Search Advanced

Networks and Heterogeneous Media

2010, Volume 5, Issue 2: 217-256. doi: 10.3934/nhm.2010.5.217
Previous Article Next Article

A mathematical model for dynamic wettability alteration controlled by water-rock chemistry

  • 1.
    University of Stavanger (UiS), 4036 Stavanger
  • 2.
    International Research Institute of Stavanger (IRIS), Prof. Olav Hanssensvei 15, NO-4068 Stavanger
  • Received: 01 November 2009 Revised: 01 March 2010

  • Primary: 76T10, 76N10, 65M12, 35L65.

  • Previous experimental studies of spontaneous imbibition on chalk core plugs have shown that seawater may change the wettability in the direction of more water-wet conditions in chalk reservoirs. One possible explanation for this wettability alteration is that various ions in the water phase (sulphate, calcium, magnesium, etc.) enter the formation water due to molecular diffusion. This creates a non-equilibrium state in the pore space that results in chemical reactions in the aqueous phase as well as possible water-rock interaction in terms of dissolution/precipitation of minerals and/or changes in surface charge. In turn, this paves the way for changes in the wetting state of the porous media in question. The purpose of this paper is to put together a novel mathematical model that allows for systematic investigations, relevant for laboratory experiments, of the interplay between (i) two-phase water-oil flow (pressure driven and/or capillary driven); (ii) aqueous chemistry and water-rock interaction; (iii) dynamic wettability alteration due to water-rock interaction.
       In particular, we explore in detail a 1D version of the model relevant for spontaneous imbibition experiments where wettability alteration has been linked to dissolution of calcite. Dynamic wettability alteration is built into the model by defining relative permeability and capillary pressure curves as an interpolation of two sets of end point curves corresponding to mixed-wet and water-wet conditions. This interpolation depends on the dissolution of calcite in such a way that when no dissolution has taken place, mixed-wet conditions prevail. However, gradually there is a shift towards more water-wet conditions at the places in the core where dissolution of calcite takes place. A striking feature reflected by the experimental data found in the literature is that the steady state level of oil recovery, for a fixed temperature, depends directly on the brine composition. We demonstrate that the proposed model naturally can explain this behavior by relating the wettability change to changes in the mineral composition due to dissolution/precipitation. Special attention is paid to the effect of varying, respectively, the concentration of SO24 ions and Mg2+ ions in seawater like brines. The effect of changing the temperature is also demonstrated and evaluated in view of observed experimental behavior.

    Citation: Steinar Evje, Aksel Hiorth. A mathematical model for dynamic wettability alteration controlled by water-rock chemistry[J]. Networks and Heterogeneous Media, 2010, 5(2): 217-256. doi: 10.3934/nhm.2010.5.217

    Related Papers:

  • Previous experimental studies of spontaneous imbibition on chalk core plugs have shown that seawater may change the wettability in the direction of more water-wet conditions in chalk reservoirs. One possible explanation for this wettability alteration is that various ions in the water phase (sulphate, calcium, magnesium, etc.) enter the formation water due to molecular diffusion. This creates a non-equilibrium state in the pore space that results in chemical reactions in the aqueous phase as well as possible water-rock interaction in terms of dissolution/precipitation of minerals and/or changes in surface charge. In turn, this paves the way for changes in the wetting state of the porous media in question. The purpose of this paper is to put together a novel mathematical model that allows for systematic investigations, relevant for laboratory experiments, of the interplay between (i) two-phase water-oil flow (pressure driven and/or capillary driven); (ii) aqueous chemistry and water-rock interaction; (iii) dynamic wettability alteration due to water-rock interaction.
       In particular, we explore in detail a 1D version of the model relevant for spontaneous imbibition experiments where wettability alteration has been linked to dissolution of calcite. Dynamic wettability alteration is built into the model by defining relative permeability and capillary pressure curves as an interpolation of two sets of end point curves corresponding to mixed-wet and water-wet conditions. This interpolation depends on the dissolution of calcite in such a way that when no dissolution has taken place, mixed-wet conditions prevail. However, gradually there is a shift towards more water-wet conditions at the places in the core where dissolution of calcite takes place. A striking feature reflected by the experimental data found in the literature is that the steady state level of oil recovery, for a fixed temperature, depends directly on the brine composition. We demonstrate that the proposed model naturally can explain this behavior by relating the wettability change to changes in the mineral composition due to dissolution/precipitation. Special attention is paid to the effect of varying, respectively, the concentration of SO24 ions and Mg2+ ions in seawater like brines. The effect of changing the temperature is also demonstrated and evaluated in view of observed experimental behavior.


  • This article has been cited by:

    1. Maria Bonto, Ali Akbar Eftekhari, Hamid Nick, 2019, A Calibrated Model for the Carbonate-Brine-Crude Oil Surface Chemistry and its Effect on the Rock Wettability, Dissolution, and Mechanical Properties, 10.2118/193865-MS
    2. Mirhossein Taheriotaghsara, Ali A. Eftekhari, Hamidreza M. Nick, Adsorption- and Diffusion-Controlled Wettability Change in Modified Salinity Water Flooding, 2020, 34, 0887-0624, 13767, 10.1021/acs.energyfuels.0c02493
    3. Adedapo Noah Awolayo, Hemanta Kumar Sarma, Long X. Nghiem, Thermodynamic Modeling of Brine Dilution-Dependent Recovery in Carbonate Rocks with Different Mineralogical Content, 2018, 32, 0887-0624, 8921, 10.1021/acs.energyfuels.8b01080
    4. Emad W. Al-Shalabi, Kamy Sepehrnoori, A comprehensive review of low salinity/engineered water injections and their applications in sandstone and carbonate rocks, 2016, 139, 09204105, 137, 10.1016/j.petrol.2015.11.027
    5. Adedapo N. Awolayo, Hemanta K. Sarma, Long X. Nghiem, 2017, A Comprehensive Geochemical-Based Approach at Modeling and Interpreting Brine Dilution in Carbonate Reservoirs, 10.2118/182626-MS
    6. Abdulla Aljaberi, Mehran Sohrabi, 2019, A New Approach to Simulate Low Salinity Water Flooding in Carbonate Reservoir, 10.2118/195081-MS
    7. Fabio Bordeaux-Rego, Mehran Mehrabi, Alireza Sanaei, Kamy Sepehrnoori, Improvements on modelling wettability alteration by Engineered water injection: Surface complexation at the oil/brine/rock contact, 2021, 284, 00162361, 118991, 10.1016/j.fuel.2020.118991
    8. Shuang Gong, Xiaojun Li, Wen Wang, Shibin Yao, Juan Liu, Dengyun Niu, Roger Serra, Effects of Acidic Environment on Dynamic Mechanical Properties and Porosity Evolution Characteristics of Coal, 2021, 2021, 1875-9203, 1, 10.1155/2021/1149550
    9. Emad Walid Al Shalabi, Kamy Sepehrnoori, 2017, 9780128136041, 73, 10.1016/B978-0-12-813604-1.00006-7
    10. P.Ø. Andersen, S. Evje, M.V. Madland, A. Hiorth, A geochemical model for interpretation of chalk core flooding experiments, 2012, 84, 00092509, 218, 10.1016/j.ces.2012.08.038
    11. Lawrence Opoku Boampong, Roozbeh Rafati, Amin Sharifi Haddad, Modelling of carbonate rock wettability based on surface charge and calcite dissolution, 2023, 331, 00162361, 125856, 10.1016/j.fuel.2022.125856
    12. M. Fouad Snosy, Mahmoud Abu El Ela, Ahmed El-Banbi, Helmy Sayyouh, Comprehensive investigation of low salinity waterflooding in carbonate reservoirs, 2022, 12, 2190-0558, 701, 10.1007/s13202-021-01330-y
    13. S. Evje, A. Hiorth, A model for interpretation of brine-dependent spontaneous imbibition experiments, 2011, 34, 03091708, 1627, 10.1016/j.advwatres.2011.09.003
    14. Emad W. Al-Shalabi, Kamy Sepehrnoori, Mojdeh Delshad, Gary Pope, 2014, A Novel Method to Model Low Salinity Water Injection in Carbonate Oil Reservoirs, 10.2118/169674-MS
    15. Steinar Evje, An integrative multiphase model for cancer cell migration under influence of physical cues from the microenvironment, 2017, 165, 00092509, 240, 10.1016/j.ces.2017.02.045
    16. Arman Namaee-Ghasemi, Hassan Shokrollah-zadeh Behbahani, Shahin Kord, Amin Sharifi, Simulation and analysis of dynamic wettability alteration and correlation of wettability-related parameters during smart water injection in a carbonate core, 2021, 331, 01677322, 115741, 10.1016/j.molliq.2021.115741
    17. Emad Walid Al Shalabi, Kamy Sepehrnoori, 2017, 9780128136041, 25, 10.1016/B978-0-12-813604-1.00004-3
    18. Emad W. Al-Shalabi, Kamy Sepehrnoori, Gary Pope, 2014, An Improved Method for Estimating Volumetric Sweep Efficiency of Low Salinity Water Injection, 10.2118/172279-MS
    19. María Bonto, Ali A. Eftekhari, Hamidreza M. Nick, Wettability Indicator Parameter Based on the Thermodynamic Modeling of Chalk-Oil-Brine Systems, 2020, 34, 0887-0624, 8018, 10.1021/acs.energyfuels.0c00716
    20. Arman Namaee-Ghasemi, Hassan Shokrollah-zadeh Behbahani, Shahin Kord, Amin Sharifi, Geochemical simulation of wettability alteration and effluent ionic analysis during smart water flooding in carbonate rocks: Insights into the mechanisms and their contributions, 2021, 326, 01677322, 114854, 10.1016/j.molliq.2020.114854
    21. Pål ØstebØ Andersen, Rajib Ahsan, Steinar Evje, Fred Bratteli, Merete Madland, Aksel Hiorth, 2013, A Model for Brine-Dependent Spontaneous Imbibition Experiments with Porous Plate, 10.2118/164901-MS
    22. Emad W. Al-Shalabi, Kamy Sepehrnoori, Mojdeh Delshad, 2013, Does the Double Layer Expansion Mechanism Contribute to the LSWI Effect on Hydrocarbon Recovery from Carbonate Rocks?, 10.2118/165974-MS
    23. Adedapo Awolayo, Hemanta Sarma, Long Nghiem, Brine-Dependent Recovery Processes in Carbonate and Sandstone Petroleum Reservoirs: Review of Laboratory-Field Studies, Interfacial Mechanisms and Modeling Attempts, 2018, 11, 1996-1073, 3020, 10.3390/en11113020
    24. Emad W. Al-Shalabi, Kamy Sepehrnoori, Gary Pope, Geochemical Investigation of the Combined Effect of Injecting Low Salinity Water and Carbon Dioxide on Carbonate Reservoirs, 2014, 63, 18766102, 7663, 10.1016/j.egypro.2014.11.800
    25. A. Hiorth, E. Jettestuen, L.M. Cathles, M.V. Madland, Precipitation, dissolution, and ion exchange processes coupled with a lattice Boltzmann advection diffusion solver, 2013, 104, 00167037, 99, 10.1016/j.gca.2012.11.019
    26. Ganxing Zhang, Juliana Y. Leung, Design of injected water salinity for enhanced oil recovery applications in sandstone reservoirs using coupled flow-geochemical simulation, 2023, 224, 29498910, 211614, 10.1016/j.geoen.2023.211614
    27. Zahra Negahdari, Mohammad R. Malayeri, Mojtaba Ghaedi, Sabber Khandoozi, Masoud Riazi, Gradual or Instantaneous Wettability Alteration During Simulation of Low-Salinity Water Flooding in Carbonate Reservoirs, 2021, 30, 1520-7439, 495, 10.1007/s11053-020-09726-z
    28. Moataz Abu-Al-Saud, Salah Al-Saleh, Subhash Ayirala, Ali Yousef, 2020, Simulation of Advanced Waterflooding in Carbonates Using a Surface Complexation-Based Multiphase Transport Model, 10.2118/200366-MS
    29. Lawrence Opoku Boampong, Roozbeh Rafati, Amin Sharifi Haddad, Evaluation of sour gas-low salinity waterflooding in carbonate reservoirs - A numerical simulation approach, 2022, 20962495, 10.1016/j.ptlrs.2022.10.003
    30. Arman Namaee-Ghasemi, Shahab Ayatollahi, Hassan Mahani, Pore-Scale Simulation of the Interplay between Wettability, Capillary Number, and Salt Dispersion on the Efficiency of Oil Mobilization by Low-Salinity Waterflooding, 2021, 26, 1086-055X, 4000, 10.2118/206728-PA
    31. Emad W. Al-Shalabi, Kamy Sepehrnoori, Gary Pope, Numerical modeling of combined low salinity water and carbon dioxide in carbonate cores, 2016, 137, 09204105, 157, 10.1016/j.petrol.2015.11.021
    32. E. W. Al-Shalabi, K.. Sepehrnoori, G.. Pope, K.. Mohanty, 2014, A Fundamental Model for Predicting Oil Recovery Due to Low Salinity Water Injection in Carbonate Rocks, 10.2118/SPE-169911-MS
    33. Aruoture Omekeh, Helmer André Friis, Ingrebet Fjelde, Steinar Evje, 2012, Modeling of Ion-Exchange and Solubility in Low Salinity Water flooding, 10.2118/154144-MS
    34. Rahul Samala, Abhijit Chaudhuri, R. Vishnudas, Jakka Yeswanth, V. Selvam, Numerical analysis of viscous fingering and oil recovery by surfactant and polymer flooding in five-spot setup for water and oil-wet reservoirs, 2020, 6, 2363-8419, 10.1007/s40948-019-00124-1
    35. Adedapo Awolayo, Hemanta Sarma, Long Nghiem, Gorucu Emre, 2017, A Geochemical Model for Investigation of Wettability Alteration during Brine-Dependent Flooding in Carbonate Reservoirs, 10.2118/188219-MS
    36. Rohit Kumar Saw, Ajay Mandal, A mechanistic investigation of low salinity water flooding coupled with ion tuning for enhanced oil recovery, 2020, 10, 2046-2069, 42570, 10.1039/D0RA08301A
    37. Nikoo Moradpour, Peyman Pourafshary, Davood Zivar, Experimental analysis of hybrid low salinity water alternating gas injection and the underlying mechanisms in carbonates, 2021, 202, 09204105, 108562, 10.1016/j.petrol.2021.108562
    38. Lawrence Opoku Boampong, Roozbeh Rafati, Amin Sharifi Haddad, A calibrated surface complexation model for carbonate-oil-brine interactions coupled with reservoir simulation - Application to controlled salinity water flooding, 2022, 208, 09204105, 109314, 10.1016/j.petrol.2021.109314
    39. Fabio Bordeaux Rego, Mehran Mehrabi, Alireza Sanaei, Kamy Sepehrnoori, 2020, Improvements on Modelling Wettability Alteration by Engineered Water Injection: Geochemical Pore-Scale Approach, 10.2118/200361-MS
    40. Emad W. Al-Shalabi, Kamy Sepehrnoori, Gary Pope, New mobility ratio definition for estimating volumetric sweep efficiency of low salinity water injection, 2015, 158, 00162361, 664, 10.1016/j.fuel.2015.06.018
    41. Nikoo Moradpour, Marzhan Karimova, Peyman Pourafshary, Davood Zivar, Effects of Slug Size, Soaking, and Injection Schemes on the Performance of Controlled Ions Water Flooding in Carbonates, 2020, 5, 2470-1343, 18155, 10.1021/acsomega.0c01766
    42. E. W. Al-Shalabi, K. Sepehrnoori, M. Delshad, Numerical Simulation of the LSWI Effect on Hydrocarbon Recovery From Carbonate Rocks, 2015, 33, 1091-6466, 595, 10.1080/10916466.2014.1003940
    43. Lawrence Opoku Boampong, Roozbeh Rafati, Amin Sharifi Haddad, Modelling of Carbonate Rock Wettability Based on Surface Charge and Calcite Dissolution, 2022, 1556-5068, 10.2139/ssrn.4097551
    44. Rohit Kumar Saw, Ajay Mandal, Experimental investigation on fluid/fluid and rock/fluid interactions in enhanced oil recovery by low salinity water flooding for carbonate reservoirs, 2023, 352, 00162361, 129156, 10.1016/j.fuel.2023.129156
    45. Sivalingam SM, V. Govindaraj, A novel numerical approach for time-varying impulsive fractional differential equations using theory of functional connections and neural network, 2024, 238, 09574174, 121750, 10.1016/j.eswa.2023.121750
    46. Rishabh Tripathi, Bidesh Kumar Hembram, Krishna Raghav Chaturvedi, Tushar Sharma, Vishnu Chandrasekharan Nair, Evaluating the role of salts on wettability alteration in dolomite rocks: Possibility of water based oil mobilization application, 2023, 388, 01677322, 122738, 10.1016/j.molliq.2023.122738
    47. Mohsen Farhadzadeh, Maria Bonto, Hamidreza M. Nick, Pore-Scale Modeling of Heterogeneous Carbonate Rock Subjected to Modified Salinity Waterflooding, 2024, 38, 0887-0624, 6821, 10.1021/acs.energyfuels.3c04103
    48. Pouriya Almasiyan, Hassan Mahani, A Bond-Product-Sum (BPS) Approach for Modeling Wettability Alteration and Enhanced Oil Recovery by Engineered Salinity Waterflooding in Carbonate Rocks, 2024, 38, 0887-0624, 5007, 10.1021/acs.energyfuels.3c05055
    49. Ali Maghsoudian, Amin Izadpanahi, Zahra Bahmani, Amir Hossein Avvali, Ali Esfandiarian, Utilizing deterministic smart tools to predict recovery factor performance of smart water injection in carbonate reservoirs, 2025, 15, 2045-2322, 10.1038/s41598-024-84402-3
    50. Belay Gulte Mino, Chengdong Yuan, Rustam N. Sagirov, Mikhail A. Varfolomeev, Decoding smart water flooding: pH, ion composition, salinity, and aging dynamics in sandstone reservoir cores, 2025, 423, 01677322, 127007, 10.1016/j.molliq.2025.127007
  • Reader Comments
  • © 2010 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)
通讯作者: 陈斌, bchen63@163.com
  • 1. 

    沈阳化工大学材料科学与工程学院 沈阳 110142

  1. 本站搜索
  2. 百度学术搜索
  3. 万方数据库搜索
  4. CNKI搜索
Networks and Heterogeneous Media
1.2 1.8

Metrics

Article views(5004) PDF downloads(249) Cited by(50)

Preview PDF
Download XML
Export Citation
Article outline
Abstract

Other Articles By Authors

Related pages

Tools

/

DownLoad:  Full-Size Img  PowerPoint
Return
Return

Catalog