Convection in porous media with dispersion

Abstract

We investigate the effect of dispersion on convection in porous media by performing direct numerical simulations (DNS) in a two-dimensional Rayleigh-Darcy domain. Scaling analysis of the governing equations shows that the dynamics of this system are not only controlled by the classical Rayleigh-Darcy number based on molecular diffusion, Ram, and the domain aspect ratio, but also controlled by two other dimensionless parameters: the dispersive Rayleigh number Rad = H/αt and the dispersivity ratio r = αl/αt, where H is the domain height, αt and αl are the transverse and longitudinal dispersivities, respectively. For = Rad/Ram > O(1), the influence from the mechanical dispersion is minor; for 1, however, the flow pattern is controlled by Rad while the convective flux is F Ram for large Ram, but with a prefactor that has a non-monotonic dependence on Rad. Our DNS results also show that the increase of mechanical dispersion, i.e. decreasing Rad, will coarsen the convective pattern by increasing the plume spacing. Moreover, the inherent anisotropy of mechanical dispersion breaks the columnar structure of the mega-plumes at large Ram, if Rad < 5000. This results in a fan-flow geometry that reduces the convective flux.