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: 692
Title Author Date Type of Contentsort descending Technology Type Stressor Receptor
A Political, Economic, Social, Technology, Legal and Environmental (PESTLE) Approach for Risk Identification of the Tidal Industry in the United Kingdom Kolios, A., Read, G. September 2013 Journal Article Marine Energy general, Tidal Socio-economics
A Techno-Economic Analysis of Tidal Energy Technology Johnstone, C., et al. January 2013 Journal Article Marine Energy general, Tidal Socio-economics
The Muskeget Channel Tidal Energy Project: A Unique Case Study in the Licensing and Permitting of a Tidal Energy Project in Massachusetts Barrett, S. July 2013 Journal Article Marine Energy general, Tidal Socio-economics
A Review of the Potential Water Quality Impacts of Tidal Renewable Energy Systems Kadiri, M., et al. January 2012 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
Accommodating Wave and Tidal Energy - Control and Decision in Scotland Johnson, K., Kerr, S., Side, J. September 2012 Journal Article Marine Energy general, Tidal, Wave Socio-economics
An Experimental Investigation on Cavitation, Noise, and Slipstream Characteristics of Ocean Stream Turbines Wang, D., Altar, M., Sampson, R. August 2006 Journal Article Marine Energy general, Tidal Energy Removal, Noise
Assessing the Sensitivity of Seabird Populations to Adverse Effects from Tidal Stream Turbines and Wave Energy Devices Furness, R., et al. June 2012 Journal Article Marine Energy general, Tidal, Wave Dynamic Device, Energy Removal, Static Device Birds
Assessment of Zooplankton Injury and Mortality Associated With Underwater Turbines for Tidal Energy Production Schlezinger, D., Taylor, C., Howes, B. July 2013 Journal Article Marine Energy general, Tidal Dynamic Device Ecosystem
Broadband Acoustic Environment at a Tidal Energy Site in Puget Sound Xu, J., et al. March 2012 Journal Article Marine Energy general, Tidal Noise
Changes in Area, Geomorphology and Sediment Nature of Salt Marshes in the Oosterschelde Estuary (SW Netherlands) Due to Tidal Changes de Jong, D., de Jong, Z., Mulder, J. May 1994 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
Effect Of Tidal Stream Power Generation On The Region-wide Circulation In A Shallow Sea Shapiro, G. February 2011 Journal Article Marine Energy general, Riverine, Tidal Energy Removal Farfield Environment
Environmental and Ecological Effects of Ocean Renewable Energy Development: A Current Synthesis Boehlert, G., Gill, A. June 2010 Journal Article Marine Energy general, OTEC, Tidal, Wave, Wind Energy general, Offshore Wind Static Device Nearfield Habitat
Epibenthic Assessment of a Renewable Tidal Energy Site Sheehan, E., et al. January 2013 Journal Article Marine Energy general, Tidal Benthic Invertebrates, Nearfield Habitat
Estimating Effects of Tidal Power Projects and Climate Change on Threatened and Endangered Marine Species and Their Food Web Busch, S., Greene, C., Good, T. December 2013 Journal Article Marine Energy general, Tidal Ecosystem, Socio-economics, Climate Change
Estimation of Tidal Power Potential Walters, R., Hiles, C., Tarbotton, M. March 2013 Journal Article Marine Energy general, Tidal
Far-Field Effects of Tidal Energy Extraction in the Minas Passage on Tidal Circulation in the Bay of Fundy and Gulf of Maine Using a Nested-Grid Coastal Circulation Model Hasegawa, D., et al. November 2011 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Far-field Dynamics Of Tidal Energy Extraction In Channel Networks Malte, P., Polagye, B. January 2011 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Far-Field Modelling of the Hydro-Environmental Impact of Tidal Stream Turbines Ahmadian, R., Falconer, R., Bockelmann-Evans, B. February 2012 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Generating Electricity from the Oceans Bahaj, A. September 2011 Journal Article Marine Energy general, Tidal, Wave
Impact of Tidal Energy Converter (TEC) Arrays on the Dynamics of Headland Sand Banks Neill, S., Jordan, J., Couch, S. January 2012 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
In-Stream Tidal Energy Potential of Puget Sound, Washington Polagye, B., Kawase, M., Malte, P. January 2009 Journal Article Marine Energy general, Riverine, Tidal Farfield Environment
Interactive Marine Spatial Planning: Siting Tidal Energy Arrays around the Mull of Kintyre Alexander, K., et al. January 2012 Journal Article Marine Energy general, Tidal Static Device Socio-economics, Marine Spatial Planning
Intertidal Ecology and Potential Power Impacts, Bay of Fundy, Canada Gordon, D. Jr. January 1994 Journal Article Marine Energy general, Tidal Energy Removal Benthic Invertebrates, Birds, Shorebirds, Fish, Nearfield Habitat
Limits To Tidal Current Power Garrett, C., Cummins, P. November 2008 Journal Article Marine Energy general, Tidal
Marine Renewable Energy: The Ecological Implications of Altering the Hydrodynamics of the Marine Environment Shields, M., et al. January 2011 Journal Article Marine Energy general, Tidal, Wave Energy Removal Farfield Environment, Nearfield Habitat
Measurements of Turbulence at Two Tidal Energy Sites in Puget Sound, WA (USA) Thomson, J., et al. December 2011 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
Measuring The Environmental Costs Of Tidal Power Plant Construction: A Choice Experiment Study Lee, J., Yoo, S. December 2009 Journal Article Marine Energy general, Tidal Nearfield Habitat, Socio-economics
Methodology for Tidal Turbine Representation in Ocean Circulation Model Roc, T., Conley, D., Greaves, D. March 2013 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Modeling Tidal Circulation and Stratification in Skagit River Estuary Using an Unstructured Grid Ocean Model Yang, Z., Khangaonkar, T. January 2009 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Modeling Tidal Stream Energy Extraction and its Effects on Transport Processes in a Tidal Channel and Bay System Using a Three-Dimensional Coastal Ocean Model Yang, Z., Wang, T., Copping, A. February 2013 Journal Article Marine Energy general, Tidal Energy Removal
Nature Conservation Implications of a Severn Tidal Barrage - A Preliminary Assessment of Geomorphological Change Pethick, J., Morris, R., Evans, D. December 2009 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Noise Measurements Of A Prototype Tidal Energy Turbine Deveau, D., et al. January 2011 Journal Article Marine Energy general, Tidal Noise
Numerical Modeling of Tidal Currents and the Effects of Power Extraction on Estuarine Hydrodynamics Along the Georgia Coast, USA Defne, Z., Haas, K., Fritz, H. December 2011 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment, Nearfield Habitat
Potential Impact of Large-Scale Tidal Power Developments in the Upper Bay of Fundy on Fisheries Resources of the Northwest Atlantic Dadswell, M., Rulifson, R., Daborn, G. July 1986 Journal Article Marine Energy general, Tidal Energy Removal, Static Device Fish
Research for the Sustainable Development of Tidal Power in Maine Johnson, T., Zydlewski, G. January 2012 Journal Article Marine Energy general, Tidal Socio-economics
Seabird Conservation and Tidal Stream and Wave Power Generation: Information Needs for Predicting and Managing Potential Impacts Langton, R., Davies, I., Scott, B. September 2011 Journal Article Marine Energy general, Tidal, Wave Static Device Birds, Seabirds
Strategic Priorities for Assessing Ecological Impacts of Marine Renewable Energy Devices in the Pentland Firth (Scotland, UK) Shields, M., et al. July 2009 Journal Article Marine Energy general, Tidal EMF, Energy Removal, Noise Benthic Invertebrates, Birds, Fish, Marine Mammals, Nearfield Habitat
Structure of Turbulent Flow in EMEC's Tidal Energy Test Site Osalusi, E., Side, J., Harris, R. May 2009 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
Ten Years of Experience at the La Rance Tidal Power Plant Andre, H. December 1978 Journal Article Marine Energy general, Tidal
The Efficiency Of A Turbine In A Tidal Channel Garrett, C., Cummins, P. September 2007 Journal Article Marine Energy general, Tidal
The Environmental Interactions of Tidal and Wave Energy Generation Devices Frid, C., et al. January 2012 Journal Article Marine Energy general, Tidal, Wave Static Device Farfield Environment, Nearfield Habitat
The Extractable Power From A Channel Linking A Bay To The Open Ocean Blanchfield, J., et al. May 2008 Journal Article Marine Energy general, Tidal
The Impact of Tidal Stream Turbines on Large-Scale Sediment Dynamics Neill, S., et al. December 2009 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
The Power Potential Of Tidal Currents In Channels Garrett, C., Cummins, P. April 2005 Journal Article Marine Energy general, Tidal
Three-Dimensional Hydrodynamic Modelling of Inland Marine Waters of Washington State, United States, for Tidal Resource and Environmental Impact Assessment Kawase, M., Thyng, K. November 2010 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment, Nearfield Habitat
Tidal Barrages and Birds Clark, N. March 2006 Journal Article Marine Energy general, Tidal Energy Removal, Static Device Birds, Nearfield Habitat
Tidal Current Energy Assessment For Johnstone Strait, Vancouver Island Sutherland, G., Foreman, M., Garrett, C. March 2006 Journal Article Marine Energy general, Tidal Energy Removal
Tidal Current Energy Technologies Fraenkel, P. March 2006 Journal Article Marine Energy general, Tidal
Tidal Power and the Aquatic Environment of La Rance Retiere, C. January 1994 Journal Article Marine Energy general, Tidal Energy Removal Birds, Fish, Nearfield Habitat
Assessment of Tidal Current Energy in the Minas Passage, Bay of Fundy Karsten, R., et al. August 2008 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Understanding and Informing Permitting Decisions for Tidal Energy Development Using an Adaptive Management Framework Jansujwicz, J., Johnson, T. January 2015 Journal Article Marine Energy general, Tidal Socio-economics
Wave and Tidal Energy Its Emergence and the Challenges it Faces Ferro, B. May 2006 Journal Article Marine Energy general, Tidal, Wave Socio-economics
Hydrokinetic Turbine Effects on Fish Swimming Behaviour Hammar, L., et al. December 2013 Journal Article Marine Energy general, Tidal Dynamic Device Fish
Using a Spatial Overlap Approach to Estimate the Risk of Collisions between Deep Diving Seabirds and Tidal Stream Turbines: A Review of Potential Methods and Approaches Waggitt, J., Scott, B. February 2014 Journal Article Marine Energy general, Tidal Dynamic Device Birds
Modelling the Far Field Hydro-Environmental Impacts of Tidal Farms - A Focus on Tidal Regime, Intertidal Zones and Flushing Nash, S., et al. October 2014 Journal Article Marine Energy general, Tidal Farfield Environment
Modeling of In-Stream Tidal Energy Development and its Potential Effects in Tacoma Narrows Washington USA Yang, Z., et al. October 2014 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
Experimental Study of the Turbulence Intensity Effects on Marine Current Turbines Behaviour. Part II: Two Interacting Turbines Mycek, P., et al. August 2014 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
Experimental Study of the Turbulence Intensity Effects on Marine Current Turbines Behaviour. Part I: One Single Turbine Mycek, P., et al. June 2014 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
The Effects of a Severn Barrage on Wave Conditions in the Bristol Channel Fairley, I., et al. August 2014 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Energy of Marine Currents in the Strait of Gibraltar and its Potential as a Renewable Energy Resource Quesada, M., et al. June 2014 Journal Article Marine Energy general, Tidal
Slipstream Between Marine Current Turbine and Seabed Chen, L., Lam, W. April 2014 Journal Article Marine Energy general, Riverine, Tidal Energy Removal Nearfield Habitat
Flow-Noise and Turbulence in Two Tidal Channels Bassett, C., et al. February 2014 Journal Article Marine Energy general, Tidal Noise
Environmental Risk Evaluation System - An Approach to Ranking Risk of Ocean Energy Development on Coastal and Estuarine Environments Copping, A., et al. January 2015 Journal Article Marine Energy general, Tidal, Wave, Wind Energy general, Offshore Wind Chemicals, Dynamic Device, Energy Removal Birds, Fish, Marine Mammals
Simulating Blade-Strike on Fish Passing Through Marine Hydrokinetic Turbines Romero-Gomez, P., Richmond, M. November 2014 Journal Article Marine Energy general, Riverine, Tidal Dynamic Device Fish
Floating Vs. Bottom-Fixed Turbines for Tidal Stream Energy: A Comparative Impact Assessment Sanchez, M., et al. August 2014 Journal Article Marine Energy general, Tidal
In-Situ Ecological Interactions with a Deployed Tidal Energy Device; An Observational Pilot Study Broadhurst, M., Barr, S., Orme, D. October 2014 Journal Article Marine Energy general, Tidal Static Device Fish
Assessing the Influence of Inflow Turbulence on Noise and Performance of a Tidal Turbine using Large Eddy Simulations Lloyd, T., Turnock, S., Humphrey, V. November 2014 Journal Article Marine Energy general, Tidal Noise
Impact of Tidal-Stream Arrays in Relation to the Natural Variability of Sedimentary Processes Robins, P., Neill, S., Lewis, M. December 2014 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Numerical Modelling of the Effect of Turbines on Currents in a Tidal Channel - Tory Channel, New Zealand Plew, D., Stevens, C. September 2013 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
Tidal Flows in Te Aumiti (French Pass), South Island, New Zealand Stevens, C., et al. November 2008 Journal Article Marine Energy general, Tidal
Tidal Stream Energy Extraction in a Large Deep Strait: The Karori Rip, Cook Strait Stevens, C., et al. February 2012 Journal Article Marine Energy general, Tidal Energy Removal
Dynamics of a Floating Platform Mounting a Hydrokinetic Turbine Dewhurst, T., et al. July 2013 Journal Article Marine Energy general, Tidal
Insights from Archaeological Analysis and Interpretation of Marine Data Sets to Inform Marine Cultural Heritage Management and Planning of Wave and Tidal Energy Development for Orkney Waters and the Pentland Firth, NE Scotland Pollard, E., et al. October 2014 Journal Article Marine Energy general, Tidal, Wave Socio-economics
Spatial and Temporal Benthic Species Assemblage Responses with a Deployed Marine Tidal Energy Device: A Small Scaled Study Broadhurst, M., Orme, C. August 2014 Journal Article Marine Energy general, Tidal Benthic Invertebrates, Ecosystem
Fish Interactions with a Commercial-Scale Tidal Energy Device in the Natural Environment Viehman, H., Zydlewski, G. January 2015 Journal Article Marine Energy general, Tidal Fish
Decision Support Tools for Collaborative Marine Spatial Planning: Identifying Potential Sites for Tidal Energy Devices Around the Mull of Kintyre, Scotland Janssen, R., Arciniegas, G., Alexander, K. March 2014 Journal Article Marine Energy general, Tidal Static Device Socio-economics, Marine Spatial Planning
Multibeam Imaging of the Environment Around Marine Renewable Energy Devices Williamson, B., Blondel, P. December 2012 Journal Article Marine Energy general, Tidal, Wave Energy Removal, Noise Birds, Fish
Numerical Modeling of the Effect of Tidal Stream Turbines on the Hydrodynamics and the Sediment Transport - Application to the Alderney Race (Raz Blanchard), France Thiébot, J., de Bois, P., Guillou, S. March 2015 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
A Modeling Study of the Potential Water Quality Impacts from In-Stream Tidal Energy Extraction Wang, T., Yang, Z., Copping, A. January 2015 Journal Article Marine Energy general, Tidal Energy Removal Nearfield Habitat
Using Hydroacoustics to Understand Fish Presence and Vertical Distribution in a Tidally Dynamic Region Targeted for Energy Extraction Viehman, H., et al. January 2015 Journal Article Marine Energy general, Tidal Fish
Tidal Power Development in Maine: Stakeholder Identification and Perceptions of Engagement Johnson, T., Jansujwicz, J., Zydlewski, G. January 2015 Journal Article Marine Energy general, Tidal Socio-economics, Stakeholder Engagement
Public Perceptions and Externalities in Tidal Stream Energy: A Valuation for Policy Making Vazquez, A., Iglesias, G. March 2015 Journal Article Marine Energy general, Tidal Socio-economics
The Regulation of Tidal Energy Development Off Nova Scotia: Navigating Foggy Waters Doelle, M., et al. September 2006 Journal Article Marine Energy general, Tidal Socio-economics
A Tidal Power Project Wright, G. September 2011 Journal Article Marine Energy general, Tidal Socio-economics
Diving Behaviour of Black Guillemots Cepphus grylle in the Pentland Firth, UK: Potential for Interactions with Tidal Stream Energy Developments Masden, E., Foster, S., Jackson, A. October 2013 Journal Article Marine Energy general, Tidal Dynamic Device Birds
Evaluation of Behavior and Survival of Fish Exposed to an Axial-Flow Hydrokinetic Turbine Amaral, S., et al. February 2015 Journal Article Marine Energy general, Tidal Dynamic Device Fish
Enhancing Local Distinctiveness Fosters Public Acceptance of Tidal Energy: A UK Case Study Devine-Wright, P. January 2011 Journal Article Marine Energy general, Tidal Socio-economics, Stakeholder Engagement
Examining the Impacts of Tidal Energy Capture from an Ecosystem Services Perspective Leslie, H., Palmer, M. January 2015 Journal Article Marine Energy general, Tidal Ecosystem
Economic Evaluation of the Recreational Value of the Coastal Environment in a Marine Renewables Deployment Area Voke, M., et al. January 2013 Journal Article Marine Energy general, Tidal, Wave Energy Removal Socio-economics, Aesthetics, Recreation
Tidal Resource Extraction in the Pentland Firth, UK: Potential Impacts on Flow Regime and Sediment Transport in the Inner Sound of Stroma Martin-Short, R., et al. April 2015 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
The Maine Tidal Power Initiative: Transdisciplinary Sustainability Science Research for the Responsible Development of Tidal Power Jansujwicz, J., Johnson, T. January 2015 Journal Article Marine Energy general, Tidal Socio-economics
The Cumulative Impact of Tidal Stream Turbine Arrays on Sediment Transport in the Pentland Firth Fairley, I., Masters, I., Karunarathna, H. August 2015 Journal Article Marine Energy general, Tidal Energy Removal Farfield Environment
A Self-Contained Subsea Platform for Acoustic Monitoring of the Environment Around Marine Renewable Energy Devices - Field Deployments at Wave and Tidal Energy Sites in Orkney, Scotland Williamson, B., et al. January 2016 Journal Article Marine Energy general, Tidal, Wave Dynamic Device, Static Device Birds, Fish, Marine Mammals
Flocculation and Sediment Deposition in a Hypertidal Creek O'Laughlin, C., van Proosdij, D., Milligan, T. July 2014 Journal Article Marine Energy general, Tidal Energy Removal
Macrotidal Estuaries: A Region of Collision Between Migratory Marine Animals and Tidal Power Development Dadswell, M., Rulifson, R. January 1994 Journal Article Marine Energy general, Tidal Dynamic Device Fish, Marine Mammals
High-Resolution Velocimetry in Energetic Tidal Currents using a Convergent-Beam Acoustic Doppler Profiler Sellar, B., Harding, S., Richmond, M. July 2015 Journal Article Marine Energy general, Tidal Energy Removal
Comparison of Underwater Background Noise during Spring and Neap Tide in a High Tidal Current Site: Ramsey Sound Broudic, M., et al. January 2013 Journal Article Marine Energy general, Tidal Noise
Sediment-Generated Noise and Bed Stress in a Tidal Channel Bassett, C., Thomson, J., Polagye, B. April 2013 Journal Article Marine Energy general, Tidal Energy Removal, Noise
Improving Assessments of Tidal Power Potential using Grid Refinement in the Coupled Ocean-Atmosphere-Wave-Sediment Transport Model Yang, X., Haas, K. July 2015 Journal Article Marine Energy general, Tidal Energy Removal
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

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