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Direct reduction of carbonate (CO32‒) to value-added chemicals presents several advantages for integrating CO2 capture from air with electrochemical conversion at near-unity efficiency. However, a critical challenge lies in effectively adsorbing CO32‒ as a reactive intermediate for sequential reduction. Density functional theory calculations indicate that the presence of oxygen vacancies (VO) on a SnO2 surface significantly enhances its reactivity toward CO32‒ adsorption, with the resulting adsorbed species (*CO3) detectable by Raman spectroscopy. Operando electrochemical Raman spectra have confirmed the formation of *CO3 on the partially reduced SnO2-xVO surface. Pulsed electrolysis has successfully converted CO32‒ to CO at a constant flow rate in an electrolyzer featuring a gas diffusion electrode configuration. A reaction cycle, encompassing SnO2 partial reduction, CO32‒ adsorption and reduction, and SnO2 regeneration, has been proposed as a viable approach for continuous direct CO32‒ reduction.

Direct Carbonate Reduction on Sn Oxide Surface / Wang, Jun; Chen, Lijuan; Huang, Lan; Chen, Tengfei; Zeng, Juqin; Wenbo Ju, And. - In: CHEMSUSCHEM. - ISSN 1864-5631. - (2025). [10.1002/cssc.202500364]

Direct Carbonate Reduction on Sn Oxide Surface

Lan Huang;Juqin Zeng;
2025

Abstract

Direct reduction of carbonate (CO32‒) to value-added chemicals presents several advantages for integrating CO2 capture from air with electrochemical conversion at near-unity efficiency. However, a critical challenge lies in effectively adsorbing CO32‒ as a reactive intermediate for sequential reduction. Density functional theory calculations indicate that the presence of oxygen vacancies (VO) on a SnO2 surface significantly enhances its reactivity toward CO32‒ adsorption, with the resulting adsorbed species (*CO3) detectable by Raman spectroscopy. Operando electrochemical Raman spectra have confirmed the formation of *CO3 on the partially reduced SnO2-xVO surface. Pulsed electrolysis has successfully converted CO32‒ to CO at a constant flow rate in an electrolyzer featuring a gas diffusion electrode configuration. A reaction cycle, encompassing SnO2 partial reduction, CO32‒ adsorption and reduction, and SnO2 regeneration, has been proposed as a viable approach for continuous direct CO32‒ reduction.
2025
CHEMSUSCHEM
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2999029