Lake hydrodynamics intensify the potential impact of watershed pollutants on coastal ecosystem services

Watersheds deliver numerous pollutants to the coastline of oceans and lakes, thereby jeopardizing ecosystem services. Regulatory frameworks for stressors often focus on loading rates without accounting for the physical dynamics of the receiving water body. Here, we use a three-dimensional hydrodynam...

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Bibliographic Details
Published in:Environmental research letters 2020-06, Vol.15 (6), p.64028
Main Authors: Gloege, Lucas, McKinley, Galen A, Mooney, Robert J, Allan, J David, Diebel, Matthew W, McIntyre, Peter B
Format: Article
Language:English
Subjects:
Anthropogenic factors
Aquatic ecosystems
Coastal ecosystems
Coastal waters
Computational fluid dynamics
Ecosystem services
Ecosystems
Environmental impact
eutrophication
Fluid flow
Fluid mechanics
Great Lakes
Human influences
Hydrodynamics
Information processing
Lake Michigan
Lakes
Loading rate
Marine ecosystems
Marine pollution
Nonpoint source pollution
nutrient loading
Oceans
Plumes
Point source pollution
Pollutants
Pollution dispersion
Pollution load
Pollution sources
Receiving waters
Rivers
Shorelines
Simulation
Sustainable use
Three dimensional models
TMDL
total maximum daily load
Water bodies
Watersheds
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Summary:Watersheds deliver numerous pollutants to the coastline of oceans and lakes, thereby jeopardizing ecosystem services. Regulatory frameworks for stressors often focus on loading rates without accounting for the physical dynamics of the receiving water body. Here, we use a three-dimensional hydrodynamic model to simulate the transport of a generic tributary-delivered anthropogenic pollutant within Lake Michigan based on the location and timing of loading. Simulating pollutant plumes from 11 rivers, and their intersections with coastal ecosystem services, reveals strong mediation of potential impacts by lake physics. Trapped pollutants accumulate in nearshore waters during spring peak flows, and become diluted by spreading offshore during the summer. The threat to coastal ecosystem services posed by pollutant loading differs sharply among rivers; high potential impact arises from the spatiotemporal coincidence of tributary input rates, lake mixing dynamics, and multiple human uses of the shoreline. Simultaneous pollution from multiple rivers yields overlapping plumes, creating a second way in which lake hydrodynamics can amplify potential impacts on coastal ecosystem services. Our simulations demonstrate that the physical dynamics of large water bodies can create a dynamic stressor landscape arising from multiple independent sources of non-point-source pollution. The design and implementation of pollution regulations rarely account for spatial and temporal complexities of load processing in receiving waters, yet the resulting variability is likely to strongly mediate impacts on society. As hydrodynamic models improve, our analytical framework could be applied to a wide range of pollutants and waterbodies to enhance the sustainable use of coastal ecosystems.
ISSN:1748-9326
1748-9326
DOI:10.1088/1748-9326/ab7f62