Welcome to the new version of CaltechAUTHORS. Login is currently restricted to library staff. If you notice any issues, please email coda@library.caltech.edu
CaltechAUTHORS
Published August 14, 2018 | Supplemental Material
Journal Article Open

Reduction of aqueous CO_2 to 1-Propanol at MoS_2 electrodes

Francis, Sonja A.
Velazquez, Jesus M.
Ferrer, Ivonne M.
Torelli, Daniel A. ORCID icon
Guevarra, Dan ORCID icon
McDowell, Matthew T. ORCID icon
Sun, Ke ORCID icon
Zhou, Xinghao ORCID icon
Saadi, Fadl H. ORCID icon
John, Jimmy ORCID icon
Richter, Matthias H. ORCID icon
Hyler, Forrest P.
Papadantonakis, Kimberly M. ORCID icon
Brunschwig, Bruce S. ORCID icon
Lewis, Nathan S. ORCID icon

Abstract

Reduction of carbon dioxide in aqueous electrolytes at single-crystal MoS_2 or thin-film MoS_2 electrodes yields 1-propanol as the major CO_2 reduction product, along with hydrogen from water reduction as the predominant reduction process. Lower levels of formate, ethylene glycol, and t-butanol were also produced. At an applied potential of −0.59 V versus a reversible hydrogen electrode, the Faradaic efficiencies for reduction of CO_2 to 1-propanol were ∼3.5% for MoS2single crystals and ∼1% for thin films with low edge-site densities. Reduction of CO_2 to 1-propanol is a kinetically challenging reaction that requires the overall transfer of 18 e– and 18 H+ in a process that involves the formation of 2 C–C bonds. NMR analyses using ^(13)CO_2 showed the production of ^(13)C-labeled 1-propanol. In all cases, the vast majority of the Faradaic current resulted in hydrogen evolution via water reduction. H_2S was detected qualitatively when single-crystal MoS_2 electrodes were used, indicating that some desulfidization of single crystals occurred under these conditions.

Additional Information

© 2018 American Chemical Society. Received: October 20, 2017; Revised: June 12, 2018; Published: June 13, 2018. We thank Dr. Nathan Dalleska and Dr. David VanderVelde of the Environmental Analysis Center and High Resolution NMR Facility, respectively, for many useful discussions and instrumental access and assistance. This material is based upon work performed by the Joint Center for Artificial Photosynthesis, a DOE Energy Innovation Hub, supported through the Office of Science of the U.S. Department of Energy under Award DE-SC0004993. S.A.F. acknowledges the Resnick Sustainability Institute at Caltech for a Postdoctoral Fellowship. J.M.V. acknowledges support through an NRC Ford Foundation Postdoctoral Fellowship and UC Davis startup funds. D.A.T. acknowledges support through a Graduate Research Fellowship from the National Science Foundation. Author Contributions: S.A.F. and J.M.V. contributed equally. The authors declare no competing financial interest.

Attached Files

Supplemental Material - cm7b04428_si_001.pdf

Files

cm7b04428_si_001.pdf
Files (3.0 MB)
Name Size Download all
md5:a2b94acd361ab884d248a713a416fe4d
3.0 MB Preview Download

Additional details

Identifiers Related works Funding Dates Caltech Custom Metadata
Created:
August 19, 2023
Modified:
October 18, 2023