Dataset Identification:
Resource Abstract:
- description: One of the most apparent effects of climate-change is sea-level rise. Analyses of mean sea elevation and topography
can produce maps of shoreline changes, but the climatic fluctuations and structural operations superimposed on the sea-level
rise create dynamic and temporal effects. In order to study scenarios related to sea-level rise in south Florida, we propose
the use of currently developed dynamic models of surface-water/ground-water flow to simulate varying levels of mean tidal-level
increase with tidal and atmospheric fluctuations. The changes in inundation hydroperiod, salinity in urban and natural areas,
and aquifer salinity intrusion can all be simulated in the Flow and Transport in a Linked Overland/Aquifer Density-Dependent
System (FTLOADDS) model. Due to the model capability for simulating dynamic events for a multi-year timescale, the simulations
will provide more information than map-based approaches. FTLOADDS is a combination of two pre-existing codes, namely, the
SWIFT2D two-dimensional hydrodynamic surface-water model code and the SEAWAT three-dimensional ground-water model code (Langevin
and others, 2005). SWIFT2D computes vertically-integrated flow by solving the St. Venant equations in two dimensions. Additionally,
SWIFT2D computes reactive constituent transport, density variations effects, drying and rewetting of periodically inundated
areas, and hydraulic structures (Schaffranek 2004). SEAWAT is a combination of the commonly used ground-water model code MODFLOW
and the solute-transport code MT3DMS (Guo and Langevin 2002). FTLOADDS therefore has the ability to simulate salinity transport
in two dimensions for surface water and three dimensions for ground water. SWIFT2D and SEAWAT operate independently within
FTLOADDS, with the exception of the leakage and salinity fluxes passed between the surface water and ground water. FTLOADDS
has been enhanced to represent heat-transport in the surface water linked to evapotranspiration effects (Swain and Decker,
2008). Applications of FTLOADDS to southern Florida coastal areas provide a comprehensive framework for predicting hydrologic
changes (Swain and others, 2003). Applications in the area include: 1) The Tides and Inflows in the Mangrove Everglades (TIME)
application in the Everglades National Park area (Wang and others, 2007); 2) The Ten-Thousand Islands (TTI) application between
Everglades National Park and Naples; and 3) The Biscayne application from Biscayne Bay inland to the L-31N levee. The model-domain
locations are shown in figure 1. The TIME application is used to evaluate CERP restoration scenarios by using output from
the SFWMD regional 2x2 model and the TTI application yield information on manatee habitats. The TIME and Biscayne applications
have been combined to produce the BIscayne/South-East Coastal Transport (BISECT) application. This tool has been used to develop
a series of hindcast and futurecast simulations that can be used to examine landscape and topography changes, sea-level rise
effects, precipitation changes, and ternperature changes. The modeling application to the Ten Thousand Islands (TTI) area
required a smaller-scale application to the Port of the Islands marina that can represent vertical stratification in salinity
and temperature. The Environmental Fluid Dynamics Code (EFDC) was applied for this purpose and used boundary conditions from
the TTI model to represent existing and restoration conditions. The implementation of heat-transport in a wetland environment
requires a number of heat-budget parameters that have not been well defined for the South Florida environment such as soil
heat storage and albedo. Physical experiments are required to define these factors and improve the numerical model.; abstract:
One of the most apparent effects of climate-change is sea-level rise. Analyses of mean sea elevation and topography can produce
maps of shoreline changes, but the climatic fluctuations and structural operations superimposed on the sea-level rise create
dynamic and temporal effects. In order to study scenarios related to sea-level rise in south Florida, we propose the use of
currently developed dynamic models of surface-water/ground-water flow to simulate varying levels of mean tidal-level increase
with tidal and atmospheric fluctuations. The changes in inundation hydroperiod, salinity in urban and natural areas, and aquifer
salinity intrusion can all be simulated in the Flow and Transport in a Linked Overland/Aquifer Density-Dependent System (FTLOADDS)
model. Due to the model capability for simulating dynamic events for a multi-year timescale, the simulations will provide
more information than map-based approaches. FTLOADDS is a combination of two pre-existing codes, namely, the SWIFT2D two-dimensional
hydrodynamic surface-water model code and the SEAWAT three-dimensional ground-water model code (Langevin and others, 2005).
SWIFT2D computes vertically-integrated flow by solving the St. Venant equations in two dimensions. Additionally, SWIFT2D computes
reactive constituent transport, density variations effects, drying and rewetting of periodically inundated areas, and hydraulic
structures (Schaffranek 2004). SEAWAT is a combination of the commonly used ground-water model code MODFLOW and the solute-transport
code MT3DMS (Guo and Langevin 2002). FTLOADDS therefore has the ability to simulate salinity transport in two dimensions for
surface water and three dimensions for ground water. SWIFT2D and SEAWAT operate independently within FTLOADDS, with the exception
of the leakage and salinity fluxes passed between the surface water and ground water. FTLOADDS has been enhanced to represent
heat-transport in the surface water linked to evapotranspiration effects (Swain and Decker, 2008). Applications of FTLOADDS
to southern Florida coastal areas provide a comprehensive framework for predicting hydrologic changes (Swain and others, 2003).
Applications in the area include: 1) The Tides and Inflows in the Mangrove Everglades (TIME) application in the Everglades
National Park area (Wang and others, 2007); 2) The Ten-Thousand Islands (TTI) application between Everglades National Park
and Naples; and 3) The Biscayne application from Biscayne Bay inland to the L-31N levee. The model-domain locations are shown
in figure 1. The TIME application is used to evaluate CERP restoration scenarios by using output from the SFWMD regional 2x2
model and the TTI application yield information on manatee habitats. The TIME and Biscayne applications have been combined
to produce the BIscayne/South-East Coastal Transport (BISECT) application. This tool has been used to develop a series of
hindcast and futurecast simulations that can be used to examine landscape and topography changes, sea-level rise effects,
precipitation changes, and ternperature changes. The modeling application to the Ten Thousand Islands (TTI) area required
a smaller-scale application to the Port of the Islands marina that can represent vertical stratification in salinity and temperature.
The Environmental Fluid Dynamics Code (EFDC) was applied for this purpose and used boundary conditions from the TTI model
to represent existing and restoration conditions. The implementation of heat-transport in a wetland environment requires a
number of heat-budget parameters that have not been well defined for the South Florida environment such as soil heat storage
and albedo. Physical experiments are required to define these factors and improve the numerical model.
Citation
- Title Development of Ecosystem Restoration and Sea-Level Rise Scenario Simulations for the Greater Everglades using the FTLOADDS
Code.
-
- creation Date
2017-12-12T06:48:10.419658
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Metadata data stamp:
2018-08-06T23:55:06Z
Resource Maintenance Information
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- notes: This metadata record was generated by an xslt transformation from a dc metadata record; Transform by Stephen M. Richard, based
on a transform by Damian Ulbricht. Run on 2018-08-06T23:55:06Z
Metadata contact
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pointOfContact
- organisation Name
CINERGI Metadata catalog
-
- Contact information
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- Address
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- electronic Mail Address cinergi@sdsc.edu
Metadata language
eng
Metadata character set encoding:
utf8
Metadata standard for this record:
ISO 19139 Geographic Information - Metadata - Implementation Specification
standard version:
2007
Metadata record identifier:
urn:dciso:metadataabout:863909f1-9e4b-401f-a960-cec0b44f39df
Metadata record format is ISO19139 XML (MD_Metadata)