With support from the New York Energy Research and Development Authority (NYSERDA) and the U.S. Department of Energy, the Regional Synthesis Workgroup has created a database that compiles and synthesizes data gaps and research needs from existing sources relevant to the environmental effects of offshore wind energy development on the U.S. Atlantic Coast. The database allows researchers and funders to easily access, sort, and prioritize research recommendations.
The Regional Synthesis Workgroup is made up of independent scientific experts and was formed by the New York State Environmental Technical Working Group to inform and provide guidance for regional-scale research and monitoring efforts in the eastern U.S. in relation to wildlife and offshore wind energy development. The database was developed for the Regional Synthesis Workgroup by the Biodiversity Research Institute and the U.S. Offshore Wind Synthesis of Environmental Effects Research (SEER) group. The team compiled over 800 research recommendations from over 60 sources, and then condensed these into roughly 220 synthesized research recommendations. The database design and content were shaped by input from the Regional Synthesis Workgroup, as well as stakeholder input from a public meeting in September 2022 (recording) and online survey in Fall 2022. To complement the database, the Workgroup developed written guidance, "Responsible Practices for Regional Wildlife Monitoring and Research in Relation to Offshore Wind Development", which focuses on recommendations for regional research and includes definitions of common terminology to support regional communications, suggested criteria for prioritization of regional research topics, and general recommendations on study design and data transparency for regional-scale research efforts.
The Database ReadMe File provides a summary of database contents, definitions of database fields, and additional information on the scope, development, and use of the database, as well as a suggested citation for the database. We strongly encourage reference to this document.
The online tool below presents a summary of the synthesized research recommendations and provides links to relevant citations. Results can be refined by selecting from the drop-down menus or entering a search term. Synthesized research recommendations are ordered alphabetically. The order does not signify the importance or priority of each recommendation.
Download the complete database as a spreadsheet here.
Download the synthesized recommendations below as a spreadsheet here.
A similar database for the U.S. Pacific Coast is available here.
| Research Recommendation | Stressor/Topic | Receptor | Development Phase | Citations |
|---|---|---|---|---|
| Collect baseline information about nocturnal activity
Extract nocturnal flight activity from existing bird telemetry data to inform estimate of nocturnal collisions. |
Baseline, Abundance and Distribution | Birds | Joint Nature Conservation Committee (JNCC) 2021 | |
| Collect baseline information about species distribution and abundance
Collect baseline data that describes the distribution and abundance and animals offshore and how this changes throughout space and time |
Baseline, Abundance and Distribution | Bats, Benthos, Birds, Fishes, Invertebrates, Marine mammals, Sea turtles | Pre-construction, Construction, Operations & Maintenance, Decommissioning | Allison et al. 2019, Bureau of Ocean Energy Management (BOEM) 2022, Bonacci-Sullivan 2018, Brodie et al. 2021, Cook et al. 2021, Gitschlag et al. 2021, Gulka and Williams 2020, Hein et al. 2021, Joint Nature Conservation Committee (JNCC) 2021, Kraus et al. 2019, Massachusetts Division of Marine Fisheries 2018, New Jersey Department of Environmental Protection Office of Science 2021, Abercrombie and Chytalo 2017, New York State Energy Research and Development Authority (NYSERDA) 2015, New York State Energy Research and Development Authority (NYSERDA) 2020, Petruny-Parker et al. 2015, Southall et al. 2021, State of Maine 2021, Van Parijs et al. 2021, Wildlife Conservation Society 2021 |
| Collect baseline information about vocalization behavior
Identify baseline vocalization behavior |
Baseline, Movement and Behavior | Marine mammals | Pre-construction | Southall et al. 2021 |
| Collect baseline information of oceanographic parameters
Measure pH, water clarity, and dissolved oxygen when conducting surveys from the surface to sea floor. |
Baseline, Ecological Drivers | Ecosystem/Oceanographic processes | Pre-construction, Operations & Maintenance | Brodie et al. 2021 |
| Collect baseline information on underwater sounds
Characterize the ambient noise levels in the ocean for historic conditions, present day, and predicted future scenarios considering climate change. |
Baseline, Noise | Fishes, Invertebrates, Marine mammals | Pre-construction | Di Franco et al. 2020, New York State Energy Research and Development Authority (NYSERDA) 2015 |
| Collect data on zooplankton distribution and shifts over time
Conduct modeling or sampling to better understand zooplankton distribution and shifts over time |
Baseline, Abundance and Distribution | Invertebrates | Pre-construction | Boon et al. 2018, Kraus et al. 2019 |
| Collect information on the spatial distribution of habitat and oceanographic features
Characterize the spatial distribution of habitat and oceanographic features through mapping, measurement, and sampling. This includes characterization and sampling of benthic and fish habitat as well as the physical and chemical features. |
Baseline, Ecological Drivers | Benthos, Ecosystem/Oceanographic processes, Fishes, Invertebrates | Pre-construction | Brodie et al. 2021, Degraer et al. 2021, Joint Nature Conservation Committee (JNCC) 2021, Massachusetts Division of Marine Fisheries 2018, New England Fishery Management Council 2021, New Jersey Department of Environmental Protection Office of Science 2021, New York State Energy Research and Development Authority (NYSERDA) 2015, Petruny-Parker et al. 2015 |
| Compare factors influencing seabed recovery
Explore recovery of the seafloor following construction-related disturbance at multiple OSW sites in relation to variables such as seabed properties, local hydrodynamics, and type of disturbance. |
Habitat Change, Oceanographic/Atmospheric Change | Benthos, Ecosystem/Oceanographic processes | Operations & Maintenance, Decommissioning | Degraer et al. 2021, Massachusetts Division of Marine Fisheries 2018 |
| Compare high-intensity noise exposure with OSW and non-OSW activities
Evaluate relative threat of serious injury (PTS) from high-intensity noise exposure associated with OSW and non-OSW activities |
Noise | Marine mammals | Construction | Southall et al. 2021 |
| Compare responses to pile-driving noise using different foundations or piling technologies
Examine animal responses concurrent with measurement of underwater noise to estimate received levels and PTS ranges in relation to different types of piling activity, including comparison between sheet piling & vibro-piling, variation based on pile size, and changes in response as the use of...Read more Examine animal responses concurrent with measurement of underwater noise to estimate received levels and PTS ranges in relation to different types of piling activity, including comparison between sheet piling & vibro-piling, variation based on pile size, and changes in response as the use of noise mitigation techniques changes. Read less |
Noise | Marine mammals | Construction, Operations & Maintenance | Gulka and Williams 2020, Joint Nature Conservation Committee (JNCC) 2021 |
| Compare structural and functional ecology of various substrata
Understand the comparative habitat and community structure/function provisioning of offshore infrastructure and other forms of substrata (i.e., based on location, design, materials, and environmental factors), including the ability to provide significant habitat for ecologically- and commercially...Read more Understand the comparative habitat and community structure/function provisioning of offshore infrastructure and other forms of substrata (i.e., based on location, design, materials, and environmental factors), including the ability to provide significant habitat for ecologically- and commercially-important species (e.g., rare or protected species; exotic or invasive species, fishery-important species) and related biological metrics (e.g., biomass, productivity, biodiversity, algal grazing, benthic enrichment) comparisons for reef-associated mobile species. Read less |
Habitat Change | Benthos, Ecosystem/Oceanographic processes, Fishes, Invertebrates | Construction, Operations & Maintenance | Boon et al. 2018, Carey et al. 2020, Degraer et al. 2017, Degraer et al. 2021, Fowler et al. 2020, Joint Nature Conservation Committee (JNCC) 2021, Massachusetts Division of Marine Fisheries 2018, Responsible Offshore Development Alliance (RODA) 2021 |
| Coordinate research and monitoring
Coordinate data collection and synthesis of existing data efforts at a regional scale including baseline data, population monitoring, and data collected at individual OSW project sites (e.g., post-construction monitoring data)....Read more Coordinate data collection and synthesis of existing data efforts at a regional scale including baseline data, population monitoring, and data collected at individual OSW project sites (e.g., post-construction monitoring data). Coordination also includes linking efforts across groups (e.g., researchers, developers, state and federal agencies) and pooling data to have the statistical power to examine regional-scale effects. Read less |
Data Management | Bats, Benthos, Birds, Ecosystem/Oceanographic processes, Marine mammals, Sea turtles | Pre-construction, Operations & Maintenance | Allison et al. 2019, Bonacci-Sullivan 2018, Brodie et al. 2021, Carpenter et al. 2021, Degraer et al. 2021, Joint Nature Conservation Committee (JNCC) 2021 |
| Create an inventory of all current tagging/tracking data and programs
Create an inventory of all ongoing tracking projects for seabirds and marine mammals to encourage a coordinated approach to making research results compatible, available and applicable in Marine Spatial Planning, particularly concerning OSW energy development. |
Data Management | Birds, Marine mammals | Joint Nature Conservation Committee (JNCC) 2021 | |
| Define site-specific wildlife and OSW assessment goals
Define site-specific wildlife and marine wind energy assessment goals for a better understanding of information needed to guide the permitting process for marine wind energy projects....Read more Define site-specific wildlife and marine wind energy assessment goals for a better understanding of information needed to guide the permitting process for marine wind energy projects. Building on current projects and traditional knowledge, identify data gaps and research, survey and monitoring needs to better understand how OSW energy infrastructure installation, transmission, maintenance and decommission are likely to affect wildlife, including benefits to wildlife through the replacement of traditional fossil fuel energy sources. Read less |
Technology/ Methods Development | Bats, Birds, Fishes, Marine mammals, Sea turtles | Construction, Operations & Maintenance, Decommissioning | Abercrombie and Chytalo 2017 |
| Define the geographic scale of fish species populations for impact assessments
Develop guidance on assessing fish population losses for impact assessments taking into consideration inconsistencies between the spatial structure of biological populations and fishery stock units....Read more Develop guidance on assessing fish population losses for impact assessments taking into consideration inconsistencies between the spatial structure of biological populations and fishery stock units. Large fisheries management units are increasingly unlikely to provide appropriate baselines when assessing fish populations or as prey species for protected marine mammals and seabirds. Read less |
Technology/ Methods Development, Population Dynamics | Fishes | Joint Nature Conservation Committee (JNCC) 2021 | |
| Design an impact reduction decision support tool
Design an impact reduction decision support tool to assist in designing practicable mitigation strategies across different scenarios |
Technology/ Methods Development | Bats | Hein and Straw 2021 | |
| Design studies whereby data can directly inform population models
Research studies on the impact of wind energy installations should be designed in such a way that data can directly inform population model parameters, including population consequences of disturbance (PCoD) or population consequences of multiple stressors (PCoMS) models....Read more Research studies on the impact of wind energy installations should be designed in such a way that data can directly inform population model parameters, including population consequences of disturbance (PCoD) or population consequences of multiple stressors (PCoMS) models. This means that specific parameters for these models should be considered with each investigation. Read less |
Technology/ Methods Development, Population Dynamics | Marine mammals | Kraus et al. 2019 | |
| Determine atmospheric effects associated with OSW energy
Understand atmospheric effects associated with energy removal by wind turbines. |
Oceanographic/Atmospheric Change | Ecosystem/Oceanographic processes | Construction, Operations & Maintenance | Responsible Offshore Development Alliance (RODA) 2021 |
| Determine biological removal rates that populations can withstand
Assess whether the number of bats at risk of collisions at OSW farms is sufficient to influence population trajectories. |
Turbine collision, Population Dynamics | Bats | Operations & Maintenance | WOZEP project team 2016 |
| Determine cause of attraction to turbines
Determine what causes bat attraction to wind farms and how this relates to flight height, collision risk, and time spent at wind farms. |
Attraction | Bats | Operations & Maintenance | WOZEP project team 2016 |
| Determine cumulative effects of cables at OSW farms
Assess the ecological function beneath cable protection (e.g., infilling or colonization of rock protection) for various protection measures and the effects of cables (e.g., EMF) associated with wind infrastructure |
Cumulative Impacts | Benthos, Fishes | Operations & Maintenance | Joint Nature Conservation Committee (JNCC) 2021 |
| Determine ecological drivers of distribution and movement patterns
Identify how ecological drivers and environmental factors influence the distribution and movement of animals |
Ecological Drivers, Abundance and Distribution, Baseline | Benthos, Birds, Fishes, Invertebrates, Marine mammals, Sea turtles | Pre-construction, Construction, Operations & Maintenance, Decommissioning | Cook et al. 2021, Degraer et al. 2021, Gitschlag et al. 2021, Gulka and Williams 2020, New York State Energy Research and Development Authority (NYSERDA) 2015, Southall et al. 2021, WOZEP project team 2016 |
| Determine ecological impacts of artificial habitat on soft-sediment ecosystems
Assess the benthic ecological impacts of infrastructure habitat on surrounding soft-sediment ecosystems, including biodiversity tradeoffs before construction and recovery after full removal of an offshore installation. |
Habitat Change | Benthos | Decommissioning | Fowler et al. 2020 |
| Determine how wind farm design affects avoidance/displacement
Determine how displacement and macro- to meso-avoidance of individual bird species is linked to the spatial configuration of turbines |
Avoidance, Displacement | Birds | Operations & Maintenance | Joint Nature Conservation Committee (JNCC) 2021, WOZEP project team 2016 |
| Determine hydrodynamic/oceanographic effects of structures
Assess the effects of multiple OSW facilities on oceanographic processes (e.g., production of turbulence, currents, temperature, seasonal stratification, sediment scour) and coupling of the hydrodynamics with water quality and ecosystems, including nutrient cycling. |
Oceanographic/Atmospheric Change | Benthos, Ecosystem/Oceanographic processes, Fishes, Invertebrates | Pre-construction, Construction, Operations & Maintenance, Decommissioning | Bureau of Ocean Energy Management (BOEM) 2022, Boon et al. 2018, Brodie et al. 2021, Dannheim et al. 2020, Degraer et al. 2021, Joint Nature Conservation Committee (JNCC) 2021, Massachusetts Division of Marine Fisheries 2018, Miles et al. 2021, New Jersey Department of Environmental Protection Office of Science 2021, New York State Energy Research and Development Authority (NYSERDA) 2015, Petruny-Parker et al. 2015, Piet et al. 2021, Responsible Offshore Development Alliance (RODA) 2021 |
| Determine if changes around OSW infrastructure affect regional-scale biodiversity
Assess how local biodiversity on OSW infrastructure contributes to regional diversity through movement of mobile organisms or larval dispersal. |
Cumulative Impacts | Benthos | Decommissioning | Fowler et al. 2020 |
| Determine level of disruption to spawning activities
Examine whether habitat changes from OSW development affect populations of managed species through temporary disruption of spawning behavior |
Habitat Change, Movement and Behavior | Fishes, Invertebrates | Construction, Operations & Maintenance, Decommissioning | Gulka and Williams 2020 |
| Determine physical effects of infrastructure habitat on surrounding soft-sediment ecosystems
Assess the physical effects of OSW infrastructure habitat on surrounding soft-sediment ecosystems to inform decommissioning considerations |
Habitat Change | Benthos | Decommissioning | Fowler et al. 2020 |
| Determine the duration of sound-related effects in relation to species mobility
Assess the potential for recovery, habituation, and adaptation to noise in relation to species mobility or other features, in order to help understand the duration/longevity of responses |
Noise | Fishes, Invertebrates | Construction, Operations & Maintenance | Di Franco et al. 2020 |
| Develop a centralized cumulative impact assessment framework
Develop a centralized, transparent, replicable, ecosystem-based framework of information and methods for Cumulative Impact Assessments at large spatial/temporal scales that incorporates other stressors beyond OSW development (e.g., climate change). |
Technology/ Methods Development, Cumulative Impacts | Benthos, Birds, Fishes, Invertebrates, Marine mammals | Joint Nature Conservation Committee (JNCC) 2021, Southall et al. 2021 | |
| Develop a centralized data repository for OSW-related ecological data
Develop a centralized publicly accessible data repository for OSW-related data including baseline surveys, passive acoustic monitoring data, and benthic monitoring data to promote transparency, prevent duplication of effort, and aid in the development of collaborations....Read more Develop a centralized publicly accessible data repository for OSW-related data including baseline surveys, passive acoustic monitoring data, and benthic monitoring data to promote transparency, prevent duplication of effort, and aid in the development of collaborations. This data can be used to inform all aspects of the decision-making process. Read less |
Data Management | Bats, Benthos, Birds, Ecosystem/Oceanographic processes, Fishes, Invertebrates, Marine mammals, Sea turtles | Pre-construction, Construction, Operations & Maintenance, Decommissioning | Degraer et al. 2021, Wildlife Conservation Society 2021, Joint Nature Conservation Committee (JNCC) 2021, Van Parijs et al. 2021 |
| Develop a field site for effect-response studies
Develop a long-term, highly instrumented field research site that can be worked at year-round, has well-defined acoustics, and ideally allows (1) control of the sounds being added to the ambient soundscape, (2) tests on various authentic substrates, focal species, etc., (3) examination of...Read more Develop a long-term, highly instrumented field research site that can be worked at year-round, has well-defined acoustics, and ideally allows (1) control of the sounds being added to the ambient soundscape, (2) tests on various authentic substrates, focal species, etc., (3) examination of particle motion and substrate vibration (not just sound pressure), and (4) behavioral and physiological response studies. Read less |
Technology/ Methods Development | Fishes, Invertebrates | Popper et al. 2021 | |
| Develop a method to calculate permanent threshold shift (PTS) impact range
Develop a PTS impact range calculation for marine mammals utilizing strategic literature review. |
Technology/ Methods Development, Noise | Marine mammals | Pre-construction | Joint Nature Conservation Committee (JNCC) 2021 |
| Develop a sound mitigation simulator tool
Develop a tool to support decision-making around the implementation of noise-related mitigation strategies as it relates to potential cumulative impacts to help accelerate permitting. |
Technology/ Methods Development | Marine mammals | Joint Nature Conservation Committee (JNCC) 2021 | |
| Develop acceptable change threshold
Determine scientifically sound threshold ranges for acceptable overall mortality, habitat loss and population change, which should be investigated at the spatial scale relevant to the population of each species under consideration at the scale of the local food web....Read more Determine scientifically sound threshold ranges for acceptable overall mortality, habitat loss and population change, which should be investigated at the spatial scale relevant to the population of each species under consideration at the scale of the local food web. Also, determine if there is an ecological bottleneck of habitat during particular periods. Read less |
Technology/ Methods Development, Habitat Change | Birds, Fishes, Marine mammals | Pre-construction, Operations & Maintenance | Joint Nature Conservation Committee (JNCC) 2021, Lindeboom et al. 2015, WOZEP project team 2016 |
| Develop and improve methods to study avoidance behavior
Improve analyses of avoidance including macro-avoidance of wind farms to micro-avoidance of turbines, including quantification of key parameters such as flight speed and height in relation to behavior. |
Technology/ Methods Development, Avoidance | Birds | Operations & Maintenance | Cook et al. 2018, Joint Nature Conservation Committee (JNCC) 2021 |
| Develop and validate environmental impact assessment estimates of piling noise
Develop an impact assessment tool that considers impulsive and non-impulsive sound to be received by a moving animal when conducting impact assessments of multiple-pulse sources and examine the degree to which existing results validate environmental impact assessment predictions of noise during...Read more Develop an impact assessment tool that considers impulsive and non-impulsive sound to be received by a moving animal when conducting impact assessments of multiple-pulse sources and examine the degree to which existing results validate environmental impact assessment predictions of noise during pile driving, how monitoring is undertaken and how the results are presented. Read less |
Technology/ Methods Development, Noise | Marine mammals | Joint Nature Conservation Committee (JNCC) 2021 | |
| Develop automated methods for species counts and identification
Design methods to automatically count and identify species, including data collections from digital aerial surveys, drone imagery, and benthic surveys. |
Technology/ Methods Development | Benthos, Birds, Marine mammals | Operations & Maintenance | Gulka and Williams 2020, Hutchison et al. 2020, Joint Nature Conservation Committee (JNCC) 2021 |
| Develop availability bias correction for diving species
Develop an availability bias correction to improve abundance estimates for long-diving marine mammal species. |
Technology/ Methods Development, Abundance and Distribution | Marine mammals | Gulka and Williams 2020 | |
| Develop better methods for collision detection
Develop better methods to measure bird collisions, including rates and the conditions contributing to variation in risk. Empirical data of collisions can be used to understand the relationship between estimated and realized risk. |
Technology/ Methods Development, Turbine collision | Bats, Birds | Construction, Operations & Maintenance | Gulka and Williams 2020, Hein and Straw 2021, Joint Nature Conservation Committee (JNCC) 2021 |
| Develop dose-response function for pile-driving noise
Develop dose-response functions for species besides harbor seal and harbor porpoise to provide a method by which the behavioral responses of species can be predicted when exposed to varying levels of noise from impact pile-driving. |
Technology/ Methods Development, Noise | Marine mammals | Joint Nature Conservation Committee (JNCC) 2021 | |
| Develop exposure/vulnerability assessment
Quantify exposure and potential vulnerability at proposed development areas to inform siting and risk assessments, identify key gaps in knowledge, and ensure that research studies are focused on species of greatest potential risk. |
Technology/ Methods Development | Birds | Pre-construction, Construction, Operations & Maintenance, Decommissioning | Cook et al. 2021, New York State Energy Research and Development Authority (NYSERDA) 2015 |
| Develop field system for rapid assessment of hearing sensitivity
Develop methods for a practical field system for rapid assessment of hearing sensitivity through the modification and validation of existing technology to inform the extent and consequences of auditory damage of marine mammals to impulsive sound. |
Technology/ Methods Development, Noise | Marine mammals | Joint Nature Conservation Committee (JNCC) 2021 | |
| Develop guidance for research, monitoring, and mitigation
Develop guidance to inform oceanographic, species effects, and population-level impacts research, including passive acoustic monitoring at the site- and regional scales, and baseline distribution surveys, as well as mitigation including best practices for underwater habitat restoration. |
Technology/ Methods Development | Bats, Benthos, Birds, Ecosystem/Oceanographic processes, Fishes, Invertebrates, Marine mammals, Sea turtles | Pre-construction, Construction, Operations & Maintenance | Carpenter et al. 2021, Gulka 2020, Joint Nature Conservation Committee (JNCC) 2021, Van Parijs et al. 2021 |
| Develop methods for estimating cumulative impacts
Develop better methods to assess the magnitude of cumulative effects across multiple OSW developments and/or across the ecosystem and other pressures, building from existing models and focusing on key processes and functions rather than species-specific stressors. |
Technology/ Methods Development, Cumulative Impacts | Bats, Benthos, Birds, Ecosystem/Oceanographic processes, Fishes, Invertebrates, Marine mammals, Sea turtles | Pre-construction, Construction, Operations & Maintenance, Decommissioning | Gulka and Williams 2020, New York State Energy Research and Development Authority (NYSERDA) 2015, Joint Nature Conservation Committee (JNCC) 2021 |
| Develop methods to apportion at-sea effects to appropriate subpopulations
Develop apportioning methodologies and test against existing methods (e.g. GPS tracking data) to ensure apportioning of at-sea effects during the breeding season to the appropriate population/s. |
Technology/ Methods Development, Population Dynamics | Birds | Joint Nature Conservation Committee (JNCC) 2021 | |
| Develop methods to translate individual effects to population-level consequences
Develop modelling frameworks (and further develop existing frameworks such as population consequences of disturbance (PCoD) and PVA) to allow the assessment of population-level effects from OSW impacts, including those related to collisions and displacement in birds and noise impacts for marine...Read more Develop modelling frameworks (and further develop existing frameworks such as population consequences of disturbance (PCoD) and PVA) to allow the assessment of population-level effects from OSW impacts, including those related to collisions and displacement in birds and noise impacts for marine mammals. Directing research towards areas of greatest need will involve 1) developing robust estimates of baseline demographic parameters, 2) developing preliminary population models, and 3) conducting sensitivity analyses and other gap analyses to identify key gaps where additional data are most needed. Read less |
Technology/ Methods Development, Cumulative Impacts | Bats, Birds, Ecosystem/Oceanographic processes, Marine mammals | Operations & Maintenance | Allison et al. 2019, Carpenter et al. 2021, Cook et al. 2021, Joint Nature Conservation Committee (JNCC) 2021, WOZEP project team 2016 |
| Develop models incorporating hydrodynamics and fish movement
Refine existing dynamic habitat or agent-based models coupled with hydrodynamic models to help quantify the scale of spatial and temporal effects of hydrodynamic cues on the movement of fishes and their habitats, which is not currently possible via conventional modeling, quantitative analysis...Read more Refine existing dynamic habitat or agent-based models coupled with hydrodynamic models to help quantify the scale of spatial and temporal effects of hydrodynamic cues on the movement of fishes and their habitats, which is not currently possible via conventional modeling, quantitative analysis approaches, or field-based observational studies and surveys. Read less |
Technology/ Methods Development, Ecological Drivers, Movement and Behavior | Fishes | Operations & Maintenance | van Berkel et al. 2020 |
| Develop models to better understand at-sea seabird distributions
Develop methods/models to better understand at-sea seabird distributions with robust estimates of uncertainty |
Technology/ Methods Development, Abundance and Distribution | Birds | Pre-construction | Joint Nature Conservation Committee (JNCC) 2021 |
| Develop monitoring networks
Develop a PAM network with standardized data collection and reporting standards and with the potential for real-time sensors to inform best-practices and mitigation, so that long-term, broad-scale questions could be answered and provide information necessary for species protection in the region....Read more Develop a PAM network with standardized data collection and reporting standards and with the potential for real-time sensors to inform best-practices and mitigation, so that long-term, broad-scale questions could be answered and provide information necessary for species protection in the region. Read less |
Technology/ Methods Development | Marine mammals | Wildlife Conservation Society 2021 |