Issue 25, 2018

Size-dependence of the flow threshold in dense granular materials

Abstract

The flow threshold in dense granular materials is typically modeled by local, stress-based criteria. However, grain-scale cooperativity leads to size effects that cannot be captured with local conditions. In a widely studied example, flows of thin layers of grains down an inclined surface exhibit a size effect whereby thinner layers require more tilt to flow. In this paper, we consider the question of whether the size-dependence of the flow threshold observed in inclined plane flow is configurationally general. Specifically, we consider three different examples of inhomogeneous flow – planar shear flow with gravity, annular shear flow, and vertical chute flow – using two-dimensional discrete-element method calculations and show that the flow threshold is indeed size-dependent in these flow configurations, displaying additional strengthening as the system size is reduced. We then show that the nonlocal granular fluidity model – a nonlocal continuum model for dense granular flow – is capable of quantitatively capturing the observed size-dependent strengthening in all three flow configurations.

Graphical abstract: Size-dependence of the flow threshold in dense granular materials

Article information

Article type
Paper
Submitted
24 Apr 2018
Accepted
04 Jun 2018
First published
06 Jun 2018

Soft Matter, 2018,14, 5294-5305

Author version available

Size-dependence of the flow threshold in dense granular materials

D. Liu and D. L. Henann, Soft Matter, 2018, 14, 5294 DOI: 10.1039/C8SM00843D

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