Abstract
Mean global air temperatures have steadily increased during recent decades, resulting in an earlier timing of lake ice breakup. In Sweden’s largest lakes, Vänern and Vättern, the breakup of ice has occurred considerably earlier since 1979 and ice-free winters have become more frequent. Comparison between the years when the lakes were ice covered with those when they remained ice-free in terms of 37 lake variables revealed significant differences in water temperatures, sulphate concentrations and the biomass of diatoms in May after ice breakup (P < 0.01). In particular, the biomass of the genus Aulacoseira increased significantly, which may explain increasing complaints about algae that clog fishing-nets, filter-beds and micro-strainers in waterworks in Vänern and Vättern. We assume that Aulacoseira is mainly affected by changes in climate-driven water circulation patterns. In contrast, other observed water quality changes such as changes in sulphate concentration might rather be attributed to changes in atmospheric deposition. To explain water quality changes in Sweden’s largest lakes it is important to consider changes in both climate and atmospheric deposition as well as catchment measures.
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References
Barica, J. & J. A. Mathias, 1979. Oxygen depletion and winterkill risk in small Prairie lakes under extended ice cover. Journal of Fisheries Research Board Canada 36: 980–986.
Eklund, A., 1999. Ice-on and ice-off in Swedish lakes. SMHI-Report Hydrologi 81 (in Swedish).
Forsius, M., J. Vuorenmaa, J. Mannio & S. Syri, 2003. Recovery from acidification of Finnish lakes: regional patterns and relations to emission reduction policy. Science of the Total Environment 310: 121–132.
Gerten, D. & R. Adrian, 2000. Climate-driven changes in spring plankton dynamics and the sensitivity of shallow polymictic lakes to the North Atlantic Oscillation. Limnology and Oceanography 45: 1058–1066.
Gerten, D. & R. Adrian, 2002. Effects of climate warming, North Atlantic Oscillation, and El Nino-Southern Oscillation on thermal conditions and plankton dynamics in northern hemispheric lakes. The Scientific World 2: 586–606.
Greenbank, J., 1945. Limnological conditions in ice-covered lakes, especially related to winterkill of fish. Ecological Monographs 15: 343–392.
Järvinen, M., M. Rask, J. Ruuhijärvi & L. Arvola, 2002. Temporal coherence in water temperature and chemistry under the ice of boreal lakes (Finland). Water Research 36: 3949–3956.
Johnson, R. K. & T. Wiederholm, 1992. Pelagic-benthic coupling — the importance of diatom interannual variability for population oscillations of Monoporeia affinis. Limnology and Oceanography 37: 1596–1607.
Kvarnäs, H., 2001. Morphometry and hydrology of the four large lakes of Sweden. Ambio 30: 467–474.
Leppäranta, M., A. Reinart, A. Erm, H. Arst, M. Hussainov & L. Sipelgas, 2003. Investigation of ice and water properties and under-ice light fields in fresh and brackish water bodies. Nordic Hydrology 34: 245–266.
Livingstone, D. M., 1993. Lake oxygenation: Application of a one-box model with ice cover. International Revue der gesamten Hydrobiologie 78: 465–480.
Livingstone, D. M., 1997. Break-up dates of alpine lakes as proxy data for local and regional mean surface air temperatures. Climatic Change 37: 407–439.
Lotter, A. F. & C. Bigler, 2000. Do diatoms in the Swiss Alps reflect the length of ice-cover? Aquatic Sciences 62:125–141.
Magnuson, J. J., D. M. Robertson, B. J. Benson, R. H. Wynne, D. M. Livingstone, T. Arai, R. A. Assel, R. G. Barry, V. Card, E. Kuusisto, N. G. Granin, T. D. Prowse, K. M. Stewart & V. S. Vuglinski, 2000. Historical trends in lake and river ice cover in the Northern Hemisphere. Science 289: 1743–1746.
Moldan, F., R. F. Wright, S. Löfgren, M. Forsius, T. Ruoho-Airola & B. L. Skjelkvale, 2001. Long-term changes in acidification and recovery at nine calibrated catchments in Norway, Sweden and Finland. Hydrology and Earth System Sciences 5: 339–349.
Palecki, M. A. & R. G. Barry, 1986. Freeze-up and break-up of lakes as an index of temperature changes during the transition seasons: A case study for Finland. Journal of Climate and Applied Meteorology 25: 893–902.
Phillips, K. A. & M. W. Fawley, 2002. Winter phytoplankton community structure in three shallow temperate lakes during ice cover. Hydrobiologia 470: 97–113.
Rice, W. R., 1989. Analyzing tables of statistical tests. Evolution 43: 223–225.
Rodhe, W., 1955. Can phytoplankton production proceed during winter darkness in subarctic lakes? Verhandlungen der Internationalen Vereinigung für Limnologie 12: 117–122.
Rummukainen, M., J. Räisänen, B. Bringfelt, A. Ullersti A. Omstedt, U. Willéen, U. Hansson & C. Jones, 2001. A regional climate model for northeastern Europe: model description and results from the downscaling of two GCM control simulations. Climate Dynamics 17: 339–359.
SAS Institute, 2002. JMP Statistics and graphics guide. Version 5, SAS Institute.
Stewart, K. M., 1976. Oxygen deficits, clarity and eutrophication in some Madison lakes. Internationale Revue der gesamten Hydrobiologie 61: 563–579.
Vavrus, S. J., R. H. Wynne & J. A. Foley, 1996. Measuring the sensitivity of southern Wisconsin lake ice to climate variations and lake depth using a numerical model. Limnology & Oceanography 41: 822–831.
Weyhenmeyer, G. A., 2001. Warmer winters — are planktonic algal populations in Sweden’s largest lakes affected? Ambio 30: 565–571.
Weyhenmeyer, G. A., 2004. Synchrony in relationships between the North Atlantic Oscillation and water chemistry among Sweden’s largest lakes. Limnology & Oceanography 49: 1191–1201.
Weyhenmeyer, G. A., T. Blenckner & K. Pettersson, 1999. Changes of the plankton spring outburst related to the North Atlantic Oscillation. Limnology & Oceanography 44: 1788–1792.
Weyhenmeyer, G. A., M. Meili & D. M. Livingstone, 2004. Nonlinear temperature response of lake ice breakup. Geophysical Research Letters 31: L07203, doi: 10.1029/2004GL019530.
Weyhenmeyer, G. A., M. Meili & D. M. Livingstone, 2005. Systematic differences in the trend towards earlier ice-out on Swedish lakes along a latitudinal temperature gradient. Verhandlungen der Internationalen Vereinigung der Limnologie 29: 257–260.
Wilander, A. & G. Persson, 2001. Recovery from eutrophication: Experiences of reduced phosphorus input to the four largest lakes of Sweden. Ambio 30: 475–485.
Willén, E., 1991. Planktonic diatoms — an ecological review. Algological Studies 62: 69–106.
Willén, E., 2001. Four decades of research on the Swedish large lakes Mälaren, Hjälmaren, Vättern and Vänern: The significance of monitoring and remedial measures for a sustainable society. Ambio 30 458–466.
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Weyhenmeyer, G.A., Westöö, AK., Willén, E. (2007). Increasingly ice-free winters and their effects on water quality in Sweden’s largest lakes. In: Nõges, T., et al. European Large Lakes Ecosystem changes and their ecological and socioeconomic impacts. Developments in Hydrobiology, vol 199. Springer, Dordrecht. https://doi.org/10.1007/978-1-4020-8379-2_13
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DOI: https://doi.org/10.1007/978-1-4020-8379-2_13
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