Pore-scale study on the effect of heterogeneity on evaporation in porous media

The evaporation process in porous media typically experiences three main periods, among which the first period, named the constant rate period (CRP), performs most efficiently in removing liquid. We aim to prolong the CRP to very low degrees of saturation (S) and increase its evaporation rate by pla...

Full description

Saved in:
Bibliographic Details
Published in:Journal of fluid mechanics 2024-03, Vol.983, Article A6
Main Authors: Fei, Linlin, Derome, Dominique, Carmeliet, Jan
Format: Article
Language:English
Subjects:
Capillary pressure
Carbon sequestration
Contact angle
Cooling
Design optimization
Drying
Efficiency
Evaporation
Evaporation rate
Gravity
Heterogeneity
JFM Papers
Multilayers
Nanoparticles
Pore size
Pores
Porous materials
Porous media
Pressure jump
Saturation
Wettability
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The evaporation process in porous media typically experiences three main periods, among which the first period, named the constant rate period (CRP), performs most efficiently in removing liquid. We aim to prolong the CRP to very low degrees of saturation (S) and increase its evaporation rate by playing with heterogeneity in wettability and pore size. First, we show that a porous medium with a smaller contact angle at the surface and increasing contact angle towards the inside generally dries out faster compared with that with uniform contact angle. Second, a constant contact angle porous medium with smaller/larger pores in the surface/inside part dries out faster than a medium with uniform pore size. The underlying mechanism is the occurrence of a capillary pressure jump at the border between the two layers accompanied by enhanced capillary pumping, increasing/maintaining the interfacial area in the surface pores. Harnessing the potential of this mechanism, we propose an optimized strategy by combining two heterogeneity effects: increasing contact angle and pore size towards the inside. This strategy is found to be robust both for multilayer and larger systems. In this case, a small drying front first penetrates fast towards the inside and then expands, followed by a horizontal drying front moving back layer by layer to the surface. Quantitatively, compared with evaporation from a homogeneously porous medium with uniform contact angle where CRP stops at $S=0.64$, our optimized design can extend the CRP down to $S=0.12$, and decrease five-fold the drying time needed to reach $S=0.05$.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2024.138