Phys Rev Lett. 2016 Feb 05;116(5):058303. doi: 10.1103/PhysRevLett.116.058303. Epub 2016 Feb 05.

Effects of Inertia on the Steady-Shear Rheology of Disordered Solids.

Physical review letters

Alexandre Nicolas, Jean-Louis Barrat, Jörg Rottler

PMID: 26894739 DOI: 10.1103/PhysRevLett.116.058303

Abstract

We study the finite-shear-rate rheology of disordered solids by means of molecular dynamics simulations in two dimensions. By systematically varying the damping strength ζ in the low-temperature limit, we identify two well-defined flow regimes, separated by a thin (temperature-dependent) crossover region. In the overdamped regime, the athermal rheology is governed by the competition between elastic forces and viscous forces, whose ratio gives the Weissenberg number Wi∝ζγ[over ˙]; the macroscopic stress Σ follows the frequently encountered Herschel-Bulkley law Σ=Σ_{0}+ksqrt[Wi], with yield stress Σ_{0}>0. In the underdamped (inertial) regime, dramatic changes in the rheology are observed for low damping: the flow curve becomes nonmonotonic. This change is not caused by longer-lived correlations in the particle dynamics at lower damping; instead, for weak dissipation, the sample heats up considerably due to, and in proportion to, the driving. By thermostating more or less underdamped systems, we are able to link quantitatively the rheology to the kinetic temperature and the shear rate, rescaled with Einstein's vibration frequency.

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• Journal Article