Litcius/Paper detail

Pore-scale Ostwald ripening of gas bubbles in the presence of oil and water in porous media

Deepak Singh, Helmer André Friis, Espen Jettestuen, Johan Olav Helland

2023Journal of Colloid and Interface Science23 citationsDOIOpen Access PDF

Abstract

HYPOTHESIS: Ostwald ripening of gas bubbles is a spontaneous mass transfer process that can impact the storage volume of trapped gas in the subsurface. In homogeneous porous media with identical pores, bubbles evolve toward an equilibrium state of equal pressure and volume. How the presence of two liquids impacts ripening of a bubble population is less known. We hypothesize that the equilibrium bubble sizes depend on the surrounding liquid configuration and oil/water capillary pressure. METHOD AND NUMERICAL EXPERIMENTS: We investigate ripening of nitrogen bubbles in homogeneous porous media containing decane and water using a level set method that alternately simulates capillary-controlled displacement and mass transfer between bubbles to eradicate chemical-potential differences. We explore impacts of initial fluid distribution and oil/water capillary pressure on the bubble evolution. FINDINGS: Ripening in three-phase scenarios in porous media stabilizes gas bubbles to sizes that depend on their surrounding liquids. Bubbles in oil decrease in size while bubbles in water increase in size with increasing oil/water capillary pressure. Bubbles in oil reach local equilibrium before the three-phase system stabilizes globally. A potential implication for field-scale gas storage is that the trapped gas fractions in oil and water vary with depth in the oil/water transition zone.

Topics & Concepts

Ostwald ripeningBubblePorous mediumMass transferChemistryCapillary actionCapillary pressureVolume (thermodynamics)Bubble pointEnhanced oil recoveryPorosityChemical engineeringThermodynamicsMaterials scienceChromatographyMechanicsNanotechnologyOrganic chemistryComposite materialEngineeringPhysicsEnhanced Oil Recovery TechniquesCO2 Sequestration and Geologic InteractionsFluid Dynamics and Mixing