Photothermal effect and application of photothermal materials in photocatalysis and photoelectric catalysis

Jingnan Zhang, Tong-Dan. Tang, Rongge Yang, Guilin Wang, Kai-Hang Ye, Jianxin Shi
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Abstract

Photocatalysis (PC) and photoelectric catalysis (PEC) are environmental protection technologies that use sunlight capacity and environmental governance, and they have a wide range of applications in hydrogen production, carbon dioxide reduction, organic degradation, and other fields. When the light is irradiated on the material, part of the light energy will be converted into heat energy, and the combination of this part of the heat energy with PC and PEC will become an important way to improve optical performance. Compared with traditional technology, the synergistic effect of light and heat can obtain higher catalytic performance and improve energy utilization efficiency. This review begins with an overview of the principle of photoheat generation, which produces heat energy in a non-radiative process through photo-induced instability of electrons. The principle of thermal effect on the performance improvement of PC/PEC is analyzed from the dynamics and thermodynamics of photoreaction and electric reaction. On this basis, several materials widely used at present are listed, such as oxides, plasmas, conductive polymers, carbon materials, and other typical photothermal materials. The specific applications of photothermal materials in PC and PEC processes, such as hydrogen production by oxidation, carbon dioxide reduction, organic matter reduction, and seawater desalination, were discussed. Finally, the challenges to PC/PEC from the introduction of thermal effects are further discussed to provide a clean and sustainable way to build a carbon-neutral society.
光热效应和光热材料在光催化和光电催化中的应用
光催化(PC)和光电催化(PEC)是利用阳光能力和环境治理的环保技术,在制氢、二氧化碳还原、有机物降解等领域有着广泛的应用。当光照射在材料上时,部分光能将转化为热能,将这部分热能与 PC 和 PEC 结合将成为提高光学性能的重要途径。与传统技术相比,光和热的协同效应可以获得更高的催化性能,提高能源利用效率。本综述首先概述了光热产生的原理,即通过光诱导电子的不稳定性在非辐射过程中产生热能。从光反应和电反应的动力学和热力学角度分析了热效应对提高 PC/PEC 性能的原理。在此基础上,列举了目前广泛应用的几种材料,如氧化物、等离子体、导电聚合物、碳材料和其他典型的光热材料。讨论了光热材料在 PC 和 PEC 过程中的具体应用,如氧化制氢、二氧化碳还原、有机物还原和海水淡化。最后,进一步讨论了引入热效应给 PC/PEC 带来的挑战,以便为建设碳中和社会提供一种清洁、可持续的方式。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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