Performance Assessment of Three Living Shorelines in Cedar Key, Florida, USA

A community-driven effort in Cedar Key, Florida, USA, resulted in the construction of three living shoreline retrofits intended to bolster failing coastal infrastructure and restore habitat functions in Daughtry Bayou. A multi-year monitoring program tracked changes in elevation and vegetation commu...

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Bibliographic Details
Published inEstuaries and coasts Vol. 48; no. 1; p. 7
Main Authors Barry, Savanna C., Hernandez, Elix M., Clark, Mark W.
Format Journal Article
LanguageEnglish
Published New York Springer US 2025
Springer Nature B.V
Subjects
Bayous
Coastal ecology
Coastal Sciences
Coastal zone management
Cyclones
Earth and Environmental Science
Ecology
Environment
Environmental Management
Freshwater & Marine Ecology
Functional Assessments of Living Shorelines
Habitats
Hurricanes
Monitoring
Performance assessment
Performance testing
Retrofitting
Sea level changes
Shorelines
Tropical depressions
Tropical storms
Water and Health
Wave attenuation
Wave energy
Wave power
Florida
United States > US
Shoreline retrofit
Marsh restoration
Sediment dynamics
Habitat restoration
Wave attenuation
Environmental monitoring
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Summary:A community-driven effort in Cedar Key, Florida, USA, resulted in the construction of three living shoreline retrofits intended to bolster failing coastal infrastructure and restore habitat functions in Daughtry Bayou. A multi-year monitoring program tracked changes in elevation and vegetation communities across the entire shoreline profile from lower-intertidal to upland/transitional zones and measured wave attenuation during typical and extreme (hurricane) conditions. Overall, these living shoreline retrofits served to soften more than 30% of the bayou’s shoreline, dramatically reducing the extent of armored shoreline in direct contact with tidal influence. The extent of vegetated habitat area has increased at all three sites, despite sediment export from higher elevation zones driven largely by repeated impacts from hurricanes and tropical storms. These living shorelines reduced wave energy by 33 to 79% in typical conditions and by up to 28% in hurricane conditions, consistently outperforming armored shorelines, even during an extreme event (Hurricane Idalia). Our monitoring efforts were sufficient to capture project trajectories and assess performance relative to project goals, but our program had limitations that could have been overcome with additional resources and increased focus on capturing spillover effects. The living shoreline retrofit projects assessed here have persisted through and shown signs of recovery after multiple tropical storms and hurricanes, while providing important energy reduction services. Thus, living shoreline retrofits continue to be a cost-effective shoreline management strategy in the short term for this area. However, our analyses suggest that persistence of these shorelines could be threatened by the combination of sea-level rise (by 2040), upland armoring, and an increasing risk of more intense tropical systems. Therefore, future interventions should more carefully consider these threats in conjunction with habitat enhancement goals.
ISSN:1559-2723
1559-2731
DOI:10.1007/s12237-024-01440-w