Interplay between entanglement and crosslinking in determining mechanical behaviors of polymer networks

IF 4.5 3区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Yuhao Liu, Weikang Xian, Jinlong He, Ying Li
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Abstract

In polymer physics, the concept of entanglement refers to the topological constraints between long polymer chains that are closely packed together. Both theory and experimentation suggest that entanglement has a significant influence on the mechanical properties of polymers. This indicates its promise for materials design across various applications. However, understanding the relationship between entanglement and mechanical properties is complex, especially due to challenges related to length scale constraints and the difficulties of direct experimental observation. This research delves into how the polymer network structure changes when deformed. We specifically examine the relationship between entanglement, crosslinked networks, and their roles in stretching both entangled and unentangled polymer systems. For unentangled polymers, our findings underscore the pivotal role of crosslinking bond strength in determining the system’s overall strength and resistance to deformation. As for entangled polymers, entanglement plays a pivotal role in load bearing during the initial stretching stage, preserving the integrity of the polymer network. As the stretching continues and entanglement diminishes, the responsibility for bearing the load increasingly shifts to the crosslinking network, signifying a critical change in the system’s behavior. We noted a linear correlation between the increase in entanglement and the rise in tensile stress during the initial stretching stage. Conversely, the destruction of the network correlates with a decrease in tensile stress in the later stage. The findings provide vital insights into the complex dynamics between entanglement and crosslinking in the stretching processes of polymer networks, offering valuable guidance for future manipulation and design of polymer materials to achieve desired mechanical properties.
缠结和交联在决定聚合物网络力学行为中的相互作用
在聚合物物理学中,缠结的概念是指紧密排列在一起的长聚合物链之间的拓扑约束。理论和实验都表明,缠结对聚合物的力学性能有重要影响。这表明了它在各种应用中的材料设计前景。然而,理解缠结和力学性能之间的关系是复杂的,特别是由于长度尺度限制和直接实验观察的困难。本研究探讨了聚合物网络结构在变形时的变化规律。我们特别研究了纠缠、交联网络之间的关系,以及它们在拉伸纠缠和非纠缠聚合物系统中的作用。对于未纠缠的聚合物,我们的研究结果强调了交联键强度在决定体系整体强度和抗变形能力方面的关键作用。对于缠结的聚合物,缠结在初始拉伸阶段的承载中起着关键作用,保持了聚合物网络的完整性。随着拉伸的继续和缠结的减少,承担载荷的责任越来越多地转移到交联网络,这标志着系统行为的关键变化。我们注意到,在初始拉伸阶段,缠结的增加与拉伸应力的上升之间存在线性相关。相反,网络的破坏与后期拉应力的降低相关。这些发现为聚合物网络拉伸过程中纠缠和交联之间的复杂动力学提供了重要的见解,为未来操作和设计聚合物材料提供了有价值的指导,以实现所需的机械性能。
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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来源期刊
International Journal of Smart and Nano Materials
International Journal of Smart and Nano Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
6.30
自引率
5.10%
发文量
39
审稿时长
11 weeks
期刊介绍: The central aim of International Journal of Smart and Nano Materials is to publish original results, critical reviews, technical discussion, and book reviews related to this compelling research field: smart and nano materials, and their applications. The papers published in this journal will provide cutting edge information and instructive research guidance, encouraging more scientists to make their contribution to this dynamic research field.
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