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Exploring the effects of multiple management objectives and exotic species on great lakes food webs and contaminant dynamics

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Abstract

A simulation model was developed to describe linkages among fish food web, nutrient cycling, and contaminant processes in the southern basin of Lake Michigan. The model was used to examine possible effects of management actions and an exotic zooplankter (Bythotrephes) on Lake Michigan food web and contaminant dynamics. The model predicts that contaminant concentrations in salmonines will decrease by nearly 20% ifBythotrephes successfully establishes itself in the lake. The model suggests that this decrease will result from lowered transfer efficiencies within the food web and increased flux of contaminants to the hypolimnion. The model also indicates that phosphorus management will have little effect on contaminant concentrations in salmonines. The modeling exercise helped identify weaknesses in the data base (e.g., incomplete information on contaminant loadings and on the biomass, production, and ecological efficiencies of dominant organisms) that should be corrected in order to make reliable management decisions.

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Authors and Affiliations

  1. NOAA-Great Lakes Environmental Research Laboratory, 2205 Commonwealth Blvd., 48105, Ann Arbor, Michigan, USA

    Thomas D. Fontaine (Director)

  2. SUNY College of Environmental Science and Forestry, 13210, Syracuse, New York, USA

    Donald J. Stewart

  3. SUNY College at Oswego, 13126, Oswego, New York, USA

    Donald J. Stewart

Authors
  1. Thomas D. Fontaine
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  2. Donald J. Stewart
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Fontaine, T.D., Stewart, D.J. Exploring the effects of multiple management objectives and exotic species on great lakes food webs and contaminant dynamics. Environmental Management 16, 225–229 (1992). https://doi.org/10.1007/BF02393827

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  • DOI: https://doi.org/10.1007/BF02393827

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