Your search keyword '"Photothermocatalysis"' showing total 3 results

1. Co0−Coδ+ Interface Double‐Site‐Mediated C−C Coupling for the Photothermal Conversion of CO2 into Light Olefins.

Author

Ning, Shangbo, Ou, Honghui, Li, Yaguang, Lv, Cuncai, Wang, Shufang, Wang, Dingsheng, and Ye, Jinhua

Subjects

*COUPLING reactions (Chemistry), *PHOTOTHERMAL conversion, *ACTIVATION energy, *ALKENES, *SOLAR stills, *CARBON dioxide, *FISCHER-Tropsch process, *PHOTOREDUCTION

Abstract

Solar‐driven CO2 hydrogenation into multi‐carbon products is a highly desirable, but challenging reaction. The bottleneck of this reaction lies in the C−C coupling of C1 intermediates. Herein, we construct the C−C coupling centre for C1 intermediates via the in situ formation of Co0−Coδ+ interface double sites on MgAl2O4 (Co−CoOx/MAO). Our experimental and theoretical prediction results confirmed the effective adsorption and activation of CO2 by the Co0 site to produce C1 intermediates, while the introduction of the electron‐deficient state of Coδ+ can effectively reduce the energy barrier of the key CHCH* intermediates. Consequently, Co−CoOx/MAO exhibited a high C2–4 hydrocarbons production rate of 1303 μmol g−1 h−1; the total organic carbon selectivity of C2–4 hydrocarbons is 62.5 % under light irradiation with a high ratio (≈11) of olefin to paraffin. This study provides a new approach toward the design of photocatalysts used for CO2 conversion into C2+ products. [ABSTRACT FROM AUTHOR]

Published

2023

2. Elemental Boron for Efficient Carbon Dioxide Reduction under Light Irradiation.

Author

Liu, Guigao, Meng, Xianguang, Zhang, Huabin, Zhao, Guixia, Pang, Hong, Wang, Tao, Li, Peng, Kako, Tetsuya, and Ye, Jinhua

Subjects

*CARBON dioxide reduction, *PHOTOREDUCTION, *BORON compounds, *IRRADIATION, *GLOBAL warming, *ENERGY conversion

Abstract

The photoreduction of CO2 is attractive for the production of renewable fuels and the mitigation of global warming. Herein, we report an efficient method for CO2 reduction over elemental boron catalysts in the presence of only water and light irradiation through a photothermocatalytic process. Owing to its high solar-light absorption and effective photothermal conversion, the illuminated boron catalyst experiences remarkable self-heating. This process favors CO2 activation and also induces localized boron hydrolysis to in situ produce H2 as an active proton source and electron donor for CO2 reduction as well as boron oxides as promoters of CO2 adsorption. These synergistic effects, in combination with the unique catalytic properties of boron, are proposed to account for the efficiency of the CO2 reduction. This study highlights the promise of photothermocatalytic strategies for CO2 conversion and also opens new avenues towards the development of related solar-energy utilization schemes. [ABSTRACT FROM AUTHOR]

Published

2017

3. Back Cover: Elemental Boron for Efficient Carbon Dioxide Reduction under Light Irradiation (Angew. Chem. Int. Ed. 20/2017).

Author

Liu, Guigao, Meng, Xianguang, Zhang, Huabin, Zhao, Guixia, Pang, Hong, Wang, Tao, Li, Peng, Kako, Tetsuya, and Ye, Jinhua

Subjects

*BORON compounds, *CARBON dioxide, *MAGAZINE covers, *IRRADIATION, *ENERGY conversion, *CHEMISTRY periodicals

Abstract

The photoreduction of carbon dioxide to give value‐added products is attractive for the production of renewable fuels and the mitigation of global warming. In their Communication on page 5570 ff., J. Ye et al. report an efficient method for CO2 reduction over elemental boron in the presence of only water and under light irradiation through a one‐step photothermocatalytic process. The boron material harvests the incident light, converts it into thermal energy, generates hydrogen, and catalyzes the overall process. [ABSTRACT FROM AUTHOR]

Published

2017