Mesoscale modeling of random chain scission in polyethylene melts

Arefin Mustafa Anik, Vaibhav Palkar, Igor Luzinov and Olga Kuksenok
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Abstract

Polyolefins account for more than half of global primary polymer production, however only a small fraction of these polymers are currently being recycled. Fragmentation of polymer chains into shorter chains with a targeted molecular weight distribution with the goal of reusing these fragments in subsequent chemical synthesis can potentially introduce an alternative approach to polyolefins recycling. Herein we develop a mesoscale framework to model degradation of polyethylene melts at a range of high temperatures. We use the dissipative particle dynamics approach with modified segmental repulsive potential to model the process of random scission in melts of linear polymer chains. We characterize the fragmentation process by tracking the time evolution of the distribution of degrees of polymerization of chain fragments. Specifically, we track the weight average and the number average degrees of polymerization and dispersity of polymer fragments as a function of the fraction of bonds broken. Furthermore, we track the number fraction distribution and the weight fraction distribution of polymer fragments with various degrees of polymerization as functions of the fraction of bonds broken for a range of high temperatures. Our results allow one to quantify to what extent the distribution of polymer chain fragments during random scission can be captured by the respective analytical distributions for the range of conversions considered. Understanding the thermal degradation of polyolefins on the mesoscale can result in the development of alternative strategies for recycling a range of thermoplastics.
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聚乙烯熔体中无规链裂解的中尺度建模
聚烯烃占全球初级聚合物产量的一半以上,但目前只有一小部分聚合物被回收利用。将聚合物链破碎成具有目标分子量分布的短链,以便在后续化学合成中重复使用这些碎片,有可能为聚烯烃的回收利用提供另一种方法。在此,我们开发了一个中尺度框架,用于模拟聚乙烯熔体在一系列高温下的降解过程。我们使用耗散粒子动力学方法和改进的分段排斥势来模拟线性聚合物链熔体中的随机分裂过程。我们通过跟踪链片段聚合度分布的时间演变来描述分裂过程。具体来说,我们跟踪聚合物片段聚合度和分散度的重量平均值和数量平均值与断裂键数的函数关系。此外,我们还跟踪了不同聚合度的聚合物片段的数量分数分布和重量分数分布,它们是一系列高温下断裂键分数的函数。通过我们的研究结果,我们可以量化随机裂解过程中聚合物链片段的分布在多大程度上可以被所考虑的转换范围内的相应分析分布所捕获。在中观尺度上了解聚烯烃的热降解,可以为一系列热塑性塑料的回收利用制定替代策略。
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