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 Sort ascending | Content Type | Technology | Stressor | Receptor |
---|---|---|---|---|---|---|
Tidal barriers and fish – Impacts and remediation in the face of increasing demand for freshwater and climate change | Bice, C.; Huisman, J.; Kimball, M.; et al. | Journal Article | Marine Energy, Tidal | Human Dimensions, Climate Change, Fisheries | ||
The effect of artificial reef design on the attraction of herbivorous fish and on coral recruitment, survival, and growth | Hylkema, A.; Debrot, A.; Cammenga, R.; et al. | Journal Article | Attraction, Habitat Change | Ecosystem Processes, Fish | ||
Cost-benefit analysis of tidal energy production in a coastal lagoon: The case of Ria Formosa – Portugal | Rodrigues, N.; Pintassilgo, P.; Calhau, F.; et al. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment, Sediment Transport, Human Dimensions, Social & Economic Data | |
Wave Farms Impact on the Coastal Processes - A Case Study Area in the Portuguese Nearshore | Onea, F.; Rusu, L.; Carp, G.; et al. | Journal Article | Marine Energy, Wave | Changes in Flow | Physical Environment, Sediment Transport | |
Fish assemblages of three common artificial reef designs during early colonization | Hylkema, A.; Debrot, A.; Osinga, R.; et al. | Journal Article | Habitat Change | Ecosystem Processes, Fish, Invertebrates | ||
An Overview of the Expected Shoreline Impact of the Marine Energy Farms Operating in Different Coastal Environments | Raileanu, A.; Onea, F.; Rusu, E. | Journal Article | Marine Energy | Changes in Flow | Physical Environment, Sediment Transport | |
Monitoring getijdenturbines Oosterscheldekering (Oosterscheldekering Tidal Turbines Monitoring Annual Report 2018) | Leopold, M.; Scholl, M. | Report | Marine Energy, Tidal | Changes in Flow, Collision | Physical Environment, Sediment Transport, Marine Mammals, Cetaceans, Pinnipeds | |
Irregular wave validation of a coupling methodology for numerical modelling of near and far field effects of wave energy converter arrays | Fernández, G.; Stratigaki, V.; Troch, P. | Journal Article | Marine Energy, Wave | Changes in Flow | Physical Environment, Water Quality | |
Coupling Methodology for Studying the Far Field Effects of Wave Energy Converter Arrays over a Varying Bathymetry | Fernández, G.; Balitsky, P.; Stratigaki, V.; et al. | Journal Article | Marine Energy, Wave | Changes in Flow | Physical Environment, Water Quality | |
Deployment characterization of a floatable tidal energy converter on a tidal channel, Ria Formosa, Portugal | Pacheco, A.; Gorbeña, E.; Garel, E.; et al. | Journal Article | Tidal, Marine Energy | Physical Environment | ||
The Effect of a Wave Energy Farm Protecting an Aquaculture Installation | Silva, D.; Rusu, E.; Soares, C. | Journal Article | Marine Energy, Wave | Changes in Flow | Physical Environment, Water Quality, Human Dimensions, Fisheries | |
Study on the Influence of the Distance to Shore for a Wave Energy Farm Operating in the Central Part of the Portuguese Nearshore | Rusu, E.; Onea, F. | Journal Article | Wave, Marine Energy | Changes in Flow | Physical Environment | |
The expected efficiency and coastal impact of a hybrid energy farm operating in the Portuguese nearshore | Onea, F.; Rusu, E. | Journal Article | Wind Energy, Fixed Offshore Wind, Marine Energy | Changes in Flow | Physical Environment | |
Assessment of the Changes Induced by a Wave Energy Farm in the Nearshore Wave Conditions | Bento, A.; Rusu, E.; Martinho, P.; et al. | Journal Article | Marine Energy, Wave | Changes in Flow | Physical Environment | |
Coastal Impact Induced by a Pelamis Wave Farm Operating in the Portuguese Nearshore | Rusu, E.; Soares, C. | Journal Article | Marine Energy, Wave | Changes in Flow | Physical Environment | |
First Specific Biodiversity Assessment in the Portuguese Pilot Zone for Marine Renewables | Coelho, H.; Rodrigues, S.; Ferriera, R.; et al. | Conference Paper | Marine Energy | Birds, Ecosystem Processes, Marine Mammals | ||
The Impact Of Wave Energy Farms In The Shoreline Wave Climate: Portuguese Pilot Zone Case Study Using Pelamis Energy Wave Devices | Palha, A.; Mendes, L.; Fortes, C.; et al. | Journal Article | Marine Energy, Wave | Changes in Flow | Physical Environment | |
Effects of Artificial Reefs (Southern Portugal) on Sediment-Water Transport of Nutrients: Importance of the Hydrodynamic Regime | Falcão, M.; Santos, M.; Drago, T.; et al. | Journal Article | Changes in Flow | Physical Environment, Sediment Transport, Water Quality | ||
A Protocol for Classifying Ecologically Relevant Marine Zones, A Statistical Approach | Verfaillie, E.; Degraer, S.; Schelfaut, K.; et al. | Journal Article | Marine Energy | Ecosystem Processes | ||
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. | Journal Article | Marine Energy, Tidal | Changes in Flow | Physical Environment |
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