Effect of Shape and Friction on the Packing and Flow of Granular Materials

Abstract: The packing and flow of aspherical frictional particles are studied using discrete element simulations. Particles are superballs with shape $|x|^{s}+|y|^{s}+|z|^{s} = 1$ that varies from sphere ($s=2$) to cube ($s=\infty$), constructed with an overlapping-sphere model. Both packing fraction, $\phi$, and coordination number, $z$, decrease monotonically with microscopic friction $\mu$, for all shapes. However, this decrease is more dramatic for larger $s$ due to a reduction in the fraction of face-face contacts with increasing friction. For flowing grains, the dynamic friction $\tilde{\mu}$ - the ratio of shear to normal stresses - depends on shape, microscopic friction and inertial number $I.$ For all shapes, $\tilde{\mu}$ grows from its quasi-static value $\tilde{\mu}_0$ as $(\tilde{\mu}-\tilde{\mu}_0) = dI^\alpha,$ with different universal behavior for frictional and frictionless shapes. For frictionless shapes the exponent $\alpha \approx 0.5$ and prefactor $d \approx 5\tilde{\mu}_0$ while for frictional shapes $\alpha \approx 1$ and $d$ varies only slightly. The results highlight that the flow exponents are universal and are consistent for all the shapes simulated here.