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首页> 外文期刊>Angewandte Chemie >Tuning Cu/Cu2O Interfaces for the Reduction of Carbon Dioxide to Methanol in Aqueous Solutions
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Tuning Cu/Cu2O Interfaces for the Reduction of Carbon Dioxide to Methanol in Aqueous Solutions

机译:调整Cu / Cu2O界面,用于将二氧化碳还原到水溶液中的甲醇

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摘要

Artificial photosynthesis can be used to store solar energy and reduce CO2 into fuels to potentially alleviate global warming and the energy crisis. Compared to the generation of gaseous products, it remains a great challenge to tune the product distribution of artificial photosynthesis to liquid fuels, such as CH3OH, which are suitable for storage and transport. Herein, we describe the introduction of metallic Cu nanoparticles (NPs) on Cu2O films to change the product distribution from gaseous products on bare Cu2O to predominantly CH3OH by CO2 reduction in aqueous solutions. The specifically designed Cu/Cu2O interfaces balance the binding strengths of H* and CO* intermediates, which play critical roles in CH3OH production. With a TiO2 model photoanode to construct a photoelectrochemical cell, a Cu/Cu(2)Odark cathode exhibited a Faradaic efficiency of up to 53.6% for CH3OH production. This work demonstrates the feasibility and mechanism of interface engineering to enhance the CH3OH production from CO2 reduction in aqueous electrolytes.
机译:人造光合作用可用于将太阳能存储,并将二氧化碳减少到燃料中以潜在缓解全球变暖和能源危机。与气态产品的产生相比,将人造光合作用的产品分布与液体燃料(如CH 3 OH)调整适用于储存和运输,这仍然是一个巨大的挑战。在此,我们描述了在Cu 2 O膜上引入金属Cu纳米颗粒(NPS),以将来自裸态产物的产物分布改变在裸露的Cu 2 O上,以通过CO 2还原在水溶液中的CH 3 OH。专门设计的Cu / Cu2O界面平衡了H *和Co *中间体的结合强度,在CH3OH生产中起着关键作用。使用TiO2模型光电码构造光电化学电池,Cu / Cu(2)Odark阴极表现出高达53.6%的CH 3 OH生产的效率。该工作证明了界面工程的可行性和机制,以增强来自CO 2的CH3OH生产在水性电解质中。

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  • 来源
    《Angewandte Chemie》 |2018年第47期|共5页
  • 作者

    Chang Xiaoxia; Wang Tuo; Zhao Zhi-Jian; Yang Piaoping; Greeley Jeffrey; Mu Rentao; Zhang Gong; Gong Zhongmiao; Luo Zhibin; Chen Jun; Cui Yi; Ozin Geoffrey A.; Gong Jinlong;

  • 作者单位

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

    Purdue Univ Davidson Sch Chem Engn W Lafayette IN 47907 USA;

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

    Chinese Acad Sci Vacuum Interconnected Nanotech Workstn Suzhou Inst Nanotech &

    Nanobion Suzhou 215123 Peoples R China;

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

    Stanford Univ Dept Mat Sci &

    Engn Stanford CA 94305 USA;

    Chinese Acad Sci Vacuum Interconnected Nanotech Workstn Suzhou Inst Nanotech &

    Nanobion Suzhou 215123 Peoples R China;

    Univ Toronto Dept Chem Toronto ON Canada;

    Tianjin Univ Key Lab Green Chem Technol Minist Educ Sch Chem Engn &

    Technol Collaborat Innovat Ctr Ch Tianjin 300072 Peoples R China;

  • 收录信息
  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类 应用化学;
  • 关键词

    artificial photosynthesis; CO2 reduction; copper; interfaces; methanol;

    机译:人造光合作用;CO2减少;铜;界面;甲醇;

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