Metal-promoted MoS clusters: a platform for probing ensemble effects on the electrochemical conversion of CO and CO to methanol

Presented herein is an investigation of a promising ternary metal sulfide catalyst that is capable of electrochemically converting CO 2 to liquid and gas fuels such as methanol and hydrogen. When promoted by copper, an extended structure of Chevrel-phase Mo 6 S 8 clusters is capable of reducing CO 2...

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Bibliographic Details
Published in:Materials horizons 2020-01, Vol.7 (1), p.193-22
Main Authors: Perryman, Joseph T, Ortiz-Rodríguez, Jessica C, Jude, Joshua W, Hyler, Forrest P, Davis, Ryan C, Mehta, Apurva, Kulkarni, Ambarish R, Patridge, Christopher J, Velázquez, Jesús M
Format: Article
Language:English
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Summary:Presented herein is an investigation of a promising ternary metal sulfide catalyst that is capable of electrochemically converting CO 2 to liquid and gas fuels such as methanol and hydrogen. When promoted by copper, an extended structure of Chevrel-phase Mo 6 S 8 clusters is capable of reducing CO 2 and CO to methanol in aqueous conditions with an overpotential of −0.4 V vs. RHE. H 2 gas is simultaneously and preferentially evolved during this process, contributing to total current densities as high as 35 mA cm −2 . It has been observed that Cu 2 Mo 6 S 8 displays unique catalytic activity in terms of product selectivity, and we attribute this activity to molybdenum sulfide cluster units based on the results of structural, electronic, and electroanalytical characterization. Also discussed is the formulation of an interesting electronic structure-function correlation founded on the basis of X-ray absorption spectroscopic analyses and corroborated by the results of electroanalytical evaluation, where it has been observed that introduction of metal promoting species into the Chevrel-phase framework encourages charge transfer into cluster chalcogen sites. Presented herein is an investigation of a promising ternary metal sulfide catalyst that is capable of electrochemically converting CO 2 to liquid and gas fuels such as methanol and hydrogen.
ISSN:2051-6347
2051-6355
DOI:10.1039/c9mh00745h