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| Titel |
Morphology and evolution of sulphuric acid caves in South Italy |
| VerfasserIn |
Ilenia M. D'Angeli, Jo De Waele, Sandro Galdenzi, Giuliana Madonia, Mario Parise, Marco Vattano |
| Konferenz |
EGU General Assembly 2016
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| Medientyp |
Artikel
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| Sprache |
en
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| Digitales Dokument |
PDF |
| Erschienen |
In: GRA - Volume 18 (2016) |
| Datensatznummer |
250133250
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| Publikation (Nr.) |
 EGU/EGU2016-13838.pdf |
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| Zusammenfassung |
| Sulphuric acid speleogenesis (SAS) related to the upwelling of acid water enriched in H2S and CO2 represents an unusual way of cave development. Since meteoric infiltration waters are not necessarily involved in speleogenesis, caves can form without the typical associated karst expressions (i.e. dolines) at the surface.
The main mechanism of sulphuric acid dissolution is the oxidation of H2S (Jones et al., 2015) which can be amplified by bacterial mediation (Engel et al., 2004). In these conditions, carbonate dissolution associated with gypsum replacement, is generally believed to be faster than the normal epigenic one (De Waele et al., 2016).
In Italy several SAS caves have been identified, but only few systems have been studied in detail: Frasassi and Acquasanta Terme (Marche)(Galdenzi et al., 2010), Monte Cucco (Umbria) (Galdenzi & Menichetti, 1995), and Montecchio (Tuscany) (Piccini et al., 2015). Other preliminary studies have been carried out in Calabria (Galdenzi, 2007) and Sicily (De Waele et al., 2016).
Several less studied SAS cave systems located in South Italy, and in particular in Apulia (Santa Cesarea Terme), Sicily (Acqua Fitusa, Acqua Mintina) and Calabria (Mt. Sellaro and Cassano allo Ionio) have been selected in the framework of a PhD thesis on SAS caves and their speleogenesis.
Using both limestone tablet weight loss (Galdenzi et al., 2012) and micro erosion meter (MEM) (Furlani et al., 2010) methods the dissolution rate above and under water in the caves will be quantified. Geomorphological observations, landscape analysis using GIS tools, and the analysis of gypsum and other secondary minerals (alunite and jarosite) (stable isotopes and dating) will help to reconstruct the speleogenetic stages of cave formation. Preliminary microbiological analysis will determine the microbial diversity and ecology in the biofilms.
References
Engel S.A., Stern L.A., Bennett P.C., 2004 – Microbial contributions to cave formation: New insight into sulfuric acid speleogenesis. Geology, 32: 369-372.
De Waele J., Audra P., Madonia G., Vattano M., Plan L., D’Angeli I.M., Bigot J.-Y., Nobécourt J.-C., 2016 - Sulfuric acid speleogenesis (SAS) close to the water table: examples from southern France, Austria, and Sicily. Geomorphology, 253: 452-467.
Furlani S., Cucchi F., Odorico R., 2010 - A new method to study micro-topographical changes in the intertidal zone: one year of TMEM measurements on a limestone removable slab (RRS). Z. Geomorph., 54(2): 137-151.
Galdenzi S., 1997 – Initial geological observations in caves bordering the Sibari plain (southern Italy). J. Cave Karst Stud., 59: 81-86.
Galdenzi S., 2012 - Corrosion of limestone tablets in sulfidic ground-water: measurements and speleogenetic implications. Int. J. Spel., 41(2): 149-159.
Galdenzi S., Menichetti M., 1995 - Occurrence of hypogenic caves in a karst region: examples from central Italy. Environmental Geology, 26: 39-47.
Galdenzi S., Cocchioni F., Filipponi G., Selvaggio R., Scuri S., Morichetti L., Cocchioni M., 2010 - The sulfidic thermal caves of Acquasanta Terme (central Italy). J. Cave Karst Stud. 72(1): 43-58.
Jones, D.S., Polerecky, L., Galdenzi, S., Dempsey, B.A., Macalady, J.L., 2015 - Fate of sulfide in the Frasassi cave system and implications for sulfuric acid speleogenesis. Chemical Geology, 410: 21-27. |
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