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 |
---|---|---|---|---|---|---|
Static magnetic fields reduce swimming activity of Atlantic cod (Gadus morhua) and haddock (Melanogrammus aeglefinus) larvae | Cresci, A.; Durif, C.; Larsen, T.; et al. | Journal Article | Marine Energy, Wind Energy | EMF | Fish, Demersal Fish | |
Effects of small marine energy deployments on oceanographic systems | Whiting, J.; Garavelli, L.; Farr, H.; et al. | Journal Article | Marine Energy, Tidal, Wave | Changes in Flow | Physical Environment | |
‘Scaling up’ our understanding of environmental effects of marine renewable energy development from single devices to large-scale commercial arrays | Hasselman, D.; Hemery, L.; Copping, A.; et al. | Journal Article | Marine Energy | Collision, Displacement, EMF, Entanglement, Habitat Change, Noise | ||
Waterbodies thermal energy based systems interactions with marine environment — A review | Bordbar, A.; Georgoulas, K.; Dai, Y.; et al. | Journal Article | Marine Energy, OTEC | Changes in Flow, Chemicals, Habitat Change | Human Dimensions | |
Modeling Morphodynamic Impacts and Optimization of Marine Hydrokinetic Arrays in Shallow Offshore Environments | Moghadam, H.; Ortiz, A. | Journal Article | Marine Energy | Changes in Flow, Habitat Change | Physical Environment, Sediment Transport | |
Red rock crab (Cancer productus) movement is not influenced by electromagnetic fields produced by a submarine power transmission cable | Williams, J.; Jaco, E.; Scholz, Z.; et al. | Journal Article | Marine Energy, Wind Energy | EMF | Invertebrates | |
Tidal energy extraction modifies tidal asymmetry and transport in a shallow, well-mixed estuary | Spicer, P.; Yang, Z.; Wang, T.; et al. | Journal Article | Marine Energy, Tidal | Changes in Flow, Habitat Change | Physical Environment, Sediment Transport, Water Quality | |
Effects of anthropogenic magnetic fields on the behavior of a major predator of the intertidal and subtidal zones, the velvet crab Necora puber | Albert, L.; Olivier, F.; Jolivet, A.; et al. | Journal Article | Marine Energy, Wind Energy | EMF | Invertebrates | |
Effect of electromagnetic fields from renewable energy subsea power cables on righting reflex and physiological response of coastal invertebrates | Chapman, E.; Rochas, C.; Piper, A.; et al. | Journal Article | Marine Energy, Wind Energy, Fixed Offshore Wind | EMF | Invertebrates | |
Recording the Magnetic Field Produced by an Undersea Energy Generating Device: A Low-Cost Alternative | Luna, V.; Silva, R.; Mendoza, M.; et al. | Journal Article | Marine Energy | EMF | Marine Mammals | |
A Computational Platform to assess the Coastal Impact of the Marine Energy Farms | Rusu, E.; Onea, F. | Conference Paper | Marine Energy, Wave | Changes in Flow | Physical Environment | |
SafeWave Deliverable 2.2 Monitoring of Electromagnetic fields | Imperadore, A.; Amaral, L.; Tanguy, F.; et al. | Report | Marine Energy, Wave | EMF | ||
European offshore renewable energy, towards a sustainable future | Soukissian, T.; O’Hagan, A-M.; Azzellino, A.; et al. | Report | Marine Energy, Ocean Current, Tidal, Wave, Wind Energy, Fixed Offshore Wind | Collision, EMF, Noise | Birds, Fish, Marine Mammals, Human Dimensions, Legal & Policy, Social & Economic Data | |
The bigger picture: developing a low-cost graphical user interface to process drone imagery of tidal stream environments | Slingsby, J.; Scott, B.; Kregting, L.; et al. | Journal Article | Marine Energy, Tidal | Changes in Flow, Collision, Displacement | Birds, Seabirds | |
Deep-sea impacts of climate interventions | Levin, L.; Alfaro-Lucas, J.; Colaco, A.; et al. | Journal Article | Marine Energy, OTEC | Changes in Flow | Physical Environment, Water Quality | |
Safe passage for fish: The case for in-stream turbines | Brown, E.; Sulaeman, S.; Quispe-Abad, R.; et al. | Journal Article | Marine Energy, Riverine | Changes in Flow, Collision, Noise | Fish | |
Environmental Impact Assessment: Wave Swell Energy Test Site, Grassy Harbour, King Island, Tasmania | Marine Solutions | Report | Marine Energy, Wave | Changes in Flow, Habitat Change | Environmental Impact Assessment | |
Magnetic fields generated by submarine power cables have a negligible effect on the swimming behavior of Atlantic lumpfish (Cyclopterus lumpus) juveniles | Durif, C.; Nyqvist, D.; Taormina, B.; et al. | Journal Article | Marine Energy, Wind Energy | EMF | Fish, Pelagic Fish | |
Insights from the management of offshore energy resources: Toward an ecosystem-services based management approach for deep-ocean industries | Bravo, M.; Brandt, M.; van der Grient, J.; et al. | Journal Article | Marine Energy, Wind Energy, Fixed Offshore Wind, Floating Offshore Wind | Avoidance, Changes in Flow, EMF, Habitat Change, Noise | Ecosystem Processes, Fish, Social & Economic Data | |
Evaluation of the Effects of Turbulence on the Behaviour of Migratory Fish | Odeh, M.; Noreika, J.; Haro, A.; et al. | Report | Riverine, Marine Energy | Changes in Flow | Fish | |
Wake Effects in Tidal Current Turbine Farms | Macleod, A.; Barnes, S.; Rados, K.; et al. | Conference Paper | Marine Energy, Tidal | Changes in Flow | Physical Environment |
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