Abstract
The success and failure of different chemical enhanced oil recovery (CEOR) techniques can control to a large extent by the presence of different types of clay, its surface area and the reactivity of the clay with the injected chemicals during CEOR techniques. Therefore, reservoir clay analysis is important to study the CEOR process in general and to formulate the CEOR slug in particular. This study pertains to the underground porous media of upper Assam basin. In this paper effective porosity, absolute permeability, minerals and clays present in porous media is studied. Effective porosities were determined to estimate the total pore volume and more importantly the connecting pores and the throat volumes. The absolute permeability are exclusively the properties of the porous media, which determines the ease of flow of fluid through the porous media. Rock petrography study was done by examining the thin sections under optical microscope, Scanning Electron Microscope (SEM) and X-ray Diffractometer (XRD). From these studies the mineral and clay content of the reservoir was characterized, which helps to study the feasibility of a CEOR in upper Assam basin. This petrography study provides two and three dimensional accurate description of minerals of reservoir rock and clay particles. The porous media is a sandstone with high porosity and low absolute permeability. The clays present are smectite, kaolinite and illite with a dominance of smectite and kaolinite, conforming to the swelling and disintegration.
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References
Ahmed, T. (2001) Reservoir Engineering Handbook, second edition, Gulf Professional Publishing.
Aksulu, H., Hamso, D., Strand, S., Puntervold, T., Austad, T. (2012) Evaluation of Low-Salinity Enhanced Oil Recovery Effects in Sandstone: Effects of the Temperature and pH Gradient. Energy Fuels, v.26, pp.3497–3503.
Allard, B., Karlsson, M., Tullborg, E.-L., Larson, S.A. (1983) Ion Exchange Capacities and Surface Areas of Some Major Components and Common Fracture Filling Materials of Igneous Rocks; KBS Technical Reports; Goteborg, Sweden.
Anovitz, L.M. (2015) Characterization and Analysis of Porosity and Pore Structures. Rev. Mineral. Geochem., v.80, pp.61–164
Baker, Paul, A. (2007) Dolomite rock, McGraw Hill Encyclopedia of Science & Technology. 10th Edition. McGraw-Hill, v.5, pp.654–655.
Borgohain, P., Hazarika, S., Gilfellon, G.B., Gogoi, M.P. (2011) Petrography and Diagenesis of the Upper Palaeocene-Lower Eocene rocks of Nahorkatiya oilfield Assam. Curr. Sci., v.101, pp.664–669
Brady, P. V., Morrow, N. R., Fogden, A., Deniz, V., Loahardjo, N., Winoto (2015) Electrostatics and the Low Salinity Effect in Sandstone Reservoirs. Energy Fuels, v.29, pp.666–677.
Burgos, W. D., Pisutpaisal, N., Mazzarese, M.C., Chorover (2002) Adsorption of quinoline to kaolinite and montmorillonite. Jour. Environ. Engg. Sci., v. 19(2), pp.59–68.
Caillere, S., Henin, S., Rautureau, M. (1982) Structure et proprietes physicochimiques, 2nd ed.; Masson: Paris, France
Collins, M.J., Bishop, A.N., Farrimond, P. (1995) Sorption by mineral surfaces: rebirth of the classical condensation pathway for kerogen formation? Geochim. Cosmochim. Acta, v.59(11), pp.2387–2391.
Das, B.M. (2014) A study on Micellar/Alkaline/Polymer (MAP) processes, with special reference to Natural Porous Media of some oil fields of Upper Assam Basin. Ph.D. Thesis, Department of Petroleum Technology, Dibrugarh University.
Das, B.M. and Gogoi, S. B. (2015) Relating IFT with Oil Recovery with Special Reference to BhogparaPorous Media of Upper Assam Basin. Jour. Engg. Tech., v.5, pp.1–8.
Fan, H.F., Zhang, Y., Lin, Y.J. (2004) The catalytic effects of minerals on aqua thermolysis of heavy oils. Fuel, v.83, pp.2035–2039.
Gogoi, S.B. (2007) Flow through porous media with special reference to Enhanced Oil Recovery of Oil India Ltd., Duliajan PhD thesis, Dibrugarh University, 42p.
Gogoi, S.B. (2009a) Adsorption of Non-petroleum Base Surfactant on Reservoir Rock. Curr. Sci., v.97, pp.1059–1063.
Gogoi, S.B. (2009b) Revisiting Naharkatiya Core Sample for Enhanced oil Recovery. Indian Jour. Petroleum Geol., v.18, pp.51–61.
Gogoi, S.B. (2010a) Adsorption of a Lignin-based Surfactant on Naharkatiya Porous Media. Indian Chemical Engineer Jour., v.52, pp.1–11.
Gogoi, S.B. (2010b) Characterization of Vesicle for Enhanced Oil Recovery. Indian Jour. Chemical Tech., v. 17, pp.282–290.
Gogoi, S.B. (2011) Adsorption-Desorption of Surfactant for Enhanced oil Recovery. Transport in Porous Media, v.90, pp.589–604.
Guojun, C., Guichao, D., Gongcheng, Z. (2011) Chlorite cement and its effect on the reservoir quality of sandstones from the Panyu low-uplift, Pearl River Mouth Basin. Pet. Sci., v.8, pp.143–150.
Hirasaki, G., Zhang, D.L. (2003) Surface chemistry of oil recovery from fractured, oil-wet, carbonate formations. In: International Symposium on Oilfield Chemistry, Houston, Texas, pp.5–7
Howari, F.M., Baghdady, A.B., Goodell, P.C. (2007) Mineralogical and geomorphologic characterization of sand dunes in the eastern part of United Arab Emirates using orbital remote sensing integrated with field investigations. Geomorphology, v.83, pp.67–81.
Hu, X., Hu, S., Jin, F. (2017) Physics of Petroleum Reservoirs. Springer Berlin Heidelberg ix, 506p.
International Drilling Fluids (IDF), (1982) Clay chemistry. In Technical Manual; International Drilling Fluids Limited: Aberdeen, UK
John, S., Loring, H., Todd Schaef, (2019) Experimental Studies of Reactivity and Transformations of Rocks and Minerals in Water-Bearing Supercritical CO2. In: Science of Carbon Storage in Deep Saline Formations. Elsevier, pp.63–88.
John, W., Morse, Fred, T., Mackenzie, (1990) Chapter 8 Carbonates as Sedimentary Rocks in Subsurface Processes. Developments in Sedimentology, Geochemistry of Sedimentary Carbonates, pp.373–446
Karpinski, B., and Szkodo, M. (2015) Clay Minerals — Mineralogy and Phenomenon of Clay Swelling in Oil & Gas Industry. Poland: Gdansk University of Technology.
Lei, H.Y., Shi, Y.S., Guang, P., Fang, X. (1997) Catalysis of aluminosilicate clay minerals to the formation of the transitional zone gas. Science in China, Series D, Earth Sciences, v. 40(2), pp.130–136
Liu, S., Zhang, D., Yan, W., et. al. (2008) Favorable attributes of alkaline-surfactant-polymer flooding. SPE Jour., v.13(1), pp.5–16
Lindholm, R.C. (1987) A practical approach to Sedimentology, CBS Publishers and Distributors, Delhi.
Mallick, R.K., Raju, S.V., Mathur, N. (1997) Geochemical characterization and genesis of Eocene crude oils in a part of Upper Assam Basin, India. In: Proceedings Second International Petroleum Conference & Exhibition, PETROTECH-97: New Delhi, v.1, pp.391–402.
Mathur, N., Raju, S.V., and Kulkarni, T.G. (2001) Improved identification of pay zones through integration of geochemical and log data—A case study from Upper Assam basin, India: AAPG Bull., v.85(2), pp.309–323.
Murty, K.N. (1983) Geology and hydrocarbon prospects of Assam Shelf— Recent advances and present status: Petroleum Asia Jour., v.6(4), pp.1–14.
Mohan, K.K., Vaidyab, R.N., Reed, M.G., Fogler, H.S. (1993) Water sensitivity of sandstones containing swelling and non-swelling clays. Colloids and Surfaces A: Physicochemical and Engineering Aspect, Elsevier Science Publishers B.V. pp.237–254, Amsterdam 73.
Mungan, N. (1965) Penneability Reduction Throug Changes in pH and Salinity, Trans., AIME, v.234, pp.1449–1453.
Murray, H.H. (2000) Traditional and new applications for kaolin, smectite, and palygorskite: A general overview. Appl. Clay Sci., v. 17, pp.207–221.
Naidu, B.D., Panda, B.K. (1997) Regional source rock mapping in upper Assam Shelf, in Proceedings of the Second International Petroleum Conference and Exhibition, PETROTECH-97: New Delhi, 1, pp.350–364.
Pal, S., Mushtaq, M., Banat, F. et al. (2018) Review of surfactant-assisted chemical enhanced oil recovery for carbonate reservoirs: challenges and future perspectives. Pet. Sci., v.15, pp.77–102.
Paul, G. (2001) Petrophysics MSc Course Notes.
Puntervold, T., Mamonov, A., Aghaeifar, Z., Frafjord, G. O., Moldestad, G. M., Strand, S. and Austad, T. (2018) Role of Kaolinite Clay Minerals in Enhanced Oil Recovery by Low Salinity Water Injection. Energy & Fuels, v.32(7), pp.7374–7382
Rangaroo, A. (1983) Geology and hydrocarbon potential of a part of Assam-Arakan basin and its adjacent region: Petroleum Asia Jour., v.6(4), pp.1–14.
Rodrigues, A.G., Goldberg, K. (2014) Primary composition and diagenetic patterns of sandstones from Barra de Itiuba Formation in Atalaia High, Sergipe Sub-Basin. Braz. Jour. Geol., v.44(4), pp.545–560.
Seethepalli, A., Adibhatla, B., Mohanty, K.K., 2004, Physicochemical interactions during surfactant flooding of fractured carbonate reservoirs. SPE Jour., v.9(4), pp.411–418.
Somerton, W.H., Radke, C.J. (1983) Role of Clays in the Enhanced Recovery of Petroleum from Some California Sands. Jour. Petrol. Tech., v.35(03), pp.643–654.
Strand, S.; Puntervold, T.; Austad, T. (2016) Water based EOR from clastic oil reservoirs by wettability alteration: A review of chemical aspects. Jour. Petrol. Sci. Engg., v.146, pp.1079–1091
Wandrey, C.J. (2004) Sylhet-Kopili/Barail-Tipam Composite Total Petroleum System, Assam Geologic Province, India, Petroleum Systems and Related Geologic Studies in Region 8, South Asia.
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Sincere thanks and gratitude are expressed by the authors to Oil India Ltd. for providing the reservoir cores samples and crude oils of the oilfield of Upper Assam. Special thanks goes to DST project no SB/S3/CE/057/2013 for financial support for this study.
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Hazarika, K., Gogoi, S.B. Clay Analysis of Upper Assam Basin for Chemical Enhanced Oil Recovery. J Geol Soc India 97, 138–144 (2021). https://doi.org/10.1007/s12594-021-1644-z
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DOI: https://doi.org/10.1007/s12594-021-1644-z