AI Article Synopsis
- Au@Pd@Pt nanorods (NRs) were engineered to enhance catalytic activity for carbon dioxide (CO) reduction, showing a six-fold increase in efficiency compared to pure Pt surfaces.
- The optimal nanostructure had a specific Pt and Pd layer configuration, where too much Pt actually decreased performance due to a synergistic effect among the materials.
- This research highlights the potential of using these nanorods for more effective CO conversion to liquid fuels and improves our understanding of how to design better catalytic materials.
Article Abstract
Herein, Au core Pd shell Pt cluster nanorods (Au@Pd@Pt NRs) with enhanced catalytic activity were rationally designed for carbon dioxide (CO) reduction. The surface composition and Pd-Pt ratios significantly influenced the catalytic activity, and the optimized structure had only a half-monolayer equivalent of Pt ( = 0.5) with 2 monolayers of Pd, which could enhance the catalytic activity for CO reduction by 6 fold as compared to the Pt surface at -1.5 V SCE. A further increase in the loading of Pt actually reduced the catalytic activity; this inferred that a synergistic effect existed among the three different nanostructure components. Furthermore, these Au NRs could be employed to improve the photoelectrocatalytic activity by 30% at -1.5 V due to the surface plasmon resonance. An SERS investigation inferred that the Au@Pd@Pt NRs ( = 0.5) were less likely to be poisoned by CO because of the Pd-Pt bimetal edge sites; due to this reason, the proposed structure exhibited highest catalytic activity. These results play an important role in the mechanistic studies of CO reduction and offer a new way to design new materials for the conversion of CO to liquid fuels.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9062470 | PMC |
| http://dx.doi.org/10.1039/c8ra10494h | DOI Listing |
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