Dolomitization and evaporate mineralization of Sachun Formation at type locality (SE Shiraz)

Abstract

The Sachun Formation (Paleocene-Lower Eocene) is mainly composed of carbonates and evaporates that were deposited in shallow-marine evaporitic mudflat environments. The Sachun Formation in the study area has been divided into three units including: lower evaporate; middle bioclastic limestone and upper evaporate. It is mainly composed of diagenetic gypsum, which originated from dehydration of anhydrite precursor. This gypsum in the Sachun Formation generally displays alabastrine and porphyroblastic textures with corroded anhydrite relics. Petrological studies reveal that the most important diagenetic processes affected the middle Part of the Sachun Formation are dolomitization and evaporate mineralization. Four types of dolomite, ranging from early to burial diagenetic environments, were identified. These are including very fine-to-fine crystalline (D1), neomorphic dolomite (D2), fine-to-medium crystalline euhedral to subhedral dolomite (D3) and pore- and fracture-filling dolomite (D4).

Keywords

References

[2] Dickson J.A.D., "Carbonate identification and genesis as revealed by staining. Journal Sedimentary Petroleum", 1966, 36: p. 491-505.

[3] Hood S.D., Nelson C. S., Kamp P.J., "Burial dolomitization in a non-tropical carbonate petroleum reservoir: the Oligocene Tikorangi Formation", Taranaki Basin, New Zealand, Sedimentary Geology, 2004. 172: p. 117-138.

[4] Mazzullo S.J., "Organogenic dolomitization in pritidal to deep sea sediments. Journal of Sedimentary Research", 2000, 70: p. 10-23.

[5] Sibley D.F., Greeg J.M., "Classification of dolomite rock Textures. Journal of Sedimentary Petroleum", 1987, 57: p. 967-975.

[6] Al-Aasm I.S., "Chemical and Isotopic constrains for recystallization of Sedimentary Dolomites from the West Canada Sedimentary basin" Aquatic Geochemistry, 2000, 6: p. 227-248.

[7] Adabi M.H., "Petrography and geochemical criteria for recognition of unaltered cold water and diagenetically altered neomorphic dolomite. Western Tasmania", Australia, 16th AGC, 2002: p. 350.

[8] Mahboubi A., Moussavi-Harami R., Brenner R.L., Gonzalez L.A., "Diagenetic history of late Paleocene potential carbonate Reservoir Rocks", Kopet-Dagh basin, NE Iran, . Journal of petroleum Geology, 2002, 25: p. 465-484.

[9] Mahboubi A., Moussavi-Harami R., Yahya-Sheibani V., Najafi M., Gonzalez L., "Petrography and Geochemical Evidence for Paragenetic Sequence Interpretation of the Lower Cretaceous Limestone in the Eastern Binalood Mountain Range", NE Iran. Iranian international Journal of Science, 2004. 5 (2): p. 181-201.

[10] Sass E., Bein A., "Dolomites and salinity: a comparative geochemical study. In: Shukla, V. and Baker", P.A. (eds.): Sedimentology and geochemistry of dolostones. Economic Paleontologists and Mineralogists, Special Publication, 1988, 43: p. 223-233.

[11] Rao C.P., "Elemental composition of marine calcite from modern temperate shelf brachiopods", bryozoans and bulk carbonates, eastern Tasmania, Australia. Carbonates and Evaporate, 1996 11(1-18).

[12] Allan j.R., Wiggins W.D., "Dolomite reservoir: geochemical techniques for evaluating origin and distribution". American Association of Petroleum Geologists Containing Education Course Notes Series, 1993, 36: p. 136.

[13] Al-Assam I.S., Pakard J. J., "Stabilization of early-formed dolomite", relate of divergence from two Mississipian dolomites. Sedimentary Geology, 2000, 131: p. 97-108.

[14] Tuker M.E., Wright V.P., "Carbonate Sedimentology. 1990: Black-Wells", Oxford. 482.

[15] Rao C.P., Jayawardane M.P.J., "Major minerals, elemental and isotopic composition in modern temperate shelf carbonates", eastern tasmania, Australia: Implications for the occurrence of extensive ancient non-tropical carbonates. Palaeogeogr. Palaeoclimatol. Palaeoecol., 1994, 107: p. 49-63.

[16] Rao C.P., Adabi M.H., "Carbonate minerals, major and minor elements and oxygen and carbon isotopes and their variation with water depth in cool", temperate carbonates, western Tasmania, Australia: Mar. Geology, 1993. 103: p. 249-272.

[17] Vizer J., "Depositional and diagenetic history of limestone, in Isotopic signatures and sedimentary records N. Clauer and S. Chaudhuri", Editors. 1992, Springer Berlin / Heidelberg. p. 13-48.

[18] Gundogana, I., Onalb, M., and Depc, T., Sedimentology, petrography and diagenesis of Eocene-Oligocene evaporates: the Tuzhisar Formation, SW Sivas Basin, Turkey.Journal of Asian Earth Sciences, 2005, 25 p. 791-803.

[19] Alsharhan, A.S., and Kendall, C.G.ST.C., Holocene coastal carbonates and evaporites of the southern Arabian Gulf and their ancient analogues Earth Science Review, 2003. 61: p. 191-243.

[20] Alssaran, N.A., Origin and geochemical reaction path of sabkha brine: Sabkha Jayb Uwayyid, eastern Saudi Arabia Arabian Journal of Geosciences, 2008. 1: p. 63-74.

[21] Warren, J., Evaporate, their evolution and economics. 1999: Black-Well Science Publ. 438.

[22] Rubio, E.S., Saanchez-Moral, S., Canaaveras, J.C., Calvo, J.P., and Rouchy, J.M., , Calcitization of Mg-Ca carbonate and Ca sulphate deposits in a continental Tertiary basin (Calatayud Basin, NE Spain).Sedimentary Geology, 2001. 140: p. 123-142.

[23] Playa, E., and Gimeno, D., Evaporate deposition and coeval volcanism in the Fortuna Basin (Neogene, Murcia, Spain) Sedimentary Geology, 2006. 188-189(205-218).

[24] Testa, G., and Lugli, S.,, Gypsum-anhydrite transformations in Messinian evaporates of central Tuscany (Italy). Sedimentary Geology, 2000, 130: p. 249-268.

[25] Orszag-Sperber F., Plaziat J.C., Baltzer F., Purser B.H., "Gypsum salina-coral reef relationships during the Last Interglacial (Marine Isotopic Stage 5e) on the Egyptian Red Sea coast: a Quaternary analogue for Neogene marginal evaporates", Sedimentary Geology, 2001. 140: p. 61-85.

[26] Kasprzyk A., "Sedimentological and diagenetic patterns of anhydrite deposits in the Badenian evaporate basin of the Carpathian Fore deep", southern Poland. Sedimentary Geology, 2003, 158: p. 167-194.

[27] El Khoriby E.M., "Origin of the gypsum-rich silica nodules", Moghra Formation, Northwest Qattara depression, Western Desert, Egypt. Sedimentary Geology, 2005, 177: p. 41-55.

[28] Lucia F.J., "Rock-fabric/petrophysical classification of carbonate pore space for reservoir characterization". American Association of Petroleum Geologists Bulletin, 1995, 79, no. 9: p. 1275-1300.
Iranian Journal of Crystallography and Mineralogy
Volume 17, Issue 4 - Serial Number 36
January 2010
Pages 609-620

Files

History

  • Receive Date: 02 July 2025
  • Revise Date: 04 February 2026
  • Accept Date: 02 July 2025

Share

How to cite

Statistics