Encapsulation of Inorganic Nanoparticles by Anionic Emulsion Polymerization of Diethyl Methylene Malonate for Developing Hybrid Microparticles with Tailorable Composition

Shreyas Joshi, John Klier, P. Beltramo
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Abstract

Colloidal particle self-assembly into higher-ordered structures has been of great interest due to the promise of creating metamaterials with novel macroscopic properties. The physicochemical properties of these metamaterials can be tailored to achieve composites with tunable functionalities, either by controlling the assembly morphology and/or chemistry of the colloidal building blocks. This work describes a strategy of developing microparticles with a hybrid configuration that have an inorganic and an organic part. The inorganic part comprises functional nanoparticles, which are embedded within an organic polymer particle composed of diethyl methylene malonate polymer [p(DEMM)] prepared using anionic emulsion polymerization. DEMM polymerization is initiated entirely by the presence of hydroxyl anions and the resulting particle diameter can be tuned between 300 nm and 1 micrometer by reaction pH. Inorganic nanoparticles with varying chemistry (TiO2, CdTe, ZnO) can be loaded into the p(DEMM) particle with a controlled weight fraction, as confirmed by thermogravimetric analysis. The colloidal stability of the composite microparticles is seen to be dependent on the ligand coating attached to the inorganic constituent. These results provide a synthetic groundwork for creating hybrid, stimuli-responsive microparticles.
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利用丙二酸二乙酯的阴离子乳液聚合技术封装无机纳米粒子,开发成分可定制的混合微粒
胶体粒子自组装成高阶有序结构一直备受关注,因为它有望创造出具有新型宏观特性的超材料。这些超材料的物理化学特性可以通过控制胶体构件的组装形态和/或化学性质来定制,以实现具有可调功能的复合材料。这项工作介绍了一种开发具有无机和有机混合结构的微颗粒的策略。无机部分由功能纳米粒子组成,这些纳米粒子被嵌入到有机聚合物粒子中,有机聚合物粒子由亚甲基丙二酸二乙酯聚合物[p(DEMM)]组成,采用阴离子乳液聚合法制备。DEMM 聚合完全是由羟基阴离子的存在引发的,由此产生的颗粒直径可通过反应 pH 值在 300 纳米到 1 微米之间进行调节。经热重分析证实,不同化学性质的无机纳米粒子(TiO2、CdTe、ZnO)可以以可控的重量分数加入 p(DEMM) 颗粒中。复合微颗粒的胶体稳定性取决于附着在无机成分上的配体涂层。这些结果为创造具有刺激响应性的混合微粒提供了合成基础。
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