Tidal

Capturing tidal fluctuations with turbines, reciprocating devices, kites, screws, barrages, or lagoons.

Gravity from the moon and sun cause water in the ocean to bulge in a cyclical pattern as the Earth rotates, causing water to rise and fall relative to the land in what are known as tides. Land constrictions such as straits or inlets can create high velocities at specific sites, which can be captured with the use of devices such as turbines. Since seawater is about 800 times denser than air, tidal turbines can collect energy with slower water currents and smaller turbines than wind energy. While tidal currents are very predictable, challenges arise due to the need for devices to collect flow from opposite directions and survive the harsh corrosive marine environment.

 

Environmental effects will vary between the seven most common approaches: axial flow turbine, cross flow turbine, reciprocating device, tidal kite, Archimedes screw, tidal lagoon, and tidal barrage.

 

Axial Flow Turbine

 

These turbines are the most similar to traditional windmills, where the kinetic energy of moving water is captured by spinning blades facing the direction of flow. Turbines can be open or ducted (shrouded) and placed anywhere in the water column, though bottom-mounted is the most common.

 

The main environmental concern is collision between turbine blades and marine organisms due to natural animal movements, attraction to the device, or inability to avoid the turbines within strong currents. It should be noted that these turbines spin much slower than propellers on ships. There is also concern that noise from turbines can affect animals that use sound for communication, social interaction, orientation, predation, and evasion. As with all electricity generation, there is a slight concern that electromagnetic fields generated by power cables and moving parts may affect animals that use Earth's natural magnetic field for orientation, navigation, and hunting. Likewise, chemicals such as anti-corrosion paint and small amounts of oil and grease may enter the waterbody during spills, though some turbine designs do not require lubrication. Large-scale tidal energy removal (from arrays) may disrupt natural physical systems to cause degradation in water quality or changes in sediment transport, potentially affecting the ecosystem.

Cross Flow Turbine

 

These turbines are generally cylindrical on a horizontal axis, where kinetic energy of moving water is captured by spinning blades oriented transversely to the direction of flow. Turbines can be open or ducted (shrouded) and placed anywhere in the water column, though bottom-mounted is the most common.

 

There is typically less environmental concern for collision between turbine blades and marine organisms because blades are spinning in the same direction to the flow of water, depending on the design. Concerns about noise, electromagnetic fields, chemicals, and energy removal are similar to that of axial flow turbines.

Reciprocating Device

 

Reciprocating devices do not have rotating components, but instead have a hydrofoil that is pushed back and forth transverse to the flow direction by lift or drag. Oscillating devices are the most common form of reciprocating devices.

 

Reciprocating devices often move slower than turbines, but move more freely in the water, resulting in some concern for collision. Reciprocating devices often produce little noise, though this depends on the design and generator. Concerns about electromagnetic fields, chemicals, and energy removal are similar to that of other tidal devices.

Tidal Kite

 

A tidal kite is comprised of a hydrodynamic wing, with a turbine attached, tethered by a cable to a fixed point that leverages water flow to lift the wing. As the kite 'flies' loops through the water, the speed increases around the turbine, allowing more energy extraction for slower currents. The kite is neutrally buoyant so as not to fall as the tide changes direction.

 

Collision risk may be of some concern with tidal kites. Although animals are more likely to collide with the tether than the kite itself, little is known about the ability of animals to detect the free movement of some tidal kites. Tidal kites emit noise over a larger frequency than horizontal axis turbines, though this depends on the design and generator. Concerns about electromagnetic fields, chemicals, and energy removal are similar to that of other tidal devices.

Archimedes Screw

 

Historically designed to efficiently transfer water up a tube, an Archimedes screw is a helical surface surrounding a ventral cylindrical shaft. Energy is generated as water flow moves up the spiral and rotates the device.

 

The helical turbine moves very slowly relative to other tidal technologies, and is likely to have little collision risk. Archimedes screws often produce little noise, though this depends on the design and generator. Concerns about electromagnetic fields, chemicals, and energy removal are similar to that of other tidal devices.

Tidal Lagoon

 

Tidal lagoons are comprised of retaining walls embedded with reversible low-head turbines that surround a large reservoir. Tides cause a difference in the water height inside and outside of the walls, functioning very similar to a low-head conventional hydrokinetic dam that works in both direction.

 

The ecosystem within the reservoir undergoes significant transformation, potentially yielding positive impacts with a more diverse seabed, depending on site selection. The changes to the physical system are similar to conventional marine engineering projects and can include altering water flow and shoreline processes partially due to energy removal. Decreased flushing of the reservoir may cause some problems for water quality. There are some collision concerns that arise if fish and benthic invertebrates try to traverse the retaining wall through turbines. Impacts from noise depend on turbine selection. There is little concern for electromagnetic fields because cables are embedded in the retaining wall and are not openly exposed to water. The new reservoir may also create calmer waters that allow better recreation.

Tidal Barrage

 

Tidal barrages are dams built across the entrance to a bay or estuary that captures potential tidal energy, similar to tidal lagoons. Energy is collected when the height difference on either side of the dam is greatest, at low or high tide. A minimum height fluctuation of 5 meters (16.4 feet) is required to justify the construction, so only 40 locations worldwide have been identified as feasible.

 

Installing a tidal barrage impacts bay or estuary ecosystems due to the alteration of tidal flows and can have negative effects such as changing the shoreline and important tidal flats. Inhibiting the flow of water in and out of the bay, may also lead to less flushing of the bay or estuary, altering the water quality, and potentially causing additional turbidity (suspended solids) and less saltwater, which may result in the death of fish that act as a vital food source to birds and mammals. Migrating fish may also be unable to access breeding streams, and may attempt to pass through the turbines and risk collision. Impacts from noise depend on turbine selection, similar to tidal lagoons. Decreasing shipping accessibility can become a major socio-economic issue, though locks can be added to allow slow passage. However, the barrage may improve the local economy by increasing land access when used as a bridge and allowing for more recreation opportunities due to calmer waters.

Total Results: 677
Title Author Date Type of Content Technology Type Stressor Receptorsort descending
A Scenario-Based Approach to Evaluating Potential Environmental Impacts Following a Tidal Barrage Installation Kidd, I., et al. November 2015 Journal Article Marine Energy general, Tidal Energy Removal Ecosystem
A Review of the Potential Impacts of Wave and Tidal Energy Development on Scotland's Marine Environment Aquatera June 2014 Report Marine Energy general, Tidal, Wave Nearfield Habitat
Evaluation and Comparison of the Levelized Cost of Tidal, Wave, and Offshore Wind Energy Astariz, S., Vazquez, A., Iglesias, G. October 2015 Journal Article Marine Energy general, Tidal, Wave, Wind Energy general, Offshore Wind Human Dimensions
An Integrated Solution to Real Time Marine Mammal Monitoring for Tidal Turbines Bromley, P., Boake, C., Broudic, M. September 2015 Conference Paper Marine Energy general, Tidal Static Device Marine Mammals
Surveying Marine Mammals in Nearby Tidal Energy Development Sites: a Comparison Benjamins, S., et al. September 2015 Conference Paper Marine Energy general, Tidal Static Device Farfield Environment, Marine Mammals
MR7.2.1 Collision Risk: A Brief Review of Available Information on Behaviour of Mammals and Birds in High Tidal Energy Areas Onoufriou, J., Thompson, D. July 2015 Report Marine Energy general, Tidal Dynamic Device Birds, Marine Mammals
MR7.2.2 Collision Risk and Impact Study: Examination of Models for Estimating the Risk of Collisions Between Seals and Tidal Turbines Lonergan, M., Thompson, D. July 2015 Report Marine Energy general, Tidal Dynamic Device Marine Mammals, Pinnipeds
MR7.2.3 Collision Risk and Impact Study: Field Tests of Turbine Blade-Seal Carcass Collisions Thompson, D., et al. July 2015 Report Marine Energy general, Tidal Dynamic Device Marine Mammals, Pinnipeds
Sediment Transport in the Pentland Firth and Impacts of Tidal Stream Energy Extraction Fairley, I., Masters, I., Karunarathna, H. September 2015 Conference Paper Marine Energy general, Tidal Energy Removal
Impact of Scaled Tidal Stream Turbine over Mobile Sediment Beds Ramírez-Mendoza, R., et al. September 2015 Conference Paper Marine Energy general, Tidal Energy Removal
Remote Detection of Sea Surface Roughness Signatures Related to Subsurface Bathymetry, Structures and Tidal Stream Turbine Wakes Bell, P., et al. September 2015 Conference Paper Marine Energy general, Tidal
Hydrodynamic Response to Large Scale Tidal Energy Extraction Brown, A., Neill, S. September 2015 Conference Paper Marine Energy general, Tidal Energy Removal Farfield Environment
Field Testing a Full-Scale Tidal Turbine Part 2: In-Line Wake Effects Schmitt, P., et al. September 2015 Conference Paper Marine Energy general, Tidal
Field Testing a Full-Scale Tidal Turbine Part 3: Acoustic Characteristics Schmitt, P., et al. September 2015 Conference Paper Marine Energy general, Tidal Noise
Numerical Modeling of the Impact Response of Tidal Devices and Marine Mammals Grear, M., Motley, M. September 2015 Conference Paper Marine Energy general, Tidal Marine Mammals, Cetaceans, Pinnipeds
A World First: Swansea Bay Tidal Lagoon in Review Waters, S., Aggidis, G. April 2016 Journal Article Marine Energy general, Tidal
A Finite Element Circulation Model for Embayments with Drying Intertidal Areas and its Application to the Quoddy Region of the Bay of Fundy Greenberg, D., et al. January 2005 Journal Article Marine Energy general, Tidal
The Tidal-Stream Energy Resource in Passamaquoddy-Cobscook Bays: A Fresh Look at an Old Story Brooks, D. November 2006 Journal Article Marine Energy general, Tidal
Installation of Tidal Turbine Array at Kyle Rhea, Scotland: Scoping Study Bedford, G., Tarrant, D., Trendall, J. March 2010 Report Marine Energy general, Tidal Invertebrates, Birds, Farfield Environment, Fish, Marine Mammals, Reptiles, Human Dimensions, Environmental Impact Assessment
The Kyle Rhea Tidal Stream Array Environmental Statement: Non-Technical Summary Sea Generation January 2013 Report Marine Energy general, Tidal Invertebrates, Birds, Farfield Environment, Fish, Marine Mammals, Human Dimensions, Environmental Impact Assessment
Fairhead Tidal Environmental Impact Assessment Scoping Document McGrath, C. December 2013 Report Marine Energy general, Tidal EMF, Noise Invertebrates, Birds, Fish, Marine Mammals, Reptiles, Human Dimensions, Environmental Impact Assessment
Estimates of Collision Risk of Harbour Porpoises and Marine Renewable Energy Devices at Sites of High Tidal-Stream Energy Wilson, B., et al. November 2014 Report Marine Energy general, Tidal Dynamic Device Marine Mammals, Cetaceans
Using Drifting Passive Echolocation Loggers to Study Harbour Porpoises in Tidal-Stream Habitats Wilson, B., Benjamins, S., Elliot, J. December 2013 Journal Article Marine Energy general, Tidal Marine Mammals
An Evaluation of the Use of Shore-Based Surveys for Estimating Spatial Overlap between Deep-Diving Seabirds and Tidal Stream Turbines Waggitt, J., Bell, P., Scott, B. December 2014 Journal Article Marine Energy general, Tidal Birds
Whale To Turbine Impact Using The GPU Based SPH-LSM Method Longshaw, S., Stansby, P., Rogers, B. June 2014 Conference Paper Marine Energy general, Tidal Dynamic Device Marine Mammals, Cetaceans
HS1000 1 MW Tidal Turbine at EMEC: Supporting Documentation Xodus AURORA August 2010 Report Marine Energy general, Tidal
Assessment of Collision Risk for Seals and Tidal Stream Turbines Davies, I., Thompson, F. January 2011 Report Marine Energy general, Tidal Dynamic Device Marine Mammals, Pinnipeds
Strangford Lough and the SeaGen Tidal Turbine Savidge, G., et al. February 2014 Book Chapter Marine Energy general, Tidal
Final Pilot License Application: Roosevelt Island Tidal Energy Project Verdant Power December 2010 Report Marine Energy general, Tidal Human Dimensions, Legal and Policy
A Framework for Environmental Risk Assessment and Decision-Making for Tidal Energy Development in Canada [Presentation] Isaacman, L., Daborn, G., Redden, A. April 2014 Presentation Marine Energy general, Tidal Human Dimensions, Legal and Policy
Fuzzy Impact Assessment on the Landscape: The Kobold Platform in the Strait of Messina Case Study Bergamascoa, A., et al. January 2011 Journal Article Marine Energy general, Tidal
Studies of Harbour Seal Behaviour in Areas of High Tidal Energy: Part 1. Movements and Diving Behaviour of Harbour Seals in Kyle Rhea Thompson, D. January 2014 Report Marine Energy general, Tidal Marine Mammals, Pinnipeds
Proceedings of the 2nd Oxford Tidal Energy Workshop University of Oxford March 2013 Workshop Article Marine Energy general, Tidal
Proceedings of the 3rd Oxford Tidal Energy Workshop University of Oxford April 2014 Workshop Article Marine Energy general, Tidal
Proceedings of the Oxford Tidal Energy Workshop University of Oxford March 2012 Workshop Article Marine Energy general, Tidal
Impact of Tidal Energy Arrays Located in Regions of Tidal Asymmetry Neill, S. March 2013 Workshop Article Marine Energy general, Tidal Energy Removal
TeraWatt Position Papers: A "Toolbox" of Methods to Better Understand and Assess the Effects of Tidal and Wave Energy Arrays on the Marine Environment Murray, R., et al. August 2015 Report Marine Energy general, Tidal, Wave Energy Removal Farfield Environment, Nearfield Habitat
NERC Knowledge Exchange: An Autonomous Device to Track Porpoise Movements in Tidal Rapids Macaulay, J., et al. November 2015 Report Marine Energy general, Tidal Marine Mammals
Environmental Monitoring of the Paimpol-Brehat Tidal Project Barillier, A., Carlier, A. February 2016 Presentation Marine Energy general, Tidal Noise, Static Device Invertebrates, Marine Mammals
What Should a Condition Monitoring System Look like for a Tidal Turbine? Marnoch, J. February 2016 Presentation Marine Energy general, Tidal
Detecting Potential and Actual Turbine-Marine Life Interactions: A Call for the Development of Best Practices Redden, A. November 2014 Presentation Marine Energy general, Tidal Dynamic Device, Static Device Fish, Marine Mammals
GHYDRO: Methodology Guide for Assessment of Environmental Impacts of Tidal Stream Energy Technologies at Sea Lejart, M. November 2014 Presentation Marine Energy general, Tidal Human Dimensions, Legal and Policy
Improvements to Probabilistic Tidal Turbine-Fish Interaction Model Parameters Tomichek, C., Colby, J., Adonizio, M. April 2015 Conference Paper Marine Energy general, Tidal Dynamic Device Fish
Annex IV - International Collaboration to Investigate Environmental Effects of Wave and Tidal Devices Copping, A., et al. April 2014 Presentation Marine Energy general, Tidal, Wave
Historic Environment Guidance for Wave and Tidal Renewable Energy Robertson, P., Shaw, A. April 2014 Presentation Marine Energy general, Tidal, Wave Human Dimensions
Marine Mammals and Tidal Turbines: What are the Issues of Concern and how are they being Resolved? Wilson, B., Hastie, G., Benjamins, S. April 2014 Presentation Marine Energy general, Tidal Marine Mammals
Using the FLOWBEC Seabed Frame to Understand Underwater Interactions between Diving Seabirds, Prey, Hydrodynamics and Tidal and Wave Energy Structures Williamson, B., et al. April 2014 Presentation Marine Energy general, Tidal, Wave Birds, Seabirds
Multi-Disciplinary Risk Identification and Evaluation for the Tidal Industry Kolios, A., Read, G., Loannou, A. April 2014 Presentation Marine Energy general, Tidal
A Review of Marine Bird Diving Behaviour: Assessing Underwater Collision Risk with Tidal Turbines Robbins, A., et al. May 2014 Presentation Marine Energy general, Tidal Dynamic Device Birds, Seabirds
Impacts of Tidal-Stream Energy Converter (TEC) Arrays in Relation to the Natural Variability of Sedimentary Processes Robins, P., Neill, S., Lewis, M. May 2014 Presentation Marine Energy general, Tidal Energy Removal
Annex IV 2016 State of the Science Report: Environmental Effects of Marine Renewable Energy Development Around the World Copping, A., et al. April 2016 Report Marine Energy general, Tidal, Wave Dynamic Device, EMF, Energy Removal, Noise, Static Device Invertebrates, Birds, Ecosystem, Farfield Environment, Fish, Marine Mammals, Nearfield Habitat, Reptiles, Human Dimensions, Marine Spatial Planning
Potential Environmental Impact of Tidal Energy Extraction in the Pentland Firth at Large Spatial Scales: Results of a Biogeochemical Model van der Molen, J., Ruardij, P., Greenwood, N. May 2016 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Tracking Technologies for Quantifying Marine Mammal Interactions with Tidal Turbines: Pitfalls and Possibilities Hastie, G., et al. February 2014 Book Chapter Marine Energy general, Tidal Marine Mammals
Wave and Tidal Consenting Position Paper Series: Marine Mammal Impacts Sparling, C., et al. October 2013 Report Marine Energy general, Tidal, Wave Marine Mammals
Advancing a Key Consenting Risk for Tidal Energy: The Risk of Marine Mammal Collision for In-Stream Tidal Energy Devices Booth, C., et al. April 2015 Conference Paper Marine Energy general, Tidal Dynamic Device Marine Mammals
Understanding the Risk to Marine Mammals from Collision with a Tidal Turbine Copping, A., et al. April 2015 Conference Paper Marine Energy general, Tidal Dynamic Device Marine Mammals
OCGen Module Mooring Design Marnagh, C., et al. April 2015 Conference Paper Marine Energy general, Tidal
Integrating a Multibeam and a Multifrequency Echosounder on the Flowbec Seabed Platform to Track Fish and Seabird Behavior around Tidal Turbine Structures Williamson, B., et al. April 2016 Conference Paper Marine Energy general, Tidal Birds, Seabirds, Fish
Impacts of Tidal Energy Extraction on Sea Bed Morphology Chatzirodou, A., Karunarathna, H. June 2014 Conference Paper Marine Energy general, Tidal Energy Removal
Modelling the Response of Sandbank Dynamics to Tidal Energy Extraction Chatzirodou, A., Karunarathna, H., Reeve, D. June 2015 Conference Paper Marine Energy general, Tidal Energy Removal
A Comparison of Numerical Modelling Techniques for Tidal Stream Turbine Analysis Masters, I., et al. July 2015 Journal Article Marine Energy general, Tidal
Tidal Energy, Underwater Noise and Marine Mammals Carter, C., Wilson, B., Burrows, M. May 2014 Presentation Marine Energy general, Tidal Noise Marine Mammals
Tracking Porpoise Underwater Movements in Tidal Rapids using Drifting Hydrophone Arrays. Filling a Key Information Gap for Assessing Collision Risk Gordon, J., et al. May 2014 Presentation Marine Energy general, Tidal Marine Mammals, Cetaceans
Movement Patterns of Seals in Tidally Energetic Sites: Implications for Renewable Energy Development Hastie, G., et al. May 2014 Presentation Marine Energy general, Tidal Marine Mammals, Pinnipeds
Marine Mammals and Tidal Turbines: Understanding True Collision Risk Sparling, C., et al. May 2014 Presentation Marine Energy general, Tidal Dynamic Device Marine Mammals
Monitoring Benthic Habitats and Biodiversity at the Tidal Energy Site of Paimpol-Brehat (Brittany, France) Carlier, A., et al. May 2014 Presentation Marine Energy general, Tidal Invertebrates
Better Together: The Implications of Tidal Resource Interactions from Resource Calculation to Policy and Governance Woolf, D., Easton, M. May 2014 Presentation Marine Energy general, Tidal Human Dimensions, Legal and Policy
The Modelling of Tidal Turbine Farms using Multi-Scale, Unstructured Mesh Models Kramer, S., et al. May 2014 Presentation Marine Energy general, Tidal
The Role of Tidal Asymmetry in Characterising the Tidal Energy Resource of Orkney Neill, S., Hashemi, M., Lewis, M. May 2014 Presentation Marine Energy general, Tidal
Use of Animal Tracking Technology to Assess Potential Risks of Tidal Turbine Interactions with Fish Redden, A., et al. May 2014 Presentation Marine Energy general, Tidal Fish
Advances in Research to Understand the Impacts of Wave and Tidal Energy Devices in the United States Brown-Saracino, J. May 2014 Presentation Marine Energy general, Tidal, Wave
Marine Radar Derived Current Vector Mapping at a Planned Commercial Tidal Stream Turbine Array in the Pentland Firth Bell, P., et al. May 2014 Presentation Marine Energy general, Tidal
Quantifying Pursuit-Diving Seabirds' Associations with Fine-Scale Physical Features in Tidal Stream Environments Waggitt, J., et al. December 2016 Journal Article Marine Energy general, Tidal Birds, Seabirds
Wave and Tidal Current Energy - A Review of the Current State of Research Beyond Technology Uihlein, A., Magagna, D. May 2016 Journal Article Marine Energy general, Tidal, Wave
Measurement of Underwater Operational Noise Emitted by Wave and Tidal Stream Energy Devices Lepper, P., Robinson, S. January 2016 Book Chapter Marine Energy general, Tidal, Wave Noise
Effects of Underwater Turbine Noise on Crab Larval Metamorphosis Pine, M., Jeffs, A., Radford, C. January 2016 Book Chapter Marine Energy general, Tidal Noise Invertebrates
Current tidal power technologies and their suitability for applications in coastal and marine areas Roberts, A., et al. May 2016 Journal Article Marine Energy general, Tidal Ecosystem, Human Dimensions
Assessing collision risk between underwater turbines and marine wildlife Scottish Natural Heritage May 2016 Report Marine Energy general, Tidal Dynamic Device
Seal Telemetry Inventory Sparling, C. March 2016 Report Marine Energy general, Tidal Marine Mammals, Pinnipeds
Harbor Seal - Tidal Turbine Collision Risk Models. An Assessment of Sensitivities. Wood, J., Joy, R., Sparling, C. March 2016 Report Marine Energy general, Tidal Marine Mammals, Pinnipeds
Tidal Lagoons: Another Technique for Capturing Marine Renewable Energy Matthew Preisser July 2016 Blog Article Tidal
Bottom substrate and associated epibenthic biota of the force tidal energy test site in Minas Passage, Bay of Fundy Morrison, K., Redden, A. January 2013 Report Marine Energy general, Tidal Invertebrates
Acoustic Tracking of Fish Movements in the Minas Passage and FORCE Demonstration Area: Pre-Turbine Baseline Studies (2011-2013) Redden, A., Stokesbury, M. January 2014 Report Marine Energy general, Tidal Fish
Minas Passage Lobster Tracking Study 2011-2013 Morrison, K., Broome, J., Redden, A. July 2014 Report Marine Energy general, Tidal Invertebrates
Temporal Patterns in Minas Basin Intertidal Weir Fish Catches and Presence of Harbour Porpoise during April - August 2013 Baker, M., Reed, M., Redden, A. July 2014 Report Marine Energy general, Tidal Marine Mammals
Assessing Marine Mammal Presence in and Near the FORCE Lease Area During Winter and Early Spring - Addressing Baseline Data Gaps and Sensor Performance Redden, A., Porskamp, P. January 2015 Report Marine Energy general, Tidal Marine Mammals
Estimating the Probability of Fish Encountering a Marine Hydrokinetic Device Shen, H., et al. November 2016 Journal Article Marine Energy general, Tidal Fish
Harbour Porpoise Distribution can Vary at Small Spatiotemporal Scales in Energetic Habitats Benjamins, S., et al. July 2017 Journal Article Marine Energy general, Tidal Marine Mammals, Cetaceans
PLAT-O at EMEC September 2019 Project Site OES-Environmental Marine Energy general, Tidal
Brims Tidal Array Planned Project Site OES-Environmental Marine Energy general, Tidal
Environmental Scoping Report: Brims Tidal Array OpenHydro, SSE Renewables August 2013 Report Marine Energy general, Tidal
Are Larvae and other Planktonic Organisms at Risk from Tidal Energy Development? Andrea Copping August 2016 Blog Article Tidal
A Coordinated Action Plan for Addressing Collision Risk for Marine Mammals and Tidal Turbines Hutchison, I., Copping, A. August 2016 Workshop Article Marine Energy general, Tidal Dynamic Device Marine Mammals
Do Changes in Current Flow as a Result of Arrays of Tidal Turbines Have an Effect on Benthic Communities? Kregting, L., et al. August 2016 Journal Article Marine Energy general, Tidal Energy Removal Invertebrates
HS1000 at EMEC December 2011 Project Site OES-Environmental Marine Energy general, Tidal
Numerical Evaluation of Marine Current Turbine: Impact on Environment and its Potential of Renewable Energy Utilization Kitazawa, D., Zhang, J. April 2016 Conference Paper Marine Energy general, Tidal Energy Removal Ecosystem, Farfield Environment
Atlantic Sturgeon Spatial and Temporal Distribution in Minas Passage, Nova Scotia, Canada, a Region of Future Tidal Energy Extraction Stokesbury, M., et al. July 2016 Journal Article Marine Energy general, Tidal Fish
Predictable Hydrodynamic Conditions Explain Temporal Variations in the Density of Benthic Foraging Seabirds in a Tidal Stream Environment Waggitt, J., et al. July 2016 Conference Paper Marine Energy general, Tidal Birds, Seabirds
Torr Head Tidal Energy Array EIA Scoping Report Tidal Ventures June 2013 Report Marine Energy general, Tidal
Consenting Guidance for Developers at the EMEC Fall of Warness Test Site European Marine Energy Centre January 2015 Report Marine Energy general, Tidal Human Dimensions, Legal and Policy

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