微波辅助流动化学在绿色合成及其他应用中的应用

IF 0.9 Q4 CHEMISTRY, MULTIDISCIPLINARY Current Microwave Chemistry Pub Date : 2022-12-08 DOI:10.2174/2213335610666221208163107
B. Török, T. Mooney, Maysa Ilamanova
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引用次数: 0

摘要

使用组合的微波辅助流动化学方法是微波化学和绿色合成最活跃的领域之一。微波辅助有机合成(MAOS)为发展绿色合成方法做出了重要贡献,而流动化学在工业化学中的应用相当流行。两者的结合具有深远的优势。在早期的研究中,流动化学的概念被应用于家用微波炉,这已经表明了未来应用的强大潜力。流动反应器相对较小的直径可以解决微波穿透深度有限的问题,这是大型间歇反应器的主要障碍。随着具有可调谐频率和更好的温度控制的专用微波合成器的商业可用性,应用流动合成的可能性变得更加广泛。事态发展集中在几个问题上;两个主要是反应器和催化剂的设计和应用。常见的反应器类型包括微波吸收材料,如碳化硅,和微波透明材料,如硼硅酸盐玻璃、石英或特氟龙,催化剂或溶剂相应调整。几种多相催化剂被认为是强微波吸收剂,可以从反应器内部加热反应。这样的材料包括粘土、沸石或负载的金属催化剂。在这里,从有机化合物到纳米颗粒和新材料,合成精细化学品将说明设计和应用方面的主要进展以及所获得的好处。
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Microwave-Assisted Flow Chemistry for Green Synthesis and Other Applications
Using combined microwave-assisted flow chemistry approaches is one of the most active areas of microwave chemistry and green synthesis. Microwave-assisted organic synthesis (MAOS) has contributed significantly to developing green synthetic methods, while flow chemistry applications are quite popular in industrial chemistry. The combination of the two has far-reaching advantages. In early studies, the flow chemistry concept was applied in domestic microwave ovens already indicating strong potential for future applications. The relatively small diameter of the flow reactors can address the limited penetration depth of microwaves, which is a major impediment in large-scale batch reactors. With the commercial availability of dedicated microwave synthesizers with tunable frequencies and better temperature control, the possibilities to apply flow synthesis grew even broader. The developments focus on several issues; the two major ones are the design and application of reactors and catalysts. Common reactor types include microwave-absorbing, such as silicon carbide, and microwave-transparent materials, such as borosilicate glass, quartz, or Teflon, with the catalyst or solvent adjusted accordingly. Several heterogeneous catalysts are considered strong microwave absorbers that can heat the reaction from inside the reactor. Such materials include clays, zeolites, or supported metal catalysts. Here, the major advances in design and applications and the benefits gained will be illustrated by synthesizing fine chemicals, from organic compounds to nanoparticles and new materials.
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来源期刊
Current Microwave Chemistry
Current Microwave Chemistry CHEMISTRY, MULTIDISCIPLINARY-
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