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Depositional history and diagenetic evolution of evaporite deposits of the Sachun Formation in Siyah anticline section–south east of Sarvestan | ||
| رخسارههای رسوبی | ||
| Article 2, Volume 9, Issue 1, October 2016, Pages 13-34 PDF (3.61 M) | ||
| Document Type: مقالات پژوهشی | ||
| DOI: 10.22067/sed.facies.v9i2.49744 | ||
| Authors | ||
| Abdolreza Bavi oveidi* 1; Mohammad hossein Adabi1; Abbas Sadeghi1; Hassan Amiri Bakhtiyar2 | ||
| 1Shahid Beheshti University | ||
| 2National Iranian South Oil Company, Ahwaz | ||
| Abstract | ||
| Introduction The Paleocene- Early Eocene Sachun Formation in southeast Zagros basin of Iran (Fars sub-basin) is composed of marl, carbonates and evaporates facies (Amiri Bakhtiyar, 2007). The first Cenozoic evaporate succession of Zagros basin in Iran is present in the Sachun Formation. This formation is at type section is composed of marl, carbonate and evaporite (Motiie, 2003; Amiri Bakhtiar, 2007). According to Heydari (2008), during this period Arabian plate and Zagros basin were at the 300 N latitude, so temperature condition was suitable for the formation of evaporate and these deposits have formed along with shallow marine carbonates of Umm er Radhuma (Paleocene), Rus (Early Eocene) and Dihban (Paleocene-Eocene) Formations (Zigler, 2001; Alavi, 2004; Ghazban, 2007). The Sachun Formation has not been studied in detail and can only been refer to works of Arzaghi et al. (2012) and Shabafrooz et al (2013). The aim of this study is to investigate depositional history and diagenetic evolution of evaporite deposits of the Sachun Formation in Siyah anticline section located about 12 kilometers south east of Sarvestan city. Materials and Methods After identification of the lower and upper boundaries of this formation, 300 samples were colocted for petrographic studies with sampling interval of 1-2 meters. In order to identify evaporate minerals and intensity of evaporation, ten samples were selected to analyze by XRD (Sw 1800). Additional studies of diagenetic processes heve been performed by Su 3500 scanning electron microscope (SEM) on ten samples at central laboratory of Shahid Beheshti University. Ten Polished section were prepared in central laboratory of National Iranin South Oil Company (NISOC) to study carbonate-evaporite alternation. In this study, structure and structural classification of evaporate have been performed according to Maiklam et al. (1969) and Warren (2006) works. Discussion and conclusion Evaporates deposits of the Sachun Formation in Siyah anticline have formed as three types: primary, secondary and tertiary. Primary evaporates are beds and laminates that have formed in sabaqoues environment (salina) due to evaporation. Along with primary evaporates, carbonate also deposited in lagoonal and sabkha environments. Secondary evaporates formed during eogenetic and mesogenetic stages. Nodules sulphates (anhydrite & gypsum) have displaced in marl-carbonate matrix as enterolithic and chicken wire structures. Transformation of gypsum to anhydrite have taken placed in mesogenetic stage due to incrassation of pressure and temperature. Tertiary evaporates or telogenetic evaporites formed in meteoric environment. The most important diagenetic processes in this stage include hydration of anhydrite and formation of bassanite along with secondary gypsum with granoblastic, porphyroblastic and alabastrian textures. Gypsum viens in evaporate and carbonate sediments have been filled by satinspare and sigmoidal gypsum cements. Besides, gypsum cements have formed in carbonate facies. Another diagenetic processes are calcification, dissolution and dissolution breccia. Keywords: Siyah Anticline; Sachun Formation; Gypsum; Anhydrite; Bssanite. Reference Alavi, M., 2004. Regional stratigraphy of the Zagros fold-thrust belt of Iran and proforland evolution. American Journal of Sciences, 304:1-20. Amiri-Bakhtiar, H., 2007. Lithostratigraphy and biostratigraphy of the Tarbur Formation in Fars region. PhD Dissertation, Shahid Beheshti University,Tehran, 439 p. Arzaghi, S., Khosrow-Tehrani, K., & Afghah, M., 2012. Sedimentology and petrography of Paleocene–Eocene evaporites: the Sachun Formation, Zagros Basin, Iran. Carbonates and Evaporites, 27:43–53. Ghazban, F., 2007. Petroleum Geology of the Persian Gulf. Tehran University Press, Iran, 707 p. Maiklem, W.R., Bebout, D.G., & Glaister, R.P., 1969. Classification of anhydrite-a practical approach. Bulletin of Canadian Petroleum Geology, 17:194-233. Heydari, E., 2008. Tectonics versus eustatic control on supersequences of the Zagros Mountains of Iran. Tectonophysics, 451:56–70 Motiei, H., 2003. Stratigraphy of Zagros, Treatise on the Geology of Iran. Ministry of Mines and Metals, Geological Survey of Iran, Tehran, 539 p Shabafrooz, R., Mahboubi, A., Moussavi-Harami, R., & Amiri Bakhtiar, H., 2013. Facies analysis and sequence stratigraphy of the evaporite bearing Sachun Formation at the type locality, South East Zagros Basin, Iran. Carbonates and Evaporites, 28: 457-574. Warren, J.k., 2006. Evaporates: Sediments, Resources and Hydrocarbons. Springer-Verlag Berlin, 1035p. Ziegler, M.A., 2001. Late Permian to Holocene paleofacies evolution of the Arabian Plate and its hydrocarbon occurrences. Geo Arabia, 6: 445-503. | ||
| Keywords | ||
| Siyah Anticline; Sachun Formation; Gypsum; Anhydrite; Bssanite | ||
| References | ||
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