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7. Second Fact Sheet

Author

Manzella, Adele, Bertani, Ruggero, and Trumpy, Eugenio

Subjects
results, geophysics, geothermal energy, drilling superhot geothermal system, exploration, dissemination, drilling, non technical
Abstract

This document, prepared in the frame of WP6, provides the second Fact Sheet of the DESCRAMBLE project, organized following the format of the first Fact Sheet delivered on October 2016. The Fact Sheet summarizes the main technical details of the projects and its results., H2020

Published
2018
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8. Proceedings Of The Final Conference

Author

Manzella, Adele and Bertani, Ruggero

Subjects
gephysics, geothermal energy, italy, exploration, dissemination, larderello, drilling, non technical
Abstract

This report describes the Final Conference of the DESCRAMBLE project and organize its Proceedings, as activity of WP6, H2020

Published
2018
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9. Geothermal energy in deep aquifers: A global assessment of the resource base for direct heat utilization

Author

Limberger, Jon, Boxem, Thijs, Pluymaekers, Maarten, Bruhn, D.F., Manzella, Adele, Calcagno, Philippe, Beekman, Fred, Cloetingh, S.A.P.L., and van Wees, Jan Diederik

Subjects
Direct heat utilization, Global resources, Geothermal energy, Heat flow, Heat in place
Abstract

In this paper we present results of a global resource assessment for geothermal energy within deep aquifers for direct heat utilization. Greenhouse heating, spatial heating, and spatial cooling are considered in this assessment. We derive subsurface temperatures from geophysical data and apply a volumetric heat-in-place method to improve current global geothermal resource base estimates for direct heat applications. The amount of thermal energy stored within aquifers depends on the Earth's heat flow, aquifer volume, and thermal properties. We assess the thermal energy available by estimating subsurface temperatures up to a depth of three kilometer depending on aquifer thickness. The distribution of geothermal resources is displayed in a series of maps and the depth of the minimum production temperature is used as an indicator of performance and technical feasibility. Suitable aquifers underlay 16% of the Earth's land surface and store an estimated 4·105 to 5·106 EJ that could theoretically be used for direct heat applications. Even with a conservative recovery factor of 1% and an assumed lifetime of 30 years, the annual recoverable geothermal energy is in the same order as the world final energy consumption of 363.5 EJ yr−1. Although the amount of geothermal energy stored in aquifers is vast, geothermal direct heat applications are currently underdeveloped with less than one thousandth of their technical potential used.

Published
2018

10. A Methodology for Assessing the Favourability of Geopressured-Geothermal Systems in Sedimentary Basin Plays: A Case Study in Abruzzo (Italy)

Author

Santilano, Alessandro, primary, Trumpy, Eugenio, additional, Gola, Gianluca, additional, Donato, Assunta, additional, Scrocca, Davide, additional, Ferrarini, Federica, additional, Brozzetti, Francesco, additional, de Nardis, Rita, additional, Lavecchia, Giusy, additional, and Manzella, Adele, additional

Published
2019
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11. IMAGE-D5.05 Database: Potential supercritical conditions

Author

Manzella, Adele

Subjects
high-temperature systems, favourability, 13. Climate action, geophysics, deep geothermal, exploration, GIS, 7. Clean energy, indicators, drilling
Abstract

Very high-temperature reservoirs are a possible target for future geothermal exploration eitherthrough the direct exploitation of super-critical fluids or as a potential high-temperature reservoir forEnhanced Geothermal Systems. By exploiting subsurface fluids at super-critical conditions, i.e.high temperature (>375 °C) and high pressure (>22 MPa), the energy output per well will increaseby a factor of ~10. This will reduce development costs by decreasing the number of wells needed(IEA Technology Roadmap 2011). In order to contribute to the EU strategic energy and climate targets for 2020 and 2050 by fosteringincreased growth in the geothermal energy market through enhanced awareness of the potential ofgeothermal energy production, a database of potential supercritical resources has been launchedby the IMAGE project. Superhot and supercritical resources are expected in the surrounding of still hot magmaticintrusions in the crust. A large part of the IMAGE activity focused on understanding what are thefavorable conditions at a few km depth for shallow magmatic emplacement, beside improvingexploration and investigation techniques for their detection and the related hot water circulation. Ina typical crust with an average thermal gradient of the order of 30-35 °C/km the critical temperatureof a brine (temperature above 450 °C) is reached at depth greater than 12-15 km. However, inmany sites around the world (e.g. Larderello and Phlegraean Fields in Italy, Nesjavellir in Iceland, The Geysers in California) where exploratory boreholes were drilled in high-temperaturegeothermal system (T > 370 °C), reservoir pressures above supercritical conditions (>22.1 MPa)were encountered. These evidences confirm that geothermal reservoirs in supercritical conditions,both in temperature and pressure, exist in the vicinity of cooling magmatic intrusions. Volcanic rifts,extensional basins and/or subduction zones with related shallow crustal magma emplacements,are the more promising environments in which supercritical conditions may be found in the upperto middle crust levels, The compilation of a European database of the favourable indicators of the presence ofsupercritical geothermal resources has been a main task in the IMAGE project. The objective is todefine areas in Europe where supercritical fluids occur at a drillable depth with a manageablechemistry composition can be found. Where do we find fluids at 4-5 km depth with a temperatureexceeding 400 °C? In various regions in Europe, including Iceland, Italy, Azores, Montserrat,Canary Island. What characterizes these areas? Can we find other areas with similar features atgreater depth? We focus on Iceland, where these resources have been searched and studied inthe last decade. We used the experience of research in Larderello, described in detail in otherIMAGE deliverables (e.g. D5.01), to look for indicators applicable over broad areas, in search ofpotential supercritical resources in continental Europe. Since temperature is the key parametercontrolling the presence of supercritical reservoirs at (relatively) shallow depth, mapping ofsupercritical resources was mainly driven by thermal models derived from crustal and lithosphericconstraints and data interpolation from available deep wells. Other information providing indirectindication of crustal thinning and shallow magmatic emplacement have been searched andanalyzed. In particular, we mapped the following indicators: the depth of 400 °C isotherm; theMOHO depth and crustal thickness; the earthquake density combined with the estimated depth ofthe Brittle-Ductile Transition in Europe. Other interesting indicators, e.g. He3/He4 ratio values fromwhich fluids of crustal origin may be inferred, or Curie Point depth that refers to deep temperatureregime, are available only for local areas, and are too restricted to be of use at regional andEuropean scale. The location of recent (Pleistocene-Holocene) volcanism, also dispersed, wasmapped since it provides useful information, but was not used in the computation of final maps. After defining the indicators, their spatial correlation was established by Geographic InformationSystem (GIS) models, and a database was organized. By prioritizing favourable conditions usingGIS spatial analysis methods, the “favourability” map of geothermal resources at supercriticalcondition was then obtained. It provides a clear overview of the distribution of potential resourcesin Europe, based on analytical data.

Published
2017
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12. Image-D5.6: Mt-Inversion Techniques With External Constraints

Author

Hersir, Gylfi Páll and Manzella, Adele

Subjects
data modelling, geophysics, geothermal energy, italy, MT-Inversion, exploration, iceland
Abstract

This report describes MT-inversion techniques with external constraints, Deliverable D5.6 within the IMAGE project. Report analysing the results of MT-inversion techniques with external contraints, describing optimal MT layout and data modelling for obtaining maximum information from MT surveys, including recommendations for opitmised MT site spacing for different a-priori constraints. The first part of the report, which was performed by ISOR, discusses the origin and nature of the static shifts and some tested methods for static shift correction, i.e. joint 1D inversion of co-located TEM and MT and spatial filtering and statistical assumptions about the shifts. A software is introduced which inverts the two datasets for both the resistivity model and the shift of the MT. Besides determining the static shift, joint inversion is an important quality check of the TEM and MT data sets, i.e. weather they are compatible. In EM surveying, software should be used make a preliminary joint inversion of TEM and MT at base camp as a quality control to make sure the field mission is not terminated until god quality data have been collected. Finally, the claim that 3D inversion of MT can deal with the static shifts, i.e. introduce shallow resistivity structures (not resolved by the data) to account for the shifts is tested. The second part was done by ISOR. On one hand the depth-location of a low-resistivity anomaly, as observed from borehole data, is build into the starting model, giving the program a headstart into gaining information on the resistivity in the survey area and on the other hand information on the ductile-brittle bounday location is used to infer the location of a deep low-resistivity anomaly, which is put into the starting model of the inversion. Several tests have been done on the site spacing in MT for 3D inversion.n This was done for MT data from the Hengill area in SW-Iceland, starting with a measurment and model grid of 1 km by 1 km (see, Árnason et al., 2010). Later a measurement and model grid seize of 500 m by 500 m was tested which improved the resolution significantly for the uppermost 1 to 2 km (Árnason, pers. comm., June 2017). Finally, a measure-ment and model grid seize 250 m by 250 m was tested (Benediktsdóttir, pers. comm., June 2017). It only improved the resolution moderately. In the third part performed by CNR, an integrated approach is proposed that greatly improved the knowledge on the deep structures of the system on the basis of the critical review of deep well data, geological and geophysical data and the analysis of new and previously acquired MT data in the Larderello-Travale field. Resistivity models by 2D deterministic inversion was achieved, focusing on the understanding of the reliability of the a-priori model for the inversion procedure. Three sets of starting models were implemented and tested: A homogeneous (without external constraints), a geological model (from the integrated model) and finally an interpolation of 1D models. The resulting models constrained with detailed and accurate geological information as well as using 1D models showed higher resolution than those unconstrained (i.e. from homogeneous half-space). It is demonstrated how the a-priori information from the analysis of MT data, i.e. by PSO optimization in this case, greatly improved the inversion results even those geologically constrained, which is not a trivial issue for the exploration of geothermal greenfield, due to lack of underground data., FP7

Published
2017
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13. Geothermal energy in deep aquifers: A global assessment of the resource base for direct heat utilization

Author

Limberger, Jon (author), Boxem, Thijs (author), Pluymaekers, Maarten (author), Bruhn, D.F. (author), Manzella, Adele (author), Calcagno, Philippe (author), Beekman, Fred (author), Cloetingh, S.A.P.L. (author), van Wees, Jan Diederik (author), Limberger, Jon (author), Boxem, Thijs (author), Pluymaekers, Maarten (author), Bruhn, D.F. (author), Manzella, Adele (author), Calcagno, Philippe (author), Beekman, Fred (author), Cloetingh, S.A.P.L. (author), and van Wees, Jan Diederik (author)

Abstract

In this paper we present results of a global resource assessment for geothermal energy within deep aquifers for direct heat utilization. Greenhouse heating, spatial heating, and spatial cooling are considered in this assessment. We derive subsurface temperatures from geophysical data and apply a volumetric heat-in-place method to improve current global geothermal resource base estimates for direct heat applications. The amount of thermal energy stored within aquifers depends on the Earth's heat flow, aquifer volume, and thermal properties. We assess the thermal energy available by estimating subsurface temperatures up to a depth of three kilometer depending on aquifer thickness. The distribution of geothermal resources is displayed in a series of maps and the depth of the minimum production temperature is used as an indicator of performance and technical feasibility. Suitable aquifers underlay 16% of the Earth's land surface and store an estimated 4·105 to 5·106 EJ that could theoretically be used for direct heat applications. Even with a conservative recovery factor of 1% and an assumed lifetime of 30 years, the annual recoverable geothermal energy is in the same order as the world final energy consumption of 363.5 EJ yr−1. Although the amount of geothermal energy stored in aquifers is vast, geothermal direct heat applications are currently underdeveloped with less than one thousandth of their technical potential used., Petroleum Engineering

Published
2018
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14. Report on the Open Access Database

Author

Trumpy, Eugenio, Manzella, Adele, and Botteghi, Serena

Subjects
mexico, geology, los humeros, geophysics, geothermal energy, dataset, exploration, europe, acoculco, GeneralLiterature_MISCELLANEOUS, database, geochemistry
Abstract

This report includes the description of the GEMex Open Access Database implementation and the collection of data. Geothermal data, in the form of maps, datasets and models will be organized and stored in an Open Access Database and will be made available in a Spatial Data Infrastructure according to international standards and protocols. Part of this report is in the form of a handbook to help user to access the available information. The database is available by a dedicated link in the project website and will be updated by the end of the project., H2020, {"references":["GeoNode web site – http://geonode.org","GeoNode documentation: http://docs.geonode.org","GeoNode Development Team – GeoNode Documentation, Release 2.4. – 2015. Available on line at the URL: https://media.readthedocs.org/pdf/GeoNode/latest/GeoNode.pdf","OGC Services - OGC Services – http://www.opengeospatial.org/","Open Geospatial Consortium – http://en.wikipedia.org/wiki/Open_Geospatial_Consortium"]}

Published
2016
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15. Evaluation Report From Transnational Activities

Author

Manzella, Adele, Trumpy, Eugenio, Ramsak, Paul, Schreiber, Stephan, Ingolfsson, Hjalti Pall, Pétursson, Baldur, Nador, Annamaria, Calcagno, Philippe, and Ketilsson, Jónas

Subjects
human resources, financial support, geothermal energy, joint activities, europe, non technical
Abstract

This report deals with the activities and results achieved by the seven Joint Activities established in the course of the Geothermal ERA-NET with a minor effort on human resources and financial support. The activities were planned and coordinated as working groups participated by the project partners, and produced survey reports and/or workshop Minutes., FP7

Published
2016
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16. Proposals For Transnational Activities

Author

Manzella, Adele and Trumpy, Eugenio

Subjects
EGIP, OpERA, 13. Climate action, knowledge exchange, geothermal energy, joint activities, europe, tansnational, 7. Clean energy, co-fund action, non technical
Abstract

This report deals with the organization of transnational activities, after their definition in WP4. In the JA1 Phase, in the form of Working Group preparatory activities, a number of workshops, surveys and reports were organized, and their results were discussed in two Geothermal ERA-NET project meetings: a main one held in Brussels on October 2015, and second one held in Ankara, Turkey, on February 2016. During the JA1 activities and these meetings, the consortium partners defined what activities could pass to the advanced phase of implementation (JA2) having a budget for doing so, or were continuing as JA1 activity providing technical reports. Of the seven themes implemented as JA1 activities, also in consideration of time and budget limits, only two JA1 activities (EGIP for the establishment of a European Geothermal Information Platform and OpERA related to operational issues in geothermal installation) proposed a follow up in the form of co-funded Calls. For EGIP, some countries found a common interest in developing a professional and appealing front-end for the pilot platform whose structure and content has been developed in kind. For OpERA, the proposal that found the interest of various countries regarded the organization of a handbook related to operational issues in geothermal installations, named OpERA-pedia, to be published on the Geothermal ERA-NET webpage and constituting a platform for knowledge exchange. These proposed JA2 activities resulted suitable for Calls for Tenders. Administrative issues, including the difficulties of some country to organize a common Call for Tenders, let the EGIP proposal to be dropped, whereas the OpERA-pedia will be organized as a simultaneous Call for Tender in the participating countries. Indeed, the JA1 activities and the experience gained in the Geothermal ERA-NET project has strengthen the transnational partnership by planning concrete joint activities as testified by the setting up of a new proposal for a geothermal ERA-NET in the form of Co-funded action, to enhance cooperation potential in the field of geothermal., FP7

Published
2016
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17. Abstract Book | IMAGE Mid-Term Conference

Author

Manzella, Adele and Nardini, Isabella

Subjects
abstract, 13. Climate action, integrated methods, geothermal energy, Pisa, conference book, structural geology, exploration, vulcanology
Abstract

Collection of abstracts from the Mid-Term Conference of theIMAGE project, 12-13 October 2015. Project Coordinator: Jan Hopman, TNO, Utrecht, NL Scientific Committee: David Bruhn, Helmholtz Centre, GFZ German Research Centre for Geosciences, Potsdam, D. Chrystel Dezayes, BRGM, Department of Geothermal Energy, Georessources Division, Orléans, F. Ólafur G. Flóvenz, ÍSOR, Iceland GeoSurvey, Reykjavík, IS. Gu.mundur Ómar Fri.leifsson, HS Orka hf, Reykjanesbær, IS. Domenico Liotta, Dipartimento di Scienze della Terra e Geoambientali, Università di Bari, I. Adele Manzella, CNR-Institute of Geosciences and Earth Resources, Pisa, I. Gylfi Páll Hersir, ÍSOR, Iceland GeoSurvey, Reykjavík, IS. Giovanni Ruggieri, CNR-Institute of Geosciences and Earth Resources, Firenze, I. Jan Diederik van Wees, TNO, Utrecht, NL. Editors: ADELE MANZELLA and ISABELLA NARDINI* CNR-Institute of Geosciences and Earth Resources, Via Moruzzi 1 – 56124 Pisa, Italy. EDIZIONI CNR ISBN 9788879580267 *contact person: isabella.nardini@igg.cnr.it Edizioni CNR ISBN 9788879580267

Published
2015
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18. Report On Developed Tools For Joint Activities

Author

Manzella, Adele

Subjects
geothermal energy, joint calls, cooperation, joint activities, economics, europe, non technical
Abstract

The present report provides guidelines for competitive and non-competitive funding mechanisms and collaborative activities. It aims not only at the facilitation of the production of calls but also at the consideration and promotion of the favourable conditions for common programming. This report and the list of research topics defined in WP4, will comprise the backbone of the uptake of JA, to be defined in the engagement meeting to be held in Brussels on October 2015., FP7, {"references":["NETWATCH policy Brief, Series N.1 (2012). ERA-NETs and the realization of ERA: increasing coordination and reducing fragmentation. Authors: N. Harrap and M. Boden, JRC Technical Report. JRC73451, ISBN 978-92-79-25936-4, ISSN 1831-9424, doi 10.2791/9503."]}

Published
2015
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19. Technical And Non-Technical Barriers & Opportunities

Author

Breembroek, Gerdi, Ramsak, Paul, Manzella, Adele, and Trumpy, Eugenio

Subjects
opportunities, energy sector status, 13. Climate action, barriers, geothermal energy, europe, exploration, 7. Clean energy, non technical
Abstract

This report shows barriers and opportunities for geothermal development in countries, participating in ERANET Geothermal energy. These barriers and opportunities have been identified by the participants of ERANET Geothermal energy. They will be an important input in setting up a programme of international collaboration., FP7

Published
2014
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20. Towards More Geothermal Electricity Generation In Europe

Author

Dumas, Philippe, van Wees, Jan-Diederik, Manzella, Adele, Nardini, Isabella, Angelino, Luca, Latham, Alexandra, and Simeonova, Detelina

Subjects
public acceptance, geothermal energy, resource assessment, economics, exploration, europe, regulatory aspects, non technical
Abstract

Geothermal power generation has its roots in Europe, where the first test in 1904 and the real beginning of power generation in 1913 took place, both at the Larderello dry steam field in Italy. Since then, the development of geothermal technology has been continuous and the total installed capacity in Europe currently amounts to 1.8 GWe, generating approximately 11.5 TWh of electric power every year. For a decade, thanks to the optimisation of the new binary system technology, geothermal electricity can be produced using lower temperatures than previously. Moreover, with Enhanced Geothermal Systems (EGS), a breakthrough technology proven since 2007, geothermal power can in theory be produced anywhere in Europe. The main benefits of geothermal power plants are provision of base-load and flexible renewable energy, diversification of the energy mix, and protection against volatile and rising electricity prices. Using geothermal resources can provide economic development opportunities for countries in the form of taxes, royalties, technology export and jobs. The potential of geothermal energy is recognised by some EU Member States in their National Renewable Energy Action Plans (NREAPs). However, the actual potential is significantly larger. In order to increase awareness, GEOELEC - an IEE project co-financed by the EU and running between 2010 and 2013- has assessed and presented for the first time the economic potential in Europe in 2020, 2030 and 2050. The figures are quite impressive, showing the large potential of geothermal and the important role it can play in the future electricity mix., GEOELEC - IEE, {"references":["EGEC Market Report 2013/2014","EGEC Market Report 2012","AGEA-AGEG, 2008. Australian Code for Reporting of Exploration Results, Geothermal Resources and Geothermal Reserves, The Geothermal Reporting Code, 2008 Edition, 26 p.","AGEA-AGEG, 2010. Australian Code for Reporting of Exploration Results, Geothermal Resources and Geothermal Reserves, The Geothermal Reporting Code, Second Edition, 28 p.","CanGEA, 2010. The Canadian Geothermal Code for Public Reporting, Reporting of Exploration Results, Geothermal Resources and Geothermal Reserves, 2010 Edition, 32 p.","IPCC, 2011. IPCC Special Report on Renewable Energy Sources and Climate Change Mitigation – Geothermal Energy, Intergovernmental Panel on Climate Change (IPCC), Working Group III – Mitigation of Climate Change, 50 p.","Beardsmore, G.R., Rybach, L., Blackwell, D., and Baron, C., 2010. A protocol for estimating and mapping the global EGS potential, July 2010 edition, 11 p.","Cloetingh, S., v. Wees, J.D., Ziegler, P.A., Lenkey, L., Beekman, F., Tesauro, M., Förster, A., Norden, B., Kaban, M., Hardebol, N., Bonté, D., Genter, A., Guillou-Frottier, L. Voorde, M.T., Sokoutis,, D. Willingshofer, E., Cornu, T., and Worum, G., 2010. Lithosphere tectonics andthermo-mechanical properties: An integrated modelling approach for Enhanced GeothermalSystems exploration in Europe. Earth-Science Reviews, vol. 102, p. 159-206.","Davies, J.H. and Davies, D.R., 2010. Earth's surface heat fl ux. Solid Earth, 1, 5–24.","Etherington, J.R., and Ritter, J.E., 2007. The 2007 SPE/AAPG/WPC/SPEE Reserves and Resources Classifi cation, Defi nitions, and Guidelines: Defi ning the Standard!, 2007 SPE Hydrocarbon Economics and Evaluation Symposium, Dallas, Texas, USA, 1-3 April 2007. SPE 107693, 9 p.","Hurtig, E., Cermak, V., Haenel, R., and Zui, V.(eds.), 1992. Geothermal Atlas of Europe, International Association for Seismology and Physics of the Earth's Interior, International Heat Flow Commission, Central Institute for Physics of the Earth, Scale 1:2,500,000.","Williams, C.F., Reed, M.J., and Mariner, R.H., 2008. A Review of Methods Applied by the U.S. Geological Survey in the Assesment of Identifi ed Geothermal Resources, U.S. Department of the Interior, U.S. Geological Survey, Open-File Report 2008-1296, p.27","Williams, A.F., Lawless, J.V., Ward, M.A., Holgate, F.L., and Larking, A., 2010. A code for geothermal resources and reserves reporting, Proceedings World Geothermal Congress 2010, Bali, Indonesia, 25-29 April 2010, 7 p.","World Petroleum Council. Petroleum Resources Managment System, SPE-AAPG-WPCSPEE, p.47","Emerging fi nancing scheme for fostering investment in the geothermal energy sector, GEOFAR project, 2011, report coordinated by Erlagen AG.","European Insurance Scheme to cover Geological Risk related to Geothermal Operations, Final Report, June 1997, report coordinated by the BRGM for the European Commission.","Handbook on planning and fi nancing geothermal power generation, Energy Sector Management Assistance Programme, The Investment Bank for Reconstruction, April 2012.","European Geothermal Energy Council, 2009. Geothermal electricity and combined heat and power.","UNEP, 2011. Towards a Green Economy: Pathways to Sustainable Development and Poverty Eradication.","Dr.T.Reif, GHC Bulletin, 2008. Probability analysis and risk management for geothermal projects,","H.Kreuter and C.Hecht, proceedings European Geothermal Congress 2007, Unterhaching, Germany, 30 May-1 June 2007. Probability concepts for the evaluation of the risk concerning temperature and the production and injection rate in hydrothermal reservoirs.","R.Schulz et al., Proceedings European Geothermal Congress, >Unterhaching, Germany, 30 May-1 June 2007. Quantifi cation of exploration risks for hydrogeothermal wells.","S.K.Sanyal and J.B. Koenig, World Geothermal Congress, Florence, Italy, May 1995. Resource risk and its mitigation for the fi nancing of geothermal projects.","H.Kreuter and C.Schrage, GeoFund-IGA Geothermal Workshop, Turkey, Istanbul, February 16- 19, 2009. Geothermal market-based insurance schemes.","B.Richter, Proceedings World Geothermal Congress, Indonesia, Bali, 25-29 April 2010. Geothermal Energy Plant Unterhaching, Germany.","H.Kreuster and C.Schrage, GRC Transactions, Vol.33, 2009. Private and State Risk Mitigation Programs for Geothermal Exploration Risk.","Economist Intelligence Unit, 2011. Managing the risk in renewable energy.","European Union, Directive 2009/28/EC of the European Parliament and the Council of 23 April 2009 on the promotion of the use of energy from renewable sources and amending and subsequently repealing Directives 2001/77/EC and 2003/30/EC (Text with EEA relevance).","European Union, Directive 2000/60/EC of the European Parliament and of the Council of 23 October 2000 establishing a framework for Community action in the fi eld of water policy.","European Union, Directive 2009/28/EC of the European Parliament and the Council of 23 April 2009 on the promotion of the use of energy from renewable sources and amending and subsequently repealing Directives 2001/77/EC and 2003/30/EC (Text with EEA relevance).","Ármannsson, H., Fridriksson, Th., Kristjánsson, B.R., 2005: CO2 emissions from geothermal power plants and natural geothermal activity in Iceland.","Bertani, R., and Thain, I., 2002. Geothermal power generating plant CO2 emission survey, IGA News, 49, 1-3.","Cataldi, Raffaele, 2001. Social acceptance of geothermal projects - problems and costs. EC International Geothermal course.","Hauff , Jochen, Conrad Heider, Hanjo Arms, Jochen Gerber, and Martin Schilling, 2011. Gesellschaftliche Akzeptanz als Säule der energiepolitischen Zielsetzung.","Haug, Stefan, and René Mono, 2012. Akzeptanz für Erneurbare Energien - Akzeptanz planen, Beteiligung gestalten, Legeitimität gewinnen. guidelines, Berlin: 100 prozent erneuerbare stiftung.","Holm, A., Jennejohn, D., Blodgett, L., GEA (2012). Geothermal Energy and Greenhouse Gas Emissions, Geothermal Energy Association, Report November 2012","Goldstein, B., Hiriart, G., Bertani, R., Bromley, C., Gutierrez-Negrin, L., Huenges, E., Muraoka, H., Ragnarsson, A., Tester, J., Zui, V. (2011). Geothermal Energy, Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA.","Nolasco, L. A. F. (2010). Hydrogen sulphide abatement during discharge of geothermal steam from well pads: a case study of well PAD TR-18, El Salvador. Reports 2010, 13, Geothermal Training Programme, Iceland.","Pellizzone, Allansdottir, De Franco, Muttoni, and Manzella, 2013. Assessment of social acceptance of geothermal energy exploration in southern Italy.\" European Geothermal Conference.","Wüstenhagen, Rolf, Maarten Wolsink, and Mary Jean Bürer, 2007. Social Acceptance of renewable energy innovation: An introduction to the concept, Energy Policy."]}

Published
2014
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21. Training Course on Geothermal Electricity - Pisa

Author

Manzella, Adele and Nardini, Isabella

Subjects
enhanced geothermal systems, surface systems / generation, geothermal energy, resource assessment, economics, europe, exploration, environmental, regulatory aspects, non technical
Abstract

Training Course manual: Session I: Geothermal exploration - Adele Manzella, Isabella Nardini, Pierre Durst and Jan-Diederik van Wees Session II: EGS technology - Jan-Diederik van Wees, Chrystel Dezayes, Pier Durst and Günther Zimmermann Session III - Plant operation, energy supply and grid integration - F. Heilemann and S. Reith Session III – Geothermal exploration and resource assessment - Adele Manzella, Pierre Durst and Jan-Diederik van Wees Session IV: Flash steam and binary technology - P. Bombarda and F. Sabatelli Session V – Market aspects - Constantine Karytsas and Dimitrios Mendrinos Session VI: Legal, environmental and financial aspects - Session VI - Legal, environmental and financial aspects - L. Angelino, R. Barontini, F.Batini, M. Borzoni, P. Dumas, M. Frey, F. Jaudin, R. Kutschick, I. Nardini, T. Reif, F. Rizzi, B. Sanner, L. Tryggvadóttir and G. Wolter Session VII: Drilling - R. Bertani, A. Lazzarotto and L. Serniotti, GEOELEC - IEE

Published
2013
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22. A Methodology For Resource Assessment And Application To Core Countries

Author

van Wees, Jan-Diederik, Boxem, Thijs, Calcagno, Philippe, Dezayes, Chrystel, Lacasse, Christian, and Manzella, Adele

Subjects
geothermal energy, resource assessment, levelized cost of energy, exploration, europe
Abstract

This document gives a definition for resource assessment for the IEE funded project GEO-ELEC. This projects aims at developing a pan-European map based overview of the location of geothermal resources which can be developed in the 2020 and 2050 timeline horizons for electricity production., GEOELEC - IEE, {"references":["AGEA-AGEG, 2008. Australian Code for Reporting of Exploration Results, Geothermal Resources and Geothermal Reserves, The Geothermal Reporting Code, 2008 Edition, 26 p.","AGEA-AGEG, 2010. Australian Code for Reporting of Exploration Results, Geothermal Resources and Geothermal Reserves, The Geothermal Reporting Code, Second Edition, 28 p.","Beardsmore, G.R., Rybach, L., Blackwell, D., and Baron, C., 2010. A protocol for estimating and mapping the global EGS potential, July 2010 edition, 11 p.","CanGEA, 2010. The Canadian Geothermal Code for Public Reporting, Reporting of Exploration Results, Geothermal Resources and Geothermal Reserves, 2010 Edition, 32 p.","Cloetingh, S., v. Wees, J.D., Ziegler, P.A., Lenkey, L., Beekman, F., Tesauro, M., Förster, A., Norden, B., Kaban, M., Hardebol, N., Bonté, D., Genter, A., Guillou-Frottier, L. Voorde, M.T., Sokoutis,, D. Willingshofer, E., Cornu, T., and Worum, G., 2010. Lithosphere tectonics and thermo-mechanical properties: An integrated modelling approach for Enhanced Geothermal Systems exploration in Europe. Earth-Science Reviews, vol. 102, p. 159-206.","Davies, J.H. and Davies, D.R., 2010. Earth's surface heat flux. Solid Earth, 1, 5–24.","Etherington, J.R., and Ritter, J.E., 2007. The 2007 SPE/AAPG/WPC/SPEE Reserves and Resources Classification, Definitions, and Guidelines: Defining the Standard!, 2007 SPE Hydrocarbon Economics and Evaluation Symposium, Dallas, Texas, USA, 1-3 April 2007. SPE 107693, 9 p.","Hurtig, E., Cermak, V., Haenel, R., and Zui, V.(eds.), 1992. Geothermal Atlas of Europe, International Association for Seismology and Physics of the Earth's Interior, International Heat Flow Commission, Central Institute for Physics of the Earth, Scale 1:2,500,000.","IPCC, 2011. IPCC Special Report on Renewable Energy Sources and Climate Change Mitigation – Geothermal Energy, Intergovernmental Panel on Climate Change (IPCC), Working Group III – Mitigation of Climate Change, 50 p.","Williams, C.F., Reed, M.J., and Mariner, R.H., 2008. A Review of Methods Applied by the U.S. Geological Survey in the Assesment of Identified Geothermal Resources, U.S. Department of the Interior, U.S. Geological Survey, Open-File Report 2008-1296, 27 p.","Williams, A.F., Lawless, J.V., Ward, M.A., Holgate, F.L., and Larking, A., 2010. A code for geothermal resources and reserves reporting, Proceedings World Geothermal Congress 2010, Bali, Indonesia, 25-29 April 2010, 7 p.","World Petroleum Council. Petroleum Resources Managment System, SPE-AAPG-WPC-SPEE, 47 p."]}

Published
2013
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23. Report on the state-of-the-art and needs in regarding geothermal data and existing tools to manage them

Author

Trumpy, Eugenio, Manzella, Adele, and Nardini, Isabella

Subjects
EGIP, information platform, geothermal energy, europe, exploration, non technical
Abstract

A description of the state-of-the-art concerning geothermal data and tools used for the management and sharing them is a sine qua non for the key task of 3.2 within Work Package 3 - Towards a European Geothermal Platform - in the framework of the Geothermal ERA-NET. This is line with the objective of WP3 is to complete the preliminary work required for the creation of a European Geothermal Platform with the purpose of sharing harmonized and systematic information on legal and regulatory aspects, policies, measures, institutions, research projects and datasets., FP7

Published
2013

24. Best Practice Handbook For The Development Of Unconventionnal Geothermal Resources With A Focus On Enhanced Geothermal System

Author

Kohl, T., Baujard, C., Manzella, Adele, Schulte, T., and Karytsas, C.

Subjects
surface systems / generation, geothermal energy, economics, exploration, europe, drilling, environmental, non technical
Abstract

The ENGINE work has been synthesized in a Best Practice Handbook presenting an overview of the investigation, exploration, and exploitation of unconventional geothermal reservoirs (UGR) and Enhanced Geothermal Systems (EGS) taking into account economic and socioenvironmental impacts. The Best Practice Handbook is designed for different groups of interest such as engineers, politicians, and decision makers from industry. The entire EGS life cycle is covered in four chapters: Chapter 1: Site investigation Chapter 2: Drilling, stimulation and reservoir assessment Chapter 3: Exploitation Chapter 4: Environmental and socioeconomic impact, ENGINE - FP6

Published
2008
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25. Technological Challenges In Exploration And Investigation Of Egs And Ugr

Author

Manzella, Adele

Subjects
enhanced geothermal systems, geothermal energy, geothermal resources, mapping, exploration, environmental
Abstract

The most pressing technological challenges in exploration and investigation of Enhanced Geothermal Systems (EGS) and Unconventional Geothermal Resources (UGR) are considered to be those associated with the identification of the nature of geothermal heat concentrations and prospective resources prior to drill and the improvement of methods allowing a spatial and temporal reconstruction of the subsurface geothermal condition that might not only cut the time from discovery to production and improve efficiency while guaranteeing sustainability of the resource, but also reduce environmental impacts forecasting possible problems and finding solutions beforehand. A list of important research themes is provided, ENGINE - FP6

Published
2008
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27. The deep geothermal structure of the Mid-Atlantic Ridge deduced from MT data in SW Iceland

Author

Oskooi, Behrooz, Pedersen, Laust Börsting, Smirnov, Maxim, Árnason, Knutur, Eysteinsson, Hjálmar, Manzella, Adele, Oskooi, Behrooz, Pedersen, Laust Börsting, Smirnov, Maxim, Árnason, Knutur, Eysteinsson, Hjálmar, and Manzella, Adele

Abstract

Iceland is very active tectonically as it is crossed by the Mid-Atlantic Ridge and its associated rift zones and transform faults. The high-temperature geothermal systems are located within the neo-volcanic zone. A detailed comparison of the main features of the resistivity models and well data in exploited geothermal fields has shown that the resistivity structure of Iceland is mainly controlled by alteration mineralogy. In areas where the geothermal circulation and related alteration take place at depths of more than 1.5 km, the investigation depth of the DC and TEM methods is inadequate and the MT method appears to be the most suitable survey method. MT soundings were carried out to determine the deep structure between two neighboring Quaternary geothermal fields: the Hengill volcanic complex and the Brennisteinsfjoll geothermal system, both known as high-temperature systems. MT data were analyzed and modeled using 1D and 2D inversion schemes. Our model of electrical conductivity can be related to secondary mineralization from geothermal fluids. At shallow depths, the resistivity model obtained from the MT data is consistent with the general geoelectrical models of high-temperature geothermal systems in Iceland, as revealed by shallow DC and TEM surveys. The current MT results reveal the presence of an outcropping resistive layer, identified as the typical unaltered porous basalt of the upper crust. This layer is underlain by a highly conductive cap resolved as the smectite–zeolite zone. Below this cap a less conductive zone is identified as the epidote–chlorite zone. A highly conductive material has been recognized in the middle of the profile, at about 5 km depth, and has been interpreted as cooling partial melt representing the main heat source of the geothermal system. This conductor may be connected to the shallow structure through a vertical fault zone located close to the southern edge of the profile.

Published
2005
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28. Methodological approach for evaluating the geo-exchange potential: VIGOR Project

Author

Galgaro, Antonio, primary, Di Sipio, Eloisa, additional, Destro, Elisa, additional, Chiesa, Sergio, additional, Uricchio, Vito, additional, Bruno, Delia, additional, Masciale, Rita, additional, Lopez, Nicola, additional, Iaquinta, Pasquale, additional, Teza, Giordano, additional, Iovine, Giulio, additional, Montanari, Domenico, additional, Manzella, Adele, additional, Soleri, Sergio, additional, Greco, Roberto, additional, Di Bella, Guido, additional, Monteleone, Salvatore, additional, Sabatino, Maria, additional, Iorio, Marina, additional, Petruccione, Emanuela, additional, Giaretta, Aurelio, additional, Tranchida, Giorgio, additional, Trumpy, Eugenio, additional, Gola, Gianluca, additional, and D'Arpa, Stefania, additional

Published
2012
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29. Combined TEM-MT investigation of shallow-depth resistivity structure of Mt. Somma-Vesuvius.

Author

Manzella, Adele, Volpi, Gianni, Zaja, Annalisa, Meju, Maxwell, Manzella, Adele, Volpi, Gianni, Zaja, Annalisa, and Meju, Maxwell

Abstract

The conductivity structure of the top 2 km of the crust is examined using data from collocated magnetotelluric (MT) and time-domain electromagnetic (TDEM) soundings across the Vesuvius volcano. The MT data were corrected for static shift using dual-configuration TDEM data. The TEM and MT data were jointly inverted to yield 1D models while the TE and TM mode MT data were jointly inverted using a 2D inversion approach. The resulting models reveal the presence of a resistive cover layer underlain by an anomalous conductive layer (c. 250–500 m below the ground surface) that is shallowest underneath the caldera. We suggest that the conductive body below the caldera is related to enhanced hydrothermal circulation; outside the caldera, the conductor is consistent with the hydrological system and is interpreted as mapping a suggested aquifer system and underlying clayey deposits. Our results show that the aquifer hosted in the Vesuvius edifice is not homogeneous, but appears particularly conductive in the western and southern sectors of the volcano. It was found from 3D numerical modelling study that the presence of the shallow and thick conductors and the Tyrrhenian sea changes the penetration depth of MT data and must be taken into account during interpretation. Recommendations are made for any future MT field studies aimed at resolving the deep resistivity structure of Mt Somma-Vesuvius.

Published
2004

31. Analysis Report With Proposals On Future Programme Collaboration And Stakeholder Collaboration

Author

Manzella, Adele and Breembroek, Gerdi

Subjects
EGIP, OpERA, 13. Climate action, geothermal energy, joint calls, joint activities, europe, 7. Clean energy, co-fund action, non technical
Abstract

This reports describes the learning from the Joint Activities in the frame of Geothermal ERA-NET and the strategies to develop further funding procedures. The main focus is on the activities for establishing a web-based knowledge transfer system related to operational issues of geothermal installations in Europe, the so-called OpERA-pedia, and those related to the implementation of the European Geothermal Information Platform, EGIP, for collecting and retrieving technical and non-technical information related to the geothermal sector in Europe. The report mentions the opportunities for future collaboration offered by the new ERA-NET Co-fund Action, GEOTHERMICA, which expands the Geothermal ERA-NET consortium and strengthen the participation by guaranteeing coordinated funds for transnational Joint Calls dedicated to demonstration projects. Eventually, an analysis of the stakeholder networks established in the frame of the Geothermal ERA-NET is provided., FP7, {"references":["D3.1 - Report on the state-of-the-art and needs in regarding geothermal data and existing tools to manage them (April 2013) ISBN: 978-9979-68-361-2. https://doi.org/10.5281/zenodo.1182422","D3.2 - Feasibility study for a European Geothermal Platform (October 2013) ISBN: 978-9979-68- 362-9 . https://doi.org/10.5281/zenodo.1182420","EGIP – Pilot Platform (2014). Link: http://egip.igg.cnr.it","Trumpy E., Coro G., Manzella A., Pagano P., Castelli D., Calcagno P., Nador A., Bragasson T., Grellet S. & Siddiqi G. (2015) Building a European geothermal information network using a distributed e- Infrastructure, International Journal of Digital Earth, DOI: 10.1080/17538947.2015.1073378 Link: http://www.tandfonline.com/doi/full/10.1080/17538947.2015.1073378)","Tuning EGIP for target user- EGIP Joint Action report (January 2016) ISBN 978-9979-68-389-6. https://doi.org/10.5281/zenodo.1182416","EGIP EG report - An overview to prepare the implementation (September 2016). https://doi.org/10.5281/zenodo.1182403"]}

32. Feasibility Study For A European Geothermal Information Platform

Author

Manzella, Adele, Trumpy, Eugenio, and Calcagno, Philippe

Subjects
EGIP, information platform, 13. Climate action, geothermal energy, europe, exploration, 7. Clean energy, non technical
Abstract

This document describes our proposal for the joint implementation of a European Geothermal Information Platform (EGIP). EGIP’s target is to increase the share of potential geothermal energy users - primarily international operators, and surveyors - primarily European bodies. Two appendicies are included in the document. Appendix 1 reports the collect references and links organized by category resulting from the questionnaire set up in task 3.2 and 2.1. Appendix 2 describes the most important technical aspects for EGIP implementation following INSPIRE implementing rules., FP7

33. Report On The Implementation Of The European Geothermal Information Platform

Author

Trumpy, Eugenio and Manzella, Adele

Subjects
EGIP, information platform, 13. Climate action, geothermal energy, europe, exploration, 7. Clean energy, non technical
Abstract

This report describes the principle activities related to Work Package 3 of the Geothermal ERA-NET project performed in the last two years (mid 2014 – September 2016). All the tasks carried out in this timeframe are here summarized highlighting the main outcomes. The included sections are dedicated to the pilot of EGIP released in 2014, the survey on EGIP completed in 2015 and the overview document on EGIP implementation currently being finalized. The report is concluded with a final section which highlights the main outcomes, the open issues and sketch the next steps., FP7, {"references":["D3.1 - Report on the state-of-the-art and needs in regarding geothermal data and existing tools to manage them. ISBN: 978-9979-68-361-2","D3.2 - Feasibility study for a European Geothermal Platform. ISBN: 978-9979-68-362-9","Games rules. Link: http://egip.igg.cnr.it/index.php/join-egip/328-games-rules)","EGIP data model. Link: http://egip.igg.cnr.it/index.php/join-egip/327-egip-data-model","EGIP xsd schema. http://egip.igg.cnr.it/index.php/join-egip/329-egip-xsd","Trumpy et al., 2015, Building a European geothermal information network using a distributed e- Infrastructure, International Journal of Digital Earth, DOI: 10.1080/17538947.2015.1073378","Report: Tuning EGIP for target user. ISBN 978-9979-68-389-6","Report: European Geothermal Information Platform - EGIP - An overview to prepare the implementation. ISBN 978-9979-68-395-7"]}

34. Analysis report with proposals on future programme collaboration and stakeholder collaboration

Author

Manzella, Adele and Breembroek, Gerdi

Subjects
EGIP, OpERA, 13. Climate action, geothermal energy, joint calls, joint activities, europe, 7. Clean energy, co-fund action, non technical
Abstract

This reports describes the learning from the Joint Activities in the frame of Geothermal ERA-NET and thestrategies to develop further funding procedures. The main focus is on the activities for establishing a web-based knowledge transfer system related to operational issues of geothermal installations in Europe, the so-called OpERA-pedia, and those related to the implementation of the European Geothermal InformationPlatform, EGIP, for collecting and retrieving technical and non-technical information related to the geothermal sector in Europe. The report mentions the opportunities for future collaboration offered by thenew ERA-NET Co-fund Action, GEOTHERMICA, which expands the Geothermal ERA-NET consortiumand strengthen the participation by guaranteeing coordinated funds for transnational Joint Calls dedicated todemonstration projects. Eventually, an analysis of the stakeholder networks established in the frame of theGeothermal ERA-NET is provided.

35. First Fact Sheet

Author

Manzella, Adele, Trumpy, Eugenio, and Bertani, Ruggero

Subjects
geophysics, geothermal energy, italy, exploration, 7. Clean energy, dissemination, larderello, drilling, non technical
Abstract

The “Drilling in dEep, Super-CRitical AMBient of continentaL Europe” (DESCRAMBLE) project is meant to drill in continental-crust, super-critical geothermal conditions, to test and demonstrate novel drilling techniques to control gas emissions, the aggressive environment and the high temperature/pressure expected from the deep fluids and to characterize the chemical and thermo-physical condition of the reservoir. The experiment is realized in Larderello, Italy, where supercritical resources are expected within a depth of 4 km., H2020

36. Proposals for transnational activities

Author

Manzella, Adele and Trumpy, Eugenio

Subjects
EGIP, OpERA, 13. Climate action, knowledge exchange, geothermal energy, joint activities, europe, tansnational, 7. Clean energy, co-fund action, non technical
Abstract

This report deals with the organization of transnational activities, after their definition in WP4. In theJA1 Phase, in the form of Working Group preparatory activities, a number of workshops, surveys andreports were organized, and their results were discussed in two Geothermal ERA-NET projectmeetings: a main one held in Brussels on October 2015, and second one held in Ankara, Turkey, onFebruary 2016. During the JA1 activities and these meetings, the consortium partners defined whatactivities could pass to the advanced phase of implementation (JA2) having a budget for doing so, orwere continuing as JA1 activity providing technical reports. Of the seven themes implemented as JA1activities, also in consideration of time and budget limits, only two JA1 activities (EGIP for theestablishment of a European Geothermal Information Platform and OpERA related to operationalissues in geothermal installation) proposed a follow up in the form of co-funded Calls. For EGIP,some countries found a common interest in developing a professional and appealing front-end for thepilot platform whose structure and content has been developed in kind. For OpERA, the proposal thatfound the interest of various countries regarded the organization of a handbook related to operationalissues in geothermal installations, named OpERA-pedia, to be published on the Geothermal ERA-NET webpage and constituting a platform for knowledge exchange. These proposed JA2 activitiesresulted suitable for Calls for Tenders. Administrative issues, including the difficulties of somecountry to organize a common Call for Tenders, let the EGIP proposal to be dropped, whereas theOpERA-pedia will be organized as a simultaneous Call for Tender in the participating countries. Indeed, the JA1 activities and the experience gained in the Geothermal ERA-NET project hasstrengthen the transnational partnership by planning concrete joint activities as testified by the settingup of a new proposal for a geothermal ERA-NET in the form of Co-funded action, to enhancecooperation potential in the field of geothermal.

37. Abstract Book | Image Mid-Term Conference

Author

Manzella, Adele and Nardini, Isabella

Subjects
abstract, 13. Climate action, integrated methods, geothermal energy, Pisa, conference book, structural geology, exploration, vulcanology
Abstract

Collection of abstracts from the Mid-Term Conference of the IMAGE project, 12-13 October 2015. Project Coordinator: Jan Hopman, TNO, Utrecht, NL Scientific Committee: David Bruhn, Helmholtz Centre, GFZ German Research Centre for Geosciences, Potsdam, D. Chrystel Dezayes, BRGM, Department of Geothermal Energy, Georessources Division, Orléans, F. Ólafur G. Flóvenz, ÍSOR, Iceland GeoSurvey, Reykjavík, IS. Gu.mundur Ómar Fri.leifsson, HS Orka hf, Reykjanesbær, IS. Domenico Liotta, Dipartimento di Scienze della Terra e Geoambientali, Università di Bari, I. Adele Manzella, CNR-Institute of Geosciences and Earth Resources, Pisa, I. Gylfi Páll Hersir, ÍSOR, Iceland GeoSurvey, Reykjavík, IS. Giovanni Ruggieri, CNR-Institute of Geosciences and Earth Resources, Firenze, I. Jan Diederik van Wees, TNO, Utrecht, NL. Editors: ADELE MANZELLA and ISABELLA NARDINI* CNR-Institute of Geosciences and Earth Resources, Via Moruzzi 1 – 56124 Pisa, Italy. EDIZIONI CNR ISBN 9788879580267 *contact person: isabella.nardini@igg.cnr.it Edizioni CNR ISBN 9788879580267, FP7

38. Feasibility Study for a European Geothermal Information Platform

Author

Manzella, Adele, Trumpy, Eugenio, and Calcagno, Philippe

Subjects
EGIP, information platform, 13. Climate action, geothermal energy, europe, exploration, 7. Clean energy, non technical
Abstract

This document describes our proposal for the joint implementation of a European GeothermalInformation Platform (EGIP). EGIP’s target is to increase the share of potential geothermalenergy users - primarily international operators, and surveyors - primarily European bodies.Two appendicies are included in the document. Appendix 1 reports the collect references andlinks organized by category resulting from the questionnaire set up in task 3.2 and 2.1.Appendix 2 describes the most important technical aspects for EGIP implementationfollowing INSPIRE implementing rules.

39. Image-D5.05 Database: Potential Supercritical Conditions

Author

Manzella, Adele

Subjects
high-temperature systems, favourability, 13. Climate action, geophysics, deep geothermal, exploration, GIS, 7. Clean energy, indicators, drilling
Abstract

Very high-temperature reservoirs are a possible target for future geothermal exploration either through the direct exploitation of super-critical fluids or as a potential high-temperature reservoir for Enhanced Geothermal Systems. By exploiting subsurface fluids at super-critical conditions, i.e. high temperature (>375 °C) and high pressure (>22 MPa), the energy output per well will increase by a factor of ~10. This will reduce development costs by decreasing the number of wells needed (IEA Technology Roadmap 2011). In order to contribute to the EU strategic energy and climate targets for 2020 and 2050 by fostering increased growth in the geothermal energy market through enhanced awareness of the potential of geothermal energy production, a database of potential supercritical resources has been launched by the IMAGE project. Superhot and supercritical resources are expected in the surrounding of still hot magmatic intrusions in the crust. A large part of the IMAGE activity focused on understanding what are the favorable conditions at a few km depth for shallow magmatic emplacement, beside improving exploration and investigation techniques for their detection and the related hot water circulation. In a typical crust with an average thermal gradient of the order of 30-35 °C/km the critical temperature of a brine (temperature above 450 °C) is reached at depth greater than 12-15 km. However, in many sites around the world (e.g. Larderello and Phlegraean Fields in Italy, Nesjavellir in Iceland, The Geysers in California) where exploratory boreholes were drilled in high-temperaturegeothermal system (T > 370 °C), reservoir pressures above supercritical conditions (>22.1 MPa) were encountered. These evidences confirm that geothermal reservoirs in supercritical conditions, both in temperature and pressure, exist in the vicinity of cooling magmatic intrusions. Volcanic rifts, extensional basins and/or subduction zones with related shallow crustal magma emplacements, are the more promising environments in which supercritical conditions may be found in the upper to middle crust levels, The compilation of a European database of the favourable indicators of the presence of supercritical geothermal resources has been a main task in the IMAGE project. The objective is to define areas in Europe where supercritical fluids occur at a drillable depth with a manageable chemistry composition can be found. Where do we find fluids at 4-5 km depth with a temperature exceeding 400 °C? In various regions in Europe, including Iceland, Italy, Azores, Montserrat, Canary Island. What characterizes these areas? Can we find other areas with similar features at greater depth? We focus on Iceland, where these resources have been searched and studied in the last decade. We used the experience of research in Larderello, described in detail in other IMAGE deliverables (e.g. D5.01), to look for indicators applicable over broad areas, in search of potential supercritical resources in continental Europe. Since temperature is the key parameter controlling the presence of supercritical reservoirs at (relatively) shallow depth, mapping of supercritical resources was mainly driven by thermal models derived from crustal and lithospheric constraints and data interpolation from available deep wells. Other information providing indirect indication of crustal thinning and shallow magmatic emplacement have been searched and analyzed. In particular, we mapped the following indicators: the depth of 400 °C isotherm; the MOHO depth and crustal thickness; the earthquake density combined with the estimated depth of the Brittle-Ductile Transition in Europe. Other interesting indicators, e.g. He3/He4 ratio values from which fluids of crustal origin may be inferred, or Curie Point depth that refers to deep temperature regime, are available only for local areas, and are too restricted to be of use at regional and European scale. The location of recent (Pleistocene-Holocene) volcanism, also dispersed, was mapped since it provides useful information, but was not used in the computation of final maps. After defining the indicators, their spatial correlation was established by Geographic Information System (GIS) models, and a database was organized. By prioritizing favourable conditions using GIS spatial analysis methods, the “favourability” map of geothermal resources at supercritical condition was then obtained. It provides a clear overview of the distribution of potential resources in Europe, based on analytical data., FP7

40. First FACT SHEET

Author

Manzella, Adele, Trumpy, Eugenio, and Bertani, Ruggero

Subjects
geophysics, geothermal energy, italy, exploration, 7. Clean energy, dissemination, larderello, drilling, non technical
Abstract

The “Drilling in dEep, Super-CRitical AMBient of continentaL Europe” (DESCRAMBLE) project is meantto drill in continental-crust, super-critical geothermal conditions, to test and demonstrate novel drillingtechniques to control gas emissions, the aggressive environment and the high temperature/pressure expectedfrom the deep fluids and to characterize the chemical and thermo-physical condition of the reservoir. Theexperiment is realized in Larderello, Italy, where supercritical resources are expected within a depth of 4 km.

41. Report on the implementation of the European Geothermal Information Platform

Author

Trumpy, Eugenio and Manzella, Adele

Subjects
EGIP, information platform, 13. Climate action, geothermal energy, europe, exploration, 7. Clean energy, non technical
Abstract

This report describes the principle activities related to Work Package 3 of the Geothermal ERA-NET project performedin the last two years (mid 2014 – September 2016). All the tasks carried out in this timeframe are here summarizedhighlighting the main outcomes. The included sections are dedicated to the pilot of EGIP released in 2014, the surveyon EGIP completed in 2015 and the overview document on EGIP implementation currently being finalized. The reportis concluded with a final section which highlights the main outcomes, the open issues and sketch the next steps.

42. Resus Survey Results And Next Steps - Reservoir Sustainability Joint Activity

Author

Trumpy, Eugenio, Manzella, Adele, Calcagno, Philippe, and Lopez, Simon

Subjects
energy sector status, 13. Climate action, geothermal energy, reservoir sustainability, production, europe, 7. Clean energy
Abstract

This report summarizes the results of survey performed in the frame of the Reservoir Sustainability (ReSus) Joint Activity. In particularly the report describes the survey setup and spread among the principal geothermal stakeholders along the European countries participating in the Geothermal ERA-NET project. The answers to each question proposed in the survey are here reported. The report is concluded with a final section which highlights the main outcomes and possible next step., FP7

43. ReSus survey results and next steps - Reservoir Sustainability Joint Activity

Author

Trumpy, Eugenio, Manzella, Adele, Calcagno, Philippe, and Lopez, Simon

Subjects
energy sector status, 13. Climate action, geothermal energy, reservoir sustainability, production, europe, 7. Clean energy
Abstract

This report summarizes the results of survey performed in the frame of the Reservoir Sustainability (ReSus) Joint Activity. In particularly the report describes the survey setup and spread among the principal geothermal stakeholders along the European countries participating in the Geothermal ERA-NET project. The answers to each question proposed in the survey are here reported. The report is concluded with a final section which highlights the main outcomes and possible next step.

44. Technical and non-technical barriers & opportunities

Author

Breembroek, Gerdi, Ramsak, Paul, Manzella, Adele, and Trumpy, Eugenio

Subjects
opportunities, energy sector status, 13. Climate action, barriers, geothermal energy, europe, exploration, 7. Clean energy, non technical
Abstract

This report shows barriers and opportunities for geothermal development in countries,participating in ERANET Geothermal energy. These barriers and opportunities have beenidentified by the participants of ERANET Geothermal energy. They will be an important input in setting up a programme of international collaboration.

45. Robust smooth magnetotelluric transfer functions

Author

Larsen, Jimmy C., Mackie, Randall L., Manzella, Adele, Fiordelisi, Adolfo, and Rieven, Shirley

Abstract

Robust estimates of the magnetotelluric (MT) transfer function are found using an iterative reweighted method on time series data corrected for outliers and gaps. The MT transfer function, composed of several analytic functions smoothly varying in frequency, is used to represent the frequency-domain relationship between electric and magnetic time series. The smoothly varying transfer function facilitates identification and removal of electric and magnetic outliers (spikes), construction of the frequency-and time-domain weights used for obtaining robust smooth and band-averaged estimates, and separation of the time series into MT and correlated noise signals if a remote site exists that is free of the correlated noise. Errors in the transfer function are calculated using jackknife estimates of the solution covariance. The method is tested on: time series from a relatively clean MT site in central California; a test time series based on Tucson magnetic time series plus synthetic noise for a given transfer function; and time series from the Larderello geothermal region in central Italy where there are strong signals from d.c. electrified railways.

Published
1996
Full Text
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46. Operational issues in Geothermal Energy in Europe - Status and overview

Author

Schreiber, Stephan, Lapanje, Andrej, Ramsak, Paul, Breembroek, Gerdi, Berg Lorenzen, Søren, Bertani, Ruggiero, Boissavy, Christian, Eichinger, Florian, Götzl, Gregor, Hartog, Niels, Haslinger, Edith, van der Hout, Martin, Ingólfsson, Hjalti Páll, Karaöz, Kaan, Küperkoch, Ludger, Manzella, Adele, Nador, Annamaria, Rauch, Andreas, Regenspurg, Simona, Rman, Nina, Schindler, Marion, Szanyi, János, Vitaller, Ana Vallejo, and Veldkamp, Hans

Subjects
energy sector status, geothermal energy, operational issues, production, europe, 7. Clean energy
Abstract

Based on the results of the Geothermal ERA-NET work package (WP) 2 „Information exchange on national incentives and status of geothermal energy“, and WP4 “Development of joint activities”, the topical field of operational issues of geothermal energy installations was identified as one of the main barriers for the development of geothermal energy and as an urgent RD&D need mentioned by most of the participating countries in a ranking process.

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