Stochastic modeling of wetland-groundwater systems

•Coupled temporal dynamics of wetlands and groundwater under stochastic hydroclimatic forcing are examined.•Analytical pdfs and mean crossing times are used to investigate wetland hydrologic temporal variability.•Few scaled physically-based parameters govern stage/volume temporal dynamics.•Analytica...

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Vydáno v:Advances in water resources Ročník 112; s. 214 - 223
Hlavní autoři: Bertassello, Leonardo Enrico, Rao, P. Suresh C., Park, Jeryang, Jawitz, James W., Botter, Gianluca
Médium: Journal Article
Jazyk:angličtina
Vydáno: Oxford Elsevier Ltd 01.02.2018
Elsevier Science Ltd
Témata:
Bathymetry
Case studies
climate
Climatic conditions
Crossing time
Data processing
Dependence
Dynamics
Eco-hydrology
Florida
Groundwater
Groundwater data
Hydro-period
Hydrologic regimes
Hydrology
Infiltration
Modelling
Probability density function
Probability density functions
probability distribution
Probability theory
Sensitivity analysis
Stochastic models
stochastic processes
water resources
Water storage
Wetlands
Florida
United States > US
Probability density function
Hydro-period
Hydrologic regimes
Crossing time
Eco-hydrology
ISSN:0309-1708, 1872-9657
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Shrnutí:•Coupled temporal dynamics of wetlands and groundwater under stochastic hydroclimatic forcing are examined.•Analytical pdfs and mean crossing times are used to investigate wetland hydrologic temporal variability.•Few scaled physically-based parameters govern stage/volume temporal dynamics.•Analytical pdf models are compared with observational data from two case studies. Modeling and data analyses were used in this study to examine the temporal hydrological variability in geographically isolated wetlands (GIWs), as influenced by hydrologic connectivity to shallow groundwater, wetland bathymetry, and subject to stochastic hydro-climatic forcing. We examined the general case of GIWs coupled to shallow groundwater through exfiltration or infiltration across wetland bottom. We also examined limiting case with the wetland stage as the local expression of the shallow groundwater. We derive analytical expressions for the steady-state probability density functions (pdfs) for wetland water storage and stage using few, scaled, physically-based parameters. In addition, we analyze the hydrologic crossing time properties of wetland stage, and the dependence of the mean hydroperiod on climatic and wetland morphologic attributes. Our analyses show that it is crucial to account for shallow groundwater connectivity to fully understand the hydrologic dynamics in wetlands. The application of the model to two different case studies in Florida, jointly with a detailed sensitivity analysis, allowed us to identify the main drivers of hydrologic dynamics in GIWs under different climate and morphologic conditions.
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ISSN:0309-1708
1872-9657
DOI:10.1016/j.advwatres.2017.12.007