The electrochemical carbon dioxide reduction reaction (CO RR) presents a viable approach to recycle CO gas into low carbon fuels. Thus, the development of highly active catalysts at low overpotential is desired for this reaction. Herein, a high-yield synthesis of unique star decahedron Cu nanoparticles (SD-Cu NPs) electrocatalysts, displaying twin boundaries (TBs) and multiple stacking faults, which lead to low overpotentials for methane (CH ) and high efficiency for ethylene (C H ) production, is reported. Particularly, SD-Cu NPs show an onset potential for CH production lower by 0.149 V than commercial Cu NPs. More impressively, SD-Cu NPs demonstrate a faradaic efficiency of 52.43% ± 2.72% for C H production at -0.993 ± 0.0129 V. The results demonstrate that the surface stacking faults and twin defects increase CO binding energy, leading to the enhanced CO RR performance on SD-Cu NPs.
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| http://dx.doi.org/10.1002/adma.201805405 | DOI Listing |
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A Highly Active Star Decahedron Cu Nanocatalyst for Hydrocarbon Production at Low Overpotentials.
Adv Mater
February 2019
Department of Materials Science and Engineering, University of California, Los Angeles, Los Angeles, CA, 90095, USA.
The electrochemical carbon dioxide reduction reaction (CO RR) presents a viable approach to recycle CO gas into low carbon fuels. Thus, the development of highly active catalysts at low overpotential is desired for this reaction. Herein, a high-yield synthesis of unique star decahedron Cu nanoparticles (SD-Cu NPs) electrocatalysts, displaying twin boundaries (TBs) and multiple stacking faults, which lead to low overpotentials for methane (CH ) and high efficiency for ethylene (C H ) production, is reported.
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