سنگ‌نگاری، کانی‌شناسی و زمین‌شیمی شیل‌های کوه کمر در برش روم (جنوب قائن) برای تعیین خاستگاه و جایگاه زمین‌ساختی

نوع مقاله : مقاله پژوهشی

نویسندگان

1 مجتمع آموزش عالی گناباد

2 دانشگاه فردوسی مشهد

3 مجتمع آموزش عالی گناباد، گناباد

4 دانشگاه بیرجند

چکیده

منطقه شیل کوه کمر با ستبرای 354 متر از سنگ­های سیلیسی آواری (ماسه سنگ و شیل) تشکیل شده است. بررسی­های سنگ­نگاری نشان می­دهد که ماسه سنگ­های این منطقه در دو گروه نیمه آرکوز و آرکوز قرار دارند. این ماسه سنگ­ها بیشتر از کوارتزهای بسبلوری و تک­بلوری و فلدسپار پتاسیم با جورشدگی متوسط و گردشدگی نیمه زاویه­دار تا نیمه گردشده تشکیل شده­اند و رسیدگی ترکیبی و بافتی متوسط تا پایینی را نشان می­دهند. از نظر سنگ­نگاری، شیل­ها غنی از کوارتز، آلبیت، کلسیت و دارای مقدار کمی کانی رسی (ایلیت و کلریت) هستند. تصاویر مکروسکپ الکترونی روبشی (SEM) نیز نشان­دهنده کانی­های رسی ایلیت و کلریت در این شیل­هاست. به منظور تعیین برخاستگاه، شیل­های این منطقه تجزیه زمین­شیمی شدند که نسبت به پوسته قاره­ای بالایی، تخلیه در مقدار SiO2، Al2O3، Na2O، P < sub>2O5 و عناصر فرعی Ba Cu, Nb,  Sr, و غنی­شدگی در U و CaO را نشان می­دهند. نمودار Al2O3 نسبت به TiO2 و نمودارهای سه تایی (SiO2/20), (K2O+Na2O), (MgO+TiO2+FeO) و همچنینAl2O3, (CaO+Na2O+ K2O), (FeO+MgO) خاستگاه اصلی شیل­های این منطقه را یک سنگ آذرین حدواسط پیشنهاد می­کند. (CIA) و (PIA) محاسبه شده بیانگر هوازدگی شیمیایی ضعیف تا متوسط و آب و هوای خشک و نیمه خشک در ناحیه خاستگاه هستند. نمودارهای تابعی برپایه اکسیدهای عناصر اصلی (SiO2 نسبت بهK2O/Na2O) و همچنین نمودار سه تایی (Na2O+K2O), (TiO2+MgO+Fe2O3), (SiO2/20) نشان می­دهد که شیل­های این منطقه در جایگاه قاره­ای فعال قرار دارند. بازسازی جغرافیای دیرینه برای این منطقه طی ائوسن نشان می­دهد که رسوبگذاری این منطقه در یک حوضه درون قاره­ای در حال فرونشینی رخ داده است.    

کلیدواژه‌ها

عنوان مقاله [English]

Petrography, Mineralogy and Geochemistry of Kuhkamar Shale in the Roum section (South of Qayen): Application for Provenance and Tectonic setting

نویسندگان [English]

  • Sedigheh Zirjanizadeh 1
  • Yaghoub Nasiri 1
  • Seyed khalil Forouzandeh 2
  • Samira Taghdisi Nikbakht 3
  • Hamid Hafezi Moghaddas 2
  • Mohammad amin Zarei Darmian 4
1
2
3
4
چکیده [English]

The Kuhkamar shale with a thickness of 354 m is composed of siliciclastic rocks (sandstone and shale). Petrography studies of the sandstones in this area show two petrofacies including arkose and sub-arkose. These sandstones composed of sub rounded to moderately sorted; therefore, compositionaly to texturaly, they are immature to submature with mono and polycrystalline quartz and k-feldespar. In terms of petrography, the shales are rich in quartz, albite, calcite and, to a lesser degree, clay minerals (illite and chlorite). Moreover, SEM images represent clay minerals of illite and chlorite in these shales. In order to interpret provenance, the shales of the studied section have been geochemically analyzed. These shales are rich in quartz, albite, and calcite with small amounts of clay minerals (illite and chlorite). With respect to (UCC), these shales show depletion in SiO2، Al2O3، Na2O, P < sub>2O5, Ba, Cu, Nb and Sr and enrichment in U and CaO. Plotting Al2O3 versus TiO2 as well as ternary diagrams, (SiO2/20), (K2O+Na2O), (MgO+TiO2+FeO) and Al2O3, (CaO + Na2O + K2O), (FeO + MgO), suggest that the original source of these shale was from intermediate igneous rocks. Calculated PIA and CIA indicate low to medium chemical weathering and arid to semi-arid climatic conditions in the source area. Prepared discrimation diagram using the major oxides (SiO2 versus K2O/Na2O) and ternary diagram (Na2O+ K2O), (TiO2+ MgO+ Fe2O3), (SiO2/20), shows that most of these shales were plotted in active continental margin. Paleogeographic reconstruction in this area, during the Eocene, shows that sedimentation in this area is mainly taken place in the intracontinental subsiding basin.

کلیدواژه‌ها [English]

  • Geochemistry
  • paleoweathering
  • source rock
  • provenance
  • South of Qayen

مراجع

[1] Mondal M.E.A., Wani H., Mondal B., "Geochemical signature of provenance, tectonics and chemical weathering in the Quaternary flood plain sediments of the Hindon River, Gangetic plain, India", Tectonophysics 566 (2012) 87- 94.

[2] Armas P., Moreno C., Sánchez M.L., González F., "Sedimentary palaeoenvironment, petrography, provenance and diagenetic inference of the Anacleto Formation in the Neuquén Basin, Late Cretaceous, Argentina", Journal of South American Earth Sciences 53 (2014) 59-76.

[3] Mahavaraju J., "Geochemistry of Late Cretaceous sedimentary rocks of the Cauvery Basin, South India: Constraints on paleo weathring, provenance, and end Cretaceous environments", Chemostratigraphy 8 (2015) 185-214.

[4] Khanehbad M., Moussavi-Harami R., Mahboubi A., Nadjafi A., "Geochemistry of Carboniferous Shales of the Sardar Formation, East Central Iran: Implication for Provenance, Paleoclimate and Paleo_oxygenation Conditions at a Passive Continental Margin", Geochemistry International 50 (2012) 777-790.

[5] Zand-Moghadam H., Moussavi-Harami R., Mahboubi A., Bavi H., "Comparison of tidalites in silicicastic, carbonate, and mixed siicicastic-carbonate System: examples from Cambrian and Devonian deposits of East-Central Iran", ISRN Geology (2013) 1-21.

[6] Oghenekome M.E., Tapas K., Chatterjee T.K., Van Bever Donker J.M., Napoleon N., Hammond Q., "Geochemistry and weathering history of the Balfour sandstone formation, Karoo basin, South Africa: Insight to provenance and tectonic setting", Journal of African Earth Sciences, 10.1016/j.jafrearsci.2018.07.014.

[7] Cullers R.L., "The geochemistry of shales, siltstones and sandstones of Pennsylvanian-Permian age, Colorado, U.S.A implications for provenance and metamorphic studies", Lithos 51 (2000) 305-327.

[8] Hessler A.M., Lower D.M., "Wethering and sediment generation in the Archean: An integrated study of the evolution of siliciclastic sedimentary rocks of the 3.2 Ga Moodies Group, Barberton Greenstone Belt, south Africa", Precambrian Research 151 (2000) 185-210.

[9] DaPeng L., YueLong C., Zhong W., Yu L., Jian Z., "Paleozoic sedimentary record of the Xing-Meng Orogenic Belt, Inner Mongolia: implications for the provenances and tectonic evolution of the Central Asian Orogenic Belt", Chinese Science Bulletin 57 (2012) 776-785.

[11] Shahidi A., Baharfiroozi A., "Geological Map of Iran. 1:100,000 Roum", Geological Survey of Iran (1991).

[12] Folk R.L., "Petrology of Sedimentary Rocks", Hamphill, Austin, Texas (1980) 182 p.

[13] Moosavirad A.M., Janardhana M.R., Sethumadhav M.S., Moghadam M.R., Shankara M., "Geochemistry of lower Jurassic shales of the Shemshak Formation, Kerman Province, Central Iran: Provenance, source weathering and tectonic setting", Chemie der ErdeGeochemistry 71 (2011) 279–288.

[14] Salehi M.A., Moussavi-Harami R., Mahboubi A., Wilmsen M., Heubeck Ch., "Tectonic and palaeogeographic implications of compositionalvariations within the siliciclastic Ab-Haji Formation (Lower Jurassic, east central Iran)", Neues Jahrbuch für Geologie und Paläontologie – Abhandlungenb 271 (2014) 21-48.

[15] Wronkiewicz D.J., Condie K.C., "Geochemistry and provenance of sediments from the Pongola Supergroup, South Africa: evidence for a 3.0-Ga-old continental craton", Geochimica et Cosmochimica Acta 53 (1989) 1537- 1549

[16] Kalsbeek F., Frei R., "Geochemistry of Precambrian sedimentary rocks used to solve stratigraphical problems: an example from the Neoproterozoic Volta basin, Ghana", Precambrian Research 176 (2010) 66–75.

[17] Mishra M., Sen S., "Geological signatures of Mesoproterozoic siliciclastic rocks of the Kaimur Group of the Vindhyan Supergroup, Central India. Chin", Journal Geochemical 20 (2010) 21–32.

[18] Quasim M.A., Nath hota R., Ahmad A.H.M., Albaroot M., "An approach to provenance and tectonic setting of the Proterozoic Upper Kaimur Group sandstones, Son Valley: constraints from framework mineralogy and heavy mineral analysis", Himalayan Geology, 3 (2018), 145 – 160.

[19] Roser B.P., Korsch R.J., "Provenance signatures of sandstone–mudstone suites determined using discriminant function analysis of major-element data", Chemical Geology 67 (1988) 119–139.

[20] Schieber J., "A combined petrographical-geochemical provenance study of the Newland formation, Mid- Proterozoic of Montana", Geological Magazine 129 (1992) 223–237.

[21] Hayashi K., Fujisawa H., Holland H.D., Ohmoto H., "Geochemistry of 1.9 sedimentary rocks from northeastern Labrador, Canada", Geochimica et Cosmochimica Acta 61 (1997) 4115–4137.

[22] Nesbitt H.W., Young G.M., "Early Proterozoic climates and plate motionsbinferred from major element chemistry of lutites", Nature 299 (1982) 715–717.

[23] Araujo C.E.G., Pineo T.R.G., Caby R., Costa, F.G.J.C., Vasconcelos, A.M., Rodrigues J.B., "Provenance of the Novo Oriente Group, Southwestern Ceara Central Boiron, Borborema province (NE Brazil): A dismembered segment of a magma-poor passive margin or a restricted rift-related basin?", Gondawana Research 18 (2010) 497-513.

[24] Velmurugan K., Madhavaraju J., Balaram V., Ramachandran A., Ramasamy S., Ramirez-Montoya E., Saucedo-Samaniego J.C., "Provenance and Tectonic Setting of the Proterozoic Clastic Rocks of the Kerur Formation, Badami Group, Mohare Area, Karnataka, India", Geological Evolution of the Precambrian Indian Shield, Society of Earth Scientists Series, 2019, https://doi.org/10.1007/978-3-319-89698-4_11.

[25] Paikaray S., Banerjee S., Mukherji S., "Geochemistry of shales from the Paleoproterozoic to Neoproterozoic Vindhyan Supergroup: Implications on provenance, tectonics and paleoweathering", Journal of Asian Earth Sciences 32 (2008) 34–48.

[26] Akulshina E.P., "Evolution of physicochemical condition of sedimentation in the Riphean and Phanerozoic (with Siberia as example), Sreda I Zhizn v Geologicheskom Proshlom (Environment and life in Geological Past)", Novosibirsk: Nauka (1990) 17-26.

[27] Alvarez N.M., Roser B.P., "Geochemistry of black shales from the Lower Cretaceous Paja Formation, Eastern Cordillera, Colombia: Source weathering, provenance, and tectonic setting", Journal of South American Earth Sciences 23 (2007) 271–289.

[28] Fedo C.M., Young G.M., Nest H.W., Hanchar J.M., "Potassicand sodic metasomatism in the Southern Province of the Canadian Shield: evidence from the Paleoproterozoic Serpent Formation, Huronian Supergroup Canada", Precambrian Research 84 (1997) 17–36.

[29] Cox R., Lower D.R., Cullers R.L., "The influence of sediment recycling and Basement composition of Evolution of mudrock chemistry in the southwestern United States", Geochimica et Cosochimica Acta 59 (1995) 2919–2940.

[30] Lee Y.L., "Provenance Derived from the Geochemistry of Late Paleozoic–Early Mesozoic Mudrocks of the Pyeongan Supergroup, Korea", Sediment. Geolical 149 (2002) 219–235.

[31] Suttner L.J., Dutta P.K., "Alluvial sandstone composition and palaeoclimate: framework mineralogy", Journal of Sedimentary Petrology, 56 (1985) 329–345.

[32] Habicht J.K.A., "Paleoclimate, Paleomagnetism, and Continental Drift", American Association of Petroleum Geologists, 9 (1979) 1-18.

[33] Nowrouzi N., Moussavi-Harami R., Mahboubi A., Mahmudy Gharaie M.H., Ghaemi F., "Petrography and geochemistry of Silurian Niur sandstones, Derenjal Mountains, East Central Iran: implications for tectonic setting, provenance and weathering", Arabian Journal of Geosciences 7 (2013) 2793-2813.

[34] Jafarzadeh M., Moussavi-Harami R., Amini A., Mahboubi A., Farzaneh F., "Geochemical constrants on the provenance of Oligocene- Miocene siliciclast deposits (Zivah Formation) of NW Iran: implications for the tectonic evolution of the Caucasus", Arabian Journal of Geosciences 7 (2014) 4245- 2463.

[35] Zaid S.M., Gahtani F.A., "Provenance, diagenesis, tectonic setting, and geochemistry of Hawkesbury Sandstone (Middle Triassic), southern Sydney Basin, Australia", Journal of Earth Sciences 24 (2015) 72-98.

[36] Bhatia M.R., "Plate tectonics and geochemical composition of sandstones", Geology 91 (1983) 611–626.

[37] Kroonenberg S.B., "Effects of provenance, sorting and weathering on the geochemistry of fluvial sands from different tectonic and climatic environments", Proceedings of the 29th International Geological Congress, Part A (1994) 69-81.

[38] Aghaei A., Mahboubi A., Moussavi-Harami R., Heubeck C., Nadjafi A., "Facies analysis and sequence stratigraphy of an Upper Jurassic carbonate ramp in the Eastern Alborz range and Binalud Mountains, NE Iran", Facies 59 (2012) 863- 889.

[39] Parent H., Raoufian A., Seyed-Emami K., Ashouri A.R., Majidifard M.R., "The Bajocian- Kimmeridgian Ammonite Fauna of the Dalichai Formation in the SE Binalud Mountains, Iran", Informes del Insitituto de Fisiografíay Geología1 (2014) 1-60.

[40] Bhatia M.R., Crook K.A., "Trace element characteristics of greywackes and tectonic

setting discrimination of sedimentary basins", Contributions to Mineralogy and Petrology

92 (1986) 181–193.

فایل ها

سابقه مقاله

  • تاریخ دریافت: 18 خرداد 1398
  • تاریخ بازنگری: 03 مهر 1398
  • تاریخ پذیرش: 04 آبان 1398

هم رسانی

ارجاع به این مقاله

آمار