Bio-based semi-interpenetrating networks with nanoscale morphology and interconnected microporous structure

IF 3.3 Q3 NANOSCIENCE & NANOTECHNOLOGY
Samy Madboul
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引用次数: 0

Abstract

Creating new bio-based sustainable polymeric materials with similar or better performance than the petroleum-based counterparts  has recently received considerable attention. It will have a significant positive impact on the environment and the sustainable polymer industry. This review article shows a relatively new method based on simultaneous in-situ polymerization and compatibilization of bio-based plant oil and biodegradable thermoplastic polymer to prepare semi-interpenetrating polymer networks (SINs) with unusual nano-scale morphology and interconnected porous structure will be summarized. The SINs were synthesized via cationic polymerization of tung oil in a homogenous solution of poly(ε-caprolactone) as a biodegradable, semi-crystalline, and biocompatible thermoplastic polymer. The degrees of miscibility, nanostructure morphology, and crystallinity was found to be composition-dependent. This relatively new blending method created  a two-phase nanoscale morphology as small as 100 nm for blends with PCL contents of 20 and 30 wt.%. For higher PCL contents (e.g., 50 wt.% PCL blend), a co-continuous, interconnected microscale two-phase morphology was detected. The microporous structure of the SINs was also changed as a function of composition. For example, the interconnectivity and pore size was considerably decreased with increasing PCL content. Furthermore, a considerable decrease in the crystallization kinetics of PCL was observed as the PCL content is higher than or equal to 30 wt.%. While on the other hand, the crystallization kinetics accelerated significantly for 50 wt.%. This novel, low-cost strategy for preparing bio-based SINs with nanoscale morphology and interconnected three-dimensional cluster structures and desired properties should be widely used for creating new polymer systems.
具有纳米形态和微孔结构的生物基半互穿网络
创造与石油基材料性能相似或更好的新型生物基可持续聚合物材料最近受到了相当大的关注。它将对环境和可持续聚合物工业产生重大的积极影响。本文综述了一种基于生物基植物油和可生物降解的热塑性聚合物同时原位聚合和相容的新方法,以制备具有不同寻常的纳米级形态和互联多孔结构的半互穿聚合物网络(SINs)。以桐油为原料,在聚ε-己内酯均相溶液中进行阳离子聚合,合成了具有生物可降解、半结晶性和生物相容性的热塑性聚合物。混溶度、纳米结构形态和结晶度与组分有关。这种相对较新的共混方法为PCL含量为20%和30wt .%的共混物创造了小至100 nm的两相纳米级形貌。对于较高的PCL含量(例如,50wt .% PCL共混物),检测到共连续,相互连接的微尺度两相形态。微孔结构也随着组成的变化而变化。例如,随着PCL含量的增加,连通性和孔径显著降低。此外,当PCL含量高于或等于30wt .%时,观察到PCL的结晶动力学显著下降。另一方面,结晶动力学在50 wt.%时显著加速。这种新颖、低成本的方法可以制备具有纳米级形态、相互连接的三维团簇结构和所需性能的生物基SINs,应该广泛用于创建新的聚合物体系。
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
Nanofabrication
Nanofabrication NANOSCIENCE & NANOTECHNOLOGY-
自引率
10.30%
发文量
13
审稿时长
16 weeks
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