Potential-Dependent CO2 Electroreduction Pathways on Cu(111) Based on an Improved Electrode/Aqueous Interface Model: Determination of the Origin of the Overpotentials

Potential-dependent CO2 electroreduction pathways on Cu(111) are systematically studied with the aim of applying an improved electrode/aqueous interface model in this paper. The results indicate that our present defined CH2O and CHOH pathways may be able to parallelly take place at low overpotential...

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Veröffentlicht in:ACS omega 2019-10, Vol.4 (17), p.17269-17278
Hauptverfasser: Ou, Lihui, Zhao, Kexin
Format: Artikel
Sprache:eng
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Zusammenfassung:Potential-dependent CO2 electroreduction pathways on Cu(111) are systematically studied with the aim of applying an improved electrode/aqueous interface model in this paper. The results indicate that our present defined CH2O and CHOH pathways may be able to parallelly take place at low overpotentials. Notably, the applied potentials will not alter the optimal CO2 reduction mechanisms. However, the presence of high overpotentials makes CO2 electroreduction more favorable, thus explaining why high overpotentials at experiments are required during CO2 electroreduction on Cu. Based on the potential-dependent energetics, the results suggest that COOH and CHO intermediates may be unstable at low overpotentials, in which COOH can easily change back to CO2 and CHO can easily change back to CO, thus preventing CO2 electroreduction. However, the high overpotentials will facilitate the formation and further electroreduction of CO and CHO. Thus, we can speculate that CO formation and then further electroreduction into CHO are the possible potential-limiting steps during CO2 electroreduction, which are regarded as the origin of experimentally observed high overpotentials. The present comprehensive understanding on CO2 electroreduction pathways can provide theoretical guidelines for efficiently designing Cu-based alloy electrocatalysts operated under the conditions of low overpotentials.
ISSN:2470-1343
2470-1343
DOI:10.1021/acsomega.9b01917