Superfluid-Like Stick−Slip Transition in Capillary Flow of Linear Polyethylene Melts. 1. General Features

This paper explores rheological characteristics of and molecular mechanism for a superfluid-like stick−slip transition occurring under controlled pressure in capillary flow of a series of highly entangled linear polyethylene (PE) melts and establishes its connection with the spurt flow phenomenon. T...

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Bibliographic Details
Published in:Macromolecules 1996-03, Vol.29 (7), p.2627-2632
Main Authors: Wang, Shi-Qing, Drda, Patrick A
Format: Article
Language:English
Subjects:
Adsorption
Applied sciences
Boundary conditions
Capillary flow
Elastomers
Exact sciences and technology
Hydrodynamics
Molecular dynamics
Organic polymers
Phase interfaces
Physicochemistry of polymers
Properties and characterization
Rheology
Rheology and viscoelasticity
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Summary:This paper explores rheological characteristics of and molecular mechanism for a superfluid-like stick−slip transition occurring under controlled pressure in capillary flow of a series of highly entangled linear polyethylene (PE) melts and establishes its connection with the spurt flow phenomenon. The transition is signified by a large discontinuity in the flow rate at a critical stress, resulting in a double value within the flow curve. The magnitude of the transition can be quantified in terms of an extrapolation length, b. In particular, the superfluid-like flow transition occurs throughout a range of temperatures from T = 180 to 260 °C as long as a critical stress, σc, is exceeded. It is found that σc increases linearly with T, and b c at the transition remains around 1.7 mm at all the temperatures for the PE (MH20) of weight-average molecular weight M w = 316 600. Thus the observed remarkably large interfacial slip is believed to be due to complete disentanglement of the adsorbed chains from free chains at the melt/wall interface at and beyond the transition. The amount of wall slip, as described by b, diminishes quickly with decreasing M w, in qualitative agreement with a simple scaling relation for noninteracting interfaces. The flow transition depends on the surface condition of the die wall and occurs at a considerably lower critical stress when the wall is treated by depositing a fluorocarbon elastomer to weaken the PE adsorption. Application of both controlled-pressure and controlled-piston speed conditions demonstrates that spurt flow instability originates from indeterminacy of the hydrodynamic boundary condition at the PE/die wall interfaces.
ISSN:0024-9297
1520-5835
DOI:10.1021/ma950898q