Quantitatively unravel the effect of chain length heterogeneity on polymer crystallization using discrete oligo l-lactide

As one of the most fundamental features of synthetic polymer, molecular weight distribution profoundly influences the structures and properties. In this work, chain length heterogeneity was precisely regulated by a reconstruction approach using a library of discrete oligol-lactide (oLLA). Crystalliz...

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Bibliographic Details
Published in:Polymer (Guilford) 2021-05, Vol.225, p.123746, Article 123746
Main Authors: Zhou, Dongdong, Xu, Miao, Tan, Rui, Sun, Yanxiao, Ma, Zhuang, Li, Jinbin, Dong, Xue-Hui
Format: Article
Language:English
Subjects:
Chain length heterogeneity
Crystallization
Crystals
Discrete oligo (l-lactic acid)
Growth kinetics
Heterogeneity
Molecular weight
Molecular weight distribution
Nucleation
Polymers
Supercooling
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Summary:As one of the most fundamental features of synthetic polymer, molecular weight distribution profoundly influences the structures and properties. In this work, chain length heterogeneity was precisely regulated by a reconstruction approach using a library of discrete oligol-lactide (oLLA). Crystallization of a series of binary blends were systemically investigated. At a specific crystallization temperature, each fraction experiences varied degrees of supercooling, leading to non-uniform nucleation and growth kinetics. Both oLLA fractions co-crystallize homogeneously when chain length heterogeneity is not significant, while partial segregation occurs when the difference is sufficiently large. The co-crystals consisting of non-uniform chains are metastable, which rearrange into a homo-crystal of longer chains by excluding the shorter components upon heating. This work highlights the profound contribution of chain length heterogeneity on crystallization, which not only provides insights into the importance of molecular weight distribution, but also bridges the intrinsic gap between discrete and disperse polymers. [Display omitted] •Discrete Polymers.•Chain Length Heterogeneity Regulation.•Crystallization Behaviors.
ISSN:0032-3861
1873-2291
DOI:10.1016/j.polymer.2021.123746