First normal stress difference and crystallization in a dense sheared granular fluid
Abstract
The first normal stress difference () and the microstructure in a dense sheared granular fluid of smooth inelastic hard-disks are probed using event-driven simulations. While the anisotropy in the second moment of fluctuation velocity, which is a Burnett-order effect, is known to be the progenitor of normal stress differences in {\it dilute} granular fluids, we show here that the collisional anisotropies are responsible for the normal stress behaviour in the {\it dense} limit. As in the elastic hard-sphere fluids, remains {\it positive} (if the stress is defined in the {\it compressive} sense) for dilute and moderately dense flows, but becomes {\it negative} above a critical density, depending on the restitution coefficient. This sign-reversal of occurs due to the {\it microstructural} reorganization of the particles, which can be correlated with a preferred value of the {\it average} collision angle in the direction opposing the shear. We also report on the shear-induced {\it crystal}-formation, signalling the onset of fluid-solid coexistence in dense granular fluids. Different approaches to take into account the normal stress differences are discussed in the framework of the relaxation-type rheological models.
Cite
@article{arxiv.cond-mat/0306689,
title = {First normal stress difference and crystallization in a dense sheared granular fluid},
author = {Meheboob Alam and Stefan Luding},
journal= {arXiv preprint arXiv:cond-mat/0306689},
year = {2009}
}
Comments
21 pages, 13 figures