Chapter 7. Radical Polymerisation under Flow Conditions

Green Chemistry Series Pub Date : 2019-09-18 DOI:10.1039/9781788016094-00217

L. Brocken, I. Baxendale

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Abstract

Polymers are an important class of compounds used in many commercial products; for example, in the aerospace and automotive industries functioning as low weight construction parts and seals, through into the packaging of food and drink and even as aqueous soluble polymers, which are found in numerous detergents and other cleaning products. Significant research has, therefore, been invested towards the design and synthesis of new polymers using a variety of polymerisation techniques to deliver specifically tailored structures with refined macromolecular structures including tailoring parameters such as molecular weight, polydispersity and tacticity. One interesting approach, which has started to demonstrate value in the synthesis of polymers, is the conducting of polymerisation processes in a dynamic continuous flow scenario. Flow polymerisation has been shown to facilitate access to new polymers which cannot be synthesised or would be difficult to prepare under conventional batch conditions through improved control over the various reaction parameters. In this chapter, a brief selective overview is given of the various syntheses of polymers and polymeric particles that have been reported in the literature via flow processes to date.

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第七章。流动条件下的自由基聚合

聚合物是许多商业产品中使用的一类重要化合物;例如，在航空航天和汽车工业中，作为低重量的建筑部件和密封件，通过进入食品和饮料的包装，甚至作为水溶性聚合物，在许多洗涤剂和其他清洁产品中发现。因此，重要的研究已经投入到使用各种聚合技术来设计和合成新的聚合物，以提供具有精细大分子结构的专门定制结构，包括分子量、多分散性和战术性等定制参数。一种有趣的方法，已经开始在聚合物合成中展示价值，是在动态连续流场景中进行聚合过程。流动聚合已被证明可以通过改进对各种反应参数的控制，促进获得在常规批处理条件下无法合成或难以制备的新聚合物。在本章中，对迄今为止文献中报道的通过流动过程合成聚合物和聚合物颗粒的各种方法进行了简要的选择性概述。

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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Green Chemistry Series

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