Powiadomienia systemowe
- Sesja wygasła!
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The scope of this analysis included fluvial sediments of the low terrace of the Grajcarek stream in the Małe Pieniny Mts. (Western Carpathians). The structure of the terrace has been surveyed in five profiles. The sedimentary sequence includes alternating layers of gravel and calcareous mud with a maximum thickness of up to 2.2 m. A rich and varied malacofauna has been found in the mud. The age of the sediments was determined using the radiocarbon method. The sediments that make up the terrace cover the younger part of the Middle Holocene and the entire Late Holocene. The analysis of the malacofauna has allowed for the characterization of environmental changes. The most important of them dates back to the Middle Ages and is associated with the phase of intensive settlement in the Pieniny Mts.. It is indicated by deforestation and the related change in the composition and structure of malacocoenoses manifested by the replacement of forest communities by ones with open-country species. Gravel horizons are records of flood periods correlated with wet climatic phases. It is possible to distinguish six such phases covering the following periods: 6600–6100 y cal BP, 5500–5100 y cal BP, 4500–4100 y cal BP, 3200–2300 y cal BP, 2000–900 y cal BP and 400–200 y cal BP. They correspond to the periods of increased fluvial activity of rivers, intensification of mass movements, advances of alpine glaciers and the increase in the water level in lakes.
Czasopismo
Rocznik
Tom
Strony
85--102
Opis fizyczny
Bibliogr. 79 poz., rys., tab., wykr.
Twórcy
- AGH University of Science and Technology, Faculty of Geology, Geophysics and Environment Protection, Chair of General Geology and Geotourism, Al. Mickiewicza 30, 30-059 Kraków, Poland
Bibliografia
- 1. Alexandrowicz, S.W. 1993. Late Quaternary landslides at eastern periphery of the National Park of the Pieniny Mountains, Carpathians, Poland. Studia Geologica Polonica, 192, 209–225.
- 2. Alexandrowicz, S.W. 1997a. Holocene dated landslides in the Polish Carpathians. In: Frenzel, B. (Ed.), Rapid mass movement as a source of climatic evidence for the Holocene. Palaeoclimate Research, 19, 75–83.
- 3. Alexandrowicz, S.W. and Alexandrowicz, W.P. 2011. Analiza malakologiczna. Metody badań i interpretacji. Rozprawy Wydziału Przyrodniczego PAU, 3, 5–302.
- 4. Alexandrowicz, S.W., Alexandrowicz, W.P., Krąpiec, M. and SzychowskaKrąpiec, E. 1997. Environmental changes of Southern Poland during historical period. Geologia Kwartalnik AGH, 23, 339–387. [In Polish with English summary]
- 5. Alexandrowicz, W.P., 1997b. Malacofauna of Quaternary deposits and environmental changes of the Podhale Basin during the Late Glacial and Holocene. Folia Quaternaria, 68, 7–132. [In Polish with English summary]
- 6. Alexandrowicz, W.P. 2004. Molluscan assemblages of Late Glacial and Holocene calcareous tufa in Southern Poland. Folia Quaternaria, 75: 3–309.
- 7. Alexandrowicz, W.P. 2013a. Molluscan assemblages in the deposits of landslide dammed lakes as indicators of late Holocene mass movements in the Polish Carpathians. Geomorphology, 180–181, 10–23.
- 8. Alexandrowicz, W.P. 2013b. Molluscan communities in Late Holocene fluvial deposits as an indicator of human activity: a study in Podhale Basin in Southern Poland. Ekologia Bratislava, 32, 111–125.
- 9. Alexandrowicz, W.P. 2013c. Late Glacial and Holocene molluscan assemblages in deposits filling paleolakes in Northern Poland. Studia Quaternaria, 30, 5–17.
- 10. Alexandrowicz, W.P. 2017. Malacofauna of the Holocene tufa in the Valley of the Ociemny Stream (Pieniny Mts., southern Poland). Geology, Goephysics and Environment, 43, 5–18.
- 11. Alexandrowicz, W.P. 2019a. Malacological evidence of the natural and anthropogenic changes of the environment in the eastern part of the Carpathian Foreland: the studies in the Glinne stream valley near Rzeszów (southern Poland). Carpathian Journal of Earth and Environmental Sciences, 14, 367–384.
- 12. Alexandrowicz, W.P. 2019b. Record of environmental changes and fluvial phases in the Late Holocene within the area of Podhale (the Carpathians, southern Poland): studies in the Falsztyński valley. Geological Quaterly, 63, 629–642.
- 13. Alexandrowicz, W.P. 2020. Development of settlements in Podhale Basin and Pieniny Mts. (western Carpathians, southern Poland) in light of malacological research. Carpathian Journal of Earth and Environmental Sciences, 15, 247–259.
- 14. Alexandrowicz, W.P. and Alexandrowicz, S.W. 2010. Expansive migrations of molluscs during the historic period. Biological Invasions in Poland, 1, 19–44.
- 15. Alexandrowicz, Z., Alexandrowicz, W.P. and Buczek, K. 2019. Conservation of the Natura 2000 Areas in the Context of Environmental Changes in Past and Present: a Case from the Polish Carpathians Geoheritage. Geoheritage, 11, 517–529.
- 16. Alexandrowicz, W.P. and Skoczylas, S. 2017. Molluscan assemblages from calcareous tufa in the Skalski Stream Valley (Pieniny Mountains, southern Poland) and their application for reconstruction of natural and anthropogenic environmental changes. Carpathian Journal of Earth and Environmental Sciences, 12, 583–594.
- 17. Alexandrowicz, W.P., Szymanek, M. and Rybska, E. 2014. Changes to the environment of intramontane basins in the light of malacological research of calcareous tufa: Podhale Basin (Carpathians, Southern Poland). Quaternary International, 353, 250–265.
- 18. Alexandrowicz, W.P., Szymanek, M. and Rybska, E. 2016. Molluscan assemblages from Holocene calcareous tufa and their significance for palaeoenvironmental reconstructions. A study in the Pieniny Mountains (Carpathians, southern Poland). Carpathian Journal of Earth and Environmental Sciences, 11, 37–54.
- 19. Benito, G., Macklin, M., Panin, A., Rossato, S., Fontana, A., Jones, A.F., Machado, M.J., Matlakhova, E., Mozzi, P. and Zielhofer C. 2015.Recurring flood distribution patterns related to shortterm Holocene climatic variability.Scientific Reports, 5, 16398, 1–8.
- 20. Birkenmajer, K. and Gedl, P. 2017. The Grajcarek Succession (Lower Jurassic–mid Paleocene) in the Pieniny Klippen Belt, West Carpathians: a stratigraphic synthesis. Annales Societatis Geologorum Poloniae, 87, 55–88.
- 21. Bond, G., Kromer, B., Beer, J., Muscheler, R., Evans, M., Showers, W., Hoffmann, S., Lotti-Bond, R., Hajdas, I. and Bonani, G. 2001. Persistent solar influence on North Atlantic climate during the Holocene. Science, 294, 2130–2136.
- 22. Bradley, K.R. 2000. Past global changes and their significance for the future. Quaternary Science Reviews, 19, 391–402.
- 23. Briffa, K.R. 2000. Annual climate variability in the Holocene: interpreting the message of ancient trees. Quaternary Science Reviews, 19, 87–105.
- 24. Bronk Ramsey, C. 2017. Methods for Summarizing Radiocarbon Datasets. Radiocarbon, 59, 1809–1833.
- 25. Čiliak, M., Čejka, T. and Šteffek, J. 2015. Molluscan diversity in stream driftwood: relation to land use and river section. Polish Journal of Ecology, 63, 124–134.
- 26. Dapples, F., Lotter, A.F., van Leeuven, J.F.N., van der Knapp, W.O., Dimitriadis, S. and Oswald, D. 2002. Palaeolimnological evidence for increased landslide activity due to forest clearing and land-use since 3600 cal BP in the western Swiss Alps. Journal of Paleolimnology, 27, 239–248.
- 27. Demény, A., Kern, Z., Hatvani, I.G., Torma, C., Topál, D., Frisia, S., LeélŐssy, S., Czuppon, G. and Surányi, G. 2021. Holocene hydrological changes in Europe and the role of the North Atlantic ocean circulation from a speleothem perspective. Quaternary International, 571, 1–10.
- 28. Frodlová, J. and Horsák, M. 2021. High-resolution mollusc record from the Mituchovci tufa (western Slovakia): a reference for the Holocene succession of Western Carpathian mid-elevation forests. Boreas, 50, 709–722.
- 29. Gerlach, T. 1966. Developpement actuel des versants dans le basin du haut Grajcarek (les Hautes Beskides – les Carpates Occidentales). Prace Geograficzne, 52, 7–111. [In Polish with French summary]
- 30. Gębica, P. 2011. Stratigraphy of alluvial fills and phases of the Holocene floods in the lower Wisłok river. Geographia Polonica, Special Issue I, 39–60.
- 31. Gębica, P. 2013a. Chronostratigraphy of alluvia and age of fluvial landforms in the Carpathians foreland during the Vistulian. Studia Quaternaria, 30, 19–27.
- 32. Gębica, P. 2013b. Geomorphological records of human activity reflected in fluvial sediments in the Carpathians and their foreland. Landform Analysis, 22, 21–31.
- 33. Gębica, P., Jacyszyn, A., Krąpiec, M., Budek, A., Czumak, N., Starkel, L., Andrejczuk, W. and Ridush, B. 2016. Stratigraphy of alluvia and phases of the Holocene floods in the valleys of the Eastern Carpathians foreland. Quaternary International, 415, 55–66.
- 34. Gębica, P. and Krąpiec, M. 2009. Young Holocene alluvia and dendrochronology of subfossil trunks in the San river valley. Studia Geomorphologica Carpatho-Balcanica, 43, 63–75.
- 35. Grove, J. 1988. The Little Ice Age. 479 pp. London-New York, Methuen.
- 36. Grove, J.M. and Switsur, R. 1994. Glacial geological evidence for the Medieval Warm Period. Climatic Change, 26, 143–169.
- 37. Helama, S., Jones, P.D. and Briffa, K.R. 2007. Dark Ages Cold Period: A literature review and directions for future research. The Holocene, 27, 1600–1606.
- 38. Hoffmann, T., Lang, A. and Dikau, R. 2008. Holocene river activity: analysing 14Cdated fluvial and colluvial sediments from Germany. Quaternary Science Reviews, 27, 2031–2040.
- 39. Holzhauser, H., Magny, M. and Zumbuühl, H.J. 2005. Glacier and lake-level variations in west-central Europe over the last 3500 years. The Holocene, 15, 789–801.
- 40. Horáčková, J., Ložek, V. and Juřičková L. 2015. List of malacologically treated Holocene sites with brief review of palaeomalacological research in the Czech and Slovak Republics. Quaternary International, 357, 207–211.
- 41. Horsák, M., Juřičkova, L. and Picka, J. 2013. Molluscs of the Czech and Slovak Republics. 264 pp. Nakladatelstvi Kabourek; Zlin.
- 42. IvyOchs, S., Kerschner, H., Maisch, M., Christl, M., Kubik, P.W. and Schlüchter Ch. 2009. Latest Pleistocene and Holocene glacier variations in the European Alps. Quaternary Science Reviews, 28, 2137–2149.
- 43. Joerin, U.E., Stocker, T.F. and Schlüchter Ch. 2006. Multicentury glacier fluctuations in the Swiss Alps during the Holocene. The Holocene, 16, 697–904.
- 44. Juřičková, L., Horsák, M., Horáčková, J., Abraham, V. and Ložek, V. 2014a. Pattern of landsnail succession in Central Europe over the 15,000 years: Man changes along environmental, spatial and temporal gradients. Quaternary Science Reviews, 93, 155–166.
- 45. Juřičkova, L., Horsák, M., Horáčková, J. and Ložek, V. 2014b. Ecological groups of snails – use and perspectives. European Malacological Congress, Cambrige, UK, poster (www. http://mollusca.sav.sk/malacology/Jurickova/2014-ecological-groups-poster.pdf).
- 46. Juřičková, L., Šída, P., Horáčková, H., Ložek, V. and Pokorný, P. 2020. The lost paradise of snails: Transformation of the middleHolocene forest ecosystems in Bohemia, Czech Republic, as revealed by declining land snail diversity. The Holocene, 30, 1254–1265.
- 47. Jurkiewicz, E, 1994. Structural analysis of the Pieniny Klippen Belt at Jaworki, Carpathians, Poland. Studia Geologica Polonica, 106, 7–87. [In Polish, English summary]
- 48. Kołaczek P., Margielewski W., Gałka M., KarpińskaKołaczek M., Buczek K., Lamentowicz M., Borek A., Zernitskaya V. and Marcisz K. 2020. Towards the understanding the impact of fire on the lower montane forest in the Polish Western Carpathians during the Holocene. Quaternary Science Reviews, 229, 106–137.
- 49. Ložek, V. 1964. Quartärmollusken der Tschechoslovakei. Rozpravy Ustředniho Ustavu Geologického, 31, 1–374.
- 50. Łajczak, A., Margielewski, W., Rączkowska, Z. and Święchowicz, J. 2014. Contemporary geomorphic processes in the Polish Carpathians under changing human impact. Episodes, 37, 21–32.
- 51. Magny, M. 1993. Holocene fluctuation of lake levels in the French Jura and SubAlpine ranges, and their impactions for past general circulation patterns. The Holocene, 3, 306–313.
- 52. Magny, M. 2004. Holocene climatic variability as reflected by mid European lakelevel fluctuations, and its probable impact on prehistoric human settlements. Quaternary International, 113, 65–79.
- 53. Magny, M., Joannin, S., Galop, D., Vannière, B., Haas, J.N., Bassetti M., Bellintani P., Scandolari R. and Desmet M. 2012. Holocene palaeohydrological changes in the northern Mediterranean borderlands as reflected by the lakelevel record of Lake Ledro, northeastern Italy. Quaternary Research, 77, 382–396.
- 54. Margielewski, W. 1998. Landslide phases in the Polish Outer Carpathians and their relation to the climatic changes in the Late Glacial and Holocene. Quaternary Studies in Poland, 15, 37–53.
- 55. Margielewski, W. 2006. Record of the Late Glacial-Holocene climatic changes in landslide forms and deposits of the Beskid Makowski and Beskid Wyspowy Mts. area (Polish Outer Carpathians). Folia Quaternaria, 76, 1–149.
- 56. Margielewski, W. 2018. Landslide fens as a sensitive indicator of paleoenvironmental changes since the Late Glacial: a case study of the Polish Western Carpathians. Radiocarbon, 60, 1199–1213.
- 57. Matthews, J.A. and Briffa, K.R. 2005. The ‘Little Ice Age’: re-evaluation of an evolving concept. Geografiska Annaler, 87, A: 17–36.
- 58. Mayewski, P.A., Rohling, E.E., Stager, J.C., Karlen, W., Maasch, K.A., Meeker, L.D., Meyerson, E.A., Gasse, F., van Kreveld, S., Holmgren, K., LeeThorp, J., Rosqvist, G., Rack, F., Staubwasser, M., Schneider, R.R. and Steig, E.J. 2004. Holocene climate variability. Quaternary Research, 62, 243–255.
- 59. Mauri, A., Davis, B.A.S., Kaplan, J.O. and Collins, P. 2015. The climate of Europe during the Holocene: a gridded pollenbased reconstruction and its multiproxy evaluation. Quaternary Science Reviews, 112, 109–127.
- 60. Nussbaumer, S.U., Steinhilber, F., Trachsel, M., Breitenmoser, P., Beer, J., Blass, A., Grosjean, M., Hafner, A., Holzhauser, H., Wanner, H. and Zumbühl H.J. 2011. Alpine climate during the Holocene: a comparison between records of glaciers, lake sediments and solar activity. Journal of Quaternary Science, 26, 703–713.
- 61. Obidowicz, A. 1990. Eine pollenanalytische und moorkundli sche Studie zur Vegetationgeschichte des PodhaleGebites (WestKarpaten). Acta Paleobotanica, 30, 147–219.
- 62. Pánek, T., Smolková, V., Hradecký, J., Baroò, I. and Šilhán, K. 2013. Holocene reactivations of catastrophic complex flowlike landslides in the Flysch Carpathians (Czech Republic/Slovakia). Quaternary Research, 80, 33–46.
- 63. Perșoiu, I. and Perșoiu, A. 2019. Flood events in Transylvania during the Medieval Warm Period and the Little Ice Age. The Holocene, 29, 85–96.
- 64. Plunkett, G. and Swindles, G.T. 2008. Determining the Sun’s influence on Lateglacial and Holocene climates: a focus on climate response to centennial-scale solar forcing at 2800 cal. BP. Quaternary Science Reviews, 27, 175–184.
- 65. Prager, C., Zangerl, C., Patzelt, G., Brandner, R. 2008. Age distribution of fossil landslides in the Tyrol (Austria) and its surrounding areas. Natural Hazards and Earth System Science, 8, 377–407.
- 66. Ralska-Jasiewiczowa, M. and Starkel, L. 1988. Record of the hydrological changes during the Holocene in the lake, mire and fluvial deposits of Poland. Folia Quaternaria, 57, 91–127.
- 67. Rădoane, M., Chiriloaei, F., Sava, T., Nechita, C., Rădoane, N. and Gâza, O. 2019. Holocene fluvial history of Romanian Carpathian rivers. Quaternary International, 527, 113–129.
- 68. Reimer, P., Austin, W., Bard, E., Bayliss, A., Blackwell, P., Bronk Ramsey, C., Butzin, M., Cheng, M.H., Edwards, R., Friedrich, M., Grootes, P., Guilderson, T., Hajdas, I., Heaton, T., Hogg, A., Hughen, K., Kromer, B., Manning, S., Muscheler, R., Palmer, J., Pearson C., van der Plicht, J., Reimer, R., Richards, D., Scott, E., Southon, J., Turney, C., Wacker, L., Adolphi, F., Büntgen, U., Capano, M., Fahrni, S., FogtmannSchulz, A., Friedrich, R., Köhler, P., Kudsk, S., Miyake, F., Olsen, J., Reinig, F., Sakamoto, M., Sookdeo, A. and Talamo, S., 2020. The IntCal20 Northern Hemisphere Radiocarbon Age Calibration Curve (0–55 cal kBP). Radocarbon, 62, 725–757.
- 69. Rybniček, K. and Rybničková, E. 2002. Vegetation of the Upper Orava region (NW Slovakia) in the last 11000 years. Acta Paleobotanica, 42, 153–170.
- 70. Sobala M. and Rahmonov O. 2020. The human impact on changes in the forest range of the Silesian Beskids (Western Carpathians). Resources, 12, 141, 1–20.
- 71. Soldati, M., Corsini, A. and Pasuto, A. 2004. Landslides and climate change in the Italian Dolomites since the Lateglacial. Catena, 55, 141–161.
- 72. Starkel, L. 1997. Mass movement during the Holocene: Carpathian example and the European perspective. In: Frenzel, B. (Ed.), Rapid mass movement as a source of climatic evidence for the Holocene. Palaeoclimate Research, 19, 385–400.
- 73. Starkel, L., Michczyńska, D.J, Krąpiec, M., Margielewski, W., Nalepka, D. and Pazdur, A. 2013. Progress in the Holocene chrono-climatostratigraphy of Polish territory. Geochronometria, 40, 1–21.
- 74. Starkel, L., Soja, R. and Michczyńska, D. J. 2006. Past hydrological events reflected in Holocene history of Polish Rivers. Catena, 66, 24–33.
- 75. Szwagrzyk, M., Kaim, D., Price, B., Wypych, A., Grabska, E. and Kozak, J. 2018. Impact of forecasted land use changes on flood risk in the Polish Carpathians.Natural Hazards, 94, 227–240.
- 76. Walker, M., Head, M. J., Lowe, J., Berkelhammer, M., Björck, S., Cheng, H., Cwynar, L. C., Fisher, D., Gkinis, V., Long, A., Newnham, R., Rasmussen, S. O. and Weiss, H. 2019. Subdividing the Holocene Series/Epoch: formalization of stages/ages and subseries/subepochs, and designation of GSSPs and auxiliary stratotypes. Journal of Quaternary Science, 34, 173–186.
- 77. Welter-Schultes, F.W. 2012. European non-marine molluscs, guide for species identification. 687 pp. Planet Poster Editions; Göttingen.
- 78. Wiktor, A. 2004. Ślimaki lądowe Polski. 302 pp. Wydawnictwo Mantis; Olsztyn.
- 79. Wirth, S.B., Glur, L. and Gilli, A. 2013. Holocene flood frequency across the Central Alps – solar forcing and evidence for variations in North Atlantic atmospheric circulation. Quaternary Science Reviews, 80, 112–128.
Uwagi
PL
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d96fb831-a22e-4d41-b546-8c9acc3c44a1