纳米结构三嵌段共聚物机械化学活化的计算研究

IF 4.7 Q1 POLYMER SCIENCE
Zijian Huo, Stephen J Skala, Lavinia R Falck, Jennifer E Laaser and Antonia Statt*, 
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引用次数: 5

摘要

力驱动的化学反应已经成为聚合物材料中各种应用的一个有吸引力的平台。然而,有效地将宏观力传递到分子尺度所需的微观链构象和拓扑结构尚未得到很好的理解。在这项工作中,我们使用粗粒度模型来研究类网络拓扑结构对自组装三嵌段共聚物机械化学活化的影响。我们发现拉伸变形过程中的机械化学活化在很大程度上取决于这些材料中的聚合物组成和链构象。激活主要发生在连接不同玻璃结构域的领带链和通过物理纠缠相互连接的环链中。在具有较高玻璃块含量的材料中,活化也需要较高的应力。总的来说,片层样品在高应力下的活化率最高。相反,在低应力下,具有最低玻璃化分数的球形形貌表现出最高的活化。此外,我们观察到激活的空间模式,这似乎与自组装形态的扭曲有关。在层状试样变形过程中形成的线形的尖端以及圆柱体之间的中心处观察到较高的活化。我们的工作表明,不同形态的网状拓扑结构的变化显著影响了这些材料的机械化学激活效率,这表明该领域将为进一步的实验研究提供富有成效的途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Computational Study of Mechanochemical Activation in Nanostructured Triblock Copolymers

Computational Study of Mechanochemical Activation in Nanostructured Triblock Copolymers

Force-driven chemical reactions have emerged as an attractive platform for diverse applications in polymeric materials. However, the microscopic chain conformations and topologies necessary for efficiently transducing macroscopic forces to the molecular scale are not well-understood. In this work, we use a coarse-grained model to investigate the impact of network-like topologies on mechanochemical activation in self-assembled triblock copolymers. We find that mechanochemical activation during tensile deformation depends strongly on both the polymer composition and chain conformation in these materials. Activation primarily occurs in the tie chains connecting different glassy domains and in loop chains that are hooked onto each other by physical entanglements. Activation also requires a higher stress in materials having a higher glassy block content. Overall, the lamellar samples show the highest percent activation at high stress. In contrast, at low stress, the spherical morphology, which has the lowest glassy fraction, shows the highest activation. Additionally, we observe a spatial pattern of activation, which appears to be tied to distortion of the self-assembled morphology. Higher activation is observed in the tips of the chevrons formed during deformation of lamellar samples as well as in the centers between the cylinders in the cylindrical morphology. Our work shows that changes in the network-like topology in different morphologies significantly impact mechanochemical activation efficiencies in these materials, suggesting that this area will be a fruitful avenue for further experimental research.

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CiteScore
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