Bubble formation due to capillary instability during evaporation of a porous medium

TL;DR

This study investigates capillary instability-driven bubble formation during evaporation in porous media, combining visualization experiments with a novel pore network model that includes inertial forces, revealing new insights into two-phase transport mechanisms.

Contribution

The paper introduces a pore network model that incorporates inertial forces, providing a more comprehensive understanding of gas-liquid transport during evaporation in porous structures.

Findings

Capillary instability causes liquid refilling and bubble movement during evaporation.

The developed model aligns well with experimental data, validating its effectiveness.

Inertial forces significantly influence two-phase flow in porous media.

Abstract

We show that during evaporation of a pore network, liquid can refill the gas occupied pores, snapping off a gas bubble, which then moves to a stable configuration. This phenomenon is induced by the capillary instability due to the wettability heterogeneity of the pore network and has a much smaller time scale as compared to the evaporation process. The capillary instability induced liquid refilling and bubble movement are explained in detail based on the analysis of the images obtained from the visualization experiment. The capillary valve effect, which hinders the movement of the gas-liquid interface and is induced by the sudden geometrical expansion between small and large pores, can be suppressed by the residual liquid in the large pore. For better understanding of the capillary instability induced gas-liquid two-phase transport during evaporation, a novel pore network model is developed, which considers not only the capillary and viscous forces but also the inertial forces that are seldom taken into account in the previous models. The pore network modeling results are in good agreement with the experimental data, demonstrating the effectiveness of the developed pore network model, which opens up a new route for better understanding of the role of inertial forces in two-phase transport in porous media.