Shear Banding of Soft Glassy Materials in Large Amplitude Oscillatory Shear

We study shear banding in soft glassy materials subject to a large amplitude oscillatory shear flow (LAOS). By numerical simulations of the widely used soft glassy rheology model, supplemented by more general physical arguments, we demonstrate strong banding over an extensive range of amplitudes and...

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Veröffentlicht in:	Physical review letters 2016-10, Vol.117 (18), p.188001-188001, Article 188001
Hauptverfasser:	Radhakrishnan, Rangarajan, Fielding, Suzanne M
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Sprache:	eng
Schlagworte:	Amplitudes Banding Computational fluid dynamics Mathematical models Shear Shear flow Slip bands Steady state
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container_title	Physical review letters
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creator	Radhakrishnan, Rangarajan Fielding, Suzanne M
description	We study shear banding in soft glassy materials subject to a large amplitude oscillatory shear flow (LAOS). By numerical simulations of the widely used soft glassy rheology model, supplemented by more general physical arguments, we demonstrate strong banding over an extensive range of amplitudes and frequencies of the imposed shear rate γ[over ˙](t)=γ[over ˙]_{0}cos(ωt), even in materials that do not permit banding as their steady state response to a steadily imposed shear flow γ[over ˙]=γ[over ˙]_{0}=const. Highly counterintuitively, banding persists in LAOS even in the limit of zero frequency ω→0, where one might a priori have expected a homogeneous flow response in a material that does not display banding under conditions of steadily imposed shear. We explain this finding in terms of an alternating competition within each cycle between glassy aging and flow rejuvenation. Our predictions have far-reaching implications for the flow behavior of aging yield stress fluids, suggesting a generic expectation of shear banding in flows of even arbitrarily slow time variation.
doi_str_mv	10.1103/physrevlett.117.188001
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subjects	Amplitudes Banding Computational fluid dynamics Mathematical models Shear Shear flow Slip bands Steady state
title	Shear Banding of Soft Glassy Materials in Large Amplitude Oscillatory Shear
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