Glossary
- Discharge:
-
A measure of the flow rate of steam, water, or heat discharged at or near the ground surface from a subsurface geothermal reservoir.
- Geothermal:
-
The naturally occurring heat found beneath the surface of the Earth, ultimately originating from the internal magmatic processes of the Earth’s core. A geothermal energy project utilizes the hot water or steam found within certain large bodies of rock, referred to as a geothermal reservoir.
- Power capacity:
-
The amount of energy produced per unit time, or the amount of the electric power capacity that a power generation facility is designed to produce.
- Recharge:
-
Natural influx of hot fluids into a geothermal system.
- Renewable:
-
A natural energy resource that is inexhaustible or can replenish itself over time.
- Specific heat:
-
The amount of heat required, in calories, to raise the temperature of 1 g of a substance by 1 °C.
- Sustainable:
-
A natural energy resource which, if managed carefully, will provide the needs of a community or...
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Bibliography
Primary Literature
Axelsson G, Stefansson V, Björnsson G (2004) Sustainable utilization of geothermal resources. In: Proceedings of the twentyÂninth workshop on geothermal reservoir engineering. Stanford University, Stanford, pp 26–28
Rybach L (2003) Sustainable use of geothermal resources: renewability aspects. In: IGC 2003 short course. UNU Geothermal Training Programme, Iceland
Axelsson G, Gudmundsson A, Steingrimsson B, Palmason G, Armannsson H, Tulinius H, Flovenz OG, Bjornsson S, Stefansson V (2001) Sustainable production of geothermal energy: suggested definition. IGAÂNews Quarterly, no. 43. pp 1–2
Stefansson V (2000) The renewability of geothermal energy. In: Proceedings world geothermal congress. KyushuÂTohoku, 28 May–10 June 2000
Rybach L, Mégel T, Eugster WJ (1999) How renewable are geothermal resources? Trans Geotherm Res Counc 23:563–566
Wright PM (1995) The sustainability of production from geothermal resources. In: Proceedings of the world geothermal congress. Florence, 18–31 May 1995
Sanyal S (2005) Sustainability and renewability of geothermal power capacity. In: Proceedings of the World geothermal congress, Antalya, Turkey, 24–29 Apr 2005
Pritchett JW (1998) Modeling postÂabandonment electrical capacity recovery for a twoÂphase geothermal reservoir. Trans Geotherm Res Counc 22:521–528
Parini M, Cappetti G, Laudiano M, Bertani R, Monterrosa M (1995) Reservoir modeling study modeling study of the Ahuachapan geothermal field (El Salvador) in the frame of a generation stabilization project. In: Proceedings of world geothermal congress. Florence, 18–31 May 1995
Butler SJ, Sanyal SK, Robertson-Tait A, Lovekin JW, Benoit D (2001) A case history of numerical modeling of a faultÂcontrolled geothermal system at Beowawe, Nevada. In: Proceedings of the twentyÂsixth workshop on geothermal reservoir engineering. Stanford University, Stanford, 29–31 Jan 2001
Butler SJ, Sanyal SK, Henneberger RC, Klein CW, Gutiérrez H, de León JS (2000) Numerical modeling of the Cerro Prieto geothermal field, Mexico. In: Proceedings of the world geothermal congress. KyushuÂTohoku, 28 May–10 June 2000
Wisian KW, Blackwell DD, Richards M (2001) Correlation of surface heat loss and total energy production for geothermal systems. Trans Geotherm Res Counc 25:331–336
Lippmann MJ, Bodvarsson GS (1985) The Heber geothermal field, California: natural state and exploitation modeling studies. J Geophys Res 90(B1):745–758
McGuinness M, White S, Young R, Ishizaki H, Ikeuchi K, Yoshida Y (1995) A model of the Kakkonda geothermal reservoir. Geothermics 24:1–48
White SP, Kissling WM, McGuinness MJ (1997) Models of the Kawareu geothermal reservoir. Trans Geotherm Res Counc 21:33–39
Tulinius H, Sigurdsson O (1989) TwoÂdimensional simulation of the KraflaÂHvitholar geothermal field, Iceland. In: Proceedings of the fourteenth workshop on geothermal reservoir engineering. Stanford University, Stanford, 24–26 Jan 1989
Sorey ML (1985) Evolution and present state of the hydrothermal system in the Long Valley caldera. J Geophys Res 90:11219–11228
Esberto MB, Sarmiento ZF (1999) Numerical modeling of the Mt. Apo geothermal reservoir. In: Proceedings of the twentyÂfourth workshop on geothermal reservoir engineering. Stanford University, Stanford, 25–27 Jan 1999
Haukwa C, Bodvarsson GS, Lippmann MJ, Mainieri A (1992) Preliminary reservoir engineering studies of the Miravalles geothermal field, Costa Rica. In: Proceedings of the seventeenth workshop on geothermal reservoir engineering. Stanford University, Stanford, 29–31 Jan 1991
Sakagawa Y, Takahashi M, Hanano M, Ishido T, Demboya N (1994) Numerical simulation of the Mori geothermal field, Japan. In: Nineteenth workshop on geothermal reservoir engineering. Stanford University, Stanford, 18–20 Jan 1994
Kiryukhin AV (2004) Modeling study of the Mutnovsky geothermal field (Dachny) in connection with the problem of steam supply for 50 MWe PP. In: TwentyÂninth workshop on geothermal reservoir engineering. Stanford University, Stanford, 26–28 Jan 2004
Steingrimsson B, Bodvarsson GS, Gunnlaugsson E, Gislason G, Sigurdsson O (2000) Modeling studies of the Nesjavellir geothermal field, Iceland. In: Proceedings of the world geothermal congress. KyushuÂTohoku, 28 MayÂ10 June 2000
McGuinness MJ (1998) Ngawha geothermal field – a review. In: Proceedings of the twentieth New Zealand geothermal workshop. University of Auckland, Auckland
Yamada M, Iguchi K, Nakanishi S, Todaka N (2000) Reservoir characteristics and development plan of the Oguni geothermal field, Kyushu, Japan. Geothermics 29:151–169
Nakanishi S, Nobuyuki I (2000) Reservoir simulation study of the Onikobe geothermal field, Japan. In: Proceedings of the world geothermal congress. KyushuÂTohoku, 28 May–10 June 2000
Yearsley E (1994) Roosevelt hot springs reservoir model applied to forecasting remaining field potential. Trans Geotherm Res Counc 18:617–622
Atmojo JP, Itoi R, Fukuda M, Tanaka T, Daud Y, Sudarman S (2001) Numerical modeling study of Sibayak geothermal reservoir, North Sumatra, Indonesia. In: Proceedings of the twentyÂsixth workshop on geothermal reservoir engineering. Stanford University, Stanford, 29–31 Jan 2001
Pritchett JW, Garg SK, Ariki K, Kawano Y (1991) Numerical simulation of the Sumikawa geothermal field in the natural state. In: Proceedings of the sixteenth workshop on geothermal reservoir engineering. Stanford University, Stanford, 23–25 Jan 1991
Furuya S, Aoki M, Gotoh H, Takenaka T (2000) Takigami geothermal system, Northeastern Kyushu, Japan. Geothermics 29:191–211
Butler SJ, Sanyal SK, Klein CW, Iwata S, Itoh M (2004) Numerical simulation and performance evaluation of the Uenotai geothermal field, Akita Prefecture. Jpn Trans Geotherm Res Counc 28:455–460
Bibby HM, Caldwell TG, Davey FJ, Webb TH (1995) Geophysical evidence on the structure of the Taupo volcanic zone and its hydrothermal circulation. J Volcanol Geotherm Res 68:29–58
Sanyal SK, Pham M, Iwata S, Suzuki M (2000) Numerical simulation of the Wasabizawa geothermal field, Akita Prefecture. Jpn Trans Geotherm Res Counc 24:623–630
Menzies AJ, Granados EE, Sanyal SK, Mérida-I L, Caicedo AA (1991) Numerical modeling of the initial state and matching of well test data from the Zunil geothermal field, Guatemala. In: Proceedings of the sixteenth workshop on geothermal reservoir engineering. Stanford University, Stanford, 23–25 Jan 1991
Sanyal SK, Klein CW, Lovekin JW, Henneberger RC (2004) National assessment of U.S. geothermal resources – a perspective. Trans Geotherm Res Counc 28:355–362
Klein CW, Lovekin JW, Sanyal SK (2004) New geothermal site identification and quantification. In: California energy commission PIER consultant report. P500Â04Â051
Clotworthy A (2000) Response of Wairakei geothermal reservoir to 40 years of production. In: Proceedings of the world geothermal congress. KyushuÂTohoku, 28 May–10 June 2000
MIT (2006) The future of geothermal energy – impact of enhanced geothermal systems (EGS) on the United States in the 21st century. An assessment by an MIT – Led interdisciplinary panel. Massachusetts Institute of Technology, Cambridge
Sanyal SK (2010) Future of geothermal energy. In: Proceedings of the thirtyÂfifth workshop on geothermal reservoir engineering. Stanford University, Stanford, 1–3 Feb 2010, SGPÂTRÂ188
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Sanyal, S.K. (2018). Sustainability and Renewability of Geothermal Power Capacity. In: Bronicki, L. (eds) Power Stations Using Locally Available Energy Sources. Encyclopedia of Sustainability Science and Technology Series. Springer, New York, NY. https://doi.org/10.1007/978-1-4939-7510-5_229
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