自愈聚合物的可持续性:从整体角度看聚合物网络的循环性

IF 26 1区 化学 Q1 POLYMER SCIENCE
Kenneth Cerdan , Marlies Thys , Aleix Costa Cornellà , Fatma Demir , Sophie Norvez , Richard Vendamme , Niko Van den Brande , Peter Van Puyvelde , Joost Brancart
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引用次数: 0

摘要

永久性聚合物网络对可持续发展提出了重大挑战。不可逆共价交联赋予了这些材料优异的机械性能、耐热性和耐化学性,但也使其难以修复和回收。自修复机制可延长热固性材料和弹性体的使用寿命,提高其耐用性,使其生命周期更具可持续性。除了延长使用寿命外,本文还从整体角度探讨了自修复聚合物的可持续性。参考绿色化学原则和可持续发展,对自愈合聚合物的整个生命周期进行了严格评估。从原料、单体官能化和聚合物合成开始,到加工和制造以及生命周期末期的考虑因素,即回收或(生物)降解,讨论了自愈合化学与生命周期各阶段可持续性方面的关系。本综述为开发更具可持续性的热固性塑料、弹性体及其复合材料提供了一个工具箱。最重要的是要考虑自愈合材料、衍生产品以及任何材料或产品的整个生命周期。自愈合能力和通常相关的可回收性应主要通过延长产品寿命和最大限度地再加工成新产品来减少满足社会需求所需的新材料数量。相对于延长的使用寿命,提高愈合效率和愈合循环次数可改善对环境的整体影响。从生物质、回收工艺或废物流中提取的可再生资源应成为制造新型自愈合聚合物的首选。最后,可生物降解性可被视为自愈合聚合物意外流失到环境中后的一种补充性报废方案,前提是生物降解不会在自愈合聚合物和产品的预期使用条件下开始,而是可以推迟到与环境中存在的刺激物接触之后。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Sustainability of self-healing polymers: A holistic perspective towards circularity in polymer networks

Sustainability of self-healing polymers: A holistic perspective towards circularity in polymer networks

Permanent polymer networks present an important sustainability challenge. Irreversible covalent crosslinks impart these materials excellent mechanical properties, thermal and chemical resistance, yet also render them difficult to repair and to recycle. Self-healing mechanisms can extend the lifetime of thermosets and elastomers, improving their durability and making their lifecycle more sustainable. In addition to the lifetime extension, this paper reviews the sustainability of self-healing polymers from a holistic point of view. The entire lifecycle of self-healing polymers is critically assessed with reference to the green chemistry principles and sustainable development. The relation between the self-healing chemistries and the sustainability aspects of each of the phases of the lifecycle are discussed, starting from the feedstocks, monomer functionalisation and polymer synthesis, to processing and manufacturing as well as end-of-life considerations, i.e. recycling or (bio)degradation. The review provides a toolbox for the development of more sustainable thermosets, elastomers and their composites. It is of utmost importance to consider the entire lifecycle of self-healing materials, derived products and – by extension – any material or product. The self-healing ability and often related recyclability should primarily reduce the amount of new materials that are necessary to fulfill societal needs, by extending the lifetime of products and maximizing reprocessing into new products. Increasing healing efficiency and the number of healing cycles improves the overall environmental impact relative to the extended service lifetime. Renewable resources derived from biomass, recycling processes or waste streams should be the first choice to create new self-healing polymers. Finally, biodegradability can be considered as a complementary end-of-life scenario upon accidental loss of self-healing polymer to the environment, provided that the biodegradation does not start under the prospected use conditions of the self-healing polymers and products, but can be postponed until contact with stimuli present in the environment.

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来源期刊
Progress in Polymer Science
Progress in Polymer Science 化学-高分子科学
CiteScore
48.70
自引率
1.10%
发文量
54
审稿时长
38 days
期刊介绍: Progress in Polymer Science is a journal that publishes state-of-the-art overview articles in the field of polymer science and engineering. These articles are written by internationally recognized authorities in the discipline, making it a valuable resource for staying up-to-date with the latest developments in this rapidly growing field. The journal serves as a link between original articles, innovations published in patents, and the most current knowledge of technology. It covers a wide range of topics within the traditional fields of polymer science, including chemistry, physics, and engineering involving polymers. Additionally, it explores interdisciplinary developing fields such as functional and specialty polymers, biomaterials, polymers in drug delivery, polymers in electronic applications, composites, conducting polymers, liquid crystalline materials, and the interphases between polymers and ceramics. The journal also highlights new fabrication techniques that are making significant contributions to the field. The subject areas covered by Progress in Polymer Science include biomaterials, materials chemistry, organic chemistry, polymers and plastics, surfaces, coatings and films, and nanotechnology. The journal is indexed and abstracted in various databases, including Materials Science Citation Index, Chemical Abstracts, Engineering Index, Current Contents, FIZ Karlsruhe, Scopus, and INSPEC.
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