可生物降解嵌段共聚物增强PLA/PCL共混相容性的结构效应：分子动力学模拟

IF 5.2 1区化学 Q1 POLYMER SCIENCE

Macromolecules Pub Date : 2025-04-03 DOI:10.1021/acs.macromol.5c0015810.1021/acs.macromol.5c00158

Orrasa Prasitnok, and , Khongvit Prasitnok*,

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引用次数: 0

摘要

我们采用分子动力学模拟研究了聚乳酸(PLA)-、聚己内酯(PCL)-和聚乙二醇（PEG）基可生物降解共聚物作为PLA/PCL共混物增容剂的效率。系统地设计和研究了具有不同嵌段序列的二嵌段和三嵌段共聚物。结果表明，共聚物的嵌段类型和结构对共聚物的增容效率起着至关重要的作用。具体来说，我们在链端具有PLA嵌段的无纠缠共聚物，特别是三嵌段结构，在PLA和PCL均聚物相中都表现出良好的定位。这种局部化增强了相间相互作用，提高了共混物的熔体拉伸性能。相反，链端有PCL嵌段的共聚物，尤其是三嵌段结构的共聚物，倾向于优先定位在PCL相中，导致增容效果较差。这些见解可以为开发量身定制的增容剂铺平道路，以优化非混相聚合物共混物的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Architectural Effects of Biodegradable Block Copolymers on Enhancing PLA/PCL Blend Compatibility: Molecular Dynamics Simulations

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Architectural Effects of Biodegradable Block Copolymers on Enhancing PLA/PCL Blend Compatibility: Molecular Dynamics Simulations

We employed molecular dynamics simulations to investigate the efficiency of polylactic acid (PLA)-, poly(caprolactone) (PCL)-, and poly(ethylene glycol) (PEG)-based biodegradable copolymers as compatibilizers in PLA/PCL blends. Di- and triblock copolymers with various block sequences were systematically designed and studied. The findings reveal that the block type and architecture of the copolymers play a crucial role in determining their compatibilization efficiency. Specifically, our unentangled copolymers with PLA blocks at the chain ends, particularly triblock structures, exhibit good localization within both PLA and PCL homopolymer phases. This localization enhances interphase interactions and improves the melt tensile performance of the blends. In contrast, copolymers with PCL blocks at the chain ends, especially triblock architectures, tend to localize preferentially within the PCL phase, leading to less effective compatibilization. These insights could pave the way for the development of tailored compatibilizers to optimize the properties of immiscible polymer blends.

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来源期刊

Macromolecules 工程技术-高分子科学

CiteScore

9.30

自引率

16.40%

发文量

942

审稿时长

2 months

期刊介绍： Macromolecules publishes original, fundamental, and impactful research on all aspects of polymer science. Topics of interest include synthesis (e.g., controlled polymerizations, polymerization catalysis, post polymerization modification, new monomer structures and polymer architectures, and polymerization mechanisms/kinetics analysis); phase behavior, thermodynamics, dynamic, and ordering/disordering phenomena (e.g., self-assembly, gelation, crystallization, solution/melt/solid-state characteristics); structure and properties (e.g., mechanical and rheological properties, surface/interfacial characteristics, electronic and transport properties); new state of the art characterization (e.g., spectroscopy, scattering, microscopy, rheology), simulation (e.g., Monte Carlo, molecular dynamics, multi-scale/coarse-grained modeling), and theoretical methods. Renewable/sustainable polymers, polymer networks, responsive polymers, electro-, magneto- and opto-active macromolecules, inorganic polymers, charge-transporting polymers (ion-containing, semiconducting, and conducting), nanostructured polymers, and polymer composites are also of interest. Typical papers published in Macromolecules showcase important and innovative concepts, experimental methods/observations, and theoretical/computational approaches that demonstrate a fundamental advance in the understanding of polymers.