{"data":[{"id":"10.25497/d78592","type":"dois","attributes":{"doi":"10.25497/d78592","identifiers":[],"creators":[{"name":"Starnes, Janet","nameType":"Personal","givenName":"Janet","familyName":"Starnes","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"CERP Picayune Strand - Post Restoration Vegetation Monitoring for the Picayune Strand Restoration Project 2016"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"CERP"},{"lang":"en","subject":"SFWMD"},{"lang":"en","subject":"Comprehensive Everglades Restoration Plan"},{"lang":"en","subject":"Picayune Strand State Forest"},{"lang":"en","subject":"Southern Golden Gate Estates"},{"lang":"en","subject":"Environmental Monitoring"},{"lang":"en","subject":"Environmental Restoration"},{"lang":"en","subject":"Hydrologic Restoration"},{"lang":"en","subject":"Vegetation"},{"lang":"en","subject":"Canopy trees"},{"lang":"en","subject":"Sub-canopy trees"},{"lang":"en","subject":"Shrub layer"},{"lang":"en","subject":"Ground cover"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The PSRP is part of a large development known as the Southern Golden Gate Estates (SGGE). The SGGE area is divided into to two areas by the I-75 (aka, Alligator Alley) interstate with the northern portion a developing residential community and the PSRP on the southside of the interstate. Since the 1940â s the entire area has undergone extensive hydrologic and environmental alterations.\n\nIn the 1940s and 50s, raised railroad beds were constructed in the deeper forested wetlands of southwest Florida to facilitate logging of cypress forests. In the 1960â s a network of east-west roads was constructed every quarter mile connecting the north-south roads. These roads and trams impeded the natural sheetflow that created colonization sites for exotic and nuisance vegetation, provided easy access to all parts of the area resulting in widespread impacts from off-road vehicles, poaching of animals and plants, vandalism, and the illegal dumping. This all resulted in the fragmentation of an extensive block of contiguous natural lands that severely compromised the value of the area for a variety of wide-ranging wildlife such as the Florida panther as well as other threatened and endangered species. \n\nPrior to development, the SGGE area was characterized by seasonal flooding and slow-moving overland sheet flow that supported a variety of plant and animal communities in uplands and freshwater wetlands and in its downstream brackish wetlands and estuaries. Channelization of water flows resulted in elimination of sheetflow across SGGE and into the estuaries, severely lowered water tables within SGGE, and created an erratically fluctuating freshwater point discharge to the estuaries. Upland, wetland, and estuarine plant communities have been severely degraded, the abundance of native fish, wildlife, and estuarine shellfish populations declined, recharge of the surficial aquifer reduced, and non-native species greatly increased in abundance. The severely drained conditions resulted in widespread and more intense wildfires than under pre-drainage conditions. These fires accelerated the change in vegetation from wetlands to upland communities dominated by fire tolerant species such as cabbage palm (Sabal palmetto) and exotics such as Brazilian pepper (Schinus terebinthifolius). \n\nThe goal of the PSRP is to restore the ecological connections with adjacent public lands. including the reestablishment of historic flow-ways, overland sheetflow, wetland hydroperiods, and wet and dry season water levels within SGGE and its adjacent public lands, as well as natural seasonal salinity patterns in its downstream coastal marshes and estuaries. Restoration targets encompass the short-term reestablishment of a pre-development hydrologic regime and its associated freshwater and estuarine fauna, and the long-term reestablishment of the pre-development plant and animal communities in those portions of SGGE that are downstream of the restoration projectâ s pumps. The primary mechanism for accomplishing these goals will be the removal of most of the roads, logging trams, and canals and leveling of all associated spoil. While significant hydrologic restoration is not expected upstream of the pump stations, the elimination of all above-natural-grade spoil associated with roads, logging trams and canals will significantly facilitate long term fire and nuisance vegetation management in these areas.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D78592","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T01:09:10Z","registered":"2022-10-07T01:09:11Z","published":null,"updated":"2025-03-13T15:09:15Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7k88h","type":"dois","attributes":{"doi":"10.25497/d7k88h","identifiers":[],"creators":[{"name":"Troxler, Tiffany","nameType":"Personal","givenName":"Tiffany","familyName":"Troxler","affiliation":["FIU"],"nameIdentifiers":[]},{"name":"Castaneda, Edward","nameType":"Personal","givenName":"Edward","familyName":"Castaneda","affiliation":["FIU"],"nameIdentifiers":[]},{"name":"Coronado, Carlos","nameType":"Personal","givenName":"Carlos","familyName":"Coronado","affiliation":["SFWMD"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.6 Landscape Pattern - Ridge, Slough, and Tree Island function: Surfacewater-Groundwater Interaction in WCA3 TIs"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2024,"subjects":[{"lang":"en","subject":"treeislands"},{"lang":"en","subject":"hydrology"},{"lang":"en","subject":"transpiration"},{"lang":"en","subject":"ENP"},{"lang":"en","subject":"WCA3"},{"lang":"en","subject":"hydroperiod"},{"lang":"en","subject":"Ghost Island"},{"lang":"en","subject":"phosphorus"},{"lang":"en","subject":"biogeochemical patterns"},{"lang":"en","subject":"electrochemical"},{"lang":"en","subject":"microbial"},{"lang":"en","subject":"hydro-geochemical"},{"lang":"en","subject":"TI"},{"lang":"en","subject":"vegetation"},{"lang":"en","subject":"soil"},{"lang":"en","subject":"surface water"},{"lang":"en","subject":"groundwater"},{"lang":"en","subject":"P"},{"lang":"en","subject":"calcite"},{"lang":"en","subject":"CaCO3"},{"lang":"en","subject":"nutrient"},{"lang":"en","subject":"mineral precipitation"},{"lang":"en","subject":"accumulation"},{"lang":"en","subject":"decomposition"}],"contributors":[],"dates":[{"date":"2024","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"This project is a component of the GE Wetland module of the CERP Monitoring and Assessment Plan (MAP) and is directly linked to the a) Ridge and Slough Landscape monitoring and research component of CERP, and b) Tree Island Stage Duration and the measurement of water depth on tree islands located in WCA 3A and 3B. It will significantly improve RECOVER and the SFWMD's ability to support Central Everglades Plan Process (CEPP), Everglades Forever Act, Minimum Flows and Levels (MFL), Regulatory Operations and CERP by: 1) developing a way to reverse the significant loss of tree island in WCA-2A (Worth 1988) and WCA-3 (Sklar and van der Valk 2002), 2) conduct environmental assessments for weekly SFWMD operational meetings, and 3) develop criteria to protect the flora and fauna that rely on the existence of Tree Islands.\nThis research monitoring will take place at four different tree islands located in the Water Conservation Area 3. This Statement of Work (SOW) includes the study objectives, a general description of the scope, a detailed listing of tasks to be undertaken and associated deliverables, and the timeframes citing the methodologies to be used by the contractor to perform assigned work efforts.\n\nThis project will compare the characteristics and dynamics of four Everglades tree islands such that hydraulic patterns and hydrogeochemical processes can be characterized. This monitoring project aims to understand how biogeochemical pattern and processes operating at inter-annual temporal and spatial scales can mediate tree island growth and patch maintenance through interaction of biological, geochemical, and climatic factors. It is hypothesized that water movement, mediated by hydraulic processes that are punctuated during the dry season by increased tree island evapotranspiration (ET), influence the lateral flux of nutrients to downstream components of the tree island ecosystem, thus concentrating phosphorus at the intersection between local and regional water pools. The objectives of this project are: 1) monitor and characterize spatial and temporal variability in diurnal ET patterns, 2) monitor and characterize temporal local and regional hydraulic patterns, and 3) characterize spatial and temporal hydro-chemical patterns in ions and nutrients among tree island plant communities and the adjacent deep water slough, and 4) design and implement a field experiment addressing questions linked to environmental conditions for soil development and feasibility of active management as a means to restore the structure and function of degraded tree islands.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7K88H","contentUrl":null,"metadataVersion":0,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2024-08-14T21:19:44Z","registered":"2024-08-14T21:19:45Z","published":null,"updated":"2024-08-14T21:19:45Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7np4r","type":"dois","attributes":{"doi":"10.25497/d7np4r","identifiers":[],"creators":[{"name":"Schwenneker, Bruce","nameType":"Personal","givenName":"Bruce","familyName":"Schwenneker","affiliation":["Malcom Pirnie"],"nameIdentifiers":[]},{"name":"Rice, Stephen","nameType":"Personal","givenName":"Stephen","familyName":"Rice","affiliation":["Malcom Pirnie, Inc."],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.4.4.3 Lake Okeechobee Fish and Wildlife relationships to Plant Community Structure and Habitat"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"fish"},{"lang":"en","subject":"macroinvertebrates"},{"lang":"en","subject":"emergent vegetation"},{"lang":"en","subject":"submerged acquatic vegetation"},{"lang":"en","subject":"plant community structure"},{"lang":"en","subject":"Lake Okeechobee"},{"lang":"en","subject":"littoral zone"},{"lang":"en","subject":"abundance"},{"lang":"en","subject":"spatial distribution"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"CERP projects are expected to substantially improve both the hydroperiod of the westernlittoral zone in Lake Okeechobee and the inputs of phosphorus and other chemical constituents to the ecosystem. These changes are anticipated to benefit the submerged and emergent plant communities in the littoral zone and consequently the invertebrates and forage fish that support the lake's fish and wildlife (e.g., sport fish, wading birds, snail kites, etc.) The intent of this project is to establish sufficient quantitative information on relationships between sport fish and other wildlife with vegetation type or water depth to make solid projections of CERP benefits. The ability to make those projections will be critical for optimization of the lake regulation schedule under the CERP. \nThis effort will characterize the abundance and distribution of fish and macroinvertebrates, with regard to vegetation type, density, seasonality and water column depth, in two emergent and three submersed plant communities along the pelagic-littoral interface zone of Lake Okeechobee. This Lake Okeechobee ecological study will include biannual sampling for:\n\nâ ¢ Fish (Only one sampling event per year)\nâ ¢ Macroinvertebrates\nâ ¢ Plants\nâ ¢ Amphibian and Reptiles (Samples in 2 emergent habitats)\n\nSampling locations will be identified in 3 regions of Lake Okeechobee and consist of quantitative replicate (3) samples being taken from 5 habitats. The abundance and distribution of fish (including juvenile sport fish), macroinvertebrates, amphibians and reptiles (herps) will be characterized with regard to vegetation type, density, seasonality and water column depth. Sampling events will occur annually for fish (August/September) and bi-annually (February/March and August/September) for macroinvertebrates, plants, amphibians and reptiles. In the startup year (2006) there will be only one sampling event in August September time frame which will include all sampling parameters. The abundance and distribution of fish and macroinvertebrate assemblages will be sampled in two emergent (bulrush, and cattail) habitats and three submersed (Hydrilla, Vallisneria and Potamogeton) habitats. The vegetative community structure will also be sampled in all five habitats to assess recovery and ecological significance to fish and wildlife. The abundance and distribution of herps will be sampled only in emergent habitats.\nAncillary water quality data from the top and bottom of the water column, including time of day, water temperature, dissolved oxygen, pH, specific conductance, turbidity, Secchi depth, PAR, water depth, wind speed and direction will be recorded at each sample location.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7NP4R","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-09-16T01:03:27Z","registered":"2022-09-16T01:03:28Z","published":null,"updated":"2024-08-14T14:37:59Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7c88n","type":"dois","attributes":{"doi":"10.25497/d7c88n","identifiers":[],"creators":[{"name":"Robbins, Rebecca","nameType":"Personal","givenName":"Rebecca","familyName":"Robbins","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]},{"name":"Welch, Barbara","nameType":"Personal","givenName":"Barbara","familyName":"Welch","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.3.3.5 SAV Transects SIRL, SLE"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"submerged aquatic vegetation"},{"lang":"en","subject":"Southern Indian River Lagoon"},{"lang":"en","subject":"St. Lucie Estuary"},{"lang":"en","subject":"SAV"},{"lang":"en","subject":"SIRL"},{"lang":"en","subject":"SLE"},{"lang":"en","subject":"transect"},{"lang":"en","subject":"macroalgae"},{"lang":"en","subject":"seagrass"},{"lang":"en","subject":"Northern Estuaries"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The data in this package is for data collected by the South Florida Water Management District from 2002 to 2007 in the St. Lucie Estuary and Southern Indian River Lagoon. Along four fixed transects, epi-benthic marine life is monitored within 1-m2 stations on an monthly basis. The methodology was changed in 2009.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7C88N","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:06:22Z","registered":"2022-10-07T00:06:23Z","published":null,"updated":"2024-08-14T14:36:30Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d77g6q","type":"dois","attributes":{"doi":"10.25497/d77g6q","identifiers":[],"creators":[{"name":"Troxler, Tiffany","nameType":"Personal","givenName":"Tiffany","familyName":"Troxler","affiliation":["FIU"],"nameIdentifiers":[]},{"name":"Castaneda, Edward","nameType":"Personal","givenName":"Edward","familyName":"Castaneda","affiliation":["FIU"],"nameIdentifiers":[]},{"name":"Coronado, Carlos","nameType":"Personal","givenName":"Carlos","familyName":"Coronado","affiliation":["SFWMD"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.6 Landscape Pattern - Ridge, Slough, and Tree Island function: Surfacewater-Groundwater Interaction in WCA3 TIs"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"treeislands"},{"lang":"en","subject":"hydrology"},{"lang":"en","subject":"transpiration"},{"lang":"en","subject":"ENP"},{"lang":"en","subject":"WCA3"},{"lang":"en","subject":"hydroperiod"},{"lang":"en","subject":"Ghost Island"},{"lang":"en","subject":"phosphorus"},{"lang":"en","subject":"biogeochemical patterns"},{"lang":"en","subject":"electrochemical"},{"lang":"en","subject":"microbial"},{"lang":"en","subject":"hydro-geochemical"},{"lang":"en","subject":"TI"},{"lang":"en","subject":"vegetation"},{"lang":"en","subject":"soil"},{"lang":"en","subject":"surface water"},{"lang":"en","subject":"groundwater"},{"lang":"en","subject":"P"},{"lang":"en","subject":"calcite"},{"lang":"en","subject":"CaCO3"},{"lang":"en","subject":"nutrient"},{"lang":"en","subject":"mineral precipitation"},{"lang":"en","subject":"accumulation"},{"lang":"en","subject":"decomposition"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"This project is a component of the GE Wetland module of the CERP Monitoring and Assessment Plan (MAP) and is directly linked to the a) Ridge and Slough Landscape monitoring and research component of CERP, and b) Tree Island Stage Duration and the measurement of water depth on tree islands located in WCA 3A and 3B. It will significantly improve RECOVER and the SFWMD's ability to support Central Everglades Plan Process (CEPP), Everglades Forever Act, Minimum Flows and Levels (MFL), Regulatory Operations and CERP by: 1) developing a way to reverse the significant loss of tree island in WCA-2A (Worth 1988) and WCA-3 (Sklar and van der Valk 2002), 2) conduct environmental assessments for weekly SFWMD operational meetings, and 3) develop criteria to protect the flora and fauna that rely on the existence of Tree Islands.\nThis research monitoring will take place at four different tree islands located in the Water Conservation Area 3. This Statement of Work (SOW) includes the study objectives, a general description of the scope, a detailed listing of tasks to be undertaken and associated deliverables, and the timeframes citing the methodologies to be used by the contractor to perform assigned work efforts.\n\nThis project will compare the characteristics and dynamics of four Everglades tree islands such that hydraulic patterns and hydrogeochemical processes can be characterized. This monitoring project aims to understand how biogeochemical pattern and processes operating at inter-annual temporal and spatial scales can mediate tree island growth and patch maintenance through interaction of biological, geochemical, and climatic factors. It is hypothesized that water movement, mediated by hydraulic processes that are punctuated during the dry season by increased tree island evapotranspiration (ET), influence the lateral flux of nutrients to downstream components of the tree island ecosystem, thus concentrating phosphorus at the intersection between local and regional water pools. The objectives of this project are: 1) monitor and characterize spatial and temporal variability in diurnal ET patterns, 2) monitor and characterize temporal local and regional hydraulic patterns, and 3) characterize spatial and temporal hydro-chemical patterns in ions and nutrients among tree island plant communities and the adjacent deep water slough, and 4) design and implement a field experiment addressing questions linked to environmental conditions for soil development and feasibility of active management as a means to restore the structure and function of degraded tree islands.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D77G6Q","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:07:25Z","registered":"2022-10-07T00:07:25Z","published":null,"updated":"2024-08-14T14:33:16Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d73s3f","type":"dois","attributes":{"doi":"10.25497/d73s3f","identifiers":[],"creators":[{"name":"Rand, Gary M.","nameType":"Personal","givenName":"Gary M.","familyName":"Rand","affiliation":["Florida International University"],"nameIdentifiers":[]},{"name":"Liehr, Gladys A.","nameType":"Personal","givenName":"Gladys A.","familyName":"Liehr","affiliation":["Florida International University"],"nameIdentifiers":[]},{"name":"Bachman, Pamela M.","nameType":"Personal","givenName":"Pamela M.","familyName":"Bachman","affiliation":["Florida International University"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.2.4.6 Salinity Relationships of Epifaunal Species in Near-Shore Biscayne Bay"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"salinity relationships"},{"lang":"en","subject":"Farfantepenaus duorarum"},{"lang":"en","subject":"Biscayne Bay"},{"lang":"en","subject":"epifaunal species"},{"lang":"en","subject":"invertebrate fauna"},{"lang":"en","subject":"salinity"},{"lang":"en","subject":"pink shrimp"},{"lang":"en","subject":"temperature"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The pink shrimp (Farfantepenaeus duorarum), supports a multi-million dollar industry in South Florida and provides a critical food resource for higher trophic level species in Biscayne Bay. Florida pink shrimp spawn offshore of the Dry Tortugas and the larvae migrate to critical nursery grounds in Florida and Biscayne Bays. Pink shrimp recruitment studies focusing on Florida Bay have shown a large degree of correlation between water quality/conditions and shrimp abundance. Specifically, salinity and temperature have been shown to have direct effects on the production of the pink shrimp nursery in Florida Bay. Therefore, understanding the physiological state and performance of pink shrimp, at different salinities and temperatures in Biscayne Bay is critical in predicting the effects of changing salinity and temperature on secondary productivity in, and the overall health of, the bay. This study investigated the effects of different salinity and temperature exposure scenarios on pink shrimp (Farfantepenaeus duorarum) collected from Biscayne Bay. The purpose was to determine the optimum salinity and temperature conditions for pink shrimp as defined for performance measures (i.e. survival, development, growth). Preliminary testing showed that at 25 degress Celsius, significant differences (p=0.05) were found in the survival of post-larval pink shrimp at different salinities from the control (30 ppt). The lowest salinity at which there was no significant difference from the control was 10 ppt.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D73S3F","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:08:27Z","registered":"2022-10-07T00:08:28Z","published":null,"updated":"2024-08-14T14:31:27Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7v880","type":"dois","attributes":{"doi":"10.25497/d7v880","identifiers":[],"creators":[{"name":"Moore, Kenneth","nameType":"Personal","givenName":"Kenneth","familyName":"Moore","affiliation":["Virginia Institute of Marine Sciences"],"nameIdentifiers":[]},{"name":"Engineers, BCI","nameType":"Personal","givenName":"BCI","familyName":"Engineers","affiliation":[],"nameIdentifiers":[]},{"name":"Goodman, Patty","nameType":"Personal","givenName":"Patty","familyName":"Goodman","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.3.3.4 SAV Monitoring for Caloosahatchee Estuary 2008-2009 4600001349"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"submerged aquatic vegetation"},{"lang":"en","subject":"Caloosahatchee Estuary"},{"lang":"en","subject":"Caloosahatchee River Estuary"},{"lang":"en","subject":"San Carlos Bay"},{"lang":"en","subject":"SAV"},{"lang":"en","subject":"CRE"},{"lang":"en","subject":"Northern Estuaries"},{"lang":"en","subject":"transect"},{"lang":"en","subject":"macroalgae"},{"lang":"en","subject":"seagrass"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"This is a continuation of a part of the Monitoring and Assessment Plan (MAP), to provide a long-term program for monitoring submerged aquatic vegetation (SAV) in the Caloosahatchee Estuary while examining the effects of variation in salinity. The premise is that RECOVER will ultimately determine if the restoration of beneficial patterns of freshwater inflow, salinity and water quality to the Caloosahatchee Estuary will improve the spatial and structural characteristics of SAV communities.\n\nThis long-term monitoring network has been successful in providing the start of a baseline dataset of existing SAV beds in the Caloosahatchee River and Estuary. A five-year continuation of the SAV Monitoring Network in the Caloosahatchee is recommended to ensure that an accurate evaluation is made of the effects of the C-43 Basin project storage facilities \n\nDuring the next five years of this project, additional data will be collected to understand and predict the effect of restoration activities influencing hydrologic changes and freshwater releases as the result of the implementation of the C-43 Basin project.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7V880","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:10:40Z","registered":"2022-10-07T00:10:41Z","published":null,"updated":"2024-08-14T14:28:37Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7qg62","type":"dois","attributes":{"doi":"10.25497/d7qg62","identifiers":[],"creators":[{"name":"Florence, Gary","nameType":"Personal","givenName":"Gary","familyName":"Florence","affiliation":["Photo Science, Inc."],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.4.3.2 Lake Okeechobee Littoral Zone Plant Communities"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"emergent vegetation"},{"lang":"en","subject":"vegetation mapping"},{"lang":"en","subject":"littoral zone"},{"lang":"en","subject":"Lake Okeechobee"},{"lang":"en","subject":"plant community"},{"lang":"en","subject":"high-resolution infrared aerial photography"},{"lang":"en","subject":"photogrammetry"},{"lang":"en","subject":"remote sensing"},{"lang":"en","subject":"Kreamer Island"},{"lang":"en","subject":"Torry Island"},{"lang":"en","subject":"Ritta Island"},{"lang":"en","subject":"Henry Creek"},{"lang":"en","subject":"Eagle Bay Island"},{"lang":"en","subject":"Clewiston lock"},{"lang":"en","subject":"orthophotography"},{"lang":"en","subject":"raster digital data"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The littoral zone emergent vegetation community found in Lake Okeechobee is a diverse mosaic of native and exotic plants covering an area larger than 400 square kilometers. It provides nesting habitat and food resources for economically important sport fish populations, wading birds, migratory waterfowl, alligator, and the federally-listed endangered Everglades snail kite. The structure of the littoral vegetation community largely determines the extent to which it can provide these habitat values. Littoral vegetation structure is influenced both by hydroperiod and phosphorus loading from the lake's eutrophic pelagic region. The spatial distribution of native and exotic plants in the lake's littoral zone is being evaluated in an ongoing program by the SFWMD. Emergent vegetation is photographed using high-resolution infrared aerial photography. Major vegetation classes (34 total) are delineated ffrom the photographs using a steroscope, and veretation maps are developed in Arc Info. This process includes extensive ground truthing. Mapping of the entire littoral vegetation community will be conducted at approximantely six-year intervals.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7QG62","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:11:45Z","registered":"2022-10-07T00:11:46Z","published":null,"updated":"2024-08-14T14:27:08Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7ks3s","type":"dois","attributes":{"doi":"10.25497/d7ks3s","identifiers":[],"creators":[{"name":"Fox, Donald","nameType":"Personal","givenName":"Donald","familyName":"Fox","affiliation":["Florida Fish and Wildlife Conservation Commission"],"nameIdentifiers":[]},{"name":"Hanlon, Charles","nameType":"Personal","givenName":"Charles","familyName":"Hanlon","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.4.3.6 Lake Okeechobee Fish Condition and Population Structure"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"fish"},{"lang":"en","subject":"Lake Okeechobee"},{"lang":"en","subject":"Florida Fish and Wildlife Conservation CommissionFlorida"},{"lang":"en","subject":"trawl fishing"},{"lang":"en","subject":"electrofishing"},{"lang":"en","subject":"community composition"},{"lang":"en","subject":"fish distribution"},{"lang":"en","subject":"biomass"},{"lang":"en","subject":"fish condition"},{"lang":"en","subject":"fish density"},{"lang":"en","subject":"fish population"},{"lang":"en","subject":"population structure"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The Florida Fish and Wildlife Conservation Commission (FWC) collected annual trawl data at 27 open-water sites from 1987 to 1991 (Bull et al. 1995). Nearly 37,000 fish were recorded in 438 10-minute open-water trawls (Bull et al. 1995). Seven species accounted for 98% of the total number and total fish biomass. Clustering of sites based on mean catch of the primary species expressed as number and weight produced four distinct groups. The groups were labeled as the northeast shore, northwest shore, south-southwest shore and open water area. Areal fish distribution patterns also were compared using analysis of variance (ANOVA) and Tukeyâ s HSD post hoc test. Within the four groups there were significant differences in the distribution of certain fish species.\nIn addition to the open-water trawl sites, the FWC has utilized electrofishing techniques to collect annual largemouth bass (Micropterous salmodies) (LMB) data from 22 near-shore and interior marsh locations since 1999 (Havens et al. 2004). Although the trawl and electrofishing data provide some baseline information, still there is limited data regarding temporal changes in the community structure, density and condition of the primary sport fish LMB, black crappie (Pomoxis nigromaculatus), bluegill (Lepomis macrochirus) and redear (Lepomis microlophus) sunfish) and other fish species in Lake Okeechobee.\nDuring this study, fish species will be collected from 49 historic sampling locations.\nFish assemblages in the 27 open water regions of the lake will be sampled with an Otter Trawl net. The 22 near-shore and interior marsh sites will be sampled utilizing electrofishing gear. Ancillary data, including water temperature, dissolved oxygen, pH, turbidity, conductivity, and sediment/aquatic plant type will be recorded at the 49 sampling locations. \nThe two historic sets of non-MAP data will be used to help establish baseline conditions for the near-shore, interior marsh and open-water fishery. It is appropriate to include the non-MAP data in our analysis as current sampling will occur at the historical locations and sampling methods will be similar. We anticipate significant spatial differences in fish abundance and biomass will exist at the near-shore, interior marsh and open water sites. Therefore, similar statistical tests including cluster analysis and analysis of variance should be used to evaluate temporal changes in the near-shore and open water fishery. Detailed statistical analysis should be conducted at a minimum of every three years to evaluate long-term trends and establish relationships between fish distribution, condition, and community structure and environmental conditions including habitat and water depth. \nThe objectives of this project are to evaluate temporal changes in Lake Okeechobeeâ s fishery by determining annual changes in the areal distribution, condition, density and community structure (year classes) of all major fish species found in the near-shore, interior marsh and open-water regions of the lake. Ancillary data including water temperature, dissolved oxygen, pH, turbidity, conductivity, and sediment type also will be recorded.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7KS3S","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:12:49Z","registered":"2022-10-07T00:12:50Z","published":null,"updated":"2024-08-14T14:25:58Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7q300","type":"dois","attributes":{"doi":"10.25497/d7q300","identifiers":[],"creators":[{"name":"Woods, Jeff","nameType":"Personal","givenName":"Jeff","familyName":"Woods","affiliation":["U.S. Geological Survey"],"nameIdentifiers":[]},{"name":"Hittle, Clinton","nameType":"Personal","givenName":"Clinton","familyName":"Hittle","affiliation":["U.S. Geological Survey"],"nameIdentifiers":[]},{"name":"Zucker, Mark","nameType":"Personal","givenName":"Mark","familyName":"Zucker","affiliation":["U.S. Geological Survey"],"nameIdentifiers":[]},{"name":"Patino, Eduardo","nameType":"Personal","givenName":"Eduardo","familyName":"Patino","affiliation":["U.S. Geological Survey"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.3 Coastal Gradients of Flow, Salinity, and Nutrients (http://sofia.usgs.gov/projects/coastal_grads/)"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2024,"subjects":[{"lang":"en","subject":"coastal gradients"},{"lang":"en","subject":"salinity"},{"lang":"en","subject":"freshwater flow"},{"lang":"en","subject":"salinity gradients"},{"lang":"en","subject":"Florida Bay"},{"lang":"en","subject":"Gulf estuaries"},{"lang":"en","subject":"nutrients"},{"lang":"en","subject":"mangrove esturary"},{"lang":"en","subject":"Greater Everglades wetlands"}],"contributors":[],"dates":[{"date":"2024","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"Coastal Gradients across the freshwater-marine interface of the mangrove estuaries of Florida Bay and the Southwest Florida shelf are monitored to:\n- Track salinity gradients along historic flow paths that will be restored by CERP and relate to fresh water flow volumes and sea level.\n- Delineate the boundaries of coastal regions for the stratified random sample design\n- Measure freshwater flow volumes and nutrient inputs into the high-productivity salinity transition zone of the mangrove estuary to support the elevation of estuarine productivity in relation to freshwater inputs from CERP.\n- Measure freshwater flow volumes and nutrient inputs from Greater Everglades Wetlands to Florida Bay and Gulf estuaries.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7Q300","contentUrl":null,"metadataVersion":0,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2024-08-13T19:47:32Z","registered":"2024-08-13T19:47:33Z","published":null,"updated":"2024-08-13T19:47:33Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7g015","type":"dois","attributes":{"doi":"10.25497/d7g015","identifiers":[],"creators":[{"name":"Warren, Gary","nameType":"Personal","givenName":"Gary","familyName":"Warren","affiliation":["Florida Wildlife Commission"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.4.3.5 Lake Okeechobee Benthic Macroinvertebrates"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"pelagic zone"},{"lang":"en","subject":"emergent macrophytes"},{"lang":"en","subject":"macroinvertebrate assemblages"},{"lang":"en","subject":"petite ponar dredge"},{"lang":"en","subject":"submersed macrophytes"},{"lang":"en","subject":"Hess sampler"},{"lang":"en","subject":"stereo-dissecting microscopes"},{"lang":"en","subject":"CERP"},{"lang":"en","subject":"Florida Wildlife Commission"},{"lang":"en","subject":"Lake Okeechobee"},{"lang":"en","subject":"benthic macroinvertebrates"},{"lang":"en","subject":"freshwater invertebrates"},{"lang":"en","subject":"invertebrates"},{"lang":"en","subject":"eutrophication"},{"lang":"en","subject":"scuds"},{"lang":"en","subject":"Amphipoda"},{"lang":"en","subject":"snails"},{"lang":"en","subject":"mussels"},{"lang":"en","subject":"Mollusca"},{"lang":"en","subject":"mayflies"},{"lang":"en","subject":"Ephemeroptera"},{"lang":"en","subject":"caddisflies"},{"lang":"en","subject":"Trichoptera"},{"lang":"en","subject":"dragonflies"},{"lang":"en","subject":"damselflies"},{"lang":"en","subject":"Odonata"},{"lang":"en","subject":"segmented worm"},{"lang":"en","subject":"Oligochaeta"},{"lang":"en","subject":"Limnodrilus hoffmeisteri"},{"lang":"en","subject":"allochthonous"},{"lang":"en","subject":"autochthonous"},{"lang":"en","subject":"nutrients"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"Benthic macroinvertebrates play an important role in the Lake Okeechobee ecosystem. They provide food resources for fish, contribute to sediment nutrient recycling, and can serve as sensitive indicators of water quality (Jonasson 1969, Brinkhurst 1965, Warren et al. 1995).\nGiven these overall MAP goals, the evaluation of benthic invertebrate communities of the Lake Okeechobee pelagic region was implemented with the following objectives:\n1. Sample Lake Okeechobee sublittoral zone benthic invertebrate communities in three\n areally dominant habitat zones (mud, sand, peat) twice annually for a three year period,\n duplicating the timing, locations, and methods of Warren et al. (1995).\n\n2. Use results from sampling to evaluate the pelagic region benthic invertebrate\n community structure, thereby establishing a baseline for future evaluation and \n comparison. Elements of community structure to be documented include: taxonomic\n composition, taxa richness, absolute abundance, relative abundance, diversity\n (Shannonâ s equation, as per Krebs 1999), and evenness (as per Pielou 1977).\n\n3. Compare current (2005-08) pelagic region benthic invertebrate community structure\n with corresponding structural elements of the 1987-96 study period. Based upon these\n comparisons, identify changes in invertebrate community structure and speculate on\n the implications to future invertebrate community health as well as the overall health\n of the Lake Okeechobee ecosystem. \n\n4. Relate results from the study to CERP hypotheses and apply conclusions to the\n adaptive management process. \n\nThe intent of maintaining continuity with the methods and sampling sites utilized during the 1987-1996 FWC sublittoral zone evaluation (Warren 1991, Warren et al. 1995) was to supplement the pre-CERP implementation baseline (2005-2008 study) with additional data collected over a longer term and over a broader range of environmental conditions. \n\nBenthic macroinvertebrate communities of the Lake Okeechobee pelagic zone were sampled by the Florida Fish and Wildlife Conservation Commission (FWC) on a quarterly (February, May, August, November) basis in 1987-1988 and then semi-annually (January and July) through 1996. Since 1996, invertebrate communities have been sampled intermittenly, with the last collection occurring in June 2000. Sampling was conducted at 18 fixed sites, with six sites each in mud (northern and mid-lake), sand (western), and peat (southern) habitat zones. Three pseudo-replicate samples were collected at each of the 18 sites during every sampling event, yielding 18 samples per habitat zone and a total of 54 samples. Samples were collected with a petite ponar dredge.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7G015","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:13:55Z","registered":"2022-10-07T00:13:56Z","published":null,"updated":"2024-08-13T19:44:18Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7b88b","type":"dois","attributes":{"doi":"10.25497/d7b88b","identifiers":[],"creators":[{"name":"Robbins, Rebecca","nameType":"Personal","givenName":"Rebecca","familyName":"Robbins","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]},{"name":"Goodman, Patty","nameType":"Personal","givenName":"Patty","familyName":"Goodman","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.3.3.3 SAV Mapping from Aerial Photography"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"submerged aquatic vegetation"},{"lang":"en","subject":"seagrass"},{"lang":"en","subject":"Southern Indian River Lagoon"},{"lang":"en","subject":"St. Lucie Estuary"},{"lang":"en","subject":"SAV"},{"lang":"en","subject":"SIRL"},{"lang":"en","subject":"SLE"},{"lang":"en","subject":"Indian River Lagoon"},{"lang":"en","subject":"macroalgae"},{"lang":"en","subject":"Northern Estuaries"},{"lang":"en","subject":"St. Lucie Inlet"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"Seagrasses species were mapped within the Southern Indian River Lagoon stretching just north of the Jensen Beach Causeway to the south end of Peck Lake using aerial photos taken in August and December 2007 and field data collected in July 2008.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7B88B","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:14:59Z","registered":"2022-10-07T00:15:00Z","published":null,"updated":"2024-08-13T18:53:23Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d76k52","type":"dois","attributes":{"doi":"10.25497/d76k52","identifiers":[],"creators":[{"name":"Geiger, Ph. D","nameType":"Personal","givenName":"Ph. D","familyName":"Geiger","affiliation":["Fish and Wildlife Research Institute"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.3.3.6 Oyster Monitoring Network East Coast"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"RECOVER Module Component 3.3.3.6"},{"lang":"en","subject":"Oyster Monitoring Network"},{"lang":"en","subject":"St. Lucie Estuary"},{"lang":"en","subject":"Loxahatchee Estuary"},{"lang":"en","subject":"Lake Worth Lagoon"},{"lang":"en","subject":"Tampa Bay"},{"lang":"en","subject":"Mosquito Lagoon"},{"lang":"en","subject":"Sebastian River"},{"lang":"en","subject":"Biscayne Bay"},{"lang":"en","subject":"Crassostrea virginica"},{"lang":"en","subject":"oyster condition"},{"lang":"en","subject":"oyster spatial distribution"},{"lang":"en","subject":"Perkinsus marinus"},{"lang":"en","subject":"Haplosporidium nelsoni"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The primary objective of this effort is to implement a long-term monitoring program for Crassostrea virginica in southeast and southwest Florida. Five aspects of oyster ecology are being monitored; condition (as measured by condition index), spatial and size distribution patterns of adult oysters, distribution and frequency patterns of the oyster diseases Perkinsus marinus (dermo) and (on the east coast only) Haplosporidium nelsoni (MSX), reproduction and recruitment, and juvenile oyster growth and survival.\n\nA baseline for oysters in each estuary is being established by mapping the existing distribution of reefs/beds, and density of living oysters (per square meter). Historical distributions, where available are being used to assist in identifying areas which may have suitable habitat conditions for reestablishment, given predictive changes in the salinity regime. At five year intervals during CERP implementation, a map of the area including size distribution, density of living oysters, and height of the oyster reef, whenever possible, will be prepared.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D76K52","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:16:06Z","registered":"2022-10-07T00:16:07Z","published":null,"updated":"2024-08-13T18:03:42Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d72s34","type":"dois","attributes":{"doi":"10.25497/d72s34","identifiers":[],"creators":[{"name":"Estevez, Ernie","nameType":"Personal","givenName":"Ernie","familyName":"Estevez","affiliation":["Mote Marine Laboratory"],"nameIdentifiers":[]},{"name":"Volety, Aswani","nameType":"Personal","givenName":"Aswani","familyName":"Volety","affiliation":["Florida Gulf Coast University"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.3.4.1 Reconnaissnce Study of Caloosahatchee"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"CRE"},{"lang":"en","subject":"Caloosahatchee River Estuary"},{"lang":"en","subject":"flow"},{"lang":"en","subject":"hydrology"},{"lang":"en","subject":"Mote Marine Labs"},{"lang":"en","subject":"SAV"},{"lang":"en","subject":"submerged aquatic vegetation"},{"lang":"en","subject":"oysters"},{"lang":"en","subject":"biomass"},{"lang":"en","subject":"abundance"},{"lang":"en","subject":"diversity"},{"lang":"en","subject":"salinity"},{"lang":"en","subject":"temperature"},{"lang":"en","subject":"fish"},{"lang":"en","subject":"shrimp"},{"lang":"en","subject":"crabs"},{"lang":"en","subject":"phytoplankton"},{"lang":"en","subject":"algae"},{"lang":"en","subject":"oyster reef biotic communitiy"},{"lang":"en","subject":"crustaceans"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The objectives of the collaborative CRE program are to describe present-dayconditions of the study area, and to determine and empirically evaluate causal relationships of river flow to the distribution, abundance, and/or condition of selected valued ecosystem components. Specific issues to be evaluated by the CRE Cooperative Research Plan include the following:\n· Role of hydrology (discharge) relative to red tide events\n· Effects of salinity fluctuations on SAV beds, oysters, and juvenile fish populations and densities\n· Ecological significance of SAV beds and oyster bars and the potential to reestablish these communities\n· The effect of the presence and intensity of red tide blooms on juvenile fish and manatee health (as assessed through immune function ) within the estuary\n· Effects of manatee use of SAV on SAV productivity in the Caloosahatchee River and nearby waters\n· The effect of loss or reduction of SAV in the estuary on manatee health\n· Immunological or other biomarkers that indicate serious exposure and potential compromises of manatee health\nStudies began in 2001-2002, on the subjects of red tide, SAV, SAV-dependent fish communities, manatee distribution and abundance, manatee immunology, oyster growth and condition, oyster disease, and oyster-dependent fish communities.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D72S34","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:17:17Z","registered":"2022-10-07T00:17:18Z","published":null,"updated":"2024-08-13T18:02:38Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7z305","type":"dois","attributes":{"doi":"10.25497/d7z305","identifiers":[],"creators":[{"name":"Robbart, Martha","nameType":"Personal","givenName":"Martha","familyName":"Robbart","affiliation":["Dial Cordy and Associates Inc."],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.3.3.9 Benthic Mapping and Substrate Characterization"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"benthic mapping"},{"lang":"en","subject":"substrate characterization"},{"lang":"en","subject":"Caloosahatchee River Estuary"},{"lang":"en","subject":"St. Lucie Estuary"},{"lang":"en","subject":"Indian River Lagoon"},{"lang":"en","subject":"Loxahatchee River Estuary"},{"lang":"en","subject":"Lakeworth Lagoon"},{"lang":"en","subject":"shell"},{"lang":"en","subject":"silt"},{"lang":"en","subject":"mud"},{"lang":"en","subject":"muck"},{"lang":"en","subject":"oyster beds"},{"lang":"en","subject":"seagrasses"},{"lang":"en","subject":"oyster reef"},{"lang":"en","subject":"benthic habitat"},{"lang":"en","subject":"bottom types"},{"lang":"en","subject":"sediment map"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The overall objective of this project is to map the four (4) Northern Estuaries (Caloosahatchee River Estuary, St. Lucie Estuary/Indian River Lagoon, Loxahatchee Estuary, and Lake Worth Lagoon) in south Florida for bottom type (e.g. shell, silt, mud, muck) and location of oyster beds and seagrasses (Figure 1). In addition, density of live oysters, as well as percent coverage of seagrasses at select locations in these estuaries will be examined. While monitoring of oyster reef and seagrass health is currently taking place in many of the subject estuaries, the extent and distribution/coverage of oyster reefs, seagrasses and their exact current locations in the estuaries is unknown. In addition, comprehensive bottom type and morphology of the estuarine portion is lacking. Since the spatial location and extent (as well as health) of oyster reefs, seagrasses, and bottom types (gravel, silt, mud, muck etc.) influences the natural expansion of oyster reefs and seagrasses and success of restoration activities, mapping of the benthic habitats and bottom types in the subject estuaries is essential. This additional mapping (beyond oyster reef and seagrass health) is essential since increasing the coverage of healthy oyster beds and seagrasses is a CERP goal. The mapping performed and data collected will serve to support several broad program objectives, including: establishment of pre-CERP reference conditions and variability, determining the status and trends in resource conditions, detecting unexpected responses in the ecosystem resulting from CERP activities, and supporting scientific investigations leading to an increased understanding of the ecosystem, cause and effect relationships, and unanticipated results.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7Z305","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:18:43Z","registered":"2022-10-07T00:18:44Z","published":null,"updated":"2024-08-13T18:00:38Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7t88p","type":"dois","attributes":{"doi":"10.25497/d7t88p","identifiers":[],"creators":[{"name":"Desmond, Greg","nameType":"Personal","givenName":"Greg","familyName":"Desmond","affiliation":["Eastern Geographic Science Center, United States Geological Survey"],"nameIdentifiers":[]},{"name":"Gottlieb, Andrew","nameType":"Personal","givenName":"Andrew","familyName":"Gottlieb","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.1 Water Conservation Area 2 \u0026amp; 3 Elevations"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"Water Conservation Areas"},{"lang":"en","subject":"elevations"},{"lang":"en","subject":"Greater Everglades"},{"lang":"en","subject":"Water Conservation Area 2"},{"lang":"en","subject":"Water Conservation Area 3"},{"lang":"en","subject":"WCA 2"},{"lang":"en","subject":"WCA 3"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The U. S. Geological Survey (USGS) Airborne Height Finder (AHF) system was used to perform topographic surveys in Water Conservation Areas 2 and 3A. The AHF is a helicopter-based instrument that uses a GPS receiver, a computer, and a mechanized plumb bob to make measurements.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7T88P","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:19:47Z","registered":"2022-10-07T00:19:48Z","published":null,"updated":"2024-08-13T17:58:22Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7pk5d","type":"dois","attributes":{"doi":"10.25497/d7pk5d","identifiers":[],"creators":[{"name":"Hansen, Mark","nameType":"Personal","givenName":"Mark","familyName":"Hansen","affiliation":["USGS"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.7 Landscape Pattern - Tidal Creek Delineation"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"Tidal creeks"},{"lang":"en","subject":"bathymetry"},{"lang":"en","subject":"USGS"},{"lang":"en","subject":"NASA EAARL"},{"lang":"en","subject":"SANDS system"},{"lang":"en","subject":"coastal wetlands"},{"lang":"en","subject":"channel surface area"},{"lang":"en","subject":"boundary morphology"},{"lang":"en","subject":"cross-section morphology"},{"lang":"en","subject":"remote sensing"},{"lang":"en","subject":"hydrodynamic monitoring"},{"lang":"en","subject":"hydrodynamic modeling"},{"lang":"en","subject":"creek level"},{"lang":"en","subject":"flow"},{"lang":"en","subject":"salinity"},{"lang":"en","subject":"geomorphic survey"},{"lang":"en","subject":"coastal ecotone"},{"lang":"en","subject":"southern Everglades"},{"lang":"en","subject":"longitudinal gradient"},{"lang":"en","subject":"channel characteristics"},{"lang":"en","subject":"Shark River"},{"lang":"en","subject":"Trout Creek"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"River and tidal creeks through coastal wetlands of the Everglades have filled in with sediments and with the vegetation of surrounding landscapes to the point that many have greatly diminished or disappeared entirely during the past century. Restoration plans under consideration are to redirect additional freshwater inflow from the Everglades to open and sustain these waterways to a level that closely resembles historic patterns.\n\nThis project will develop and analyze cost-effective methods to determine channel surface area, boundary and cross-section morphology using boat based and airborne remote sensing techniques. The purpose is twofold: hydrodynamic modeling and monitoring. Hydrodynamic models will be used to simulate river and tidal creek levels, flows and salinities to guide these restoration efforts. These hydrodynamic models require high-resolution boundary conditions in order to produce accurate results. Monitoring changes in coastal channel and creek systems is necessary because of uncertainty regarding the flow volumes necessary to sustain them. \n\nThis study has two objectives:\n\n1) Determine methodology to conduct geomorphic surveys of tidal rivers and creeks along the coastal ecotone of the southern Everglades. These surveys will characterize the longitudinal gradient and cross-profiles of the tidal river networks. Broad River and Trout Creek in (Florida Bay) will be used as pilot locations for initiation of this project.\n\n2) Establish a protocol for channel characteristic mapping that will provide adequate, consistent information about different channels and changes in channels through time that can be used in Everglade process modeling and restoration impact monitoring.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7PK5D","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:20:54Z","registered":"2022-10-07T00:20:54Z","published":null,"updated":"2024-08-13T17:57:09Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7js3g","type":"dois","attributes":{"doi":"10.25497/d7js3g","identifiers":[],"creators":[{"name":"Osborne, Todd","nameType":"Personal","givenName":"Todd","familyName":"Osborne","affiliation":["Wetland Biogeochemistry Laboratory, Soil and Water Science Department, University of Florida"],"nameIdentifiers":[]},{"name":"Cohen, Matthew","nameType":"Personal","givenName":"Matthew","familyName":"Cohen","affiliation":["School of Forest Resources and Conservation, University of Florida"],"nameIdentifiers":[]},{"name":"Clark, Mark","nameType":"Personal","givenName":"Mark","familyName":"Clark","affiliation":["Wetland Biogeochemistry Laboratory, Soil and Water Science Department, University of Florida"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.2 Regional Diatribution of Soil Nutrients"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"soil nutrients"},{"lang":"en","subject":"soil mapping"},{"lang":"en","subject":"ecological type"},{"lang":"en","subject":"ecological status"},{"lang":"en","subject":"nugget variance"},{"lang":"en","subject":"spatial variability"},{"lang":"en","subject":"ecological change"},{"lang":"en","subject":"hierarchically nested sampling"},{"lang":"en","subject":"PSU"},{"lang":"en","subject":"probabalistic sampling unit"},{"lang":"en","subject":"Greater Everglades"},{"lang":"en","subject":"water depth"},{"lang":"en","subject":"community type"},{"lang":"en","subject":"vegetation composition"},{"lang":"en","subject":"WAAS"},{"lang":"en","subject":"wide area augmentation system"},{"lang":"en","subject":"WCA3A"},{"lang":"en","subject":"WCA1"},{"lang":"en","subject":"TP"},{"lang":"en","subject":"TN"},{"lang":"en","subject":"TC"},{"lang":"en","subject":"LOI"},{"lang":"en","subject":"loss on ignition"},{"lang":"en","subject":"semivariogram"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"Mapping soil quality (nutrients, carbon quality, process dynamics) has recently been undertaken as part of an effort to characterize baseline conditions for performance assessment of Everglades recovery activities. While large scale maps are useful for characterization of spatial pattern, several layers of uncertainty limit use as measures of performance and restoration progress. In particular, large scale maps (Greater Everglades) make specific assumptions about short range variability that are not well quantified. Nugget variance (variability in space over short separation distances) directly confounds use of baseline map products because future spatial sampling will not, in practicality, be at identical locations. If nugget variability is high, then significant uncertainty about ecosystem change arises from not knowing if observed differences arise from intrinsic ecosystem processes or from responses to human management. Our primary objective is to determine the extent to which spatial variability and sampling uncertainty confound ecological change detection. We will use hierarchically nested sampling of soils to establish nugget variability so that change through time can be assigned as observational uncertainty or management response.\n A related issue for mapping soil nutrients is greatly improving our understanding of the role of ecosystems in regulating nutrient conditions. Previous mapping efforts regarded space as the primary co-variate with soil nutrients, when there are numerous reasons to expect that ecological type and status are more important descriptors (with spatial autocorrelation playing a secondary, though still significant role). Our second objective is to partition variability in soil nutrient conditions in space and time, by ecosystem type, ecological status, and proximity to canals. We anticipate sampling of soils on a fine scale which traverse ecological transitions will help develop predictive models of the role of ecosystem type, geographic setting and, eventually, spatial structuring in regulating soil processes.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7JS3G","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:22:07Z","registered":"2022-10-07T00:22:08Z","published":null,"updated":"2024-08-13T17:53:30Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7f30h","type":"dois","attributes":{"doi":"10.25497/d7f30h","identifiers":[],"creators":[{"name":"Smith III, Thomas","nameType":"Personal","affiliation":["U.S. Geological Survey, Florida Integrated Science Center"],"nameIdentifiers":[]},{"name":"Anderson, Gordon","nameType":"Personal","givenName":"Gordon","familyName":"Anderson","affiliation":["USGS-Florida Integrated Science Center"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.9 Trophic Level - Primary - Mangrove Forest Soil Accretion"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"elevation gradients"},{"lang":"en","subject":"wetland ecosystems"},{"lang":"en","subject":"wetland soils"},{"lang":"en","subject":"nutrient concentration"},{"lang":"en","subject":"salinity"},{"lang":"en","subject":"oxidation"},{"lang":"en","subject":"reduction status"},{"lang":"en","subject":"coastal wetlands"},{"lang":"en","subject":"sediment surface elevation"},{"lang":"en","subject":"mangroves"},{"lang":"en","subject":"hydrology"},{"lang":"en","subject":"coastal mangrove forests"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"Understanding the factors controlling changes in wetland sediment surface elevation has been identified as a key component of the Comprehensive Everglades Restoration Plan (CERP). This is true for coastal saline wetlands such as mangrove forests and for interior freshwater wetlands such as the ridge and slough. Hydrology is a driving factor for plant species distribution in wetlands and for influencing primary production. Upstream freshwater inflows determine downstream salinity regimes which in turn influence plant species occurrence and productivity. Plant productivity, especially belowground productivity (i.e. roots) can produce peat which has a positive feedback on sediment elevation by raising it (Fig. 1). Disturbances (drought, fires and hurricanes) can influence elevation through a variety of mechanisms. Hurricanes may deposit sediment\nleading to a direct increase in wetland elevation. Hurricanes may also kill the vegetation which leads to peat collapse and loss of elevation (Cahoon et al. 2003). Prior to FY2004, the U.S. Geological Survey â Biological Resources Discipline was sampling wetlands hydrology at a number of sites in the coastal Everglades as part of the Mangrove Hydrology Sampling Network (Fig. 2, see Smith 2004). Both surface water and ground water sampling wells were installed along two transects. Sediment elevation and vegetation dynamics were sampled concurrently at these sites. Our work addresses several questions related to wetland sediment surface elevation in the coastal Everglades: (1) Wetland sediment surface elevation is more variable in freshwater than in estuarine wetlands; (2) Fluctuations in groundwater stage are more important in determining sediment surface elevation in downstream estuarine wetlands than are factors in the shallow root zone; (3) Surface water fluctuation is more important in controlling sediment elevation in upstream freshwater wetlands; and, (4) How do pulse disturbances, such as hurricanes, interact with long-term processes, such as\nsea-level rise, to affect wetland elevation? With regard to CERP, we address Hypothesis Cluster 9.2.4 of the 2005 Assessment Strategy for the Monitoring and Assessment Plan. Specifically we deal with Hypothesis #4: Sea level and freshwater flow as determinants of production, organic soil\naccretion and resilience of coastal mangrove forests (Recover 2005).","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7F30H","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:23:11Z","registered":"2022-10-07T00:23:12Z","published":null,"updated":"2024-08-13T17:40:24Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d79881","type":"dois","attributes":{"doi":"10.25497/d79881","identifiers":[],"creators":[{"name":"Sternberg, Leonel","nameType":"Personal","givenName":"Leonel","familyName":"Sternberg","affiliation":["University of Miami"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.6 Landscape Pattern - Ridge, Slough, and Tree Island function in relation to marsh hydrology"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"treeislands"},{"lang":"en","subject":"hydrology"},{"lang":"en","subject":"transpiration"},{"lang":"en","subject":"foliar carbon isotope ratios"},{"lang":"en","subject":"ENP"},{"lang":"en","subject":"WCA3"},{"lang":"en","subject":"hydroperiod"},{"lang":"en","subject":"Granier probes"},{"lang":"en","subject":"sap flux rates"},{"lang":"en","subject":"foliar nutrient concentrations"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"This project will support two existing MAP projects: 1) Tree Islands in Everglades National Park (ENP) - Big Cypress and 2) Tree Island Stage Duration and the measurement of water depth on tree islands located in WCA 3A and 3B. While these projects have similar broad objectives, some of the specific monitoring design and constituents differ. Tree island elevations and species composition were measured on over 200 islands in WCA 3, while community dynamics, hydrology, soil moisture, and transpiration and growth rates of the dominant trees are monitored on tree islands located within ENP. The ENP monitoring program was based on work originally funded by the ENP in 2005. Ross and Oberbauer (2006) have shown large seasonal differences between dry and wet season transpiration rates in an island located in the eastern prairies of ENP. However, no seasonal differences were observed in the islands located in Shark Slough where the dry season water levels remained above the marsh surface. These results have implications for the management of these systems, since it appears that extended dry-downs during the November â May dry season may cause significant declines in tree island productivity. These changes in productivity, in turn, may alter the role tree islands play in nutrient cycles in the Everglades marshes. The role of tree islands in marsh nutrient cycles has been the subject of recent journal articles (Ross et al. 2006, Wetzel et al. 2005), and in the last year RECOVER has sponsored several discussions dedicated to the development of tree island conceptual models and performance measures (e.g. GEER 2008). The WCA 3 monitoring effort has begun to add many of the physiological measurements to their monitoring program, but is currently lacking the funding necessary to fully implement the effort. This work will place all the existing MAP projects within a common framework that links tree island productivity with nutrient cycles and hydrologic conditions in the marsh. The results are expected to provide information useful for the development of cost-effective, long-term monitoring tools for the MAP.\nThe overall objective of the study is to test the transpiration model presented by Ross et al. (2006 and Wetzel et al. (2005), which states that high transpiration is the driving force for nutrient accumulation of tree islands (Fig 1). According to this model, slough tree islands can maintain high transpiration rates during the dry season using standing marsh water around the island or groundwater, while prairie tree islands will have low transpiration rate during dry season due to low water availability. Thus, the difference in hydroperiod between slough and prairie tree islands will result in differential nutrient accumulation rates and suggests that slough tree islands can accumulate more nutrients than prairie tree islands. \n\n \nThe specific objectives of this study are 1) to test whether there is a decrease in transpiration from wet to dry season in prairie tree islands but not in slough tree islands, 2) to test whether the above transpiration shift is reflected in the foliar carbon isotope ratios and 3) to test whether prairie tree islands showing the decrease from wet to dry season transpiration have lower foliar nutrient concentrations compared to slough tree islands. The objective is to use Granier probes to measure sap flux rates as a proxy for transpiration, foliar carbon and nitrogen isotope analysis as well foliar phosphorus and nitrogen concentrations to answer the above questions. The results of this project will be submitted to a peer reviewed journal. The results of this research will link transpiration with nutrient accumulation and will provide guidelines to tree island models. In addition, the foliar isotopic analysis, if consistent with the above hypotheses, will provide a measure of tree island nutrient stability and may be suitable for use as a MAP monitoring tool.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D79881","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:24:17Z","registered":"2022-10-07T00:24:18Z","published":null,"updated":"2024-08-13T17:36:08Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d75k5r","type":"dois","attributes":{"doi":"10.25497/d75k5r","identifiers":[],"creators":[{"name":"Heffernan, James","nameType":"Personal","givenName":"James","familyName":"Heffernan","affiliation":["Southeast Environmental Research Center, Florida International University"],"nameIdentifiers":[]},{"name":"Ross, Mike","nameType":"Personal","givenName":"Mike","familyName":"Ross","affiliation":["Southeast Environmental Research Center, Florida International University"],"nameIdentifiers":[]},{"name":"Cohen, Matthew","nameType":"Personal","givenName":"Matthew","familyName":"Cohen","affiliation":["School of Forest Resources and Conservation, University of Florida, Gainesville, FL"],"nameIdentifiers":[]},{"name":"Osborne, Todd","nameType":"Personal","givenName":"Todd","familyName":"Osborne","affiliation":["Wetland Biogeochemistry Laboratory, Soil and Water Science Department, University of Florida"],"nameIdentifiers":[]},{"name":"Sah, Jay","nameType":"Personal","givenName":"Jay","familyName":"Sah","affiliation":["Southeast Environmental Research Center, Florida International University"],"nameIdentifiers":[]},{"name":"Scinto, Leonard","nameType":"Personal","givenName":"Leonard","familyName":"Scinto","affiliation":["Southeast Environmental Research Center, Florida International University"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.6 Landscape Pattern - Ridge, Slough, and Tree Island Mosaics 4600001726 Baseline"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"landscape patterns"},{"lang":"en","subject":"ridge and slough"},{"lang":"en","subject":"mosaic"},{"lang":"en","subject":"ridge"},{"lang":"en","subject":"slough"},{"lang":"en","subject":"microtopography"},{"lang":"en","subject":"landscape structure"},{"lang":"en","subject":"vegetation"},{"lang":"en","subject":"hydrology"},{"lang":"en","subject":"soil elevations"},{"lang":"en","subject":"peat production"},{"lang":"en","subject":"sediment entrainment"},{"lang":"en","subject":"sediment deposition"},{"lang":"en","subject":"hydrologic management"},{"lang":"en","subject":"nutrient enrichment"},{"lang":"en","subject":"CERP"},{"lang":"en","subject":"WCA3A"},{"lang":"en","subject":"soil dynamics"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"In the current managed Everglades system, the pre-drainage, patterned mosaic of sawgrass ridges, sloughs and tree islands has been substantially altered or reduced largely as a result of human alterations to historic ecological and hydrological processes that sustained landscape patterns. The pre-compartmentalization ridge and slough landscape was a mosaic of sloughs, elongated sawgrass ridges (50-200m wide), and tree islands. The ridges and sloughs and tree islands were elongated in the direction of the water flow, with roughly equal area of ridge and slough. Over the past decades, the ridge-slough topographic relief and spatial patterning have degraded in many areas of the Everglades. Nutrient enriched areas have become dominated by Typha with little topographic relief; areas of reduced flow have lost the elongated ridge-slough topography; and ponded areas with excessively long hydroperiods have experienced a decline in ridge prevalence and shape, and in the number of tree islands (Sklar et al. 2004, Ogden 2005). \n\nDecoupling of soil elevations from underlying bedrock topography in areas of relatively conserved landscape pattern suggests that historic microtopography and landscape structure were self-organized by feedbacks between vegetation, hydrology, and soil elevations. Potential mechanisms for such positive feedbacks include differential peat production, sediment entrainment and deposition, transpiration-driven nutrient concentration (particularly in tree islands), and hydrologic competence (Larsen et al. 2007, Givnish et al. 2007, Ross et al. 2006, Watts et al in review). While the relative importance of and interactions between these mechanisms remains an active area of research, observations of pattern loss in response to hydrologic management, nutrient enrichment, and other disturbances points to the disruption of those feedbacks as a primary cause of landscape degradation (Sklar et al. 2004). \nThis monitoring project seeks to provide information necessary for the evaluation of efficacy of the Comprehensive Everglades Restoration Program (CERP), as delineated in the Water Resources Development Act (WRDA) of 2000. The work described will provide indices of system-wide applicability of performance measures related to the response of the ridge-slough mosaic, tree islands, and other landscape features of the central Everglades to the restoration of historic hydrologic conditions, with the goal of informing the adaptive management of Everglades restoration as outlined in the CERP Monitoring and Assessment Plan (RECOVER 2004).\n\nThe general goals of restoration are to stem, and possibly reverse, degradation of the ridge-slough-tree island landscape by redirecting flows now released unused to coastal waters across the surface of this landscape (USACE and SFWMD 1999). The CERP MAP, Parts 1 and 2, presented the overarching monitoring framework for guiding restoration efforts throughout the entire process (RECOVER 2004, 2006). This requires not only a comprehensive assessment of the current state of the ecosystem and assessment of restoration endpoints (targets), but also ongoing monitoring and evaluation throughout the process that will aid the implementing agencies in optimizing operational procedures and project designs. The work described below is the first step toward full implementation of the system wide landscape monitoring design that was developed with RECOVER MAP funds and provides for a multi-year monitoring program for the Greater Everglades Wetlands ecosystem. \n\nThe primary objective of this monitoring project is to begin systematic implementation of a landscape sampling design, described below, across the Greater Everglades Wetlands ecosystem. This effort will establish the current condition of the ridge and slough ecosystem and will allow scientists to detect changes/trends in the patterns and vegetation communities of these systems as a result of water management operations, restoration initiatives and episodic events such as droughts, fire and hurricanes. Our secondary objective of this project is to work with other RECOVER researchers to integrate knowledge regarding landscape patterning, soil dynamics and community structure and composition with hydrologic data provided by Everglades Depth Estimation Network (EDEN) and other sources. We will pay particular attention to how these dynamics might: 1) be affected by restoration and 2) relate to CERP hypotheses from the MAP. The resulting data will be utilized to validate existing models and establish or revise restoration targets. \nThis four (4) year monitoring project addresses needs identified in the Greater Everglades wetlands performance measures: 1) Wetland Landscape Patterns â Ridge-Slough Community Sustainability and 2) Wetland Landscape Patterns - Marl Prairie Cape Sable Sparrow Habitat. Our proposal specifically address the Greater Everglades Wetland Landscape and Plant Community Dynamics hypotheses: 1) ridge and slough micro-topography in relation to organic soil accretion and loss, 2) ridge and slough landscape pattern in relation to microtopography, and 3) plant community dynamics along elevation gradients as water depths and thus hydroperiods change (RECOVER 2006). \nThe specific objectives of the proposed work are:\n1) To determine extant reference conditions for each of the performance measures described below (including variability of those measures in time and space).\n2) To establish present status of landscape performance measures throughout the central Everglades, particularly in areas of historic ridge-slough landscape patterning, identify spatial and temporal trends of those performance measures, and quantify their relationships to the present hydrologic regime.\n3) To detect unanticipated changes in ecosystem structure and processes that result from hydrologic management or manipulation, CERP restoration activities, or climatic variation\n4) To provide data in support of scientific studies of inter-relationships among vegetation, microtopography, and hydrologic regime that may provide insight into the causes of unanticipated ecosystem responses.\n\nMonitoring efforts will consist of three core components: (1) mapping vegetation features from aerial photographs, (2) aerial surveys for classification of tree island type, and (3) ground surveys of water depth and plant community structure (both tree island and marsh), which will be used to quantify aspects of the hydrologic regime, determine relationships between vegetation structure and water depth, quantify the distribution and spatial structure of peat elevations, and ground-truth broader-scale maps based on remote sensing and aerial surveys.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D75K5R","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:25:24Z","registered":"2022-10-07T00:25:24Z","published":null,"updated":"2024-08-13T17:22:10Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7x30v","type":"dois","attributes":{"doi":"10.25497/d7x30v","identifiers":[],"creators":[{"name":"Gann, Daniel","nameType":"Personal","givenName":"Daniel","familyName":"Gann","affiliation":["FIU Geographic Information Systems and Remote Sensing Center"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.1.3.4 Lanscape Pattern Vegetation Mapping with Worldview 2 Imagery"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"Vegetation mapping"},{"lang":"en","subject":"Vegetation classification"},{"lang":"en","subject":"satellite imagery"},{"lang":"en","subject":"Digital Globe WorldView 2 imagery"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"RECOVER supports assessment of vegetation community structure and landscape pattern via various means: ground truthing and related mapping of field morphometrics, community and species identification along elevation gradients (marl prairie to ridge and slough gradients), and community typing via photogrammetry. The focus of this initiative is on methods development using new satellite imagery (with greater spectral and spatial resolution). New imagery and new methods (including technological advancements) make remote sensing using the Digital Globe WorldView 2 imagery a strong candidate to track landscape and vegetative change within the Everglades CERP footprint. Information gained from this and related efforts is expected to provide future guidance relevant to CERP project implementation and structure operations. This scope is written as part of the RECOVER Monitoring and Assessment Plan (MAP) section 3.1.3 and 3.1.4. The objectives include:\nâ ¢ Develop vegetation/landscape community maps and assess effectiveness of mapping using WorldView 2 imagery.\n1) Acquire needed imagery (in consultation with RECOVER GE working group to determine most relevant areas of expected change given expected CERP project sequencing and implementation. As well as considering the location of available or expected ground truthing information- GRTS panels, marl prairie- slough transects and photogrammetric mapping in ENP).\n2) Create map above and below Tamiami trail upstream and downstream of 1 mile bridge\n3) Create map of Ridge and Slough, Tree Island, wet prairie habitat in WCA3A (using the same panels as the RECOVER R\u0026amp;S landscape contract- Heffernan)\n\nâ ¢ Investigate and characterize the spectral and metric qualities of the Worldview-2 data as related to specific aspects of the sensor, data acquisition, and level of processing (including available band combinations, angle of acquisition, sun elevation angle, method of geo-referencing, etc).\nâ ¢ Investigate and characterize the outcome of spatial re-sampling on the spectral integrity of the imagery and on the type of landscape information that can be derived at various spatial scales with the intent of comparing the results to similar work of this type (e.g. 30 m Landsat classification of the Everglades.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7X30V","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:27:41Z","registered":"2022-10-07T00:27:41Z","published":null,"updated":"2024-08-12T21:59:55Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7s88c","type":"dois","attributes":{"doi":"10.25497/d7s88c","identifiers":[],"creators":[{"name":"Browder, Joan","nameType":"Personal","givenName":"Joan","familyName":"Browder","affiliation":["National Marine Fisheries Service, Southeast Fisheries Center, National Oceanic and Atmospheric Administration"],"nameIdentifiers":[]},{"name":"Robblee, Michael B.","nameType":"Personal","givenName":"Michael B.","familyName":"Robblee","affiliation":["Center for Water and Restoration Studies, United States Geological Survey"],"nameIdentifiers":[]},{"name":"Graves, Greg","nameType":"Personal","givenName":"Greg","familyName":"Graves","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.2.3.5 \u0026amp; 3.2.4.5 Epifaunal Communities of Mainland Nearshore South Biscayne Bay"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"epifaunal communities"},{"lang":"en","subject":"Biscayne Bay"},{"lang":"en","subject":"fauna"},{"lang":"en","subject":"nearshore"},{"lang":"en","subject":"pink shrimp"},{"lang":"en","subject":"pipefish"},{"lang":"en","subject":"Farfantepenaeus duorarum"},{"lang":"en","subject":"Penaeid shrimp"},{"lang":"en","subject":"Caridean shrimp"},{"lang":"en","subject":"crab"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"Biscayne Bayâ s benthic community is a primary source of its productivity and diversity. The benthic faunal community, consisting of small forage fish, juvenile game fish, and invertebrates such as pink shrimp, is particularly well developed in the shallow nearshore zone adjacent to the mainland and may be dependent, either directly or indirectly, upon freshwater inflow to the bay. Many small forage fish are found more abundantly in the shallow nearshore waters than in the deeper waters of the bay. The commercially important pink shrimp and blue crab also are found in western nearshore Biscayne Bay. Caridean shrimps form another important component of the epifauna. The epifaunal community is a direct food source for gray snapper, spotted seatrout, and great barracuda. It is an important link in the food web that leads to higher trophic level species such as crocodiles. This community will be the first to change when the Biscayne Bay Coastal Wetlands projects are started. A dynamic characterization of this community and how its components vary along the shoreline is needed to provide baseline information for evaluating CERP.\nIn a first view of our sample data from the community perspective, we addressed determining (1) whether sites nearest to each had more similar species compositions and (2) whether species with similar salinity requirements would have similar geographic distributions. The data were investigated with cluster analyses and multidimensional scaling to gain these perspectives.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7S88C","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:28:43Z","registered":"2022-10-07T00:28:44Z","published":null,"updated":"2024-08-12T21:58:50Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7nk53","type":"dois","attributes":{"doi":"10.25497/d7nk53","identifiers":[],"creators":[{"name":"Serafy, Joseph","nameType":"Personal","givenName":"Joseph","familyName":"Serafy","affiliation":["National Marine Fisheries Service, Southeast Fisheries Center, National Oceanic and Atmospheric Administration"],"nameIdentifiers":[]},{"name":"Graves, Greg","nameType":"Personal","givenName":"Greg","familyName":"Graves","affiliation":["South Florida Water Management District"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.2.3.6 Shoreline Fish Community Visual Assessment"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"Biscayne Bay"},{"lang":"en","subject":"Card Sound"},{"lang":"en","subject":"Barnes Sound"},{"lang":"en","subject":"fish"},{"lang":"en","subject":"fauna"},{"lang":"en","subject":"shoreline"},{"lang":"en","subject":"Lutjanus griseus"},{"lang":"en","subject":"gray snapper"},{"lang":"en","subject":"Sphyraena barracuda"},{"lang":"en","subject":"great barracuda"},{"lang":"en","subject":"Gerres cinereus"},{"lang":"en","subject":"yellowfin mojarra"},{"lang":"en","subject":"Eucinostomus spp."},{"lang":"en","subject":"mojarras"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"The purpose of this study is to perform data analyses that evaluate variability in Biscayne Bay, Card Sound, and Barnes Sound fish communities before, during, and after CERP-related changes to freshwater flow and salinity are implemented; and to correlate changes in salinity regime with changes in the shoreline ichthyofauna. Species-specific abundance (occurrence, concentration, and delta density) and community taxonomic richness and dominance metrics were determined. Time series of abundance metrics were constructed of four fish taxa: Lutjanus griseus (gray snapper), Sphyraena barracuda (great barracuda), Gerres cinereus (yellowfin mojarra), and Eucinostomus spp. (small mojarras). Mean seasonal levels, with 95% confidence intervals, of each fish metric were generated from 1998 through 2009 and these were plotted for the mainland shoreline and its component segments, as well as for shorelines on the leeward side of Sands and Elliot Keys on Biscayne Bayâ s eastern boundary.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7NK53","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:29:47Z","registered":"2022-10-07T00:29:48Z","published":null,"updated":"2024-08-12T21:57:50Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}},{"id":"10.25497/d7hs35","type":"dois","attributes":{"doi":"10.25497/d7hs35","identifiers":[],"creators":[{"name":"Tunberg, Bjorn G.","nameType":"Personal","givenName":"Bjorn G.","familyName":"Tunberg","affiliation":["Smithsonian Marine Station"],"nameIdentifiers":[]}],"titles":[{"lang":"en","title":"RECOVER MAP 3.3.3.8 Benthic Macroinvertebrate Monitoring"}],"publisher":"CERP - South Florida Water Management District","container":{},"publicationYear":2022,"subjects":[{"lang":"en","subject":"St. Lucie Estuary"},{"lang":"en","subject":"Southern Indian River Lagoon"},{"lang":"en","subject":"benthos"},{"lang":"en","subject":"benthic"},{"lang":"en","subject":"infaunal"},{"lang":"en","subject":"macroinvertebrates"},{"lang":"en","subject":"sediment"},{"lang":"en","subject":"water quality"},{"lang":"en","subject":"Oligochaeta"},{"lang":"en","subject":"Chironomidae"},{"lang":"en","subject":"Diptera"},{"lang":"en","subject":"aquatic worms"},{"lang":"en","subject":"non-biting midges"},{"lang":"en","subject":"chironomids"},{"lang":"en","subject":"salinity"}],"contributors":[],"dates":[{"date":"2022","dateType":"Issued"}],"language":"en","types":{"ris":"DATA","bibtex":"misc","citeproc":"dataset","schemaOrg":"Dataset","resourceTypeGeneral":"Dataset"},"relatedIdentifiers":[],"relatedItems":[],"sizes":[],"formats":["text/xml"],"version":null,"rightsList":[],"descriptions":[{"lang":"en","description":"Benthos may be valued in terms of their links with other resources, as well as containing representatives which are themselves commercially harvested (e.g., crabs, shrimps, flatfish). Unlike many other biotic or chemical measures, benthos reflect environmental conditions at specific areas because adults of most benthic invertebrate species are either sessile or of limited mobility. As constant features of the bottom sediments, benthos vary predictably in association with the physical habitat and in response to man made changes. Thus, they are good indicators of locally induced environmental changes.","descriptionType":"Abstract"}],"geoLocations":[],"fundingReferences":[],"url":"https://cerp-sfwmd.dataone.org/view/doi:10.25497/D7HS35","contentUrl":null,"metadataVersion":3,"schemaVersion":"http://datacite.org/schema/kernel-4","source":"mds","isActive":true,"state":"findable","reason":null,"viewCount":0,"downloadCount":0,"referenceCount":0,"citationCount":0,"partCount":0,"partOfCount":0,"versionCount":0,"versionOfCount":0,"created":"2022-10-07T00:30:51Z","registered":"2022-10-07T00:30:52Z","published":null,"updated":"2024-08-12T21:56:05Z"},"relationships":{"client":{"data":{"id":"cdl.ucsb","type":"clients"}}}}],"meta":{"total":120,"totalPages":5,"page":1},"links":{"self":"https://api.datacite.org/dois?prefix=10.25497","next":"https://api.datacite.org/dois?page%5Bnumber%5D=2\u0026page%5Bsize%5D=25\u0026prefix=10.25497"}}