Diffusiophoretic transport of colloids in porous media

TL;DR

This study reveals that chemical gradients induce diffusiophoretic migration of colloids, significantly altering their transport in porous media, which challenges classical models and impacts various applications.

Contribution

The paper combines experiments, simulations, and modeling to show how solute gradients affect colloid dispersion, highlighting the need to revise classical transport models.

Findings

Diffusiophoresis causes order-of-magnitude changes in colloid dispersion.

Solute gradients significantly influence colloid transport times.

Classical models need revision to incorporate chemical gradient effects.

Abstract

Understanding how colloids move in crowded environments is key for gaining control over their transport in applications such as drug delivery, filtration, contaminant/microplastic remediation and agriculture. The classical models of colloid transport in porous media rely on geometric characteristics of the medium, and hydrodynamic/non-hydrodynamic equilibrium interactions to predict their behavior. However, chemical gradients are ubiquitous in these environments and can lead to the non-equilibrium diffusiophoretic migration of colloids. Here, combining microfluidic experiments, numerical simulations, and theoretical modeling we demonstrate that diffusiophoresis leads to significant macroscopic changes in the dispersion of colloids in porous media. We displace a suspension of colloids dispersed in a background salt solution with a higher/lower salinity solution and monitor the removal of the colloids from the medium. While mixing weakens the solute gradients, leading to the diffusiophoretic velocities that are orders of magnitude weaker than the background fluid flow, we show that the cross-streamline migration of colloids changes their macroscopic transit time and dispersion through the medium by an order of magnitude compared to the control case with no salinity gradients. Our observations demonstrate that solute gradients modulate the influence of geometric disorder on the transport, pointing to the need for revisiting the classical models of colloid transport in porous media to obtain predictive models for technological, medical, and environmental applications.