Ecosystem response to early and late Holocene lake-level changes in lake Jjuusa, Southern Estonia

• Autorzy: Koff T. , Punning J.-M. , Sarmaja-Korjonen K. , Martma T.
• Języki publikacji: EN

Abstrakty

EN

The main aim of the study is to analyse the response of the catchment and lake ecosystem to the lake-level change on the basis of pollen, macrofossil, cladoceran and stable isotope records obtained by a comprehensive study of sediments from a shore core from Lake Juusa (Southern Estonia). The obtained multi-proxy data indicate that there is good correspondence between lithological, macrofossil and cladoceran changes during most time in the studied period. The palaeorecords show that the development of the Lake Juusa ecosystem was triggered mainly by the fluctuations of the lake level. Discrepancies of the data for some periods are caused by the concurrent processes having specific impact on the obtained records.

Słowa kluczowe

EN

cladocera; Estonia; lake-level changes; lake sediments; macrofossil; pollen; stable isotope

• Wydawca: Museum and Institute of Zoology, Polish Academy of Sciences
• Czasopismo: Polish Journal of Ecology
• Rocznik: 2005
• Tom: Vol. 53, nr 4
• Strony: 553--570
• Opis fizyczny: Bibliogr. 56 poz., rys., tab., wykr.

Twórcy

autor

Koff T.

• Institute of Ecology at Tallinn University, Kevade 2, Tallinn 10137, Estonia

autor

Punning J.-M.

• Institute of Ecology at Tallinn University, Kevade 2, Tallinn 10137, Estonia

autor

Sarmaja-Korjonen K.

• Department of Geology, P.O. Box 64, FI-00014, University of Helsinki, Finland

autor

Martma T.

• Institute of Geology, Tallinn Technological University, Estonia Av. 7, Tallinn 10143

Bibliografia

• 1. Alhonen P. 1970 – On the significance of the planktonic/littoral ratio in the cladoceran stratigraphy of lake sediments – Societas Scientiarum Fennica. Commentationes Biologicae, 35: 1–9.
• 2. Beijerinck W. 1947 – Zadenatlas der Nederlandsche Flora – H. Veenman and Zonen, Wageningen, 316 pp. (in Dutch).
• 3. Birks H. H. 1980 – Plant macrofossils in Quaternary lake sediments – Arch. Hydrobiol., 15: 1–60.
• 4. Birks H. H. 2001 – Plant macrofossils (In: Tracking Environmental Change Using Lake Sediments. Vol.3: Terrestrial, Algal and Siliceous Indicators, Eds: J. P. Smol, H. J. B. Birks and W. M. Last) – Kluwer Academic Publishers, Dordrecht, pp. 49–74.
• 5. Brauer A. 1990 – Preliminary results of δ18O and δ13C analyses of lake marls from southern Finland (In: Proceedings of the Workshop at Lammi Biological Station, 4–6 June, Eds: M. Saarnisto, L. Kahra) – Geological Survey of Finland Helsinki, pp. 95–102.
• 6. de Eyto E. 2001 – Chydorus sphaericus as a biological indicator of water quality in lakes – Mitteilungen, Internationale Vereinigung für Theoretische und Angewandte Limnologie, 27: 3358–3362.
• 7. de Eyto E., Irvine K., García-Criado F., Gyllström M., Jeppesen E., Kornijów R., Miracle M. R., Nykänen M., Bareiss C., Cerbin S., Salujõe J., Franken R., Stephens D., Moss B. 2003 – The distribution of chydorids (Branchiopoda, Anomopoda) in European shallow lakes and its application to ecological quality monitoring - Arch. Hydrobiol., 156: 181–202.
• 8. Frey D. G. 1986a – Cladocera analysis (In: Handbook of palaeoecology and palaeohydrology, Ed., B. E. Berglund) – John Wiley & Sons Ltd., Chichester, pp. 667–692.
• 9. Frey D. G. 1986b – The non-cosmopolitanism of chydorid Cladocera: Implications for biogeography and evolution (In: Crustacean Biogeography, Eds: R. H. Gore and K. L. Heck) - Balkema, Rotterdam, pp. 237–256.
• 10. Grimm E. C. 1990 – TILIA and TILIAGRAPH. PC spreadsheet and graphics software for pollen data – INQUA, Working Group on Data-Handling Methods, Newsletter 4: 5–7.
• 11. Grosse-Brauckmann G. and Streitz B. 1992 - Pflanzliche Makrofossilien mitteleuropäischer Torfe III. Früchte, Samen und einige Gewebe – TELMA, 22: 53–102. (in German).
• 12. Haas J. N. 1994 – First identification key for charophyte oospores from central Europe - Eur. J. Phycol., 29: 227–235.
• 13. Hammarlund D., Aravena R., Barnekow L., Buchardt B., Possnert G. 1997 – Multi-component carbon isotope evidence of early Holocene environmental change and carbon-flow pathways from a hard-water lake in northern Sweden – J. Paleolim., 18: 219–233.
• 14. Hannon G. E. and Gaillard M.-J. 1997 - The plant macrofossil record of past lakelevel changes – J. Paleolim., 18: 15–28.
• 15. Hofmann W. 1998 – Cladocerans and chironomids as indicators of lake level changes in north temperate lakes – J. Paleolim., 19: 55–62.
• 16. Hyvärinen H., Martma T., Punning J.-M. 1990 – Stable isotope and pollen stratigraphy of a Holocene lake marl section from NE Finland - Boreas, 19: 17–24.
• 17. Jaagus J., Tarand A. 1988 – Sademete territoriaalne jaotus Eestis [Territorial distribution of Precipitation in Estonia] (In: Eesti Geograafia Seltsi Aastaraamat 24 [Year-book of the Estonian Geographical Society 24] - Valgus, Tallinn, pp. 5–18. (in Estonian, English summary]
• 18. Kangur M. 2005 – Palynostratigraphy of Holocene lake sediments on the Otepää Heights, southern Estonia – Proc. Estonian Acad. Sci. Geol., 54, 1: 52–68.
• 19. Katz N. J., Katz S. V., Skobeejeva E. I. 1977 – Atlas of Plant Remains in Peat. – Nedra, Moscow, 99 pp.
• 20. Koff T. 2004 – Macrofossils in the sediments of L. Juusa (southern Estonia) – Estonia. Geographical Studies 9 – Estonian Academy Publishers, Tallinn, pp. 30–40.
• 21. Koff T., Kangur M. 2003 – Vegetation history in Northern Estonia during the Holocene based on pollen diagrams from a small kettlehole and lake sediments (In: Aspects of Palynology and Palaeoecology, Ed. S. Tonkov) - PENSOFT Publisher, Sofia-Moscow, pp. 113–126.
• 22. Koff T., Punning J.-M. 2002 – The last hundred years of land-use history in Estonia as inferred from pollen records – Ann. Bot., 39: 213–224.
• 23. Koff T., Punning J.-M., Kangur M. 2000 - Impact of forest disturbance on the pollen influx in lake sediments during the last century - Rev. Palaeobot. Palynol., 111: 19–29.
• 24. Korhola A. 1999 – Distribution patterns of Cladocera in subarctic Fennoscandian lakes and their potential in environmental reconstruction - Ecography, 22: 357–373.
• 25. Korhola A., Rautio M. 2001 – Cladocera and other branchiopod crustaceans. (In: Tracking Environmental Change Using Lake Sediments Volume 4: Zoological Indicators, Eds: J. P. Smol, H. J. B. Birks and W. M. Last) – Kluwer Academic Publishers, Dordrecht, pp 5–41.
• 26. Langangen A. 1974 – Ecology and distribution of Norwegian Charophytes – Norw. J. Bot., 21: 31–52.
• 27. Leht M. (Ed.) 1999 – Eesti taimede määraja [Estonian flora] – Eesti Loodusfoto, Tartu, 447 pp. (in Estonian).
• 28. Leng M. J., Marshall J. D. 2004 – Palaeoclimatic interpretation of stable isotope data from lake sediment archives – Quat. Sci. Rev., 23: 811–831.
• 29. Lillieroth S. 1950 – Über Folgen kulturbedingter Wasserstandsenkungen für Makrophytenund Planktongemeinschaften in seichten Seen des südschweischen Oligotrophiegebietes - Acta Limnologica 3, Limnological Institute of the University of Lund, Sweden, 288 pp. (in German).
• 30. Madsen J. D., Chambers P. A., James W. F., Koch E. W., Westlake D. F. 2001 - The interactions between water movement, sediment dynamics and submersed macrophytes. - Hydrobiologia, 444: 71–84.
• 31. Mitchell E. A. D., Buttler A., Warner B., Gobat J-M. 1999 – Ecology of testate amoebae (Protozoa: Rhizopoda) in Sphagnum-dominated peatlands in the Jura Mountains, Switzerland and France – Ecoscience, 6: 565–576.
• 32. Mook W. G. 1983 – 14C calibration curves depending on sample time-width – PACT 8: 517–525.
• 33. Moore P., Webb J. A. 1978 – An Illustrated Guide to Pollen Analysis – Hodder and Stoughton, London, 133 pp.
• 34. Mäemets A. 1961 – Eesti vesikirbuliste (Cladocera) ökoloogiast ja fenoloogiast [On the ecology and phenology of the Cladocera of Estonia] – Hüdrobioloogilised uurimused [Hydrobiological research], 2: 108–158. (in Estonian).
• 35. Mäemets A. 1991 – Suurtaimestik kui järvede hindamise informatsiooniallikas [Macrophytes as information source about assessment of the lakes] (In: Inimene ja geograafiline keskkond [Man and geographical environment] – Tallinn, pp. 93–97. (in Estonian).
• 36. Ott I., Kõiv T. 1999 – Estonian Small Lakes: Special Features and Changes – Estonian Environment Information Centre, Tallinn, 128 pp.
• 37. Punning J.-M., Koff T., Martma T. 2000 - Stable isotope and pollen records in marl sections from some Estonian lakes and their palaeoclimatic interpretation. – Estonia. Geographical studies 8. Estonian Academy Publisher, Tallinn, pp. 20–34.
• 38. Punning J.-M., Koff T., Martma T., Possnert G. 2002 – Stable isotope and pollen stratigraphy in marl sediments from Lake Ilmjärv (central Estonia) – Proc. Estonian Acad. Sci. Geol., 51: 180–192.
• 39. Punning J.-M., Koff, T. Kadastik, E., Mikomägi, A. 2005 – Holocene lake level fluctuations recorded in the sediment composition of the small dimictic Lake Juusa (SE Estonia) – J. Paleolim., 34, 3: 377–390.
• 40. Punning J.-M., Puusepp L., Koff T. 2004 - The spatial variability of diatoms, subfossil macrophytes and OC/N values in surface sediments of Lake Väike-Juusa (southern Estonia) - Proc. Estonian Acad. Sci. Biol. Ecol., 53: 147–160.
• 41. Punning J.-M., Raukas A., Serebryannyi L., Stelle V. 1968 – Paleogeographic pecularities and absolute age of the Luga stadial of the Valdai glaciation on the Russian Plain - Proc. Acad. Sci. USSR Geol., 178: 916–918 (in Russian).
• 42. Rajamäe R., Punning J.-M. 1980. Some possibilities for the development of 14C measurements by liquid scintillation counting - Radiocarbon, 22: 435–441.
• 43. Raukas A., Saarse L., Veski S. 1995 – A new version of the Holocene stratigraphy in Estonia – Proc. Estonian Acad. Sci. Geol., 44: 201–210.
• 44. Reintam L. 1995 – Muldade kujunemine [Formation of the soils] (In: Eesti Loodus [Estonia Nature] Ed. A. Raukas) – Valgus, Eesti Entsüklopeediakirjastus, Tallinn, pp. 419–429. (in Estonian).
• 45. Røen U. 1995 – Krebsdyr V. Danmarks Fauna 85. – Dansk Naturhistorisk Forening, Copenhagen, 358 pp. (in Danish).
• 46. Saarse L., Poska A., Veski S. 1999 – Spread of Alnus and Picea in Estonia – Proc. Estonian Acad. Sci. Geol., 48: 170–186.
• 47. Sarmaja-Korjonen K. 2001 – Correlation of fluctuations in cladoceran planktonic/littoral ratio between three cores from a small lake in S. Finland – Holocene water-level changes - Holocene, 11: 53–63.
• 48. Sarmaja-Korjonen K. 2003 – Chydorid ephippia as indicators of environmental change – biostratigraphical evidence from two lakes in southern Finland – Holocene, 13: 691–700.
• 49. Sarmaja-Korjonen K., Alhonen P. 1999 - Cladoceran and diatom evidence of lakelevel fluctuations from a Finnish lake and the effect of aquatic moss layers on microfossil assemblages - J. Paleolim., 22: 277–290.
• 50. Sarmaja-Korjonen K., Hyvärinen H. 1999 – Cladoceran and diatom stratigraphy of calcareous lake sediments from Kuusamo, NE Finland. Indications of Holocene lake-level changes – Fennia, 177: 55–70.
• 51. Sarmaja-Korjonen K., Szeroczyńska K., Gąsiorowski M. 2003 – Subfossil chydorid taxa and assemblages from lake sediments in Poland and Finland with special reference to climate – Studia Quaternaria, 20: 25–34.
• 52. Talbot M. R. 1990 – A review of the paleohydrological interpretation of carbon and oxygen isotopic ratios in primary lacustrine carbonates - Chemical Geology, 80: 261–279.
• 53. Tarras-Wahlberg H., Everard M., Harper D. M. 2002 – Geochemical and physical characteristics of river and lake sediments at Naivasha, Kenya – Hydrobiologia, 488: 27–41.
• 54. Troels-Smith, J. 1955 – Karakterisering af løse jrdarter [Characterization of unconsolidated sediments] – Danm. Geol. Unders., IV 3: 1–73. (in Danish).
• 55. van Geel B. 2001 – Non-pollen palynomorphs (In: Tracking Environmental Change Using Lake Sediments. Vol.3: Terrestrial, Algal and Siliceous Indicators, Eds: J. P. Smol, H. J. B. Birks, W .M. Last) – Kluwer Academic Publishers, Dordrecht, pp. 99–119.
• 56. Wetzel R. G. 1983 – Limnology. Second edition - Saunders College Publishing, Philadephia, New York, Chicago, 767 pp.