Better constraining silica-enthalpy mixing models in a setting of two separate (karst and non-karst) dilution regimes

It would be possible to elucidate an ambiguity associated with the “silica-enthalpy mixing models” geothermometric technique, provided that an independent estimate was obtained concerning the enthalpy and the dissolved SiO 2 content of the hot end-member involved in a mixture between two liquid-phas...

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Bibliographic Details
Published in:Hydrogeology journal 2019-02, Vol.27 (1), p.291-304
Main Authors: Mitrofan, Horia, Marin, Constantin, Povară, Ioan, Ioniţă, Daniela E., Tudorache, Alin, Vişan, Mădălina
Format: Article
Language:English
Subjects:
Aquatic Pollution
Chlorides
Convergence
Dilution
Divers
Earth and Environmental Science
Earth Sciences
Enthalpy
Freshwater
Geology
Geophysics/Geodesy
Geotemperature
Hydrogeology
Hydrology/Water Resources
Hypotheses
Inland water environment
Karst
Liquid phases
Silica
Silicon dioxide
Solutes
Tracers
Vapors
Waste Water Technology
Water Management
Water Pollution Control
Water Quality/Water Pollution
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Summary:It would be possible to elucidate an ambiguity associated with the “silica-enthalpy mixing models” geothermometric technique, provided that an independent estimate was obtained concerning the enthalpy and the dissolved SiO 2 content of the hot end-member involved in a mixture between two liquid-phase groundwaters. This would allow one to ascertain whether or not, prior to mixing with the cold parent-water, the hot end-member had undergone a boiling process. The specificities of the Băile Herculane geothermal system (South Carpathians, Romania) provides an opportunity to solve this uncertainty, in contrast to the majority of the so-far investigated natural settings. Advantage has been taken, in this respect, of the fact that a hot brackish Na-Ca-Cl-type parent-water was found to be involved at this site in two separate mixing settings: one which involved only a diluting fluid that was, itself, chloride-rich, and another one which additionally involved, as a third end-member, karst freshwater. By exploiting the two distinct, and converging, linear mixing trends (obtained from the conservatively-behaving natural tracers Cl − and Na + , as well as reasonably tight correlations between the chloride concentration and the contents of both heat and SiO 2 ), the concerned hot brackish end-member contents of heat (enthalpy) and of conservative solutes were quite accurately assessed. This result enabled independent validation of the “no steam loss” hypothesis, out of various alternative scenarios proposed by the “silica-enthalpy mixing models” technique.
ISSN:1431-2174
1435-0157
DOI:10.1007/s10040-018-1846-7