Large-amplitude oscillatory shear flow simulation for a FENE fluid

Aldo Gómez-López; Víctor H. Ferrer; Eduardo Rincón; Juan P. Aguayo; Ángel E. Chávez; René O. Vargas

doi:10.1007/s00397-019-01145-z

Large-amplitude oscillatory shear flow simulation for a FENE fluid

Aldo Gómez-López, Víctor H. Ferrer, Eduardo Rincón, Juan P. Aguayo, Ángel E. Chávez, René O. Vargas

Escuela Superior de Ingeniería Mecánica y Eléctrica (ESIME), Unidad Azcapotzalco

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

4 Scopus citations

Abstract

In this work, the FENE dumbbell model under small- and large-amplitude oscillatory shear flows using a micro-macro approach is presented. This approach involves the evolution of an ensemble of Brownian Configuration Fields which describes the polymer dynamics of the microscopic scale and the momentum equation describes the macroscopic scale. The Lissajous curves for the shear stress and the first normal stress difference versus the instantaneous strain or strain rate for the elastic or viscous projection are shown. The influences of the solvent/polymer viscosity ratio, the maximum extension length, and the relation between strain rate and frequency are analyzed. An important finding is the self-intersection of the Lissajous curves, which forms secondary loops for short extension lengths and high Weissenberg/Deborah dimensionless numbers ratio.

Original language	English
Pages (from-to)	241-260
Number of pages	20
Journal	Rheologica Acta
Volume	58
Issue number	5
DOIs	https://doi.org/10.1007/s00397-019-01145-z
State	Published - 1 May 2019

Keywords

FENE model
LAOS
Maximum extension length
Multiscale
Oscillatory flow
Viscoelasticity

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10.1007/s00397-019-01145-z

Cite this

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title = "Large-amplitude oscillatory shear flow simulation for a FENE fluid",

abstract = "In this work, the FENE dumbbell model under small- and large-amplitude oscillatory shear flows using a micro-macro approach is presented. This approach involves the evolution of an ensemble of Brownian Configuration Fields which describes the polymer dynamics of the microscopic scale and the momentum equation describes the macroscopic scale. The Lissajous curves for the shear stress and the first normal stress difference versus the instantaneous strain or strain rate for the elastic or viscous projection are shown. The influences of the solvent/polymer viscosity ratio, the maximum extension length, and the relation between strain rate and frequency are analyzed. An important finding is the self-intersection of the Lissajous curves, which forms secondary loops for short extension lengths and high Weissenberg/Deborah dimensionless numbers ratio.",

keywords = "FENE model, LAOS, Maximum extension length, Multiscale, Oscillatory flow, Viscoelasticity",

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AU - Gómez-López, Aldo

AU - Ferrer, Víctor H.

AU - Rincón, Eduardo

AU - Aguayo, Juan P.

AU - Chávez, Ángel E.

AU - Vargas, René O.

PY - 2019/5/1

Y1 - 2019/5/1

N2 - In this work, the FENE dumbbell model under small- and large-amplitude oscillatory shear flows using a micro-macro approach is presented. This approach involves the evolution of an ensemble of Brownian Configuration Fields which describes the polymer dynamics of the microscopic scale and the momentum equation describes the macroscopic scale. The Lissajous curves for the shear stress and the first normal stress difference versus the instantaneous strain or strain rate for the elastic or viscous projection are shown. The influences of the solvent/polymer viscosity ratio, the maximum extension length, and the relation between strain rate and frequency are analyzed. An important finding is the self-intersection of the Lissajous curves, which forms secondary loops for short extension lengths and high Weissenberg/Deborah dimensionless numbers ratio.

AB - In this work, the FENE dumbbell model under small- and large-amplitude oscillatory shear flows using a micro-macro approach is presented. This approach involves the evolution of an ensemble of Brownian Configuration Fields which describes the polymer dynamics of the microscopic scale and the momentum equation describes the macroscopic scale. The Lissajous curves for the shear stress and the first normal stress difference versus the instantaneous strain or strain rate for the elastic or viscous projection are shown. The influences of the solvent/polymer viscosity ratio, the maximum extension length, and the relation between strain rate and frequency are analyzed. An important finding is the self-intersection of the Lissajous curves, which forms secondary loops for short extension lengths and high Weissenberg/Deborah dimensionless numbers ratio.

KW - FENE model

KW - LAOS

KW - Maximum extension length

KW - Multiscale

KW - Oscillatory flow

KW - Viscoelasticity

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JO - Rheologica Acta

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Large-amplitude oscillatory shear flow simulation for a FENE fluid

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Keywords

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