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Modeling low saline carbonated water flooding including surface complexes

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Abstract

Carbonated water flooding (CWI) increases oil production due to favorable dissolution effects and viscosity reduction. Accurate modeling of CWI performance requires a simulator with the ability to capture the true physics of such process. In this study, compositional modeling coupled with surface complexation modeling (SCM) are done, allowing a unified study of the influence in oil recovery of reduction of salt concentration in water. The compositional model consists of the conservation equations of total carbon, hydrogen, oxygen, chloride and decane. The coefficients of such equations are obtained from the equilibrium partition of chemical species that are soluble both in oleic and the aqueous phases. SCM is done by using the PHREEQC program, which determines concentration of the master species. Estimation of the wettability as a function of the Total Bound Product (TBP) that takes into account the concentration of the complexes in the aqueous, oleic phases and in the rock walls is performed. We solve analytically and numerically these equations in \(1-\)D in order to elucidate the effects of the injection of low salinity carbonated water into a reservoir containing oil equilibrated with high salinity carbonated water.

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Acknowledgements

We would like to express our sincere gratitude to the reviewers for their constructive feedback and insightful comments, which greatly enhanced the quality and depth of our manuscript. The authors are grateful to Ali A. Eftekhari for reviewing the calculations carried out using the PHREEQC program. Additionally, they would like to thank Sergio Pilotto for his support and acknowledge the funding received from CAPES under grant 88881.156518/2017-01 and CAPES/NUFFIC grant 88887.156517/2017-00, CNPq under grants 405366/2021-3 and 306566/2019-2, and FAPERJ under grants E-26/210.738/2014, E-26/202.764/2017, and E-26/201.159/2021.

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Alvarez, A., Bruining, J. & Marchesin, D. Modeling low saline carbonated water flooding including surface complexes. Comput Geosci 28, 373–393 (2024). https://doi.org/10.1007/s10596-024-10274-1

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