2. Geothermal energy is the natural heat of the Earth.

3. Heat flows outward from Earth's interior. The crust insulates us from Earth's interior heat. The mantle is semi-molten, the outer core is liquid and the inner core is solid.

4. The deeper you go, the hotter it gets (in Fahrenheit and miles).

6. Earth's crust is broken into huge plates that move apart or push together at about the rate our fingernails grow. Convection of semi-molten rock in the upper mantle helps drive plate tectonics.

7. New crust forms along mid-ocean spreading centers and continental rift zones. When plates meet, one can slide beneath another. Plumes of magma rise from the edges of sinking plates.

8. Thinned or fractured crust allows magma to rise to the surface as lava. Most magma doesn't reach the surface but heats large regions of underground rock.

9. Rainwater can seep down faults and fractured rocks for miles. After being heated, it can return to the surface as steam or hot water.

10. This steaming ground is in the Philippines.

11. When hot water and steam reach the surface, they can form fumaroles, hot springs, mud pots and other interesting phenomena.

12. When the rising hot water and steam is trapped in permeable and porous rocks under a layer of impermeable rock, it can form a geothermal reservoir.

13. A geothermal reservoir is a powerful source of energy!

15. Many areas have accessible geothermal resources, especially countries along the circum-Pacific "Ring of Fire," spreading centers, continental rift zones and other hot spots.

16. These and other methods are used.

17. Exploration commonly begins with analysis of satellite images and aerial photographs.

18. Volcanoes are obvious indications of underground heat, this volcano, Mt. Mayon in the Albay province of the Philippines erupted in 1999.

19. Geologists explore volcanic regions to find the most likely areas for further study, like this steaming hillside in El Hoyo, Nicaragua.

20. Geologic landforms and fault structures are mapped in the region. This view overlooks Basin and Range terrain East of the Sierra Nevadas.

21. Rocks are examined up close.

22. Geologic maps like this one are created, showing rock type and ages in different colors.

23. Data from electrical, magnetic, chemical and seismic surveys is gathered in the field.

24. The data obtained in the field are displayed in various ways and analyzed.

25. Geologists and drillers study the data to decide whether to recommend drilling. Geothermal reservoirs suitable for commercial use can only be discovered by drilling.

26. First, a small- diameter "temperature gradient hole" is drilled (some only 200' deep, some over 4000 feet deep) with a truck-mounted rig to determine the temperatures and underground rock types.

27. Workers on a temperature gradient hole drilling project.

28. Either rock fragments or long cores of rock are brought up from deep down the hole and temperatures are measured at depth.

29. Geologists examine the cored rock (shown here marked with depth markers).

30. Temperature results like this would definitely encourage the drilling of a larger, deeper well to try to find a hydrothermal reservoir.

31. Production-sized wells require large drill rigs like these and can cost as much as a million dollars or more to drill. Geothermal wells can be drilled over two miles deep.

32. On these large rigs, drilling continues 24 hours per day.

33. If a reservoir is discovered, characteristics of the well and the reservoir are tested by flowing the well.

34. If the well is good enough, a wellhead, with valves and control equipment, is built onto the top of the well casing.

35. This photograph shows a vertical geothermal well test in the Nevada Desert.

37. Natural steam from the production wells power the turbine generator. The steam is condensed by evaporation in the cooling tower and pumped down an injection well to sustain production.

38. Like all steam turbine generators, the force of steam is used to spin the trubine blades which spin the generator, prducing electricity. But with geothermal energy, no fuels are burned.

39. Turbine blades inside a geothermal turbine generator.

40. Turbine generator outdoors at an Imperial Valley geothermal power plant in California.

41. Turbine generator in a geothermal power plant in Cerro Prieto, Mexico.

42. Geothermal power plant operators in geothermal power plant control room in the Philippines.

43. Substation with transformer and insulators, at a geothermal power plant.

44. Wood power poles delivering electricity from geothermal power plants in the Mojave Desert in California to the electrical grid. Steam from well-testing in background.

45. Those white plumes you see at geothermal power plants are steam (water vapor). Geothermal plants do not burn fuel or produce smoke.

46. Geothermal power plants are clean and are operating successfully in sensitive environments.

47. These geothermal plants are operating successfully in a Philippine cornfield, at Mammoth Lakes, Calif., in the Mojave Desert of California, and in a tropical forest, at Mt. Apo, Philippines.

48. There are different kinds of geothermal reservoirs and different kinds of power plants.

49. In dry steam power plants, the steam (and no water) shoots up the wells and is passed through a rock catcher (not shown) and then directly into the turbine. Dry steam fields are rare.

50. Prince Piero Ginori Conti invented the first geothermal power plant in 1904, at the Larderello dry steam field in Italy.

51. The first modern geothermal power plants were also built in Lardello, Italy. They were destroyed in World War II and rebuilt. Today after 90 years, the Lardello field is still producing.

52. The first geothermal power plants in the U.S. were built in 1962 at The Geysers dry steam field, in northern California. It is still the largest producing geothermal field in the world.

53. 20 plants are still operating at The Geysers. Wastewater from nearby cities is injected into the field, providing environmentally safe disposal and increased steam to power plants.

54. Flash steam power plants use hot water reservoirs. In flash plants, as hot water is released from the pressure of the deep reservoir in a flash tank, some if it flashes to steam.

55. Flash technology was invented in New Zealand. Flash steam plants are the most common, since most reservoirs are hot water reservoirs. This flash steam plant is in East Mesa, California.

56. This flash plant is in Japan. In flash plants, both the unused geothermal water and condensed steam are injected back into the periphery of the reservoir to sustain the life of the reservoir.

57. This plant operates in the middle of crops in the Imperial Valley, California. High mineral contents of some southern California geothermal reservoirs provide salable byproducts like silica and zinc.

58. This flash plant is in Dixie Valley, Nevada. Nevada is rich in geothermal resources, with more hot springs for its size than any other state.

59. In a binary cycle power plant (binary means two), the heat from geothermal water is used to vaporize a "working fluid" in separate adjacent pipes. The vapor, like steam, powers the turbine generator.

60. In the heat exchanger, heat is transferred from the geothermal water to a second liquid. The geothermal water is never exposed to the air and is injected back into the periphery of the reservoir.

61. Binary technology allows the use of lower temperature reservoirs, thus increasing the number of reservoirs that can be used. This binary plant is at Soda Lake, Nevada.

62. This power plant provides about 25% of the electricity used on the Big Island of Hawaii. It is a hybrid binary and flash plant.

63. This binary power plant, at Wendell-Amadee, California, runs by itself. If it detects a problem, it automatically radios the operator to come to the site.

64. This small binary power plant is in Fang, Thailand.

65. Geothermal power has many local and global benefits.

66. The fastest growth in US geothermal capacity was from 1980 to 1990, following enactment of federal laws that compelled utilities to purchase electricity from independent power producers.

69. People who live in these areas are receiving electricity from geothermal power plants.

70. Geothermal power could serve 100% of the electrical needs of 39 countries (over 620,000,000 people) in Africa, Central/ South America and the Pacific. See: www.geotherm.org/PotentialReport.htm www.geotherm.org/PotentialReport.htm

71. Producing electricity is a relatively new use of geothermal energy. People have used Earth's natural hot water directly since the dawn of humankind.

74. This historical drawing depicts Native Americans using hot springs at what is now Calistoga, California. Some tribes considered hot springs to be neutral territory where no wars were allowed.

75. Use of hot springs by Maoris of New Zealand for cooking and other purposes extends into modern times.

76. Modern day Beppu Japan uses geothermal water and heat in buildings and factories and has 4,000 hot springs and bathing facilities that attract 12 million tourists a year.

77. Bathing in hot pools like these at Hot Creek, Mammoth Lakes, California, has been practiced throughout history. Be careful -- people and animals have been burned badly in unfamiliar pools.

78. Since Roman times, we have piped the hot water into pools to better control the temperature. These are photos of outdoor and indoor pool and spa bathing in Japan, the US, and Europe.

79. This small greenhouse is heated with geothermal water. Plants grow faster and larger when they have additional heat available.

80. In several western US states, many long greenhouses are built and heated with geothermal water. This one is in New Mexico.

81. Peppers, tomatoes, and flowers are commonly grown in geothermally heated greenhouses.

82. Geothermal water is also used to speed the growth of fish. These are growing in a geothermally heated hatchery at Mammoth Lakes, California.

83. This net full of fish was grown in geothermally heated waters in California's Imperial Valley.

84. Closeup of individual fish from a geothermal fish farm.

85. Closeup of a prawn grown in a research project with geothermally heated water at the GeoHeat Center, Oregon Institute of Technology.

86. These alligators are grown in geothermally heated water in Idaho.

87. Geothermal water is also used for industrial uses, like drying lumber or food products. This plant in Brady, Nevada, provides dried onions to Burger King.

88. Pipes of geothermal water can be installed under sidewalks and roads to keep them from icing over in winter, like this sidewalk in Klamath Falls, Oregon.

89. In some places, geothermal water is piped from wells to heat single homes or whole residential or commercial districts. This truck-mounted drill rig is drilling a well for use in Klamath Falls, Oregon.

90. Hot water from one or more geothermal wells is piped through a heat exchanger plant to heat city water in separate pipes. Hot city water is piped to heat exchangers in buildings to warm the air.

91. The geothermal water never mixes with the city water. Once its heat is transferred to the city water, the geothermal water is injected back into the reservoir to be reheated and recycled.

92. This is a "plate type" heat exchanger which passes hot geothermal water past many layers of metal plates, transferring the heat to other water passing through the other side of each plate.

93. These pumps are used to pump the heated water to buildings in a district heating system, after it has passed through the heat exchanger.

94. This photo of Reykjavik, Iceland, was taken in 1932, when buildings were all heated by burning of (imported) fossil fuels.

95. Today, about 95% of the buildings in Reykjavik are heated with geothermal water. Reykjavik is now one of the cleanest cities in the world.

96. The first geothermal district heating system in the US was built in Boise, Idaho. Today, Boise's capital and city buildings are heated with a geothermal district heating system.

99. The areas in orange and red are where with today's technology, we can find and use geothermal reservoirs.

101. Geothermal heat pumps can be used almost everywhere in the world, without a geothermal reservoir. The insulating properties of the earth, just below our feet, can keep us warm or cool.

104. Different styles of pipes are installed beside a building. A liquid is piped through the pipes to pick up the heat FROM the ground or (in the summer) to bring heat from the building TO the ground.

105. In a poll, over 95% of people who had installed a geothermal heat pump said they would recommend it and would do it again.

108. The entire U.S. (and most other areas of the world) are suitable for geothermal heat pumps. In the U.S., geothermal reservoirs occur primarily in western states.

109. It is of critical importance that we use energy sources that are easy on the environment.

110. Our modern world relies more and more on electricity -- to run our simplest household appliances, to keep businesses humming, to operate our computers and to light the night.

111. We rely on abundant, affordable energy. We must conserve, use energy more efficiently, and diversify our energy resource base.

112. Today, coal provides 55% of the U.S. electricity supply and the U.S. imports more than half of the oil it consumes. The burning of fossil fuels cannot be sustained.

114. Much air pollution is caused by burning of fossil fuels. The costs of pollution include health effects like rising rates of asthma, especially in children and especially in cities.

115. Currently we are using primarily fossil fuels.

116. What will be the consequences if our growing energy needs are also met by fossil fuels?

121. You can choose clean renewable energy from wind, solar, small hydropower and geothermal resources.