A palaeohydrological record of a complete Eemian series from Żabieniec Ża-19 (Garwolin Plain, Central Poland) with reference to palaeoclimate data

Kultys, Kamil; Mirosław-Grabowska, Joanna; Zalat, Abdelfattah; Hrynowiecka, Anna; Łabęcka, Karolina; Terpiłowski, Sławomir; Żarski, Marcin; Pidek, Irena Agnieszka

doi:10.24425/agp.2023.145613

Artykuł - szczegóły

Tytuł artykułu

A palaeohydrological record of a complete Eemian series from Żabieniec Ża-19 (Garwolin Plain, Central Poland) with reference to palaeoclimate data

Autorzy

Kultys Kamil , Mirosław-Grabowska Joanna , Zalat Abdelfattah , Hrynowiecka Anna , Łabęcka Karolina , Terpiłowski Sławomir , Żarski Marcin , Pidek Irena Agnieszka

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.24425/agp.2023.145613

Warianty tytułu

Języki publikacji

Abstrakty

The aim of this study was to reconstruct the evolution of the Eemian palaeolake in the Żabieniec site (Garwolin Plain, Central Poland); it identifies changes in the water level and the trophic status of the lake resulting from pan-regional factors, including climate changes occurring during individual phases of the last interglacial, and local geologic-geomorphological factors shaping the palaeoenvironment using multi-proxy methods (palaeobotanical analyses, subfossil Cladocera and diatoms analyses as well as determinations of the stable isotopes). A record was obtained of all seven Regional Pollen Assemblage Zones (RPAZs) according to Mamakowa’s description of the Eemian pollen succession (1989), and of the changes in microfossil assemblages and isotopes in palaeolake sediments associated with lake evolution. Special attention was paid to the Middle Eemian RPAZ 4 (i.e. hazel phase) of the climatic optimum; all proxies associate this with the highest water level and a warm humid climate. During the E5/E6 RPAZs, the eutrophic lake transformed very quickly, and a transitional peatbog was formed. The higher humidity of the late Eemian resulted in another increase in water level. The multi-proxy record of the Żabieniec palaeolake which we obtained was compared to those of other Eemian water bodies in the Garwolin Plain and in Central Poland that exhibit sedimentation gaps especially during the younger part of the E5 RPAZ.

Słowa kluczowe

eemian interglacial Fossil Lake multi-proxy analyses climate changes Central Poland

interglacjał eemski zmiany klimatyczne Centralna Polska

Wydawca

Faculty of Geology of the University of Warsaw
Komitet Nauk Geologicznych PAN

Czasopismo

Acta Geologica Polonica

Rocznik

2023

Tom

Vol. 73, no. 3

Strony

355–--378

Opis fizyczny

Bibliogr. 76 poz., rys., tab., wykr.

Twórcy

autor

Kultys Kamil

kamilkultys8@o2.pl

Institute of Earth and Environmental Sciences, Maria Curie-Skłodowska University
ECOTECH-COMPLEX , Maria Curie-Skłodowska University

autor

Mirosław-Grabowska Joanna

jmirosla@twarda.pan.pl

Institute of Geological Sciences, Polish Academy of Sciences

autor

Zalat Abdelfattah

abzalat@science.tanta.edu.eg

Geology Department, Faculty of Science, Tanta University

autor

Hrynowiecka Anna

ahry@pgi.gov.pl

Polish Geological Institute-National Research Institute, Marine Geology Branch

autor

Łabęcka Karolina

Institute of Earth and Environmental Sciences, Maria Curie-Skłodowska University

autor

Terpiłowski Sławomir

slawomir.terpilowski@mail.umcs.pl

Institute of Earth and Environmental Sciences, Maria Curie-Skłodowska University

autor

Żarski Marcin

mzar@pgi.gov.pl

Polish Geological Institute-National Research Institute

autor

Pidek Irena Agnieszka

irena.pidek@mail.umcs.pl

Institute of Earth and Environmental Sciences, Maria Curie-Skłodowska University

Bibliografia

1. Battarbee, R.W. and Kneen, M.J. 1982. The use of electroni-cally counted microspheres in absolute diatom analysis. Limnology and Oceanography, 27, 184–188.
2. Berglund, B.E. and Ralska-Jasiewiczowa, M. 1986. Pollen analysis and pollen diagrams. In: Berglund, B.E. and Ralska- Jasiewiczowa, M. (Eds), Handbook of Holocene Palaeoecology and Palaeohydrology, 455–484. J. Wiley & Sons Ltd.; Chichester-Toronto.
3. Błędzki, L.A. and Rybak, J.I. 2016, Freshwater Crustacean Zooplankton of Europe Cladocera & Copepoda (Calanoi-da, Cyclopoida), Key to species identification, 87–438. Springer; Cham.
4. Bober, A., Pidek, I.A. and Żarski, M. 2018, Late Saalian and Eemian Interglacial at the Struga site (Garwolin Plain, cen-tral Poland), Acta Paleobotanica, 58 (2), 219–229.
5. Bober, A., Brzozowicz, D., Drzymulska, D., Zarski, M. and Suchora, M. 2021. Palaeobotanical record of the Eemian Interglacial succession at the Jagodne site (Garwolin plain, central Poland). Geological Quarterly, 65 (2), 34.
6. Bruj, M. and Roman, M. 2007. Zasięg pojezierza z interglacjału eemskiego w Polsce a pozycja stratygraficzna lądolodów zlodowaceń środkowopolskich, Biuletyn Państwowego In¬stytutu Geologicznego, 425, 29–36.
7. Cohen, K.M. and Gibbard, P. 2019. Global chronostratigraphi-cal correlation table for the last 2.7 million years. Subcom-mission on Quaternary Stratigraphy (International Com-mission on Stratigraphy); Cambridge.
8. Denys, L. 1991–1992. A check-list of the diatoms in the Ho-locene deposits of the western Belgian coastal plain with a survey of their apparent ecological requirements. I. In-troduction, ecological code and complete list. Professor Paper Belgium Geological Survey, 246, 1–41.
9. De Klerk, P., Donner, N., Joosten, H., Karpov, N.S., Minke, M., Seifert, N. and Theuerkauf, M. 2009. Vegetation patterns, recent pollen deposition and distribution of non-pollen pal-ynomorphs in a poligon mire near Chokurdakh (NE Yaku-tia, NE Siberia). Boreas, 38, 39–58.
10. Flössner, D. 2000. Die Haplopoda und Cladocera Mitteleuro-pas, 428 pp. Backhuys; Leiden.
11. Frey, D.G. 1986. Cladocera analysis. In: Berglund, B.E. (Ed.), Handbook of Holocene palaeoecology and palaeohydro-logy, 667–692, John Wiley, Sons Ltd.; New York.
12. Gerdemann, J.W. and Trappe, J.M. 1974. The endogonaceae in the Pacific Northwest. Mycologia memoir, 5, 36–59.
13. Granoszewski, W. 2003. Late Pleistocene vegetation history and climatic changes at Horoszki Duże, Eastern Poland: a palaeobotanical study. Acta Palaeobotanica (Supplement), 4, 3–95.
14. Grimm, E.C. 2011. Tilia software v. 1.7. 16. Illinois State Museum; Springfield.
15. GRIP members 1993. Climate instability during the last inter-glacial period recorded in the GRIP ice core. Nature, 364, 203–207.
16. Haas, J.N. 1996. Neorhabdocoela oocytes – palaeoecological in-dicators found in pollen preparations from Holocene fresh-water lake sediments. Review of Palaeobotany and Palyno-logy, 91, 371–382.
17. Wu, H.-X., Schoch, C.L., Boonmee, S., Bahkali, A.H., Chom-nunti, P. and Hyde, K.D. 2011. A reappraisal of Microthyria-ceae. Fungal Diversity, 5, 189–248.
18. Hammer, Ø., Harper, D.A. and Ryan, P.D. 2001. PAST: paleon-tological statistics software package for education and data analysis. Palaeontologia Electronica, 4 (1), 1–9.
19. Hofmann, G., Werum, M. and Lange-Bertalot, H. 2011. Diato-meen im Süßwasser-Benthos von Mitteleuropa, 908 pp. A.R.G. Gantner Verlag; Rugell, Liechtenstein.
20. Hrynowiecka A., Żarski M., Jakubowski G., Nadachowski A., Pawłowska K., Pawłowski D., Szymanek M. and Nast, D. 2018. Eemian and Vistulian (Weichselian) paleoenvironmental changes: A multi-proxy study of sediments and mammal remains from the Ławy paleolake (Eastern Po-land). Quaternary International, 467, 131–146.
21. Hrynowiecka, A., Brzozowicz, D., Żarski, M., Stachowicz-Rybka, R. and Pidek, I.A. 2020. Record of climate and palae-oenvironment changes in the fossil Eemian lake in Żabieniec (Central Poland). Proceedings of INQUA SEQS2020, 55.
22. Klatkowa H. 1990. Występowanie eemskich osadów organicznych i uwagi o paleomorfologii środkowej Polski u schyłku warty i podczas eemu. Acta Geographica Lodzien¬sia, 61, 7–17.
23. Kołaczek, P., Karpińska-Kołaczek, M. and Petera-Zganiacz, J. 2012. Vegetation patterns under climate changes in the Eemian and Early Weichselian in Central Europe inferred from a palynological sequence from Ustków (central Po-land). Quaternary International, 268, 9–20.
24. Kołaczek, P., Niska, M., Mirosław-Grabowska, J. and Gałka, M. 2016. Periodic lake-peatland shifts under the Eemian and Early Weichselian climate changes in Central Europe on the basis of multi-proxy studies. Palaeogeography Pa¬laeoclimatology Palaeoecology, 461, 29–43.
25. Kowalewski G. 2014. Alogeniczne i autogeniczne składowe zarastania jezior: hipoteza wahań poziomu wody. Studia Limnologica et Telmatologica. Monographiae I, 1–192.
26. Krammer, K. and Lange-Bertalot, H. 1986–1991. Bacillariophy-ceae. In: Ettl, H., Gerloff, J., Heynig, H., Mollenhauer, D. (Eds), Süßwasserflora von Mitteleuropa 2 (1), 876, 2 (2), 611, 2 (3), 563, 2 (4). 468. Gustav Fischer Verlag; Stuttgart/New York.
27. Ku, H.-W., Chen, Y.-G., Chan, P.-S., Liu, H.-C. and Lin, C.-C. 2007. Paleo- environmental evolution as revealed by analysis of organic carbon and nitrogen: A case of coastal Taipei Basin in Northern Taiwan. Geochemical Journal, 41, 111–120.
28. Kultys, K., Hrynowiecka, A. and Żarski, M. 2022. Ewolucja eemskiego jeziora w zapisie kopalnej fauny Cladocera na tle faz rozwoju roślinności: stanowisko Puznówka PU-19 (Równina Garwolińska). Sympozjum Sekcji Paleobota nicz-nej PTB (https://pbsociety.org.pl/repository/)Kultys, K., Brzozowicz, D., Drzymulska, D., Szymanek, M., Mirosław-Grabowska, J., Pidek, I.A. and Żarski, M. 2023. Does the multi-proxy Eemian record from the Słup site (Central Poland) indicate a more humid climate at the beginning of the hornbeam phase? Geological Quarterly (under review).
29. Kupryjanowicz, M., Żarski, M. and Drzymulska, D. 2003. Kontrowers – a new locality of the Eemian interglacial and the Early Vistulian at Zelechow Upland (eastern Poland). Acta Palaeobotanica, 43 (1), 77–90.
30. Kupryjanowicz, M. 2008. Vegetation and climate of the Eemi-an and Early Vistulian Lakeland in northern Podlasie, Acta Palaeobotanica, 48 (1), 3–130.
31. Kupryjanowicz, M. and Granoszewski, W. 2018. Detailed pal-ynostratigraphy of the Eemian Interglacial in Poland. In: Kupryjanowicz, M., Nalepka, D., Madeyska, E. and Turner, Ch. (Eds), Eemian history of vegetation in Poland based on isopollen maps , 17–20. W. Szafer Institute of Botany, Polish Academy of Sciences; Kraków.
32. Kupryjanowicz, M., Nalepka, D., Madeyska, E. and Turner, Ch. (Eds) 2018. Eemian history of vegetation in Poland based on isopollen maps, 262 pp. W. Szafer Institute of Botany, Polish Academy of Sciences; Kraków.
33. Kurek, J., Korosi, J.B., Jeziorski, A. and Smol, J.P. 2010. Establishing reliable minimum count sizes for cladoceran sub-fossils sampled from lake sediments. Journal of Paleolimno¬logy, 44 (2), 603–612.
34. Lauterbach, S., Brauer, A., Litt, T. and Schettler, G. 2012. Re-evaluation of the Bispingen palaeolake record – a re-vised chronology for the Eemian in Northern Germany. In: EGU General Assembly 2012, held 22–27 April, 2012 in Vienna, Austria, 8613.
35. Lehmitz, R. 2014. The oribatid mite community of a German peatland in 1987 and 2012 – effects of anthropogenic dessication and aforestation, Soil Organizms, 86 (2), 131–145.
36. Lindner, L. 1992. Interglacjał eemski (Riss/Wurm). In: Lindner, L. (Ed.), Czwartorzęd. Osady, Metody Badan, Stratygrafia, 555–573. Wydawnictwo Geologiczne Polska Agencja Eko-logiczna; Warszawa.
37. Makowska, A. 1979. Interglacjał eemski w dolinie dolnej Wisły. Studia Geologica Polonica, 63, 1–90.
38. Makowska, A. 2009. Międzymorenowa formacja dolnopowiślańska na tle budowy osadów plejstoceńskich pomorza nadwiślańskiego i jej rozwój w młodszym plejstocenie. Biuletyn PIG, 437, 59–124.
39. Malkiewicz, M. 2003. Palynology of biogenic sediments of the Eemian Interglacial at Bieganin near Kalisz, Central Po-land. Geological Quarterly, 47 (4), 367–372.
40. Malkiewicz, M. 2018. A Late Saalian Glaciation, Eemian Inter-glacial and Early Weichselian pollen sequence at Szklarka, SW Poland – Reconstruction of vegetation and climate. Quaternary International, 467, 43–53.
41. Mamakowa, K. 1989. Late Middle Polish Glaciation, Eem ian and Early Vistulian vegetation at Imbramowice near Wrocław and the pollen stratigraphy of this part of the Pleistocene in Poland. Acta Palaeobotanica, 29 (1), 11–176.
42. Metzeltin, D. and Lange-Bertalot, H. 1998. Tropical diatoms of South America I: About 700 predominantly rarely known or new taxa representative of the neotropical flora. In: Lange-Bertalot, H. (Ed.), Iconographia Diatomo-logica. Anno tated Diatom Micrographs. Vol. 5. Diversity – Taxonomy – Geobotany, 3–695. Koeltz Scientific Books; Königstein.
43. Mirosław-Grabowska, J. and Gąsiorowski, M. 2010. Changes of water level in the Eemian palaeolake at Imbramowice (SW Poland) based on isotopic and cladoceran data. Qua¬ternary Research, 73 (1), 143–150.
44. Mirosław-Grabowska, J. and Niska, M. 2005. Isotopic and Cladocera records of climate changes of Early Eemian at Besiekierz (Central Poland). Geological Quarterly, 49 (1), 67–74.
45. Mirosław-Grabowska, J. and Niska, M. 2007a, Isotope and Cladocera data and interpretation from the Eemian optimum and postoptimum deposits, Kaliska palaeolake (Cen-tral Poland). Quaternary International, 175 (1), 155–167.
46. Mirosław-Grabowska, J., Niska, M. and Kupryjanowicz, M. 2015, Reaction of lake environment on the climatic cooling – Transition from the Eemian Interglacial to Early Vistulian on the basis of Solniki palaeolake sediments (NE Poland). Quaternary International, 386, 158–170.
47. Mirosław-Grabowska, J., Niska, M. and Roman, M. 2018. Long (MIS 5e-3) environmental history of a paleolake in Central Poland recorded in the succession from Kubłowo. Quaternary International, 467, 26–42.
48. Mojski, J. 1993. Europa w plejstocenie – ewolucja środowiska przyrodniczego. Wydawnictwo Polskiej Agencji Ekologicznej; Warszawa.
49. Myślińska, E. 2001. Grunty organiczne i laboratoryjne metody ich badania, 208 pp. PWN; Warszawa.
50. Nalepka, D. and Walanus, A. 2003. Data processing in pollen analysis. Acta Palaeobotanica, 43 (1), 125–134.
51. Niska, M. 2015. History of the development of Eemian Interglacial lakes on the basis of Cladocera subfossil analysis (Central and Eastern Poland), Limnological Review, 15 (3), 85–93.
52. Niska, M. and Kołodziej, A. 2015. History of development and terrestrialization of Lake Starowlany in the eemian inter-glacial based on Cladocera analysis (Sokółka Hills, NE Poland), Studia Quaternaria, 32 (1), 43–52.
53. Pawłowski D. 2011. Ewolution of an Eemian Lake based on Cladocera analysis (Konin area, Central Poland), Acta Geologica Polonica, 61 (4), 441–450.
54. Pidek, I.A., Hrynowiecka, A. and Żarski, M. 2021a. Zapis interglacjału eemskiego w stanowisku Puznówka (Równina Garwolińska, Polska Centralna) – trudności interpretacyjne. Sympozjum Sekcji Paleobotanicznej PTB, 35–36.
55. Pidek, I.A., Zalat, A.A., Hrynowiecka, A. and Żarski, M. 2021b. A high-resolution pollen and diatom record of mid-to late-Eemian at Kozłów (Central Poland) reveals no drastic climate changes in the hornbeam phase of this interglacial. Quaternary International, 583, 14–30.
56. Pidek, I.A., Poska, A., Hrynowiecka, A., Brzozowicz, D. and Żarski, M. 2022. Two pollen-based methods of Eemian climate reconstruction employed in the study of the Żabieniec-Jagodne palaeolakes in central Poland. Quaternary International, 632, 21–35.
57. Rühland, K.M., Paterson, A.M., and Smol, J.P. 2015. Lake diatom responses to warming: reviewing the evidence. Jour¬nal of paleolimnology, 54, 1–35.
58. Roman, M., Mirosław-Grabowska, J. and Niska, M. 2021. The Eemian Lakeland of the central Polish Plain: Environmen-tal changes and palaeogeography. Palaeogeography Palae¬oclimatology Palaeoecology, 561, 110087.
59. Shackleton, N.J., Chapman, M., Sánchez-Goñi, M.F., Pailler, D. and Lancelot, Y. 2002. The Classic Marine Isotope Sub-stage 5e. Quaternary Research, 58 (1), 14–16.
60. Shumilovskikh, L.S. and van Geel, B. 2020. Non-Pollen Palynomorphs. In: Henry, A.G. (Eds), Handbook for the Ana-lysis of Micro-Particles in Archaeological Samples, 65–94. Interdisciplinary Contributions to Archaeology, Springer; Cham.
61. Solon, J., Borzyszkowski, J., Bidłasik, M., Richling, A., Badora, K., Balon, J., Brzezińska-Wójcik, T., Chabudziński, Ł., Dobrowolski, R., Grzegorczyk, I., Jodłowski, M., Kis-towski, M., Kot, R., Krąż, P., Lechnio, J., Macias, A., Majchrowska, A., Malinowska, E., Migoń, P., Myga-Piątek, U., Nita, J., Papińska E., Rodzik, J., Strzyż, M., Terpiłows-ki, S. and Ziaja, W. 2018. Physicogeographical mesoregions of Poland: Verification and adjustment of boundaries on the basis of contemporary spatial data. Geographia Po¬lonica, 91 (2), 143–170.
62. Suchora, M., Kultys, K., Stachowicz-Rybka, R., Pidek, I.A., Hrynowiecka, A., Terpiłowski, S., Łabęcka K. and Żarski, M. 2022. Palaeoecological record of long Eemian series from Kozłów (Central Poland) with reference to palaeoclimatic and palaeohydrological interpretation. Quaternary International, 583, 14–30.
63. Szeroczyńska, K. 1998. Anthropogenic transformation of nine lakes in Central Poland from Mesolithic to modern times in the light of Cladocera analysis. Studia Geologica Polonica, 112, 123–165.
64. Szeroczyńska K. and Sarmaja-Korjonen K. 2007. Atlas of Sub-fossil Cladocera from Central and Northen Europe, 83 pp. Society of Friends of the Lower Vistula; Świecie.
65. van Dam, H., Mertens, A. and Sinkeldam, J. 1994. A coded checklist and ecological indicator values of freshwater diatoms from the Netherlands. Netherland Journal of Aquatic Ecology, 28 (1), 117–133.
66. van Geel, B. 1978. A palaeoecological study of Holocene peat bog sections in Germany and the Netherlands, based on the analysis of pollen, spores and macro- and microscopic re-mains of fungi, algae cormophytes and anymals. Review of Palaeobotany and Palynology, 25, 1–120.
67. Williams, D.M. and Round, F.E. 1987. Revision of the genus Fragilaria. Diatom Research, 2, 267–288.
68. Witkowski, A., Lange-Bertalot, H. and Metzeltin, D. 2000. Dia-tom flora of marine coasts I. Iconographia Diatomologica, 7, 1–925.
69. Zagwijn, W.H. 1989. The Netherlands during the Tertiary and Quaternary: a case history of Coastal Lowland evolution. Coastal Lowlands. Springer, 68, 107–120.
70. Zalat, A., Welc, F., Nitychoruk, J., Marks, L., Chodyka, M. and Zbucki, L. 2018. Last two millennia water level changes of the Młynek Lake (northern Poland) inferred from diatoms and chrysophyte cysts record. Studia Quaternaria, 35 (2), 77–89.
71. Zalat, A.A., Bober, A., Pidek, I.A. and Żarski, M. 2021. Environmental and climate change during the Late Saalian–Eemian Interglacial at the Struga site (Central Poland): a diatom record against the background of palynostratigraphy. Review of Palaeobotany and Palynology,288, 104386.
72. Zalat, A.A., Nitychoruk, J., Chodyka, M., Pidek, I.A. and Welc, F. 2022. Recent and fossil freshwater diatoms of Poland: taxonomy, distribution and their significance in the environmental reconstruction. Part 1 Coscinodiscophyceae, Mediophyceae and Fragilariophycidae, 304 pp. John Paul II University of Applied Science; Biala Podlaska.
73. Zalat, A.A. and Servant-Vildary, S. 2007. Environmental change in Northern Egyptian Delta lakes during the late Holocene, based on diatom analysis. Journal of Paleolimnology, 37, 273–299.
74. Żarski, M. 2020. Detailed Geological Map of Poland scale 1: 50, 000 Garwolin sheet (566), PIG-PIB; Warszawa.
75. https://non-pollen-palynomorphs.uni-goettingen.de/?fbclid= IwAR1WT_bA5EW7a0lJtNCgswbEJ7a2Pi-RHgulz4lt kfrmTgWLE_ubKWZY8ew
76. https://pbsociety.org.pl/repository/handle/20.500.12333/372? fbclid=IwAR0E4BUJljEhbWdhNgrbaTdzvFD6JT 387p0QrSM745NngafGb2fwXcPhtOg

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr POPUL/SP/0154/2024/02 w ramach programu "Społeczna odpowiedzialność nauki II" - moduł: Popularyzacja nauki (2025).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-a6e24bdd-14b9-4c72-a385-b4fcd557c3bb