Percolation through Voids around Randomly Oriented Platonic Solids

Abstract

Porous materials made up of impermeable polyhedral grains constrain fluid flow to voids around the impenetrable constituent barrier particles. A percolation transition marks the boundary between assemblies of grains which contain system spanning void networks, admitting bulk transport, and configurations which may not be traversed on macroscopic scales. With dynamical infiltration of void spaces using virtual tracer particles, we give an exact treatment of grain geometries, and we calculate critical densities for polyhedral inclusions for the five platonic solids (i.e. tetrahedra, cubes, octahededra, dodecahedra, and icosahedra). In each case, we calculate percolation threshold concentrations c for aligned and randomly oriented grains, finding distinct c values for the former versus the latter only for cube-shaped grains. We calculate the dynamical scaling exponent at the percolation threshold, finding subdiffusive value z = 0.19(1) common to all grain shapes considered.