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RESEARCH PRODUCT
Regional variations in the chemical and helium–carbon isotope composition of geothermal fluids across Tunisia
Elise FourréE. GaubiFrancesco ParelloSergio CalabreseR. Di NapoliPhilippe Jean-baptisteA. Ben MamouPatrick AllardAlessandro AiuppaAlessandro Aiuppasubject
Tunisia010504 meteorology & atmospheric sciencesEarth scienceGeochemistryAquiferengineering.material010502 geochemistry & geophysics01 natural sciencesMantle (geology)Geochemistry and PetrologyTunisia; Helium isotopes; Carbon isotopes; Geothermal fluids; Groundwaters; Thermal springs[SDU.ENVI]Sciences of the Universe [physics]/Continental interfaces environmentGroundwaterChemical compositionGeothermal gradientComputingMilieux_MISCELLANEOUS0105 earth and related environmental sciences[SDU.OCEAN]Sciences of the Universe [physics]/Ocean Atmospheregeographygeography.geographical_feature_categoryRiftCarbon isotopeThermal springsGeologyHelium isotopeSettore GEO/08 - Geochimica E Vulcanologia13. Climate actionIsotopes of carbonMagmatismengineeringHaliteGeothermal fluidGeologydescription
Abstract Tunisia has numerous thermo-mineral springs. Previous studies have shown that their chemical composition and occurrence are strongly influenced by the regional geology. However little work has been done so far to study the isotopic composition of volatiles associated with these geothermal manifestations. Here, we report on the results of an extensive survey of both natural hot springs and production wells across Tunisia, aimed at investigating the spatial distribution of thermal fluids' geochemical characteristics and He–C isotopic composition. The chemistry of the analyzed samples highlights the heterogeneity of the water mineralization processes in Tunisia, as a consequence of the complex geological and tectonic setting of the country. In terms of chemical composition, we are able to conclude, however, that dissolution of halite and gypsum plays a key control on groundwater chemistry. Helium and carbon isotope systematics confirm the prevalently crustal origin of the volatiles interacting with the aquifer systems, consistent with the absence of any recent magmatism. Most samples are characterized by crustal-type helium ( 3 He/ 4 He in the range 0.02 Ra–0.4 Ra) associated with a CO 2 predominantly metamorphic in origin (with the exception of the Saharan platform where the carbon content is low and mostly organically-derived). In Eastern Tunisia, however, a few samples have He–C isotope compositions which suggest (at least partial) mantle derivation of the dissolved gas phase : the 3 He/ 4 He ratio reaches 2.4 Ra (corresponding to 30% of mantle-derived helium) at the Ain Garci site, a CO 2 rich mineral spring located some 30 km south of the city of Zaghouan. This mantle signature is consistent with the fact that the Pelagian Block, to which Eastern Tunisia belongs, has been deeply affected by extensional and transtensional tectonics since the opening of the Tethys, a process which is still ongoing in the Sicily channel (Pantelleria Rift). As a whole however, our results show that the Italian mantle gas anomaly only marginally extends to Northwestern Africa.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-09-01 | Chemical Geology |