The Effect of Monovalent Ions on the Oil/Brine Electrical Behavior Using a Novel Surface Complexation Model

Oil/brine electrical behavior could control the wettability of the oil/brine/rock system during low salinity water flooding. However, there is a lack of understanding of chemical reactions occurring on the oil surface. There are a few surface complexation models (SCMs) for the oil/brine interface, a...

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Bibliographic Details
Published inJournal of petroleum science and technology Vol. 13; no. 1; pp. 49 - 61
Main Author Farhadi, Hmaed
Format Journal Article
LanguageEnglish
Published Tehran Research Institute of Petroleum Industry 01.02.2023
Reaserch Institute of Petroleum Industry
Subjects
Brines
Calcium chloride
Carboxylic acids
Chemical reactions
complexation model
Crude oil
interfacial tension
Ions
Salinity
Sodium chloride
Sodium sulfate
surface chemistry
zeta potential
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Summary:Oil/brine electrical behavior could control the wettability of the oil/brine/rock system during low salinity water flooding. However, there is a lack of understanding of chemical reactions occurring on the oil surface. There are a few surface complexation models (SCMs) for the oil/brine interface, and all of them assume that the surface site density is a fixed number, like the mineral surface. The current study assessed two existing models on this subject (Model A and B). These models ignore the dynamic nature of the oil/brine interface. Therefore, they failed to capture experimentally measured ζ potentials appropriately. Therefore, this study constructed a novel diffuse layer SCM (Model C) considering the interfacial concentration of surface carboxylic acid as a function of brine salinity for each salt, including NaCl, Na2SO4, CaCl2, MgCl2, and NaHCO3. Model C matches the experimental data of the literature far better than A and B. Based on Model C, Na+, Cl-, and SO42- cannot be adsorbed on the oil/brine interface; however, the role of these ions in the electrical behavior of crude oil/brine is only to affect the interfacial concentration of -COOH. For example, an increase in Na+ reduced the oil/brine IFT. Therefore, more carboxylic groups would be available at the oil/brine interface. As a result, -COO- concentration increases, and the crude oil surface becomes more negatively charged. The current study indicated that Ca2+ and Mg2+ are not the only factors that make the interface more positively charged. However, an increase in IFT (in this study by salinity reduction) significantly makes the oil/brine interface more positive, too.
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ISSN:2251-659X
2645-3312
DOI:10.22078/jpst.2023.5197.1894