Microfacies and sedimentary environment of the Mishan Formation in the Shahdadi Area, the southeast of the Zagros Basin (N Bandarabbas)

Document Type : مقالات پژوهشی

Authors

1 Graduate University of Advanced Technology

2 Payame Noor University of Kerman, Zangiabad BranchD

3 Hormozgan

Abstract

Introduction
The Zagros structural Zone is an important structural zone in the Middle East because of its valuable and enormous hydrocarbon reservoirs. In this zone, the Fars Group is a key stratigraphic unit; which consists of valuable reservoir and cap rocks. The Mishan Formation is the middle member of the Fars Group, was deposited in the Zagros Basin during the Early Miocene to Pliocene. The facies changes of the Mishan Formation in the Zagros basin is considerable and interesting for researchers. One of the unique lithofacies of this formation is the Guri Member, which is out cropped in the Hormozgan province in many of anticlines. In the Hormozgan province, the Mishan Formation is poorly studied because of harsh climatic condition and accessibility, therefore, there are few published literatures have been carried out about it (Heidari et al., 2014a, b; Rashidi et al., 2014a, b).
To consider the microfacies and reconstructing the depositional environment of this formation in the southeast of the Zagros Basin, a stratigraphic section of this formation in the Shahdadi Area has been chosen and sampled. The studied section locates at 27° 29ˊ 1.5 ̋ N & 56° 43ˊ 30  ̋ E near the Shahdadi area, 105 km north of the Bandar Abbas. The main surrounded unites include Cenozoic strata of the Zagros basin. The studied section overlays the Razak Formation and underline by the Aghajari Formation unconformably.
 
Materials and methods
The total thickness of the studied section is 446 m, 78 loos and 236 hard samples have been collected from the Mishan Formation strata. For microfacies analyses, thin sections prepared from hard samples. The loos samples have disaggregated by sodium sulfate solution and frizzing method and Sodium Hexa Meta Phosphate solution for micropaleontological and grain size analyzes. The microfacies have named after Dunham (1962) and Carozzi (1989). The faunal content and grain size of the marly strata compared with Geel (2000), BouDagher-Fadel (2008).
 
Discussion
Based on the lithostratigraphic analyzes, tow lithofacies, include limestone lithofacies and marl lithofacies have been distinguished. The limestone lithofacies involves three rock unites and includes nine microfacies (L1-L9) base on the carbonate components and textural characteristics. These microfacies have been compared with the Wilson (1975) and Flugel (2010) standard microfacies. This comparison shows that the identified microfacies have deposited in intra tidal, restricted lagoon, sand shoal, path reef, non-restricted lagoon and open marine facies belts. The marl lithofacies, based on the faunal content and grain size analyzes, includes deposits of the restricted lagoon, non-restricted lagoon and open marine environments and involves tow rock unites. The charactristics of identified facies belts, such as lateral extend, lack of the onchoids, pizzoids, aggregates and turbidities have suggest a homoclinal carbonate ramp as the sedimentary model in the studied area for the Mishan Formation. This platform can be divided to distinct facies associations include inner ramp, middle ramp and outer ramp.
The inner ramp facies association includes intra tidal, restricted lagoon and sand shoal facies belts; the middle ramp facies association includes non-restricted lagoon and patch reef facies belts and the outer ramp facies association includes open marine facies belt. Deposits of the non-restricted lagoon, restricted lagoon and open marine facies belts are the most common deposits in the studied section respectively, which are deposited in deepening upward cycles.
 
Conclusion
The field, microfacies and micropaleontological studies show that the Mishan Formation in the Shahdadi area, the north of Bandarabbas, overlays the Razak Formation’s clastic strata unfonformably. This formation underlays by the Aghajari formation unconformably and the effects of erosional activities are observed at the top of the Mishan formation. The Mishan Formation in the studied area consists of three limestone and tow marl rock unites and considerably includes the Guri Member. The microfacies analyses of the marly and limestone strata suggest a hemoclinal carbonate ramp as the sedimentary model for the Mishan Formation in this area. The suggested ramp includes inner ramp, middle ramp and outer ramp facies assemblages and intra tidal, restricted lagoon, sand shoal, non restricted lagoon, patch reef and open marine facies belts.
 
Key words: Mishan Formation; Microfacies; Depositional environment; Zagros; Shahdadi.
 
References
Carozzi, A.V., 1989. Carbonate rocks depositional model. Prentice, Hall, New Jersey, 1-604.
Dunham, R.J., 1962. Classification of carbonate rocks according to depositional texture. In proceeding of symposium of American Association Petroleum Geologist, New York, 108-121.
Flugel, E., 2010. Microfacies of Carbonate Rocks, Analysis, Interpretation and Application. Springer-Verlag Berlin, 1-976.
Geel, T., 2000. Recognition of stratigraphic sequences in carbonate platform and slope deposits, empirical models based on microfacies analysis of paleogene deposits in southeastern Spin. Palaeogeography, Palaeoclimatology, Palaeoecology, 155: 211-238.
Heidari, A., Gonzalez, L.A., Mahboubi, A., Moussavi-Harami, R., Ludvigson, G.A., & Chakrapani, G.J., 2014 a. Diagenetic Model of Carbonate Rocks of Guri Member of Mishan Formation (Lower to Middle Miocene) SE Zagros Basin, Iran. Journal of the Geological Society of India, 84 (1): 87-104.
Heidari, A., Mahboubi, A., Moussavi-Harami, R., Gonzalez, L., & Moalemi, S.A., 2014 b. Biostratigraphy, sequence stratigraphy, and paleoecology of the Lower-Middle Miocene of Northern Bandar Abbas, Southeast Zagros basin in south of Iran. Arabian Journal of Geosciences, 7 (5): 1829-1855.
Rashidi, R.F., Vaziri, S.H., Khaksar, K., & Gholamalian, H., 2014 a. Lithostratigraphy of the Mishan Formation in North and West of Hormozgan province (South of Iran). MAGNT Research Report, 2 (7): 490-499.
Rashidi, R.F., Vaziri, S.H., Khaksar, K., & Gholamalian, H., 2014 b. Microfacies and sedimentary environment of the early-middle Miocene deposits (Mishan Formation) in south of Iran. Advances in Environmental Biology, 1031-1040.
Wilson, J.L., 1975. Carbonate Facies in Geologic History. Springer-Verlag, New York, 1-472.

Keywords

References

احمدی، و.، قربانی، م.، توللی، ر.، 1390. مطالعه محیط رسوبی سازند میشان در جنوب باختر بستگ استان هرمزگان. دومین همایش علوم زمین.
آقانباتی، ع.، 1385. زمین شناسی ایران. سازمان زمین شناسی و اکتشافات معدنی کشور، 603 ص.
فخاری، م.، 1374. نقشه زمین شناسی چهارگوش 1:250000 بندرعباس. شرکت ملی نفت ایران.
لاسمی، ی.، رستگار لاری، ع.ر.، 1385. محیط رسوبی و چینه‌نگاری سکانسی سازند میشان (رسوبات جلوی کمربند چین‌خورده) در باختر فارس و خاور بوشهر. فصلنامه علوم زمین، 61: 68-77.
Adabi, M.H., Kakemem, U., & Sadeghi, A., 2016. Sedimentary facies, depositional environment, and sequence stratigraphy of Oligocene-Miocene shallow water carbonate from the Rig Mountain, Zagros basin (SW Iran). Carbonates and Evaporites, 31 (1): 69-85.
Ahr, W.M., 1973. The carbonate ramp: an alternative to the shelf model. Gulf Coast Association of Geological Societies Transactions, 23: 221-225.
Andjić, G., Baumgartner-Mora, C., & Baumgartner, P.O., 2016. An upper Paleogene shallowing-upward sequence in the southern Sandino Forearc Basin (NW Costa Rica): Response to tectonic uplift. Facies, 62 (9): 1-35.
Aronson, R.B., 2007. Geological Approaches to Coral Reef Ecology. Springer, Berlin, 1-457.
Assadi, A., Honarmand, J., Moallemi, S.A., & Abdollahie-Fard, I., 2016. Depositional environments and sequence stratigraphy of the Sarvak Formation in an oil field in the Abadan Plain, SW Iran. Facies, 62 (4): 26.
Barattolo, F., Bassi, D., & Romano, R., 2007. Upper Eocene larger foraminiferal-coralline algal facies from the Klokova Mountain (south continental Greece). Facies, Berlin, 53: 361-375.
Beavington-Penney, S.J., & Racey, A., 2004. Ecology of extant nummulitids and other larger benthic foraminifera: applications in paleoenvironmental analysis. Earth Science Review, 67: 219-265.
BouDagher-Fadel, M.K., 2008. Evolution and geological significance of larger benthic foraminifera. Elsewier, Netherlands, 1-571.
BouDagher-Fadel, M.K., 2013. Biostratigraphic and geological significance of planktonic foraminifera. UCL Press, London, 1-299.
Beresi, M.S., Cabaleri, N.G., Löser, H., & Armella, C., 2017. Coral patch reef system and associated facies from southwestern Gondwana: paleoenvironmental evolution of the Oxfordian shallow-marine carbonate platform at Portada Covunco, Neuquen Basin, Argentina. Facies, Berlin, 63 (1): 4-16.
Carozzi, A.V., 1989. Carbonate rocks depositional model. Prentice, Hall, New Jersey, 1-604.
Daraei, M., Amini, A., & Ansari, M., 2015. Facies analysis and depositional environment study of the mixed carbonate-evaporite Asmari Formation (Oligo-Miocene) in the sequence stratigraphic framework, NW Zagros, Iran. Carbonates and Evaporites, 30 (3): 253-272.
Dunham, R.J., 1962. Classification of carbonate rocks according to depositional texture. In proceeding of symposium of American Association Petroleum Geologist, New York, 108-121.
Einsele, G., 1982. Limestone-marl cycles (periodites): diagnosis, significance, causes-a review. In: Einsele, G., & Seilacher, A., (eds.), Cyclic and event stratification. Springer, Berlin, 8-53.
Fanati, R.R., Vaziri, S.H., Khaksar, K., & Gholamalian, H., 2015. Paleoecology of early to middle Miocene deposits (Guri Member) and sedimentary environment, SE Zagros Zone, Roydar, Iran. Iranian Journal of Earth Sciences, 7: 68-77.
Flugel, E., 2010. Microfacies of Carbonate Rocks, Analysis. Interpretation and Application. Springer-Verlag Berlin, 1-976.
Geel, T., 2000. Recognition of stratigraphic sequences in carbonate platform and slope deposits, empirical models based on microfacies analysis of paleogene deposits in southeastern Spin. Palaeogeography, Palaeoclimatology, Palaeoecology, 155: 211-238.
Heidari, A., Gonzalez, L.A., Mahboubi, A., Moussavi-Harami, R., Ludvigson, G.A., & Chakrapani, G.J., 2014 a. Diagenetic Model of Carbonate Rocks of Guri Member of Mishan Formation (Lower to Middle Miocene) SE Zagros Basin, Iran. Journal of the Geological Society of India, 84 (1): 87-104.
Heidari, A., Mahboubi, A., Moussavi-Harami, R., Gonzalez, L., & Moalemi, S.A., 2014 b. Biostratigraphy, sequence stratigraphy, and paleoecology of the Lower-Middle Miocene of Northern Bandar Abbas, Southeast Zagros basin in south of Iran. Arabian Journal of Geosciences, 7 (5): 1829-1855.
Hutchison, C.S., 2004. Marginal basin evolution: the southern South China Sea. Marine and Petroleum Geology, 21 (9): 1129-1148.
Jamalian, M., & Adabi, M.H., 2015. Geochemistry, microfacies and diagenetic evidences for original aragonite mineralogy and open diagenetic system of Lower Cretaceous carbonates Fahliyan Formation (Kuh-e Siah area, Zagros Basin, South Iran). Carbonates and Evaporites, 30 (1): 77-98.
James, G.A., & Wynd, G.G., 1965. Stratigraphic Nomenclature of Iranian Oil Consortium Agreement Area. American Association of Petroleum Geologists, 49 (12): 2182-2245.
Johari, M.M., & Ghasemi-Nejad, E., 2017. Paleoenvironment, Biostratigraphy and sequence stratigraphic studies of the Permian-Triassic boundrary of the offshore Persian Gulf, Iran: using an integrated approach. Geopersia, 7 (1): 35-54.
Kietzmann, D.A., Palma, R.M., Riccardi, A.C., Martin-Chivelet, J., & Lopez-Gomez, J., 2014. Sedimentology and sequence stratigraphy of a Tithonian-Valanginian carbonate ramp (Vaca Muerta Formation): A misunderstood exceptional source rock in the Southern Mendoza area of the Neuquen Basin, Argentina. Sedimentary Geology, 302: 64-86.
Martin, R.E., 2000. Environmental Micropaleontology: The Application of Microfossils to Environmental Geology. Kluwer Academic/ Plenum Publishers, New York, 1-345.
Martinuš, M., Fio, K., Pikelj, K., & Aščić, Š., 2013. Middle Miocene warm-temperate carbonates of Central Paratethys (Mt. Zrinska Gora, Croatia): paleoenvironmental reconstruction based on bryozoans, coralline red algae, foraminifera, and calcareous nannoplankton. Facies, 59 (3): 481-504.
Mazaheri Johari, M., & Ghasemi-Nejad, E., 2017. Paleoenvironment, Biostratigraphy and sequence stratigraphic studies of the Permian-Triassic boundrary of the offshore Persian Gulf, Iran: using an integrated approach. Geopersia 7 (1): 35-54.
Mial, A.D., 1984 Principles of sedimentary Basin Analysis. Springer Science+ Business Media, New York, 1-457.
Miall, A.D., & Tyler, N., 1991. The three-dimensional facies architecture of terrigenous clastic sediments and its implications for hydrocarbon discovery and recovery. Society for Sedimentary Geology, New York, 1-313.
Molinaro, M., Guezou, J.C., Leturmy, P., Eshraghi, S.A., & de Lamotte, D.F., 2004. The origin of changes in structural style across the Bandar Abbas syntaxis, SE Zagros (Iran). Marine and Petroleum Geology, 21 (6): 735-752.
Motiei, H., 1993. Stratigraphy of Zagros. In: Treatise on the geology of Iran. No. 1. Ministry of Mines and Metals. Geological Society of Iran Publications, Tehran.
Murray, J.W., 2006. Ecology and Applications of Benthic Foraminifera. Cambridge University Press, New York, 1-440.
Nebelsick, J.H., Rasser, M., & Bassi, D., 2005. Facies dynamic in Eocene to Oligocene Circumalpine carbonates. Facies, 51 (4): 197-216.
Novak, V., Santodomingo, N., Rösler, A., Di Martino, E., Braga, J.C., Taylor, P.D., Johnson, K.G., & Renema, W., 2013. Environmental reconstruction of a late Burdigalian (Miocene) patch reef in deltaic deposits (East Kalimantan, Indonesia). Palaeogeography, Palaeoclimatology, Palaeoecology, 374: 110-122.
Racey, A., 1994. Biostratigraphy and palaeobiogeographic significance of Tertiary nummulitids (foraminifera) from northern Oman. In: Simmons, M.D., (ed.), Micropalaeontology and Hydrocarbon Exploration in the Middle East. Chapman and Hall, London, 343-370.
Rashidi, R.F., Vaziri, S.H., Khaksar, K., & Gholamalian, H., 2014 a. Lithostratigraphy of the Mishan Formation in North and West of Hormozgan province (South of Iran). MAGNT Research Report, 2 (7): 490-499.
Rashidi, R.F., Vaziri, S.H., Khaksar, K., & Gholamalian, H., 2014 b. Microfacies and sedimentary environment of the early-middle Miocene deposits (Mishan Formation) in south of Iran. Advances in Environmental Biology, 1031-1040.
Reineck, H.E., & Singh, I.B., 1975. Depositional Sedimentary Environments. Springer, Netherland, 1-431.
Romero, J., Caus, E., & Rossel, J., 2002. A model for the paleoenvironmental distribution of larger foraminifera based on late Middle Eocene deposites on the margin of the south Pyrenean basin. Palaeogeography, Palaeoclimatology, Palaeoecology, 179: 43-56.
Roozpeykar, A., & Maghfouri Moghaddam, I., 2016. Benthic foraminifera as biostratigraphical and paleoecological indicators: An example from Oligo-Miocene deposits in the SW of Zagros basin, Iran. Geoscience Frontiers, 7: 125-140.
Sadeghi, R., Vaziri-Moghaddam, H., & Mohammadi, E., 2017. Biofacies, depositional model, and sequence stratigraphy of the Asmari Formation, Interior Fars sub-zone, Zagros Basin, SW Iran. Carbonates and Evaporites, In Press, 1-19.
Sadeghi, R., Vaziri-Moghaddam, H., & Taheri, A., 2010. Microfacies and sedimentary environment of the Oligocene sequence (Asmari Formation) in Fars sub-basin, Zagros Mountains, southwest Iran. Facies, 57 (3): 431-446.
Sadeghi, R., Vaziri-Moghaddam, H., & Taheri, A., 2009. Biostratigraphy and paleoecology of the Oligo-Miocene succession in Fars and Khuzestan areas (Zagros Basin, SW Iran). Historical Biology 21: 17-3.
Sahy, D., Sasaran, E., & Tamas, T., 2008. Microfacies analysis of Upper Eocene shallow-water carbonates from the Rodnei Mountains (N Romania). Studia UBB Geologia, 53 (2): 13-24.
Sooltanian, N., Seyrafian, A., & Vaziri-Moghaddam, H., 2011. Biostratigraphy and paleo-ecological implications in microfacies of the Asmari Formation (Oligocene), Naura anticline (Interior Fars of the Zagros Basin), Iran. Carbonates Evaporates, 26: 167-180.
Thunell, R., Rio, D., Sprovieri, R., & Raffi, I., 1991. Limestone-marl couplets: origin of the early Pliocene Trubi marls in Calabria, southern Italy. Journal of Sedimentary Research, 61(7): 15-36
Walker, P., & Wood, E., 2005. The Coral Reef. Facts and File, Inc., New York, 1-158.
Westphal, H., 2006. Limestone-marl alternations as environmental archives and the role of early diagenesis: a critical review. International Journal of Earth Sciences, 95 (6): 947-961.
Westphal, H., & Munnecke, A., 2003. Limestone-marl alternations: A warm-water phenomenon? Geology, 31 (3): 263-266.
Wilson, J. L., 1975. Carbonate Facies in Geologic History. Springer-Verlag, New York, 1-472.
Zvy, D., & Stambler, N., 2011. Coral Reefs: An Ecosystem in Transition. Springer, Berlin, 1-562.
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 11 March 2017
  • Accept Date: 11 March 2017

Share

How to cite

Statistics