Enhanced dispersion in intermittent multiphase flow

TL;DR

This study uses numerical simulations to reveal that intermittent multiphase flow in porous media significantly enhances transverse dispersion due to capillary-driven flow pathway activation, leading to a new scaling law.

Contribution

It introduces a novel understanding of transverse dispersion in multiphase flow, highlighting the role of intermittent flow patterns and fluid cluster size in porous media.

Findings

Transverse dispersion is strongly enhanced by intermittent flow patterns.

Dispersion is inversely proportional to the square root of the Bond number.

A new scaling law relates flow dynamics to transport properties.

Abstract

Transport in multiphase flow through porous media plays a central role in many biological, geological, and engineered systems. Here, we use numerical simulations of transport in immiscible two-phase flow to investigate dispersion in multiphase porous media flow. While dispersion in the main flow direction is similar to that of a single-phase flow and is governed by the porous media structure, we find that transverse dispersion exhibits fundamentally different dynamics. The repeated activation and deactivation of different flow pathways under the effect of capillary forces lead to intermittent flow patterns, strongly enhancing dispersion. We show that the transverse dispersion is controlled by the length scale of fluid clusters, and thus inversely proportional to the square root of the Bond number, the ratio of the force driving the flow and the surface tension. This result leads to a new scaling law relating multiphase flow dynamics to transport properties, opening a range of fundamental and engineering applications.