A hydrologic tracer study in a small, natural wetland in the humid tropics of Costa Rica

Growing populations and food demand in the tropics are leading to increased environmental pressures on wetland ecosystems, including a greater reliance on natural wetlands for water quality improvement. Effective assessment of wetland treatment potential requires an improved understanding of the hyd...

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Bibliographic Details
Published in:Wetlands ecology and management 2015-04, Vol.23 (2), p.167-182
Main Authors: Kaplan, D., Bachelin, M., Yu, C., Muñoz-Carpena, R., Potter, Thomas L., Rodriguez-Chacón, W.
Format: Article
Language:English
Subjects:
Aquatic ecosystems
Biogeochemistry
Biomedical and Life Sciences
Computational fluid dynamics
Conservation Biology/Ecology
Contaminants
Costa Rica
Ecological function
Ecosystems
Environmental Law/Policy/Ecojustice
Environmental services
Fluid flow
Freshwater & Marine Ecology
Heterogeneity
Hydraulics
Hydrology
Hydrology/Water Resources
Life Sciences
Management
Marine & Freshwater Sciences
Mathematical models
Original Paper
Pollutant removal
Tropical environments
Tropics
Water quality
Water Quality/Water Pollution
Wetlands
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Summary:Growing populations and food demand in the tropics are leading to increased environmental pressures on wetland ecosystems, including a greater reliance on natural wetlands for water quality improvement. Effective assessment of wetland treatment potential requires an improved understanding of the hydraulic and biogeochemical factors that govern contaminant behavior, however detailed studies of flow through natural, tropical wetlands are scarce. We performed a tracer study using a conservative salt (potassium bromide) to examine the hydraulic behavior of a small, natural wetland in the Costa Rican humid tropics and modeled observed breakthrough curves using the 1-D advection–dispersion equation. Velocities in the wetland were extremely slow, from less than 4 m day −1 to a maximum of ~30 m day −1 , and were distributed across several flowpaths, illustrating a spatial heterogeneity of flow and velocities. Modeled dispersion coefficients were also low (33 ± 33 m 2  day −1 ). Estimated residence times suggested high potential pollutant removal capacity over a range of influent concentrations, reinforcing the environmental services provided by this and other small tropical wetlands. The study also highlighted how small variations in wetland topography and vegetation yield strong differences in transport patterns that affect transport and mixing in densely vegetated, heterogeneous wetland systems. Empirical data on the hydraulics, and resulting ecosystem functions, of small, distributed wetlands may provide support for improved conservation and management of these important ecosystems.
ISSN:0923-4861
1572-9834
DOI:10.1007/s11273-014-9367-1