Return to Wildland Fire
Return to Northern Bobwhite site
Return to Working Lands for Wildlife site
Return to Working Lands for Wildlife site
Return to SE Firemap
Return to the Landscape Partnership Literature Gateway Website
return
return to main site

Skip to content. | Skip to navigation

Sections

Personal tools

You are here: Home / Projects / LP Coastal Resiliency / Salt marsh modeling coupled with hydrodynamic modeling

Salt marsh modeling coupled with hydrodynamic modeling

Marsh modeling Hydro-MEM

Combining marsh equilibrium modeling approach with a hydrodynamic modeling approach, this coupled model forecasts the evolution of marsh landscapes under different sea-level rise scenarios, with or without marsh restoration and storm surge factored in, to inform future management decisions with regard to system dynamics.

Part of the suite of North Atlantic LCC Hurricane Sandy Marsh resilience projects, this cooperative agreement focused on increasing understanding of how marshes across a range of conditions in the Northeast are likely to respond to sea level rise and storms.  Researchers parameterized coupled marsh and hydrodynamic models for estuaries in the Northeast affected by Hurricane Sandy. In 2015, the model was applied to the Plum Island Sound in Massachusetts. In the second year of the project, the Hydro-MEM model was applied to the Edwin B. Forsythe National Wildlife Refuge, in coastal New Jersey, the John H. Chafee National Wildlife Refuge, in Rhode Island, and the back barrier marsh complexes from the inlet of Chesapeake Bay to Ocean City Maryland, including the Assateague Island National Seashore in Maryland and the Chincoteague National Wildlife Refuge.

The objective of this project was to forecast the evolution of marsh landscapes under different sea-level rise scenarios with and without marsh restoration and added storm-surge modeling.

Available Products & Tools:

A. A coupled biological-hydrodynamic model (Hydro-MEM) that is parameterized for Plum Island estuary to forecast marsh responses to sea-level rise and forecast storm surge with sea-level rise and with altered marsh landscapes. Modeled spatial data outputs will be at a resolution that can be input by larger project partners in decision support tools.

B. Integrated Hydro-MEM models for other Northeast estuaries representing a range of geography, estuary type, tidal range, sediment budget and other factors and with spatial data outputs at a resolution that can be input by larger project partners in decision support tools.

C. Final summary and report on model results including recommendations for next steps to apply across the region.

 

LCC Staff Contact: , Science Coordinator

Additional data collection for specific sites to be modeled under this project has taken place in the summer and fall of 2015.  Dr. Katherine Renken is collating extensive existing data for the Plum Island ecosystem for the first MEM/ADCIRC application under this cooperative agreement.

Progress Reports

University of South Carolina progress reports: 1st Qtr 2015; July-December 2015; January-June 2016


Hurricane Sandy Disaster Mitigation Funds

Hurricane Sandy affected region (Maine to Virginia)

See links to presentations by project principal investigators Jim Morris and Scott Hagen at the first North Atlantic Tidal Marsh Resilience workshop in Hadley, MA in December 2014.

Read a case study about how the Hydro-MEM model has been applied by partners working to protect the Great Marsh in Northeastern Massachusetts.

Salt marsh modeling coupled with hydrodynamic modeling
Project ID
Start Date: November 01, 2014
End Date: October 31, 2017
Participating Organizations/Partners

See links to presentations by project principal investigators Jim Morris and Scott Hagen at the first North Atlantic Tidal Marsh Resilience workshop in Hadley, MA in December 2014.

Read a case study about how the Hydro-MEM model has been applied by partners working to protect the Great Marsh in Northeastern Massachusetts.