E057-02 - Fachbereich Universitäre Serviceeinrichtung für Transmissions- Elektronenmikroskopie
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Journal:
ACS Catalysis
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ISSN:
2155-5435
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Date (published):
2021
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Number of Pages:
9
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Publisher:
AMER CHEMICAL SOC
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Peer reviewed:
Yes
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Keywords:
General Chemistry; Catalysis; XPS; electrocatalysis; transition-metal carbides; electrochemical CO2 reduction; surface Pourbaix diagram; ab initio thermodynamics; solid/liquid interface; HER
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Abstract:
Compound materials, such as transition-metal (TM) carbides, are
anticipated to be effective electrocatalysts for the carbon dioxide reduction reaction
(CO2RR) to useful chemicals. This expectation is nurtured by density functional theory
(DFT) predictions of a break of key adsorption energy scaling relations that limit CO2RR
at parent TMs. Here, we evaluate these prospects for hexagonal Mo2C in aqueous
electrolytes in a multimethod experiment and theory approach. We find that surface
oxide formation completely suppresses the CO2 activation. The oxides are stable down to
potentials as low as −1.9 V versus the standard hydrogen electrode, and solely the
hydrogen evolution reaction (HER) is found to be active. This generally points to the
absolute imperative of recognizing the true interface establishing under operando conditions in computational screening of catalyst
materials. When protected from ambient air and used in nonaqueous electrolyte, Mo2C indeed shows CO2RR activity.
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Research Areas:
Materials Characterization: 50% Special and Engineering Materials: 50%
