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BUILDING STRONG®
PRESENTATION TITLERECOVER Applied Science Framework Supporting Everglades Restoration ImplementationJenna May, USACEDave Rudnick2, Agnes McLean2, Jed Redwine2, Fred Sklar3, Phyllis Klarmann3, Andrew Rodusky3, Thomas Dreschel3, Patti Gorman3, Patrick Pitts4, Miles Meyer4, Michael Simmons1, Gretchen Ehlinger1
1U.S. Army Corps of Engineers, Jacksonville, FL2South Florida Natural Resources Center, Everglades National Park, Homestead, FL 3South Florida Water Management District, West Palm Beach, FL4US Fish and Wildlife Service, Vero Beach, FL,
National Conference on Ecosystem RestorationDetermining Everglades Ecosystem Restoration Benefits for Projects
August 30, 2018
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Outline
Introduction RECOVER Science Framework
► Conceptual Ecological Models► Hypothesis Clusters► Performance Measures
Example – Prey base fish
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Human impacts on natural ecosystems Challenges for natural resource managers
responsible for protecting and restoring natural systems► Chesapeake Bay – Degraded waters► Louisiana – Receding coastlines► Florida Everglades – Altered hydrology, increased
nutrients Restoration programs need the integration of
science and policy to establish agreement on restoration objectives
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CERP Science Framework The Science Behind CERP The RECOVER Monitoring and
Assessment Plan► Organized around Conceptual
Ecological Models ► Hypothesis Clusters► Indicator Species► Performance Measures
Adaptive Management► Feedback Loop
Plan Projects
Inform and Adapt
Implement Projects
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Non-quantitative planning tools that identify: ► Major anthropogenic drivers and stressors
on natural systems► Ecological effects ► Best biological indicators (attributes)
Provide a logical process for synthesizing, organizing, and prioritizingexisting ecological knowledge
Conceptual Ecological Models
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Drivers
Attributes
Stressors
EcologicalEffects
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Water Management
Practices
Shortened Hydroperiods
Reduced Water Storage Capacity Compartmentalization
Marsh Fishes & Invertebrates
Wading Birds
Ponding
Altered PeriphytonComposition &
Production
Relocation of Deep Water
Refugia
Altered Wading Bird Nesting and
Foraging Patterns
Altered Fish Community
Composition and Structure
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LAKEOKEECHOBEE
EVERGLADESAGRICULTURAL
AREA
WCA 3A
SOUTHERN COASTAL SYSTEM
GREATER EVERGLADES
NORTHERN ESTUARIES
LAKE OKEECHOBEE
REGIONS
CALOOSAHATCHEERIVER ESTUARY
GULF OFMEXICO
EVERGLADESNATIONAL
PARK
WCA 3B
WCA 2
WCA 1
BISCAYNEBAY
FLORIDABAY
SHARK RIVERSLOUGH
TAYLORSLOUGH
ATLANTICOCEAN
ST. LUCIEESTUARY
Published in Wetlands, Vol. 25, No. 4, December 2005
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Conceptual Ecological Models Facilitate the formulation of hypotheses describing not only what
system attributes are important but why changes occur
Provide the framework for creating performance measures
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Hypothesis Clusters Subject-specific conceptual ecological
models Address the integration of stressor-
response relationships of the system Provide refinement in types and
numbers of performance measures and metrics► Linked to monitoring components
Identify monitoring/research needs and plan the design of restoration programs
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Greater Everglades Example: Prey Base Fish
Plan Projects
Inform and Adapt
Implement Projects
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Plan Projects
Inform and Adapt
Implement Projects
Greater Everglades Example: Prey Base Fish
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Plan Projects
Inform and Adapt
Implement Projects
Greater Everglades Example: Prey Base Fish
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Plan Projects
Inform and Adapt
Implement Projects
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Greater Everglades Example: Prey Base Fish
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Greater Everglades Example: Prey Base Fish
Equations Developed From The Data:
• DSLDD = days since last dry down• r = growth constant• TOTFISH = total small-sized fish density (number of individuals) per m2
• K=asymptotic density• Y0=Y intercept
( ) ( )
+
=+− DSLDDre *
Y0Y0-K1
K 1) HLOG(TOTFIS
Table 1. Trexler small-sized fish density logistic regression equation parameters per monitoring region
Monitoring region
WCA-3A/B
Shark RiverSlough
Taylor Slough
K 2.901 2.757 2.625r 0.097 0.006 0.003
Y0 0.300 1.486 1.08
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Greater Everglades Example: Prey Base Fish
Plan Projects
Inform and Adapt
Implement Projects
Small-sized Freshwater Fish Density Performance
Measure
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Improving scientific tools will enhance the ability of Everglades restoration projects to restore and sustain the
Everglades ecosystem
• Updates to conceptual ecological models• Vulnerability analysis
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QUESTIONS
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RECOVER Conceptual Ecological Models:http://141.232.10.32/pm/recover/cems.aspx
Contact:Jenna.C.May@usace.army.mil
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