Fragility and hysteretic creep in frictional granular jamming

Abstract

The granular jamming transition is experimentally investigated in a two-dimensional system of frictional, bi-dispersed disks subject to quasi-static, uniaxial compression at zero granular temperature. Currently accepted results show the jamming transition occurs at a critical packing fraction φc. In contrast, we observe the first compression cycle exhibits fragility - metastable configuration with simultaneous jammed and un-jammed clusters - over a small interval in packing fraction (φ1 < φ < φ2). The fragile state separates the two conditions that define φc with an exponential rise in pressure starting at φ1 and an exponential fall in disk displacements ending at φ2. The results are explained through a percolation mechanism of stressed contacts where cluster growth exhibits strong spatial correlation with disk displacements. Measurements with several disk materials of varying elastic moduli E and friction coefficients μ, show friction directly controls the start of the fragile state, but indirectly controls the exponential slope. Additionally, we experimentally confirm recent predictions relating the dependence of φc on μ. Under repetitive loading (compression), the system exhibits hysteresis in pressure, and the onset φc increases slowly with repetition number. This friction induced hysteretic creep is interpreted as the granular pack's evolution from a metastable to an eventual structurally stable configuration. It is shown to depend upon the quasi-static step size φ which provides the only perturbative mechanism in the experimental protocol, and the friction coefficient μ which acts to stabilize the pack.