Structure induced vortices control anomalous dispersion in porous media

TL;DR

This study reveals how microscopic vortices within dead-end pores in porous media significantly influence particle dispersion, leading to anomalous tailing in arrival times, with implications for environmental and medical applications.

Contribution

It introduces a microfluidic model and analytical framework linking dead-end pore vortices to anomalous dispersion, a novel insight into microscopic flow effects on macroscopic transport.

Findings

Power-law tailing with exponent 2/3 in arrival times

Vortices inside dead-end pores cause particle trapping and tailing

Stochastic model predicts full evolution of particle arrival times

Abstract

Natural porous systems, such as soil, membranes, and biological tissues comprise disordered structures characterized by dead-end pores connected to a network of percolating channels. The release and dispersion of particles, solutes, and microorganisms from such features is key for a broad range of environmental and medical applications including soil remediation, drug delivery and filtration. Yet, the role of microscopic structure and flow for the dispersion of particles and solutes in such disordered systems has been only poorly understood, in part due to the stagnant and opaque nature of these microscopic systems. Here, we use a microfluidic model system that features a pore structure characterized by dead-ends to determine how particles are transported, retained and dispersed. We observe strong tailing of arrival time distributions at the outlet of the medium characterized by power-law decay with an exponent of 2/3. Using numerical simulations and an analytical model, we link this behavior to particles initially located within dead-end pores, and explain the tailing exponent with a hopping and rolling mechanism along the streamlines inside vortices within dead-end pores. These dynamics are quantified by a stochastic model that predicts the full evolution of arrival times. Our results demonstrate how microscopic flow structures can impact macroscopic particle transport.