Chapter 8. Ionic Polymerisation and New Approaches to Polymerisation under Flow Conditions

L. Brocken, I. Baxendale
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Abstract

Although ionic polymerisations are a valuable methodology historically they are less widely used because they are considered capricious, requiring significantly more optimisation due to their sensitivity to the specific reaction and processing conditions. Increasingly though flow processing regimes are being successfully implemented to allow better control over reaction parameters and facilitate a more consistent processing environment; this has also shown promising results for challenging reactions such as ionic polymerisation. Furthermore, as flow chemistry is becoming more widely implemented additional and complementary processing tools such as photochemical, supported reagents and enzymatic based plug-in reactors are being evaluated for their ability to expand the range of polymers on offer. Supplementing this era of advanced and accelerated synthesis is an explosion in direct integrated analysis routines and the development of smart self-optimising platforms capable of self-sustained assembly of new polymers. Whilst the machines have been taking over the physical synthesis, chemists have been starting to think beyond simply the isolated stage of polymer synthesis, considering options to create more encompassing work-flows. The next generations of polymer synthesis will encompass all aspects of synthesis, purification and final analysis as a single unified sequence. These new polymer products will ultimately be used for new applications such as light-emitting diodes and in photovoltaics.
第八章。离子聚合及流动条件下聚合的新途径
尽管离子聚合在历史上是一种有价值的方法,但它们的应用并不广泛,因为它们被认为是反复无常的,由于它们对特定反应和处理条件的敏感性,需要显着更多的优化。虽然越来越多的流动处理制度正在成功实施,以便更好地控制反应参数并促进更一致的处理环境;这在离子聚合等具有挑战性的反应中也显示出有希望的结果。此外,随着流动化学的应用越来越广泛,人们正在评估光化学、支撑试剂和酶基插入式反应器等附加和互补的处理工具,以扩大聚合物的使用范围。补充这个先进和加速合成的时代是直接集成分析程序的爆炸式增长,以及能够自我维持新聚合物组装的智能自优化平台的发展。虽然机器已经接管了物理合成,但化学家们已经开始考虑超越简单的聚合物合成的孤立阶段,考虑创造更全面的工作流程。下一代的聚合物合成将包括合成、纯化和最终分析的所有方面,作为一个统一的序列。这些新的聚合物产品最终将用于新的应用,如发光二极管和光伏。
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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