Use of pyridine derivatives as inhibitor/retarding agent for photoinduced cationic polymerization of epoxides

IF 4.5 3区工程技术 Q1 CHEMISTRY, APPLIED

Reactive & Functional Polymers Pub Date : 2024-04-30 DOI:10.1016/j.reactfunctpolym.2024.105922

Emile Goldbach, Xavier Allonas, Lucile Halbardier, Christian Ley, Céline Croutxé-Barghorn

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Abstract

In this study, the cationic photopolymerization of epoxy controlled by pyridine derivative was investigated. Two pyridines were selected in order to explore the impact of the associated pKa and the amine steric hindrance on the polymerization. The inhibition, the polymerization rate, the heat flow and the conversion during dark polymerization were found to be affected depending of the pyridine derivative structure. Two mechanisms seem to be involved. 1) During the initiation step, the proton is trapped by pyridine derivative, a fact which delays the polymerization reaction, because of less growing chains and lower exothermicity. 2) During the propagation reaction, an interaction between the oxonium ion and the pyridine derivative takes place, which results in a decrease of the rate of polymerization. These two mechanisms depend on the concentration, but also on the associated pKa and on the steric hindrance of the amine, which allows a tailorable control over the cationic polymerization kinetics.

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使用吡啶衍生物作为环氧化物光诱导阳离子聚合的抑制剂/缓凝剂

本研究探讨了吡啶衍生物控制的环氧阳离子光聚合反应。为了探讨相关 pKa 和胺立体阻碍对聚合的影响，选择了两种吡啶。研究发现，吡啶衍生物结构的不同会影响暗聚合过程中的抑制作用、聚合速率、热流和转化率。这似乎涉及两种机制。1) 在起始步骤中，质子被吡啶衍生物截留，从而延迟了聚合反应，因为生长的链较少，放热较低。2) 在传播反应过程中，氧离子与吡啶衍生物发生相互作用，导致聚合速率降低。这两种机理不仅取决于浓度，还取决于相关的 pKa 值和胺的立体阻碍，因此可以对阳离子聚合动力学进行有针对性的控制。

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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来源期刊

Reactive & Functional Polymers 工程技术-高分子科学

CiteScore

8.90

自引率

5.90%

发文量

259

审稿时长

27 days

期刊介绍： Reactive & Functional Polymers provides a forum to disseminate original ideas, concepts and developments in the science and technology of polymers with functional groups, which impart specific chemical reactivity or physical, chemical, structural, biological, and pharmacological functionality. The scope covers organic polymers, acting for instance as reagents, catalysts, templates, ion-exchangers, selective sorbents, chelating or antimicrobial agents, drug carriers, sensors, membranes, and hydrogels. This also includes reactive cross-linkable prepolymers and high-performance thermosetting polymers, natural or degradable polymers, conducting polymers, and porous polymers. Original research articles must contain thorough molecular and material characterization data on synthesis of the above polymers in combination with their applications. Applications include but are not limited to catalysis, water or effluent treatment, separations and recovery, electronics and information storage, energy conversion, encapsulation, or adhesion.