Microstructure and Performance Evolution of Poly(l-Lactic Acid) during Physical Aging: Effect of Molecular Weight

IF 5.4 2区化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biomacromolecules Pub Date : 2025-10-01 DOI:10.1021/acs.biomac.5c01668

Zhi-xuan Zhang, , , Chao-qun Wu, , , Yi-fan Zha, , , De-xiang Sun*, , , Xiao-dong Qi, , , Jing-hui Yang, , and , Yong Wang*,

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Abstract

With the growing public awareness of environmental protection, poly(l-lactic acid) (PLLA) has started to establish a presence across various industries. However, the inevitable physical aging of PLLA products leads to substantial alterations in both microstructural evolution and macroscopic properties. Therefore, it is essential to conduct an in-depth discussion of the underlying mechanism associated with physical aging. As an intrinsic parameter of PLLA, the mechanism by which molecular weight influences physical aging remains to be clarified. In this article, the regulatory mechanism of molecular weight over the physical aging timeline in PLLA is elucidated according to the cohesional entanglement theory. The ″growth process″ of cohesional entanglements within the high-molecular-weight sample system is inhibited, leading to a decrease in the effective number of such structures, which is manifested as a delay in physical aging behavior. Moreover, the effect of molecular weight on the physical aging exhibits a nonlinear increase, and a ″saturation effect″ is observed. This work provides a theoretical basis for elucidating the regulatory mechanism of molecular weight on the physical aging behavior of PLLA.

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物理老化过程中聚l-乳酸的微观结构与性能演变：分子量的影响

随着公众环保意识的增强，聚l-乳酸（PLLA）开始在各个行业中崭露头角。然而，PLLA产品不可避免的物理老化导致微观组织演变和宏观性能的实质性变化。因此，有必要深入探讨与物理老化相关的潜在机制。分子量作为聚乳酸的固有参数，其影响物理老化的机理尚不清楚。本文根据内聚缠结理论，阐述了分子量对聚乳酸物理老化时间线的调控机制。高分子量样品体系内黏结缠结的″生长过程″受到抑制，导致黏结缠结的有效数量减少，表现为物理老化行为的延迟。此外，分子量对物理老化的影响呈非线性增加，并存在″饱和效应″。本研究为阐明分子量对聚乳酸物理老化行为的调控机制提供了理论基础。

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来源期刊

Biomacromolecules 化学-高分子科学

CiteScore

10.60

自引率

4.80%

发文量

417

审稿时长

1.6 months

期刊介绍： Biomacromolecules is a leading forum for the dissemination of cutting-edge research at the interface of polymer science and biology. Submissions to Biomacromolecules should contain strong elements of innovation in terms of macromolecular design, synthesis and characterization, or in the application of polymer materials to biology and medicine. Topics covered by Biomacromolecules include, but are not exclusively limited to: sustainable polymers, polymers based on natural and renewable resources, degradable polymers, polymer conjugates, polymeric drugs, polymers in biocatalysis, biomacromolecular assembly, biomimetic polymers, polymer-biomineral hybrids, biomimetic-polymer processing, polymer recycling, bioactive polymer surfaces, original polymer design for biomedical applications such as immunotherapy, drug delivery, gene delivery, antimicrobial applications, diagnostic imaging and biosensing, polymers in tissue engineering and regenerative medicine, polymeric scaffolds and hydrogels for cell culture and delivery.