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Ceria -Mediated Dynamic Sn<sup>0</sup>/Sn<sup>δ+</sup> Redox Cycle for CO<sub>2</sub> Electroreduction

Hai Liu, Boyang Li, Zhihui Liu, Zhanpeng Liang, Hongyuan Chuai, Hui Wang, Shi Nee Lou, Yaqiong Su, Sheng Zhang, Xinbin Ma

2023ACS Catalysis114 citationsDOI

Abstract

Electrocatalytic CO 2 reduction has been considered an effective carbon neutrality as well as energy storage strategy integrated with renewable electricity. CO 2 conversion to formate is a feasible route using earth-abundant and nontoxic tin-based catalysts. However, they suffer from degradation and thus decrease in formate selectivity during operation. Guided by density functional theory (DFT) calculations, herein, we synthesized CeO 2 –SnO 2 heterostructures by a facile electrospinning method, which exhibited a maximum formate partial current density of ∼500 mA·cm –2 with 87.1% faradaic efficiency and a long-term stability in a flow cell. Proved by in situ attenuated total reflectance infrared absorption spectroscopy (ATR-IRAS) and Raman spectra as well as post-X-ray photoelectron spectroscopy (XPS) analysis, a dynamic CeO 2 -mediated Sn 0 /Sn δ+ redox cycle mechanism was proposed: oxygen vacancies generated on cerium oxides prompted water dissociation to produce *OH and *H species, where the former oxidize Sn 0 into active Sn δ+, facilitating the conversion of CO 2 to the key intermediate *OCHO with the help of the latter. This work may provide a general strategy to design stable and efficient catalysts for practical CO 2 electrolyzers.

Topics & Concepts

FormateCatalysisX-ray photoelectron spectroscopyFaraday efficiencyDensity functional theoryRedoxDissociation (chemistry)Inorganic chemistryCeriumCerium oxideChemistryMaterials scienceNanoflowerPhotochemistryChemical engineeringElectrolyteElectrodePhysical chemistryComputational chemistryEngineeringBiochemistryCO2 Reduction Techniques and CatalystsElectrocatalysts for Energy ConversionIonic liquids properties and applications
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