嵌段共聚物颗粒的动力学和平衡机制

IF 4.7 Q1 POLYMER SCIENCE ACS polymers Au Pub Date : 2022-08-23 DOI:10.1021/acspolymersau.2c00033
Timothy P. Lodge*, Claire L. Seitzinger, Sarah C. Seeger, Sanghee Yang, Supriya Gupta and Kevin D. Dorfman, 
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引用次数: 14

摘要

嵌段共聚物自组装成有趣而有用的纳米结构,无论是在溶液中还是在体中,都是一个充满活力的研究领域。虽然人们对平衡相的表征和预测给予了很大的关注,但相关的动态过程还远远没有完全理解。在这里,我们探讨了什么是已知的和不知道的平衡颗粒相在体,并在溶液中的球形胶束。假定的主要平衡机制是链交换、融合和断裂。这些过程在表面活性剂和脂质中被广泛研究,它们发生在亚秒的时间尺度上。相反,嵌段共聚物中增加的链长会产生更大的屏障,并且时间尺度会变得非常缓慢。在实践中,嵌段共聚物的平衡只有在接近临界胶束温度(溶液中)或有序-无序转变(体中)时才能实现。关于嵌段共聚物中这些过程的详细理论很少。在整体中,链交换速率可以通过示踪剂扩散测量来量化。从粒子的数目密度和聚集数目来看,平衡的速度往往比链交换慢得多,因此观察到的粒子相往往是亚稳态的。在相图中Frank-Kasper相出现的区域尤其如此。用时间分辨SANS定量地研究了溶液中的链交换,但理论不能很好地捕获结果。计算机模拟,特别是通过耗散粒子动力学,开始揭示分子水平上的链逃逸机制。在一些实验系统中,碎片的速率已经被量化,透射电镜图像支持一种类似于细胞有丝分裂后期的机制,通过一个细颈夹断产生两个较小的胶束。直接测量胶束融合是相当罕见的。对今后的理论、计算和实验工作提出了建议。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Dynamics and Equilibration Mechanisms in Block Copolymer Particles

Self-assembly of block copolymers into interesting and useful nanostructures, in both solution and bulk, is a vibrant research arena. While much attention has been paid to characterization and prediction of equilibrium phases, the associated dynamic processes are far from fully understood. Here, we explore what is known and not known about the equilibration of particle phases in the bulk, and spherical micelles in solution. The presumed primary equilibration mechanisms are chain exchange, fusion, and fragmentation. These processes have been extensively studied in surfactants and lipids, where they occur on subsecond time scales. In contrast, increased chain lengths in block copolymers create much larger barriers, and time scales can become prohibitively slow. In practice, equilibration of block copolymers is achievable only in proximity to the critical micelle temperature (in solution) or the order–disorder transition (in the bulk). Detailed theories for these processes in block copolymers are few. In the bulk, the rate of chain exchange can be quantified by tracer diffusion measurements. Often the rate of equilibration, in terms of number density and aggregation number of particles, is much slower than chain exchange, and consequently observed particle phases are often metastable. This is particularly true in regions of the phase diagram where Frank–Kasper phases occur. Chain exchange in solution has been explored quantitatively by time-resolved SANS, but the results are not well captured by theory. Computer simulations, particularly via dissipative particle dynamics, are beginning to shed light on the chain escape mechanism at the molecular level. The rate of fragmentation has been quantified in a few experimental systems, and TEM images support a mechanism akin to the anaphase stage of mitosis in cells, via a thin neck that pinches off to produce two smaller micelles. Direct measurements of micelle fusion are quite rare. Suggestions for future theoretical, computational, and experimental efforts are offered.

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