bicarbonate electrolysers convert aqueous carbon capture solutions enriched with bicarbonate into carbon products ( e.g. , CO), and generate hydroxide for further reaction with waste CO 2 . These electrolysers link upstream carbon capture to electrochemical CO 2 utilization without high temperature or pressurization steps. We report here a bicarbonate electrolyser with a free-standing porous silver electrode rather than a composite carbon electrode widely used in electrolysers fed with gaseous CO 2 . This free-standing metal electrode is easier to fabricate than a composite carbon electrode, and the higher hydrophilicity helps to mediate efficient electrolysis of 3.0 M bicarbonate solutions into CO: faradaic efficiencies for CO production of 59% at 100 mA cm −2 at ambient pressure, and 95% at 100 mA cm −2 and 4 atmospheres of pressure. These performance metrics are comparable to those observed for gas-fed CO 2 electrolysers. The free-standing porous metal electrode is more closely aligned with electrodes used in commercial electrolysers, and is also more durable than composite carbon electrodes. The porous metal electrode is also more resistant to impurities common to carbon capture solutions. Bicarbonate electrolysers with free-standing porous metal electrodes can benefit carbon capture schemes where OH − solutions react with CO 2 to form bicarbonate-rich solutions. Bicarbonate electrolysers convert carbon capture solutions into chemicals and fuels and bypass the need for energy-intensive CO 2 recovery. Porous metal electrodes are more effective than composite carbon electrodes for this type of electrolyser.
ISSN:1754-5692
1754-5706
DOI:10.1039/d1ee02608a