Kinetic study of multiphase reactions under microwave irradiation: A mini-review

IF 2.5 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Frontiers in chemical engineering Pub Date : 2022-11-01 DOI:10.3389/fceng.2022.1059160
Kazem Adavi, A. Amini, M. Latifi, Jaber Shabanian, J. Chaouki
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引用次数: 5

Abstract

Microwave (MW) heating is rapid, selective, and volumetric, and it is a compelling non-conventional heating approach for driving chemical reactions. The effect of MW irradiation on the kinetics of thermal/catalytic reactions is still under debate. A group of researchers reported that the effect of MW heating on reaction kinetics is highlighted through the non-thermal effects of MWs on kinetic parameters and reaction mechanisms in addition to the thermal effect. However, another group attributed the observations to the thermal effect only. In the present work, we summarized and critically synthesized available information in the literature on the subject. It can be concluded that MW heating has solely the thermal effect on gas-solid reactions, and the variations of kinetic parameters are related to the direct and indirect impacts of that. Temperature measurement limitations, physical structure variation, and non-uniform temperature distribution are the primary sources of the discrepancy in previous studies. In ionic liquid-solid reactions, the presence of electromagnetic fields can affect the movement of ions/polar molecules which can be considered a non-thermal effect of MWs. However, the effect of MW absorption by solid/catalyst, and the formation of hot spots must be taken into account to avoid potential discrepancy. Therefore, further theoretical/experimental studies are required to clarify the effect of MWs on liquid-solid reactions. In addition, developing reliable temperature measurement methods and isothermal reaction domain are required for an accurate kinetic study during MW irradiation.
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微波辐射下多相反应动力学研究综述
微波加热具有快速、选择性和体积性,是驱动化学反应的一种引人注目的非传统加热方法。微波辐照对热催化反应动力学的影响仍存在争议。一组研究人员报道,除了热效应外,MW加热对动力学参数和反应机理的非热效应也突出了MW加热对反应动力学的影响。然而,另一组将观察结果仅仅归因于热效应。在目前的工作中,我们总结并批判性地综合了有关该主题的文献中的可用信息。可以得出,MW加热对气固反应只有热效应,动力学参数的变化与热效应的直接和间接影响有关。温度测量的局限性、物理结构的变化和温度分布的不均匀是以往研究中产生差异的主要原因。在离子液固反应中,电磁场的存在可以影响离子/极性分子的运动,这可以被认为是mw的非热效应。但是,必须考虑固体/催化剂吸收MW的影响,以及热点的形成,以避免潜在的差异。因此,需要进一步的理论/实验研究来阐明MWs对液固反应的影响。此外,开发可靠的温度测量方法和等温反应域是精确研究毫瓦辐照动力学的必要条件。
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来源期刊
CiteScore
3.50
自引率
0.00%
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0
审稿时长
13 weeks
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