Plasmon-Induced Semiconductor-Based Photo-Thermal Catalysis: Fundamentals, Critical Aspects, Design, and Applications

Photochem Pub Date : 2022-10-02 DOI:10.3390/photochem2040052
A. Sial, A. Dar, Yifan Li, Chuanyi Wang
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引用次数: 2

Abstract

Photo-thermal catalysis is among the most effective alternative pathways used to perform chemical reactions under solar irradiation. The synergistic contributions of heat and light during photo-thermal catalytic processes can effectively improve reaction efficiency and alter design selectivity, even under operational instability. The present review focuses on the recent advances in photo-thermal-driven chemical reactions, basic physics behind the localized surface plasmon resonance (LSPR) formation and enhancement, pathways of charge carrier generation and transfer between plasmonic nanostructures and photo-thermal conversion, critical aspects influencing photo-thermal catalytic performance, tailored symmetry, and morphology engineering used to design efficient photo-thermal catalytic systems. By highlighting the multifield coupling benefits of plasmonic nanomaterials and semiconductor oxides, we summarized and discussed several recently developed photo-thermal catalysts and their catalytic performance in energy production (CO2 conversion and H2 dissociation), environmental protection (VOCs and dyes degradation), and organic compound synthesis (Olefins). Finally, the difficulties and future endeavors related to the design and engineering of photo-thermal catalysts were pointed out to draw the attention of researchers to this sustainable technology used for maximum solar energy utilization.
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等离子体诱导半导体光热催化:基础、关键方面、设计和应用
光热催化是在太阳照射下进行化学反应的最有效的替代途径之一。在光热催化过程中,热和光的协同作用可以有效地提高反应效率和改变设计选择性,即使在操作不稳定的情况下也是如此。本文综述了光热驱动化学反应的最新进展,局部表面等离子体共振(LSPR)形成和增强背后的基本物理学,等离子体纳米结构与光热转化之间电荷载流子产生和转移的途径,影响光热催化性能的关键方面,定制对称,以及用于设计高效光热催化系统的形态学工程。通过强调等离子体纳米材料和半导体氧化物的多场耦合优势,我们总结和讨论了近年来开发的几种光热催化剂及其在能源生产(CO2转化和H2解离)、环境保护(VOCs和染料降解)和有机化合物合成(烯烃)方面的催化性能。最后,指出了光热催化剂在设计和工程方面存在的困难和未来的努力,以引起研究人员对这一可持续技术的关注,以最大限度地利用太阳能。
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CiteScore
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