Spatial information on the arrangement of geological features, habitats and living marine resources on the seabed are often the foundation for decision-making in ecosystem management and ocean planning. Collecting information on the seabed depths and geomorphology is an expensive operation requiring airborne platforms like satellites, planes or drones, or small vessels to large research ships. Coordinating these data needs and data collection efforts will better leverage collective resources and meet shared goals. To help enable this coordination, in 2020 the National Oceanic and Atmospheric Administration (NOAA) National Centers for Coastal Ocean Science (NCCOS) developed a spatial framework, process, and online application to identify common data collection priorities for seafloor mapping, sampling, and visual surveys along shore and offshore of the Southeast United States (North Carolina, South Carolina, and Georgia). Twenty-five representatives from federal and state agencies, academic institutions, and non-governmental conservation groups, designated seafloor mapping priorities using an online prioritization tool. Participants allocated virtual coins across 5 km x 5 km grid cells to denote their organization’s regions of seafloor mapping needs. Grid cells with more coins were higher priorities than cells with fewer coins. Participants also reported why these locations were important and what data types were needed. Results were analyzed and mapped using statistical techniques to identify significant relationships between priorities, reasons for those priorities and data needs. These data are the summarized results from this project and can also be viewed in an online web map (https://noaa.maps.arcgis.com/apps/webappviewer/index.html?id=04cdd2a68c4f427f893f2042f326dc80). Several common areas of interest were identified in the spatially explicit analysis of the responses. Nearshore surfzone along Georgia, South Carolina, and North Carolina were highlighted by several agencies and organizations interested in sediment and sand resources as well as potential for rocky reef habitats. Inshore estuarine areas were highlighted by state agencies and conservation groups interested in monitoring change in managed areas like National Estuarine Reserves. On the outer continental shelf, areas near Blake Plateau off South Carolina and the continental shelf break off North Carolina were identified by federal agencies and conservation organizations as areas of sensitive habitats or historically significantly shipwrecks and maritime resources. The seafloor mapping prioritization approach described in the Buckel et al. (2021) report associated with these data provides recommendations to organizations charged with mapping the seabed for navigation and commerce as well as resource assessments and management. Already, the priority areas identified in this exercise are being used by NOAA to focus planned seafloor mapping missions. Furthermore, the outcomes from this regional exercise contribute into a National Mapping Prioritization under the lead of NOAA to coordinate mapping activities across the entire US EEZ. Together, these quantitative seafloor mapping prioritization approaches will enable improved coordination and more efficient allocation of resources needed to conduct seafloor mapping providing data to support environmental stewardship, safe navigation and commerce.

This layer is intended to represent the geographic extent of NOAA Fisheries’ Northern California Current Ecosystem Survey transects. The Northern California Current Ecosystem Surveys started in 1996 and is led by NMFS Northwest Fisheries Science Center. These surveys expand the biophysical sampling conducted along the Newport Line out to the edge of the U.S. Exclusive Economic Zone. These surveys help us understand lower trophic level responses to environmental variability across the Pacific Northwest and California Current ecosystem. We also incorporate information on the abundance and distribution of mid-trophic level nekton, marine mammals, and birds. These samples inform broad-scale analyses of hydrography, phytoplankton, zooplankton, larval and juvenile fish, and ocean acidification and hypoxia. This survey is also part of a larger collaboration with Oregon State University researchers studying the marine biodiversity and size structure across broad spatial scales in the northern California Current. The Northern California Current Ecosystem Survey samples seasonally from northern Washington to the Oregon/California border, and offshore to 200 nautical miles off Newport, Oregon and 150 nautical miles off Crescent City, California on the NOAA Ship Bell M. Shimada. Seasonal sampling efforts include CTD, acoustic transects, zooplankton, ichthyoplankton, and macro-plankton sampling via bongo and Methot nets, as well as midwater and beam trawls.

This layer is intended to represent the geographic extent of NOAA Fisheries’ Northern California Current Ecosystem Survey stations. The Northern California Current Ecosystem Surveys started in 1996 and is led by NMFS Northwest Fisheries Science Center. These surveys expand the biophysical sampling conducted along the Newport Line out to the edge of the U.S. Exclusive Economic Zone. These surveys help us understand lower trophic level responses to environmental variability across the Pacific Northwest and California Current ecosystem. We also incorporate information on the abundance and distribution of mid-trophic level nekton, marine mammals, and birds. These samples inform broad-scale analyses of hydrography, phytoplankton, zooplankton, larval and juvenile fish, and ocean acidification and hypoxia. This survey is also part of a larger collaboration with Oregon State University researchers studying the marine biodiversity and size structure across broad spatial scales in the northern California Current. The Northern California Current Ecosystem Survey samples seasonally from northern Washington to the Oregon/California border, and offshore to 200 nautical miles off Newport, Oregon and 150 nautical miles off Crescent City, California on the NOAA Ship Bell M. Shimada. Seasonal sampling efforts include CTD, acoustic transects, zooplankton, ichthyoplankton, and macro-plankton sampling via bongo and Methot nets, as well as midwater and beam trawls.

This layer is intended to represent the geographic extent of NOAA Fisheries’ California Current Cetacean and Ecosystem Assessment Survey. The California Current Cetacean and Ecosystem Assessment Survey started in 1991 and is led by NMFS Southwest Fisheries Science Center. This survey includes ship-, aerial-, and land-based surveys of marine mammals throughout the California Current Large Marine Ecosystem. Survey data have been used to estimate cetacean population size and trends, delineate cetacean population stock structure, describe cetacean and seabird distributions and hotspots, develop species distribution models, and inform marine mammal stock assessment reports pursuant to statutory requirements under the Marine Mammal Protection Act (MMPA). Research vessels conduct line-transect surveys, typically every three years, in summer and fall and span waters out 300 nautical miles offshore, from the US-Canada to US-Mexico border. NOAA research vessels (David Starr Jordan, McArthur, McArthur II, Reuben Lasker, Bell M. Shimada) collect visual sightings data for cetaceans and seabirds, passive acoustic (e.g., towed or drifting array) data for cetaceans, tissue biopsy sampling used for genetics analysis, and oceanographic sampling.

This layer is intended to represent the geographic extent of NOAA Fisheries’ California Current Ecosystem Survey. The California Current Ecosystem Survey started in 2006 and is led by NMFS Southwest Fisheries Science Center. This survey monitors West Coast coastal pelagic fish species (CPS) including the northern and central sub-populations of Northern Anchovy, the northern subpopulation of Pacific Sardine, Jack Mackerel, Pacific Mackerel, Pacific Herring, their prey items, and the biotic and abiotic environments of the California Current Ecosystem. These data are used to estimate the distribution, biomass, and demographics of species of interest to inform stock assessments. The CCES survey typically occurs annually between July and September on the West Coast of the U.S. and Canada, with a recent expansion into Mexico thanks to a collaboration with the Instituto Mexicano Investigación en Pesca y Acuacultura Sustentables (IMIPAS, formerly INAPESCA). During the day multifrequency, scientific echosounders, a continuous underway fish egg sampler (CUFES), and an underway conductivity-temperature-depth (UCTD) probe are all used to collect data. At night, surface trawls are conducted in locations where coastal pelagic species were observed acoustically during the day. The trawls serve to estimate the species composition and demographics of the fishes sampled acoustically during the day. In recent years, sampling from NOAA ships has been augmented with acoustic sampling by unmanned surface vehicles (Saildrone USVs), and with acoustic and purse-seine sampling from industry fishing vessels off WA, OR, and CA. The sampling from fishing vessels expands the survey into areas that are inhabited by CPS but are too shallow for the NOAA ships to safely navigate.

This layer is intended to represent information collected during NOAA Fisheries’ California Current Ecosystem Survey. The California Current Ecosystem Survey started in 2006 and is led by NMFS Southwest Fisheries Science Center. This survey monitors West Coast coastal pelagic fish species (CPS) including the northern and central sub-populations of Northern Anchovy, the northern subpopulation of Pacific Sardine, Jack Mackerel, Pacific Mackerel, Pacific Herring, their prey items, and the biotic and abiotic environments of the California Current Ecosystem. These data are used to estimate the distribution, biomass, and demographics of species of interest to inform stock assessments. The CCES survey typically occurs annually between July and September on the West Coast of the U.S. and Canada, with a recent expansion into Mexico thanks to a collaboration with the Instituto Mexicano Investigación en Pesca y Acuacultura Sustentables (IMIPAS, formerly INAPESCA). During the day multifrequency, scientific echosounders, a continuous underway fish egg sampler (CUFES), and an underway conductivity-temperature-depth (UCTD) probe are all used to collect data. At night, surface trawls are conducted in locations where coastal pelagic species were observed acoustically during the day. The trawls serve to estimate the species composition and demographics of the fishes sampled acoustically during the day. In recent years, sampling from NOAA ships has been augmented with acoustic sampling by unmanned surface vehicles (Saildrone USVs), and with acoustic and purse-seine sampling from industry fishing vessels off WA, OR, and CA. The sampling from fishing vessels expands the survey into areas that are inhabited by CPS but are too shallow for the NOAA ships to safely navigate.

NOAA's Coral Reef Conservation Program (CRCP) has identified a need for priority locations based on emerging management requirements in shallow coral reef areas (up to 40 meters) surrounding the main Hawaiian Islands. The priorities provided by participating agencies will inform research and monitoring activities, address current and future management needs, and maximize opportunities to leverage and complement existing regional efforts. To meet this need, NOAAs National Centers for Coastal Ocean Science (NCCOS) developed a systematic, quantitative approach and online GIS application to gather seafloor mapping priorities from researchers and coral reef managers. Participants placed virtual coins into a grid overlaid on the project area to express the location of their mapping priorities. They also used pull-down menus to indicate specific mapping data needs and the rationale for their selections. Participants inputs were compiled and analyzed to identify high priority areas along with their justifications and requirements. A total of 17 participant groups entered their mapping priorities into the online tool. Identifying these high priority areas provide a critical spatial framework for prioritizing mapping efforts in shallow coral reef ecosystems in Hawaii.

The NOAA Coastal Change Analysis Program (C-CAP) produces national standardized land cover and change products for the coastal regions of the U.S. C-CAP products inventory coastal intertidal areas, wetlands, and adjacent uplands with the goal of monitoring changes in these habitats, on a one-to-five year repeat cycle. The timeframe for this metadata is reported as 2006-Era, but the actual dates of the Landsat imagery used to create the land cover may have been acquired a few years before or after each era. These maps are developed utilizing Landsat Thematic Mapper imagery, and can be used to track changes in the landscape through time. This trend information gives important feedback to managers on the success or failure of management policies and programs and aid in developing a scientific understanding of the Earth system and its response to natural and human-induced changes. This understanding allows for the prediction of impacts due to these changes and the assessment of their cumulative effects, helping coastal resource managers make more informed regional decisions. NOAA C-CAP is a contributing member to the Multi-Resolution Land Characteristics consortium and C-CAP products are included as the coastal expression of land cover within the National Land Cover Database.

The NOAA Coastal Change Analysis Program (C-CAP) produces national standardized land cover and change products for the coastal regions of the U.S. C-CAP products inventory coastal intertidal areas, wetlands, and adjacent uplands with the goal of monitoring changes in these habitats, on a one-to-five year repeat cycle. The timeframe for this metadata is reported as 2016-Era, but the actual dates of the Landsat imagery used to create the land cover may have been acquired a few years before or after each era. These maps are developed utilizing Landsat Thematic Mapper imagery, and can be used to track changes in the landscape through time. This trend information gives important feedback to managers on the success or failure of management policies and programs and aid in developing a scientific understanding of the Earth system and its response to natural and human-induced changes. This understanding allows for the prediction of impacts due to these changes and the assessment of their cumulative effects, helping coastal resource managers make more informed regional decisions. NOAA C-CAP is a contributing member to the Multi-Resolution Land Characteristics consortium and C-CAP products are included as the coastal expression of land cover within the National Land Cover Database.

The NOAA Coastal Change Analysis Program (C-CAP) produces national standardized land cover and change products for the coastal regions of the U.S. C-CAP products inventory coastal intertidal areas, wetlands, and adjacent uplands with the goal of monitoring changes in these habitats, on a one-to-five year repeat cycle. The timeframe for this metadata is reported as 1985-Era, but the actual dates of the Landsat imagery used to create the land cover may have been acquired a few years before or after each era. These maps are developed utilizing Landsat Thematic Mapper imagery, and can be used to track changes in the landscape through time. This trend information gives important feedback to managers on the success or failure of management policies and programs and aid in developing a scientific understanding of the Earth system and its response to natural and human-induced changes. This understanding allows for the prediction of impacts due to these changes and the assessment of their cumulative effects, helping coastal resource managers make more informed regional decisions. NOAA C-CAP is a contributing member to the Multi-Resolution Land Characteristics consortium and C-CAP products are included as the coastal expression of land cover within the National Land Cover Database.