Mineralogy, Geochemistry and Petrogenesis of Mantle Peridotites of Nehbandan Ophiolitic Complex, East of Iran

Document Type : Research Article

Authors

1 Shahid Beheshti University

2 Institute for Advanced Studies in Basic Sciences (IASBS)

Abstract

Introduction
Ophiolites are a set of oceanic rocks with different appearance and mineralogy in the world's largest orogenic belt, from the Alpine to the Himalayas. The ophiolites of Iran are also located in this belt. Among ophiolites in Iran, the Nehbandan Ophiolitic Complex in the east of the country is of great importance. The complete ophiolitic sequence consists of two sets. The first is the crust sequence, gabbro, diabase and basalt, and the second is a mantle sequence or peridotites, both of which are sequences in the Nehbandan Ophiolitic Complex. The main purpose of this research study is mantle section. There are three study areas, located near the city of Nehbandan: Kalateh-Shahpori, Qadam Gah peridotites that are about 30 km northwest of the city of Nehbandan near the Chahar Farsang village and the third area is located between the Khansharaf village and Nasfandeh Kuh area that is 10 km east of Nehbandan.
 
Materials and methods
In this lithological and mineralogical research study, thin and polished sections were prepared from samples. The thin sections were analyzed by polarizing OLYMPUS microscope BH-2 and the polished sections were analyzed by the OLYMPUS BX-60 reflecting microscope. A CAMECA SX100 electron probe microanalyzer was used to determine the chemical composition of the minerals in samples. The analytical condition include 15 kV and 20 nA rays with periods of 10 to 30 seconds at peaks for different minerals that are analyzed at the electron probe microanalysis center in the University Of Toulouse, France. The stoichiometry of minerals was used to calculate the amount of Fe3+ for access to the structural formula of minerals (Droop, 1987.(
 
Results and discussion
In terms of petrography, the Kalateh Shahpori peridotites are of the Harzburgite type and the Nasfandeh Kuh peridotites are of the Lherzolite type. The Qadam Gah peridotites are both geographically and petrographically indicative of the state of transition between the two other regions. The mineralogy of the Kalateh Shahpori peridotites is composed of olivine (Fo91), orthopyroxene (En90 Fs9), and the Cr-spinel is of the high Cr type. The Nasfandeh Kuh peridotites have olivine minerals that are Chrysolite (Fo89), orthopyroxene (En89 Fs9) and (En86 Fs10), clinopyroxene (En46 Fs5 Wo49) and, the Cr-spinel is of the high Al type. The Qadam Gah peridotites are composed of olivine (Fo90), orthopyroxene (En89 Fs9.5), clinopyroxene (En47 Fs3 Wo50) and, the Cr-spinel is of the medium Cr type.
According to geochemical data and petrogenesis, the Kalateh Shahpori harzburgites are of the supra-subduction zone type in the forearc basin. The Nasfandeh Kuh Lherzolites are of the middle-oceanic type. The Lherzolites of Qadam Gah have the same characteristics of both regions in terms of the formation environment. However, they are much more similar to the middle-oceanic peridotites. The degree of partial melting of the peridotite has a direct relationship with the Cr content and it has an inverse relationship with the Al2O3 content in the chromium-spinel of the peridotite (Hellebrand et al., 2001). Probably, these lherzolites formed due to the re-fertilization of harzburgites (Monsef et al., 2018). Accordingly, Kalateh-Shahpori harzburgites with 20% partial melting are of high-grade, and the Nasfandeh Kuh Lherzolites with 5% partial melting are of the low grade type. The herzolites of the Qadam Gah are approximately 11% partial melting and are located between the Kalateh Shahpori peridotites and the Nasfandeh Kuh peridotites. The high degree of melting in the Harzburgites may indicate their remelting in the fluid environment because the hydrosis condition increases the degree of partial melting of peridotite (Hirose and Kawamoto, 1995). The Cr# in Cr-spinel, and the Mg# in olivine of the peridotites indicate the presence of at least 3 types of peridotites in the Nehbandan Ophiolitic Complex. According to mineralogy, petrography, geochemistry, and petrogenesis studies of the peridotites in the Nehbandan ophiolitic complex, it is recommended to explore possible chromite deposits, high melting and supra-subduction harzburgite zones such as Kalateh Shahpori harzburgites which should be considered to be the first priority. Then the peridotites of transition regions such as Qadam Gah should be at second priority and finally the low melting middle-oceanic lherzolites such as the Nasfandeh Kuh shuld be considered to be the third priority.
 
References
Droop, G.‌T.‌R., 1987. A general equation for estimating Fe3+ concentrations in ferromagnesian silicatesand oxides from microprobe analyses, using stoichiometric criteria. Mineralogical Magazine, 51(361): 431–435.
Hellebrand, E., Snow, J.‌E., Dick, H.‌J.‌B. and Hofmann, A.‌W., 2001. Coupled major and trace elements as indicators of the extent of melting in mid-ocean-ridge peridotites. Nature, 410(1): 677–681.
Hirose, K. and Kawamoto, T., 1995. Hydrous partial melting of lherzolite at 1Gpa: the effect of H2O on the genesis of basaltic magmas. Earth and Planetary Science Letters, 133(3): 463– 473.
Monsef, I., Rahgoshay, M., Pirouz, M., Chiaradia, M., Michel Grégoire, M. and Ceuleneer, G., 2018. The Eastern Makran Ophiolite (SE Iran): evidence for a Late Cretaceous fore-arc oceanic crust. International Geology Review, 60(1):1–27

Keywords

References

Alavi, M., 1991. Sedimentary and structural characteristics of the Paleo-Tethys remnants in northeastern Iran. Geological Society of America. Bulletin, 103(8): 983–992.
Alavi Naini, M., Eftekharnezhad, J. and Aghanabati, A., 1990. Gological map of Zabol. Scale 1:250,000. Geological Survey of Iran.
Arai, S., 1994. Characterization of spinel peridotites by olivine-spine1 compositional relationships: review and interpretation. Chemical Geology, 113(3): 191–204.
Arai, S., Shimizu, Y., Ismail, S.A. and Ahmed, A.H., 2006. Low-T formation of high-Cr spinel with apparently primary chemical characteristics within podiform chromitite from Rayat, northeasternIraq. Mineralogical Magazine, 70(5): 49–508.
Berberian, M. and King, G.C.P., 1981. Towards a palaeogeography and tectonic evolution of Iran. Canadian Journal of Earth Sciences, 18(2): 210–265.
Büchl, A., Brügmann, G. and Batanova, V.G., 2004. Formation of podiform chromitite deposits: implications from PGE abundances and Os isotopic compositions of chromites from the Troodos complex, Cyprus. Chemical Geology, 208(1): 217–232.
Coleman, R.G., 1977. Ophiolites: ancient oceanic lithosphere. Springer-Verlag, New York, 229 pp.
Delavari, M., Amini, S., Saccani, E. and Beccaluva, L., 2009. Geochemistry and Petrology of Mantle Peridotites from the Nehbandan OphioliticComplex, Eastern Iran. Journal of Applied Sciences, 9(15): 2671–2687.
Dick, H.J.B. and Bullen, T., 1984. Chromian spinel as a petrogenetic indicator in abyssal and alpian–type peridotites and spatially associated lavas. Contributions to Mineralogy and Petrology, 86(1): 54–76.
Droop, G.T.R., 1987. A general equation for estimating Fe3+ concentrations in ferromagnesian silicatesand oxides from microprobe analyses, using stoichiometric criteria. Mineralogical Magazine, 51(361): 431–435.
Godard, M., Jousselin, D. and Bodinier, J. L., 2000. Relationships between geochemistry and structure beneath a palaeospreading centre: a study of the mantle section in the Oman Ophiolite. Earth and Planetary Science Letters, 180(1): 133–148.
Hamzehpour, B., 1975. Geological map of the Chahar-farsakh, Scale 1:100,000. Geological Survay of Iran.
Hellebrand, E., Snow, J.E., Dick, H.J.B. and Hofmann, A.W., 2001. Coupled major and trace elements as indicators of the extent of melting in mid-ocean-ridge peridotites. Nature, 410(1): 677–681.
Hirose, K. and Kawamoto, T., 1995. Hydrous partial melting of lherzolite at 1Gpa: the effect of H2O on the genesis of basaltic magmas. Earth and Planetary Science Letters, 133(3): 463– 473.
Hoffman, M.A. and Walker, D., 1978. Textural and chemical variations of olivine and chrome spinel in the East Donver ultramafic bodies, soyth-central Vermont. Geological Society of America. Bulletin, 89(5): 699–710.
Ishii, T., Robinson, P.T., Maekawa, H. and Fiske, R., 1992. Petrological studies of peridotites from diapiric serpentinite seamounts in the Izu-Ogasawara-Mariana forearc. Publication Dates of ODP Proceedings: Scientific Results at Texas A & M University, Texas, Report 27, 41 pp.
Johnson, K.T.M., Dick, H.J.B. and Shimizu, N., 1990. Melting in the oceanic upper mantle: an ion microprobe study of diopsides in abyssal peridotites. Journal of Geophysical Research, 95(3): 2661–2678.
Kamenetsky, V.S., Crawford, A.J. and Meffre, S., 2001. Factors controlling chemistry of magmatic spinel: an empirical study of associated olivine, Cr-spinel and melt inclusions from primitive rocks. Journal of Petrology, 42(4): 655–671.
Kapsiotis, A., 2009. PGM and Chromite Mineralization Associated with the Petrogenesis of the Vourinos and Pindos Ophiolite Complexes, Northwestern Greece. Unpublished Ph.D. thesis, University of Patras, Patras, Greece, 891 pp.
Karipi, S., Tsikouras, B., Hatzipanagiotou, K. and Grammatikopoulos, T.A., 2007. Petrogenetic significance of spinelgroup minerals from the ultramafic rocks of the Iti and Kallidromon ophiolites (Central Greece). Lithos, 99(1): 136–149.
Kretz, R., 1983, Symbols for rock-forming minerals. American Mineralogist, 68(2): 277–279.
Le Bas, M.J., 2000. IUGS Reclassification of the High-Mg and Picritic Volcanic Rocks. Journal of Petrology, 41(10): 1467–1470.
Masoudi, J. and Imamalipour, A., 2019. Application of geological methods for prospecting of podiform chromite deposits in the Khoy ophiolite zone, Northwestern Iran. Journal of Economic Geology, 11(2): 285–303. (in Persian with English abstract)
Matsumoto, L. and Arai, S., 2001. Petrology of dunite/harzburgite with decimeter-scale stratification in a drill core from the Trai-Misaka ultramafic complex southwestern Japan. Journal of Mineralogical and Petrological Sciences, 96(1): 19–28.
Monsef, I., Rahgoshay, M., Pirouz, M., Chiaradia, M., Michel Gregoire, M. and Ceuleneer, G., 2018. The Eastern Makran Ophiolite (SE Iran): evidence for a Late Cretaceous fore-arc oceanic crust. International Geology Review, 60(1):1–27
Nabavi, M.H., 1976. An introduction to geology of Iran. Geological Survey of Iran, Tehran, 109 pp. (in Persian)
Parkinson, I.J. and Pearce, J.A., 1998. Peridotites from the Izu-Bonin-Mariana forearc (ODP Leg 125): evidence for mantle melting and melt–mantle interaction in a supra-subduction zone setting. Journal of Petrology, 39(9): 1577–1618.
Passchier, C.‌W. and Trouw, R.‌A., 1996. Microtectonics. Springer, Berlin, 289 pp.
Piccardo, G.B., Zanetti, A.O. and Müntener, 2007. Melt/peridotite interaction in the Southern Lanzo peridotite: Field, textural and geochemical evidence. Lithos, 94(1):181–209
Saccani, E., Delavari, M., Beccaluva, L. and Amini, S., 2010. Petrological and geochemical constraints on the origin of the Nehbandan ophiolitic complex (eastern Iran): Implication for the evolution of the Sistan Ocean. Lithos, 117(3): 209–228.
Shirdashtzadeh, N., Torabi, G. and Samadi, R., 2017. Petrography and mineral chemistry of metamorphosed mantle peridotites of Nain Ophiolite (Central Iran). Journal of Economic Geology, 9(1): 57–79. (in Persian with English abstract)
Stevens, R.E., 1944. Composition of some chromites of the western hemisphere. American Mineralogist, 29(2):1–64.
Streckeisen, A., 1979. Classification and nomenclature of volcanic rocks, lamprophyres, carbonatites, and melilitic rocks: recommendation and suggestion of the IUGS, subcommission on the systematic of Igneous Rock. Geology, 7(7): 331–335.
Tirrul, R., Bell, I.R., Griffis, R.J. and Camp, V.E., 1983. The Sistan suture zone of eastern Iran. Geological Society of America Bulletin, 94(1): 134–150.
Tirrul, R., Johns, J.W., Willoughby, N.O., Camp, V.E., Griffis, R.J., Bell, I.R. and Meixner, H.M., 1989. Geological map of Nehbandan. Scale 1:100,000. Geological Survey of Iran.
Zarrinkoub, M.H., Pang, K.N., Chung, S.L., Khatib, M.M., Mohammadi, S.S., Chiu, H.Y. and Lee, H.Y., 2012. Zircon U–Pb age and geochemical constraints on the origin of the Birjand ophiolite, Sistan suture zone, eastern Iran. Lithos, 154(4): 392–405.
Zhou, M.F., Sun, M., Keays, R.R. and Kerrich, R.W., 1998. Controls of platinum-group elemental distributions of podiform chromitites: a case study of high-Cr and high-Al chromitites from Chinese orogenic belts. Geochimica et Cosmochimica Acta, 62(4): 677– 688.
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  • Receive Date: 02 December 2018
  • Accept Date: 07 April 2019

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