Tectono-sedimentary environment of Upper Jurassic evaporite-carbonate deposits in the Ravar Zone, south of Tabas Block

Document Type : Original Article

Authors

1 Department of Geology, Faculty of Sciences, University of Sistan and Baluchestan, Zahedan, Iran

2 Department of Geology, Faculty of Earth Sciences, Shahid Beheshti University, Tehran, Iran

Abstract

Extended abstract
The Ravar terrane, is situated at the south of the Tabas block. At the Ravar series Mesozoic strata, especially the Jurassic carbonate- evaporite deposits known as Pectinid limestone, Magu gypsum and Bido red evaporates are the most important parts of this deposits and have a variety of facies, distribution, and suitable exposure. Upper Jurassic Sequence stratigraphy of the mentioned deposits were messed up and even their position on the geological maps are not coherently elaborated. So investigation on the sedimentary environment and tectonic controller factors will be a great help in understanding the sequence stratigraphy position of these deposits. Thickness of mostly shale, interbedded Pectinid limestone, gypsiferous marl, red gypsum to white and finally red evaporates sequences were measured 470, 725, 50, more than 1450 (possibly contains Hojedk and Baghamshah Formations), and 1300 m, respectively. Eleven indicator facies were identified in the studied deposits which ended in tidal flat, lagoon, shoal and open marine belts. These facies illustrate environmental characteristics of carbonate-evaporite sequences. The facies changes, display the shallow carbonate homocline ramp setting.  
Material and methods
After studying satellite images and field surveys in the Ravar region of Kerman, 5 sections of Lakarkuh-1 and 2, Horjond, Khorand and East of Bahabad were selected as the most suitable geological sections. Total of 68 thin sections from four sections of LakarKuh-1 and 2, Horjand and Khorand were examined by petrography. Of course, it is worth mentioning that no samples were taken from the Bahabad section and these were examined only to compare the thickness and lithological facies and especially evaporite deposits.
Conclusion
After extensive field surveys, five geological sections with the most complete outcrops were finally selected. The reason for the decrease in the thickness of evaporative deposits from 1450 m in the Khordand, 1300 m in the Bahabad, 725 m in the Horjond, 450 m in Lakarkuh-1 and 50 m in LakarKuh-2 can probably be due to the local changes in sea water levels and availability of more evaporative conditions. 
In order to identify and interpret gypsum and anhydrite facies and related fabrics, several sections have been selected in the Lakarkuh and Horjond areas. First, after introducing field photos, some of the important identified fabrics were examined. The microfacies investigation of 4 sections has led to the identification of 11 microfacies with the acronyms A, B, C and D, which belong to the 4 facies belts of intertidal, lagoon, shoal and open sea environments. Finally, according to the identified facies, a sedimentary environment model was presented.
Results
The unusual and high thicknesses of gypsum in the Ravar region often have a tectonic origin and are mainly related to the formation of disharmonic folds. Evidence such as single nodules, enterolytic, and fenestral textures in evaporites show that these factories formed simultaneously with deposition or in the early stages of diagenesis. Three facies’ belts including intertidal zone facies (A1, A2 and A3 facies), high tidal zone facies (A4 and A5), and lagoon (B1) have been identified. The sedimentary model presented for the studied deposits in the shallow parts of a carbonate-evaporative system, which was probably a hemoclinical ramp. Examination of evaporitic facies in Lakarkuh and Horjond regions indicates that these facies are often deposited in sabkha and intertidal and lagoon environments.

Keywords

References

References
Persian References:
-Adabi, M.A., 2011. Sedimentary Geochemistry, Ariyan Zamin Publication, 2nd Edition, 504 p, (in Persian).
-Aghanabati, A. and Haghipour, A., 1978. Geological Quadrangle Map of Tabas, Scale 1:250,000. Geological Survey of Iran, Tehran.
-Bagheri, S., Edalatimanesh, S.N., Ghomashi, M. and Bakhshi Mohebi, M.R., 2016. Reconstruction of a Jurassic continental rift system in the Ravar area, Southern Tabas Block. 4 th national conference of tectonics and structural Geology, Birjand, Iran.
-Edalatimanesh, S.N., Bagheri, S., Adabi, M.H., Ghomashi, M. and Boomeri, M., 2017. Investigation of evaporite- carbonate deposits of the Upper Jurassic in the Ravar zone, South of Tabas Block. 1st international congress on Jurassic of Iran and neighboring countries, 4- 5 October, 2017.
-HajMolaAli, A., 1995. Geological Quadrangle Map of Ravar, Scale 1:100,000. Geological Survey of Iran, Tehran.
 
English References:
-Annon, P., 1985. World Survey of Potash Resources. 4th edition, British Sulfur Corp, 144 p.
-Babel, M. and Schreiber, B.C., 2014. Geochemistry of Evaporites and Evolution of Seawater. Treatise on Geochemistry, second edition, v. 9. Sediments, Diagenesis, and Sedimentary Rocks, Edition: 2nd, Editors: Mackenzie Fred, Chapter: Chapter 9.18, Publisher: Elsevier, p. 483-560.
-Blatt, H., Middleton, G.V. and Murray, R.C., 1980. Origin of Sedimentary Rocks, 2nd edition, Englewood Cliffs, New Jersey: Prentice-Hall Publication, 782 p.
-Blomme, K., Fowler, S.J., Bachaud, P., Nader, F.H., Michel, A. and Swennen, R., 2017. Ferroan dolomitization by seawater interaction with mafic igneous dikes and carbonate host rock at the Latemar platform, dolomites, Italy: Numerical modeling of spatial, temporal, and temperature data, Journal of Geofluids, p. 1-14.
-Braitsch, O., 1971. Salt Deposits: Their Origin and Composition, Springer-Verlag, New York, 297 p.
-Burchette, T.P. and Wright, V.P., 1992. Carbonate ramp depositional systems, Journal of Sedimentary Geology, v. 79, p. 3-75.
-Butler, G.P., Harris, P.M. and Kendall, C.G.ST.C., 1982. Recent evaporates from the Abu Dhabi coastal flats. In: Handford, C.R., Loucks, R.G., and Davis, G.R. (eds.), Deposition and Diagenetic Spectra of Evaporites. Society of Economic Palaeontologists and Mineralogists Core Workshop 3, Tulsa, p. 33-64.
-Calvert, S.T. and Price, N.B., 1972. Diffusion and reaction profiles of dissolved manganese in pore waters of marine sediments. Journal of Earth and Planetary Science Letters, v. 16, p. 245-249.
-Dean, W.E. and Schreiber, B.C., 1978. Marine Evaporites, Society of Economic Palaeontologists and Mineralogists Short Course Notes, Oklahoma City, 188 p.
-Dunham, R.J., 1962. Classification of carbonate rocks according to depositional texture. In Classification of carbonate rocks, Edited by Hallam, W.E. American Association of Petroleum Geologists Memembers, v. 1, p. 108-121.
-Einsele, G., 1992. Sedimentary Basins, Evolution, Facies, and Sedimenatary Budget. Springer- Verlag, New York, 9 p.
-Eugster, H.P., 1980. Geochemistry of evaporitic lacustrine deposits. Journal of Annual Review of Earth and Planetary Sciences, v. 8, p. 35-63.
-Flugel, E., 2010. Microfacies of Carbonate Rocks, Analyses, Interpretation and Application, Springer Verlag, 976 p.
-Gandin, A., Wright, D.T., Melezhik, V., 2005. Vanished evaporites and carbonate formation in the Neoarchaean Kogelbeen and Gamohaan formations of the Campbellrand Subgroup, South Africa. Journal of African Earth Sciences, v. 41, p. 1-23.
-Hallam, A., 1978. Eustatic cycles in the Jurassic: Journal of Palaeogeography, Palaeoclimatology, Palaeoecology, v. 23, p. 1-32.
-Hallam, A., 1988, A re-evaluation of Jurassic eustasy in the light of new data and the revised Exxon curve. In: Wilgus, C.K. et al. (eds.), Sea- level Changes: an integrated approach: Society of Economic Paleontologists and Mineralogist, Special Publications, v. 42, p. 261- 273.
-Handford, C.R., 1982. Sedimentology and evaporie genesis in a Holocene continental sabkha playa basin –Bristol Dry Lake, California. Journal of Sedimentary Petrology, v. 29, p. 239-253.
-Haq, B.U., Hardenbol, J. and Vail, P.R., 1988. Mesozoic and Cenozoic chronostratigraphy and cycles of sea- level change. In: Wilgus, C. K., Hastings, B. S., Kendall, C. G., Posamentier, H. W., Ross, C. A. and Van Wagoner, J. C. (eds.), sea level changes: An integrated approach: Journal of Geological Society Special Publications, v. 42, p. 71-108.
-Kasprzyk, A. and Orti, F., 1998. Palaeogeographic and burial controls on anhydrite genesis: The Badenian basin in the Carpathian Foredeep (Southern Poland, Western Ukraine), Journal of Sedimentology, v. 45, p. 889-907.
-Kendall, A.C., 1984. Evaporites, in Walker, R.G., ed., Facies Models, 2nd edition: Journal of Canadian Geoscience, Reprint Series, p. 269-296.
-Kendall, A.C., 1992. Evaporite, in facies models: responses to sea level changes, Edited by Walker, R.G., and James, N.P., Journal of Geological Association of Canada, p. 375-409.
-Kendall, C.G.St.C. and Skipwith, P.A., 1969. Geomorphology of a recent shallow water carbonate province: Khoral Bazam, Trucial Coast, and Southwest Persian Gulf: Geological Society of America Bulletin, v. 80, p. 865-891.

Files

Share

How to cite

Statistics