Clinopyroxene chemistry based Petrogenesis of Triassic interlayer magmatism in the north of Shahreza (South of Isfahan, Sanandaj–Sirjan zone)

Document Type : Research Article

Authors

1 Payame Noor University

2 Payame Noor Universtiy

Abstract

Introduction
The Shahzade-Ali Akbar area located at 68 Km south of Isfahan is located in the southern zone of the Cimmerian Sanandaj-Sirjan block as a part of the northern shelf of the Neo-Tethyan Ocean (Stampli and Borel, 2002). This area lies in the Shahreza-Abadeh-Hambast belt and is well-known for its classic Permian-Triassic outcrops. The Lower Triassic carbonate rocks have hosted several interlayer igneous horizons. The composition of these rocks varies from olivine basalt to quartz basalt and their hypabyssal equivalents. Plagioclase (labradorite), clinopyroxene (augite), olivine, amphibole and quartz are major and ilmenite and titanomagnetite are minor minerals. The main objective of this research study is to investigate the geological, geochemical and petrogenesis of igneous rocks using mineral chemistry.
 
Materials and methods
More than 50 samples representing whole units were selected in order to identify the geological setting of the igneous horizon, and their thin sections were prepared. Minerals and textures of rocks were studied by using polarizing microscope (Olympus BH-2). Then, 6 samples were selected for mineral chemistry and their mineral compositions were determined by electron microprobe at the Naruto University, Japan. The EPMA (Jeol- JXA-8800R) was used at operating conditions of 15 kV, 20 nA. Minpet software and spread sheet have been used for mineral chemistry studies and mineral formula calculations.
 
Discussion
Based on the field observations, igneous units that are 120 centimeters to 10 meters thick have basaltic composition and are interlayered with Lower Triassic carbonate rocks. Microscopic study showed that these rocks are composed of plagioclase, clinopyroxene, olivine, amphibole, quartz and opaque minerals (ilmenite and titanomagnetite) and have porphyritic, ophitic, intersertal to intergranular textures. These rocks have undergone alterations and secondary minerals are widespread. EPMA analyses show andesine to labradorite composition, clinopyroxene (augite) and amphibole (edenite). In the Q-J diagram (Morimoto et al., 1988), all clinopyroxenes are located in the Mg-Fe-Ca (Quad) field. In the Wo-En-Fs diagram (Beccaluva et al., 1989), clinopyroxens show augitic with lessor amounts of diopside composition.  According to clinopyroxene chemistry diagrams such as Si­­O2 vs. Al2O3 and Ti vs. Al (Le Bas, 1962), the samples belong to sub-alkaline series. Discriminate diagrams such as Ti­­O2 vs. Al2O3 (Le Bas, 1962), Ti­­ vs. Ca+Na and Ti vs. Al (Leterrier et al., 198a2) are used for identification of magma affinity. These diagrams show that the studied rocks are tholeiitic. The rocks under study demonstrate the MORB feature on tectonic discrimination diagrams (TiO2-SiO2/100-Na2O, Beccaluva et al., 1989)
In the 2Ti+Cr+AlVI vs. Na+AlIV diagram (Morimoto et al., 1988) all clinopyroxenes are located below the Fe3+=0 line that indicates low oxygen fugacity during crystallization (Schweitzer et al., 1979). In Helz (1973) diagrams, the pressure and percentage of magma water estimated to be 2 to 10 Kbar pressure and about 10% water content. In YPT vs. XPT diagrams (Soesoo, 1997) the temperatures and the pressure of clinopyroxene crystallization are about 1150-1200 ◦C and 2-10 Kbar respectively.
 
Results
The studied area had been a part of the Cimmeride microcontinent (Horacek et al., 2007) which had begun separating from the northern margin of Gondwana during Triassic time (Şengör, 1984), and traversed north to the southern Eurasian border (Stampli and Borel, 2002).
In this area, several interlayer igneous rocks with basaltic composition are seen with Lower Triassic carbonate rocks.
Based on the chemical composition of pyroxenes, the magma has sub-alkaline and tholeiitic affinity. The crystallization of ilmenite-titanomgenetite and diagram of clinopyroxenes crystallization conditions illustrate the low level of oxygen fugacity in the formation of the rocks under discussion. The pressure of magma crystallization is estimated to be between 2 and 10 kb, and the magmatic water content is about 10%. The studied rocks show MORB characteristics. Interlayering with lower Triassic sediments, sub-alkaline nature of the magma, low level oxygen fugacity during crystallization and geotectonic environment, suggest that the rocks have been formed in the early stages of the opening of the oceanic crust. A process that has led to the formation of the Neo-Tethys Ocean in the later stages.
 
References
Beccaluva, L., Macciotta, G., Piccardo, G.‌B. and Zeda, O., 1989. Clinopyroxene composition of ophiolite basalts as petrogenetic indicator. Chemical Geology, 77(3–4): 165–182.
Helz, R.‌T., 1973. Phase relations of basalts in their melting range at PH2O= 5 kb as a function of oxygen fugacity. Journal of Petrology, 17(2): 139–193.
Horacek, M., Richoz, S., Brander, R., Krystyn, L. and Spötl, Ch., 2007. Evidence for recurrent changes in Lower Triassic oceanic circulation of the Tethys: The δ13C record from marine sections in Iran. Palaeogeography, Palaeoclimatology, Palaeoecology, 252(1–2): 355–369.
Le Bas, N.J., 1962. The role of aluminous in igneous clinopyroxenes with relation to their parentage. American Journal of Science, 260(4): 267–88.
Leterrier, J., Maury, R.C., Thonon, P., Girard, D. and Marchal, M., 1982. Clinopyroxene composition as a method of identification of the magmatic affinities of paleo-volcanic series. Earth and Planetary Science Letters, 59(1): 139–154.
Morimoto, N., Fabries, J., Ferguson, A.K., Ginzburg, I.V., Ross, M., Seifert, F.A., Zussman, J., Aoki, K. and Gottardi, D., 1988. Nomenclature of pyroxenes. American Mineralogist, 73(9–10): 1123–1133.
Schweitzer, E.L., Papike, J.J. and Bence, A.E., 1979. Statitical analysis of clinopyroxenes from deep sea basalts. American Mineralogist, 64(2): 501–513.
Şengör, A.M.C., 1984. The Cimmeride orogenic system and the tectonics of Eurasia. Geological Society of America, Special paper, America, 82 pp.
Soesoo, A., 1997. A multivariate statistical analysis of clinopyroxene composition: empirical coordinates for the crystallization P-T estimations. Geological Society of Sweden (Geologiska Föreningen), 119(1): 55–60.
Stampli, G.M. and Borel, G.D., 2002. A plate tectonic model for the Paleozoic and Mesozoic constrained by dynamic plate boundaries and restored synthetic oceanic isochrones. Earth and Planetary Science Letters, 196(1–2): 17–33.

Keywords

References

Aghanabati, S.A., 2013. Magmatism in Iran. Roshd magazine, 18(4): 18–23. (in Persian)
Baghbani, D., 1993. The Permian sequence in the Abadeh region, Central Iran. In: A.E.M. Nairn and V.A.V. Koroteev (Editors), Contributions to Eurasian geology. Earth Sciences and Resources Institute, Russia, pp. 7–22.
Beccaluva, L., Macciotta, G., Piccardo, G.B. and Zeda, O., 1989. Clinopyroxene composition of ophiolite basalts as petrogenetic indicator. Chemical Geology, 77(3–4): 165–182.
Besse, J., Torq, F., Gallet, Y., Ricou, L.E., Krystyn, L. and Saidi, A., 1998. Late Permian to Late Triassic paleomagnetic data from Iran: constraints on the migration of the Iranian block through the Tethyan Ocean and initial destruction of Pangaea. Geophysical Journal International, 135(1): 77-–92.
Buddington, A.F and Lindsley, D.H., 1964. Iron-titanium oxides minerals and synthetic equivalents. Journal of Petrology, 5(2): 310–357.
Deer, W.A., Howie, R.A. and Zussman, J., 1992. An introduction to the Rock-Forming Minerals. Longman, London, 696 pp.
Falahaty, S., Noghreyan, M., Sharifi, M., Torabi, Gh., Safaei, H. and Mackizadeh, M.A. 2016. Clinopyroxene application in petrogenesis identification of volcanic rocks associated with salt domes from Shurab Southeast Qom). Journal of Economic Geology, 8(1): 21–38. (in Persian with English abstract)
Foley, S.F. and Venturelli, G., 1989. High K2O rocks with high MgO, High SiO2 affinities. In: A.J. Crawford (Editor), Boninites and related rocks. Unwin Hyman, London, pp. 72–88.
France, L., Ildefonse, B., Koepke, J. and Bech, F., 2010. A new method to estimate the oxidation state of basaltic series from microprobe analyses. Journal of Volcanology and Geothermal Research, 189(3–4): 340–346.
Helz, R.T., 1973. Phase relations of basalts in their melting range at PH2O= 5 kb as a function of oxygen fugacity. Journal of Petrology, 17(2): 139–193.
Heydari, E., Arzani, N. and Hassanzadeh, J., 2008. Mantle plume: The invisible serial killer ‐Application to the Permian‐Triassic boundary mass extinction. Palaeogeography, Palaeoclimatology and Palaeoecology, 264(1–2): 147–162.
Horacek, M., Richoz, S., Brander, R., Krystyn, L. and Spötl, Ch., 2007. Evidence for recurrent changes in Lower Triassic oceanic circulation of the Tethys: The δ13C record from marine sections in Iran. Palaeogeography, Palaeoclimatology, Palaeoecology, 252(1–2): 355–369.
Korte, C., Kozur, H.W. and Mohtat-Aghai, P., 2004. Dzhulfian to lowermost Triassic d13C record at the Permian/Triassic boundary section at Shahreza, Central Iran. Hallesches Jahrbuch für Geowissenschaften – Beihefte, 18(1): 73–78.
Le Bas, N.J., 1962. The role of aluminous in igneous clinopyroxenes with relation to their parentage. American Journal of Science, 260(4): 267–88.
Leake, B.E., Woolley, A.R., Arps, C.E.S., Birch, W.D., Gilbert, M.C., Grice, J.D., Hawthorne, F.C., Kato, A., Kisch, H.J., Krivovichev, V.G., Linthout, K., Laird, J., Mandarino, J.A., Maresch, W.V., Nickel, E.H., Rock, N.M.S., Schumacher, J.C., Smith, D.C., Stephenson, N.C.N., Ungaretti, L., Whittaker, E.J.W. and Youzhi, G., 1997. Nomenclature of amphiboles, report of the subcommittee on amphiboles of the international mineralogical association, commission on new minerals and mineral names. American Mineralogist, 82(9–10): 1019–1037.
Leterrier, J., Maury, R.C., Thonon, P., Girard, D. and Marchal, M., 1982. Clinopyroxene composition as a method of identification of the magmatic affinities of paleo-volcanic series. Earth and Planetary Science Letters, 59(1): 139–154.
Liu, T.C., Chen, B.R. and Chen, C.H. 2000. Melting experiment of a Wannienta basalt in the Kuanyinshan area, northern Taiwan, at pressures up to 2.0 GPa. Journal of Asian Earth Sciences, 18(5): 519–531.
Malgarotto, C., Molin, G. and Zanazzi, F., 1993. Crystal chemistry of clinopyroxenes from Filicudi and Salina (Aeolian Islands, Italy): geothermometry and barometry. European Journal of Mineralogy, 5(5): 915–923.
Mehvari, R., Noghreyan, M., Sharifi, M., Mackizadeh, M.A., Tabatabaei, S.H. and Torabi, Gh., 2017. Mineral chemistry of clinopyroxene: guidance on geo- thermobarometry and tectonomagmatic setting of Nabar volcanic rocks, South of Kashan. Journal of Economic Geology, 8(2): 493–506. (in Persian with English abstract)
Moretti, R., 2005. Polymerization, basicity, oxidation state and their role in ionic modelling of silicate melts. Geophysics, 48(4–5): 583–608.
Morimoto, N., Fabries, J., Ferguson, A.K., Ginzburg, I.V., Ross, M., Seifert, F.A., Zussman, J., Aoki, K. and Gottardi, D., 1988. Nomenclature of pyroxenes. American Mineralogist, 73(9–10): 1123–1133.
Nazzareni, S., Molin, G., Peccerillo, A. and Zanazzi, P.F., 2001. Volcanological implications of crystal-chemical variations in clinopyroxenes from the Aeolian Arc, Southern Tyrrhenian Sea (Italy). Bulletin of Volcanology, 63(1): 73–82.
Nisbet, E.G. and Pearce, J.A., 1977. Clinopyroxene composition of mafic lavas from different tectonic settings. Contributions to Mineralogy and Petrology, 63(2): 161–173.
Richoz, S., Krystyn, L., Baud, A., Brandner, R., Horacek, M. and Mohtat-Aghai, P., 2010. Permian-Triassic boundary interval in the Middle East (Iran and N. Oman): Progressive environmental change from detailed carbonate carbon isotope marine curve and sedimentary evolution. Journal of Asian Earth Sciences, 39(4): 236–253.
Sayari, M. and Sharifi, M., 2016. Application of clinopyroxene chemistry to interpret the physical conditions of ascending magma, a case study of Eocene volcanic rocks in the Ghohrud area (North of Isfahan). Journal of Economic Geology, 8(1): 61–78. (in Persian with English abstract)
Schweitzer, E.L., Papike, J.J. and Bence, A.E., 1979. Statitical analysis of clinopyroxenes from deep sea basalts. American Mineralogist, 64(2): 501–513.
Şengör, A.M.C., 1984. The Cimmeride orogenic system and the tectonics of Eurasia. Geological Society of America, Special paper, America, 82 pp.
Shelly, D., 1993. Igneous and Metamorphic Rocks under the Microscope. Chapman and Hall, London, 445 pp.
Shirezadeh Esfahani, F., Kohansal Ghadimvand, N., Kangazian, A., Hejazi, S.H. and Hairapetian, V., 2006. The new data on the lithostratigraphic subdivision of the Vazhnan formation (Latest Carboniferous-Early Permian) in the Shahreza-Abadeh belt. Scientific Quarterly Journal, GEOSCIENCES, 25(99): 3–10. (in Persian with English abstract)
Soesoo, A., 1997. A multivariate statistical analysis of clinopyroxene composition: empirical coordinates for the crystallization P-T estimations. Geological Society of Sweden (Geologiska Föreningen), 119(1): 55–60.
Stampli, G.M. and Borel, G.D., 2002. A plate tectonic model for the Paleozoic and Mesozoic constrained by dynamic plate boundaries and restored synthetic oceanic isochrones. Earth and Planetary Science Letters, 196(1–2): 17–33.
Tabatabaei, S.H., Tabaei, M., Mansouri Esfahani, M. and Asadi Haroni, H., 2014. Geological, Mineralogical and Geochemical Characteristics of Titanium Deposit in Cheshmeh Siah Shahreza, Isfahan. Geochemistry, 3(3): 235–246.
Tabbakh Shabani, A.A., Delavari Kooshan, M. and Hajiabdolrahim Khabbaz, M., 2017. Geochemistry and mineral chemistry of zeolites bearing basic volcanic rocks from the Boumehen-Roudehen area, east of Tehran. Journal of Economic Geology, 9(2): 397–418. (in Persian with English abstract)
Taraz. H., 1971. Uppermost Permian and Permo-Triassic transition beds in Central Iran. AAPG Bulletin. 55(8): 1280–1294.
Taraz, H., 1974. Geology of the Surmaq-Deh Bid area, Abadeh region, Central Iran. Geological Survey of Iran, Iran, Report 37, 148 pp.
Taraz, H., Golshani, F., Nakazawa, K., Shimizu, D., Bando, Y., Ishii, K., Murata, M., Okimura, Y., Sakagami, S., Nakamura, K. and Tokuoka, T., 1981. The Permian and the Lower Triassic systems in Abadeh region, Central Iran. Memoirs of the Faculty of Science, Kyoto University. Series of Geology and Mineralogy, 47(2): 61–133.
Wass, S.Y., 1979. Multiple origins of clinopyroxenes in alkali basaltic rocks. Lithos, 12(2): 115–132.
Whitney, D.L. and Evans, B.W., 2010. Abbreviations for names of rock-forming minerals. American Mineralogist, 95(1): 185–187
Zahedi, M., 1976. Geological map of Shahreza, scale 1:100000. Geological Survey of Iran, Iran.
Zhu, Y.F. and Ogsasawara, Y., 2004. Clinopyroxene phenocrysts (with green salite cores) in trachybasalts: implications for two magma chambers under the Kokche NAPV UHP massif, North Kazakhstan. Journal of Asian Earth Sciences, 22(5): 517–527.
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 21 January 2019
  • Accept Date: 22 May 2019

Share

How to cite

Statistics