Photothermal synergistic catalytic technology in energy field

doi:10.16085/j.issn.1000-6613.2016-1881

Abstract

Abstract: Photothermocatalysis has presented a novel technology which introduces simultaneous light into thermocatalytic system or heat into photocatalytic system for the purpose of co-catalysis,which has become popular in catalysis field.This paper mainly reviews chemical reactions in the field of energy synthesis under cooperative catalysis condition,including photothermocatalytic hydrogenation of CO,photothermocatalytic CO₂ reduction,and photothermal hydrolysis,etc.The current results suggested that the coupling of photocatalysis and thermocatalysis could drive reaction more efficiently,and overcome the obstacles existed in single-driven catalytic system.In the field of CO hydrogenation reaction,the introduction of illumination not only can obviously increase the CO conversion efficiency but also control hydrocarbon products'distribution.In the field of CO₂ reduction,it can be implemented that converting CO₂ into CO,CH₄,or other hydrocarbon products efficiently and selectively by modulating appropriate photothermal conditions.In the field of hydrolysis reaction,hydrogen production efficiency can be improved under mild conditions.Meanwhile,the related photothermal synergistic reaction mechanisms and the deficiencies at the present stage in various systems have been summarized.Finally,the prospects for future photothermal catalytic study are proposed,which might provide a positive pathway for developing new photothermal catalytic systems.

Key words: photothermocatalysis, carbon monoxide, hydrogenation, carbon dioxide, selective catalytic reduction, hydrogen production

摘要： 光热催化是在光催化的基础上同时加热，或在热催化的基础上同时进行光照以达到共同催化目的的一种新型催化手段，是当前催化领域的研究热点。文章介绍了光热协同催化在能源合成领域的应用，包括光热催化CO加氢、光热催化CO₂还原、光热分解水制氢等。研究发现，光催化与热催化耦合确实能够高效驱动反应的进行，明显改善了单一光催化或单一热催化的不足。在催化CO加氢方面，引入光照能明显提高CO的转化效率，同时能够调控烃类产物分布；在催化CO₂还原方面，通过调变合适的光热反应条件，能够实现高效地、选择性地将CO₂还原为CO、CH₄或其他烃类产物；在催化H₂O分解制氢方面，在温和条件下提高了产氢效率。与此同时，本文也分析了部分体系的光热协同作用机制以及现阶段研究的不足之处。最后展望了光热催化的发展前景，以期对于光热协同驱动体系的研究起到积极的促进作用。

关键词: 光热催化, 一氧化碳, 加氢, 二氧化碳, 选择催化还原, 制氢

CLC Number:

O643.32

WANG Limin, WANG Liqing, ZHANG Yichi, SU Haiquan. Photothermal synergistic catalytic technology in energy field[J]. Chemical Industry and Engineering Progress, 2017, 36(07): 2457-2463.

王丽敏, 王利清, 张一弛, 苏海全. 光热协同催化技术在能源领域的应用[J]. 化工进展, 2017, 36(07): 2457-2463.

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