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Sand- and mud-filled fluvial palaeochannels in the Wielkopolska Member of Neogene Poznań Formation, central Poland

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This study focuses on the single- and multi-storey fluvial palaeochannel lithosomes encased in mud- rich floodplain deposits in the alluvial succession of the late Neogene Wielkopolska Member of the Poznań For- mation, central Poland, well-exposed in the lignite mining pits of the region. The fluvial lithosomes include both sand-filled and mud-filled channel varieties. The channel-fill facies are not diagnostic for any particular type of fluvial system, as the fine- to very fine-grained sandy deposits are massive to trough cross-stratified and also the muddy deposits are massive to weakly flat-laminated. The scarcity of lateral accretion bedding precludes the possibility of meandering rivers, whereas the low width/thickness ratios of the palaeochannels preclude braided rivers. The width/thickness ratio is in the range of 4.5–14 (averaging 7.5) for sand-filled channels and in the range of 6–10 (averaging 9) for mud-filled ones, which indicates narrow ribbons in general classification of fluvial channel belts. The origin of the alluvial succession is attributed to a W-/NW-directed anastomosing river system characterized by laterally inactive cut-and-fill channels with cohesive and vegetated banks. The sand-filled chan- nels conveyed water and sediment discharges on a perennial basis, whereas the mud-filled conduits are thought to have been the cut-and-abandoned branches of the system, filled by overbank flooding from adjacent active channels. Minor lateral migration of channels occurred probably during periods of minimum subsidence rate, when the fluvial system was forced to develop lateral accommodation for its discharges.
Rocznik
Strony
19--28
Opis fizyczny
Bibliogr. 77 poz., rys., tab.
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autor
  • Institute of Geology, Adam Mickiewicz University, Maków Polnych 16, 61-606 Poznań, Poland
Bibliografia
  • 1. Allen, J. R. L., 1965. A review of the origin and characteristics of recent alluvial sediments. Sedimentology, 5: 89-191.
  • 2. Allen, J. R. L., 1978. Studies in fluviatile sedimentation: an exploratory quantitative model for the architecture of avulsion- controlled alluvial suites. Sedimentary Geology, 21: 129-147.
  • 3. Areń, B., 1957. Geological Atlas of Poland: Stratigraphic and Facies Problems. Tertiary, 11/5. Wydawnictwa Geologiczne, Warszawa. [In Polish, with English summary].
  • 4. Areń, B., 1964. Geological Atlas of Poland: Stratigraphic and Facies Problems. Tertiary, 11/a. Wydawnictwa Geologiczne, Warszawa. [In Polish, with English summary].
  • 5. Badura, J. & Przybylski, B., 2004. Evolution of the Late Neogene and Eopleistocene fluvial system in the foreland of the Sudetes Mountains, SW Poland. Annales Societatis Geologorum Poloniae, 74: 43-61.
  • 6. Baas, J. H. & Best, J. L., 2002. Turbulence modulation in clay-rich sediment-laden flows and some implications for sediment deposition. Journal of Sedimentary Research, 72: 336-340.
  • 7. Baas, J. H., Best, J. L., Peakall, J. & Wang, M., 2009. A phase diagram for turbulent, transitional, and laminar clay suspension flows. Journal of Sedimentary Research, 79: 162-183.
  • 8. Bridge, J. S., 2003. Rivers andFloodplains: Forms, Processes, and Sedimentary Record. Blackwell Publishing, Malden, 491 pp.
  • 9. Bridge, J. S., Jalfin, G. A. & Georgieff, S. M., 2000. Geometry, lithofacies, and spatial distribution of Cretaceous fluvial sandstone bodies, San Jorge Basin, Argentina: outcrop analog for the hydrocarbon-bearing Chubut Group. Journal of Sedimentary Research, 70: 341-359.
  • 10. Bridge, J. S. & Leeder, M. R., 1979. A simulation model of alluvial stratigraphy. Sedimentology, 26: 617-644.
  • 11. Ciuk, E., 1970. Schemes of the Tertiary from the Polish Lowland area. Kwartalnik Geologiczny, 14: 754-771. [In Polish, with English summary].
  • 12. Ciuk, E. & Pożaryska, K., 1982. On paleogeography of the Tertiary of the Polish Lowland. Prace Muzeum Ziemi, 35: 81-88.
  • 13. Collinson, J. D. & Thompson, D. B. 1982. Sedimentary Structures. Allen and Unwin, London, 207 pp.
  • 14. Czapowski, G. & Kasiński, J. R., 2002. Facje i warunki depozycji utworów formacji poznańskiej. Przegląd Geologiczny, 50: 256-257. [In Polish].
  • 15. Davies-Vollum, K. S. & Kraus, M. J., 2001. A relationship between alluvial backswamps and avulsion cycles: an example from the Willwood Formation of the Bighorn Basin, Wyotming. Sedimentary Geology, 140: 235-245.
  • 16. Doktor, M., 2007. Conditions of accumulation and sedimentary architecture of the upper Westphalian Cracow Sandstone Series (Upper Silesia Coal Basin, Poland). Annales Societatis Geologorum Poloniae, 77: 219-268.
  • 17. Duczmal-Czernikiewicz, A., 2010. Geochemistry and mineralogy of the Poznań Formation (Polish Lowlands). Adam Mickiewicz University Press, Poznań, 88 pp.
  • 18. Duczmal-Czernikiewicz, A., 2011. Microfabric of the Poznań clays in microscopic studies as the indication of the polygenetic origin of sediments. Biuletyn Państwowego Instytutu Geologicznego, 444: 47-54. [In Polish, with English summary].
  • 19. Dyjor, S., 1968. Marine horizons within Poznań clays. Kwartalnik Geologiczny, 12: 941-955. [In Polish, with English summary].
  • 20. Dyjor, S., 1970. The Poznań Series in West Poland. Kwartalnik Geologiczny, 14: 819-835. [In Polish, with English summary].
  • 21. Eberth, D. A. & Miall, A. D., 1991. Stratigraphy, sedimentology and evolution of a vertebrate-bearing, braided to anastomosing fluvial system, Cutler Formation (Permian-Pennsylvanian), north- central New Mexico. Sedimentary Geology, 72: 225-252.
  • 22. Friend, P. F., 1983. Towards the field classification of alluvial architecture or sequence. In: Collinson, J. & Lewin, J. (eds), Modern and Ancient Fluvial Systems. Special Publication of the International Association of Sedimentologists, 6: 345¬354. Blackwell, Oxford.
  • 23. Friend, P. F., Slater, M. J. & Williams, R. C., 1979. Vertical and lateral building of river sandstone bodies, Ebro Basin, Spain. Geological Society of London Journal, 136: 39-46.
  • 24. Gibling, M. R., 2006. Width and thickness of fluvial channel bodies and valley fills in the geological record: a literature compilation and classification. Journal of Sedimentary Research, 76: 731-770.
  • 25. Gibling, M. R., Nanson, G. C. & Maroulis, J. C., 1998. Anastomosing river sedimentation in the Channel Country of central Australia. Sedimentology, 45: 595-619.
  • 26. Gibling, M. R. & Rust, B. R., 1990. Ribbon sandstones in the Pennsylvanian Waddens Cove Formation, Sydney Basin, Atlantic Canada: the influence of siticeous duricrusts on channel-body geometry. Sedimentology, 37: 45-66.
  • 27. Gonzalez-Bonorino, G., Colombo, F. & Abascal, L., 2010. Architecture of an Oligocene fluvial ribbon sandstone in the Ebro Basin, North-eastern Spain. Sedimentology, 57: 845-856.
  • 28. Gouw, M. J. P., 2007. Alluvial architecture of fluviodeltaic success ions: a review with special reference to Hol ocene settings. In: Middelkoop, H., Stouthamer, E. & Hoek, W. Z. (eds), Geomorphology and Climate. Netherlands Journal of Geosciences/Geologie en Mijnbouw, 86: 211-227.
  • 29. Górniak, K., Szydlak, T., Sikora, W.S., Gaweł, A., Bahranowski, K. & Ratajczak T., 2001. Clay minerals in colourful rocks appearing over lignite deposits in Konin region. Górnictwo Odkrywkowe, 43: 129-139. [In Polish, with English summary].
  • 30. Gradziński, R., Doktor, M. & Słomka, T., 1995. Depositional environments of the coal-bearing Cracow Sandstone Series (upper Westphalian), Upper Silesia, Potand. Studia Geologica Polonica, 108: 149-170.
  • 31. Gradziński, R., Baryła, J., Danowski, W., Doktor, M., Gmur, D., Gradziński, M., Kędzior, A., Paszkowski, M., Soja, R., Zieliński, T. & Żurek, S., 2000. Anastomosing system of the upper Narew River, NE Poland. Annales Societatis Geologorum Poloniae, 70: 219-229.
  • 32. Gradziński, R., Baryła, J., Doktor, M., Gmur, D., Gradziński, M., Kędzior, A., Paszkowski, M., Soja, R., Zieliński, T. & Żurek, S., 2003. Vegetation-controlled modern anastomosing system of the upper Narew River (NE Poland) and its sediments. Sedimentary Geology, 157: 253-276.
  • 33. Gross, M., Piller, W. E., Ramos, M. I. & Paz, J. D. S., 2011. Late Miocene sedimentary environments in south-western Amazonia (Solimoes Formation; Brazil). Journal of South American Earth Science, 32: 169-181.
  • 34. Gruszka, B. & Zieliński, T., 2008. Evidence for a very low-energy fluvial system: a case study from the dinosaur-bearing Upper Triassic rocks of southern Poland. Geological Quarterly, 52: 239-252.
  • 35. Harwood, K. & Brown, A. G., 1993. Fluvial processes in a forested anastomosing river: flood parlitioning and changing flow pattterns. Earth Surfaces Processes and Landforms, 18: 741-748.
  • 36. Horne, J. C., Ferm, J. C., Caruccio, F. T. & Baganz, B. P., 1978. Depositional models in coal exploration and mine planning in Appalachian region. American Association of Petroleum Geologists Bulletin, 62: 2379-2411.
  • 37. Kasiński, J. R., 2000. Geological atlas of Tertiary lignite-bearing association in the Polish part of the Zittau Basin, scale 1:50,000. Państwowy Instytut Geologiczny, Warszawa. [In Polish, with English summary].
  • 38. Kraus, M. J., 1996. Avulsion deposlts in lower Eocene alluvial rocks, Bighorn Basin, Wyoming. Journal of Sedimentary Research, 66: 354-363.
  • 39. Kraus, M. J. & Davies-Vollum, K. S., 2004. Mudrock dominated fills formed in avulsion splay channels: examples from the Willwood Formation, Wyoming. Sedimentology, 51: 1127- 1144.
  • 40. Leeder, M. R., 1977. A quantitative stratigraphic model for alluvium, with special references to channel deposit density and interconnectedness. In: Miall. A. D. (ed.), Fluvial Sedimentology. Canadian Society of Petroleum Geologists Memoir, 5: 587-596.
  • 41. Lorenz, J. C., Heinze, D. M., Clark, J. A. & Searls, C. A., 1985. Determination of widths of meander-belt sandstone reservoirs from vertital downhole data, Mesaverde Group, Piceance Creek Basin, Colorado. American Association of Petroleum Geologists Bulletin, 69: 710-721.
  • 42. Lowe, D. R., 1988. Suspended-load fallout rate as an independent variable in the analysis of current structures. Sedimentology, 35: 765-776.
  • 43. Lundegard, P. D. & Samuels, N. D., 1980. Field classification of fine-grained sedimentary rocks. Journal of Sedimentary Petrology, 50: 781-786.
  • 44. Makaske, B., 2001. Anastomosing rivers: a review of their classification, origin and sedimentary products. Earth-Science Reviews, 53: 149-196.
  • 45. McCarthy, T. S., Stanistreet, I. G. & Cairncross, B., 1991. The sedimentary dynamics of active fluvial channels on the Okavango fan, Botswana. Sedimentology, 38: 471-487.
  • 46. Miall, A. D., 1977. A review of the braided-river depositional environment. Earth-Science Reviews, 13: 1-62.
  • 47. Miall, A. D., 1996. The Geology of Fluvial Deposits. Springer, Berlin, 582 pp.
  • 48. Mroczkowski, J., 1977. Lower Triassic sandstones in the northern part of the Intra-Sudetic Trough. Annales Societatis Geologorum Poloniae, 47: 49-72. [In Polish, with English summary].
  • 49. Mroczkowski, J. & Mader, D., 1985. Sandy inland braidplain deposition with local aeolian sedimentation in the lower and middle parts the Buntsandstein and sandy coastal braidplain deposiiion in the topmost Zechstein in the Sudetes (Lower Silesia, Poland). In: Mader, D. (ed.), Aspects of Fluvial Sedimentation in the Lower Triassic Bundsandstein of Europe. Lecture Notes in Earth Sciences, 4: 165-196. Springer Verlag, Berlin.
  • 50. Nadon, G. C., 1994. The genesis and recognition of anastomosed fluvial deposits: data from the St. Mary River Formation, south-western Alberta, Canada. Journal of Sedimentary Research, B64: 451-463.
  • 51. Nemec, W., 1984. Wałbrzych Beds (Lower Namurian, Wałbrzych Coal Basin): analysis of alluvial sedimentation in a coal basin. Geologia Sudetica, 19: 7-73. [In Polish, with Engiish summary].
  • 52. Nemec, W., 1992. Depositional controls on plant growth and peat accumulation in a braidplain delta environmernt: Helvetiafjellet Formation (Barremian-Aptian), Svalbard. In: McCabe, P. J. & Parrish, J. T. (eds), Controls on the Distribution and Quality of Cretaceous Coals. Geological Society of America Special Paper, 267: 209-226.
  • 53. Nemec, W., 2009. What is a hyperconcentrated flow? In: Lecture Abstracts, International Association of Sedimentologists Annual Meeting, Alghero, Sardinia.
  • 54. Pierson, T. C., 2005. Hyperconcentrated flow - transitional process between waier flow and debris flow. In: Jakob, M. & Hungr, O. (eds), Debris-flow Hazards and Re iated Phenomena. Springer-Verlag Praxis Books, Berlin, pp. 159-202.
  • 55. Piwocki, M., 1992. Extent and correlations of main groups of the Tertiary lignite seams on Polish platform area. Przegląd Geologiczny, 40: 281-286. [In Polish, with English summary].
  • 56. Piwocki, M., 1998. An outline of the palaeogeographic and palaeoclimatic developments. In: Ważyńska, H. (ed.), Palynology and palaeogeography of the Neogene in Poltsh Lowtands. Prace Państwowego Instytutu Geologicznego, 160: 8-12.
  • 57. Piwocki, M., Badura, J. & Przybylski, B., 2004. Neogene. In: Peryt, T. & Piwocki, M. (eds), Polish Geology 1, Stratigraphy 3a, Cenozoic-Paleogene, Neogene. Polish Geological Institute, Warszawa: 71-133. [In Polish, with English summary].
  • 58. Piwocki, M. & Ziembińska-Tworzydło, M., 1995. Lithostratigraphy and pollenspore zones in Neogene of the Polish Lowlands. Przegląd Geologiczny, 43: 916-927. [In Polish, with English summary].
  • 59. Piwocki, M. & Ziembińska-Tworzydło, M., 1997. Neogene of the Polish Lowiands lithostratigraphy and polienspore zones. Geological Quarterly, 41, 1: 21-40.
  • 60. Rust, B. R., 1978. A classification of alluvial channel systems. In: Miall, A.D. (ed.), Fluvial Sedimentology. Canadian Society of Petroleum Geologists Memoir, 5, Calgary: 187-198.
  • 61. Rust, B. R., 1981. Sedimeniaiion in an arid-zone anastomosing fluvial system: Cooper’s Creek, Central Australia. Journal of Sedimentary Petrology, 51: 745-755.
  • 62. Schumm, S. A., 1968. Specuiations concerning paleohydrologic controls of terrestrial sedimentation. Geological Society of America Bulletin,79: 1573-1588.
  • 63. Schumm, S. A., 1977. The Fluvial System. John Wiley & Sons, New York, 338 pp.
  • 64. Smith, D. G., 1983. Anastomosed fluvial deposits: modern examples from Western Canada. In: Collinson, J. & Lewin, J. (eds), Modern and Ancient Fluvial Systems. Special Publication of the International Association of Sedimentologists 6, Black¬well, Oxford: 155-168.
  • 65. Smith, D. G., 1986. Anastomosing river deposits, sedimentation rates and basin subsidence, Magdalena River, northwestern Coiomibia, South America. Sedimentary Geology, 46: 177- 196.
  • 66. Stear, W. M., 1983. Morphological characteristics of ephemeral stream channel and overbank splay sandstone bodies in the Permian Lower Beaufort Group, Karoo Basin, South Africa. In: Collinson, J. & Lewin, J. (eds), Modern and Ancient Flu¬vial Systems. Special Publication of the International Associ¬ation of Sedimentologists, 6, Blackwell, Oxford: 405-420.
  • 67. Stouthamer, E., 2001. Sedimeniary products of avulsions in the Holocene Rhine-Meuse Delta, The Netherlands. Sedimentary Geology, 145: 73-92.
  • 68. Tornqvist, T. E., Van Ree, M. H. M. & Faessen, E. L. J. H., 1993. Longitudinal facies architectural changes of a Middle Holocene anastomosing distributary system (Rhine-Meuse delta, central Netherlands). In: Fielding, C.R. (ed.), Current Research in Fluvial Sedimentology. Sedimentary Geology, 85: 203-219.
  • 69. Troć, M. & Sadowska, A., 2006. The age of Poznań Formation in the area of Poznań. Przegląd Geologiczny, 54: 588-593. [In Polish, with English summary].
  • 70. Udden, J. A., 1914. Mechanical composition of clastic sediments. Bulletin of the Geological Society of America, 25: 655-744.
  • 71. Ważyńska, H. (ed.), 1998. Palynology and palaeogeography of the Neogene in Polish Lowiands. Prace Państwowego Instytutu Geologicznego, 160, 41 pp.
  • 72. Weniworth, C. K., 1922. A scale of grade and class terms for clastic sediments. Journal of Geology, 30: 377-392.
  • 73. Widera, M., 2004. Phases of Paleogene and Neogene tectonic evolution of selected grabens in the Wielkopolska area, centralwestern Poland. Annales Societatis Geologorum Poloniae, 74: 295-310.
  • 74. Widera, M., 2007. Lithostratigraphy and palaeotectonics of the sub-Pleistocene Cenozoic of Wielkopolska. Adam Mickiewicz University Press, Poznań, 224 pp. [In Polish, with English summary].
  • 75. Widera, M., 2010. The morphology of fossil pebbles as a tool for determining their transport processes (Koźmin South lignite open-cast pit, central Poland). Annales Societatis Geologorum Poloniae, 80: 315-325.
  • 76. Widera, M., 2012. Fluvial origin of the Wielkopolska Member based on data from the ceniral Poland. Górnictwo Odkrywkowe, 53: 109-118. [In Polish, with English summary].
  • 77. Wyrwicki, R. & Wiewióra, A., 1981. Clay minerals of the Upper Miocene sediments in Poland. Bulletin Polish Academy of Science, Earth Sciences, 29: 67-71.
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