Discrete Miktoarm Star Block Copolymers with Tailored Molecular Architecture

IF 4.7 Q1 POLYMER SCIENCE ACS polymers Au Pub Date : 2023-10-13 DOI:10.1021/acspolymersau.3c00017
Zhuang Ma, Zhongguo Liu, Tianyu Zheng, Zhanhui Gan, Rui Tan* and Xue-Hui Dong*, 
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Abstract

Molecular architecture is a critical factor in regulating phase behaviors of the block copolymer and prompting the formation of unconventional nanostructures. This work meticulously designed a library of isomeric miktoarm star polymers with an architectural evolution from the linear-branched block copolymer to the miktoarm star block copolymer and to the star-like block copolymer (i.e., 3AB → 3(AB1)B2 → 3(AB)). All of the polymers have precise chemical composition and uniform chain length, eliminating inherent molecular uncertainties such as chain length distribution or architectural defects. The self-assembly behaviors were systematically studied and compared. Gradually increasing the relative length of the branched B1 block regulates the ratio between the bridge and loop configuration and effectively releases packing frustration in the formation of the spherical or cylindrical structures, leading to a substantial deflection of phase boundaries. Complex structures, such as Frank–Kasper phases, were captured at a surprisingly higher volume fraction. Rationally regulating the molecular architecture offers rich possibilities to tune the packing symmetry of block copolymers.

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具有定制分子结构的离散 Miktoarm 星型嵌段共聚物
分子结构是调节嵌段聚合物相行为和促使形成非常规纳米结构的关键因素。这项研究精心设计了一个异构米克托臂星型聚合物库,其结构从线性枝状嵌段聚合物演变为米克托臂星型嵌段聚合物,再演变为星型嵌段聚合物(即 3AB → 3(AB1)B2 → 3(AB))。所有聚合物都具有精确的化学成分和均匀的链长,消除了固有的分子不确定性,如链长分布或结构缺陷。我们对其自组装行为进行了系统研究和比较。逐步增加支链 B1 嵌段的相对长度可调节桥形和环形构型之间的比例,并在形成球形或圆柱形结构的过程中有效释放堆积挫折,从而导致相界发生大幅偏移。复杂结构(如弗兰克-卡斯帕相)以惊人的较高体积分数被捕获。合理调节分子结构为调整嵌段共聚物的堆积对称性提供了丰富的可能性。
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