Impact of water salinity differential on a crude oil droplet constrained in a capillary: Pore-scale mechanisms

•Proposed the hypothesis about water-in-oil emulsification and water diffusion through oil phase.•Measurement of oil globules movement in glass capillaries due to water diffusion.•Measured contact angle by confocal microscopy and indicated the potential of making glass surface more water-wet by low-...

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Bibliographic Details
Published in:Fuel (Guildford) 2020-08, Vol.274, p.117798, Article 117798
Main Authors: Yan, Lifei, Aslannejad, Hamed, Hassanizadeh, S. Majid, Raoof, Amir
Format: Article
Language:English
Subjects:
Capillaries
Capillary tubes
Chemical reactions
CMOS
Confocal microscopy
Contact angle
Contact angle change
Crude oil
Diameters
Droplets
Emulsification
Enhanced oil recovery
Fiber optics
Flooding
Interfaces
Low-salinity effect
Oil
Oil droplet movement
Oil recovery
Optical fibers
Osmosis
Osmotic pressure
Phases
Salinity
Salinity effects
Scanning microscopy
Time
Water diffusion
Water salinity
Water-in-oil emulsification
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Summary:•Proposed the hypothesis about water-in-oil emulsification and water diffusion through oil phase.•Measurement of oil globules movement in glass capillaries due to water diffusion.•Measured contact angle by confocal microscopy and indicated the potential of making glass surface more water-wet by low-salinity water and high-salinity water.•Monitoring pressure change of water with low and high-salinity by sensitive fiber-optic sensors.•Proposed three stages for the changes in contact angle and pressure. Low-salinity water flooding can be effectively used for enhanced oil recovery. Given the complex physical and chemical processes involved, several controlling mechanisms have been proposed to describe oil re-mobilization in the presence of water solution with low salinity. Osmosis and water-in-oil emulsification are among these mechanisms. However, our current knowledge about these processes is limited and their associated time scales are not well understood. In this study, we have used 11 capillary tubes with an inner diameter of 800 µm to inject a sequence of low-salinity water, crude oil, and high-salinity water phases and to observe the evolution of the system. The monitoring was done for a period of 40 days. We used two setups, a CMOS camera and a confocal laser scanning microscopy, to capture dynamics of the oil droplet re-mobilization as well as the 2D/3D water–oil interfaces. Additionally, microscopic pore pressures were directly measured at both low and high-salinity water phases containing the oil droplet using two fiber-optic sensors. We observed that in the water-wet capillaries the oil droplet moved a distance of about 524 µm. The contact angles at both low and high-salinity water interfaces with crude oil gradually decreased by 34.32° and 18.23°, respectively, during the first 15 days. We found that the pressure difference between high/low-salinity water phases reached a plateau with a maximum value of 1.65 kPa during a period of 24 days. Further, based on these changes and their time scales, we propose a hypothesis about emulsification and water diffusion through the oil phase.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2020.117798