Your search keyword '"D'ALESSANDRO W"' showing total 22 results

1. The Domuyo volcanic system: An enormous geothermal resource in Argentine Patagonia

Author

Chiodini G.[1], Liccioli C. [2, Vaselli O. [2, Calabrese S. [5], Tassi F.[3, Caliro S.[1], Caselli A. [2], Agusto M. [6], D'Alessandro W. [7], Chiodini, G, Liccioli, C, Vaselli, O, Calabrese, S, Tassi, F, Caliro, S, Caselli, A, Agusto, M, and D'Alessandro, W

Subjects

Geothermal potential, Geochemistry, Hydrothermal circulation, Argentine Patagonia, Water geochemistry, Ciencias de la Tierra y relacionadas con el Medio Ambiente, Vulcanología, Geochemistry and Petrology, Boiling, Geothermal gradient, Hydrology, geography, Domuyo volcano, geography.geographical_feature_category, water geochemistry, geothermal potential, Advection, business.industry, Settore GEO/08 - Geochimica E Vulcanologia, Domuyo volcano, Argentine, Patagonia, Geothermal potential, Water geochemistry, Geophysics, Volcano, Heat flux, business, CIENCIAS NATURALES Y EXACTAS, Thermal energy, Geology, Thermal fluids

Abstract

Fil: Chiodini, Giovanni. Istituto Nazionale Di Geofisica E Vulcanologia. Italia. Fil: Liccioli, Caterina. Universidad Nacional de Rio Negro. Instituto de Investigaciones en Paleobiologia y Geologia; Argentina. Río Negro, Argentina Fil: Vaselli, Orlando. Universita Degli Studi Di Firenze; Italia Fil: Calabrese, Sergio. Università di Palermo; Italia Fil: Tassi, Franco. Universita Degli Studi Di Firenze; Italia Fil: Caliro, Stefano. Istituto Nazionale Di Geofisica E Vulcanologia; Italia Fil: Caselli, Alberto Tomás Universidad Nacional de Rio Negro. Instituto de Investigaciones en Paleobiologia y Geologia; Argentina. Río Negro, Argentina Fil: Agusto, Mariano R. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina Fil: D'alessandro, Walter. Istituto Nazionale Di Geofisica E Vulcanologia; Italia Fil: Liccioli, Caterina. Consejo Nacional de Investigaciones Científicas y Técnicas. Río Negro, Argentina. Fil: Caselli, Alberto Tomás Consejo Nacional de Investigaciones Científicas y Técnicas. Río Negro, Argentina. A geochemical survey of the main thermal waters discharging in the southwestern part of the Domuyo volcanic complex (Argentina), where the latest volcanic activity dates to 0.11 Ma, has highlighted the extraordinarily high heat loss from this remote site in Patagonia. The thermal water discharges are mostly Na-Cl in composition and have TDS values up to 3.78 g L− 1 (El Humazo). A simple hydrogeochemical approach shows that 1,100 to 1,300 kg s− 1 of boiling waters, which have been affected by shallow steam separation, flow into the main drainage of the area (Rio Varvarco). A dramatic increase of the most conservative species such as Na, Cl and Li from the Rio Varvarco from upstream to downstream was observed and related solely to the contribution of hydrothermal fluids. The equilibrium temperatures of the discharging thermal fluids, calculated on the basis of the Na-K-Mg geothermometer, are between 190 °C and 230 °C. If we refer to a liquid originally at 220 °C (enthalpy = 944 J g− 1), the thermal energy release can be estimated as high as 1.1 ± 0.2 GW, a value that is much higher than the natural release of heat in other important geothermal fields worldwide, e.g., Mutnovsky (Russia), Wairakei (New Zealand) and Lassen Peak (USA). This value is the second highest measured advective heat flux from any hydrothermal system on Earth after Yellowstone. A geochemical survey of the main thermal waters discharging in the southwestern part of the Domuyo volcanic complex (Argentina), where the latest volcanic activity dates to 0.11 Ma, has highlighted the extraordinarily high heat loss from this remote site in Patagonia. The thermal water discharges are mostly Na-Cl in composition and have TDS values up to 3.78 g L− 1 (El Humazo). A simple hydrogeochemical approach shows that 1,100 to 1,300 kg s− 1 of boiling waters, which have been affected by shallow steam separation, flow into the main drainage of the area (Rio Varvarco). A dramatic increase of the most conservative species such as Na, Cl and Li from the Rio Varvarco from upstream to downstream was observed and related solely to the contribution of hydrothermal fluids. The equilibrium temperatures of the discharging thermal fluids, calculated on the basis of the Na-K-Mg geothermometer, are between 190 °C and 230 °C. If we refer to a liquid originally at 220 °C (enthalpy = 944 J g− 1), the thermal energy release can be estimated as high as 1.1 ± 0.2 GW, a value that is much higher than the natural release of heat in other important geothermal fields worldwide, e.g., Mutnovsky (Russia), Wairakei (New Zealand) and Lassen Peak (USA). This value is the second highest measured advective heat flux from any hydrothermal system on Earth after Yellowstone.

Published

2014

2. A new approach for the measurement of gaseous elemental mercury (GEM) and H2S in air from anthropogenic and natural sources: Examples from Mt. Amiata (Siena, Central Italy) and Solfatara Crater (Campi Flegrei, Southern Italy)

Author

Cabassi J.[1, Tassi F.[1, 2] Venturi S.[1, Calabrese S.[3], Capecchiacci F.[1, D'Alessandro W.[4], Vaselli O. [1, Cabassi, Jacopo, Tassi, Franco, Venturi, Stefania, Calabrese, Sergio, Capecchiacci, Francesco, D'Alessandro, Walter, and Vaselli, Orlando

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Gaseous contaminants, Limit value, Mineralogy, Elemental mercury, GEM and H2S, 010501 environmental sciences, 01 natural sciences, Hydrothermal circulation, Gas analyzer, Wind speed, Impact crater, Volcano, Geochemistry and Petrology, Solfatara crater, Gaseous contaminant, Economic Geology, Real-time measurements, Real-time measurement, Geothermal gradient, Mt. Amiata, Geology, 0105 earth and related environmental sciences

Abstract

Real-time measurements of GEM and H2S discharged from natural and anthropogenic sources are a valuable tool to investigate the dispersion dynamics of these contaminants in air. In this study, a new approach to measure GEM and H2S concentrations in air, carried out by coupling a portable Zeeman atomic absorption spectrometer with high frequency modulation of light polarization (Lumex RA-915M) and a pulsed fluorescence gas analyzer (Thermo Scientific Model 450i), was applied to two distinct areas: (i) in the surroundings of Piancastagnaio (Siena, Central Italy), located in the eastern flanks of Mt. Amiata (a 200,000Âyears old volcano), where three geothermal plants are operating and whose exhaust gases are dispersed in the atmosphere after passing through the turbines and an abatement system to mitigate the environmental impact on air, and (ii) at Solfatara Crater (Campi Flegrei, Southern Italy), a volcanic apparatus characterized by intense hydrothermal activity. In 2014, seven GEM and H2S surveys were carried out in the two areas along pre-defined pathways performed by car at both the study sites. The lowest and highest recorded GEM and H2S concentrations at Piancastagnaio were up to 194 and 77Âng/m3, respectively, whilst at Solfatara Crater were up to 690 and 3392Âμg/m3, respectively. Although the GEM concentrations at Piancastagnaio were lower than the limit value recommended by local regulations for outdoor environment (300Âng/m3), they were almost one order of magnitude higher than the GEM background both in Tuscany (~Â3.5Âng/m3) and Mt. Amiata (3–5Âng/m3), suggesting that the main source of GEM was likely related to the geothermal plants. At Solfatara Crater, the highest GEM values were recognized in proximity of the main fumarolic gas discharges. As far as the H2S concentrations are concerned, the guideline value of 150Âμg/m3, recommended by WHO (2000), was frequently overcome in the study areas. Dot (in the surroundings of Piancastagnaio) and contour (at Solfatara Crater) maps for GEM and H2S concentrations built for each survey highlighted the important effects played by the meteorological parameters, the latter being measured by a Davis® Vantage Vue weather station. In particular, the GEM and H2S plumes were strongly affected by the wind speed and direction that were able to modify the dispersion of the two parameters in air in a matter of hours, indicating that the proposed analytical approach is able to produce a more realistic picture of the distribution of these air pollutants than that provided by using passive traps. Finally, the H2S/GEM ratio, calculated by normalizing the measured GEM and H2S concentrations to their highest values (nH2S/GEM), was used as a good proxy for the chemical-physical processes that these two gas species can suffer once emitted in the air. In particular, H2S resulted to be more affected by secondary processes than GEM, possibly related to photochemical oxidation reactions.

Published

2017

3. Chemical characterisation of the gases released at Gyali Island, Dodecanese, Greece and preliminary estimation of the CO2 output

Author

Antonina Lisa Gagliano, Lorenza Li Vigni, Giovannella Pecoraino, Walter D'Alessandro, Manfredi Longo, Sergio Calabrese, Konstantinos Kyriakopoulos, Kyriaki Daskalopoulou, Daskalopoulou K., Calabrese S., Gagliano A.L., Kyriakopoulos K., Li Vigni L., Longo M., Pecoraino G., and D'Alessandro W.

Subjects

Shore, geography, geography.geographical_feature_category, Volcanic arc, Geochemistry, chemistry.chemical_element, Geology, 010502 geochemistry & geophysics, 01 natural sciences, Hydrothermal circulation, Methane, Settore GEO/08 - Geochimica E Vulcanologia, Carbon degassing, Flux measurements, SAAVA, chemistry.chemical_compound, chemistry, Volcano, Carbon dioxide, General Earth and Planetary Sciences, Carbon, 0105 earth and related environmental sciences

Abstract

Greece belongs to the most geodynamically active regions of the world and as such, it has to be considered an area of intense geogenic degassing. In terms of carbon, the territory is characterized by the high hydrothermal and volcanic activity of the South Aegean Active Volcanic Arc (SAAVA), and by widespread geological seeps of buried carbon dioxide and methane. In the present work, we investigate the island of Gyali located in the volcanic system Kos-Gyali-Nisyros. Nine gas samples have been collected on the island of Gyali in areas found both on land, in a small lake (∼2000 m2) along its beach, and in the sea close to the shore at shallow depths (

Published

2021

4. Gas geochemistry and CO2 output estimation at the island of Milos, Greece

Author

Antonina Lisa Gagliano, Sergio Calabrese, Konstantinos Hantzis, Manfredi Longo, Konstantinos Kyriakopoulos, Kyriaki Daskalopoulou, Walter D'Alessandro, and Daskalopoulou K., Gagliano A.L., Calabrese S., Longo M., Hantzis K., Kyriakopoulos K., D'Alessandro W.

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Volcanic arc, Stable isotope ratio, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Hydrothermal circulation, Mantle (geology), Methane, Settore GEO/08 - Geochimica E Vulcanologia, chemistry.chemical_compound, Geophysics, Hydrothermal gases, Stable isotopes, Geogenic degassing, Carbon dioxide, Volcano, chemistry, Geochemistry and Petrology, Carbon dioxide, Geothermal gradient, Geology, 0105 earth and related environmental sciences

Abstract

Twenty gas samples have been collected from the natural gas manifestations of Milos Island, the majority of which is found underwater along its coast. Furthermore, three anomalous degassing fumarolic areas (Kalamos, Paleochori and Adamas) have been recognized on-land. Almost all the gases are CO2-dominated with CO2 ranging from 88 to 99% vol for the samples taken underwater, while the on-land manifestations show a wider range (15–98%) due to air contamination. Methane reaches up to 1.0% vol, H2 up to 3.2% vol and H2S up to 3.5% vol indicating a hydrothermal origin of the gases. The isotope composition of He points out to mantle contributions up to 45%, while the C-isotope composition of CO2 (from −1.9 to +1.3‰ vs. V-PDB with most of the values around −0.5‰) suggests a prevailing limestone origin. Isotope composition of CH4, ranging from −18.4 to −5.0‰ vs. V-PDB for C and from −295 to +7‰ vs. V-SMOW for H, points to a geothermal origin with sometimes evident secondary oxidation processes. Additionally, CO2-flux measurements showed high values in the three fumarolic areas (up to 1100, 1500 and 8000 g/m2/d at Kalamos, Paleochori and Adamas respectively) with the highest CO2-flux values (up to about 23,000 g/m2/d) being measured in the sea at Kanavas with a floating chamber. The south-western part of the island was covered with a lower density prospection revealing only few anomalous CO2 flux values (up to 650 g/m2/d). The total output of the island (30.5 t/d) is typical of quiescent closed-conduit volcanoes and comparable to the other volcanic/geothermal systems of the south Aegean active volcanic arc (Nisyros, Kos, Nea Kameni, Methana and Sousaki).

Published

2018

5. Geochemical characterisation of the alkaline and hyperalkaline groundwater in the Othrys Ophiolite Massif, central Greece

Author

Francesco Parello, Sergio Calabrese, Kyriaki Daskalopoulou, Lorenza Li Vigni, Walter D'Alessandro, Li Vigni L., Daskalopoulou K., Calabrese S., Parello F., and D'Alessandro W.

Subjects

geography, geography.geographical_feature_category, Isotope, Chemistry, Stable isotope ratio, Outcrop, Geology, Massif, 010502 geochemistry & geophysics, Ophiolite, 01 natural sciences, Continental serpentinization, Hydrogeochemistry, Methane, Stable isotopes, Trace elements, Methane, Abiogenic petroleum origin, Settore GEO/08 - Geochimica E Vulcanologia, chemistry.chemical_compound, Environmental chemistry, General Earth and Planetary Sciences, Groundwater, 0105 earth and related environmental sciences

Abstract

The complex geology of Greece includes two important parallel running ophiolitic belts. The Othrys Massif in central Greece belongs to the westernmost of them. In the current study, 33 water samples from cold hyperalkaline and hypothermal (T < 40°C) alkaline springs and 30 gas samples (either dissolved or free) were collected at 17 different sites in and around this wide ophiolite outcrop, aiming to determine the origin of fluids and evidence gas-water-rock interaction processes taking place in the area. Water samples were analysed for their chemical (major ions and trace elements) and isotope (d18O-H2O, d2H-H2O) composition. They can be subdivided into alkaline (pH 11 and Ca-OH composition). Trace elements generally showed very low concentrations and mostly inversely correlated with pH. Gases were analysed for their chemical (He, Ne, Ar, H2, O2, N2, CH4, C2H6, CO2 and H2S) and isotope (d13C-CH4, d2H-CH4, d13C-CO2) composition. Samples from alkaline waters were mainly dominated by CH4 (from 128,000 to 915,000 μmol/mol), while hyperalkaline waters showed a N2-rich composition (from 727,000 to 977,000 μmol/mol). Methane had a wide range of isotope compositions (d13C-CH4 from -74.5 to -14.5 and d2H-CH4 from -343 to -62 ). Alkaline waters present the most negative isotope values for CH4, evidencing a biogenic (both thermogenic and microbial) origin. Many of the hyperalkaline waters had CH4 isotope values compatible with an abiogenic origin through serpentinization processes but occasionaly very negative values were recorded, indicating sometimes a clear biogenic contribution. Finally, few samples both from alkaline and hyperalkaline waters showed some evidence of secondary oxidation processes.

Published

2020

6. A christmas gift: Signature of the 24th December 2018 eruption of Mt. Etna on the chemical composition of bulk deposition in eastern sicily

Author

Lorenza Li Vigni, Francesco Parello, Lorenzo Brusca, Filippo Brugnone, Sergio Calabrese, Sergio Bellomo, Vincenzo Prano, Filippo Saiano, Walter D'Alessandro, Brugnone F., D'Alessandro W., Calabrese S., Li Vigni L., Bellomo S., Brusca L., Prano V., Saiano F., and Parello F.

Subjects

geography, geography.geographical_feature_category, Geochemistry, Geology, 010502 geochemistry & geophysics, Fluoride, Rainwater, Trace elements, Volcanic emissions, 01 natural sciences, Strombolian eruption, Settore GEO/08 - Geochimica E Vulcanologia, chemistry.chemical_compound, Deposition (aerosol physics), Volcano, Impact crater, chemistry, General Earth and Planetary Sciences, Environmental science, Seawater, Sulfate, Volatiles, Chemical composition, 0105 earth and related environmental sciences

Abstract

The eruption of Mt. Etna which occurred on December 24th 2018 was characterized by strombolian activity and fire fountains, emitted by the New South-East Crater and along a fissure that propagated towards the SE. The influence of volcanic emissions on atmospheric deposition was clearly detectable at several kilometres from the source. Wet and dry (bulk) deposition samples were collected each month, through a network of eleven collectors, in the areas of Milazzo, and Priolo between June 2018 and June 2019. They were analysed for major ions and trace elements concentrations. The pH values range from 3.9 to 8.3, while the EC values range from 7 to 396 μS cm-1. An extensive neutralization of the acidity has been recognised mainly due to the suspended alkaline dust particles, which have a buffering role in rainwater. A high load of Na+ and Cl- was observed at all sites, related to the closeness of the study areas to the coast, showing a high positive correlation (R2 = 0.989) along the line of Na+/Cl- ratio in seawater. During the eruption, the volcanic plume was carried by the winds for long distance (more than 300 km) affecting the area of Priolo but not that of Milazzo, which was upwind with respect to Mt. Etna. The impact of volcanic HF was clearly recognised in the samples collected after the eruption. Volcanic SO2 and HCl had a lower impact due to the overwhelming input of anthropogenic sulfate and marine chloride. On the contrary, the signature of the Mt. Etna eruption can be well recognised in the high concentrations of certain trace elements in the samples collected immediately after the eruption. The strongest contrast between affected and non-affected samples was recognised in Al, Cd, and especially in the volatile elements Tl and Te, which are typically enriched in volcanic emissions. The results showed that volcanic eruptions might have a relevant effect on the atmospheric chemistry and on the composition of rainwater up to distances of 80 km from the emission vents.

Published

2020

7. Hydrogen sulfide measurements in air by passive/diffusive samplers and high-frequency analyzer: A critical comparison

Author

Jacopo Cabassi, Sergio Calabrese, Franco Tassi, Walter D'Alessandro, Sergio Bellomo, Orlando Vaselli, Stefania Venturi, Francesco Capecchiacci, Venturi, S., Cabassi, J., Tassi, F., Capecchiacci, F., Vaselli, O., Bellomo, S., Calabrese, S., and D'Alessandro, W.

Subjects

Pollution, Spectrum analyzer, Air quality monitoring, 010504 meteorology & atmospheric sciences, Orders of magnitude (temperature), media_common.quotation_subject, Hydrogen sulfide, Active analyzers, Analytical chemistry, Passive/diffusive samplers, 010501 environmental sciences, Hydrogen sulphide, 01 natural sciences, chemistry.chemical_compound, Geochemistry and Petrology, Environmental Chemistry, 0105 earth and related environmental sciences, media_common, geography, geography.geographical_feature_category, Gaseous contaminants, Passive/diffusive sampler, chemistry, Volcano, Environmental chemistry, Gaseous contaminant, H2S in air, Active analyzer

Abstract

In this study, hydrogen sulfide (H2S) measurements in air carried out using (a) passive/diffusive samplers (Radiello® traps) and (b) a high-frequency (60 s) real-time analyzer (Thermo® 450i) were compared in order to evaluate advantages and limitations of the two techniques. Four different sites in urban environments (Florence, Italy) and two volcanic areas characterized by intense degassing of H2S-rich fluids (Campi Flegrei and Vulcano Island, Italy) were selected for such measurements. The concentrations of H2S generally varied over 5 orders of magnitude (from 101e103 mg/m3), the H2S values measured with the Radiello® traps (H2SR) being significantly higher than the average values measured by the Thermo® 450i during the trap exposure (H2STa), especially when H2S was

Published

2016

8. Degassing and Cycling of Mercury at Nisyros Volcano (Greece)

Author

Kyriaki Daskalopoulou, Francesco Parello, Sergio Bellomo, F. Capecchiacci, Walter D'Alessandro, Antonina Lisa Gagliano, Gaetano Giudice, Jacopo Cabassi, Sergio Calabrese, Franco Tassi, Maria Bonsignore, Lorenzo Brusca, Silvia Milazzo, Lorenza Li Vigni, Gagliano A.L., Calabrese S., Daskalopoulou K., Cabassi J., Capecchiacci F., Tassi F., Bellomo S., Brusca L., Bonsignore M., Milazzo S., Giudice G., Li Vigni L., Parello F., and D'Alessandro W.

Subjects

Article Subject, chemistry.chemical_element, 010501 environmental sciences, 010502 geochemistry & geophysics, 01 natural sciences, Volcanic degassing, Mercury Cycle, Greece, Soil pH, Cistus, Caldera, Erica arborea, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, biology, lcsh:QE1-996.5, Mercury, 15. Life on land, biology.organism_classification, Mercury (element), Settore GEO/08 - Geochimica E Vulcanologia, lcsh:Geology, Cistus creticus, chemistry, Volcano, 13. Climate action, Environmental chemistry, Soil water, General Earth and Planetary Sciences, Environmental science

Abstract

Nisyros Island (Greece) is an active volcano hosting a high-enthalpy geothermal system. During June 2013, an extensive survey on Hg concentrations in different matrices (fumarolic fluids, atmosphere, soils, and plants) was carried out at the Lakki Plain, an intracaldera area affected by widespread soil and fumarolic degassing. Concentrations of gaseous elemental mercury (GEM), together with H2S and CO2, were simultaneously measured in both the fumarolic emissions and the atmosphere around them. At the same time, 130 samples of top soils and 31 samples of plants (Cistus creticus and salvifolius and Erica arborea and manipuliflora) were collected for Hg analysis. Mercury concentrations in fumarolic gases ranged from 10,500 to 46,300 ng/m3, while Hg concentrations in the air ranged from high background values in the Lakki Plain caldera (10-36 ng/m3) up to 7100 ng/m3 in the fumarolic areas. Outside the caldera, the concentrations were relatively low (2-5 ng/m3). The positive correlation with both CO2 and H2S in air highlighted the importance of hydrothermal gases as carrier for GEM. On the other hand, soil Hg concentrations (0.023-13.7 μg/g) showed no significant correlations with CO2 and H2S in the soil gases, whereas it showed a positive correlation with total S content and an inverse one with the soil pH, evidencing the complexity of the processes involving Hg carried by hydrothermal gases while passing through the soil. Total Hg concentrations in plant leaves (0.010-0.112 μg/g) had no direct correlation with soil Hg, with Cistus leaves containing higher values of Hg with respect to Erica. Even though GEM concentrations in the air within the caldera are sometimes orders of magnitude above the global background, they should not be considered dangerous to human health. Values exceeding the WHO guideline value of 1000 ng/m3 are very rare (

Published

2019

9. Zirconium–hafnium and rare earth element signatures discriminating the effect of atmospheric fallout from hydrothermal input in volcanic lake water

Author

Giovannella Pecoraino, Sergio Bellomo, Paolo Censi, Pierpaolo Zuddas, Lorenzo Brusca, Claudio Inguaggiato, Walter D'Alessandro, Dipartimento di Scienze della Terra e del Mare [Palermo] (DiSTeM), Università degli studi di Palermo - University of Palermo, Institut des Sciences de la Terre de Paris (iSTeP), Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), Istituto Nazionale di Geofisica e Vulcanologia - Sezione di Palermo (INGV), Istituto Nazionale di Geofisica e Vulcanologia, Inguaggiato, C., Censi, P., Zuddas, P., D'Alessandro, W., Brusca, L., Pecoraino, G., and Bellomo, S.

Subjects

Rare Earth Elements, 010504 meteorology & atmospheric sciences, Geochemistry, chemistry.chemical_element, 010502 geochemistry & geophysics, 01 natural sciences, Hydrothermal circulation, Lake, Rare earth elements, Zirconium, Hafnium, CO2-rich waters, Lake, Aeolian input, Geochemistry and Petrology, [SDU.STU.GC]Sciences of the Universe [physics]/Earth Sciences/Geochemistry, Precipitation, 0105 earth and related environmental sciences, geography, Zirconium, geography.geographical_feature_category, CO 2 -rich waters, Rare-earth element, Geology, Authigenic, Hafnium, Aeolian input, Volcano, chemistry, Oil shale

Abstract

The geochemical behaviour of Rare Earth Elements, Zr and Hf was investigated in the thermal waters of Nevado del Ruiz volcano system. A wide range of pH, between 1.0 and 8.8, characterizes these fluids. The acidicwaters are sulphate dominatedwith different Cl/SO4 ratios. The important role of the pH and the ionic complexes for the distribution of REE, Zr a nd Hf in the aqueous phase was evidenced. The pH rules the precipitation of authigenic Fe and Al oxyhydroxides producing changes in REE, Zr, Hf amounts and strong anomalies of Cerium. The precipitation of alunite and jarosite removes LREE from the solution, changing the REE distribution in acidic waters. Y-Ho and Zr-Hf (twin pairs) have a different behaviour in strong acidic waterswith respect to the water with pH near-neutral. Yttrium and Ho behave as Zr and Hf in waters with pH near neutral-to-neutral, showing superchondritic ratios. The twin pairs showed to be sensitive to the co-precipitation and/or adsorption onto the surface of authigenic particulate (Fe-, Al-oxyhydroxides), suggesting an enhanced scavenging of Ho and Hf with respect to Y and Zr, leading to superchondritic values. In acidic waters, a different behaviour of twin pairs occurs with chondritic Y/Ho ratios and sub-chondritic Zr/Hf ratios. For the first time, Zr and Hf were investigated in natural acidic fluids to understand the behaviour of these elements in extreme acidic conditions and different major anion chemistry. Zr/Hf molar ratio changes from 4.75 to 49.29 in water with pH < 3.6. In strong acidic waters the fractionation of Zr and Hf was recognized as function of major anion contents (Cl and SO4), suggesting the formation of complexes leading to sub-chondritic Zr/Hf molar ratios.

Published

2016

10. Mount Etna volcano (Italy) as a major 'dust' point source in the Mediterranean area

Author

Francesco Parello, Silvia Milazzo, Giovannella Pecoraino, Cecilia Doriana Tramati, Sergio Calabrese, Giuseppe Montana, Giovanni Giuffrida, Walter D'Alessandro, Salvatore Giammanco, Luciana Randazzo, G. Salerno, Salvatrice Vizzini, Sergio Bellomo, Kyriaki Daskalopoulou, Lorenzo Brusca, Sarah Scaglione, Tommaso Caltabiano, Calabrese, S., Randazzo, L., Daskalopoulou, K., Milazzo, S., Scaglione, S., Vizzini, S., Tramati, C., D’Alessandro, W., Brusca, L., Bellomo, S., Giuffrida, G., Pecoraino, G., Montana, G., Salerno, G., Giammanco, S., Caltabiano, T., and Parello, F.

Subjects

Mediterranean climate, 010504 meteorology & atmospheric sciences, Earth science, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Troposphere, Atmosphere, Environmental impact, chemistry.chemical_compound, Chemical composition, Aerosol, 0105 earth and related environmental sciences, General Environmental Science, geography, Volcanic emission, geography.geographical_feature_category, Particulates, Silicate, Settore GEO/08 - Geochimica E Vulcanologia, Volcano, chemistry, Trace element, General Earth and Planetary Sciences, Earth and Planetary Sciences (all), Geology

Abstract

Volcanic emissions represent one of the most relevant natural sources of trace elements to the troposphere. Due to their potential toxicity, they may have important environmental impacts from local to global scale. They can also severely affect the atmospheric and terrestrial environment at timescales ranging from a few to millions of years. Mt. Etna volcano is known as one of the largest global contributors of magmatic gases (CO2, SO2 and halogens) and particulate matter, including some toxic trace elements. The aim of this study is to characterize the chemical composition and the mineralogical features of the volcanogenic aerosol passively emitted from Mt. Etna. Twenty-five samples were collected by filtration technique from different sites between 2008 and 2014. Chemical and mineralogical analyses allowed to discriminate two main constituents: the first is mainly referable to the silicate component in the volcanic plume, like lithic, juvenile fragments or glass shards and crystals (e.g. plagioclases, pyroxenes, oxides); the second constituent consists of soluble compounds like sulphosalts or halide minerals (sulphates, chlorides and fluorides). Fluxes of major and trace metals emitted in the atmosphere have been estimated. By comparing the Etnean trace elements with those from European anthropic emissions, we conclude that Mt. Etna is the main persistent point source of major and trace metals in the Mediterranean region. Results gathered from this investigation is of fundamental importance due to the exposure and potential impact of harmful chemical compounds for hundred thousand tourist visits each year to the summit of Mt. Etna.

Published

2016

11. Mineral control of arsenic content in thermal waters from volcano-hosted hydrothermal systems: Insights from island of Ischia and Phlegrean Fields (Campanian Volcanic Province, Italy)

Author

Giovannella Pecoraino, Rosario Avino, Stefano Caliro, Lorenzo Brusca, Giovanni Chiodini, Alessandro Aiuppa, Mariano Valenza, Rocco Favara, Manfredi Longo, Cinzia Federico, Salvatore Inguaggiato, W. Ginevra, Walter D'Alessandro, AIUPPA A, AVINO R, BRUSCA L, CALIRO S, CHIODINI G, D'ALESSANDRO W, FAVARA R, FEDERICO C, GINEVRA W, INGUAGGIATO S, LONGO M, PECORAINO G, and VALENZA M

Subjects

Arsenopyrite, geography, geography.geographical_feature_category, arsenic, Geochemistry, chemistry.chemical_element, Geology, engineering.material, Hydrothermal circulation, Volcano, chemistry, Geochemistry and Petrology, visual_art, engineering, visual_art.visual_art_medium, Pyrite, Leaching (agriculture), Pyrrhotite, Groundwater, Arsenic

Abstract

This paper documents arsenic concentrations in 157 groundwater samples from the island of Ischia and the Phlegrean Fields, two of the most active volcano-hosted hydrothermal systems from the Campanian Volcanic Province (Southern Italy), in an attempt to identify the environmental conditions and mineral-solution reactions governing arsenic aqueous cycling. On Ischia and in the Phlegrean Fields, groundwaters range in composition from NaCl brines, which we interpret as the surface discharge of deep reservoir fluids, to shallow-depth circulating fluids, the latter ranging from acid-sulphate steam-heated to hypothermal, cold, bicarbonate groundwaters. Arsenic concentrations range from 1.6 to 6900 μg·l- 1 and from 2.6 to 3800 μg·l- 1 in the Phlegrean Fields and on Ischia, respectively. They increase with increasing water temperature and chlorine contents, and in the sequence bicarbonate groundwaters < steam-heated groundwaters < NaCl brines. According to thermochemical modeling, we propose that high As concentrations in NaCl brines form after prolonged water-rock interactions at reservoir T, fO2 and fH2S conditions, and under the buffering action of an arsenopyrite + pyrite + pyrrhotite rock assemblage. On their ascent toward the surface, NaCl brines become diluted by As-depleted meteoric-derived bicarbonate groundwaters, giving rise to hybrid water types with intermediate to low As contents. Steam-heated groundwaters give their intermediate to high As concentrations to extensive rock leaching promoted by interaction with As-bearing hydrothermal steam. © 2005 Elsevier B.V. All rights reserved.

Published

2006

12. Characterization of the Etna volcanic emissions through an active biomonitoring technique (moss-bags): Part 1 – Major and trace element composition

Author

Walter D'Alessandro, Francesco Parello, Lorenzo Brusca, Sergio Calabrese, Sergio Bellomo, R.S. Martin, Filippo Saiano, Calabrese, S, D’Alessandro, W, Bellomo, S, Brusca, L, Martin, RS, Saiano, F, and Parello, F

Subjects

Environmental Engineering, Health, Toxicology and Mutagenesis, Settore AGR/13 - Chimica Agraria, Volcanic Eruptions, Volcanoe, Atmospheric deposition, Sphagnum, Mass Spectrometry, Environmental impact, Metals, Heavy, Volcanoes, Bioaccumulators, Enrichment factors, Biomonitoring, Trace element composition, Sphagnopsida, Environmental Chemistry, Sicily, geography, Air Pollutants, geography.geographical_feature_category, biology, Geography, Bioaccumulator, Public Health, Environmental and Occupational Health, General Medicine, General Chemistry, biology.organism_classification, Pollution, Moss, Enrichment factor, Settore GEO/08 - Geochimica E Vulcanologia, Deposition (aerosol physics), Volcano, Bioaccumulation, Environmental chemistry, Indicator species, Environmental science, Environmental Monitoring

Abstract

Active biomonitoring using moss-bags was applied to an active volcanic environment for the first time. Bioaccumulation originating from atmospheric deposition was evaluated by exposing mixtures of washed and air-dried mosses (Sphagnum species) at 24 sites on Mt. Etna volcano (Italy). Concentrations of major and a large suite of trace elements were analysed by inductively coupled mass and optical spectrometry (ICP-MS and ICP-OES) after total acid digestion. Of the 49 elements analysed those which closely reflect summit volcanic emissions were S, Tl, Bi, Se, Cd, As, Cu, B, Na, Fe, Al. Enrichment factors and cluster analysis allowed clear distinction between volcanogenic, geogenic and anthropogenic inputs that affect the local atmospheric deposition. This study demonstrates that active biomonitoring with moss-bags is a suitable and robust technique for implementing inexpensive monitoring in scarcely accessible and harsh volcanic environments, giving time-averaged quantitative results of the local exposure to volcanic emissions. This task is especially important in the study area because the summit area of Mt. Etna is visited by nearly one hundred thousand tourists each year who are exposed to potentially harmful volcanic emissions.

Published

2015

13. Characterization of the Etna volcanic emissions through an active biomonitoring technique (moss-bags): Part 2 – Morphological and mineralogical features

Author

Sergio Calabrese, Walter D'Alessandro, Calabrese, S, and D'Alessandro, W

Subjects

Energy Dispersive Spectrometer, Plume, Environmental Engineering, Health, Toxicology and Mutagenesis, Mineralogy, Volcanic Eruptions, Passive degassing, Sphagnum, Mass Spectrometry, Atmosphere, Impact crater, Metals, Heavy, Volcanic aerosols, Sulfates, Biomonitoring, Sphagnopsida, Environmental Chemistry, Volcanic aerosol, Sicily, geography, Settore GEO/06 - Mineralogia, geography.geographical_feature_category, Geography, biology, Silicates, Public Health, Environmental and Occupational Health, General Medicine, General Chemistry, Particulates, biology.organism_classification, Pollution, Settore GEO/08 - Geochimica E Vulcanologia, Volcano, Microscopy, Electron, Scanning, Environmental science, Particulate Matter, Environmental Monitoring

Abstract

Volcanic emissions were studied at Mount Etna (Italy) by using moss-bags technique. Mosses were exposed around the volcano at different distances from the active vents to evaluate the impact of volcanic emissions in the atmosphere. Morphology and mineralogy of volcanic particulate intercepted by mosses were investigated using scanning electron microscopy (SEM) equipped with energy dispersive spectrometer (EDS). Particles emitted during passive degassing activity from the two active vents, Bocca Nuova and North East Crater (BNC and NEC), were identified as silicates, sulfates and halide compounds. In addition to volcanic particles, we found evidences also of geogenic, anthropogenic and marine spray input. The study has shown the robustness of this active biomonitoring technique to collect particles, very useful in active volcanic areas characterized by continuous degassing and often not easily accessible to apply conventional sampling techniques.

Published

2015

14. Trace elements mobility in soils from the active hydrothermal area of Nisyros (Greece)

Author

Francesco Parello, Konstantinos Kyriakopoulos, Walter D'Alessandro, Franco Tassi, Kyriaki Daskalopoulou, Sergio Calabrese, Lorenzo Brusca, Silvia Milazzo, Sergio Bellomo, Daskalopoulou, K, Calabrese, S, Milazzo, S, Brusca, L, Bellomo, B, D'Alessandro, W, Kyriakopoulos, K, Tassi, F, and Parello, F

Subjects

geography, geography.geographical_feature_category, Soil test, volatile elements, lcsh:QC801-809, Trace element, trace elements, Greece, hydrothermal emissions, biomonitoring, Mineralogy, volcanoes, lcsh:QC851-999, Hydrothermal circulation, Settore GEO/08 - Geochimica E Vulcanologia, lcsh:Geophysics. Cosmic physics, Geophysics, Volcano, Soil water, Caldera, lcsh:Meteorology. Climatology, Volatiles, Chemical composition, fumarolic gases, Geology

Abstract

Nisyros Island, Greece, is a stratovolcano known for its intense hydrothermal activity. On June 2013, during a multidisciplinary field campaign, soil samples were collected in the caldera area to determinate the main mineralogical paragenesis and to investigate the distribution of trace elements concentrations and the possible relationship to the contribution of deep originated fluids. Soil samples were analysed with XRD and for the chemical composition of their leachable (deionized water) and near total (microwave digestion) fraction both for major and trace elements. All data were compared to a local background soil. The results allow to divide the samples in 2 groups: Lakki Plain and Stefanos Crater. The latter, where a fumarolic area is located, shows a mineralogical paragenesis dominated by phases typical of hydrothermal alteration. Their very low pH values (1.9 – 3.4) evidence the strong impact of fumarolic gases which are probably also the cause of strong enrichments in these soils of highly volatile elements like S, As, Se, Bi, Sb, Tl and Te. The soils of the Lakki Plain, being less exposed to the fumarolic activity, show minearalogical and chemical characteristics intermediate between the background soil and those of Stefanos Crater.

Published

2014

15. Passive degassing at Nyiragongo (D.R. Congo) and Etna (Italy) volcanoes

Author

Dario Tedesco, Francesco Parello, Silvia Milazzo, Sarah Scaglione, Giovanni Giuffrida, Sergio Calabrese, Mathiew Yalire, Nicole Bobrowski, Walter D'Alessandro, Calabrese, S, Scaglione, S, Milazzo, S, D'Alessandro, W, Bobrowski, N, Giuffrida, G B, Tedesco, D, Parello, F, and Yalire, M

Subjects

geography, Trace elements, geography.geographical_feature_category, lcsh:QC801-809, Trace element, Geochemistry, Mineralogy, Particulates, volcanic emissions, lcsh:QC851-999, Settore GEO/08 - Geochimica E Vulcanologia, Troposphere, Atmosphere, lcsh:Geophysics. Cosmic physics, Geophysics, Deposition (aerosol physics), Volcano, Impact crater, rainwater, biomonitoring, Stratovolcano, lcsh:Meteorology. Climatology, volcanic degassing, trace elements, biomonitoring, atmospheric deposition, Geology

Abstract

Volcanoes are well known as an impressive large natural source of trace elements into the troposphere. Etna (Italy) and Nyiragongo (D.R. Congo) are two stratovolcanoes located in different geological settings, both characterized by persistent passive degassing from their summit craters. Here, we present some results on trace element composition in volcanic plume emissions, atmospheric bulk deposition (rainwater) and their uptake by the surrounding vegetation, with the aim to compare and identify differences and similarities between these two volcanoes. Volcanic emissions were sampled by using active filter-packs for acid gases (sulfur and halogens) and specific teflon filters for particulates (major and trace elements). The environmental impact of the volcanogenic deposition in the area surrounding of the crater rims was investigated by using different sampling techniques: bulk rain collectors’ gauges were used to collect atmospheric bulk deposition, and biomonitoring was carried out to collect gases and particulates by using endemic plant species. The estimates of the trace element fluxes confirm that Etna and Nyiragongo are large sources of metals into the atmosphere, especially considering their persistent state of passive degassing. The large amount of emitted trace elements is clearly reflected on the chemical composition of rainwater collected at the summit areas both for Etna and Nyiragongo. Moreover, the biomonitoring results highlight that bioaccumulation of trace elements is extremely high in the proximity of the crater rim and de- creases with the distance from the active craters.

Published

2014

16. Active moss monitoring allows to identify and track distribution of metal(loid)s emitted from fumaroles on Vulcano Island, Italy

Author

Julia Arndt, Walter D'Alessandro, Britta Planer-Friedrich, Sergio Calabrese, Arndt, J, Calabrese, S, D’Alessandro, W, and Planer-Friedrich, B

Subjects

geography, geography.geographical_feature_category, biology, Mineralogy, chemistry.chemical_element, Particulates, biology.organism_classification, Sea spray, Moss, Fumarole, Settore GEO/08 - Geochimica E Vulcanologia, Geophysics, Volcano, chemistry, Impact crater, Geochemistry and Petrology, La Fossa, Particle transport, Biomonitoring, Volatilization, Transect, Arsenic, Geology

Abstract

Volatile metal(loid)s are known to be emitted from volcanoes worldwide. We tested the suitability of active moss monitoring for tracking volatile metal(loid)s released from the fumarolic field on Vulcano Island, Italy, and differentiated fumaroles from other sources of gaseous and particulate trace elements such as sea spray and soil. Metal(loid) accumulation on the mosses per day did depend neither on the state of the exposed moss (dead or living) nor exposure time (3, 6, or 9 weeks). After collection, mosses were digested with either HNO3/H2O2 or deionized water and analyzed by ICP-MS. While for most elements both extraction methods yielded similar concentrations, higher concentrations were observed e.g. for Pb in the stronger HNO3/H2O2 extracts, indicating the presence of particles, which were not digested and removed by filtration in deionized water extracts. Due to their ubiquitous detection in comparable concentrations at all 23 moss monitoring stations all over the island, Li, Mg and Sr were attributed to sea spray origin. Iron, Co, W, V, Pb, Cr, Mo, and Ba occurred predominantly at the crater, where the soil was not covered by vegetation, and thus likely represent soil-borne particulate transport. Arsenic, Sb, S, Se, Tl, Bi, and I showed a clear concentration maximum within the fumarolic field. Concentrations gradually decreased along a transect in wind direction from the fumaroles, which confirms their volcanic origin. Active moss monitoring thus proved to be an inexpensive and easy-to-apply tool for investigations of volcanic metal(loid) emissions and distributions enabling differentiation of trapped elements by their source of origin.

Published

2014

17. Sulphur-gas concentrations in volcanic and geothermal areas in Italy and Greece: Characterising potential human exposures and risks

Author

Walter D'Alessandro, Sergio Calabrese, Alessandro Aiuppa, Manfredi Longo, Konstantinos Kyriakopoulos, Lorenzo Brusca, Marcello Liotta, Sergio Bellomo, D'Alessandro, W, Aiuppa, A, Bellomo, S, Brusca, L, Calabrese, S, Kyriakopoulos, K, Liotta, M, and Longo, M

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Hydrogen sulphide, 010502 geochemistry & geophysics, 01 natural sciences, Volcanic risk, Fumarole, Settore GEO/08 - Geochimica E Vulcanologia, Sulphur dioxide, Hydrogen sulphide, Volcanic risks,Gas hazard, Volcano, 13. Climate action, Geochemistry and Petrology, Economic Geology, Physical geography, Geothermal gradient, Geology, Seismology, 0105 earth and related environmental sciences

Abstract

Passive samplers were used to measure the atmospheric concentrations of SO 2 naturally emitted at three volcanoes in Italy (Etna, Vulcano and Stromboli) and of H 2 S naturally emitted at three volcanic/geothermal areas in Greece (Milos, Santorini and Nisyros). The measured concentrations and dispersion patterns varied with the strength of the source (open conduits or fumaroles), the meteorological conditions and the area topography. At Etna, Vulcano and Stromboli, SO 2 concentrations reach values that are dangerous to people affected by bronchial asthma or lung diseases (> 1000 μg m − 3 ). H 2 S values measured at Nisyros also exceed the limit considered safe for the same group of people (> 3000 μg m − 3 ). The data obtained using passive samplers represent time-averaged values over periods from a few days up to 1 month, and hence concentrations probably reached much higher peak values that were potentially also dangerous to healthy people. The present study provides evidence of a peculiar volcanic risk associated with tourist exploitation of active volcanic areas. This risk is particularly high at Mt. Etna, where the elderly and people in less-than-perfect health can easily reach areas with dangerous SO 2 concentrations via a cableway and off-road vehicles.

Published

2013

18. Selenium mobilization in soils due to volcanic derived acid rain: An example from Mt Etna volcano, Sicily

Author

Gabriela Roman-Ross, Sergio Calabrese, W. D´Alessandro, Geerke H. Floor, Alessandro Aiuppa, Floor, G, Calabrese, S, Roman-Ross, G, D´Alessandro, W, Aiuppa, A, UNIVERSITY OF GIRONA ESP, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), Bureau de Recherches Géologiques et Minières (BRGM) (BRGM), University of Palermo, Italy, and Istituto Nazionale di Geofisica e Vulcanologia

Subjects

010504 meteorology & atmospheric sciences, Selenium, Volcanic soils, Geogenic, Volcanoes, Contamination, GroundwaterSelenium, Groundwater, chemistry.chemical_element, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, Volcanoe, 010502 geochemistry & geophysics, 01 natural sciences, Selenate, Volcanic soil, chemistry.chemical_compound, Geochemistry and Petrology, Selenium, acid rain, soils, Chemical composition, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Geology, Settore GEO/08 - Geochimica E Vulcanologia, Deposition (aerosol physics), chemistry, Volcano, 13. Climate action, [SDU]Sciences of the Universe [physics], Environmental chemistry, Soil water, Acid rain

Abstract

International audience; The significant amounts of selenium (Se) emitted by volcanoes may have important impact on human health due to the narrow range between nutrition requirement and toxic effects for living organisms upon Se exposure. Although soils play a key role in determining the level in food and water and thereby human health, little is known about the behaviour of Se in volcanic soils. In this work we evaluated the Se release during rainwater–soil interaction under controlled conditions using soils collected on the flanks of Etna volcano and synthetic rain. Selenium concentrations in soil leachate solutions displayed a spatial distribution, which cannot be explained by plume deposition, total Se soil concentrations or the presence of Fe oxides. Instead, Al compounds and to a minor extent SOM were identified as the active phases controlling the selenate mobilization during interaction with sulphate-containing rainwater. This shows the importance of soils as reactive interfaces. Selenium is mobilized when volcanic-derived acid rain interacts with poorly developed soils close to the crater. This geogenic process might influence the chemical composition of groundwater and as a result, human health.

Published

2011

19. Atmospheric sources and sinks of volcanogenic elements in a basaltic volcano (Etna, Italy)

Author

Emanuela Rita Bagnato, Francesco Parello, Sergio Calabrese, Alessandro Aiuppa, P. Allard, Lorenzo Brusca, Sergio Bellomo, Walter D'Alessandro, Calabrese, S, Aiuppa, A, Allard, P, Bagnato, E, Bellomo, S, Brusca, L, D’Alessandro, W, and Parello, F

Subjects

Basalt, geography, geography.geographical_feature_category, Trace element, Geochemistry, Mineralogy, Aerosol, Plume, Settore GEO/08 - Geochimica E Vulcanologia, Deposition (aerosol physics), Impact crater, Volcano, Geochemistry and Petrology, Etna, Trace element, volcanic emission, atmospheric deposition, Volatiles, Geology

Abstract

This study reports on the first quantitative assessment of the geochemical cycling of volcanogenic elements, from their atmospheric release to their deposition back to the ground. Etna’s emissions and atmospheric depositions were characterised for more than 2 years, providing data on major and trace element abundance in both volcanic aerosols and bulk depositions. Volcanic aerosols were collected from 2004 to 2007, at the summit vents by conventional filtration techniques. Precipitation was collected, from 2006 to 2007, in five rain gauges, at various altitudes around the summit craters. Analytical results for volcanic aerosols showed that the dominant anions were S, Cl, and F, and that the most abundant metals were K, Ca, Mg, Al, Fe, and Ti (1.5–50 μg m−3). Minor and trace element concentrations ranged from about 0.001 to 1 μg m−3. From such analysis, we derived an aerosol mass flux ranging from 3000 to 8000 t a−1. Most analysed elements had higher concentrations close to the emission vent, confirming the prevailing volcanic contribution to bulk deposition. Calculated deposition rates were integrated over the whole Etna area, to provide a first estimate of the total deposition fluxes for several major and trace elements. These calculated deposition fluxes ranged from 20 to 80 t a−1 (Al, Fe, Si) to 0.01–0.1 t a−1 (Bi, Cs, Sc, Th, Tl, and U). Comparison between volcanic emissions and atmospheric deposition showed that the amount of trace elements scavenged from the plume in the surrounding of the volcano ranged from 0.1% to 1% for volatile elements such as As, Bi, Cd, Cs, Cu, Tl, and from 1% to 5% for refractory elements such as Al, Ba, Co, Fe, Ti, Th, U, and V. Consequently, more than 90% of volcanogenic trace elements were dispersed further away, and may cause a regional scale impact. Such a large difference between deposition and emission fluxes at Mt. Etna pointed to relatively high stability and long residence time of aerosols in the plume.

Published

2011

20. A model for Ischia hydrothermal system: Evidences from the chemistry of thermal groundwaters

Author

R. Di Napoli, Lorenzo Brusca, Sergio Bellomo, Mariano Valenza, Alessandro Aiuppa, Manfredi Longo, Walter D'Alessandro, E. Gagliano Candela, Giovannella Pecoraino, Di Napoli, R, Aiuppa, A, Bellomo, S, Brusca, L, D'Alessandro, W, Gagliano Candela, E, Longo, M, Pecoraino, G, and Valenza, M

Subjects

Hot spring, geography, geography.geographical_feature_category, ischia volcano, hydrothermal systems, Geochemistry, Trachyte, Hydrothermal circulation, Geophysics, Oceanography, Volcano, Geochemistry and Petrology, Magma, Meteoric water, Seawater, Geology, Thermal fluids

Abstract

Ischia volcano, in Central Italy, has long been known for its copious surface hydrothermal manifestations, signs of a pervasive circulation of hot fluids in the subsurface. Because of the significant chemical heterogeneity of fumarolic gas discharges and hot spring discharges, evidences of a complex hydrothermal setting, a definite model of fluid circulation at depth is currently unavailable, in spite of the several previous efforts. Here, we report on the chemical and isotopic composition of 120 groundwater samples, collected during several sampling surveys from 2002 to 2007. The acquired data suggest that the composition of surface manifestations reflect contributions from meteoric water, sea water, and thermal fluids rising from two distinct hydrothermal reservoir, with equilibrium temperatures of respectively ~ 150 °C and ~ 270 °C, and depths of 150–300 m and > 300 m (but possibly > 1000 m). We also make use of an isotopic characterization of the dissolved gas phase in thermal waters to demonstrate that the Ischia hydrothermal system is currently supplied by a deep-rising gas component (DGC), characterized by CO2 ~ 97.7 ± 1.2 vol.% (on a water-free basis), δ13CCO2 = − 3.51 ± 0.9‰, and helium isotopic ratio of about 3.5 Ra (3He/4He ratio normalized to the air ratio, Ra), likely magmatic in origin. An assessment of the thermal budget for Ischia hydrothermal system is also presented, in the attempt to derive a first estimate of the size and rate of degassing of the magmatic reservoir feeding the gas emissions. We calculate that a heat flow of about 153–222 MW presently drives hydrothermal circulation on the island, which we suggest is supplied in convective form (e.g., by the ascent of a high-T magmatic vapour phase) by complete degassing of 2.2–3.3 · 107 m3 yr− 1 of trachytic magma (with ~ 2.1 wt.% dissolved H2O content). If extrapolated to entire period of quiescence lasting since the Arso eruption in 1302 A.D., this volume corresponds to 1.6–2.3·1010 m3 of magma degassed in about 700 years of quiescent activity.

Published

2009

21. Evaluation of the environmental impact of volcanic emissions from the chemistry of rainwater: Mount Etna area (Sicily)

Author

Francesco Parello, Pietro Bonfanti, L. Brusca, Cinzia Federico, Alessandro Aiuppa, Walter D'Alessandro, Aiuppa, A, Bonfanti, P, Brusca, L, D'Alessandro, W, Federico, C, and Parello, F

Subjects

Hydrology, geography, geography.geographical_feature_category, Fluorine, Precipitation, Bromine, Pollution, Rainwater harvesting, Plume, Settore GEO/08 - Geochimica E Vulcanologia, chemistry.chemical_compound, Impact crater, Volcano, Nitrate, chemistry, Geochemistry and Petrology, Nitrogen compound, Panache, Environmental Chemistry, Halogen compound, Environmental impact assessment, Chlorine, Groundwater, Negative ion

Abstract

The S, halogen and NO 3 contents of rainwater samples from the Etnean area were studied in order to define the environmental impact of plume emissions on the local environment. Samples, collected on a network of 11 bulk rain gauges, show significant variability in anion content, which can be ascribed to different meteorological and environmental conditions at each sampling site and to a variable distance from the different source areas. Data analysis suggests that S, F, Cl and Br are mainly magma-derived, whereas NO 3 mainly originates from anthropogenic sources. Samples collected from sites close to craters display considerable temporal variability, with increased anion concentrations being recorded during periods of intense plume degassing. Variations in precipitation also induce significant modifications in the chemistry of the meteoric-derived Etnean groundwaters.

Published

2001

22. Interaction between the deep fluids and the shallow groundwaters on Vulcano island (Italy)

Author

Rocco Favara, Walter D'Alessandro, Francesco Parello, Salvatore Inguaggiato, Giorgio Capasso, Capasso, G, D'Alessandro, W, Favara, R, Inguaggiato, S, and Parello, F

Subjects

geography, geography.geographical_feature_category, Soil gas, Gase, Geochemistry, Mineralogy, Aquifer, Bromine, Fumarole, Nitrogen compounds, Settore GEO/08 - Geochimica E Vulcanologia, Geophysics, Mediterranean sea, Flux (metallurgy), Volcano, Geochemistry and Petrology, Groundwater, Geology, Water well, Boron

Abstract

The aim of this work is to study the interactions processes between the fluids of deep origin and the shallow groundwaters of the Vulcano Porto area. During 1995, 13 well waters were sampled three times (May, July and November) and analysed for major and some minor elements (B, Br and NH4) and for dissolved gases. The close relationship of these waters with the deep magmatic source is highlighted by the composition of the dissolved gases. Furthermore, the areal distribution of dissolved species is controlled mainly by the gas fluxes from depth and by the presence of a deeper thermal aquifer. The distribution of major anomalies in the parameters measured in the groundwaters, in fact, overlaps the soil gas fluxes distribution that are related to the existence of preferential upflow routes of fumarolic fluids through weak structural lines in the volcanic edifice.

Published

2001