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Enhanced catalytic activity of Au core Pd shell Pt cluster trimetallic nanorods for CO2 reduction

机译:增强Au芯PD壳PT簇三聚体纳米杆用于CO2的催化活性

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摘要

Herein, Au core Pd shell Pt cluster nanorods (Au@Pd@Pt NRs) with enhanced catalytic activity were rationally designed for carbon dioxide (CO2) 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 ((Pt) = 0.5) with 2 monolayers of Pd, which could enhance the catalytic activity for CO2 reduction by 6 fold as compared to the Pt surface at -1.5 V vs. 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 in situ SERS investigation inferred that the Au@Pd@Pt NRs ((Pt) = 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 CO2 reduction and offer a new way to design new materials for the conversion of CO2 to liquid fuels.
机译:这里,具有增强催化活性的Au核心Pd壳Pt簇纳米棒(Au @ Pd @ PtnRS)是针对二氧化碳(CO2)还原的合理设计。表面组合物和PD-PT比率显着影响催化活性,并且优化的结构仅具有2个单层相当于Pt((Pt)= 0.5),其中2个单层Pd,其可以增强CO 2减少的催化活性与PT表面相比,在-1.5V与SCE相比,折叠。 PT负载的进一步增加实际降低了催化活性;这推断了三种不同纳米结构组分中存在协同效应。此外,由于表面等离子体共振,可以使用这些AU NRS在-1.5V下将光电催化活性提高30%。原位SERS调查推断,由于PD-PT双缘位点,AU @ PD @ Pt NRS((PT)= 0.5)不太可能被CO中毒;由于这个原因,所提出的结构表现出最高的催化活性。这些结果在二氧化碳减少的机械研究中发挥着重要作用,并提供了设计用于将CO2转化为液体燃料的新材料的新方法。

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  • 来源
    《RSC Advances 》 |2019年第18期| 共6页
  • 作者

    He Lan-qi; Yang Hao; Huang Jia-jun; Lu Xi-hong; Li Gao-Ren; Liu Xiao-qing; Fang Ping-ping; Tong Ye-xiang;

  • 作者单位

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

    Sun Yat Sen Univ Key Lab Low Carbon Chem &

    Energy Conservat Guangd MOE Key Lab Bioinorgan &

    Synthet Chem KLGHEI Environm &

    Energy Chem Sch Chem Guangzhou 510275 Guangdong Peoples R China;

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  • 正文语种 eng
  • 中图分类 化学 ;
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