`Sinking' in a bed of grains activated by shearing

Abstract

We show how a weak force, f, enables intruder motion through dense granular materials subject to external mechanical excitations, in the present case stepwise shearing. A force acts on a Teflon disc in a two dimensional system of photoelastic discs. This force is much smaller than the smallest force needed to move the disc without any external excitation. In a cycle, material + intruder are sheared quasi-statically from γ = 0 to γmax, and then backwards to γ = 0. During various cycle phases, fragile and jammed states form. Net intruder motion, δ, occurs during fragile periods generated by shear reversals. δ per cycle, e.g. the quasistatic rate c, is constant, linearly dependent on γmax and f. It vanishes as, c (φc - φ)a, with a 3 and φc φJ, reflecting the stiffening of granular systems under shear as φ → φJ. The intruder motion induces large scale grain circulation. In the intruder frame, this motion is a granular analogue to fluid flow past a cylinder, where f is the drag force exerted by the flow.