Geothermal energy in the United States

One of 21 power plants at The Geysers, California, the largest geothermal development in the world.

Geothermal energy in the United States generated a record 16.792 million megawatt-hours in 2012, narrowly beating the previous record of 16.789 set in 1993.[1] In 2012, the United States led the world in geothermal electricity production with 3,386 megawatts (MW) of installed capacity;[2][3] the largest group of geothermal power plants in the world is located at The Geysers, a geothermal field in California.[4] The United States generates an average of 15 billion kilowatt hours of geothermal power per year, comparable to burning some 25 million barrels (4,000,000 m3) of oil or 6 million short tons of coal per year.[5] In the twelve months through April 2013, geothermal energy generated 16.9 million megawatt-hours, 0.41% of total US electricity.[1]

Geothermal power plants are largely concentrated in the western states. They are the fourth largest source of renewable electricity, after hydroelectricity, biomass, and wind power. A geothermal resource assessment shows that nine western states together have the potential to provide over 20 percent of national electricity needs.[5][6]

History

According to archaeological evidence, geothermal resources have been in use on the current territory of the United States for more than 10,000 years. The Paleo-Indians first used geothermal hot springs for warmth, cleansing, and minerals.[5]

The first commercial geothermal power plant producing power to the U.S. utility grid opened at The Geysers in California in 1960, producing eleven megawatts of net power. The Geysers system continues to operate successfully today, and the complex has grown into the largest geothermal development in the world, with an output of 750 MW.[5]

Plants

Map showing geothermal power capacity by state in 2000 (USGS).

The largest dry steam field in the world is the Geysers, 116 km (72 mi) north of San Francisco. It was here that Pacific Gas and Electric began operation of the first successful geothermal electric power plant in the United States in 1960.[7] The original turbine lasted for more than 30 years and produced 11 MW net power.[8] The Geysers has 1517 megawatt (MW)[9] of active installed capacity with an average capacity factor of 63%.[10] Calpine Corporation owns 15 of the 18 active plants in the Geysers and is currently the United States' largest producer of geothermal energy.[11] Two other plants are owned jointly by the Northern California Power Agency and the City of Santa Clara's municipal Electric Utility (now called Silicon Valley Power). The remaining Bottle Rock Power plant owned by the US Renewables Group has only recently been reopened.[12] A nineteenth plant is now under development by Ram Power, formerly Western Geopower. Since the activities of one geothermal plant affects those nearby, the consolidation plant ownership at The Geysers has been beneficial because the plants operate cooperatively instead of in their own short-term interest. The Geysers is now recharged by injecting treated sewage effluent from the City of Santa Rosa and the Lake County sewage treatment plant. This sewage effluent used to be dumped into rivers and streams and is now piped to the geothermal field where it replenishes the steam produced for power generation.

Another major geothermal area is located in south central California, on the southeast side of the Salton Sea, near the cities of Niland and Calipatria, California. In 2001, there were 15 geothermal plants producing electricity in the area. CalEnergy owns about half of them and the rest are owned by various companies. Combined the plants have a capacity of about 570 MW. Hudson Ranch I geothermal plant, a 50 MW plant opened in May 2012, the first in the area in 20 years. A second similar plant is to open in 2013.[13]

The Basin and Range geologic province in Nevada, southeastern Oregon, southwestern Idaho, Arizona and western Utah is now an area of rapid geothermal development. Several small power plants were built during the late 1980s during times of high power prices. Rising energy costs have spurred new development. Plants in Nevada at Steamboat Springs, Brady/Desert Peak, Dixie Valley, Soda Lake, Stillwater and Beowawe now produce about 235 MW.

By state

Existing and planned US geothermal power generation, in February 2013

Installed geothermal capacity in megawatts (MW) by state as of February 2013:[2]

StateCapacity (MW)Share of U.S total
California2,732.280.7%
Nevada517.515.3%
Utah48.11.4%
Hawaii38.01.1%
Oregon33.31.0%
Idaho15.80.5%
New Mexico[14]4.00.1%
Alaska0.7<0.1%
Wyoming0.3<0.1%
Total3,389.9100%

Production and development

US electricity generated from geothermal sources 1960-2008 (blue), and as a percentage of total US electricity (red).

With 3,040.27 MW of installed geothermal capacity, the United States remains the world leader with 30% of the online capacity total.[3] The future outlook for expanded production from conventional and enhanced geothermal systems is positive as new technologies promise increased growth in locations previously not considered.[15]

As of August 2008, 103 new projects are under way in 13 U.S. states. When developed, these projects could potentially supply up to 3,979 MW of power, meeting the needs of about 4 million homes. At this rate of development, geothermal production in the United States could exceed 15,000 MW by 2025.[15]

The most significant catalyst behind new industry activity is the Energy Policy Act of 2005. This Act made new geothermal plants eligible for the full federal production tax credit, previously available only to wind power projects and certain kinds of biomass. It also authorized and directed increased funding for research by the Department of Energy, and enabled the Bureau of Land Management to address its backlog of geothermal leases and permits.[3]

Estimated subterranean temperatures at a depth of 6 kilometers

In April 2008, exploratory drilling began at Newberry Volcano in Oregon.[16]

In 2009, investment bank Credit Suisse calculated that geothermal power costs 3.6 cents per kilowatt-hour, versus 5.5 cents per kilowatt-hour for coal, if geothermal receives loans with lower rates than offered by the market."[17]

Reliability

Unlike some other renewable power sources such as wind and solar, geothermal energy is dispatchable, meaning that it is both available whenever needed, and can quickly adjust output to match demand. According to the US Energy Information Administration (EIA), of all types of new electrical generation plants, geothermal generators have the highest capacity factor, a measure of how much power a facility actually generates as a percent of its maximum capacity. The EIA rates new geothermal plants as having a 92% capacity factor, higher than those of nuclear (90%), gas (87%), or coal (85%), and much higher than those of intermittent sources such as onshore wind (34%) or solar photovoltaic (25%).[18] While the carrier medium for geothermal electricity (water) must be properly managed, the source of geothermal energy, the Earth's heat, will be available, for most intents and purposes, indefinitely.[5][19]

In 2008 the USDOE funded research in Enhanced Geothermal Systems (EGS) to learn more about the fracture systems in geothermal reservoirs and better predict the results of reservoir stimulation. The DOE Geothermal Technologies Program (part of the American Recovery and Reinvestment Act of 2009) provided funding to establish the National Geothermal Data System (NGDS). Through the NGDS, many older paper archives and drill logs that are stored at state geological surveys are now being digitized and made available for free to the public.[20]

Environmental effects

The underground hot water and steam used to generate geothermal power may contain chemicals that could pollute the air and water if released at the surface.

Hydrogen sulfide, which is toxic in high concentrations, is sometimes found in geothermal systems.[21] Newer methods of generating geothermal power separate the hot steam collected underground from the steam used to power turbines, and substantially reduce the risk of releasing air-polluting contaminants.[22]

The water mixed with the steam contains dissolved salts that can damage pipes and harm aquatic ecosystems.[23] Some subsurface water associated with geothermal sources contain high concentrations of toxic elements such as boron, lead, and arsenic.

Injection of water in enhanced geothermal systems may cause induced seismicity. Earthquakes at the Geysers geothermal field in California, the largest being Richter magnitude 4.6, have been linked to injected water.[24]

"Possible effects include scenery spoliation, drying out of hot springs, soil erosion, noise pollution, and chemical pollution of the atmosphere and of surface- and groundwaters."[25]

See also

References

  1. 1 2 US Energy Information Administration, Table 1.1.A. Net Generation by Other Renewable Sources: Total (All Sectors), 2003-April 2013, Table 1.1. Net Generation by Energy Source: Total (All Sectors), 2003-April 2013, accessed 20 July 2013.
  2. 1 2 "2012 Annual US Geothermal Power Production and Development Report" (PDF). Geothermal Energy Association. February 2013.
  3. 1 2 3 6 Million American Households to be Powered by Geothermal Energy, New Survey Reports
  4. Khan, M. Ali (2007), The Geysers Geothermal Field, an Injection Success Story (pdf), Annual Forum of the Groundwater Protection Council, retrieved 2010-01-25
  5. 1 2 3 4 5 A Guide to Geothermal Energy and the Environment
  6. Energy Information Administration
  7. Lund, J. (September 2004), "100 Years of Geothermal Power Production" (PDF), Geo-Heat Centre Quarterly Bulletin (Klamath Falls, Oregon: Oregon Institute of Technology) 25 (3), pp. 11–19, ISSN 0276-1084, retrieved 2009-04-13
  8. McLarty, Lynn; Reed, Marshall J. (October 1992). "The U.S. Geothermal Industry: Three Decades of Growth" (PDF). Energy Sources, Part A: Recovery, Utilization, and Environmental Effects (London: Taylor & Francis) 14 (4): 443–455. doi:10.1080/00908319208908739. ISSN 1556-7230.
  9. DiPippo, Ronald. Geothermal Power Plants, Second Edition: Principles, Applications, Case Studies and Environmental Impact. Butterworth-Heinemann. ISBN 978-0-7506-8620-4.
  10. Lund, John W.; Bloomquist, R. Gordon; Boyd, Tonya L.; Renner, Joel (24–29 April 2005), "The United States of America Country Update" (PDF), Proceedings World Geothermal Congress, Antalya, Turkey, retrieved 2009-11-09 Missing or empty |title= (help)
  11. All figures adjusted to include recently reopened Bottle Rock Power plant.
  12. Baker, David R. (January 14, 2007). "Steamy industry may clear the air". San Francisco Chronicle (Lake County). p. F-1. Retrieved 2009-11-09.
  13. 49.9-MW Hudson Ranch I Geothermal Plant Unveiled in California, Meg Cichon, RenewableEnergyWorld.com
  14. Danko, Pete. New Mexico joins the geothermal power ranks. Geothermal Power. Renewable Energy. Earth Techling. http://www.earthtechling.com/2014/01/new-mexico-joins-the-geothermal-power-ranks/. Accessed 6 February 2014.
  15. 1 2 Update: The State of U.S. Geothermal Production and Development
  16. Gail Kinsey-Hill (2008-06-03). "Company Seeks Power From Crater". Vancouver Sun. p. B2.
  17. Christopher Mims “Can Geothermal Power Compete with Coal on Price?” Scientific American, 2 March 2009. Web. 9 Oct. 2009.
  18. US Energy Information Administration, Levelized cost of new generation resources, Annual Energy Outlook 2013, 15 April 2013.
  19. Geothermal 101: Basics of Geothermal Energy Production and Use p. 5 & 7. Archived March 6, 2009 at the Wayback Machine
  20. "New Geothermal Data System Could Open Up Clean-Energy Reserves". Scientific American, William Ferguson on February 25, 2013
  21. McFarland, Ernest L. “Geothermal Energy.” Macmillan Encyclopedia of Energy. Ed. Ed John Zumerchik. Vol. 2. New York: Macmillan Reference USA, 2001. 572-579. Gale Virtual Reference Library. Web. 9 Oct. 2009.
  22. Raser Technologies - How Modular Geothermal Power Generation Works
  23. “Alternative Energy Sources.” UXL Encyclopedia of Science. Ed. Rob Nagel. 2nd ed. Detroit: UXL, 2007. Student Resource Center Gold. Web. 9 Oct. 2009.
  24. Lawrence Berkeley National Laboratory, The Geysers
  25. Arnórsson, Stefán (2004). "Environmental impact of geothermal energy utilization". Special Publications (The Geological Society of London) 236: 297–336. doi:10.1144/GSL.SP.2004.236.01.18. Retrieved 2013-09-23.

External links

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