Simplified numerical model for clarifying scaling behavior in the intermediate dispersion regime in homogeneous porous media

The dispersion of solute in porous media shows a non-linear increase in the transition from diffusion to advection dominated dispersion as the flow velocity is raised. In the past, the behavior in this intermediate regime has been explained with a variety of models. We present and use a simplified n...

Full description

Saved in:
Bibliographic Details
Published in:Computer physics communications 2014-12, Vol.185 (12), p.3291-3301
Main Authors: van Milligen, B.Ph, Bons, P.D.
Format: Article
Language:English
Subjects:
Differential equations
Diffusion
Dispersions
Flow velocity
Flows through porous media
Mathematical models
Media
Nonlinearity
Phase transformations
Phase transitions
Porosity
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The dispersion of solute in porous media shows a non-linear increase in the transition from diffusion to advection dominated dispersion as the flow velocity is raised. In the past, the behavior in this intermediate regime has been explained with a variety of models. We present and use a simplified numerical model which does not contain any turbulence, Taylor dispersion, or fractality. With it, we show that the non-linearity in the intermediate regime nevertheless occurs. Furthermore, we show that the intermediate regime can be regarded as a phase transition between random, diffusive transport at low flow velocity and ordered transport controlled by the geometry of the pore space at high flow velocities. This phase transition explains the first-order behavior in the intermediate regime. A new quantifier, the ratio of the amount of solute in dominantly advective versus dominantly diffusive pore channels, plays the role of ‘order parameter’ of this phase transition. Taylor dispersion, often invoked to explain the supra-linear behavior of longitudinal dispersion in this regime, was found not to be of primary importance. The novel treatment of the intermediate regime paves the way for a more accurate description of dispersion as a function of flow velocity, spanning the whole range of Péclet numbers relevant to practical applications, such as ground water remediation.
ISSN:0010-4655
1879-2944
DOI:10.1016/j.cpc.2014.09.006