Mechanism of emulsion polymerization

Journal of Polymer Science: Polymer Symposia Pub Date : 1985-01-01 DOI:10.1002/polc.5070720121

John W. Vanderhoff

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引用次数: 47

Abstract

Both conventional and inverse emulsion polymerization comprise the emulsification of an immiscible monomer in a continuous medium followed by polymerization with a free radical initiator to give a colloidal sol of polymer particles. Both processes give “emulsion polymerization kinetics,” i.e., a proportionality of both the polymerization rate and polymer molecular weight to the number of particles instead of the inverse relationship between rate and molecular weight observed for mass, solution, and suspension polymerization. The emulsion polymerization process can be divided into particle nucleation and particle growth stages and can be carried out using batch, semicontinuous, or continuous processes. Seeded emulsion polymerization can be used to avoid the particle nucleation stage in all three processes. The many mechanisms proposed for the initiation of emulsion polymerization can be divided into four categories according to the locus of particle initiation: (i) monomer-swollen micelles; (ii) adsorbed emulsifier layer; (iii) aqueous phase; (iv) monomer droplets. These general principles are applied to: (i) the preparation of monodisperse latexes by seeded emulsion polymerization; (ii) the locus of particle initiation for various monomers and initiators; (iii) emulsion copolymerization; (iv) core-shell emulsion copolymerization; (v) polymerization in fine monomer droplets; (vi) inverse emulsion polymerization.

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乳液聚合机理

常规和反相乳液聚合都包括在连续介质中不混溶单体的乳化，然后用自由基引发剂聚合以得到聚合物颗粒的胶体溶胶。这两种过程都给出了“乳液聚合动力学”，即聚合速率和聚合物分子量与颗粒数量成正比，而不是在质量、溶液和悬浮聚合中观察到的速率和分子量之间的反比关系。乳液聚合过程可分为颗粒成核和颗粒生长阶段，可采用间歇、半连续或连续过程进行。种子乳液聚合可以避免这三个过程中的颗粒成核阶段。根据颗粒的起始位置，乳液聚合的起始机制可分为四类:(1)单体膨胀胶束;(ii)吸附乳化剂层;(iii)水相;(iv)单体液滴。这些一般原则适用于:(i)通过种子乳液聚合制备单分散乳胶;(ii)各种单体和引发剂的粒子起始轨迹;(iii)乳液共聚;(iv)核-壳乳液共聚;(v)细单体液滴聚合;反相乳液聚合。

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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Journal of Polymer Science: Polymer Symposia

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