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 |
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Recent Advances in Assessing Environmental Effects of Marine Renewable Energy Around the World | Copping, A.; Martinez, L.; Hemery, L.; et al. | Journal Article | Marine Energy, Ocean Current, OTEC, Riverine, Salinity Gradient, Tidal, Wave | Attraction, Changes in Flow, Collision, Displacement, EMF, Habitat Change, Noise | Birds, Fish, Invertebrates, Marine Mammals, Physical Environment | |
Predicted ecological consequences of wave energy extraction and climate-related changes in wave exposure on rocky shore communities | Want, A.; Waldman, S.; Burrows, T.; et al. | Journal Article | Marine Energy, Wave | Changes in Flow | Invertebrates | |
Anthropogenic underwater noise: A review on physiological and molecular responses of marine biota | El-Dairi, R.; Outinen, O.; Kankaanpää, H. | Journal Article | Noise | Fish, Invertebrates, Marine Mammals | ||
Automatic classification of biofouling images from offshore renewable energy structures using deep learning | Signor, J.; Schoefs, F.; Quillienn, N.; et al. | Journal Article | Attraction | Invertebrates | ||
Key Biofouling Organisms in Tidal Habitats Targeted by the Offshore Renewable Energy Sector in the North Atlantic Include the Massive Barnacle Chirona hameri | Want, A.; Goubard, A.; Jonveaux, S.; et al. | Journal Article | Marine Energy, Tidal | Attraction, Habitat Change | Invertebrates | |
Impact of hydrodynamics on community structure and metabolic production of marine biofouling formed in a highly energetic estuary | Portas, A.; Carriot, N.; Ortalo-Magne, A.; et al. | Journal Article | Attraction | Invertebrates | ||
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 | |
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 | |
Marine energy converters: Potential acoustic effects on fishes and aquatic invertebrates | Popper, A.; Haxel, J.; Staines, G.; et al. | Journal Article | Marine Energy | Noise | Fish, Invertebrates | |
Introducing energy into marine environments: A lab-scale static magnetic field submarine cable simulation and its effects on sperm and larval development on a reef forming serpulid | Oliva, M.; De Marchi, L.; Cuccaro, A.; et al. | Journal Article | EMF | Invertebrates | ||
A New Miniaturized Acoustic Transmitter for Marine Animal Tracking | Li, H.; Deng, Z.; Lu, Z.; et al. | Journal Article | Marine Energy | Fish, Invertebrates, Marine Mammals | ||
Evaluation of the Effects of Electrical Stimulation: A Pilot Experiment on the Marine Benthic Foraminiferal Species Amphistegina lessonii | Rebecchi, F.; Lattanzi, D.; Abramovich, S.; et al. | Journal Article | EMF | Invertebrates | ||
Sound sensitivity of the giant scallop (Placopecten magelanicus) is life stage, intensity, and frequency dependent | Jézéquel, Y.; Cones, S.; Mooney, T. | Journal Article | Noise | Invertebrates | ||
Assessing the impacts of anthropogenic sounds on early stages of benthic invertebrates: The “Larvosonic system” | Olivier, F.; Gigot, M; Mathias, D.; et al. | Journal Article | Marine Energy, Wind Energy | Noise | Invertebrates | |
Commercial cuttlefish exposed to noise from offshore windmill construction show short-range acoustic trauma | Solé, M.; De Vreese, S.; Fortuno, J-M.; et al. | Journal Article | Marine Energy, Wind Energy | Noise | Invertebrates | |
Eukaryotic diversity of marine biofouling from coastal to offshore areas | Portas, A.; Quillienn, N.; Culioli, J.; et al. | Journal Article | Marine Energy | Chemicals | Invertebrates | |
A comprehensive overview of environmental footprints of water desalination and alleviation strategies | Shokri, A.; Fard, M. | Journal Article | Marine Energy | Chemicals, Entanglement | Fish, Invertebrates, Human Dimensions | |
Influence of coating type, colour, and deployment timing on biofouling by native and non-native species in a marine renewable energy context | Nall, C.; Schläppy, M.; Cottier-Cook, E.; et al. | Journal Article | Marine Energy | Attraction | Invertebrates | |
Seabed morphology and bed shear stress predict temperate reef habitats in a high energy marine region | Jackson-Bué, T.; Williams, G.; Whitton, T.; et al. | Journal Article | Marine Energy, Tidal | Invertebrates, Physical Environment | ||
Practical Approaches for Providing Empirical Data on Seabird Behavior and Prey Assemblages in Tidal Channels | Fraser, S.; Waggitt, J. | Journal Article | Marine Energy, Tidal | Collision, Habitat Change | Birds, Seabirds, Fish, Invertebrates | |
Conceptualisation of multiple impacts interacting in the marine environment using marine infrastructure as an example | Komyakova, V.; Jaffrés, J.; Strain, E.; et al. | Journal Article | Marine Energy, Wind Energy | Attraction | Invertebrates | |
Satellite-Based Lagrangian Model Reveals How Upwelling and Oceanic Circulation Shape Krill Hotspots in the California Current System | Messie, M.; Sancho-Gallegos, D.; Fiechter, J.; et al. | Journal Article | Invertebrates | |||
Can artificial magnetic fields alter the functional role of the blue mussel, Mytilus edulis? | Albert, L.; Maire, O.; Olivier, F.; et al. | Journal Article | Marine Energy, Wind Energy, Fixed Offshore Wind | EMF | Invertebrates | |
The Effects of Anthropogenic Electromagnetic Fields (EMF) on the Early Development of Two Commercially Important Crustaceans, European Lobster, Homarus gammarus (L.) and Edible Crab, Cancer pagurus (L.) | Harsanyi, P.; Scott, K.; Easton, B.; et al. | Journal Article | EMF | Invertebrates | ||
Establishing an Agenda for Biofouling Research for the Development of the Marine Renewable Energy Industry in Indonesia | Iswadi, A.; Porter, J.; Bell, M.; et al. | Journal Article | Marine Energy | Attraction | Invertebrates | |
Noisy waters can influence young-of-year lobsters’ substrate choice and their antipredatory responses | Leiva, L.; Scholz, S.; Gimenez, L.; et al. | Journal Article | Noise | Invertebrates | ||
Biological Consequences of Marine Energy Development on Marine Animals | Hemery, L.; Copping, A.; Overhus, D. | Journal Article | Marine Energy, Tidal | Changes in Flow, Collision, EMF, Entanglement, Habitat Change, Noise | Seabirds, Pelagic Fish, Invertebrates, Cetaceans, Pinnipeds | |
A new framework and tool for ecological risk assessment of wave energy converters projects | Galparsoro, I.; Korta, M.; Subirana, I.; et al. | Journal Article | Marine Energy, Wave | Birds, Ecosystem Processes, Fish, Invertebrates, Marine Mammals, Physical Environment, Reptiles, Human Dimensions | ||
Environmental Impacts of Tidal and Wave Energy Converters | Hutchison, Z.; Lieber, L.; Miller, R.; et al. | Journal Article | Marine Energy, Tidal, Wave | Changes in Flow, Collision, EMF, Habitat Change, Noise | Invertebrates, Marine Mammals, Physical Environment | |
A roadmap towards quantitative cumulative impact assessments: Every step of the way | Piet, G.; Tamis, J.; Volwater, J.; et al. | Journal Article | Wind Energy, Fixed Offshore Wind | Collision, Displacement, Noise | Birds, Invertebrates, Marine Mammals, Human Dimensions | |
Effects of a Wave Power Park with No-Take Zone on Decapod Abundance and Size | Bender, A.; Langhamer, O.; Molis, M.; et al. | Journal Article | Marine Energy, Wave | Invertebrates, Human Dimensions, Fisheries | ||
Exposure to Electromagnetic Fields (EMF) from Submarine Power Cables Can Trigger Strength-Dependent Behavioural and Physiological Responses in Edible Crab, Cancer pagurus (L.) | Scott, K.; Harsanyi, P.; Easton, B.; et al. | Journal Article | Marine Energy, Wind Energy, Fixed Offshore Wind | EMF | Invertebrates | |
Sea Lice Are Sensitive to Low Frequency Sounds | Solé, M.; Lenoir, M.; Fortuno, J-M.; et al. | Journal Article | Marine Energy, Wind Energy | Noise | Invertebrates, Human Dimensions, Fisheries | |
Renewable energy production in a Mexican biosphere reserve: Assessing the potential using a multidisciplinary approach | Wojtarowski, A.; Martinez, M.; Silva, R.; et al. | Journal Article | Marine Energy, Salinity Gradient | Birds, Ecosystem Processes, Invertebrates, Human Dimensions, Social & Economic Data | ||
A call to assess the impacts of electromagnetic fields from subsea cables on the movement ecology of marine migrants | Klimley, A.; Putnam, N.; Keller, B.; et al. | Journal Article | Marine Energy, Wind Energy | EMF | Fish, Invertebrates | |
A modelling evaluation of electromagnetic fields emitted by buried subsea power cables and encountered by marine animals: considerations for marine renewable energy development | Hutchison, Z.; Gill, A.; Sigray, P.; et al. | Journal Article | Marine Energy, Wind Energy, Fixed Offshore Wind | EMF | Fish, Invertebrates | |
Substrate vibrations and their potential effects upon fishes and invertebrates | Hawkins, A.; Hazelwood, R.; Popper, A.; et al. | Journal Article | Noise | Fish, Invertebrates | ||
Multi-Disciplinary and Multi-Scale Assessment of Marine Renewable Energy Structure in a Tidal System | Raoux, A.; Robin, I.; Pezy, J.; et al. | Journal Article | Marine Energy, Tidal, Wind Energy, Fixed Offshore Wind | Attraction, Changes in Flow, Habitat Change | Physical Environment, Fish, Invertebrates | |
Larval cross‐shore transport estimated from internal waves with a background flow: The effects of larval vertical position and depth regulation | Garwood, J.; Lucas, A.; Naughton, P.; et al. | Journal Article | Changes in Flow | Invertebrates | ||
The soundscape of the Anthropocene ocean | Duarte, C.; Chapuis, L.; Collin, S.; et al. | Journal Article | Noise | Birds, Fish, Invertebrates, Marine Mammals | ||
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 | |
PelagiCam: a novel underwater imaging system with computer vision for semi-automated monitoring of mobile marine fauna at offshore structures | Sheehan, E.; Bridger, D.; Nancollas, S.; et al. | Journal Article | Marine Energy, Wind Energy, Fixed Offshore Wind | Fish, Invertebrates | ||
Effects of marine noise pollution on Mediterranean fishes and invertebrates: A review | Di Franco, E.; Pierson, P.; Di lorio, L.; et al. | Journal Article | Marine Energy, Wind Energy, Fixed Offshore Wind | Noise | Fish, Invertebrates | |
Colonisation of wave power foundations by mobile mega- and macrofauna – a 12 year study | Bender, A.; Langhamer, O.; Sundberg, J. | Journal Article | Marine Energy, Wave | Attraction, Habitat Change | Fish, Invertebrates | |
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 | |
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 | ||
Transferable, predictive models of benthic communities informs marine spatial planning in a remote and data‐poor region | Bridge, T.; Huang, Z.; Przeslawski, R.; et al. | Journal Article | Marine Energy | Invertebrates, Human Dimensions, Marine Spatial Planning | ||
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 | |
Tongan socio-environmental spatial layers for marine ecosystem management | Smallhorn-West, P.; Gordon, S.; Dempsey, A.; et al. | Journal Article | Invertebrates, Physical Environment, Human Dimensions, Social & Economic Data |
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