Branches, Tie Chains and Entanglements in Bimodal Polyethylene Single Crystals under Uniaxial Tensile Strain

William S. Fall, Jörg Baschnagel, Hendrik Meyer
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Abstract

Using coarse-grained molecular dynamics simulations and a united-monomer model of PE, single well-aligned multi-lamella PE crystals grown in previous work [ACS Macro Letters 12, 808 (2023)] are deformed uniaxially to mimic tensile testing. During deformation, the crystallinity, tie-chain segments, entanglements and folds are monitored and correlated with the stress-strain behaviour and mechanical properties. At small strains, the single well-aligned PE crystals reveal a larger Young modulus when the deformation direction is perpendicular to the global stem direction. At large strains, the memory of the initial topology plays little role in the mechanical response and is observed to be completely destroyed. Short chain branching appears to suppress disentanglement and shear induced alignment of the chains during deformation. As a result, tie-chains and entanglements persist in branched systems and the peak stress at failure is found to be proportional to the change in number of tie-chains from the beginning of the brittle break to its end. Our findings suggest the remarkable mechanical properties of bimodal branched PE result directly from tie-chains, with entanglements playing a secondary role in the mechanical response.
单轴拉伸应变下双模聚乙烯单晶中的分支、拉链和缠结
利用粗粒度分子动力学模拟和聚乙烯联合分子模型,对先前工作[ACS Macro Letters 12, 808 (2023)]中生长的单个排列整齐的多层聚乙烯晶体进行单轴变形,以模拟拉伸试验。在变形过程中,对结晶度、连接链段、缠结和褶皱进行监测,并将其与应力-应变行为和机械性能联系起来。在小应变下,当变形方向垂直于总杆方向时,排列整齐的单个PE 晶体显示出较大的杨氏模量。在大应变下,初始拓扑结构的记忆在机械响应中几乎不起作用,据观察完全被破坏。短链分支似乎抑制了变形过程中链的解缠和剪切对齐。因此,支化体系中的连接链和纠缠持续存在,并且发现破坏时的峰值应力与从脆断开始到脆断结束的连接链数量变化成正比。我们的研究结果表明,双模支化聚乙烯的显著机械特性直接来自于拉杆链,而缠结在机械响应中起次要作用。
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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