Riverine

Capturing energy from river currents.

Riverine energy technologies extract the kinetic energy from flowing water in rivers to generate electricity. Although not technically a marine resource, as part of the natural hydrological cycle, water from drainage basins, groundwater springs, and snow melt feed rivers that flow towards lakes, seas, and oceans. This movement of water downstream can be used to generate electricity via riverine turbines or hydroelectric dams.

Riverine Turbines

Riverine turbines capture the kinetic energy from the flowing water in rivers, streams, canals, and creeks to generate electricity. These turbines can be mounted on the ground, attached to a fixed or floating structure, or suspended within the water column. Riverine turbines are similar to those used for tidal energy, except that they are designed to extract energy from water that flows in only one direction.

_{Photo Credit: Ocean Renewable Power Company (ORPC)}

Hydroelectric Dams

Hydroelectric dams store large volumes of water which, when allowed to flow downstream, spin turbines that then generate electricity. The power extracted from the water depends on the volume of dammed water and the height between the source and the turbines.
Please note: Very little of the content in Tethys deals with the environmental effects of hydroelectric dams, as this topic falls outside of Tethys’ scope.

_{Photo Credit: Martina Nolte / Creative Commons CC-by-sa-3.0 de}

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 turbines within strong currents. It should be noted that these turbines spin much slower than propellers on ships, and that marine mammals are typically less common in most rivers. There is some concern that noise from the 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 and affect water quality. Large-scale changes in flow (from arrays) may alter the natural physical system, potentially affecting ecosystem processes, though this may be seen as a benefit for flood protection.

Affiliated Marine and Wind Energy Environmental Documents

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Title	Author	Date	Content Type	Technology	Stressor	Receptor
Collision Risk Evidence Base	OES-Environmental	April 2025	Summary	Marine Energy, Ocean Current, Riverine, Tidal	Collision
Marine Fish Passage: Underappreciated Threats to Connectivity Within the Marine Environment	Lennox, R., Birnie-Gauvin, K., Bate, C.	January 2025	Journal Article	Marine Energy, Riverine, Tidal, Wind Energy, Fixed Offshore Wind, Floating Offshore Wind	Displacement, EMF, Habitat Change, Noise	Fish, Demersal Fish, Pelagic Fish, Physical Environment, Sediment Transport, Human Dimensions, Marine Spatial Planning
Recent Advances in Assessing Environmental Effects of Marine Renewable Energy Around the World	Copping, A., Martinez, L., Hemery, L.	September 2024	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
In situ wake measurement behind a 25-kW freewheeling vertical axis hydrokinetic turbine in energetic riverine environment using acoustic Doppler current profiler and acoustic Doppler velocimeter	Dharamsi, A.	August 2024	Thesis	Marine Energy, Riverine	Changes in Flow	Physical Environment
Ocean Energy in Islands and Remote Locations: Insights from Five Experts	Ocean Energy Systems (OES)	October 2023	Report	Marine Energy, Riverine, Tidal, Wave		Human Dimensions
Imaging-sonar observations of salmonid interactions with a vertical axis instream turbine	Bender, A., Langhamer, O., Francisco, F.	June 2023	Journal Article	Marine Energy, Riverine	Attraction, Avoidance	Fish
Fish response to the presence of hydrokinetic turbines as a sustainable energy solution	Müller, S., Muhawenimana, V., Sonnino-Sorisio, G.	May 2023	Journal Article	Marine Energy, Riverine	Attraction, Avoidance	Fish
Safe passage for fish: The case for in-stream turbines	Brown, E., Sulaeman, S., Quispe-Abad, R.	March 2023	Journal Article	Marine Energy, Riverine	Changes in Flow, Collision, Noise	Fish
Towards Resolving the Risk of Turbine Collision on Fish	Garavelli, L., Rose, D., Staines, G.	November 2022	Report	Marine Energy, Riverine, Tidal	Collision	Fish
Implementation of the Spatial Environmental Assessment Toolkit	McWilliams, S., Jones, C., Roberts, J.	September 2022	Presentation	Marine Energy, Riverine, Tidal, Wave	Habitat Change, Noise
Acoustic characteristics of a horizontal axis micro hydrokinetic turbine	Wang, X., Hu, Z., Yan, Y.	September 2022	Journal Article	Marine Energy, Riverine, Tidal	Noise
Characterizing Sockeye Salmon Smolt Interactions with a Hydrokinetic Turbine in the Kvichak River, Alaska	Courtney, M., Flanigan, A., Hostetter, M.	July 2022	Journal Article	Marine Energy, Riverine	Collision	Fish
Hydrokinetic energy conversion: A global riverine perspective	Ridgill, M., Lewis, M., Robins, P.	July 2022	Journal Article	Marine Energy, Riverine
Capabilities of an Acoustic Camera to Inform Fish Collision Risk with Current Energy Converter Turbines	Staines, G., Mueller, R., Seitz, A.	March 2022	Journal Article	Marine Energy, Riverine, Tidal	Collision	Fish
Development of riverine hydrokinetic energy systems in Colombia and other world regions: a review of case studies	Aristizábal-Tique, V., Villegas-Quiceno, A., Arbeláez-Pérez, O.	November 2021	Journal Article	Marine Energy, Riverine
Assessments of Available Riverine Hydrokinetic Energy: A Review	Kirby, K., Ferguson, S., Rennie, C.	November 2021	Journal Article	Marine Energy, Riverine		Human Dimensions
Environmental Impact Assessment: Nuyakuk River Small Scale Hydroelectric Project	Squire, R., Owen, A., Ngo-Ly, J.	October 2021	Report	Marine Energy, Riverine	Changes in Flow, Displacement, Habitat Change, Noise	Ecosystem Processes, Fish, Physical Environment, Sediment Transport, Water Quality, Human Dimensions, Environmental Impact Assessment, Recreation & Tourism, Visual Impacts
Are fish in danger? A review of environmental effects of marine renewable energy on fishes	Copping, A., Hemery, L., Viehman, H.	October 2021	Journal Article	Marine Energy, Riverine, Tidal, Wave	Avoidance, Collision, Displacement, EMF, Entanglement, Habitat Change, Noise	Fish
Renewable electricity generation for off grid remote communities; Life Cycle Assessment Study in Alaska, USA	McCallum, C., Kumar, N., Curry, R.	October 2021	Journal Article	Marine Energy, Riverine		Human Dimensions, Life Cycle Assessment
Assessment of hydrokinetic energy – A case study of eastern Yamuna canal	Saini, G., Kumar A., Saini, R.	August 2021	Conference Paper	Marine Energy, Riverine		Physical Environment
Towards sustainable blue energy production: an analysis of legal transformative and adaptive capacity	Simila, J., Soininen, N., Paukku, E.	February 2021	Journal Article	Marine Energy, Riverine, Wind Energy, Fixed Offshore Wind		Human Dimensions, Legal & Policy
Against the Tide: Potential for Marine Renewable Energy in Eastern and Southern Africa	Belletti, E., McBride, M.	February 2021	Journal Article	Marine Energy, Riverine, Tidal		Human Dimensions, Legal & Policy, Social & Economic Data
Quantifying biodiversity trade-offs in the face of widespread renewable and unconventional energy development	Popescu, V., Munshaw, R., Shackelford, N.	May 2020	Journal Article	Marine Energy, Riverine, Wind Energy, Land-Based Wind		Fish, Terrestrial Mammals
Vertical Distribution of Juvenile Salmon in a Large Turbid River	Jump, S., Courtney, M., Seitz, A.	December 2019	Journal Article	Marine Energy, Riverine	Collision, Habitat Change	Fish
Measuring the hydraulic effect of hydrokinetic energy extraction in the Tanana River, Alaska	Edgerly, E., Ravens, T.	August 2019	Journal Article	Riverine, Marine Energy	Changes in Flow	Physical Environment
Experimental and Numerical Investigation of Wake Interactions of Marine Hydrokinetic Turbines	Gotelli, C., Musa, M., Guala, M.	August 2019	Journal Article	Marine Energy, Riverine	Changes in Flow	Ecosystem Processes
Interaction between hydrokinetic turbine wakes and sediment dynamics: array performance and geomorphic effects under different siting strategies and sediment transport conditions	Musa, M., Hill, C., Guala, M.	August 2019	Journal Article	Marine Energy, Riverine	Changes in Flow	Physical Environment, Sediment Transport
Over or under? Autonomous sensor fish reveals why overshot weirs may be safer than undershot weirs for fish passage	Pflugrath, B., Boys, C., Cathers, B.	July 2019	Journal Article	Riverine, Marine Energy	Collision	Fish
Local and Non-local Geomorphic Effects of Hydrokinetic Turbines: Bridging Renewable Energy and River Morphodynamics	Musa, M.	June 2019	Thesis	Marine Energy, Riverine	Changes in Flow	Physical Environment
Evaluation of hydrokinetic energy potentials of selected rivers in Kwara State, Nigeria	Adeogun, A., Ganiyu, H., Ladokun, L.	April 2019	Journal Article	Marine Energy, Riverine
Environmental Assessment for Hydropower License: Igiugig Hydrokinetic Project	Federal Energy Regulatory Commission (FERC)	February 2019	Report	Marine Energy, Riverine		Human Dimensions, Environmental Impact Assessment
Numerical modelling of the effect of the hydro-kinetic turbines on the transport of sediments - Application to the Rhone site.	Khaled, F., Guillou, S., Hadri, F.	January 2019	Conference Paper	Marine Energy, Riverine	Changes in Flow	Physical Environment, Sediment Transport
Igiugig RivGen® Power System	Ocean Renewable Power Company (ORPC)	January 2019	Project Site	Marine Energy, Riverine
Igiugig Hydrokinetic Project, Appendix A-D. FERC Project No. P-13511-002	Ocean Renewable Power Company	November 2018	Report	Marine Energy, Riverine		Fish
Sustainable Hydropower: Using Ecosystem-based Adaptation to Increase Local Adaptation Capacity in Brazil	Garcia, K., Mollica, A., Ferreira de Matos, D.	September 2018	Book Chapter	Riverine, Marine Energy		Human Dimensions
Energy droughts from variable renewable energy sources in European climates	Raynaud, D., Hingray, B., François, B.	September 2018	Journal Article	Wind Energy, Riverine, Marine Energy		Social & Economic Data, Human Dimensions
Performance and resilience of hydrokinetic turbine arrays under large migrating fluvial bedforms	Musa, M., Hill, C., Sotiropoulos, F.	July 2018	Journal Article	Riverine, Marine Energy	Changes in Flow	Sediment Transport, Physical Environment
University of New Hampshire Living Bridge Project	University of New Hampshire	July 2018	Project Site	Marine Energy, Riverine, Tidal
2018 State of the Sector Report: Marine Renewable Energy in Canada	Marine Renewables Canada	June 2018	Report	Wind Energy, Wave, Tidal, Riverine, Fixed Offshore Wind, Marine Energy
Comparison of damage to live v. euthanized Atlantic salmon Salmo salar smolts from passage through an Archimedean screw turbine	Brackley, R., Lucas, M., Thomas, R.	May 2018	Journal Article	Riverine, Marine Energy	Collision	Pelagic Fish, Fish