Abstract
A deterministic heat transport model was developed to calculate stream water temperatures downstream of reservoir outlets (tailwaters) and groundwater sources. The model calculates heat exchange between the atmosphere, the water and the sediments and is driven by climate and stream hydrologic parameters. Past and projected climate conditions were used as input to the stream water temperature model. To produce a projected future weather scenario, output from the Columbia University Goddard Institute for Space Studies (GISS) global circulation model (GCM) for a doubling of atmospheric CO2 were used to adjust past (1955–1979) weather parameters. Stream reach lengths, within which water temperatures are suitable for survival or good growth of 28 fish species, were determined for four selected streams. Several alternative upstream inflow conditions were chosen: Discharges from surface (epilimnion) and bottom (hypolimnion) outlets of reservoirs, and two groundwater inflow scenarios. By applying water temperature criteria for fish survival and good growth (Stefanet al., 1993) to simulated stream temperatures, it was possible to estimate stream lengths with suitable habitat. When simulated suitable habitat was compared to actual fish observations, good agreement was found. For projected climate change, the simulations showed how much of the available stream habitat would be lost. In the examples presented the effect of cold hypolimnetic water release from a reservoir or groundwater discharges is felt as far as 48 km (30 miles) downstream from its source, especially in smaller shaded streams. The impact of climate change on stream temperatures below dams is more pronounced when the water release is from the epilimnion (reservoir surface) rather than the hypolimnion (deep water). Examples used for this study show elimination of coldwater habitat for rainbow trout when the upstream release is from the surface of a reservoir, but only reductions of coldwater habitat when the upstream release is from a reservoir hypolimnion.
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References
Baker, D. G. and Ruschy, D. L.: 1993, ‘The Recent Warming in Eastern Minnesota Shown by Groundwater Temperatures’,Geophys. Res. Lett. AGU 20, No. 5, 371–374.
Benson, N. G.: 1953, ‘The Importance of Groundwater to Trout Populations in the Pigeon River, Michigan’,Trans. N. Am. Wildl. Nat. Resourc. Conf., 258–281.
Brocard, D. N. and Harleman, D. R. F.: 1976, ‘One-Dimensional Temperature Predictions in Unsteady Flow’,J. Hydraul. Div., ASCE 102, 227–240.
Brown, G. W.: 1969, ‘Predicting Temperatures of Small Streams’,Water Resourc. Res. 5, No. 1.
Collins, W. D.: 1925, ‘Temperature of Water Available for Industrial Use in the United States’, United States Geological Survey Water Supply Paper 520-F.
Eaton, J. G., McCormick, J. H., Goodno, B. E., O'Brien, D. G., Stefan, H. G., and Hondzo, M.: 1995, ‘A Field Information Based System for Estimating Fish Temperature Requirements’,Fisheries 20, No. 4, April.
Edinger, J. E., Duttweiler, D. W., and Geyer, J. G.: 1968, ‘The Response of Water Temperatures to Meteorological Conditions’,Water Resourc. Res. 4, No. 5.
Heath, R. C.: 1964, ‘Seasonal Temperature Fluctuations in Surficial Sand near Albany, New York’, United States Geological Survey Professional Paper 475-D.
Hondzo, M. and Stefan, H. G.: 1993, ‘Regional Water Temperature Characteristics of Lakes Subjected to Climate Change’,Clim. Change 24, 187–211.
Jobson, H. E.: 1973, ‘The Dissipation of Excess Heat from Water Systems’,J. Power Div., ASCE 99, No. P01.
Jobson, H. E.: 1977, ‘Bed Conduction Computation for Thermal Models’,J. Hydraul. Div., ASCE 103, No. HY10.
Mathess, G.: 1982,The Properties of Groundwater, John Wiley and Sons, New York, NY.
Meisner, J. D.: 1990, ‘Potential Loss of Thermal Habitat for Brook Trout, due to Climate Warming, in Two Southern Ontario Streams’,Trans. Am. Fish. Soc. 119, 282–291.
Meisner, J. D., Rosenfeld, J. S., and Regier, H. A.: 1988, ‘The Role of Groundwater in the Impact of Climate Warming on Stream Salmonides’,Trans. Am. Fish. Soc. 13, No. 3.
Needham, P. R. and Jones, R. C.: 1959, ‘Flow Temperature, Solar Radiation, and Ice in Relation to Activities of Fishes in Sagehen Creek’,Ecology 40.
Raphael, J. M.: 1962, ‘Prediction of Temperature in Rivers and Reservoirs’,Power Div., ASCE 88, No. PO2.
Poff, N. L. and Allan, J. D.: 1993,Stream Variability Structure, and Implications for Climatic Change, Project Report to USEPA/Environmental Research Laboratory-Duluth, MN 55804 (J. D. Yount, project officer), Proj. CR-816540010, 202 pp.
Schneider, S. H.: 1989, ‘The Greenhouse Effect: Science and Policy’,Science 243, No. 10, 771–781.
Sinokrot, B. A. and Stefan, H. G.: 1992,Projected Global Climate Change Effects on Regional Stream Water Temperatures and Implications for Fish, University of Minnesota, St. Anthony Falls Hydraulic Laboratory. Minneapolis, MN 55414. Report No. 337.
Sinokrot, B. A. and Stefan, H. G.: 1993, ‘Stream Temperature Dynamics: Measurements and Modeling’,Water Resourc. Res. 29, No. 7.
Stark, J. R.: 1989,Written Communications, U.S. Geological Survey St. Paul District, St. Paul, MN.
Stefan, H. G., Gulliver, J., Hahn, M. G., and Fu, A. Y.: 1980,Water Temperature Dynamics in Experimental Field Channels: Analysis and Modeling, University of Minnesota, St. Anthony Falls Hydraulic Laboratory Report No. 193.
Stefan, H. G., Hondzo, M., Sinokrot, B. A., and Fang, X.: 1992, ‘A Methodology to Estimate Global Climate Change Impacts on Lake and Stream Environmental Conditions and Fishery Resources with Application to Minnesota’, University of Minnesota, St. Anthony Falls Hydraulic Laboratory Report No. 323.
Stefan, H. G. and Sinokrot, B. A.: 1993, ‘Projected Global Climate Change Impacts on Water Temperatures in Five Northern Central US Streams’,Clim. Change 24, 353–381.
Todd, D. K.: 1980,Groundwater Hydrology, 2nd Ed., John Wiley and Sons, New York, Chichester, Toronto, ON.
Ward, J. V.: 1985, ‘Thermal Characteristics of Running Water’,Hydrobiologia 125.
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Sinokrot, B.A., Stefan, H.G., McCormick, J.H. et al. Modeling of climate change effects on stream temperatures and fish habitats below dams and near groundwater inputs. Climatic Change 30, 181–200 (1995). https://doi.org/10.1007/BF01091841
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DOI: https://doi.org/10.1007/BF01091841