Modeling strain hardening of polydisperse polystyrene melts by molecular stress function theory |
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| Authors: | M. H. Wagner S. Kheirandish K. Koyama A. Nishioka A. Minegishi T. Takahashi |
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| Affiliation: | (1) Polymertechnik/Polymerphysik, Technische Universität Berlin, Fasanenstr. 90, D-10623 Berlin, Germany;(2) Department of Materials Science and Engineering, Yamagata University, 992-8510 Yonezawa, Japan |
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| Abstract: | ![]()
The strain hardening of blends of polystyrene (PS) and ultra-high molecular weight polystyrene (UHMW-PS) in elongational flow is modeled by the molecular stress function (MSF) theory. Assuming that the ratios of strain energies stored in polydisperse and monodisperse polymers are identical for linear and nonlinear deformations, the value of the only non-linear parameter of the theory in extensional flows, the maximum molecular stress fmax, can be determined and is shown to be related to steady-state compliance Je0. Using only linear-viscoelastic data, the elongational viscosity of PS/UHMW-PS blends is consistently predicted by the MSF theory. |
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| Keywords: | Polystyrene Blends Broad molecular weight distribution Molecular stress function Elongational viscosity Linear and non-linear viscoelasticity |
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