SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2980473868> ?p ?o ?g. }

Showing items 1 to 100 of ±140 with 100 items per page.

W2980473868 endingPage "440" @default.
W2980473868 startingPage "440" @default.
W2980473868 abstract "Experimental characterization of thermal transport in fractured media through thermal tracer tests is crucial for environmental and industrial applications such as the prediction of geothermal system efficiency. However, such experiments have been poorly achieved in fractured rock due to the low permeability and complexity of these media. We have thus little knowledge about the effect of flow configuration on thermal recovery during thermal tracer tests in such systems. We present here the experimental set up and results of several single-well thermal tracer tests for different flow configurations, from fully convergent to perfect dipole, achieved in a fractured crystalline rock aquifer at the experimental site of Plœmeur (H+ observatory network). The monitoring of temperature using Fiber-Optic Distributed Temperature Sensing (FO-DTS) associated with appropriate data processing allowed to properly highlight the heat inflow in the borehole and to estimate temperature breakthroughs for the different tests. Results show that thermal recovery is mainly controlled by advection processes in convergent flow configuration while in perfect dipole flow field, thermal exchanges with the rock matrix are more important, inducing lower thermal recovery." @default.
W2980473868 created "2019-10-25" @default.
W2980473868 creator A5015206222 @default.
W2980473868 creator A5029316868 @default.
W2980473868 creator A5033313852 @default.
W2980473868 creator A5039397694 @default.
W2980473868 creator A5061402015 @default.
W2980473868 creator A5079802614 @default.
W2980473868 date "2019-10-15" @default.
W2980473868 modified "2023-10-17" @default.
W2980473868 title "Dipole and Convergent Single-Well Thermal Tracer Tests for Characterizing the Effect of Flow Configuration on Thermal Recovery" @default.
W2980473868 cites W1531947643 @default.
W2980473868 cites W1550010211 @default.
W2980473868 cites W1607054860 @default.
W2980473868 cites W1693802668 @default.
W2980473868 cites W1838857989 @default.
W2980473868 cites W1971686709 @default.
W2980473868 cites W1975579778 @default.
W2980473868 cites W1978305759 @default.
W2980473868 cites W1988659304 @default.
W2980473868 cites W2008981917 @default.
W2980473868 cites W2010564888 @default.
W2980473868 cites W2022683096 @default.
W2980473868 cites W2030030000 @default.
W2980473868 cites W2032981359 @default.
W2980473868 cites W2036999289 @default.
W2980473868 cites W2037202728 @default.
W2980473868 cites W2056711963 @default.
W2980473868 cites W2061508544 @default.
W2980473868 cites W2069748150 @default.
W2980473868 cites W2071580582 @default.
W2980473868 cites W2076041674 @default.
W2980473868 cites W2079382435 @default.
W2980473868 cites W2087952853 @default.
W2980473868 cites W2093882316 @default.
W2980473868 cites W2097685787 @default.
W2980473868 cites W2109711869 @default.
W2980473868 cites W2118560452 @default.
W2980473868 cites W2120941781 @default.
W2980473868 cites W2131604286 @default.
W2980473868 cites W2137820449 @default.
W2980473868 cites W2146904562 @default.
W2980473868 cites W2149710775 @default.
W2980473868 cites W2151226756 @default.
W2980473868 cites W2153127411 @default.
W2980473868 cites W2155106710 @default.
W2980473868 cites W2161492607 @default.
W2980473868 cites W2278652265 @default.
W2980473868 cites W2330263860 @default.
W2980473868 cites W2338490158 @default.
W2980473868 cites W2470987681 @default.
W2980473868 cites W2476262587 @default.
W2980473868 cites W2564209525 @default.
W2980473868 cites W2586749176 @default.
W2980473868 cites W2592897157 @default.
W2980473868 cites W2754235722 @default.
W2980473868 cites W2901126407 @default.
W2980473868 cites W2902951602 @default.
W2980473868 cites W2975215696 @default.
W2980473868 doi "https://doi.org/10.3390/geosciences9100440" @default.
W2980473868 hasPublicationYear "2019" @default.
W2980473868 type Work @default.
W2980473868 sameAs 2980473868 @default.
W2980473868 citedByCount "4" @default.
W2980473868 countsByYear W29804738682020 @default.
W2980473868 countsByYear W29804738682021 @default.
W2980473868 countsByYear W29804738682023 @default.
W2980473868 crossrefType "journal-article" @default.
W2980473868 hasAuthorship W2980473868A5015206222 @default.
W2980473868 hasAuthorship W2980473868A5029316868 @default.
W2980473868 hasAuthorship W2980473868A5033313852 @default.
W2980473868 hasAuthorship W2980473868A5039397694 @default.
W2980473868 hasAuthorship W2980473868A5061402015 @default.
W2980473868 hasAuthorship W2980473868A5079802614 @default.
W2980473868 hasBestOaLocation W29804738681 @default.
W2980473868 hasConcept C111766609 @default.
W2980473868 hasConcept C121332964 @default.
W2980473868 hasConcept C127313418 @default.
W2980473868 hasConcept C150560799 @default.
W2980473868 hasConcept C153294291 @default.
W2980473868 hasConcept C173523689 @default.
W2980473868 hasConcept C178790620 @default.
W2980473868 hasConcept C185544564 @default.
W2980473868 hasConcept C185592680 @default.
W2980473868 hasConcept C187320778 @default.
W2980473868 hasConcept C192562407 @default.
W2980473868 hasConcept C204530211 @default.
W2980473868 hasConcept C2776132308 @default.
W2980473868 hasConcept C2778863792 @default.
W2980473868 hasConcept C38349280 @default.
W2980473868 hasConcept C5072599 @default.
W2980473868 hasConcept C57879066 @default.
W2980473868 hasConcept C8058405 @default.
W2980473868 hasConcept C97355855 @default.
W2980473868 hasConceptScore W2980473868C111766609 @default.
W2980473868 hasConceptScore W2980473868C121332964 @default.
W2980473868 hasConceptScore W2980473868C127313418 @default.
W2980473868 hasConceptScore W2980473868C150560799 @default.