Bifurcating-Paths: the relation between preferential flow bifurcations, void, and tortuosity on the Darcy scale

TL;DR

This paper investigates how heterogeneity in porous media influences preferential flow bifurcations, void formation, and tortuosity at the Darcy scale, revealing power-law relationships that impact transport behavior.

Contribution

It introduces a model linking heterogeneity to flow bifurcations, voids, and tortuosity, highlighting the dominant scaling behavior affecting transport properties.

Findings

Bifurcation fraction decreases with heterogeneity, reaching an asymptote.

Void fraction, tortuosity, and fractal dimension scale with heterogeneity via a power law.

Heterogeneity-driven scaling influences transport times and anomalous transport phenomena.

Abstract

In recent years, Darcy scale transport in porous media was characterized to be Fickian or non-Fickian due to the homogeneity or heterogeneity of the porous medium conductivity layout. Yet, evidence shows that preferential flows that funnel the transport occur in heterogeneous and homogenous cases. We model the Darcy scale transport using a 2D conductivity field ranging from homogenous to heterogeneous and find that these preferential flows bifurcate, leaving voids where particles do not invade while forming a tortuous path. The fraction of bifurcations decreases downflow and reaches an asymptotical value, which scales as a power-law with the heterogeneity level. We show that the same power-law scaling of the bifurcations to heterogeneity level appears for the void fraction, tortuosity, and fractal dimension analysis with the same heterogeneity level. We conclude that the scaling with the heterogeneity is the dominant feature in the preferential flow geometry, which will lead to variations in weighting times for the transport and eventually to anomalous transport.