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Item – Theses Canada
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Item – Theses Canada
OCLC number
1006741452
Link(s) to full text
LAC copy
LAC copy
Author
Meeuwig, Jessica J.(Jessica Jane),1966-
Title
All water is wet : predicting eutrophication in lakes and estuaries.
Degree
Ph. D. -- McGill University, 1999
Publisher
Ottawa : National Library of Canada = Bibliothèque nationale du Canada, [2001]
Description
4 microfiches
Notes
Includes bibliographical references.
Abstract
Coastal eutrophication, defined as an increase in algal biomass (as chlorophyll (Chl)) is of increasing international concern. Although coastal eutrophication will likely increase as coastal populations grow, few models exist to support its management. Lake eutrophication has also long been recognized as an important environmental concern. However, effective lake eutrophication management exists, supported by regression and mass-balance models. Traditionally, these "Vollenweider" models link land-use to Chl via total phosphorus (TP), the nutrient considered to be limiting Chl. However, based on a data set of 63 lakes, Chl was more accurately predicted by models based on land-use than by those based on TP. This result provided the rationale to build Chl:land-use models for estuaries where the Chl:nutrient relations are unclear. Chl:land-use models were developed for 15 estuaries in PEI, 19 estuaries in Finland and 26 US estuaries. Land-use models predicted Chl more accurately than TP in the US estuaries and in some of the Finnish estuaries. In the Finnish estuaries, Chl was best predicted by a land-use model in estuaries dominated by nonpoint source loading whereas Chl was most accurately predicted by the Vollenweider approach in estuaries dominated by point-source loading. In the PEI estuaries, the accuracy of the land-use model was comparable to the accuracy of the TP model. The PEI estuaries had much lower yields of Chl per unit nutrient than lakes suggesting differences among systems. This Chl deficit (expected-observed Chl) was accounted for by herbivory and turbidity, neither of which factors are exclusive to estuaries. The comparison of Chl response to nutrients and land-use across lakes and estuaries demonstrated no systematic differences as a function of tidal energy, openness or salinity. The regression models based on the combined data accurately predicted Chl as a function of TP and percentage of the catchment forested and mean depth. These results suggest that differences among systems are more likely a function of pan-system properties such as herbivory rather than the presence of a lake-estuary dialectic, and that limnological approaches can effectively be applied to estuaries to support efforts to manage coastal eutrophication.
ISBN
0612502201
9780612502208
Date modified:
2022-09-01