Abstract
Thermal maturity information has been compiled for one of the deepest parts of the Central European Basin system, the Schleswig-Holstein area in northern Germany. New vitrinite reflectance data were obtained and old data were evaluated from a total of 31 wells. Furthermore, numerical 1D basin modelling was performed in order to interpolate/extrapolate vitrinite reflectance data to base Zechstein and base Keuper. For these two horizons, maturity maps were finally compiled revealing large differences in present-day thermal maturity within the basin. For example, vitrinite reflectance at base Zechstein ranges from greater than 4.5% in the Glueckstadt Graben to less than 1% in the northern part of the study area. Highest thermal maturity of base Keuper occurs in the West Holstein Trough and in the northern part of the Glueckstadt Graben. The timing of maturation is greatly affected by the complex tectonic evolution of the area. For six key wells distributed over the entire study area, burial and temperature histories as well as evolution of maturity were evaluated using 1D basin modelling. Deepest burial and maximum temperatures occurred either during Jurassic, Upper Cretaceous or Neogene times in these wells. Only some parts of the sedimentary package in Schleswig-Holstein show a significant increase in maturity during the Tertiary leading to additional hydrocarbon generation and entrapment.
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References
Allen PA, Allen JR (1990) Basin analysis: principles and applications. Oxford
Bachmann GH, Grosse S (1989) Struktur und Entstehung des Norddeutschen Beckens—geologische und geophysikalische Interpretation einer verbesserten Bouguer-Schwerekarte. In: Dohr G (ed) Das Norddeutsche Becken. Nds Akad Geowiss Veröff 2:23–47
Baldschuhn R, Binot F, Fleig S, Kockel F (2001) Geotektonischer Atlas von Nordwest-Deutschland und dem deutschen Nordsee-Sektor—Strukturen, Strukturentwicklung, Paläogeographie. Geol Jahrb A153:3–95
Best G, Kockel F, Schoeneich H (1983) Geological history of the southern Horn graben. Geologie en Mijnbouw 62:25–33
Bethke CM (1989) Modeling subsurface flow in sedimentary basins. Geol Rundschau 78:129–154
Brink HJ, Dürschner H, Trappe H. (1992) Some aspects of the late and post-Variscian development of the Northwestern German Basin. Tectonophysics 207:65–95
Coward MP (1995) Structural and tectonic setting of the Permo-Triassic basins of northwest Europe. In: Boldy SAR (ed) Permian and Triassic rifting in Northwest Europe. Geological Society Special Publication No. 91:7–39
Franke W (1992) Tectonic evolution of Europe; Phanerozoic structures and events in Central Europe. In: Blundell D, Freeman R, Mueller, Stephan (eds) A continent revealed; the European geotraverse, Cambridge, pp 164–180
Franke D (1995) The North Variscan Foreland. In: Dallmeyer RD, Franke W, Weber K (eds) Pre-Permian geology of Central and Eastern Europe, pp 554–566
Friberg L (2001) Untersuchungen zur Temperatur- und Absenkungsgeschichte sowie zur Bildung und Migration von Methan und molekularem Stickstoff im Norddeutschen Becken. Berichte des Forschungszentrums Jülich 3914
Gemmer L, Nielsen SB, Huuse M, Lykke-Anderson H (2002) Post-mid-Cretaceous eastern North Sea evolution inferred from 3D thermo-mechanical modelling. Tectonophysics 350:315–342
Gerling P, Kockel F, Krull, P (1999) Das Kohlenwasserstoff-Potential des Präwestfals im norddeutschen Becken—Eine Synthese. DGMK-Forschungsbericht 433; Hamburg
Glennie KW (1999) Exploration activities in the Netherlands and North-West Europe since Groningen. Geol Mijnbouw 80:33–52
Grassmann S, Cramer B, Delisle G, Messner J, Winsemann J (2005) Influence of salt dynamics on the petroleum system of the Mittelplate oil field (this volume)
Haenel R (1980) The subsurface temperature atlas of the European communities—EOS, Transactions, American Geophysical Union 62/17:226
Horsfield B, Bharati S, Larter SR, Leistner F, Littke R, Schenk HJ, Dypvik H (1992) On the atypical petroleum-generation characteristics of alginite in the Cambrian Alum Shale. In: Schidlowski M (ed) Early organic evolution: implications for mineral and energy resources. Springer, Berlin, pp 257–266
Jaritz W (1980) Einige Aspekte der Entwicklungsgeschichte der nordwestdeutschen Salzstöcke. Zeitschr Dt Geol Gesellschaft 131:307–408
Koch J, Kockel F, Krull P (1997) Coalification at the Base of the Zechstein and the pre-Permian Surface in Northern Germany. Geol Jb D103:33–42
Kockel F (1995) Structural and palaeogeographical development of the German North Sea sector. Beiträge zur regionalen Geologie der Erde, 26; Stuttgart
Kockel F (2002) Rifting processes in NW-Germany and the German North Sea Sector. Geologie en Mijnbouw 81:149–158
Leischner K (1994) Kalibration simulierter Temperaturgeschichten von Gesteinen mit organischen Reifeparametern und anorganischen Temperaturindikatoren. Berichte der Kernforschungsanlage Jülich 2909
Littke R, Sachsenhofer RF, Hantschel T, Wygrala B (1993) Absenkungsgeschichte und Kohlenwasserstoffbildung im Oberkarbon des westlichen Emslandes—Eine Simulationsstudie. DGMK Forschungsberichte, 459–462; Hamburg
Littke R, Krooss BM, Idiz E, Frielingsdorf J (1995) Molecular nitrogen in natural gas accumulations: generation from sedimentary organic matter at high temperatures. Amer Assoc Petr Geol Bull 79:410–430
Lokhorst A (ed) (1998) Northwest European gas atlas—composition and isotope ratios of natural gases. Netherlands Inst. Applied Geoscience TNO—National Geological Survey, Harlem, The Netherlands, ISBN 90-72869-60-5
Lopatin NV (1971) Temperature and geologic time as factors in coalification—Akad. Nauk. SSSR Izv. Ser. Geol. 3:95–106; Moskva
Magri F, Bayer U, Jahnke C (2005) Deep-reaching fluid flow in the NE-German Basin, part 1: Fluid dynamics driving saline waters (this volume)
Maystrenko Y, Bayer U, Scheck-Wenderoth M (2005) The Glueckstadt Graben, a sedimentary record between the North and Baltic Sea in north Central Europe. Tectonophysics, in press
McCartney JT, Teichmüller R (1972) Classification of coals according to the degree of coalification by the reflectance of vitrinite components. Fuel 51:64–68
McKenzie DP (1978) Some remarks on the development of sedimentary basins. Earth Planet Sci Letters 40:25–32
Menning M (1995) A numerical time scale for the Permian and Triassic period. In: Scholle P, Peryt TM, Ulmer-Scholle DS (eds) Permian of the northern continents, vol. 1, Springer, Berlin, pp 77–79
Neunzert GH, Gaupp R, Littke R (1996) Absenkungs- und Temperaturgeschichte paläozoischer und mesozoischer Formationen im Norddeutschen Becken. Z dt geol Ges 147/2:183–208
Petmecky S, Meier L, Reiser H, Littke R (1999) High thermal maturity in the Lower Saxony Basin: intrusion or deep burial? Tectonophysics 304:317–344
Poelchau HS, Baker DR, Hantschel T, Horsfield B, Wygrala B (1997) Basin simulation and the design of the conceptual basin model. In: Welte DH, Horsfield B, Baker DR (eds) Petroleum and basin evolution. Springer Verlag, Berlin, p 535
Sachsenhofer RF, Littke R (1993) Vergleich und Bewertung verschiedener Methoden zur Berechnung der Vitrinitreflexion am Beispiel von Bohrungen im Steirischen Tertiärbecken. Zbl Geol Paläont Teil I 1992:597–610
Scheck M, Bayer U (1999) Evolution of the Northeast German Basin: inferences from a 3D structural model and subsidence analysis. Tectonophysics 313:145–169
Sweeney JJ, Burnham AK (1990) Evaluation of a simple model of vitrinite reflectance based on chemical kinetics. AAPG Bulletin 74/10:1559–1570
Taylor GH, Teichmüller M, Davis A, Diessel CFK, Littke R, Robert P (1998) Organic Petrology; Stuttgart, p 704
Teichmüller G, Teichmüller M, Bartenstein H (1984) Inkohlung und Erdgas—eine neue Inkohlungskarte der Karbon-Oberfläche in Nordwestdeutschland. Fortschr Geol Rheinld u Westf 32:11–34
Van Balen RT, van Bergen F, de Leeuw C, Pagnier H, Simmelink H, van Wees JD, Verweij JM (2000) Modeling the hydrocarbon generation and migration in the West Netherlands Basin, The Netherlands. Geol Mijnbouw/ Netherl Journ Geosc 79:29–44
Waples DW (1980) Time and temperature in petroleum formation: application of Lopatin’s method to petroleum exploration. AAPG Bull 64:916–926
Welte DH, Horsfield B, Baker DR (eds) (1997) Petroleum and Basin Evolution. Springer Verlag, Berlin, p 535
Welte DH, Yalcin MN (1987) Basin Modelling—a new comprehensive method in petroleum geology. Org Geochem 13:141–151
Welte DH, Yükler MA (1981) Petroleum Origin and Accumulation in Basin Evolution – a quantitative Model. AAPG Bulletin 65:1387–1396
Wygrala BP (1989) Integrated study of an oil field in the southern Po basin, northern Italy. Berichte Kernforschungsanlage Jülich 2313:p. 217
Ziegler PA (1990) Geological Atlas of Western and Central Europe. 2nd edn, Shell International Petroleum Maatschappij B.V.; Den Haag
Acknowledgements
This work was conducted and funded under the umbrella of the DFG (German Research Foundation) priority programme 1135 “Dynamics of sedimentary systems under varying stress regimes: the example of the Central European basin system” (grant no. Li 618/14). Vitrinite reflectance data and additional information were made available by the German petroleum industry coordinated by DGMK (German Society for Petroleum and Coal Science and Technology) and by BGR, Hannover. We would like to express our gratitude to all these organisations. In particular, we wish to thank Andreas Szabados (RWE Dea), Werner Hiltmann (BGR) and Ingrid Winter (DGMK). Walter Pickel and Rolando di Primio are thanked for their helpful reviews and suggestions.
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Rodon, S., Littke, R. Thermal maturity in the Central European Basin system (Schleswig-Holstein area): results of 1D basin modelling and new maturity maps. Int J Earth Sci (Geol Rundsch) 94, 815–833 (2005). https://doi.org/10.1007/s00531-005-0006-1
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DOI: https://doi.org/10.1007/s00531-005-0006-1