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交联烯烃树脂自由基聚合中氧消耗对过渡金属催化剂的依赖性

Dependence of O Depletion on Transition Metal Catalyst in Radical Polymerization of Cross-Linking Alkene Resins.

作者信息

den Besten Hugo, Zhang Yanrong, Eijsink Linda E, Sardjan Andy S, Volker Anouk, Browne Wesley R

机构信息

Molecular Inorganic Chemistry, Stratingh Institute for Chemistry, Faculty of Science and Engineering, University of Groningen, Nijenborgh 3, 9747 AG Groningen, The Netherlands.

出版信息

Inorg Chem. 2025 Apr 21;64(15):7716-7725. doi: 10.1021/acs.inorgchem.5c00760. Epub 2025 Apr 5.

DOI:10.1021/acs.inorgchem.5c00760
PMID:40186563
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12015813/
Abstract

Cobalt(II) carboxylates show broad reactivity with peroxides and O and are the industry standard catalyst for the activation of peroxide initiators for the radical polymerization of alkenes under ambient conditions. Curing alkene-based resins containing cross-linking units, i.e., monomers containing two or more alkene units, is important in forming hard protective coatings and materials. The activation of peroxide initiators produces the propagating chain end radicals needed for polymerization. Since polymerization progress depends on the rate of initiator activation and the concentration of propagating radicals, interception of radicals by O can inhibit curing. Cobalt(II) carboxylates are used due to their reactivity in the presence of oxygen, even in resin coatings. Alternative catalysts based on manganese and iron are desirable. Hence, the impact of O on their performance in resin curing is of interest. Here, we use NIR emission and time-resolved spectroscopy, employing the O-sensitive probe [Ru(phphen)], to determine the concentration of dissolved [O] in alkene resins during curing with three representative catalysts, Co(II)(2-ethylhexanoate), Fe(II)-bispidine, and Mn(II)(neodecanoate). The rate of depletion of O is highly dependent on the catalyst used, but in all cases, it is well before the onset of the autoacceleration of polymerization in cross-linking resins.

摘要

羧酸钴(II)与过氧化物和氧气具有广泛的反应性,是在环境条件下用于烯烃自由基聚合中过氧化物引发剂活化的行业标准催化剂。固化含有交联单元的烯烃基树脂,即含有两个或更多烯烃单元的单体,对于形成坚硬的保护涂层和材料很重要。过氧化物引发剂的活化产生聚合所需的增长链端自由基。由于聚合进程取决于引发剂活化速率和增长自由基的浓度,氧气对自由基的拦截会抑制固化。羧酸钴(II)因其在氧气存在下的反应性而被使用,即使在树脂涂层中也是如此。基于锰和铁的替代催化剂是理想的。因此,氧气对它们在树脂固化中性能的影响备受关注。在这里,我们使用近红外发射和时间分辨光谱,采用对氧气敏感的探针[Ru(phphen)],来测定在用三种代表性催化剂(Co(II)(2-乙基己酸酯)、Fe(II)-联吡啶和Mn(II)(新癸酸酯))固化过程中烯烃树脂中溶解的[O]的浓度。氧气的消耗速率高度依赖于所使用的催化剂,但在所有情况下,都远在交联树脂聚合自动加速开始之前。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/657f/12015813/12d62cc93ff6/ic5c00760_0005.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/657f/12015813/a4ebf96f2668/ic5c00760_0007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/657f/12015813/616dbf016112/ic5c00760_0008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/657f/12015813/77151991128a/ic5c00760_0009.jpg
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本文引用的文献

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