06737nam 2201837z- 450 991063998660332120240911075446.03-0365-6053-X(CKB)5470000001633488(oapen)https://directory.doabooks.org/handle/20.500.12854/95887(EXLCZ)99547000000163348820202301d2022 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierEnhanced Geothermal Systems and other Deep Geothermal Applications throughout Europe: The MEET ProjectBaselMDPI - Multidisciplinary Digital Publishing Institute20221 electronic resource (544 p.)3-0365-6054-8 The MEET Special Issue aims at showing the gains in geothermal energy that can be achieved using a variety of techniques, depending on the geological setting of the underground. Among the list of exploitation concepts, enhanced geothermal systems (EGS) are particularly interesting, as their application is much less dependent of the underground setting, allowing, in turn, a large geographical deployment and market penetration in Europe. The challenges of EGS are multiple in terms of investment costs, the testing of novel reservoir exploitation approaches with an inherent risk of induced seismicity, and the presence of aggressive geothermal brines, damaging infrastructures. The conversion of oil wells or coproduction of heat or electricity together with oil is also addressed. This Special Issue summarizes the output of the H2020 MEET project based on laboratory experiments, geological field works on high-quality analogues, advanced reservoir modeling, the development of a decision-maker tool for investors and specific demonstration activities, such as chemical stimulation or the innovative monitoring of deep geothermal wells, and the production of electrical power via small-scale binary technology tested in various geological contexts in Europe.Enhanced Geothermal Systems and other Deep Geothermal Applications throughout EuropeResearch & information: generalbicsscIwantja / Indulkana / Granite Downs (SA Central Australia SG53-09)aiatsispSoultz-Sous-Forêtsgeothermal siteheat exchangerscalessulfatessulfidesAs and Sb-bearing galenacrystal growthcrystal shapesfracture networkDeath ValleyNoble Hillspower law distributionmultiscale analysisgeothermal reservoir characterizationNoble Hills graniteOwlshead Mountains granitemetamorphic gradefluid/rock interactionsnewly formed mineralselement variationsgeothermal reservoirdeep geothermal energyEGSVariscan fold-and-thrust beltdistrict heating and coolingeconomic indicatorsCO2 abatement costsensitivity analysisfracturing processesfluid circulationgranite alterationlow to moderate regional strainblind geothermal systemcompositional anomalieshierarchical clusteringself-organizing mapsunconventional reservoirsgeothermalOVSPwell seismic datafaultfracturegeothermal deriskingFWInumerical modellinginversionimagingpermeabilityfluid-rock interactionsslatetemperaturetime-dependentpressure solutiondissolutionSoultz-sous-Forêtshydro-thermal modelingconversionclusteringupscalingheatelectricityscenariosLCOELCOHNPVCO2 emissionsUpper Rhine Grabengeothermal brinescalingmetal sulfidesthermodynamickineticsoilcorrosiongeologystressfluid pressureMohr diagramsfracturinggreywackesslatesdeep geothermal reservoirstructural modelthermo-hydraulic simulationsMEET H2020 projectfracture network variabilitygranitespacing distributionfracture intensity P10well placementCO2-EGSwater-EGSdiscrete fracture networksTHM modelingenhanced geothermal systems (EGS)fractured granitecore flooding experimentsautoclave experimentsCornubian BatholithEnhanced Geothermal Systems (EGS)Variscan rocksquartziteclaystonegraywackegougefracture transmissivityeffective stressUnited Downshydraulic stimulationequivalent permeability fieldexposed analogueenhanced geothermal systemfracturesResearch & information: generalLedésert Béatrice Aedt1278526Hébert Ronan LedtTrullenque GhislainedtGenter AlbertedtDalmais EléonoreedtHérisson JeanedtLedésert Béatrice AothHébert Ronan LothTrullenque GhislainothGenter AlbertothDalmais EléonoreothHérisson JeanothBOOK9910639986603321Enhanced Geothermal Systems and other Deep Geothermal Applications throughout Europe: The MEET Project3013402UNINA