The Lower Oligocene geological evolution of the Chah-e-Alikhan area (Northeast of Isfahan province); constrains from the study of alkali basalt dikes

Document Type : Research Article

Authors

1 M.Sc., Department of Geology, University of Isfahan, Isfahan, Iran

2 Ph.D., Department of Geology, University of Isfahan, Isfahan, Iran

3 Professor, Department of Geology, University of Isfahan, Isfahan, Iran

4 Associate Professor, Department of Geology, Faculty of Basic Sciences, Tarbiat Modares University, 14115-175, Tehran, Iran

10.22067/econg.2023.84766.1090

Abstract

The Lower Oligocene basic dikes are cropped out in the Chah-e-Alikhan area (Northeast of Isfahan province, North of the Daq-e-Sorkh desert). These dikes show NE-SW and NW-SE trends and cross cut the Eocene volcanic rocks and associated flysches. NW-SE dikes are younger and cut the NE-SW ones. These dikes are similar in petrography and are composed of plagioclase, clinopyroxene, olivine, sanidine, Cr-spinel and ilmenite. Zeolite, serpentine, calcite and magnetite are secondary minerals. These dikes represent the porphyritic, glomeroporphyritic, poikilitic and trachytic textures. Intergranular and granular textures can be seen at the center of the larger dikes. These basalts are enriched in alkalis (Na2O+K2O), LREE and LILE (Cs, Rb, Ba, Pb) and have high values of LREE/HREE ratio (La/Yb=8.9-10). In the classification diagrams, which are based on the incompatible elements and HFSEs, they are classified as alkali basalts. The primitive magma of these basaltic dikes has been produced by partial melting of a garnet-spinel lherzolite of the mantle previously suffered the carbonate metasomatism. The formation of the alkali basalt dikes of the Chah-e-Alikhan area can be ascribed to the former subduction of the Central- East Iranian Microcontinent (CEIM) confining oceanic crust and decompression melting induced by the extensional basin of the Anarak‒Jandaq area in Early Oligocene. The primary basaltic magma has been formed by low degree of partial melting of a metasomatised mantle lherzolite during continental crust extension episode in the lower Oligocene and has been ascent through the faults. 
 
Introduction
In the Northwest of CEIM (Central-East Iranian Microcontinent), along the Great Kavir fault, volumes of alkali basalts with the lower Oligocene age are outcropped as volcanic and subvolcanic (Dike) rocks. In this research, the subvolcanic exposures of this basic magmatism in the the Chah-e-Alikhan area is discussed. The Lower Oligocene basic dikes are cropped out in the Chah-e-Alikhan area (Northeast of Isfahan, Northeast of Zavareh, and Northwest of the CEIM). These dikes show NE-SW and NW-SE trends and cross cut the Eocene volcanic rocks and associated flysches. In this paper, the geological and petrological aspects, as well as the geodynamic setting of alkali basalt dikes of the Chah-e-Alikhan area are discussed. Study of these dikes, as a part of the Cenozoic alkaline magmatism from Northwest of the CEIM, will be useful in understanding the geodynamical evolution of the Central Iran.
 
Analytical method
 The method of study is including petrography (field, library and microscopic studies) and whole rocks geochemical analysis of rocks. 13 fresh whole rock samples of alkali basalts from the Chah-e-Alikhan area were selected for the major and trace elements chemical analyses.
Whole rock geochemical analyses carried out by using a Bruker S4 Pioneer XRF at the Central Laboratory of the University of Isfahan. Trace element compositions of the selected samples were achieved by ICP-MS (Inductively coupled plasma-mass spectrometry) at the Zarazma Mineral Studies Company (Tehran, Iran).
 
Results and discussion
The rock-forming minerals of the Chahe-e-Alikhan basic dikes are Cr-spinel, olivine, clinopyroxene, plagioclase, sanidine and ilmenite. Zeolite, serpentine, calcite and magnetite are secondary minerals which are formed as a result of the alteration of primary minerals. Petrographical characteristics indicate that these dikes are alkali basalt and represent the porphyritic, glomeroporphyritic and trachytic textures. Intergranular and granular textures can be seen at the center of the larger dikes.
These basalts are enriched in alkalis (Na2O+K2O=4.5-5.4 wt%), LILEs (Cs, Rb, Ba, Pb) and have high values of LREE/HREE ratio (La/Yb=8.9-10). Trace elements ratio diagrams such as La/Nb versus La/Yb, Dy/Yb against La/Yb, Sm/Yb versus La/Yb (Bogaard and Worner, 2003) and Ce/Yb-Ce (Ellam, 1992) are used in order to determination of the depth, type and degree of partial melting of the source rock. Based on the geochemical characteristics and diagrams, the primitive magma of the Chah-e-Alikhan alkali basalts possibly have been produced by about 5 to 10 percent partial melting of a garnet-spinel lherzolite, which is located at the depth of about 105 km, as a part of a mixed asthenospheric–lithospheric mantle. The elevated values of the Zr/Hf ratio and the Na2O + K2O versus TiO2 diagram (Zeng et al., 2010) indicate that the primitive magma of the studied basic dikes previously suffered the carbonate metasomatism.
The Chah-e-Alikhan alkali basalts show high values of the Alkalis (Na2O + K2O), enrichment in LREE, HFSE and LILE. The subducted oceanic slab is the source of carbon and LILEs are the mobile components of subduction (Shaw et al., 2003). Considering that Cs is a highly fluid mobile element, enrichment in Cs relative to Rb suggests that the fluid phases derived from a subducting slab are probably the metasomatic agents.
The lower Oligocene alkaline magmatism in the Chah-e-Alikhan area and the enrichment of the mantle with incompatible elements (metasomatism) can be attributed to two oceanic crust subduction events: (1) Northeast ward Neotethys subduction along the Zagros Thrust Zone beneath the Central Iran from the Triassic to the Eocene (Torabi, 2010); and (2) Subduction of an oceanic crust along the Great Kavir Fault, which is situated to the western margin of the CEIM. The spreading of the last ocean crust started in the Triassic and ended in the Eocene. The remnants of this oceanic crust are found as ophiolitic melanges on the western side of the CEIM, such as the Nain, Surk, and Ashin ophiolites (Rajabi and Torabi, 2012; Torabi, 2010). The geological history and position of the Chah-e-Alikhan alkali basalt dikes suggests that the the carbonate metasomatism of the mantle peridotites can be attributed to the subduction of the CEIM confining oceanic crust.
Several tectonic discrimination diagrams have been used for determination of the tectonic setting of the Chah-e-Alikhan basalts. The La/Yb versus Th/Nb (Hollocher et al., 2012), Ta/Yb against Th/Yb (Gorton and Schandl, 2000) and DF1 versus DF2 (Verma and Agrawual, 2011) diagrams suggest a within-plate (continental) tectonic setting.
The activity of the major faults of the area such as Great Kavir, Chah Mishury and Chah Gireh Faults has been created a suitable inter-plate extensional system to ascending the Lower Oligocene alkali basalt magma in the Chah-e-Alikhan area.
 
Conclusion
The Lower Oligocene alkali basalts of the Chah-e-Alikhan area is a part of the intra-continental alkaline magmatism crosscuts the Eocene volcanic rocks. The area provides a setting to study the Cenozoic alkaline magmatism of the northwest of the CEIM.
These basalts are enriched in total Alkalis, TiO2, LREE and LILEs. They have been produced by about 5 to 10 percent degree of partial melting of a garnet-spinel bearing lherzolite of a mixed lithospheric-asthenospheric mantle which is previously metasomatised. The mantle enrichment can be ascribed to the subduction of the CEIM confining oceanic crust beneath the Central Iran from the Triassic to the Eocene. The Grate Kavir Fault and related faults have played an important role in the Lower Oligocene alkaline magmatism in northwest of the CEIM.
 
Acknowledgments
The authors thank the University of Isfahan for financial support.
 
 

Keywords

References

Abdel-Fattah, M., Abdel-Rahman, A.M. and Nassar, P.E., 2004. Cenozoic volcanism in the Middle East: petrogenesis of alkali basalts from Northern Lebanon. Geological Magazine, 141(5): 545–63. https://doi.org/10.1017/S0016756804009604
Aistov, L., Melnikov, B., Krivyakin, B., Morozov, L., Kiristaev, V. and Romanko, E., 1984. Geology of the Khur Area (Central Iran). Geological Survey of Iran, Tehran, Report 20, 132 pp.
Bayat, F. and Torabi, G., 2011. Alkaline lamprophyric province of Central Iran. Island Arc, 20(3): 386–400. https://doi.org/10.1111/j.1440-1738.2011.00776.x
Bogaard, P.J.F. and Worner, G., 2003. Petrogenesis of basanitic to tholeiitic volcanic rocks from the Miocene Vogelsberg, Central Germany. Journal of Petrology, 44(3): 569–602. https://doi.org/10.1093/petrology/44.3.569
Cox, K.G., Bell, J.D. and Pankhurts, R.J., 1979. The interpretation of Igneous rocks, Allen and Unwin, London, 450 pp. https://doi.org/10.1007/978-94-017-3373-1
Dostal, J. 2017. Rare earth element deposits of alkaline igneous rocks. Resources 6(3): 34. https://doi.org/10.3390/resources6030034
Ellam, R., 1992. Lithospheric thickness as a control on basalt geochemistry. Geology, 20(2): 153–156. https://doi.org/10.1130/0091-7613(1992)020<0153:LTAACO>2.3.CO;2
Fitton, J.G. and Upton, B.G.J., 1987. Alkaline Igneous Rocks, Blackwell, London, 576 pp.
Ghasemi, H., Barahmand, M. and Sadeghian, M., 2011. The Oligocene basaltic lavas of east and southeast of Shahroud: Implication for back-arc basin setting of Central Iran Oligo-Miocene basin. Petrological Journal, 2(7): 77-94. (in Persian with English abstract) Retrieved November 1 2023 from https://ijp.ui.ac.ir/article_16081.html?lang=en
Ghasemi, H., Rostami Hossuri, M., Sadeghian, M. and Kadkhodaye Arab, F., 2016. Back-arc extensional magmatism in the Oligo-Miocene basin of the Northern edge of Central Iran. Scientific Quarterly Journal of Geosciences, 25(99): 239–252. (in Persian with English abstract) https://doi.org/10.22071/gsj.2016.40915
Goli, Z., Torabi, G. and Arai, S., 2021. High-K calc-alkaline Eocene volcanic rocks from the Anarak area (Central Iran): A key structure for the early stages of oceanic basin closure and the beginning of collision. Geotectonics, 55(4): 600–617. https://doi.org/10.1134/S0016852121040075
Gorton, M.P. and Schandl, E.S., 2000. From continents to island arcs: a geochemical index of tectonic setting for arc-related and within-plate felsic to intermediate volcanic rocks. The Canadian Mineralogist, 38(5): 1065–1073. https://doi.org/10.2113/GSCANMIN.38.5.1065
Hollocher, K., Robinson, P., Walsh, E. and Roberts, D., 2012. Geochemistry of amphibolite-facies volcanics and gabbros of the Storen Nappe in extensions west and southwest of Trondheim, western Gneiss region, Norway: A key to correlations and paleotectonic settings. American Journal of Science, 312(4): 357–416. https://doi.org/10.2475/04.2012.01
Hughes, C.J., 1973. Spilites, keratophyres, and the igneous spectrum. Geological Magazine, 109(6): 513–527. https://doi.org/10.1017/S0016756800042795
Jamshidzaei, A., Torabi, G., Morishita, G. and Tamura, A., 2021. Eocene dike swarm and felsic stock in Central Iran: Roles of metasomatized mantle wedge and Neo-Tethyan slab. Journal of Geodynamics, 145 (1): 101844. https://doi.org/:10.1016/j.jog.2021.101844
Jaques, A.L., Creaser, R.A., Ferguson, J. and Smith, C.B., 1985. A review of the alkaline rocks of Australia. Geological Society of South Africa, 88: 34‌–311. Retrieved October 14, 2023 from https://pubs.geoscienceworld.org/gssa/sajg/article/88/2/311/122026/A-review-of-the-alkaline-rocks-of-Australia
Kiseeva, E.S., Kamenetsky, V.S., Yaxley, G.M. and Shee, S.R., 2017. Mantle melting versus mantle metasomatism–“The chicken or the egg” dilemma. Chemical Geology, 455(20): 120–130. https://doi.org/10.1016/j.chemgeo.2016.10.026
Le Maitre, R.‌W., 1976. The chemical variability of some common igneous rocks. Journal of Petrology 17(4): 589–637. https://doi.org/10.1093/petrology/17.4.589
Le Maitre, R.W., 2002. Igneous Rocks: A classification and glossary of terms, 2nd edn. Cambridge University Press, New York, 236 pp. https://doi.org/10.1017/CBO9780511535581
McDonough, W.F. and Sun, S.S., 1995. The composition of the Earth. Chemical Geology, 120(3–4): 223–253. https://doi.org/10.1016/0009-2541(94)00140-4
McKenzie, D.P. and Bickle, M.J. 1988. Volume and composition of melt generated by extension of the lithosphere. Journal of Petrology, 29(3): 625–679. https://doi.org/10.1093/petrology/29.3.625
Mohammadi, N., Sodoudi, F., Mohammadi, E. and Sadidkhouy, A., 2013. New constraints on lithospheric thickness of the Iranian plateau using converted waves. Journal of Seismology, 17(3): 883–895. https://doi.org/10.1007/s10950-013-9359-2
Moradi, S., Khaksar, T., Nazarinia, A. and Hussain, A., 2022. Petrology and geochemistry of Plio-Quaternary high-Nb basalts from Shahr-e-Babak area: Insights into post-collision magmatic processes in the Kerman Cenozoic Magmatic Arc. Geologica Acta, 20(8): 1–19. https://doi.org/10.1344/GeologicaActa2022.20.8
Rajabi, S. and Torabi, G., 2012. Petrology of mantle peridotites and volcanic rocks of the narrowest Mesozoic ophiolitic zone from central Iran (Yazd province). Neues Jahrbuch fur Geologie und Palaeontologie - Abhandlungen, 265(1): 49–78. https://doi.org/10.1127/0077-7749/2012/0245
Rajabi, S., Torabi, G. and Arai, S., 2014. Oligocene crustal xenolith-bearing alkaline basalt from Jandaq area (Central Iran): implications for magma genesis and crustal nature. Island Arc, 23(2): 125–141. https://doi.org/10.1111/iar.12063
Ramezani, J. and Tucker, R. D., 2003. The Saghand region, central Iran: U-Pb geochronology, petrogenesis and implications for Gondwana tectonics. American Journal of Science, 303(7): 65–622. http://dx.doi.org/10.2475/ajs.303.7.622
Rostami-Hossouri, M., Ghasemi, H., Pang, K.N., Shellnutt, J.G., Rezaei-Kahkhaei, M., Miao, L., Mobasheri, M., Iizuka, Y., Lee, H-Y. and Lin, T-H., 2020. Geochemistry of continental alkali basalts in the Sabzevar region, northern Iran: implications for the role of pyroxenite in magma genesis. Contributions to Mineralogy and Petrology, 175(5): 1–22. https://doi.org/:10.1007/s00410-020-01687-z
Rudnick, R.L., McDonough, W.F. and Chappell, B.W., 1993. Carbonatite metasomatism in the northern Tanzanian mantle: petrographic and geochemical characteristics. Earth and Planetary Science Letters, 114(4): 463–475. https://doi.org/10.1016/0012-821X(93)90076-L
Salim, H., Torabi, G., Shirdashtzadeh, N., Sahlabadi, M. and Morishita, T., 2022. Early Oligocene continental alkalibasalts of the Central Toveireh area (Southwest of Jandaq, Isfahan Province, Iran). Geotectonics, 56(2): 241–256. https://doi.org/10.1134/s001685212202011x
Shakerardakani, F., Neubauer, F., Bernroider, M., Von Quadt, A., Peytcheva, I., Liu, X., Genser, J., Monfaredi, B. and Masoudi, F., 2017. Geochemical and isotopic evidence for Carboniferous rifting: mafic dikes in the central Sanandaj-Sirjan zone (Dorud-Azna, West Iran). Geologica Carpathica, 68(3): 229–247. https://doi.org/10.1515/geoca-2017-0017
Sharkovski, M., Susov, M., Krivyakin, B., Morozov, L., Kiristaev, V. and Romanko, E., 1984. Geology of the Anarak Area (Central Iran), Geological Survey of Iran, Technoexport, Report 19: 143 pp.
Shaw, A.M., Hilton, D.R., Fischer, T.P., Walker, J.A. and Alvarado, G.E., 2003. Contrasting He-C relationships in Nicaragua and Costa Rica: insights into C cycling through subduction zones. Earth and Planetary Science Letters, 214(3–4): 499–513. https://doi.org/10.1016/S0012-821X(03)00401-1
Sun, S.S. and McDonough, W.F., 1989. Chemical and isotopic systematics of oceanic basalts: Implications for mantle composition and processes. In: A.D. Saunders and M.J. Norry, (Editors) Magmatism in ocean basins. Geological Society London, Special Publications, 42(1): 313–345. https://doi.org/10.1144/GSL.SP.1989.042.01.19
Torabi, G., 2010. Early Oligocene alkaline lamprophyric dikes from the Jandaq area (Isfahan Province, Central Iran): Evidence of Central-East Iranian microcontinent confining oceanic crust subduction. Island Arc, 19(2): 277–291. https://doi.org/10.1111/j.1440-1738.2009.00705.x
Torabi, G., 2011. Middle Eocene volcanic shoshonites from western margin of Central-East Iranian Microcontinent (CEIM), a mark of previously subducted CEIM-confining oceanic crust. Petrology, 19(7): 675–689. https://doi.org/10.1134/S0869591111030039
Torabi, G. and Hemmati, O., 2011. Alkaline basalt from the Central Iran, a mark of previously subducted Paleo-Tethys oceanic crust. Petrology, 19(7): 690–704. https://doi.org/10.1134/S0869591111070034
Turner, S., Sandiford, M. and Foden, J., 1992. Some geodynamicand compositional constraints on post orogenic magmatism. Journal of Economic Geology, 20(10): 931–934. https://doi.org/10.1130/0091-7613(1992)020<0931:SGACCO>2.3.CO;2
Verma, S.P. and Agrawual, S., 2011. New tectonic discrimination diagrams for basic and ultrabasic volcanic rocks through log-transformed ratios of high field strength elements and implications for petrogenetic processes. Revista Mexicana de Ciencias Geológicas, 28(1): 24–44. Retrieved October 14, 2023 from https://www.redalyc.org/articulo.oa?id=57220090003
Whitney, D.L. and Evans, B.W., 2010. Abbreviations for Names of Rock-Forming Minerals. American Mineralogist, 95(1): 185–187. http://dx.doi.org/10.2138/am.2010.3371
Winchester, J.A. and Floyd, P.A., 1977. Geochemical discrimination of different magma series and their differentiation products using immobile elements. Chemical Geology, 20: 249–284. https://doi.org/10.1016/0009-2541(77)90057-2
Zeng, G., Chen, L.H., Xu, X.S., Jiang, S.Y. and Hofmann, A.W., 2010. Carbonated mantle sources for Cenozoic intra-plate alkaline basalts in Shandong, North China. Chemical Geology, 273(1–2): 35–45. https://doi.org/10.1016/j.chemgeo.2010.02.009
Zhang, G., Peng, R., Qiu, H., Wen, H., Feng, Y., Chen, B., Zhang, L., Liu, S. and Liu, T., 2020. Origin of Northeast Fujian basalts and limitations on the heterogeneity of mantle sources for Cenozoic alkaline magmatism across SE China: Evidence from zircon U–Pb dating petrological, whole-rock geochemical, and isotopic studies. Minerals 10(9): 1–18. https://doi.org/:10.3390/min10090770
     
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 17 October 2023
  • Revise Date: 12 December 2023
  • Accept Date: 12 December 2023

Share

How to cite

Statistics