分子动力学和第一性原理计算研究分子链长度和分子链缠结对非晶态聚乙烯强度的影响

IF 0.3 4区 工程技术 Q4 MATERIALS SCIENCE, TEXTILES Journal of Fiber Science and Technology Pub Date : 2020-08-15 DOI:10.2115/fiberst.2020-0031
K. Naito, Y. Ochiai, Rei Tsuboi, Kohei Nimura, K. Yashiro
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引用次数: 0

摘要

为了全面研究从分子链形态(长度和缠结)对聚乙烯强度的影响到其断裂机理,采用低分子量非晶态聚乙烯进行了单轴张力的分子动力学模拟,并采用亚甲基三聚体进行了单轴张力的第一性原理计算。结果发现,当分子质量为纠缠分子量的两倍时,分子链不能形成网状结构。化学键拉伸对应力的影响最大,而范德华力对应力的影响为负,且在分子量较低时影响更大。此外,还发现在达到最大应力后应力的减小是由于分子链的滑动,因为分子链不会因张力而断裂。此外,最大应力随分子链越长而增加,这是因为缠结点对张力起着阻力作用,而且分子链越长,缠结点的数量越多。从以上结果可知,缠结对应力起正作用,范德华力起负作用,分子链的缠结对聚乙烯的强度有较大的影响。
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Study by Molecular Dynamics and First-Principles Calculation on the Influence of Length of Molecular Chain and Entanglement of Molecular Chains on the Strength of Amorphous Polyethylene
: In order to comprehensively investigate from the effects of the morphology (length and entanglement) of the molecular chain on the strength of polyethylene to its fracture mechanism, molecular dynamics simulation of uniaxial tension using low molecular weight amorphous polyethylene and first-principles calculation of uniaxial tension using methylene trimer were performed. As a result, it was found that when the molecular weight is twice the entanglement molecular weight, the molecular chains can not form a network structure. And the bond stretch had the greatest effect on stress, in contrast, the van der Waals force had negative effect on stress and the effect was larger at lower molecular weights. In addition, it is also found that the decrease in stress after reaching the maximum stress is due to slipping of the molecular chains because the molecular chains donʼt break due to tension. Furthermore, the maximum stress increased with the longer the molecular chain because the entanglement point acted as a resistive force against the tension and because the longer the molecular chain, the higher the number of entanglement points. From the above results, it was clarified that the entanglement works positively for stress, the van der Waals force works negatively, and the entanglement of the molecular chains has a large effect on the strength of polyethylene.
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来源期刊
Journal of Fiber Science and Technology
Journal of Fiber Science and Technology Materials Science-Materials Science (miscellaneous)
CiteScore
0.50
自引率
0.00%
发文量
17
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