Journal article

Increasing reactivity of plasmonic hot holes by a trapping strategy

C Li, Z Ma, B Han

Applied Catalysis B Environmental | Published : 2022

Abstract

Plasmonic photocatalysis has emerged as a promising solution for global energy crisis and environment pollution by facilitating wide ranging chemical transformations using photons in a broad region of solar spectrum. Despite numerous successful examples on improvement of electron-driven photochemistry, effective utilization of plasmonic hot holes is a long-standing challenge due to their ultrafast relaxation and short lifetime. Herein, we report that the reactivity of plasmonic hot holes can be greatly enhanced by a novel hot hole trapping strategy. We demonstrate a new concept of a metal-adsorbate interfacial structure that can be in situ constructed on gold (Au) surface in the presence of ..

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University of Melbourne Researchers

Grants

Awarded by National Natural Science Foundation of China


Funding Acknowledgements

This work was financially supported by Victoria-Jiangsu Program for Technology and Innovation Research and Development (VIC-JS TECH) project "Development of novel bio-organic fertilisers", Research Innovation Team of College of Chemistry and Environmental Science of Hebei University (hxkytd-py2104), National Natural Science Foundation of China (22002032), Hebei Key R&D Program (20327303D), Natural Science Foundation of Hebei Province (B2019201064), and The Excellent Going Abroad Experts' Training Program in Hebei Province (202001).