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  • Abad Fernandez, J., Sanchez Guzman, J.:
    Geothermal energy in the Spanish energy plan: Present status of the most advanced projects.
    In: Geothermics Nummer 14(2) (1985), S. 379-384
  • Abé, H., Duchane, D., Parker, R., Kuriyagawa, M.:
    Present status and remaining problems of HDR/HWR system design.
    In: Geothermics Nummer 28(4) (August–October 1999), S. 573-590
  • Abé, H., Niitsuma, H., Murphy, H.:
    Summary of discussions, structured academic review of HDR/HWR reservoirs.
    In: Geothermics Nummer 28(4) (August–October 1999), S. 671-679
  • Abbasi, M., Khazali, N., Sharifi, M.:
    Analytical model for convection-conduction heat transfer during water injection in fractured geothermal reservoirs with variable rock matrix block size.
    In: Geothermics Nummer 69() (September 2017), S. 1-14
  • Abdallah, A., Gandino, A., Sommaruga, C.:
    Technical-economic studies of geothermal projects: The Djibouti case.
    In: Geothermics Nummer 14(2) (1985), S. 327-334
  • Abdel Moktader A. El Sayed, Nahla A. El Sayed:
    Thermal conductivity calculation from P-wave velocity and porosity assessment for sandstone reservoir rocks.
    In: Geothermics Nummer 82(S0375650519300550) (2019-11-30), S. 91-96, 10.1016/j.geothermics.2019.06.001
  • Abdel Zaher, M., Elbarbary, S., Sultan, S., El-Qady, G., Ismail, A., Takla, E.:
    Crustal thermal structure of the Farafra oasis, Egypt, based on airborne potential field data.
    In: Geothermics Nummer 75() (September 2018), S. 220-234
  • Abdelaziz, S., Olgun, C., Martin II, J.:
    Equivalent energy wave for long-term analysis of ground coupled heat exchangers.
    In: Geothermics Nummer () (January 2015), S. 67-84
  • Abdelaziz, S., Olgun, C., Martin, J.:
    Counterbalancing ambient interference on thermal conductivity tests for energy piles.
    In: Geothermics Nummer () (July 2015), S. 45-59
  • Abdelaziz, S., Ozudogru, T., Olgun, C., Martin, J.:
    Multilayer finite line source model for vertical heat exchangers.
    In: Geothermics Nummer () (July 2014), S. 406-416
  • Abdelfettah, Y., Sailhac, P., Larnier, H., Matthey, P., Schill, E.:
    Continuous and time-lapse magnetotelluric monitoring of low volume injection at Rittershoffen geothermal project, northern Alsace – France.
    In: Geothermics Nummer 71() (January 2018), S. 1-11
  • Abdelfettah, Y.; Schill, E.; Kuhn, P.:
    Characterization of geothermally relevant structures at the top of crystalline basement in Switzerland by filters and gravity forward modelling.
    In: Geophysical Journal International Nummer 7(1) (2014), S. 226–241
  • Abdelrahman, E. M., and Bayoumi, A. I.:
    Nomograms for determining fault parameters from gravity data with application to the Mersa Matruh Basin.
    In: Journal of African Earth Sciences, Nummer 9 (1989), S. 455-459
  • Abdelrahman, E. M., and El-Araby, T. M.:
    Shape and depth solutions from moving average residual gravity anomalies.
    In: Journal of Applied Geophysics Nummer 36 (1996), S. 89-95
  • Abdelrahman, E. M., El-Araby, H. M., El-Araby, T. M., and Abo-Ezz, E. R.:
    A least-squares derivatives analysis of gravity anomalies due to faulted thin slabs.
    In: Geophysics Nummer 68 (2003), S. 535-543
  • Abdelrahman, E. M., El-Araby, H. M., Hassaneen, A. G., and Hafez, M. A.:
    New methods for shape and depth determinations from SP data: .
    In: Geophysics, Nummer 68 (2003), S. 1202–1210
  • Abdelrahman, E. M., El-Araby, T. M., El-Araby, H. M., and Abo-Ezz, E. R.:
    A new method for shape and depth determinations from gravity data.
    In: Geophysics Nummer 66 (2001), S. 535-543
  • Abdelrahman, E. M., Riad, S., Refai, E., and Amin, Y.:
    On the least-squares residual anomaly determination.
    In: Geophysics Nummer 50 (1985), S. 473-480
  • Abdulagatov IM, Emirov SN, Abdulagatova ZZ, Askerov SY. :
    Effect of pressure and temperature on the thermal conductivity of rocks.
    In: Chem Eng Data. Nummer 51/1 (2006), S. 22-33
  • Abdulagatova Z, Abdulagatov IM, Emirov VN.:
    Effect of temperature and pressure on the thermal conductivity of sandstone.
    In: Int J Rock Mech Min Sci. Nummer 46/6 (2009), S. 1055-1071
  • Abdurrahman Satman, Züleyha Uğur:
    Flashing point compressibility of geothermal fluids with low CO2 content and its use in estimating reservoir volume.
    In: Geothermics Nummer 31(S0375650500000572) (2002-02-28), S. 29-44, 10.1016/S0375-6505(00)00057-2
  • Abedin AH, Rosen MA:
    A critical review of thermochemical energy storage systems.
    In: TOREJ Nummer 53 (2016), S. 897-923
  • Aber, M., Fritschen, R.:
    Rock mechanical analysis of a ML = 4.0 seismic event induced by mining in the Saar District, Germany.
    In: GJI Nummer 186 (2011), S. 359-372, doi: 101111/j.1365-245X.2011.05047.x
  • Abercrombie RE.:
    Earthquake source scaling relationships from -1 to 5 ML using seismograms recorded at 2.5-km depth.
    In: Journal of Geophysical Research Nummer 100 (1995), S. 24015-24036
  • Abiye, T., Tigistu Haile, .:
    Geophysical exploration of the Boku geothermal area, Central Ethiopian Rift.
    In: Geothermics Nummer 37(6) (December 2008), S. 586-596
  • Abraham, E.M., Lawal, K.M., Ekwe, A.C., Alile, O., Murana, K.A., Lawal, A.A.:
    Spectral analysis of aeromagnetic data for geothermal energy investigation of Ikogosi Warm Spring - Ekiti State, southwestern Nigeria.
    In: Geothermal Energy Nummer 2 (2014), 10.1186/s40517-014-0006-0
  • Abraham, E.M., Lawal, K.M., Ekwe, A.C., Alile, O., Murana, K.A., Lawal, A.A.:
    Reply to discussion on ‘Spectral analysis of aeromagnetic data for geothermal energy investigation of Ikogosi Warm Spring - Ekiti State, southwestern Nigeria’.
    In: Geothermal Energy Nummer 2 (2014), 10.1186/s40517-014-0018-9
  • Abrahamson, N.A., Silva, W.J., and Kamai, R.,:
    Summary of the ASK14 ground motion relation for active crustal regions.
    In: Earthquake Spectra, Nummer 30 (2014), S. 1025-1055
  • Abrigo, M., Molling, P., Acuña, J.:
    Determination of recharge and cooling rates using geochemical constraints at the Mak-Ban (Bulalo) geothermal reservoir, Philippines.
    In: Geothermics Nummer 33(1) (February 2004), S. 11-36
  • Abril G., A., Noble, J.:
    Geophysical well - log correlations along various cross-sections of the Cerro Prieto geothermal field.
    In: Geothermics Nummer 8(3) (1979), S. 177-182
  • Abubakar Kawuwa Sani, Rao Martand Singh, Cristina de Hollanda Cavalcanti Tsuha, Ignazio Cavarretta:
    Pipe–pipe thermal interaction in a geothermal energy pile.
    In: Geothermics Nummer 81(S0375650518302980) (2019-09-30), S. 209-223, 10.1016/j.geothermics.2019.05.004
  • Abul Khair, H., Cooke, D., Hand, M.:
    Seismic mapping and geomechanical analyses of faults within deep hot granites, a workflow for enhanced geothermal system projects.
    In: Geothermics Nummer () (January 2015), S. 46-56
  • Abyhammer, T., Eriksson A. & Johansson, S.:
    Aquifer-based Energy System.
    4. Aufl.
    Stockholm : Swedish Council for Building Research, 1991.
    - ISBN 3-492-02488-2
  • Acatech:
    Hydraulic Fracturing – eine Technologie in der Diskussion“.
    Berlin : Deutsche Akademie der Technikwissenschaften, 2015.
  • Acharya, H.:
    Influence of plate tectonics on the locations of geothermal fields.
    In: PAGEOPH Nummer 121 (5/6) (1983), S. 853-867
  • Achiller, Herbert:
    Tiefpumpen in der Bayrischen Molasse: Erfahrungen mit Tauchkreiselpunpen zur Förderung von Thermalwasser aus tifen Geothermiebohrungen.
    In: GTE Nummer 83 (2016), S. 4-5
  • Acocella, V. and Funiciello, R.::
    Transverse systems along the ex- tensional Tyrrhenian margin of central Italy and their influence on volcanism,.
    In: Acocella, V. and Funiciello, R.: Nummer 25 (2006), S. 1–24, doi: 10.1029/2005TC001845
  • Acuña, J., Stimac, J., Sirad-Azwar, L., Pasikki, R.:
    Reservoir management at Awibengkok geothermal field, West Java, Indonesia.
    In: Geothermics Nummer 37(3) (June 2008), S. 332-346
  • Ada Villafáfila García, Kaj Thomsen, Erling H. Stenby:
    Prediction of mineral scale formation in geothermal and oilfield operations using the Extended UNIQUAC model: Part II. Carbonate-scaling minerals.
    In: Geothermics Nummer 35(S0375650506000289) (2006-06-30), S. 239-284, 10.1016/j.geothermics.2006.03.001
  • Ada Villafáfila García, Kaj Thomsen, Erling H. Stenby:
    Prediction of mineral scale formation in geothermal and oilfield operations using the extended UNIQUAC model: Part I. Sulfate scaling minerals.
    In: Geothermics Nummer 34(S0375650504000690) (2005-02-28), S. 61-97, 10.1016/j.geothermics.2004.11.002
  • Adam, Christoph, Gläßler Walter & Hölting, Bernward:
    Anhydritzemente im Rhätsandstein Hamburgs – Morphologie und Strukturen.
    1. Aufl.
    Stuttgart/New York : Chapman & Hall, 1991.
    - ISBN 3-492-02488-2
  • ADAM, D. & OBERHAUSER, A.::
    Kosten und Nutzen der Geothermie für die Verkehrsinfrastruktur.
    In: EI-Eisenbahningenieur, Nummer 59(3) (2008), S. 6-12
  • ADAMS, B.M., KUEHN, T.H., BIELICKI, J.M., RANDOLPH, J.B., & SAAR, M.O.:
    A comparison of electric power output of CO2 Plume Geothermal (CPG) and brine geothermal systems for varying reservoir conditions.
    In: Applied Energy Nummer 140 (2015), S. 265-377
  • ADAMS, B.M., KUEHN, T.H., BIELICKI, J.M., RANDOLPH, J.B., & SAAR, M.O.:
    On the importance of the thermosiphon effect in CPG (CO2 Plume Geothermal) power.
    In: Energy (2014)
  • ADAMS, B.M., KUEHN, T.H., BIELICKI, J.M., RANDOLPH, J.B., & SAAR, M.O.:
    On the importance of the thermosiphon effect in CPG (CO2 Plume Geothermal) power systems.
    In: Energy (2014)
  • Adams, M.:
    Chemistry of fluids from ascension #1, a deep geothermal well on ascension island, South Atlantic Ocean.
    In: Geothermics Nummer 25(4) (August–October 1996), S. 561-579
  • Adams, M., Beall, J., Enedy, S., Hirtz, P., Kilbourn, P., Koenig, B., Kunzman, R., Bill Smith, J.:
    Hydrofluorocarbons as geothermal vapor-phase tracers.
    In: Geothermics Nummer 30(6) (December 2001), S. 747-775
  • Adams, M., Davis, J.:
    Kinetics of fluorescein decay and its application as a geothermal tracer.
    In: Geothermics Nummer 20(1) (1991), S. 53-66
  • Adams, M., Moore, J., Fabry, L., Ahn, J.:
    Thermal stabilities of aromatic acids as geothermal tracers.
    In: Geothermics Nummer 21(3) (June 1992), S. 323-339
  • Ademe:
    Géothermie, projet pour un programme d´actions pluri-annuel.
    Paris, 1994
  • Ader, T., M. Chendorain, M. Free, T. Saarno, P. Heikkinen, P. E.Malin, P. Leary, G. Kwiatek, G. Dresen, F. Bluemle,et al.:
    Design and implementation of a traffic light system for deep geo-thermal well stimulation in Finland.
    In: J. Seismol (2019), doi:10.1007/s10950-019-09853-
  • ADOLF, J. et al.:
    Klimaschutz im Wohnungssektor – Wie heizen wir morgen?,.
    Hamburg, Köln : 2013.
  • Adorni, N., Ceppatelli, L., Grassi, A., Palama, A., Rosselli, P.:
    Construction of a probe for measuring temperature and pressure in deep wells.
    In: Geothermics Nummer 9(3) (1980), S. 251-259
  • Adorni, N., Ceppatelli, L., Papale, R., Parmeggiani, A.:
    Instrumentation for geothermal wells: Present status and future prospects.
    In: Geothermics Nummer 14(2) (1985), S. 287-307
  • AGEA AGEG :
    The geothermal reporting code Second edition.
    2010.
  • AGEA AGEG :
    Geothermal lexicon for resources and reserves definition and reporting.
    2010.
  • Agemar, T.:
    Fachinformationssystem Geophysik: Änderung der BHTKorrekturverfahren für einfach belegte Messungen.
    LIAG-Bericht, 2017
  • Agemar, T., Alten, J., Ganz, B., Kuder, J., Kühne, K., Schumacher, S. & Schulz, R.:
    The Geothermal Information System for Germany - GeotIS.
    In: ZDGG Nummer 165/2 (2014), S. 129-144
  • Agemar, T., Alten, J., Ganz, B., Kuder, J., Kühne, K., Schumacher, S. & Schulz, R.:
    The Geothermal Information System for Germany - GeotIS –.
    ZDGG Band 165 Heft 2, 129–144., 2014
  • Agemar, T., Brunken, J., Jodocy, M. Schellschmidt, R., Schulz, R. & Stober, I.:
    Untergrundtemperaturen in Baden-Württemberg.. In: Z. Dt. Ges. Geowiss. : (2013), Nummer 164 (1), S. 49-62
  • Agemar, T., Schellschmidt, R., Schulz, R.:
    Subsurface temperature distribution in Germany.
    In: Geothermics Nummer () (October 2012), S. 65-77
  • Agemar, T., Weber, J., & Schulz, R.:
    Deep Geothermal Energy Production in Germany..
    In: energies Nummer 7/7 (2014), S. 4397-4416
  • Agemar, T.; Alten, J.; Ganz, B.; Kuder, J.; Kühne, K.; Schumacher, S.; Schulz, R. :
    The Geothermal Information System for Germany—GeotIS.
    In: Z. Dtsch. Ges. Geowiss. Nummer 165 (2014), S. 129-144
  • Agemar, T.; Hese, F.; Moeck, I.; Stober, I. :
    Kriterienkatalog für die Erfassung tiefreichender Störungen und ihrer geothermischen Nutzbarkeit in Deutschland.
    In: Zeitschrift der Deutschen Gesellschaft für Geowissenschaften Nummer 168, DOI: 10.1127/zdgg/2017/0084 (2017), S. 285-300
  • Agemar, Thorsten, et al.:
    A new approach to estimating the geothermal potential of faults in Germany.
    In: WGC (2015)
  • Agemar, Thorsten, Evelyn Suchi, Inga Moeck:
    Die Rolle der tiefen Geothermie bei der Wärmewende.
    In: GTE Nummer 89 (2018), S. 04
  • Aggistalis, G., Alivizatos, A., Stamoulis, D., and Stournaras, G:
    Correlating uniaxial compressive strength with Schmidt hardness, point load index, Young’s modulus, and mineralogy of gabbros and basalts (Northern Greece.
    In: Bull. Int. Assoc. Eng. Geol Nummer 54 (1996), S. 3-11
  • Agioutantis, Z., Bekas, A.:
    The potential of district heating using geothermal energy. A case study, Greece.
    In: Geothermics Nummer 29(1) (February 2000), S. 51-64
  • Agocs, W. B.:
    Least-squares residual anomaly determination.
    In: Geophysics Nummer 16 (1951), S. 686-696
  • Agonga, O.:
    Geothermal geology: stratigraphy and hydrothermal alteration well OW-716, Olkaria geothermal area, Kenya.
    Reykjavik, 1993
  • Agosta, F., Alessandroni, M., Tondi, E., and Aydin, A. :
    Oblique normal faulting along the northern edge of the Majella Anticline, central Italy: Inferences on hydrocarbon migration and accumulation.
    In: Journal of Structural Geology Nummer 32(9), (2010), S. 1317-1333
  • Agosta, F., Prasad, M. & Aydin, A.:
    Physical properties of carbonate fault 494 rocks, fucino basin (Central Italy): implications for fault seal in platform carbonates. .
    In: Geofluids Nummer 7 (2007), S. 19-32
  • Agosta, F., Prasad, M. & Aydin, A. :
    Physical properties of carbonate fault rocks, fucino basin (Central Italy): implications for fault seal in platform carbonates.
    In: Geofluids Nummer 7 (2007), S. 19-32
  • Agostinetti, N. P. et al.:
    Discovering geothermal supercritical fluids: a new frontier for seismic exploration.
    In: Sci. Rep. Nummer 7 (2017), S. 14592
  • Agostini, S., Corti, G., Doglioni, C., Carminati, E., Innocenti, F., Tonarini, S., Manetti, P., Di Vincenzo, G., Montanari, D.:
    Tectonic and magmatic evolution of the active volcanic front in El Salvador: insight into the Berlín and Ahuachapán geothermal areas.
    In: Geothermics Nummer 35(4) (August 2006), S. 368-408
  • Agostini, S., Doglioni, C., Innocenti, F., Manetti, P., Tonarini, S., and Sava ̧sçin, M. Y:
    The transition from subduction-related to intraplate Neogene magmatism in the Western Anatolia and Aegean area.
    In: Cenozoic Volcanism in the Mediterranean Area, edited by: Beccaluva, L., Bianchini, G., and Wilson, M., Geol. S. Am (2007), S. 418. 1-15, doi: 10.1130/2007.2418(01)
  • Agrawal, H. M., J. B Garg, J. A. Harvey:
    89Y + n resonances for E = 10–740 keV and intermediate structure.
    In: Nuclear Physics A Nummer 501(0375947489905630) (1989-09-11), S. 18-50
  • Agrawal, K.K., Bhardwaj, M., Misra, R., Das Agrawal, G., Bansal, V.:
    Optimization of operating parameters of earth air tunnel heat exchanger for space cooling: Taguchi method approach.
    In: Geothermal Energy Nummer 6 (2018), 10.1186/s40517-018-0097-0
  • Aguiar, A. C., G. C. Beroza:
    PageRank for earthquakes.
    In: Seismol. Res. Lett Nummer 85 (2014), S. 344-350
  • Aguilera, E., Cioni, R., Gherardi, F., Magro, G., Marini, L., Pang, Z.:
    Chemical and isotope characteristics of the Chachimbiro geothermal fluids (Ecuador).
    In: Geothermics Nummer 34(4) (August 2005), S. 495-517
  • ahara, D.P., Kohl, T.:
    Importance of active fractures in the borehole breakouts heterogeneity.
    In: 9th International Geothermal Conference Freiburg (2012)
  • Ahmad, M., Akram, W., Ahmad, N., Tasneem, M., Rafiq, M., Latif, Z.:
    Assessment of reservoir temperatures of thermal springs of the northern areas of Pakistan by chemical and isotope geothermometry.
    In: Geothermics Nummer 31(5) (October 2002), S. 613-631
  • Ahmad, Moghees and M.N Karimi:
    Thermodynamic Analysis of Kalina Cycle.
    In: International Journal of Science and Research Nummer 5/3 (2016)
  • Ahmed SF, Khalid M, Rashmi W, Chan A, Shahbaz K.:
    Recent progress in solar thermal energy storage using nanomaterials.
    In: Renew Sustain Energy Rev Nummer 67 (2017), S. 450-460
  • Ahrens, H. :
    Neotektonische Karte der DDR 1 : 1 000 000.
    Zentrales Geologisches Institut (ZGI), 1972.
  • Ahrens, T. J.:
    Global earth physics - a handbook of physical contants.
    Washington : Am. Geophys. Union, 1995.
  • Aichholzer, C., Duringer, P., Orciani, S., Genter, A.:
    New stratigraphic interpretation of the Soultz-sous-Forêts 30-year-old geothermal wells calibrated on the recent one from Rittershoffen (Upper Rhine Graben, France).
    In: Geothermal Energy Nummer 4 (2016), 10.1186/s40517-016-0055-7
  • Aiken, C.L.V., Balde, M., Xu, X., Abdel-Salam, M.G., De la Fuente, M.F., Mena, M.,:
    Integrated studies of Mexico with gravity, magnetic, and GIS database.
    In: Lead. Edge Nummer 16 (1997), S. 1779-1785
  • Airah
    Great Dane.
    Aufgerufen: October 10, 2017
  • Aires-Barros, L.:
    FAO-European cooperative networks on rural energy.
    In: Geothermics Nummer 17(1) (1988), S. 269-275
  • Aires-Barros, L., Marques, J., Graça, R., Matias, M., Van Der Weijden, C., Kreulen, R., Eggenkamp, H.:
    Hot and cold CO2-rich mineral waters in Chaves geothermal area (Northern Portugal).
    In: Geothermics Nummer 27(1) (February 1998), S. 89-107
  • Aires-Barros, Luis, José Manuel Marques, Rui Cores Graça, Maria Jose Matias, Cornelis H.Van Der Weijden, Rob Kreulen, Hermanus Gerardus, M.Eggenkamp:
    Hot and cold CO2-rich mineral waters in Chaves geothermal area (Northern Portugal).
    In: Geothermics Nummer 27(S0375650597844835) (1998-02-28), S. 89-107
  • Aiuppa, A., Carapezza, M., Parello, F.:
    Fluid geochemistry of the San Vicente geothermal field (El Salvador).
    In: Geothermics Nummer 26(1) (February 1997), S. 83-97
  • Akaku, K.:
    Geochemical study on mineral precipitation from geothermal waters at the fushime field, Kyushu, Japan.
    In: Geothermics Nummer 19(5) (1990), S. 455-467
  • Akand W. Islam, Hamid Reza Lashgari, Kamy Sephernoori:
    Double diffusive natural convection of CO2 in a brine saturated geothermal reservoir: Study of non-modal growth of perturbations and heterogeneity effects.
    In: Geothermics Nummer 51(S0375650514000248) (2014-07-31), S. 325-336, 10.1016/j.geothermics.2014.03.001
  • Akand W. Islam, Muhammad A. R. Sharif, Eric S. Carlson:
    Numerical investigation of double diffusive natural convection of CO2 in a brine saturated geothermal reservoir.
    In: Geothermics Nummer 48(S0375650513000497) (2013-10-31), S. 101-111, 10.1016/j.geothermics.2013.07.001
  • Akın, T., Kargı, H.:
    Modeling the geochemical evolution of fluids in geothermal wells and its implication for sustainable energy production.
    In: Geothermics Nummer 77() (January 2019), S. 115-129