The crystallization of low-density polyethylene: A molecular dynamics simulation

Xiu bin Zhang; Ze sheng Li; Zhong yuan Lu; Chia Chung Sun

doi:10.1016/S0032-3861(02)00126-X

The crystallization of low-density polyethylene: A molecular dynamics simulation

Xiu bin Zhang, Ze sheng Li^*, Zhong yuan Lu, Chia Chung Sun

^*Corresponding author for this work

Jilin University

Research output: Contribution to journal › Article › peer-review

24 Citations (Scopus)

Abstract

Three models (star-shaped, H-shaped, and comb-shaped polyethylenes) are used to study the crystallization behavior of low-density polyethylene at the molecular level by means of molecular dynamics simulation. It is shown that, for the three types of polyethylene corresponding to the models, the neighboring sequences of trans bonds firstly aggregate together to form local ordered domains, and then they coalesce to a lamellar structure. In the process, the branching sites are rejected to the fold surface gradually. The driving force for the relaxation process is the attractive van der Waals interaction between the chain segments. Furthermore, it is found that the number of the branch sites and the length of the branch play an important role in determining the formation of the lamellar structure. The longer the length of the branch and the fewer the number of the branch sites, the more perfect lamellar structure can be formed.

Original language	English
Pages (from-to)	3223-3227
Number of pages	5
Journal	Polymer
Volume	43
Issue number	11
DOIs	https://doi.org/10.1016/S0032-3861(02)00126-X
Publication status	Published - 4 Apr 2002
Externally published	Yes

Keywords

Long branching
Molecular dynamics simulation
Polyethylene

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10.1016/S0032-3861(02)00126-X

Cite this

Zhang, X. B., Li, Z. S., Lu, Z. Y., & Sun, C. C. (2002). The crystallization of low-density polyethylene: A molecular dynamics simulation. Polymer, 43(11), 3223-3227. https://doi.org/10.1016/S0032-3861(02)00126-X

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abstract = "Three models (star-shaped, H-shaped, and comb-shaped polyethylenes) are used to study the crystallization behavior of low-density polyethylene at the molecular level by means of molecular dynamics simulation. It is shown that, for the three types of polyethylene corresponding to the models, the neighboring sequences of trans bonds firstly aggregate together to form local ordered domains, and then they coalesce to a lamellar structure. In the process, the branching sites are rejected to the fold surface gradually. The driving force for the relaxation process is the attractive van der Waals interaction between the chain segments. Furthermore, it is found that the number of the branch sites and the length of the branch play an important role in determining the formation of the lamellar structure. The longer the length of the branch and the fewer the number of the branch sites, the more perfect lamellar structure can be formed.",

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T2 - A molecular dynamics simulation

AU - Zhang, Xiu bin

AU - Li, Ze sheng

AU - Lu, Zhong yuan

AU - Sun, Chia Chung

PY - 2002/4/4

Y1 - 2002/4/4

N2 - Three models (star-shaped, H-shaped, and comb-shaped polyethylenes) are used to study the crystallization behavior of low-density polyethylene at the molecular level by means of molecular dynamics simulation. It is shown that, for the three types of polyethylene corresponding to the models, the neighboring sequences of trans bonds firstly aggregate together to form local ordered domains, and then they coalesce to a lamellar structure. In the process, the branching sites are rejected to the fold surface gradually. The driving force for the relaxation process is the attractive van der Waals interaction between the chain segments. Furthermore, it is found that the number of the branch sites and the length of the branch play an important role in determining the formation of the lamellar structure. The longer the length of the branch and the fewer the number of the branch sites, the more perfect lamellar structure can be formed.

AB - Three models (star-shaped, H-shaped, and comb-shaped polyethylenes) are used to study the crystallization behavior of low-density polyethylene at the molecular level by means of molecular dynamics simulation. It is shown that, for the three types of polyethylene corresponding to the models, the neighboring sequences of trans bonds firstly aggregate together to form local ordered domains, and then they coalesce to a lamellar structure. In the process, the branching sites are rejected to the fold surface gradually. The driving force for the relaxation process is the attractive van der Waals interaction between the chain segments. Furthermore, it is found that the number of the branch sites and the length of the branch play an important role in determining the formation of the lamellar structure. The longer the length of the branch and the fewer the number of the branch sites, the more perfect lamellar structure can be formed.

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The crystallization of low-density polyethylene: A molecular dynamics simulation

Abstract

Keywords

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