Shear-induced pressure anisotropy in granular materials of nonspherical particles

Abstract

When a granular material composed of elongated grains is sheared in a split-bottom shear cell, a pressure difference develops within the material. This pressure difference depends on the interparticle friction (μ), which affects shear localization and particle alignment. For large μ, alignment is confined to a narrow shear band, leading to localized increases in packing density and pressure. For small μ, particles align over a wider region, leading to a nearly uniform packing density and pressure throughout the material. In contrast, spherical particles, regardless of μ, maintain a uniform packing density and pressure throughout the material. We observe a phenomenological similarity to the Weissenberg effect in non-Newtonian fluids, where normal stress differences induce radial pressure gradients, unlike the uniform pressure in Newtonian fluids.

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