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.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.References
Alvarez, A.C., Bruining, J., Lambert, W.J., Marchesin, D.: Analytical and numerical solutions for carbonated waterflooding. Comput. Geosci. 22(2), 505–526 (2018)
Al-Shalabi, E.W., Sepehrnoori, K., Delshad, M., Pope, G.: A novel method to model low-salinity-water injection in carbonate oil reservoirs. SPE J. 20(05), 1154–1166 (2015)
Al-Shalabi, E.W., Sepehrnoori, K., Pope, G.: Geochemical interpretation of low-salinity-water injection in carbonate oil reservoirs. SPE J. 20(06), 1212–1226 (2015)
Alvarez, A.C., Bruining, J., Marchesin, D.: Nonlinear wave interactions in geochemical modeling. J. Differ. Equ. 359, 1–22 (2023)
Alvarez, A.C., Goedert, G.T., Marchesin, D.: Resonance in rarefaction and shock curves: local analysis and numerics of the continuation method. J. Hyperbolic Differ. Equ. 17(04), 639–676 (2020)
Alvarez, A.C., Blom, T., Lambert, W.J., Bruining, J., Marchesin, D.: Analytical and numerical validation of a model for flooding by saline carbonated water. J. Pet. Sci. Eng. 167, 900–917 (2018)
Appelo, C., Anthony, J., Postma, D.: Geochemistry, Groundwater and Pollution. Taylor & Francis (2005)
Appelo, C.A.J.: Cation and proton exchange, \(pH\) variations, and carbonate reactions in a freshening aquifer. Water Resour. Res. 30(10), 2793–2805 (1994)
Ayirala, S.C., Yousef, A.A.: A state-of-the-art review to develop injection-water-chemistry requirement guidelines for ior/eor projects. SPE Prod. Oper. 30(01), 26–42 (2015)
Bonto, M., Eftekhari, A.A., Nick, H.M.: An overview of the oil-brine interfacial behavior and a new surface complexation model. Sci. Rep. 9(1), 1–16 (2019)
Bordeaux-Rego, F., Mehrabi, M., Sanaei, A., Sepehrnoori, K.: Improvements on modelling wettability alteration by engineered water injection: surface complexation at the oil/brine/rock contact. Fuel. 284, 118991 (2021)
Brady, P.V., Krumhansl, J.L., Mariner, P.E.: Surface complexation modeling for improved oil recovery. In: SPE Improved Oil Recovery Symposium, pp. SPE 153744
Bruining, H.: Upscaling of Single-and Two-Phase Flow in Reservoir Engineering. CRC Press (2021)
Bryant, S.L., Schechter, R.S., Lake, L.W.: Interactions of precipitation/dissolution waves and ion exchange in flow through permeable media. AIChE J. 32(5), 751–764 (1986)
Bryant, S.L., Schechter, R.S., Lake, L.W.: Mineral sequences in precipitation/dissolution waves. AIChE J. 33(8), 1271–1287 (1987)
Buckley, S.E., Leverett, M.: Mechanism of fluid displacement in sands. Trans. AIME. 146(01), 107–116 (1942)
Christensen, R.J.: Carbonated waterflood results–Texas and Oklahoma. In: Annual Meeting of Rocky Mountain Petroleum Engineers of AIME. OnePetro (1961)
De Nevers, N.: A calculation method for carbonated water flooding. Soc. Pet. Eng. J. 4(01), 9–20 (1964)
Dong, Y., Dindoruk, B., Ishizawa, C., Lewis, E., Kubicek, T.: An experimental investigation of carbonated water flooding. In: SPE Annual Technical Conference and Exhibition. OnePetro
Dubey, S.T., Doe, P.H.: Base number and wetting properties of crude oils. SPE Reserv. Eng. 8(3), 195–200 (1993)
Dumoré, J.M., Hagoort, J., Risseeuw, A.S.: An analytical model for one-dimensional, three-component condensing and vaporizing gas drives. Soc. Pet. Eng. J. 24(02), 169–179 (1984)
Ebeltoft, E., Lomeland, F., Brautaset, A., Haugen, Å.: Parameter based scal-analysing relative permeability for full field application. In: International Symposium of the Society of Core Analysis, Avignon, France, pp. 8–11 (2014)
Elakneswaran, Y., Shimokawara, M., Nawa, T., Takahashi, S.: Surface complexation and equilibrium modelling for low salinity waterflooding in sandstone reservoirs. In: Abu Dhabi International Petroleum Exhibition & Conference. OnePetro (2017)
Erzuah, S., Fjelde, I., Omekeh, A.V.: Wettability estimation using surface-complexation simulations. SPE Reserv. Eval. Eng. 22(02), 509–519 (2019)
Erzuah, S., Fjelde, I., Omekeh, A.V.: Modelling low-salinity waterflooding: effect of divalent cations and capillary pressure. J. Pet. Sci. Eng. 149, 1–8 (2017)
Farajzadeh, R., Matsuura, T., van Batenburg, D., Dijk, H.: Detailed modeling of the alkali/surfactant/polymer (ASP) process by coupling a multipurpose reservoir simulator to the chemistry package PHREEQC. SPE Reserv. Eval. Eng. 15(04), 423–435 (2012)
Foroozesh, J., Jamiolahmady, M., Sohrabi, M.: Mathematical modeling of carbonated water injection for EOR and CO2 storage with a focus on mass transfer kinetics. Fuel. 174, 325–332 (2016)
Ginn, D.: Effects of potential determining ions and \(pH\) on the wettability of intermediate wet outcrop limestone. Master’s thesis, University of Stavanger, Norway (2020)
Glimm, J.: Solutions in the large for nonlinear hyperbolic systems of equations. Commun. Pur. Appl. Math. 18(4), 697–715 (1965)
Grogan, A.T., Pinczewski, W.V.: The role of molecular diffusion processes in tertiary CO\(_2\) flooding. J. Pet. Technol. 39(05), 591–602 (1987)
Hassan, A.M., Ayoub, M., Eissa, M., Bruining, H., Zitha, P.: Study of surface complexation modeling on a novel hybrid enhanced oil recovery (eor) method; smart-water assisted foam-flooding. J. Pet. Sci. Eng. 195, 107563 (2020)
Helfferich, F.G.: The theory of precipitation/dissolution waves. AIChE J. 35(1), 75–87 (1989)
Hirasaki, G., Zhang, D.L.: Surface chemistry of oil recovery from fractured, oil-wet, carbonate formation. In: International Symposium on Oilfield Chemistry. OnePetro (2003)
Honarpour, M.M.: Relative Permeability of Petroleum Reservoirs. CRC press (1986)
Jerauld, G.R., Webb, K.J., Lin, C.Y., Seccombe, J.C.: Modeling low-salinity waterflooding. SPE Reserv. Eval. Eng. 11(06), 1000–1012 (2008)
Jerauld, G.R., Lin, C.Y., Webb, K.J., Seccombe, J.C.: Modeling low-salinity waterflooding. SPE Reserv. Eval. Eng. 11(06), 1000–1012 (2008)
Johns, R.T., Dindoruk, B., Orr, F.M., Jr.: Analytical theory of combined condensing/vaporizing gas drives. SPE Adv. Technol. Ser. 1(02), 7–16 (1993)
Korrani, A.K., Jerauld, G.R., Sepehrnoori, K.: Mechanistic modeling of low-salinity waterflooding through coupling a geochemical package with a compositional reservoir simulator. SPE Reserv. Eval. Eng. 19(01), 142–162 (2016)
Korrani, A.K., Jerauld, G.R.: Modeling wettability change in sandstones and carbonates using a surface-complexation-based method. J. Pet. Sci. Eng. 174, 1093–1112 (2019)
Kumar, S., Mandal, A.: A comprehensive review on chemically enhanced water alternating gas/CO\(_2\) (CEWAG) injection for enhanced oil recovery. J. Pet. Sci. Eng. 157, 696–715 (2017)
Lake, L.W.: Enhanced Oil Recovery. Prentice Hall Inc. (1989)
Lake, L.W., Johns, R.T., Rossen, W.R., Pope, G.A.: Fundamentals of Enhanced Oil Recovery. Society of Petroleum Engineers, Richardson (2014)
Lambert, W.J., Alvarez, A.C., Matos, V., Marchesin, D., Bruining, J.: Nonlinear wave analysis of geochemical injection for multicomponent two phase flow in porous media. J. Differ. Equ. 266(1), 406–454 (2019)
Lax, P.D.: Hyperbolic systems of conservation laws II. Commun. Pur. Appl. Math. 10(4), 537–566
Leverett, M.C.: Flow of oil-water mixtures through unconsolidated sands. Trans. AIME. 132(01), 149–171 (1939)
Liu, T.P.: The Riemann problem for general 2\(\times \) 2 conservation laws. Trans. Am. Math. Soc. 199, 89–112
Liu, T.P.: The Riemann problem for general systems of conservation laws. J. Differ. Equ. 18(1), 218–234 (1975)
Lomeland, F., Ebeltoft, E., Hasanov, B.: A versatile representation of upscaled relative permeability for field applications (spe 154487). In: 74th EAGE Conference and Exhibition incorporating EUROPEC 2012, pp. cp–293. European Association of Geoscientists & Engineers (2012)
Lutzenkirchen, J.: Surface Complexation Modelling. Elsevier (2006)
Marmier, N., Dumonceau, J., Fromage, F.: Surface Complexation Modeling of yb (iii) sorption and desorption on hematite and alumina. J. Contam. Hydrol. 26(1–4), 159–167 (1997)
Mehdiyev, F., Erzuah, S., Omekeh, A., Fjelde, I.: Surface Complexation Modelling of wettability alteration during carbonated water flooding. Energies. 15(9), 3020 (2022)
Mehraban, M.F., Ayatollahi, S., Sharifi, M.: Experimental investigation on synergic effect of salinity and ph during low salinity water injection into carbonate oil reservoirs. J. Petrol. Sci. Eng. 202, 108555 (2021)
Merkel, B.J.: Groundwater Geochemistry. Springer (2005)
Nowrouzi, I., Manshad, A.K., Mohammadi, A.H.: Effects of dissolved binary ionic compounds and different densities of brine on interfacial tension (ift), wettability alteration, and contact angle in smart water and carbonated smart water injection processes in carbonate oil reservoirs. J. Mol. Liq. 254, 83–92 (2018)
Oleinik, O.A.: Discontinuous solutions of non-linear differential equations. Usp. Matematicheskikh Nauk. 12(3), 3–73 (1957)
Omekeh, A., Friis, H.A., Fjelde, I., Evje, S.: Modeling of ion-exchange and solubility in low salinity water flooding. In: SPE Improved Oil Recovery Symposium. OnePetro (2012)
Parkhurst, D.L., Appelo, C.A.J.: User’s guide to PHREEQC (version 2): A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations (1999)
Parkhurst, D.L., Appelo, C.A.J.: Description of input and examples for PHREEQC version 3a computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations (2013)
Pope, G.A.: The application of fractional flow theory to enhanced oil recovery. Soc. Pet. Eng. J. 20(03), 191–205 (1980)
Sanaei, A., Tavassoli, S., Sepehrnoori, K.: Investigation of modified water chemistry for improved oil recovery: application of DLVO theory and surface complexation model. Colloids Surf. A Physicochem. Eng. Asp. 574, 131–145 (2019)
Sanaei, A., Varavei, A., Sepehrnoori, K.: Mechanistic modeling of carbonated waterflooding. J. Petrol. Sci. Eng. 178, 863–877
Sari, A., Chen, Y., Xie, Q., Saeedi, A.: Low salinity water flooding in high acidic oil reservoirs: Impact of \(pH\) on wettability of carbonate reservoirs. J. Mol. Liq. 281, 444–450 (2019)
Sheng, J.J.: Enhanced oil recovery field case studies. Gulf Professional Publishing (2013)
Sohrabi, M., Riazi, M., Jamiolahmady, M., Ireland, S., Brown, C.: Mechanisms of oil recovery by carbonated water injection. In: SCA annual meeting (2009)
Stumm, W., Morgan, J.J.: Aquatic Chemistry: Chemical Equilibria and Rates in Natural Waters, vol. 126. John Wiley & Sons (2012)
Welge, H.J., Johnson, E.F., Ewing, S.P., Jr., Brinkman, F.H.: The linear displacement of oil from porous media by enriched gas. J. Petrol. Technol. 13(08), 787–796 (1961)
Wolthers, M., Charlet, L., Van Cappellen, P.: The surface chemistry of divalent metal carbonate minerals; a critical assessment of surface charge and potential data using the charge distribution multi-site ion complexation model. Am. J. Sci. 308(8), 905–941 (2008)
Xie, Q., Sari, A., Pu, W., Chen, Y., Brady, P.V., Al Maskari, N., Saeedi, A.: pH effect on wettability of oil/brine/carbonate system: Implications for low salinity water flooding. J. Petrol. Sci. Eng. 168, 419–425 (2018)
Yousef, A.A., Al-Saleh, S., Al-Jawfi, M.: Smart waterflooding for carbonate reservoirs: Salinity and role of ions. In: SPE Middle East Oil and Gas Show and Conference. OnePetro (2011)
Yousef, A.A., Al-Saleh, S., Al-Jawfi, M.: Improved/enhanced oil recovery from carbonate reservoirs by tuning injection water salinity and ionic content. In: SPE Improved Oil Recovery Symposium. OnePetro (2012)
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.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
There are no conflicts of competing interests.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
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
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10596-024-10274-1