OTEC

Capturing energy using temperature gradients across water depths.

Ocean thermal energy conversion (OTEC) technology converts solar energy stored in the layers of the tropical and subtropical oceans. Thermal heat engines use the temperature difference between the sun-warmed surface water and cold water in the deep ocean. The temperature difference between surface waters and deeper water can reach over 25 oC in summer months, although usually this temperature difference exists only over water with depths of 1,000 m or greater. Many different OTEC archetypes have been investigated, some on floating offshore platforms and some built onshore with pipelines to transport the water to and from the ocean. Each system uses one or a combination of thermodynamic processes to turn the temperature difference into mechanical energy.

Closed-cycle: A working fluid with a low-boiling point, such as ammonia or propane, is circulated. Warm, surface seawater is pumped through a heat exchanger where the working fluid is vaporized and driven through a turbine, which then generates electricity. Cold, deep seawater is then pumped through a second heat exchanger where the working fluid vapor condenses back into a liquid and is recycled through the system.
Open-cycle: Warm, surface seawater is placed in a low-pressure container that causes the water to boil, turning a turbine as the steam expands. The steam is then exposed to cold, deep seawater and condenses into freshwater.
Hybrid-cycle: Warm, surface seawater enters a vacuum chamber where it is flash-evaporated into steam. The steam is used to vaporize a working fluid with a low-boiling point, which then turns a turbine to generate electricity. Hybrid configurations also produce freshwater, which can have other uses such as agriculture and potable drinking water.

The primary environmental concerns associated with OTEC technologies typically encompass changes in water quality. A major environmental concern arises as cool, nutrient rich water is withdrawn from the deep ocean and discharged higher in the water column. The effects of this cooler water and transport of nutrients on ecosystem processes could vary but may affect nearby habitats through temperature changes or increased biological growth. Screens will cover the intake tubes, but there is still a chance that marine organisms could be fatally entrapped. In order to maintain the efficiency of the heat exchangers, the warm water will need to be treated with chlorine, which will cause changes to water quality.

Photo Credit: Okinawa Prefecture Industrial Policy Division

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 OTEC.

Total: 126

Type of Content

Technology

Stressor

Receptor

Searches title and abstract.

Title	Author	Date	Content Type	Technology	Stressor	Receptor
Using Sea Water For Heating, Cooling And Power Production	Natural Resources Canada	January 2022	Report	Marine Energy, OTEC		Physical Environment, Sediment Transport, Human Dimensions, Legal & Policy, Stakeholder Engagement
Environmental impacts of utilization of ageing fixed offshore platform for ocean thermal energy conversion	Zulkifli, M., Husain, M., Zaki, N.	January 2022	Conference Paper	Marine Energy, OTEC	Attraction, Changes in Flow	Fish, Human Dimensions, Environmental Impact Assessment, Fisheries, Marine Spatial Planning
Water quality modeling in subtropical shallow waters to predict environmental impacts of ocean thermal energy conversion	Oshimi, R., Tabeta, S., Mizuno, K.	July 2021	Journal Article	Marine Energy, OTEC		Physical Environment, Water Quality
A systemic view of potential environmental impacts of ocean energy production	Martinez, M., Vázquez, G., Pérez-Maqueo O.	June 2021	Journal Article	Marine Energy, Ocean Current, OTEC, Salinity Gradient, Tidal, Wave	Collision, Habitat Change, Noise	Birds, Physical Environment, Fish, Marine Mammals
Regulating wave, tidal and ocean thermal energy	Adimazoya, T., Doelle, M.	May 2021	Book Chapter	Marine Energy, OTEC, Tidal, Wave		Human Dimensions, Legal & Policy
Viability of renewable technologies from marine derived energy as global sources of electricity	Dubois, S., Klein, K., Villemure, M.	April 2021	Journal Article	Marine Energy, OTEC, Wave		Human Dimensions, Environmental Impact Assessment, Marine Spatial Planning, Social & Economic Data
Ocean Thermal Energy Conversion and Other Uses of Deep Sea Water: A Review	Herrera, J., Sierra, S., Ibeas, A.	March 2021	Journal Article	Marine Energy, OTEC
Accelerating Energy Innovation for the Blue Economy	The Economist Intelligence Unit	November 2020	Report	Marine Energy, OTEC, Tidal, Wave, Wind Energy, Fixed Offshore Wind, Floating Offshore Wind		Human Dimensions, Legal & Policy, Social & Economic Data
A Review on Environmental and Social Impacts of Thermal Gradient and Tidal Currents Energy Conversion and Application to the Case of Chiapas, Mexico	Rivera, G., Felix, A., Mendoza, E.	October 2020	Journal Article	Marine Energy, OTEC, Tidal	Changes in Flow, Collision, EMF, Habitat Change, Noise	Birds, Ecosystem Processes, Physical Environment, Fish, Marine Mammals, Human Dimensions
Is ocean energy an alternative in developing regions? A case study in Michoacan, Mexico	Hernández-Fontes, J., Martinez, M., Wojtarowski, A.	September 2020	Journal Article	Marine Energy, OTEC, Wave		Human Dimensions, Social & Economic Data, Stakeholder Engagement
Hawai'i National Marine Renewable Energy Center (HINMREC)	Vega, L., Cross, P.	June 2020	Report	Marine Energy, OTEC, Wave
The Social Energy: Contexts for Its Assessment	Pérez, A., Agudelo, M., Camacho, G.	May 2020	Book Chapter	Marine Energy, OTEC		Human Dimensions, Social & Economic Data
Environmental Impact Assessment of the Operation of an Open Cycle OTEC 1MWe Power Plant in the Cozumel Island, Mexico	Chan, E., Tun, M., Graniel, J.	May 2020	Book Chapter	Marine Energy, OTEC		Human Dimensions, Environmental Impact Assessment
Tapping Renewable Energy Sources in Contemporary India: Issues and Challenges	Chandy, S.	April 2020	Journal Article	Marine Energy, OTEC, Tidal, Wave, Wind Energy		Human Dimensions, Legal & Policy
Wave, Tidal and Ocean Thermal Energy	Adimazoya, T., Doelle, M.	April 2020	Book Chapter	Marine Energy, OTEC, Tidal, Wave		Human Dimensions, Legal & Policy
Prospects of ocean-based renewable energy for West Africa’s sustainable energy future	Adesanya, A., Misra, S., Maskeliunas, R.	March 2020	Journal Article	Marine Energy, OTEC		Human Dimensions, Legal & Policy, Social & Economic Data
A Numerical Investigation of the Plunging Phenomenon of Cold Water Discharged from Ocean Thermal Energy Conversion Systems	Hua, D., Yasunaga, T., Ikegami, Y.	February 2020	Journal Article	Marine Energy, OTEC	Changes in Flow	Physical Environment, Water Quality
Pan American Marine Energy Conference 2020 Book of Abstracts	Rojas M., J., Meza, C.	February 2020	Conference Paper	Marine Energy, Ocean Current, OTEC, Salinity Gradient, Tidal, Wave, Wind Energy, Fixed Offshore Wind, Floating Offshore Wind
Marine Heat as a Renewable Energy Source	Suparta, W.	January 2020	Journal Article	Marine Energy, OTEC		Human Dimensions
Modern energy conversion technologies	Islam, M., Hasanuzzaman, M., Pandey, A.	January 2020	Book Chapter	Marine Energy, OTEC
Potential effects of deep seawater discharge by an Ocean Thermal Energy Conversion plant on the marine microorganisms in oligotrophic waters	Giraud, M., Garçon, V., de la Broise, D.	November 2019	Journal Article	Marine Energy, OTEC	Changes in Flow	Physical Environment, Water Quality
Ocean Renewable Energy Potential, Technology, and Deployments: A Case Study of Brazil	Shadman, M., Silva, C., Faller, D.	September 2019	Journal Article	Marine Energy, OTEC, Salinity Gradient, Tidal, Wave		Human Dimensions, Social & Economic Data
Environmental Impacts of Renewable Energy	Mazhar, N., Zia, S.	September 2019	Book Chapter	Marine Energy, OTEC, Wave, Wind Energy
A framework to evaluate the environmental impact of OCEAN energy devices	Mendoza, E., Lithgow, D., Flores, P.	September 2019	Journal Article	Marine Energy, Ocean Current, OTEC, Tidal, Wave, Wind Energy, Fixed Offshore Wind		Human Dimensions
Study of the currentology of Moroccan facades and assessment of the marine energy potential for the fight against the impact of climate changes	Hariss, S., Saifaoui, D., Hilmi, K.	August 2019	Conference Paper	Marine Energy, Ocean Current, OTEC, Wind Energy, Fixed Offshore Wind		Human Dimensions
Decision framework for ocean thermal energy plant site selection from a sustainability perspective: The case of China	Zhang, J., Xu, C., Song, Z.	July 2019	Journal Article	OTEC, Marine Energy		Legal & Policy, Human Dimensions
On the Marine Energy Resources of Mexico	Hernández-Fontes, J., Felix, A., Mendoza, E.	June 2019	Journal Article	Marine Energy, Ocean Current, OTEC, Salinity Gradient, Wave		Ecosystem Processes, Physical Environment
Offshore Ocean Thermal Energy Conversion in Layang-Layang Island, Sabah-Malaysia	Fahmie, M., Koto, J., Tasri, A.	March 2018	Journal Article	Marine Energy, OTEC		Human Dimensions
Analysis of the environmental issues concerning the deployment of an OTEC power plant in Martinique	Devault, D., Péné-Annette, A.	November 2017	Journal Article	OTEC, Marine Energy
Legal Considerations on OTEC Deployment in Malaysia	Rani, M., Yusof, M., Mahdzir, A.	June 2017	Report	Marine Energy, OTEC		Human Dimensions, Legal & Policy
Potential of 100 kW of Ocean Thermal Energy Conversion in Karangkelong, Sulawesi Utara, Indonesia	Negara, R., Koto, J.	January 2017	Journal Article	Marine Energy, OTEC		Human Dimensions
Integration of wave energy and other marine renewable energy sources with the needs of coastal societies	Manasseh, R., Sannasiraj, S., McInnes, K.	January 2017	Journal Article	Wind Energy, Wave, Tidal, OTEC, Fixed Offshore Wind, Ocean Current, Marine Energy		Social & Economic Data, Human Dimensions
Potential of ocean thermal energy conversion in Indonesia	Koto, J.	October 2016	Journal Article	Marine Energy, OTEC		Human Dimensions
Progress in Renewable Energies Offshore	Soares, C.	October 2016	Book	Marine Energy, OTEC, Tidal, Wave, Wind Energy, Fixed Offshore Wind
Study on Electrification of Remote and Isolated Tropical Islands Using OTEC	Hassan, M., Habib, W., Rupam, T.	October 2016	Conference Paper	Marine Energy, OTEC		Physical Environment, Human Dimensions, Social & Economic Data
Reviews of Power Supply and Environmental Energy Conversions for Artificial Upwelling	Zhang, D., Fan, W., Yang, J.	April 2016	Journal Article	Wave, OTEC, Marine Energy
Environmental Impact Assessment for an OTEC Plant in Martinique Island	Auvray, C., Ledoux, S., Diaz, B.	April 2015	Journal Article	Marine Energy, OTEC		Human Dimensions, Environmental Impact Assessment
An Economic and Environmental Assessment of Transporting Bulk Energy from a Grazing Ocean Thermal Energy Conversion Facility	Gilmore, E., Blohm, A., Sinsabaugh, S.	November 2014	Journal Article	Marine Energy, OTEC		Physical Environment, Human Dimensions
Observing Ocean Changes at the Nation's First SWAC System	Comfort, C., Ostrander, C., McManus, M.	September 2013	Presentation	Marine Energy, OTEC		Ecosystem Processes
Potential Environmental Consequences of Enhanced Ocean Upwelling	Karl, D., Böttjer, D., Clemente, T.	September 2013	Presentation	Marine Energy, OTEC		Ecosystem Processes