生物聚合物混合物的相容:综述

IF 9.9 Q1 MATERIALS SCIENCE, COMPOSITES Advanced Industrial and Engineering Polymer Research Pub Date : 2023-11-14 DOI:10.1016/j.aiepr.2023.11.002
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引用次数: 0

摘要

来自可再生生物资源的生物聚合物为石油衍生塑料提供了一种可持续的替代品,但其脆性和成本等局限性限制了其适用性。混合提供了一条经济实惠的途径,可将不同生物聚合物的优势结合起来,实现量身定制的性能。然而,大多数生物聚合物对本质上是不相溶的,因此必须进行相容,以获得最佳的共混形态、界面相互作用和性能。本综述总结了在定制生物聚合物共混物方面的主要相容策略和最新进展。使用嵌段共聚物或接枝共聚物的非反应性技术可提高相容性,但性能提升通常不大。更有影响的是反应性方法,即在熔融混合过程中就地官能化并形成相容性共聚物。纳米粒子的加入也能通过界面定位和形态控制有效地实现相容性。通过这些策略,聚乳酸(PLA)和其他脆性生物聚酯与韧性聚合物(如聚己二酸丁二醇酯-共对苯二甲酸酯(PBAT))或弹性体(如天然橡胶)共混后,可实现显著的增韧和相容。适当相容的聚乳酸共混物在伸长率、强度和抗冲击性方面同时有很大的改善。使用廉价的淀粉可降低成本,但需要进行相容处理以保持足够的性能。此外,纳米颗粒还具有阻隔和阻燃等功能。然而,将相互作用、加工、形态和性能定量地联系起来将有助于进一步优化共混物。开发量身定制的活性化学物质和纳米粒子具有超越传统技术的潜力,而保持生物降解性也至关重要。总之,相容促进了互补性生物聚合物的协同性能组合,为各种应用领域提供了环保、高性能和高成本效益的传统塑料替代品。
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Compatibilization of biopolymer blends: A review

Biopolymers from renewable bio-based resources provide a sustainable alternative to petroleum-derived plastics, but limitations like brittleness and cost restrict applicability. Blending offers an affordable route to combine the advantages of different biopolymers for tailored performance. However, most biopolymer pairs are intrinsically immiscible, necessitating compatibilization to obtain optimal blend morphology, interfacial interaction, and properties. This review summarizes key compatibilization strategies and recent advances in tailoring biopolymer blends. Non-reactive techniques using block or graft copolymers can increase compatibility, though property enhancements are often modest. More impactful are reactive methods, which functionalize and form compatibilizing copolymers in-situ during melt-blending. Nanoparticle incorporation also effectively compatibilizes through interface localization and morphology control. These strategies enable significant toughening and compatibilization of poly(lactic acid) (PLA) and other brittle biopolyesters by blending with ductile polymers such as poly(butylene adipate-co-terephthalate)((PBAT) or elastomers like natural rubber. Properly compatibilized PLA blends exhibit major simultaneous improvements in elongation, strength, and impact resistance. Using inexpensive starch decreases cost but requires compatibilization to maintain adequate properties. Nanoparticles additionally impart functionality like barrier and flame retardance. However, quantitatively correlating interaction, processing, morphology, and properties will enable further blend optimization. Developing tailored reactive chemistries and nanoparticles offers potential beyond conventional techniques, and retaining biodegradability is also crucial. Overall, compatibilization facilitates synergistic property combinations from complementary biopolymers, providing eco-friendly, high-performance, and cost-effective alternatives to traditional plastics across diverse applications.

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来源期刊
Advanced Industrial and Engineering Polymer Research
Advanced Industrial and Engineering Polymer Research Materials Science-Polymers and Plastics
CiteScore
26.30
自引率
0.00%
发文量
38
审稿时长
29 days
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