Project

Green Infrastructure Design for Shoreline Resilience

Full Title: Robust design of green infrastructure for shoreline resiliency and habitat restoration: applying probabilistic hydrodynamic modeling to predict site-scale suitability for living shorelines
This project aims to enhance shoreline resilience and habitat restoration by prioritizing living shoreline designs using robust green infrastructure principles, directly addressing Florida Sea Grant priorities. Through the creation of shoreline prioritization and hydrodynamic habitat suitability models for estuarine shorelines in the Indian River and Lake Worth Lagoons, the project seeks to inform resource allocation and stabilization strategies while engaging diverse communities in environmental education and fostering inclusive participation in coastal management efforts.
Lead Investigator: Dr. Kelly Kibler Assistant Professor Environmental and Construction Engineering Kelly.Kibler@ucf.edu Dr. Melinda Donnelly Assistant Research Scientist Biology department Melinda.Donnelly@ucf.edu
Project Team: Molly Klinepeter Lagoon Plan Environmental Specialist, Irene Arpayoglou Florida Department of Environmental Protection, Jennifer Báez Ecosystem Management Supervisor, Beth Orlando Environmentalist II, Florida Sea Grant Extension in Martin and St. Lucie Counties, Palm Beach County.
Collaborator: Indian River County
Award Amount: $186,872
Year Funded: 2022
Award Period: 2/1/22 – 1/31/24
Project Abstract:

Application of robust green infrastructure design principles can improve success of efforts to restore ecosystem function to degraded, eroding shorelines. The health and stability of Florida’s estuarine shorelines are directly related to all three Florida Sea Grant priorities of water quality, sustainable fisheries and resilient coastal communities. The project will create a living shoreline prioritization model and hydrodynamic habitat suitability models for 240 miles (384 km) of estuarine shorelines in the Indian River and Lake Worth Lagoons. The shoreline models will address two questions often posed by coastal managers: 1) How should finite resources for shoreline stabilization or restoration be prioritized? and 2) How should a particular site be stabilized or restored? High-resolution field surveys will document shoreline ecotone characteristics and site-scale hydrodynamic conditions

will be assessed by long-term hydrodynamic modeling. Relationships between hydrodynamics and species distribution will be used to establish the hydrodynamic habitat limits of key ecosystem engineers applied in living shorelines (mangrove, oyster, marsh grasses, seagrasses). Spatial shoreline models will be constructed to prioritize shorelines in terms of geomorphic urgency for stabilization and inform which species and stabilization designs are likely to be robust to each site’s unique hydrodynamic and geomorphic conditions. The technology will be transferred to end-users in user-friendly formats for direct application to planning, design and engineering of green infrastructure in Indian River, Martin, St. Lucie and Palm Beach Counties. The project will advance diversity, equity and inclusion in each of the four participating counties by engaging at-risk youth and underserved communities in environmental education, accomplished through both direct involvement in shoreline assessment in the field and

classroom or virtual educational programming. Diverse end-user groups, including planners and coastal managers, shoreline stabilization practitioners, permitting agencies and the public, will benefit from cost savings, avoided costs, improved environmental decision-making and educational opportunities resulting from this research.

 

Project received a no cost extension through 1/31/25. The extension was needed yo account for the late start of project Year 1 and also to ensure project end users will have sufficient time to implement the research outcomes.

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