Reynolds Pressure and Relaxation in a Sheared Granular System

Abstract

We describe experiments that probe the evolution of shear jammed states, occurring for packing fractions φS ≤ φ ≤ φJ, for frictional granular disks, where above φJ there are no stress-free static states. We use a novel shear apparatus that avoids the formation of inhomogeneities known as shear bands. This fixed φ system exhibits coupling between the shear strain, γ, and the pressure, P, which we characterize by the `Reynolds pressure', and a `Reynolds coefficient', R(φ) = (∂ 2 P/∂ γ 2)/2. R depends only on φ, and diverges as R (φc - φ)α, where φc φJ, and α -3.3. Under cyclic shear, this system evolves logarithmically slowly towards limit cycle dynamics, which we characterize in terms of pressure relaxation at cycle n: P -β (n/n0). β depends only on the shear cycle amplitude, suggesting an activated process where β plays a temperature-like role.