Abstract
We assessed effects of groundwater pumping to elevate lake levels on lake water chemistry and fish population metrics at seven Florida lakes. Following groundwater pumping, lake level fluctuation was reduced and lake water samples increased in mean pH, total alkalinity, total phosphorus, chloride and Secchi depth compared to historical means, indicating a close resemblance to the chemistry of aquifer water in the region. Fish community metrics from the augmented lakes were compared to 36 non-augmented lakes in Florida. The mean values for catch per unit effort, species richness and biomass of harvestable fishes, determined by electrofishing, were lower in augmented lakes compared to non-augmented lakes. Canonical correspondence analysis (CCA) indicated a high probability of a low abundance of individual species in augmented lakes compared to a majority of non-augmented lakes. The augmented lake with the lowest pumping rate exhibited less of a shift in limnological variables from historical values, and had fish population characteristics more closely resembling those of non-augmented lakes. Thus, reduced volumes of groundwater introduction could lower impacts to limnological and fish population characteristics. Augmentation allows for lakes to be utilized for recreational activities, and without augmentation some lakes in central Florida would likely go dry due to groundwater withdrawals for water supply. Therefore, allowing more natural water level fluctuations and possible reductions in total pumpage are recommended to reduce impacts to limnological and fish population characteristics, while still allowing sufficient groundwater pumping to preserve lake habitats.
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References
M. S. Allen (1999) Assessment of Fish Assemblages in Lakes Dosson, Halfmoon and Round in Hillsborough County, Florida Southwest Florida Water Management District Brooksville
American Public Health Association (APHA), 1989. Standard Methods for the Examination of Water and Waste Water (17th edn). New York.
R. W. Bachmann B. L. Jones D. D. Fox M. Hoyer L. A. Bull D. E. Canfield SuffixJr. (1996) ArticleTitleRelations between trophic state indicators and fish in Florida (USA) Lakes Canadian Journal of Fisheries and Aquatic Sciences 53 842–855 Occurrence Handle10.1139/cjfas-53-4-842
R. W. Bachmann C. A. Horsburgh M. V. Hoyer L. K. Mataraza D. E. Canfield SuffixJr. (2002) ArticleTitleRelations between trophic state indicators and plant biomass in Florida lakes Hydrobiologia 470 219–234 Occurrence Handle10.1023/A:1015660922494
C. D. Barbour J. H. Brown (1974) ArticleTitleFish species diversity in lakes American Naturalist 108 IssueID962 473–489 Occurrence Handle10.1086/282927
Bartos, L. F., 1998. Environmental augmentation. The resource regulation newsletter. Southwest Florida Water Management District 10(3). Brooksville.
T. V. Belanger R. A. Kirkner (1994) ArticleTitleGroundwater/surface water interaction in a Florida augmentation lake Lake and Reservoir Management 8 165–174 Occurrence Handle10.1080/07438149409354468
InstitutionalAuthorNameBiological Research Associates (BRA) (1982) Ecological Impact of Augmentation in Three Lakes in Hillsborough County, Florida Pinellas County Water System Tampa
Biological Research Associates (BRA), 1996. General limnological assessment of three augmented lakes in Northwest Hillsborough County, Florida. Pinellas County Water System, Clearwater.
InstitutionalAuthorNameBiological Research Associates (BRA) (2001) Mountain Lake Limnological Evaluation and Lake Management Alternatives Mountain Lake Corporation Lake Wales, Florida
T. F. Bonvechio M. S. Allen (2005) ArticleTitleRelations between hydrological variables and year-class strength of sportfish in eight Florida waterbodies Hydrobiologia 532 193–207 Occurrence Handle10.1007/s10750-004-1388-y
D. E. Canfield SuffixJr. M. V. Hoyer (1990) A characterization of fish populations in two central Florida Lakes Florida Turfgrass Association Gainesville
D. E. Canfield SuffixJr. M. V. Hoyer (1992) Aquatic macrophytes and their relation to the limnology of Florida lakes Florida Department of Natural Resources Tallahassee
I. G. Cowx (2000) ArticleTitlePotential impact of groundwater augmentation of river flows on fisheries: A case study from the River Ouse, Yorkshire, UK Fisheries Management and Ecology 7 85–96
W. G. Crumpton T. M. Isenhart P. D. Mitchell (1992) ArticleTitleNitrate and organic N analysis with second-derivative spectroscopy Limnology and Oceanography 37 907–913 Occurrence Handle1:CAS:528:DyaK38XmsFOrs74%3D Occurrence Handle10.4319/lo.1992.37.4.0907
C. F. D’Elia P. A. Steudler N. Corwin (1977) ArticleTitleDetermination of total nitrogen in aqueous samples using persulfate digestion Limnology and Oceanography 22 760–764 Occurrence Handle1:CAS:528:DyaE2sXlslamtbc%3D
Dooris, P. M., 1982. Lake Augmentation in Northwest Hillsborough County. Technical Report of the Southwest Florida Water Management District, Brooksville.
P. M. Dooris D. F. Martin (1979) ArticleTitleGroundwater induced changes in lake chemistry Ground Water 17 324–327 Occurrence Handle1:CAS:528:DyaE1MXls1aktr4%3D
P. M. Dooris G. M. Dooris D. F. Martin (1982) ArticleTitlePhytoplankton responses to ground water addition in central Florida Lakes Water Resources Bulletin 18 335–337
S. Engel M. H. Hoff M. T. Vogelsang SuffixJr. K. E. Bass J. S. Anderson (2000) Fish Population Dynamics in Max Lake, a Softwater Wisconsin Lake Subject to Ground-Water Pumping Wisconsin Department of Natural Resources Research Report Woodruff
Florida Lakewatch, 2000. A beginner’s guide to water management – nutrients. Information circular #102. Department of Fisheries and Aquatic Sciences, University of Florida, Gainesville.
C. Forsberg S. O. Ryding (1980) ArticleTitleEutrophication parameters and trophic state indices in 30 Swedish waste-receiving lakes Archive fur Hydrobiologie 88 189–207
Hach Chemical Company, 1975. Water and wastewater analysis procedures, 3rd edn. Ames, Iowa.
Hassell, A. L., 1994. A chemical and biochemical characterization of lakes Cooper, Strawberry, Crystal, Hobbs, Starvation, and Saddleback in Hillsborough County (Florida). Master’s thesis submitted to the Department of Chemistry at the University of South Florida, Tampa.
A. L. Hassell P. M. Dooris D. F. Martin (1997) ArticleTitleMaucha diagrams and chemical analyses to diagnose changes in lake chemistry Environmental Chemistry 60 75–80 Occurrence Handle1:CAS:528:DyaK2sXjtlOgtrY%3D
S. G. Hinch N. C. Collins (1993) ArticleTitleRelationships of littoral fish abundance to water chemistry and macrophyte variables in central Ontario lakes Canadian Journal of Fisheries and Aquatic Sciences 50 1870–1878
A. E. Kellar T. L. Crisman (1990) ArticleTitleFactors influencing fish assemblages and species richness in subtropical Florida lakes and a comparison with temperate lakes Canadian Journal of Fisheries and Aquatic Sciences 47 2137–2146
C. J. Krebs (1999) Ecological Methodology EditionNumber2 Benjamin Cummings Menlo Park, California
M.J. Maceina J.V. Shireman (1980) ArticleTitleThe use of a recording fathometer for determination of distribution and biomass of Hydrilla Journal of Aquatic Plant Management 18 34–39
D. F. Martin D. M. Victor P. M. Dooris (1976a) ArticleTitleEffects of artificially introduced ground water on the chemical and biochemical characteristics of six Hillsborough County (Florida) Lakes Water Research 10 65–69 Occurrence Handle1:CAS:528:DyaE28Xks1OqtrY%3D Occurrence Handle10.1016/0043-1354(76)90159-7
D. F. Martin D. M. Victor P. M. Dooris (1976b) ArticleTitleImplications of lake augmentation on Hydrilla growth Environmental Science Engineering A11 245–253 Occurrence Handle1:CAS:528:DyaE28XlsVyktb0%3D
J. E. Matuszek G. L. Beggs (1988) ArticleTitleFish species richness in relation to lake area, pH, and other abiotic factors on Ontario lakes Canadian Journal of Fisheries and Aquatic Sciences 45 1931–1941 Occurrence Handle10.1139/f88-225
D. M. McKinsey L. J. Chapman (1998) ArticleTitleDissolved oxygen and fish distribution in a Florida spring Environmental Biology of Fishes 53 211–223 Occurrence Handle10.1023/A:1007497503542
D. W. Menzel N. Corwin (1965) ArticleTitleThe measurement of total phosphorus in seawater based on the liberation of organically bound fractions of persulfate oxidation Limnology and Oceanography 10 280–282 Occurrence Handle10.4319/lo.1965.10.2.0280
J. Murphy J. P. Riley (1962) ArticleTitleA modified single solution method for the determination of phosphate in natural waters Analytica Chimica Acta 27 31–36 Occurrence Handle1:CAS:528:DyaF38XksVyntr8%3D Occurrence Handle10.1016/S0003-2670(00)88444-5
M. W. Palmer (1993) ArticleTitlePutting things in even better order: The advantages of canonical correspondence analysis Ecology 74 IssueID8 2215–2230
PC-ORD., 1999. Multivariate analysis of ecological data, version 4. MjM Software Design, Gleneden Beach, Oregon.
J. B. Reynolds (1996) Electrofishing B. R. Murphy D. W. Willis (Eds) Fisheries Techniques EditionNumber2 American Fisheries Society Bethesda, Maryland 221–253
D. P. Sartory J. U. Grobbelaar (1984) ArticleTitleExtraction of chlorophyll a from freshwater phytoplankton for spectrophotometric analysis Hydrobiologia 114 177–187 Occurrence Handle1:CAS:528:DyaL2cXlvVOgs7k%3D
InstitutionalAuthorNameStatistical Analysis Systems (SAS) (1996) SAS statistics user’s guide SAS Institute, Inc. Cary, North Carolina
J. Simal M. A. Lage I. Iglesias (1985) ArticleTitleSecond derivative ultraviolet spectroscopy and sulfamic acid method for determination of nitrates in water Journal – Association of Official Analytical Chemists 68 962–964 Occurrence Handle1:CAS:528:DyaL2MXls1Grsrw%3D
Sinclair, W. C., 1977. Experimental study of artificial recharge alternatives in Northwest Hillsborough County, Florida United States Geological Survey: Water-Resources Investigations 77–13.
J. W. Stewart (1968) Hydrologic Effects of Pumping from the Floridan Aquifer in Northwest Hillsborough, Northeast Pinellas, and Southwest Pasco Counties, Florida United States Geological Survey Tallahassee
Stewart, J. W. & G. H. Hughes, 1974. Hydrologic consequences of using groundwater to maintain lake levels affected by water wells near Tampa, Florida. Florida Department of Natural Resources, Tallahassee.
Southwest Florida Water Management District (SWFWMD), 1998. Water supply assessment 1995–2020. Resource Projects Department, Southwest Florida Water Management District, Brooksville.
C. J. F. Ter Braak (1986) ArticleTitleCanonical correspondence analysis: A new eigenvector technique for multivariate direct gradient analysis Ecology 67 IssueID5 1167–1179
K. M. Wollin (1987) ArticleTitleNitrate determination in surface waters as an example of the application of UV derivative spectrometry to environmental analysis Acta Hydrochemica Hydrobiologia 15 459–469 Occurrence Handle1:CAS:528:DyaL2sXmsVahur0%3D
J. H. Zarr (1999) Biostatistical Analysis EditionNumber4 Prentice-Hall Upper Saddle River, New Jersey
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Cooney, P.B., Allen, M.S. Effects of Introduced Groundwater on Water Chemistry and Fish Assemblages in Central Florida Lakes. Hydrobiologia 556, 279–294 (2006). https://doi.org/10.1007/s10750-005-0936-4
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DOI: https://doi.org/10.1007/s10750-005-0936-4