A sequence of physical processes determined and quantified in LAOS: Application to a yield stress fluid

Simon A. Rogers; Brian M. Erwin; Dimitris Vlassopoulos; Michel Cloitre

doi:10.1122/1.3544591

A sequence of physical processes determined and quantified in LAOS: Application to a yield stress fluid

Simon A. Rogers, Brian M. Erwin, Dimitris Vlassopoulos, Michel Cloitre

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

Abstract

Recently, large-amplitude oscillatory shear has been studied in great detail with emphasis on its impact on the material response. Here we present a conceptually different, robust methodology based on viewing the stress waveforms as representing a sequence of physical processes. This novel approach provides the viscous and elastic contributions while overcoming the problems with infinite series encountered by Fourier transformation. Application to a soft colloidal star glass leads to the unambiguous determination and quantification of rate-dependent static and dynamic yield stresses, the rationalization of the response to strain sweeps and the post-yield regime by introducing the apparent cage modulus, and a connection to the steady-shear stress, all from a single-amplitude experiment. We propose that this approach is generic, but focus in this contribution only on a yield stress material which exhibits repeating cycles of (i) elastic extension, (ii) yielding, (iii) flow, and (iv) reformation. We show that this approach is qualitatively consistent with the Fourier-Chebyshev analysis.

Original language	English (US)
Pages (from-to)	435-458
Number of pages	24
Journal	Journal of Rheology
Volume	55
Issue number	2
DOIs	https://doi.org/10.1122/1.3544591
State	Published - Mar 2011
Externally published	Yes

Keywords

Colloidal glass
Fourier-Chebyshev
LAOS
Yield strain
Yield stress

ASJC Scopus subject areas

General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

Online availability

10.1122/1.3544591

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title = "A sequence of physical processes determined and quantified in LAOS: Application to a yield stress fluid",

abstract = "Recently, large-amplitude oscillatory shear has been studied in great detail with emphasis on its impact on the material response. Here we present a conceptually different, robust methodology based on viewing the stress waveforms as representing a sequence of physical processes. This novel approach provides the viscous and elastic contributions while overcoming the problems with infinite series encountered by Fourier transformation. Application to a soft colloidal star glass leads to the unambiguous determination and quantification of rate-dependent static and dynamic yield stresses, the rationalization of the response to strain sweeps and the post-yield regime by introducing the apparent cage modulus, and a connection to the steady-shear stress, all from a single-amplitude experiment. We propose that this approach is generic, but focus in this contribution only on a yield stress material which exhibits repeating cycles of (i) elastic extension, (ii) yielding, (iii) flow, and (iv) reformation. We show that this approach is qualitatively consistent with the Fourier-Chebyshev analysis.",

keywords = "Colloidal glass, Fourier-Chebyshev, LAOS, Yield strain, Yield stress",

author = "Rogers, {Simon A.} and Erwin, {Brian M.} and Dimitris Vlassopoulos and Michel Cloitre",

note = "Funding Information: The star polymer used in this work has been generously provided by Jacques Roovers. We acknowledge the EU (NoE Softcomp Grant No. NMP3-CT-2004-502235, ToK Cosines Grant No. MTKD-CT-2005-029944, and NMP SMALL Nanodirect-NMP Grant No. 213948) for financial support. We acknowledge insightful and informative discussions with Christopher Klein at the nascence of this work and useful conversations with Pierre Ballesta and Nick Virgillio during the latter stages of this work. We thank Jan Mewis for comments on the manuscript. ",

year = "2011",

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doi = "10.1122/1.3544591",

language = "English (US)",

volume = "55",

pages = "435--458",

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publisher = "Society of Rheology",

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AU - Erwin, Brian M.

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AU - Cloitre, Michel

N1 - Funding Information: The star polymer used in this work has been generously provided by Jacques Roovers. We acknowledge the EU (NoE Softcomp Grant No. NMP3-CT-2004-502235, ToK Cosines Grant No. MTKD-CT-2005-029944, and NMP SMALL Nanodirect-NMP Grant No. 213948) for financial support. We acknowledge insightful and informative discussions with Christopher Klein at the nascence of this work and useful conversations with Pierre Ballesta and Nick Virgillio during the latter stages of this work. We thank Jan Mewis for comments on the manuscript.

PY - 2011/3

Y1 - 2011/3

N2 - Recently, large-amplitude oscillatory shear has been studied in great detail with emphasis on its impact on the material response. Here we present a conceptually different, robust methodology based on viewing the stress waveforms as representing a sequence of physical processes. This novel approach provides the viscous and elastic contributions while overcoming the problems with infinite series encountered by Fourier transformation. Application to a soft colloidal star glass leads to the unambiguous determination and quantification of rate-dependent static and dynamic yield stresses, the rationalization of the response to strain sweeps and the post-yield regime by introducing the apparent cage modulus, and a connection to the steady-shear stress, all from a single-amplitude experiment. We propose that this approach is generic, but focus in this contribution only on a yield stress material which exhibits repeating cycles of (i) elastic extension, (ii) yielding, (iii) flow, and (iv) reformation. We show that this approach is qualitatively consistent with the Fourier-Chebyshev analysis.

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A sequence of physical processes determined and quantified in LAOS: Application to a yield stress fluid

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