Diagenetic Control on the Distribution of Porosity within the Depositional Facies of Proterozoic Rajgarh Formation, Alwar Sub-basin, Northeastern Rajasthan
Authors
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Department of Geology, Aligarh Muslim University, Aligarh - 202 002
Sadia Khanam -
Department of Geology, Aligarh Muslim University, Aligarh - 202 002
M. A. Quasim
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Department of Geology, Aligarh Muslim University, Aligarh - 202 002
A. H. M. Ahmad
DOI:
https://doi.org/10.1007/s12594-021-1752-9Keywords:
No keywordsAbstract
The sandstones of the Proterozoic Rajgarh Formation are texturally immature and compositionally sub-mature quartz arenite to arkose in composition. The reservoir quality of sandstones is strongly influenced by depositional facies and various types of diagenetic modifications. A significant reduction in primary porosity in the studied sandstone is mainly due to high mechanical compaction followed by chemical compaction rather than the cementation process. Arkose from the river-dominated estuary facies show infiltrated clay coating, feldspar dissolution, iron-oxide cementation, leaching of detrital by iron-oxide cement, kaolinization of feldspar, the fracturing of detrital, partial albitization and folding of mica. The pore-lining clay has helped in retaining primary porosity, and leaching and dissolution processes were the main process generating secondary porosity in this facies. Tidal flat sub-arkose petrofacies display compaction of micas and unstable rock fragments into the pseudomatrix, expansion of muscovite by kaolinite, and pore-filling silty matrix that occupied intergranular spaces. Quartz-arenite petrofacies from shallow marine deposit show grain replacive kaolinite, pyrite precipitation, glauconite authigenesis, muscovite bending, albitization of plagioclase, feldspar overgrowths, dissolution, and grain fracturing. Pyrite plays a significant role in the reduction of both primary and secondary porosity by precipitating in intergranular spaces and in dissolution voids of feldspar. Moreover, fractures in detrital act as a second cycle porosity generation process in the shallow marine petrofacies. The linking between the diagenetic processes and depositional facies provides a geologic model for hydrocarbon exploration through reservoir quality prediction. Therefore, the petrographic observations indicate quartz-arenite (shallow marine facies) and sub-arkosic sandstones (tidal flat facies) are the least suitable latent reservoir because of their lowest primary and secondary porosity and unconnected pore spaces. Arkosic (river-dominated estuary facies) compositions are considered to be appropriate frameworks for potential reservoir rocks. This study reveals that the depositional environment largely controls the diagenetic pathways and hence, influences the reservoir quality.
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Ajdukiewicz, J.M., Lander, R.H. (2010) Sandstone reservoir quality prediction: the state of the art. Amer. Assoc. Petrol. Geologists Studies, v.94, pp.1083–1091.
Amorosi, A. (1995) Glaucony and sequence stratigraphy: A conceptual framework of distribution In siliciclastic sequences. Jour. Sediment. Res., v.65, pp.419–442.
Banerjee S., Bansal U., Thorat A. (2016) A review on palaeogeographic implications and temporal variation in glaucony composition. Jour. Palaeogeog., v.5, pp.43–71.
Bjørlykke, K. (1998) Clay mineral diagenesis in sedimentary basins — a key to the prediction of rock properties. Examples from the North Sea Basin. Clay Minerals, v.33, pp.15–34.
Bjørlykke, K. (1999a) Principal aspects of compaction and fluid flow in mudstones. In: A. C. Aplin, A. J. Fleet and J. H. S. Macquaker (Eds.), Mud and Mudstones: Physical and Fluid Flow Properties. Geol. Soc. Spec. Publ., v. 158, pp.73–78.
Bjørlykke, K. (1999b) An overview of factors controlling rates of compaction, fluid generation and fluid flow in sedimentary basins. In: B. Jamtveit and P. Meakin (Eds.), Growth, Dissolutions and Pattern Formation in Geosystems. Kluwer Academic Publishers, The Netherlands, pp.381–404.
Bjørlykke, K. (2014) Relationships between depositional environments, burial history and rock properties. Some principal aspects of diagenetic process in sedimentary basins. Sediment. Geol., v.301, pp.1–14.
Bjørlykke, K., Aagaard, P. (1992) Clay Minerals in North Sea Sandstones. In: Houseknecht D.W., Pittman, E.D. (Eds.), Origin, Diagenesis and Petrophysics of Clay Minerals in Sandstones. SEPM Spec. Publ., v.47, pp.65–80.
Bloch, S., McGowen, J.H. (1994) Influence of depositional environment on reservoir quality prediction. In: M. D. Wilson (Ed.), Reservoir Quality Assessment and Prediction in Clastic Rocks, SEPM Short Course, no.30, pp.41–58.
Critelli, S., E. Le Pera, F. Galluzzo, S. Milli, M. Moscatelli, S. Perrotta., M. Santantonio (2007) Interpreting siliciclastic-carbonate detrital modes in foreland basin systems: An example from upper Miocene arenites of the central Apennines, Italy. Geol. Soc. Amer. Spec. Paper, no.420, pp.107–133.
Dutton, S.P., Diggs, T.N. (1990) History of quartz cementation in the Lower Cretaceous Travis Peak Formation, East Texas. Jour. Sediment. Petrol., v.60, pp.191–202.
Ehrenberg, S.N. (1989) Assessing the relative importance of compaction processes and cementation to reduction of porosity in: sandstones discussion: compaction and porosity evolution of Pliocene sandstones, Ventura Basin, California: discussion. AAPG Bull., v. 73, pp.1274–1276.
El-Ghali, M. A. K., H. Mansurbeg, S. Morad, I. Al-Aasm., G. Ajdanlisky (2006b) Distribution of diagenetic alterations in fluvial and paralic deposits within sequence stratigraphic framework: Evidence from the Petrohan terrigenous group and the Svidol Formation, Lower Triassic, NW Bulgaria. Sediment. Geol., v.190, pp.299–321.
Gluyas, J.G., Grant, S.M., Robinson A.G. (1993) Geochemical evidence for a temporal control on sandstone cementation, In: A. Horbury and A. Robinson (Eds.), Diagenesis and basin development: AAPG Studies in Geology, v.36, pp.23–33.
Gold, P. B. (1987) Textures and geochemistry of authigenic albite from Miocene sandstones, Louisiana Gulf Coast. Jour. Sediment. Petrol., v.57, pp.353–362.
Henares, S., Caracciolo, L., Cultrone, G., Fernández, J., Viseras, C. (2014) The role of diagenesis and depositional facies on pore system evolution in a Triassic outcrop analogue (SE Spain). Marine and Petrol. Geol., v.51, pp.136–151.
Houseknecht, D.W. (1988) Intergranular pressure solution in four quartzose sandstones. Jour. Sediment. Petrol., v.58, pp.228–246.
Ingersoll, R.V., Bullard, T.F., Ford, R.L., Grimm, J.P., Pickle, J.D., Sares, S.W. (1984) The effect of grain size on detrital modes: A test of the Gazzi Dickinson point counting method. Jour. Sediment. Petrol., v.54, pp.103–116.
Islam, M.A. (2009) Diagenesis and reservoir quality of Bhuban sandstones (Neogene), Titas gas field, Bengal Basin, Bangladesh. Jour. Asian Earth Sci., v.35, pp.89–100.
Jokhan, R. (2003) Frontier basins: A major thrust area in Indian energy scenario, “new challenges in hydrocarbon research and exploration”. CSIR Diamond Jubilee Workshop III, NGRI, Hyderabad.
Kaur, P., Zeh, A., Chaudhri, N., Tiwana, J.K. (2020) First Evidence of Late Paleoproterozoic/Early Mesoproterozoic Sediment Deposition and Magmatism in the Central Aravalli Orogen (NW India). Jour. Geol., v.128, pp.109–129.
Ketzer, J.M., M. Holz, S. Morad., I. Al-Aasm (2003a) Sequence stratigraphic distribution of diagenetic alterations in coal-bearing, paralic sandstones: Evidence from the Rio Bonito Formation (Early Permian), southern Brazil: Sedimentology, v.50, pp.855–877.
Ketzer, J. M., S. Morad., A. Amorosi (2003b) Predictive diagenetic clay-mineral distribution in siliciclastic rocks within a sequence stratigraphic framework. In: R.H. Worden and S. Morad (Eds.), Clay cements in sandstones. Internat. Assoc. Sedimentol. Spec. Publ., v.34, pp.42–59.
Khanam, S., Quasim, M.A., Ahmad, A.H.M., Ghosh, S.K. (2020) Sedimentation in a Rifted Basin: Insights from the Proterozoic Rajgarh Siliciclastics, Delhi Supergroup, Northeastern Rajasthan. Jour. Geol. Soc. India, v.95(2), pp.117–130.
Khanna, M., Bjørlykke, K., Saigal, G.C. (1997) Controls of depositional facies and meteoric flux on kaolinitisation in Upper Triassic — Lower Jurassic sandstones of the North Sea: Implication for prediction of reservoir quality. In: Montanez, I.P., Gregg, J.M., Shelton, K.L. (Eds.), Basinwide Diagenetic Patterns: Integrated Petrologic. Geological and Hydrologic Considerations: SEPM Spec. Publ., v.57, pp.253–268.
Kyser, T.K., Hiatt, E., Renac, C., Durocher, K, Holk, G., Deckart, K. (2000) Diagenetic fluids in Paleo-and Meso-Proterozoic sedimentary basins and their implications for long protracted fluid histories. Mineral. Assoc. Canada Short Course, no.28, pp.225–262.
Lundegard, P.D. (1992) Sandstone porosity loss- a ‘big picture’ view of the importance of compaction. Jour. Sediment. Petrol., v.62, pp.250–260.
Mcbride, E.F., Diggs, T.N., Wilson, J.C. (1991) Compaction of Wilcox and Carrizo sandstones (Paleocene-Eocene) to 4420 m, Texas Gulf Coast. Jour. Sediment. Petrol., v.61, pp.73–85.
McBride, E.F., (1963) A classification of common sandstones. Jour. Sediment. Res., v.33(3), pp.664–669.
McRae, S. (1972) Glauconite. Earth-Science Rev., v.8, pp.397–440.
Meisler, H., Leahy, P.P., Knobel, L.L. (1984) Effect of eustatic sea-level changes on saltwater-freshwater in the North Atlantic Coast Plain. USGS Water-Supply Paper no.2255, p.27.
Morad, S., Al-Ramadan, K., Ketzer, J.M., De Ros, L.F. (2010) The impact of diagenesis on the heterogeneity of sandstone reservoirs: a review of the role of depositional facies and sequence stratigraphy. AAPG Bull., v.94, pp.1267–1309.
Morad, S., Bergan, M., Knarud, R., Nystuen, J.P. (1990) Albitization of detrital plagioclase in Triassic reservoir sandstone from the Snorre field, Norwegian North Sea. Jour. Sediment. Petrol., v.60, pp.411–425.
Morad, S., Ketzer, J.M., De Ros, L.F. (2000) Spatial and temporal distribution of diagenetic alterations in siliciclastic rocks: implications for mass transfer in Sedimentary Basins. Sedimentol., v. 47, pp.95–120.
Moraes, M.A.S., De Ros, L.F. (1990) Infiltrated clays in fluvial Jurassic sandstones of Reconcavo basin, northeastern Brazil. Jour. Sediment. Petrol., v.60, pp.810–815.
Odin, G., Matter, A. (1981) De glauconiarum origine. Sedimentol., v.28, pp.611–641.
Ollier, C.D., Galloway, R.W. (1990) The laterite profile ferricrete and unconformity. Catena, v.17, pp.97–109.
Quasim, M.A., Ghosh, S.K., Ahmad, A.H.M. (2019) Petrography and diagenetic evolution of the proterozoic Kaimur Group sandstones, Son Valley, India: Implication towards reservoir quality. In: Geological Evolution of the Precambrian Indian Shield. Springer, Cham., pp.515–550.
Quasim, M.A., Khan, S., Srivastava, V.K., Ghaznavi, A.A., Ahmad, A.H.M. (2021) Role of cementation and compaction in controlling the reservoir quality of the Middle to Late Jurassic Sandstones, Jara dome, Kachchh Basin, western India. Geol. Jour., v.56(2), pp.976–994.
Roy, A.B., Jakhar, S.R. (2002) Geology of Rajasthan (Northwest India) Precambrian to Recent. India: Scientific Publishers, 421p
Roy, A.B. (1988) Stratigraphic and tectonic framework of the Aravalli Mountain Range. In: Precambrian of the Aravalli Mountain, Rajasthan, India. Mem. Geol. Soc. India, v. 7, pp.3–31.
Singh, S.P. (1982) Palaeotectonics and sedimentation trend of the Delhi Supergroup around Rajgarh, northeastern Rajasthan. Jour. Indian Assoc. Sedimentol., v.3, pp.29–44.
Singh, S.P. (1984) Fluvial sedimentation of the Proterozoic Alwar group in the Lalgarh graben, Northwestern India. Sediment. Geol., v.39, pp.95–119.
Singh, S.P. (1988) Sedimentation patterns of the Proterozoic Delhi Supergroup, Northeastern Rajasthan, India, and their tectonic implications. Sediment. Geol., v.58, pp.79–94.
Sinha-Roy, S. (1984) Precambrain crustal interaction in Rajasthan NW India. Indian Journal of Earth Sciences, CEISM Seminar Volume. pp.84–91.
Taylor, J. M. (1950) Pore space reduction in sandstone. AAPG Bull., v.34, pp.710–716.
Williams, P.J. (1998) An introduction to the metallogeny of the McArthur River-Mount Isa-Cloncurry minerals province. Econ. Geol., v.93, pp.1120–1131.
Worden, R.H., Morad, S. (2000) Quartz cementation in oil field sandstone: a review of the key controversies. In: Worden, R.H., Morad, S. (Eds.), Quartz Cementation in Sandstone. Internat. Assoc. Sedimentol. Spec. Publ., no.29, pp.1–20.
Worden, R.H., Oxtoby, N.H., Smalley, P.C. (1998) Can oil emplacement prevent quartz cementation in sandstones? Petrol. Geosci., v. 4, pp.129–137.
