2010
DOI: 10.1021/ma1017555
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Melt Structure and Dynamics of Unentangled Polyethylene Rings: Rouse Theory, Atomistic Molecular Dynamics Simulation, and Comparison with the Linear Analogues

Abstract: Atomistic configurations of model unentangled ring polyethylene (PE) melts ranging in chain length from C 24 up to C 400 have been subjected to detailed molecular dynamics (MD) simulations in the isothermal-isobaric statistical ensemble at temperature T = 450 K and P = 1 atm. Strictly monodisperse samples were employed in all cases. We present and discuss in detail simulation results for a variety of structural, thermodynamic, conformational and dynamic properties of these systems, and their variation with cha… Show more

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Cited by 120 publications
(191 citation statements)
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“…These theories make use of the fact that linear chains have free ends but ring polymers do not have free ends so the application of these theories, and especially reptation theory, is questionable. However, the Rouse model can be solved for a Gaussian ring 22 . The diffusion times from Rouse theory for the linear and ring models are given in Table II.…”
Section: Discussionmentioning
confidence: 99%
“…These theories make use of the fact that linear chains have free ends but ring polymers do not have free ends so the application of these theories, and especially reptation theory, is questionable. However, the Rouse model can be solved for a Gaussian ring 22 . The diffusion times from Rouse theory for the linear and ring models are given in Table II.…”
Section: Discussionmentioning
confidence: 99%
“…Thus we show further that spatially confined molecules fold into specific conformations close to those found for linear chains, and strongly dependent on the size of the confining box. DOI: 10.1103/PhysRevLett.106.248301 PACS numbers: 82.35.Gh, 87.64.Dz, 36.20.Ey, 87.14.gk Ring closure of a polymer is one of the important factors influencing its statistical mechanical properties [1], e.g., scaling [2,3], shape [4,5], and diffusion [6][7][8], because it restrains the accessible phase space. The theoretical description of circular chains (knots or catenanes) is a challenging problem, owing to the difficulties inherent to a systematic theoretical analysis of such objects constrained to a unique topology.…”
mentioning
confidence: 99%
“…Ring closure of a polymer is one of the important factors influencing its statistical mechanical properties [1], e.g., scaling [2,3], shape [4,5], and diffusion [6][7][8], because it restrains the accessible phase space. The theoretical description of circular chains (knots or catenanes) is a challenging problem, owing to the difficulties inherent to a systematic theoretical analysis of such objects constrained to a unique topology.…”
mentioning
confidence: 99%
“…For example, all segments of a cyclic homopolymer chain are equivalent due to a lack of free chain ends (Iatrou et al 2002;Watanabe et al 2006;Tsolou et al 2010). Then, the mean orientational anisotropy appears to be the same for these segments under the steady shear flow (Watanabe et al 2006;Tsolou et al 2010).…”
Section: Introductionmentioning
confidence: 99%