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Memory-induced motion reversal in Brownian liquids

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Abstract

We study the Brownian dynamics of hard spheres under spatially inhomogeneous shear, using event-driven Brownian dynamics simulations and power functional theory. We examine density and current profiles both for steady states and for the transient dynamics after switching on and switching off an external square wave shear force field. We find that a dense hard sphere fluid (volume fraction ≈0.35) undergoes global motion reversal after switching off the shear force field. We use power functional theory with a spatially nonlocal memory kernel to describe the superadiabatic force contributions and obtain good quantitative agreement of the theoretical results with simulation data. The theory provides an explanation for the motion reversal: internal superadiabatic nonequilibrium forces that oppose the externally driven current arise due to memory after switching off. The effect is genuinely viscoelastic: in steady state, viscous forces oppose the current, but they elastically generate an opposing current after switch-off.

Graphical abstract: Memory-induced motion reversal in Brownian liquids

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Article information


Submitted
08 Oct 2019
Accepted
07 Jan 2020
First published
08 Jan 2020

Soft Matter, 2020, Advance Article
Article type
Paper

Memory-induced motion reversal in Brownian liquids

L. L. Treffenstädt and M. Schmidt, Soft Matter, 2020, Advance Article , DOI: 10.1039/C9SM02005E

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