Molecular physics of a polymer engineering instability: Experiments and computation

D. G. Hassell; M. R. MacKley; M. Sahin; H. J. Wilson; O. G. Harlen; T. C.B. McLeish

doi:10.1103/PhysRevE.77.050801

Molecular physics of a polymer engineering instability: Experiments and computation

D. G. Hassell, M. R. MacKley, M. Sahin, H. J. Wilson, O. G. Harlen, T. C.B. McLeish

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

12 Citations (Scopus)

Abstract

Entangled polymer melts exhibit a variety of flow instabilities that limit production rates in industrial applications. We present both experimental and computational findings, using flow of monodisperse linear polystyrenes in a contraction-expansion geometry, which illustrate the formation and development of one such flow instability. This viscoelastic disturbance is observed at the slit outlet and subsequently produces large-scale fluid motions upstream. A numerical linear stability study using the molecular structure based Rolie-Poly model confirms the instability and identifies important parameters within the model, which gives physical insight into the underlying mechanism. Chain stretch was found to play a critical role in the instability mechanism, which partially explains the effectiveness of introducing a low-molecular weight tail into a polymer blend to increase its processability.

Original language	English
Article number	050801
Journal	Physical Review E
Volume	77
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevE.77.050801
Publication status	Published - 19 May 2008
Externally published	Yes

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T2 - Experiments and computation

AU - Hassell, D. G.

AU - MacKley, M. R.

AU - Sahin, M.

AU - Wilson, H. J.

AU - Harlen, O. G.

AU - McLeish, T. C.B.

PY - 2008/5/19

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N2 - Entangled polymer melts exhibit a variety of flow instabilities that limit production rates in industrial applications. We present both experimental and computational findings, using flow of monodisperse linear polystyrenes in a contraction-expansion geometry, which illustrate the formation and development of one such flow instability. This viscoelastic disturbance is observed at the slit outlet and subsequently produces large-scale fluid motions upstream. A numerical linear stability study using the molecular structure based Rolie-Poly model confirms the instability and identifies important parameters within the model, which gives physical insight into the underlying mechanism. Chain stretch was found to play a critical role in the instability mechanism, which partially explains the effectiveness of introducing a low-molecular weight tail into a polymer blend to increase its processability.

AB - Entangled polymer melts exhibit a variety of flow instabilities that limit production rates in industrial applications. We present both experimental and computational findings, using flow of monodisperse linear polystyrenes in a contraction-expansion geometry, which illustrate the formation and development of one such flow instability. This viscoelastic disturbance is observed at the slit outlet and subsequently produces large-scale fluid motions upstream. A numerical linear stability study using the molecular structure based Rolie-Poly model confirms the instability and identifies important parameters within the model, which gives physical insight into the underlying mechanism. Chain stretch was found to play a critical role in the instability mechanism, which partially explains the effectiveness of introducing a low-molecular weight tail into a polymer blend to increase its processability.

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Molecular physics of a polymer engineering instability: Experiments and computation

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