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High-Efficiency Conversion of CO2 to Oxalate in Water Is Possible Using a Cr-Ga Oxide Electrocatalyst

Author(s): Paris, Aubrey R; Bocarsly, Andrew B

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Abstract: Electrochemical transformation of CO2 into commodity chemicals such as oxalate is a strategy for profitably remediating high atmospheric CO2 levels. Electrocatalysts for oxalate generation, however, have required prohibitively large applied potentials, forcing the use of nonaqueous electrolytes. Here, a thin film comprised of alloyed Cr and Ga oxides on glassy carbon is shown to electrocatalytically generate oxalate from aqueous CO2 with high Faradaic efficiencies at 690 mV overpotential. Oxalate is produced at a surface anion site via a CO-dependent pathway; the process is highly sensitive to the hydrogen-bonding environment and avoids the commonly invoked CO2•– intermediate. Ultimately, this catalytic system accomplishes efficient CO2 to oxalate conversion in protic electrolyte.
Publication Date: 30-Jan-2019
Electronic Publication Date: 30-Jan-2019
Citation: Paris, Aubrey R, Bocarsly, Andrew B. (2019). High-Efficiency Conversion of CO2 to Oxalate in Water Is Possible Using a Cr-Ga Oxide Electrocatalyst. ACS Catalysis, 9 (3), 2324 - 2333. doi:10.1021/acscatal.8b04327
DOI: doi:10.1021/acscatal.8b04327
ISSN: 2155-5435
EISSN: 2155-5435
Pages: 2324 - 2333
Language: en
Type of Material: Journal Article
Journal/Proceeding Title: ACS Catalysis
Version: Author's manuscript



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