The viscoelastic signature underpinning polymer deformation under shear flow

Airidas Korolkovas; Sylvain Prévost; Maciej Kawecki; Anton Devishvili; Franz A. Adlmann; Philipp Gutfreund; Max Wolff

doi:10.1039/c8sm02255k

The viscoelastic signature underpinning polymer deformation under shear flow

Airidas Korolkovas, Sylvain Prévost, Maciej Kawecki, Anton Devishvili, Franz A. Adlmann, Philipp Gutfreund, Max Wolff

Physical Chemistry

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

Abstract

Entangled polymers are deformed by a strong shear flow. The shape of the polymer, called the form factor, is measured by small angle neutron scattering. However, the real-space molecular structure is not directly available from the reciprocal-space data, due to the phase problem. Instead, the data has to be fitted with a theoretical model of the molecule. We approximate the unknown structure using piecewise straight segments, from which we derive an analytical form factor. We fit it to our data on a semi-dilute entangled polystyrene solution under in situ shear flow. The character of the deformation is shown to lie between that of a single ideal chain (viscous) and a cross-linked network (elastic rubber). Furthermore, we use the fitted structure to estimate the mechanical stress, and find a fairly good agreement with rheology literature.

Original language	English
Pages (from-to)	371-380
Number of pages	10
Journal	Soft Matter
Volume	15
Issue number	3
DOIs	https://doi.org/10.1039/c8sm02255k
Publication status	Published - 2019

Subject classification (UKÄ)

Physical Chemistry (including Surface- and Colloid Chemistry)

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title = "The viscoelastic signature underpinning polymer deformation under shear flow",

abstract = "Entangled polymers are deformed by a strong shear flow. The shape of the polymer, called the form factor, is measured by small angle neutron scattering. However, the real-space molecular structure is not directly available from the reciprocal-space data, due to the phase problem. Instead, the data has to be fitted with a theoretical model of the molecule. We approximate the unknown structure using piecewise straight segments, from which we derive an analytical form factor. We fit it to our data on a semi-dilute entangled polystyrene solution under in situ shear flow. The character of the deformation is shown to lie between that of a single ideal chain (viscous) and a cross-linked network (elastic rubber). Furthermore, we use the fitted structure to estimate the mechanical stress, and find a fairly good agreement with rheology literature.",

author = "Airidas Korolkovas and Sylvain Pr{\'e}vost and Maciej Kawecki and Anton Devishvili and Adlmann, {Franz A.} and Philipp Gutfreund and Max Wolff",

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T1 - The viscoelastic signature underpinning polymer deformation under shear flow

AU - Korolkovas, Airidas

AU - Prévost, Sylvain

AU - Kawecki, Maciej

AU - Devishvili, Anton

AU - Adlmann, Franz A.

AU - Gutfreund, Philipp

AU - Wolff, Max

PY - 2019

Y1 - 2019

N2 - Entangled polymers are deformed by a strong shear flow. The shape of the polymer, called the form factor, is measured by small angle neutron scattering. However, the real-space molecular structure is not directly available from the reciprocal-space data, due to the phase problem. Instead, the data has to be fitted with a theoretical model of the molecule. We approximate the unknown structure using piecewise straight segments, from which we derive an analytical form factor. We fit it to our data on a semi-dilute entangled polystyrene solution under in situ shear flow. The character of the deformation is shown to lie between that of a single ideal chain (viscous) and a cross-linked network (elastic rubber). Furthermore, we use the fitted structure to estimate the mechanical stress, and find a fairly good agreement with rheology literature.

AB - Entangled polymers are deformed by a strong shear flow. The shape of the polymer, called the form factor, is measured by small angle neutron scattering. However, the real-space molecular structure is not directly available from the reciprocal-space data, due to the phase problem. Instead, the data has to be fitted with a theoretical model of the molecule. We approximate the unknown structure using piecewise straight segments, from which we derive an analytical form factor. We fit it to our data on a semi-dilute entangled polystyrene solution under in situ shear flow. The character of the deformation is shown to lie between that of a single ideal chain (viscous) and a cross-linked network (elastic rubber). Furthermore, we use the fitted structure to estimate the mechanical stress, and find a fairly good agreement with rheology literature.

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DO - 10.1039/c8sm02255k

M3 - Article

C2 - 30519692

AN - SCOPUS:85060014311

SN - 1744-683X

VL - 15

SP - 371

EP - 380

JO - Soft Matter

JF - Soft Matter

IS - 3

ER -

The viscoelastic signature underpinning polymer deformation under shear flow

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