The Knowledge Base provides access to documents and information about the environmental effects of marine renewable energy, supporting the OES-Environmental initiative. Relevant documents from around the world are compiled into a user-friendly table that displays all content available in Tethys. Results can be narrowed using the keyword filters on the right, or with search terms entered in the text box, including targeted searches (e.g., org:DOE, author:copping). Content may also be sorted alphabetically by clicking on column headers. Some entries will appear on the next page.
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Title | Author | Date | Content Type | Technology | Stressor | Receptor |
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2020 State of the Science Report - Chapter 10: Environmental Monitoring Technologies and Techniques for Detecting Interactions of Marine Animals with Turbines | Hasselman, D.; Barclay, D.; Cavagnaro, R.; et al. | Report | Marine Energy, Tidal, Wave | |||
2020 State of the Science Report - Chapter 9: Social and Economic Data Collection for Marine Renewable Energy | Freeman, M. | Report | Marine Energy, Tidal, Wave | Human Dimensions, Social & Economic Data | ||
2020 State of the Science Report - Chapter 8: Encounters of Marine Animals with Marine Renewable Energy Device Mooring Systems and Subsea Cables | Garavelli, L. | Report | Marine Energy, Tidal, Wave | Entanglement | Marine Mammals | |
2020 State of the Science Report - Chapter 7: Changes in Oceanographic Systems Associated with Marine Renewable Energy Devices | Whiting, J.; Chang, G. | Report | Marine Energy, Tidal, Wave | Changes in Flow | Physical Environment, Sediment Transport, Water Quality | |
2020 State of the Science Report - Chapter 6: Changes in Benthic and Pelagic Habitats Caused by Marine Renewable Energy Devices | Hemery, L. | Report | Marine Energy, Tidal, Wave | Habitat Change | ||
2020 State of the Science Report - Chapter 5: Risk to Animals from Electromagnetic Fields Emitted by Electric Cables and Marine Renewable Energy Devices | Gill, A.; Desender, M. | Report | Marine Energy, Tidal, Wave | EMF | Fish, Invertebrates | |
2020 State of the Science Report - Chapter 4: Risk to Marine Animals from Underwater Noise Generated by Marine Renewable Energy Devices | Polagye, B.; Bassett, C. | Report | Marine Energy, Tidal, Wave | Noise | Fish, Marine Mammals | |
2020 State of the Science Report - Chapter 3: Collision Risk for Animals around Turbines | Sparling, C.; Seitz, A.; Masden, E.; et al. | Report | Marine Energy, Tidal | Collision | Birds, Fish, Marine Mammals | |
2020 State of the Science Report - Chapter 2: Marine Renewable Energy: Environmental Effects and Monitoring Strategies | Copping, A. | Report | Marine Energy, Tidal, Wave | |||
2020 State of the Science Report - Chapter 1: Marine Renewable Energy and Ocean Energy Systems | Copping, A. | Report | Marine Energy, Tidal, Wave | |||
Summary of workshop: Passive acoustic monitoring in high flow environments | European Marine Energy Centre (EMEC) | Report | Marine Energy, Tidal | |||
Assessing the effects of tidal stream marine renewable energy on seabirds: A conceptual framework | Isaksson, N.; Masden, E.; Williamson, B.; et al. | Journal Article | Marine Energy, Tidal | Collision, Displacement | Birds, Seabirds | |
Public perceptions of tidal energy: Can you predict social acceptability across coastal communities in England? | Hooper, T.; Hattam, C.; Edwards-Jones, A.; et al. | Journal Article | Marine Energy, Tidal | Human Dimensions, Social & Economic Data, Stakeholder Engagement | ||
The Push for Tidal Power Faces Its Biggest Challenge Yet | Royte, E. | Magazine Article | Marine Energy, Tidal | |||
Simulating Current-Energy Converters: SNL-EFDC Model Development, Verification, and Parameter Estimation | James, S.; Johnson, E.; Barco, J.; et al. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment | |
Short Science Summary: Collision Risk | OES-Environmental | Summary | Marine Energy, Tidal | Collision | ||
2020 State of the Science Report - Chapter 14: Summary and Path Forward | Copping, A. | Report | Marine Energy, Tidal, Wave | |||
2020 State of the Science Report - Chapter 13: Risk Retirement and Data Transferability for Marine Renewable Energy | Copping, A.; Freeman, M.; Gorton, A.; et al. | Report | Marine Energy, Tidal, Wave | EMF, Noise | Human Dimensions | |
2020 State of the Science Report - Chapter 12: Adaptive Management Related to Marine Renewable Energy | Le Lièvre, C. | Report | Marine Energy, Tidal, Wave | Human Dimensions | ||
2020 State of the Science Report - Chapter 11: Marine Spatial Planning and Marine Renewable Energy | O'Hagan, A. | Report | Marine Energy, Tidal, Wave | Human Dimensions, Marine Spatial Planning | ||
Tidal current power effects on nearby sandbanks: a case study in the Race of Alderney | Blunden, L.; Haynes, S.; Bahaj, A. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment, Sediment Transport | |
Integrating Hydroacoustic Approaches to Predict Fish Interactions with In-stream Tidal Turbines | Viehman, H.; Hasselman, D.; Boucher, T.; et al. | Report | Marine Energy, Tidal | Collision | Fish | |
Assessing the Environmental Impact of the Annapolis Tidal Power Project | Tidmarsh, W. | Journal Article | Marine Energy, Tidal | Physical Environment, Fish | ||
Cavitation observations, underwater radiated noise measurements and full-scale predictions of the Hydro-Spinna turbine | Rosli, R.; Shi, W.; Aktas, B.; et al. | Journal Article | Marine Energy, Tidal | Noise | ||
Mapping cumulative impacts to coastal ecosystem services in British Columbia | Singh, G.; Eddy, I.; Halpern, B.; et al. | Journal Article | Marine Energy, Tidal, Wave | Human Dimensions, Marine Spatial Planning | ||
Integrating stakeholder knowledge through modular cooperative participatory processes for marine spatial planning outcomes (CORPORATES) | Slater, A.; Irvine, K.; Byg, A.; et al. | Journal Article | Marine Energy, Tidal, Wave, Wind Energy, Fixed Offshore Wind | Human Dimensions, Marine Spatial Planning, Stakeholder Engagement | ||
Tidal Patterns and Sediment Dynamics in a Hypertidal Estuary Influenced by a Tidal Power Station | Rtimi, R.; Sottolichio, A.; Tassi, P. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment, Sediment Transport | |
Succession in epibenthic communities on artificial reefs associated with marine renewable energy facilities within a tide-swept environment | Taormina, B.; Percheron, A.; Marzloff, M.; et al. | Journal Article | Marine Energy, Tidal | Attraction, Habitat Change | Fish, Invertebrates | |
Socioeconomic Analysis Plan for the ELEMENT Project | Smith, D.; Gorintin, F. | Guidance | Marine Energy, Tidal | Human Dimensions, Social & Economic Data | ||
Fundy Tidal Power Development: Preliminary Evaluation of Its Environmental Consequences to the Resources of the State of Maine | Larsen, P.; Topinka, J.; Lerman, A.; et al. | Report | Marine Energy, Tidal | |||
Automatic Classification of Biological Targets in a Tidal Channel using a Multibeam Sonar | Cotter, E.; Polagye, B. | Journal Article | Marine Energy, Tidal | |||
Current trends and prospects of tidal energy technology | Chowdhury, M.; Rahman, K.; Selvanathan, V.; et al. | Journal Article | Marine Energy, Tidal | Human Dimensions, Legal & Policy | ||
A review of multi-criteria decision making applications for renewable energy site selection | Shao, M.; Han, Z.; Sun, J.; et al. | Journal Article | Marine Energy, Tidal, Wave, Wind Energy, Land-Based Wind, Fixed Offshore Wind | Human Dimensions, Marine Spatial Planning | ||
Asymmetric effects of a modelled tidal turbine on the flow and seabed | Ramírez-Mendoza, R.; Murdoch, L.; Jordan, L.; et al. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment, Sediment Transport | |
Potential Environmental Effects of Marine Renewable Energy Development—The State of the Science | Copping, A.; Hemery, L.; Overhus, D.; et al. | Journal Article | Marine Energy, Tidal, Wave | Changes in Flow, Collision, EMF, Entanglement, Habitat Change, Noise | Birds, Fish, Invertebrates, Marine Mammals, Physical Environment, Human Dimensions, Marine Spatial Planning, Social & Economic Data | |
Evaluating the Effects of Tidal Turbines on Water-Mass Transport with the Lagrangian Barycentric Method | Guillou, N.; Chapalain, G. | Book Chapter | Marine Energy, Tidal | Changes in Flow | Physical Environment, Sediment Transport | |
Assessing the Impact of Rows of Tidal-Stream Turbines on the Overtides of the M2 | Potter, D.; Ilić, S.; Folkard, A. | Conference Paper | Marine Energy, Tidal | Changes in Flow | ||
Renewable energy homes for marine life: Habitat potential of a tidal energy project for benthic megafauna | Taormina, B.; Laurans, M.; Marzloff, M.; et al. | Journal Article | Marine Energy, Tidal | Habitat Change | Physical Environment, Fish, Invertebrates | |
Update on the Marine Environmental Consequences of Tidal Power Development in the Upper Reaches of the Bay of Fundy | Gordon, D.; Dadswell, M. | Report | Tidal, Marine Energy | Physical Environment | ||
A Review on Environmental and Social Impacts of Thermal Gradient and Tidal Currents Energy Conversion and Application to the Case of Chiapas, Mexico | Rivera, G.; Felix, A.; Mendoza, E. | Journal Article | Marine Energy, OTEC, Tidal | Changes in Flow, Collision, EMF, Habitat Change, Noise | Birds, Ecosystem Processes, Physical Environment, Fish, Marine Mammals, Human Dimensions | |
Data Transferability and Collection Consistency in Marine Renewable Energy: An Update to the 2018 Report | Copping, A.; Gorton, A.; Freeman, M.; et al. | Report | Marine Energy, Tidal, Wave | |||
Pan American Marine Energy Conference 2020 Book of Abstracts | Rojas M., J.; Meza, C. | Conference Paper | Marine Energy, Ocean Current, OTEC, Salinity Gradient, Tidal, Wave, Wind Energy, Fixed Offshore Wind, Floating Offshore Wind | |||
Three-dimensional modelling of suspended sediment transport in the far wake of tidal stream turbines | Li, X.; Li, M.; Amoudry, L.; et al. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment, Sediment Transport | |
Enhancing local support for tidal energy projects in developing countries: Case study in Flores Timur Regency, Indonesia | Ramachandran, R.; Takagi, K.; Matsuda, H. | Journal Article | Marine Energy, Tidal | Human Dimensions, Social & Economic Data | ||
Public perceptions of tidal energy between Australia and Canada | Barber, D. | Thesis | Marine Energy, Tidal | Human Dimensions, Social & Economic Data | ||
Tapping Renewable Energy Sources in Contemporary India: Issues and Challenges | Chandy, S. | Journal Article | Marine Energy, OTEC, Tidal, Wave, Wind Energy | Human Dimensions, Legal & Policy | ||
Use of a model turbine to investigate the high striking risk of fish with tidal and oceanic current turbine blades under slow rotational speed | Yoshida, T.; Zhou, J.; Park, S.; et al. | Journal Article | Marine Energy, Ocean Current, Tidal | Collision | Fish | |
Environmental impact index for tidal power plants in amazon region coast | Progênio, M.; Blanco, C.; Cruz, J.; et al. | Journal Article | Marine Energy, Tidal | |||
Towards a Tidal Farm in Banks Strait, Tasmania: Influence of Tidal Array on Hydrodynamics | Auguste, C.; Marsh, P.; Nader, J.; et al. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment, Sediment Transport | |
Life Cycle Assessment of Electricity Generation from an Array of Subsea Tidal Kite Prototypes | Kaddoura, M.; Tivander, J.; Molander, S. | Journal Article | Marine Energy, Tidal | Human Dimensions, Life Cycle Assessment |
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