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Thermal History of Lower Paleozoic Rocks on the Peri-Tornquist Margin of the East European Craton (Podolia, Ukraine) Inferred from Combined XRD, K-Ar, and AFT Data

Published online by Cambridge University Press:  01 January 2024

Jan Środoń*
Affiliation:
Institute of Geological Sciences, Polish Academy of Sciences - Research Centre in Kraków, ul. Senacka 1, 31-002 Kraków, Poland
Mariusz Paszkowski
Affiliation:
Institute of Geological Sciences, Polish Academy of Sciences - Research Centre in Kraków, ul. Senacka 1, 31-002 Kraków, Poland
Daniel Drygant
Affiliation:
Natural History Museum of National Academy of Sciences of Ukraine, 18 Teatralna St., 79008 L’viv, Ukraine
Aneta Anczkiewicz
Affiliation:
Institute of Geological Sciences, Polish Academy of Sciences - Research Centre in Kraków, ul. Senacka 1, 31-002 Kraków, Poland
Michał Banaś
Affiliation:
Institute of Geological Sciences, Polish Academy of Sciences - Research Centre in Kraków, ul. Senacka 1, 31-002 Kraków, Poland
*
*E-mail address of corresponding author: [email protected]
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Abstract

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The Upper Silurian–Lower Devonian section of the Dniester gorge in Podolia and samples from boreholes located S and N of this area were studied in order to reconstruct the thermal history of Lower Paleozoic sedimentary rocks in the Dniester segment of the Peri-Tornquist margin of the East European Craton which is the most eastern part of a major shale-gas target in Europe. X-ray diffraction data for illite-smectite from shales and carbonates indicate very advanced diagenesis and maximum paleotemperatures of ~200ºC, higher than interpreted from the ‘conodont alteration index’ (CAI) data. Diagenesis of the Devonian section is slightly less advanced than that of the underlying Silurian section, indicating that it is a regional feature and the result of burial. The regional distribution of the diagenetic grade based on illite matches well with the pattern established from the CAI data. K-Ar dating of illite-smectite from Silurian bentonites and shales gave a consistent set of dates ranging from 390 to 312 Ma. To explain such advanced levels of diagenesis and such K-Ar dates, the extension of the Carboniferous foreland basin (which today is only preserved to the NW of L’viv) toward the SE on the craton margin has to be assumed. The diagenetic zonation pattern of the Carboniferous coals supports this hypothesis. The Carboniferous cover may have been either sedimentary or partially tectonic (Variscan intracratonic duplexes) in origin and the thickness, necessary for the observed level of diagenesis, may have been reduced by an elevated heat flow along the major tectonic zone at the edge of the craton (TESZ). The presence of such cover is confirmed by completely reset Cretaceous apatite fission track (AFT) ages of the Silurian bentonites. The AFT dates also imply a Tertiary heating event in the area.

The 10 Å clay mineral present in the dolomitic part of the profile (Silurian), both in bentonites and in other rocks, is aluminoceladonite or intermediate between illite and aluminoceladonite, while in the Devonian shale section only illite was documented. Chlorite is also common in the studied rocks and is at least partially authigenic. It is non-expandable in the samples from boreholes, while often expandable to variable extents in the samples from outcrops, which also contain goethite. Such variation in chlorite is attributed to contemporary weathering.

Type
Research Article
Copyright
Copyright © Clay Minerals Society 2013

References

Altaner, S.P. Hower, J. Whitney, G. and Aronson, J.L., 1984 Model for K-bentonite formation: evidence from zoned K-bentonites in the disturbed belt, Montana Geology 12 412415.2.0.CO;2>CrossRefGoogle Scholar
Anczkiewicz, A.A., 2005 Apatite fission track verification of the maximum paleotemperatures estimated from smectite illitization for the Tatra Mts., Podhale Basin, and the adjacent area of the External Carpathians Kraków, Poland Institute of Geological Sciences PAN.Google Scholar
Anczkiewicz, A.A. Zattin, M. and Środoń, J., 2005 Cenozoic uplift of the Tatras and Podhale basin from the perspective of the apatite fission track analyses Mineralogical Society of Poland — Special Papers 25 261264.Google Scholar
Antonowicz, L. Hooper, R. and Iwanowska, E., 2003 Lublin Syncline as a result of thin-skinned Variscan deformation (SE Poland) Przeglad Geologiczny 51 344350.Google Scholar
Barker, C.h.E. Pawlewicz, M.J., Buntebarth G, G. and Stegena, L., 1986 The correlation of vitrinite reflectance with maximum temperature in humic organic matter Paleogeothermics Berlin Springer-Verlag 7993.CrossRefGoogle Scholar
Bergström, S.M., 1980 Conodonts as paleotemperature tools in Ordovician rocks of the Caledonides and adjacent areas in Scandinavia and the British Isles Geologiska Föreningens i Stockholm Förhandlingar 102 377392.CrossRefGoogle Scholar
Botor, D. Kotarba, M. and Kosakowski, P., 2002 Petroleum generation in the Carboniferous strata of the Lublin Trough (Poland): an integrated geochemical and numerical modelling approach Organic Geochemistry 33 461476.CrossRefGoogle Scholar
Buła, Z. and Habryn, R., 2011 Precambrian and Paleozoic basement of the Carpathian Foredeep and the adjacent Outer Carpathians (SE Poland and Western Ukraine) Annales Societatis Geologorum Poloniae 81 221239.Google Scholar
Clauer, N. Środoń, J. Franců, J. and Šucha, V., 1997 K-Ar dating of illite fundamental particles separated from illite-smectite Clay Minerals 32 181196.CrossRefGoogle Scholar
Croker, P.F., Croker, P.F. and Shannon, P.M., 1995 The Clare basin: a geological and geophysical outline The Petroleum Geology of Ireland’s Offshore London Geological Society 327339.Google Scholar
Cunningham, D., 2005 Active intracontinental transpressional mountain building in the Mongolian Altai: Defining a new class of orogen Earth and Planetary Science Letters 240 436444.CrossRefGoogle Scholar
Cunningham, D. Mann, P., Cunningham, W.D. and Mann, P., 2007 Tectonics of strike-slip restraining and releasing bends Tectonics of Strike-Slip Restraining and Releasing Bends London Geological Society 112.Google Scholar
Danisik, M. Sachsenhofer, R. Frisch, W. Privalov, V. Panova, E. and Spiegel, C., 2010 Thermotectonic evolution of the Ukrainian Donbas Foldbelt revisited: new constraints from zircon and apatite fission track data Basin Research 22 681698.CrossRefGoogle Scholar
Drits, V.A. Zviagina, B.B. McCarty, D.K. and Salyn, A.L., 2010 Factors responsible for crystal-chemical variations in the solid solutions from illite to aluminoceladonite and from glauconite to celadonite American Mineralogist 95 348361.CrossRefGoogle Scholar
Drygant, D., 1993 Conodont colour as indicator of the geological processes (Volyn-Podolia) Paleontologiceskij Zbirnyk 29 3537.Google Scholar
Drygant, D., 2010 Devonian Conodonts from South-West Margin of the East European Platform (Volyn’-Podolian, Ukraine) Kyiv Academperiodyka.Google Scholar
Drygant, D., 2011 Remarks on the geology of the Carpathian Foredeep basement Geology and Geochemistry of Combustible Minerals 3–4 139155.Google Scholar
Dudek, T. and Środoń, J., 1996 Identification of illite/smectite by X-ray powder diffraction taking into account the lognormal distribution of crystal thickness Geologica Carpathica–Series Clays 5 2132.Google Scholar
Dumitru, T.A., 1993 A new computer automated microscope stage system for fission-track analysis Nuclear Tracks and Radiation Measurements 21 575580.CrossRefGoogle Scholar
Dunkl, I., 2002 TRACKKEY: A Windows program for calculation and graphical presentation of fission track data Computer Geoscience 28 312.CrossRefGoogle Scholar
Epstein, A.G. Epstein, J.B. and Harris, L.D., 1977 Conodont Color Alteration — an Index to Organic Metamorphism.CrossRefGoogle Scholar
Franců, J. Muller, P. Sucha, V. and Zatkalikova, V., 1990 Organic matter and clay minerals as indicators of thermal history in the Transcarpathian Depression (East Slovakian Neogene Basin) and the Vienna Basin Geologica Carpathica 41 535546.Google Scholar
Galbraith, R.F., 1981 On statistical models for fission track counts Mathematical Geology 13 471–438.Google Scholar
Galbraith, R.F., 1990 The radial plot; graphical assessment of spread in ages Nuclear Tracks and Radiation Measurements 17 207214.CrossRefGoogle Scholar
Galbraith, R.F. and Laslett, G.M., 1993 Statistical models for mixed fission track ages Nuclear Tracks and Radiation Measurements 21 459470.CrossRefGoogle Scholar
Gallagher, K. Brown, R. and Johnson, C., 1998 Fission track analysis and its applications to geological problems Annual Review of Earth & Planetary Sciences 26 519–72.CrossRefGoogle Scholar
Garetsky, R.G. Zinovenko, G.V. Vishnyakov, I.B., Garetsky, R.G., 1981 Baltic-Dnestrian System of the Pericratonic Depressions Geology of the Western Part of the East European Platform 4461.Google Scholar
Gorokhov, I.M. Yakovleva, O.V. Semikhatov, M.A. Mel’nikov, N.N. Ivanovskaya, T.A. and Kutyavin, E.P., 1997 “Rejuvenated” Al-glauconite in Vendian-Cambrian deposits of Podolian Dniester region, Ukraine: Rb-Sr and K-Ar systematics and 57Fe Moessbauer spectra Lithology and Mineral Resources 32 541558.Google Scholar
Green, P.F., 1981 ‘Track-in track’ length measurements in annealed apatites Nuclear Tracks 5 1218.CrossRefGoogle Scholar
Green, P.F. Duddy, I.R. Laslett, G.M. Hegarty, K.A. Gleadow, A.J.W. and Lovering, J.F., 1989 Thermal annealing of fission tracks in apatite 4. Quantitative modelling techniques and extention to geological time-scales Chemical Geology (Isotope Geoscience Section) 79 155182.CrossRefGoogle Scholar
Grocholski, A. and Ryka, W., 1995 Carboniferous magmatism of Poland The Carboniferous System in Poland 148 181190.Google Scholar
Huff, W.D. Bergström, S.M. and Kolata, D.R., 2000 Silurian K-bentonites of the Dnestr Basin, Podolia, Ukraine Journal of the Geological Society London 157 493504.CrossRefGoogle Scholar
Hunziker, J.C. Frey, M. Clauer, N. Dallmeyer, R.D. Friedrichsen, H. Flehmig, W. Hochstrasser, K. Roggwiler, P. and Schwander, H., 1986 The evolution of illite to muscovite: mineralogical and isotopic data from the Glarus Alps, Switzerland Contributions to Mineralogy and Petrology 92 157180.CrossRefGoogle Scholar
Jackson, M.L., 1975.Soil Chemical Analysis — Advanced CourseGoogle Scholar
Jaworowski, K., 2002 Geotectonic significance of Carboniferous deposits NW of the Holy Cross Mts. (central Poland) Geological Quarterly 46 267280.Google Scholar
Jelenska, M. Bakhmutov, V. and Konstantinienko, L., 2005 Paleomagnetic and rock magnetic data from the Silurian succession of the Dniester basin, Ukraine Physics of the Earth and Planetary Interiors 149 307320.CrossRefGoogle Scholar
Karnkowski, P.H., 2003 Carboniferous time in the evolution of the Lublin Basin as the main hydrocarbon formation stage in the Lublin area — results of the geological modelling (PetroMod) Przegląd Geologiczny 51 783790.Google Scholar
Ketcham, RA D RA and Donelick, M.B., 2000 AFTSolve: A program for multi-kinetic modeling of apatite fission-track data Geological Material Research 2 132.Google Scholar
Kipli, T. Tsegelnjuk, P.D. and Kollaste, T., 2000 Volcanic interbeds in the Silurian of the southwestern part of the East European Platform Proceedings Estonian Academy of Sciences, Geology 49 163176.Google Scholar
Kornpihl, K., 2005 Tectono-sedimentary evolution of the NE German Variscan foreland basin Germany University of Bonn.Google Scholar
Kowalska, S., 2008 Border of diagenesis and anchimetamorphism in Upper Proterozoic and Cambrian rocks of E part of Małopolska block established by clay mineral studies Kraków, Poland Institute of Geological Sciences PAN.Google Scholar
Kozłowska, A., 2002 Upper Carboniferous sandstone diagenesis in NW part of the Lublin trough Warsaw Polish Geological Institute.Google Scholar
Kozłowska, A., 2011 Clay minerals in the Carboniferous sandstones of the southeastern part of the Lublin basin as paleotemperature indicators of diagenesis Biuletyn Państwowego Instytutu Geologicznego 444 99112.Google Scholar
Krzywiec, P., 2009 Devonian-Cretaceous repeated subsidence and uplift along the Tornquist-Teisseyre Zone in SE Poland ù insight from seismic data interpretation Tectonophysics 142159.CrossRefGoogle Scholar
Kübler, B., 1964 Le argiles, indicateurs de metamorphisme Revue de l’Institut Francais du Petrole 19 10931112.Google Scholar
Lindgreen, H. Drits, V.A. Sakharov, B.A. Salyn, A.L. Wrang, P. and Dainyak, L.G., 2000 Illite-smectite structural changes during metamorphism in black Cambrian Alum shales from the Baltic area American Mineralogist 85 12231238.CrossRefGoogle Scholar
Majorowicz, J. Marek, S. and Znosko, J., 1984 Paleogeothermal gradients by vitrinite reflectance data and their relation to the present geothermal gradient patterns of the Polish Lowland Tectonophysics 103 141156.CrossRefGoogle Scholar
Majorowicz, J.A. Čermak, V. Šafanda, J. Krzywiec, P. Wróblewska, M. Guterch, A. and Grad, M., 2003 Heat flow models across the Trans-European Suture Zone in the area of the POLONAISE’97 seismic experiment Physics and Chemistry of the Earth 28 375391.CrossRefGoogle Scholar
Małkowski, K. Racki, G. Drygant, D. and Szaniawski, H., 2009 Carbon isotope stratigraphy across the Silurian–Devonian transition in Podolia, Ukraine: evidence for a global biogeochemical perturbation Geological Magazine 146 674689.CrossRefGoogle Scholar
McCarty, D.K. Drits, V.A. and Sakharov, B., 2006 Relationship between composition and lattice parameters of some sedimentary dolomite varieties European Journal of Mineralogy 18 611627.CrossRefGoogle Scholar
Moore, D.M. and Reynolds, R.C., 1997 X-ray Diffraction and the Identification and Analysis of Clay Minerals Oxford-New York Oxford University Press.Google Scholar
Morton, J.P. and Long, L.E., 1984 Rb-Sr ages of glauconite recrystallization: dating times of regional emergence above sea level Journal of Sedimentary Petrology 54 495506.Google Scholar
Muszyński, A. Biernacka, J. Lorenc, S. Protas, A. Urbanek, Z. and Wojewoda, J., 1996 Petrology and a depositional environment of Lower Carboniferous rocks near Dygowo and Kłanino (the Koszalin-Chojnice zone) Geologos 1 93126.Google Scholar
Mystkowski, K. Środoń, J. and McCarty, D.K., 2002 Application of evolutionary programming to automatic XRD quantitative analysis of clay-bearing rocks Abstracts with Programs 134.Google Scholar
Naeser, C.W., 1981 The fading of fission tracks in the geologic environment — data from deep drill holes Nuclear Tracks 5 248250.CrossRefGoogle Scholar
Nawrocki, J. and Poprawa, P., 2006 Development of Trans-European Suture Zone in Poland: from Ediacaran rifting to Early Palaeozoic accretion Geological Quarterly 50 5976.Google Scholar
Nehring-Lefeld, M. Modlinski, Z. and Swadowska, E., 1997 Thermal evolution of the Ordovician in the western margin of the East-European Platform: CAI and Ro data Geological Quarterly 41 129138.Google Scholar
Nikishin, A.M. Ziegler, P.A. Stephenson, R.A. Cloetingh, SAPL Furne, A.V. Fokin, P.A. Ershov, A.V. Bolotov, S.N. Korotaev, M.V. Alekseev, A.S. Gorbachev, V.I. Shipilov, E.V. Lankreijer, A. Bembinova, E.Y.u. and Shlimov, I.V., 1996 Late Precambrian to Triassic history of the East European Craton: dynamics of sedimentary basin evolution Tectonophysics 268 2363.CrossRefGoogle Scholar
Nowak, J., 1938 Dniestr a gipsy tortonskie Rocznik Polskiego Towarzystwa Geologicznego 14 155194.Google Scholar
Paszkowski, M. and Kusiak, M., 2005 Geotectonic aspects of detritus provenance in some Paleozoic epiplatform basins of Poland and adjacent countries 2005 Report of the Institute of Geological Sciences PAS 1112.Google Scholar
Poprawa, P., 2010 Shale gas potential of the Lower Palaeozoic complex in the Baltic and Lublin-Podlasie basins (Poland) Przeglad Geologiczny 58 226249.Google Scholar
Poprawa, P. and Zywiecki, M., 2005 Heat transfer during development of the Lublin basin (SE Poland): maturity modelling and fluid inclusion analysis Mineralogical Society of Poland — Special Papers 26 241250.Google Scholar
Poprawa, P. Kossakowski, P. and Wróbel, M., 2010 Burial and thermal history of the Polish part of the Baltic region Geological Quarterly 54 131142.Google Scholar
Pozaryski, W. and Dembowski, Z., 1983 Geological Map of Poland and Adjoining Countries 1:1000000 Warsaw Geological Institute.Google Scholar
Reznikov, A.I., 1978 Geological position and general features of flyshoid mass of the middle part of the Donbass Geologicheskij Zhurnal 38 6472.Google Scholar
Sachsenhofer, R.F. and Koltun, Y.V., 2012 Black shales in Ukraine — A review Marine and Petroleum Geology 31 125136.CrossRefGoogle Scholar
Seifert, F., 1968 X-ray powder data for Mg-Al-celadonite (leucophyllite) from Barcza, Poland Contributions to Mineralogy and Petrology 19 9396.CrossRefGoogle Scholar
Shulga, V.F. Zdanowski, A. and Zajceva, L.B., 2007 Correlation of Carboniferous Coal-bearing Formations of the L’viv-Volyn and Lublin Basins Kiev National Academy of Sciences of Ukraine and Polish State Geological Institute.Google Scholar
Skompski, S. Łuczyński, P. Drygant, D. and Kozłowski, W., 2008 High-energy sedimentary events in lagoonal successions of Upper Silurian of Podolia, Ukraine Facies 54 277296.CrossRefGoogle Scholar
Sliaupa, S. Fokin, P. Lazauskiene, J. Stephenson, R.A., Gee, D.G. and Stephenson, R.A., 2006 The Vendian–Early Palaeozoic sedimentary basins of the East European Craton European Lithosphere Dynamics London Geological Society 449462.Google Scholar
Srodon, J. (1976) Mixed-layer smectite/illites in the bentonites and tonsteins of the Upper Silesian Coal Basin. Prace Mineralogiczne, 49, 84 pp.Google Scholar
Środoń, J., 1984 X-ray powder diffraction identification of illitic materials Clays and Clay Minerals 32 337349.CrossRefGoogle Scholar
Środoń, J., 2007 Illitization of smectite and history of sedimentary basins Proceedings of the 11th EUROCLAY Conference 7482.Google Scholar
Środoń, J. and Clauer, N., 2001 Diagenetic history of Lower Paleozoic sediments in Pomerania (northern Poland) traced across the Teisseyre-Tornquist tectonic zone using mixed-layer illite-smectite Clay Minerals 36 1527.CrossRefGoogle Scholar
Środoń, J. and Paszkowski, M., 2011 Role of clays in diagenetic history of boron and nitrogen in the Carboniferous of Donbas (Ukraine) Clay Minerals 46 561582.CrossRefGoogle Scholar
Środoń, J. Drits, V.A. McCarty, D.K. Hsieh, J.C.C. and Eberl, D.D., 2001 Quantitative XRD analysis of clay-rich rocks from random preparations Clays and Clay Minerals 49 514528.CrossRefGoogle Scholar
Środoń, J. Clauer, N. and Eberl, D.D., 2002 Interpretation of K-Ar dates of illitic clays from sedimentary rocks aided by modeling American Mineralogist 87 15281535.CrossRefGoogle Scholar
Środoń, J. Kotarba, M. Biroň, A. Šucha, P. Clauer, N. and Wójtowicz, A., 2006 Diagenetic history of the Podhale-Orava basin and the underlying Tatra sedimentary structural units (Western Carpathians): evidence from XRD and K-Ar of illite-smectite Clay Minerals 41 747770.CrossRefGoogle Scholar
Środoń, J. Clauer, N. Banaś, M. and Wójtowicz, A., 2006 K-Ar evidence for a Mesozoic thermal event superimposed on burial diagenesis of the Upper Silesia Coal Basin Clay Minerals 41 671692.CrossRefGoogle Scholar
Środoń, J. Clauer, N. Huff, W. Dudek, T. and Banas, M., 2009 K-Ar dating of Ordovician bentonites from the Baltic Basin and the Baltic Shield: implications for the role of temperature and time in the illitization of smectite Clay Minerals 44 361387.CrossRefGoogle Scholar
Środoń, J. Zeelmaekers, E. and Derkowski, A., 2009 The charge of component layers of illite-smectite in bentonites and the nature of end-member illite Clays and Clay Minerals 57 650672.CrossRefGoogle Scholar
Šucha, V. Kraus, I. Gerthofferova, H. Petes, J. and Serekova, M., 1993 Smectite to illite conversion in bentonites and shales of the East Slovak Basin Clay Minerals 28 243253.CrossRefGoogle Scholar
Suggate, R.P., 1998 Relations between depth of burial, vitrinite reflectance and geothermal gradient Journal of Petroleum Geology 21 532.CrossRefGoogle Scholar
Świdrowska, J. Hakenberg, M. Poluhtoviè, B. Seghedi, A. and Višnâkov, I., 2008 Evolution of the Mesozoic basins on the southwestern edge of the East European Craton (Poland, Ukraine, Moldova, Romania) Studia Geologica Polonica 130 3130.Google Scholar
Tsegelnjuk, P.D., 1980 Rukshin and Tsygan series (Lower–Upper Silurian) of Podolia and Volynia Kiev Inst. Geol. Nauk.Google Scholar
Tsegelnjuk, P.D., 1980 Yaruga andMalinovtsy series (Upper Silurian–Lower Devonian) of Podolia and Volynia Kiev Inst. Geol. Nauk.Google Scholar
Ulmishek, G., 1990 Geologic evolution and petroleum resources of the Baltic Basin American Association of Petroleum Geologists Memoir 51 603632.Google Scholar
Vishnjakov, I.B. Glushko, V.V. Pomjanovskaja, G.M., Garetsky, R.G., 1981 The South-Western Border of the East-European Platform in the Ukraine and Moldavia. Baltic-Dnestrian System of the Pericratonic Depressions Geology of the Western Part of the East-European Platform Minsk Nauka i Tekhnika 2235.Google Scholar
Warr, L.N. and Hecht, C.A., 1993 A clay mineral crystallinity investigation of the Upper Carboniferous Culm Basin of south-west England Proceedings of the Ussher Society 8 9498.Google Scholar
Whitney, G. and Northop, H.R., 1987 Diagenesis and fluid flow in the San Juan Basin, New Mexico — regional zonation in the mineralogy and stable isotope composition of clay minerals in sandstone American Journal of Science 287 253282.CrossRefGoogle Scholar
Wiewiora, A. and Wilamowski, A., 1996 The relationship between composition and b for chlorite Geologica Carpathica — Series Clays 5 7987.Google Scholar
Znosko, J., 1970 Tectonic position of Poland in Europe Biuletyn Instytutu Geologicznego 251 4570.Google Scholar