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.

Marine and Wind Energy Environmental Documents

Tethys is a knowledge hub that contains documents on the environmental effects of wind and marine energy. The table below contains all of the documents in the Tethys Knowledge Base associated with Riverine.

Total: 107

Type of Content

Technology

Stressor

Receptor

Searches title and abstract.

Title	Author	Date	Content Type	Technology	Stressor	Receptor
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
How Green is 'Green' Energy?	Gibson, L., Wilman, E., Laurance, W.	December 2017	Journal Article	Wind Energy, Riverine, Marine Energy		Physical Environment
Triton: Igiugig Fish Video Analysis	Matzner, S., Trostle, C., Staines, G.	August 2017	Report	Riverine, Marine Energy		Fish
Evaluating riverine hydrokinetic turbine operations relative to the spatial ecology of wild fishes	Struthers, D., Gutowsky, L., Enders, E.	January 2017	Journal Article	Marine Energy, Riverine		Fish, Demersal Fish, Pelagic Fish
Anthropogenic Sources of Underwater Sound can Modify how Sediment-Dwelling Invertebrates Mediate Ecosystem Properties	Solan, M., Hauton, C., Godbold, J.	February 2016	Journal Article	Marine Energy, Riverine	Noise	Invertebrates
The Spatial Ecology and Biological Responses of Wild Fishes Relative to Hydropower Development on the Winnipeg River	Struthers, D.	January 2016	Thesis	Marine Energy, Riverine		Fish, Demersal Fish, Pelagic Fish
Characterizing Large River Sounds: Providing Context for Understanding the Environmental Effects of Noise Produced by Hydrokinetic Turbines	Bevelhimer, M., Deng, D., Scherelis, C.	January 2016	Journal Article	Marine Energy, Riverine	Noise
Acoustic Characterization of a Hydrokinetic Turbine	Polagye, B., Murphy, P.	September 2015	Conference Paper	Marine Energy, Riverine	Noise
Characterizing the Juvenile Fish Community in Turbid Alaskan Rivers to Assess Potential Interactions with Hydrokinetic Devices	Bradley, P., Evans, M., Seitz, A.	August 2015	Journal Article	Riverine, Marine Energy		Pelagic Fish, Fish
Surface Debris Characterization and Mitigation Strategies and Their Impact on the Operation of River Energy Conversion Devices on the Tanana River at Nenana, Alaska	Johnson, J., Kasper, J., Schmid, J.	June 2015	Report	Riverine, Marine Energy
Hydrodynamic Effects of Hydrokinetic Turbine Deployment in an Irrigation Canal	Gunawan, B., Roberts, J., Neary, V.	April 2015	Conference Paper	Marine Energy, Riverine	Changes in Flow	Physical Environment
Estimation of Acoustic Particle Motion and Source Bearing Using a Drifting Hydrophone Array Near a River Current Turbine to Assess Disturbances to Fish	Murphy, P.	January 2015	Thesis	Marine Energy, Riverine	Noise	Fish, Pelagic Fish
Assessment of Fish and Wildlife Presence Near Two River Instream Energy Conversion Devices in the Kvichak River, Alaska in 2014	Nemeth, M., Priest, J., Patterson, H.	December 2014	Report	Marine Energy, Riverine		Birds, Fish, Pelagic Fish, Terrestrial Mammals
Environmental and ecological effects of Lake Shihwa reclamation project in South Korea: A review	Lee, C., Lee, B. , Chang, W.	December 2014	Journal Article	Marine Energy, Riverine, Tidal		Human Dimensions
Simulating Blade-Strike on Fish Passing Through Marine Hydrokinetic Turbines	Romero-Gomez, P., Richmond, M.	November 2014	Journal Article	Tidal, Riverine, Marine Energy	Collision	Pelagic Fish, Fish, Demersal Fish
PMEC: Tanana River Test Site	Kasper, J., Johnson, J., Schmid, J.	October 2014	Presentation	Marine Energy, Riverine		Fish
Characterizing the Mean Flow Field in Rivers for Resource and Environmental Impact Assessments of Hydrokinetic Energy Generation Sites	Petrie, J., Diplas, P., Guitierrez, M.	September 2014	Journal Article	Marine Energy, Riverine	Changes in Flow
Computational Tools to Assess Turbine Biological Performance	Richmond, M., Serkowski, J., Rakowski, C.	July 2014	Magazine Article	Riverine, Marine Energy		Fish
Quantifying Barotrauma Risk to Juvenile Fish during Hydro-Turbine Passage	Richmond, M., Serkowski, J., Ebner, L.	June 2014	Journal Article	Riverine, Marine Energy	Collision	Fish
Hydraulic Impacts of Hydrokinetic Devices	Kartezhnikova, M., Ravens, T.	June 2014	Journal Article	Marine Energy, Riverine	Changes in Flow	Physical Environment
Field Measurement Test Plan to Determine Effects of Hydrokinetic Turbine Deployment on Canal Test Site in Yakima, WA, USA	Gunawan, B., Neary, V., Roberts, J.	April 2014	Conference Paper	Marine Energy, Riverine	Changes in Flow	Physical Environment
Slipstream Between Marine Current Turbine and Seabed	Chen, L., Lam, W.	April 2014	Journal Article	Tidal, Riverine, Marine Energy	Changes in Flow	Physical Environment
US Department of Energy (DOE) National Lab Activities in Marine Hydrokinetics: Scaled Model Testing of DOE Reference Turbines	Neary, V., Fontaine, A., Bachant, P.	September 2013	Conference Paper	Marine Energy, Riverine, Tidal
A 1:8.7 Scale Water Tunnel Verification & Validation of an Axial Flow Water Turbine	Fontaine, A., Straka, W., Meyer, R.	August 2013	Report	Marine Energy, Riverine, Tidal
Characterization of the Tanana River at Nenana, Alaska, to Determine the Important Factors Affecting Site Selection, Deployment, and Operation of Hydrokinetic Devices to Generate Power	Johnson, J., Toniolo, H., Seitz, A.	March 2013	Report	Marine Energy, Riverine		Fish
Söderfors Project	Uppsala University	March 2013	Project Site	Marine Energy, Riverine
SNL-EFDC Model Application to Scotlandville Bend, Mississippi River	Barco, J., Roberts, J., Johnson, E.	September 2012	Report	Riverine, Marine Energy	Changes in Flow	Sediment Transport, Physical Environment
Laboratory Experiments on the Effects of Blade Strike from Hydrokinetic Energy Technologies on Larval and Juvenile Freshwater Fishes	Schweizer, P., Cada, G., Bevelhimer, M.	March 2012	Report	Riverine, Marine Energy	Collision	Fish
Evaluation of Fish Injury and Mortality Associated with Hydrokinetic Turbines	Amaral, S., Perkins, N., Giza, D.	November 2011	Report	Riverine, Marine Energy	Collision	Fish
Fish Passage Through Turbines: Application of Conventional Hydropower Data to Hydrokinetic Technologies	Electric Power Research Institute (EPRI)	October 2011	Report	Marine Energy, Riverine	Collision	Fish
Ecology of Fishes in a High-Latitude, Turbid River with Implications for the Impacts of Hydrokinetic Devices	Seitz, A., Moerlain, K., Evans, M.	September 2011	Journal Article	Riverine, Marine Energy		Fish
Effects on Freshwater Organisms of Magnetic Fields Associated with Hydrokinetic Turbines	Cada, G., Bevelhimer, M., Riemer, K.	July 2011	Report	Riverine, Marine Energy	EMF	Invertebrates, Fish
Mississippi River Projects	Free Flow Power	June 2011	Project Site	Marine Energy, Riverine
Estimation of the Risks of Collision or Strike to Freshwater Aquatic Organisms Resulting from Operation of Instream Hydrokinetic Turbines	Schweizer, P., Cada, G., Bevelhimer, M.	May 2011	Report	Riverine, Marine Energy	Collision, Avoidance, Attraction	Fish
Attraction To and Avoidance of Instream Hydrokinetic Turbines by Freshwater Aquatic Organisms	Cada, G., Bevelhimer, M.	May 2011	Report	Riverine, Marine Energy	Habitat Change, Avoidance, Attraction	Fish, Demersal Fish