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Pore-scale study of water salinity effect on thin-film stability for a moving oil droplet.

Authors :
Abu-Al-Saud, Moataz O.
Esmaeilzadeh, Soheil
Riaz, Amir
Tchelepi, Hamdi A.
Source :
Journal of Colloid & Interface Science. Jun2020, Vol. 569, p366-377. 12p.
Publication Year :
2020

Abstract

• A pore-level numerical investigation and a subgrid scale lubrication model for studying thin-films is presented. • The water salinity and solid roughness effects are studied for the thin-film stability. • A physical map quantifying the dependency of thin-film stability on salinity and roughness is presented. • Novelty of the work is at capturing the electric double layer effects at the pore-scale. • This work can well serve as a physical basis for studying water salinity effects at larger scales. The interfacial dynamics in natural porous media are affected not only by the interplay between viscous and capillary forces but also the solid surface wettability. It has been hypothesized that the wettability alteration induced by changes in the water salinity is primarily caused by electric double-layer force expansion, which strongly affects the multiphase flow dynamics. We investigate the effect of water ionic composition and surface roughness on pore-scale wettability alteration. Multiphase hydrodynamics is numerically captured by a lubrication approximation describing the evolution of thin-films coupled with a multiscale level-set approach. An oil blob mobilized by water within a single pore is considered as a case study. The effect of brine ionic composition is accounted for by an electric double-layer through the water ionic strength and zeta-potential parameters. We demonstrate that high-salinity water thin-films collapse to an adsorbed nanometer layer, leading to a large pressure drop during mobilization of the blob induced by the attractive surface forces. However, low-salinity water thin-films are stable due to the repulsive electric double-layer forces, leading to less pressure drop during mobilization of the blob. The novelty of this work lies in efficiently capturing the nanoscale effects of the electric double-layer in pore-scale multiphase flow displacements. Our quantitative investigations provide fundamental insights into the efficiency of low-salinity waterflooding. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
00219797
Volume :
569
Database :
Academic Search Index
Journal :
Journal of Colloid & Interface Science
Publication Type :
Academic Journal
Accession number :
142537272
Full Text :
https://doi.org/10.1016/j.jcis.2020.02.044