ALBERT

Description: A biomonitoring survey, above tree line level, using two endemic species (Senecio aethnensis and Rumex aethnensis) was performed on Mt. Etna, in order to evaluate the dispersion and the impact of volcanic atmospheric emissions. Samples of leaves were collected in summer 2008 from 30 sites in the upper part of the volcano (1500- 3000 m a.s.l). Acid digestion of samples was carried out with a microwave oven, and 44 elements were analyzed by using plasma spectrometry (ICP-MS and ICP-OES). The highest concentrations of all investigated elements were found in the samples collected closest to the degassing craters, and in the downwind sector, confirming that the eastern flank of Mt. Etna is the most impacted by volcanic emissions. Leaves collected along two radial transects from the active vents on the eastern flank, highlight that the levels of metals decrease one or two orders of magnitude with increasing distance from the source. This variability is higher for volatile elements (As, Bi, Cd, Cs, Pb, Sb, Tl) than for more refractory elements (Al, Ba, Sc, Si, Sr, Th, U). The two different species of plants do not show significant differences in the bioaccumulation of most of the analyzed elements, except for lanthanides, which are systematically enriched in Rumex leaves. The high concentrations of many toxic elements in the leaves allow us to consider these plants as highly tolerant species to the volcanic emissions, and suitable for biomonitoring researches in the Mt. Etna area.

Description: Published

Description: Vienna, Austria

Description: 4.4. Scenari e mitigazione del rischio ambientale

Description: open

Description: The sustained and uninterrupted plume degassing at Mount Etna volcano, Southern Italy, represents the troposphere’s most prominent natural source of fluorine. Of the ~ 200 Mg of fluorine (as HFg) emitted daily by the volcano, 1.6±2.7 Mg are deposited by wet and dry deposition. Fluorine-deposition via volcanic ash, here characterised for the first time, can be quite significant during volcanic eruptions (i.e. 60 Mg of fluorine were deposited during the 2001 eruption through volcanic ash, corresponding to ~ 85% of the total fluorine deposition). Despite the fact that these depositions are huge, the fate of the deposited fluorine and its impact on the environment are poorly understood. We herein present original data on fluorine abundance in vegetation (Castanea Sativa and Pinus Nigra) and andosoils from the volcano’s flank, in the attempt to reveal the potential impact of volcanogenic fluorine emissions. Fluorine contents in chestnut leaves and pine needles are in the range 1.8-35 µg/g and 2.1-74 µg/g respectively; they exceed the typical background concentrations in plants growing in rural areas, but fall within the lower range of typical concentrations in plants growing near high fluorine anthropogenic emission sources. The rare plume fumigations on the lower flanks of Mt Etna (distance 〉 4 km from summit craters) are probably the cause of the “undisturbed” nature of Etnean vegetation: climatic conditions, which limit the growth of vegetation on the upper regione deserta, are a natural limit to the development of more severe impacts. High fluorine contents, associated with visible symptoms, were only measured in pine needles at three sites, located near recently-active (2001 to 2003) lateral eruptive fractures. Total fluorine contents (FTOT) in the Etnean soils have a range of 112-341 µg/g, and fall within the typical range of undisturbed soils; fluorine extracted with distilled water (FH2O) have a range of 5.1 to 61 µg/g and accounts for 2-40 % of FTOT. FH2O is higher in topsoils from the eastern flank (downwind), while it decreases with depth in soil profiles and on increasing soil grain size (thereby testifying to its association with clay-mineral-rich, fine soil fractions). The fluorine adsorption capacity of the andosoils acts as a natural barrier that protects the groundwater system.

Description: Published

Description: 87-101

Description: 1.2. TTC - Sorveglianza geochimica delle aree vulcaniche attive

Description: 4.5. Degassamento naturale

Description: JCR Journal

Description: reserved

Description: Fluorine is the most reactive and the most electronegative of all elements, meaning that it has a powerful attraction for electrons and that it is able to attack all other elements, with the exception of oxygen and nitrogen, so it is not found in the free elemental state in nature. Fluorine is widely distributed throughout the earth’s crust as the fluoride ion. Fluorine is reported to be the 13th most abundant element in the earth’s crust (Smith and Hodge, 1979), with an average concentration of 0.032% by weight. Fluorides are released into the environment naturally through the weathering and dissolution of minerals, the emissions from volcanoes and from marine aerosols (WHO, 2002). Fluorides are also released into the environment via coal combustion and process waters and waste from various industrial processes, including steel manufacture, primary aluminium, copper and nickel production, phosphate ore processing, phosphate fertilizer production and use, petroleum refining, glass, brick and ceramic manufacturing, and glue and adhesive production (WHO, 2002). Based on available data, phosphate ore production and use as well as aluminium manufacture are the major industrial sources of fluoride release into the environment. According to Wellburn (1997), fluorine (in the form of HF) occupies - after O3, SO2 and nitrogencontaining air pollutants - the fourth place with regard to its detrimental effects on harvest, at least in the US. Relative to its weight fluorine even has the highest level of phytotoxicity of all air pollutants. Wellburn (1997) reports that F-related damages at sensitive plants can develop at concentration levels 10 to 10.000 times lower than other pollutants. There is no doubt that inorganic fluoride was one of the major air pollutants of the 20th century damaging crops, forests and natural vegetation, and causing fluorosis in factory workers, livestock and wild mammals. However there have been enormous improvements during the last 40 years in the containment and scrubbing of emissions, so that modern fluoride emitting industries generally have little or no environmental impact outside the factory fence at the present time (Weinstein and Davison, 2003). On the other hand, fluoride emissions from volcanoes and the natural occurrence of excessive amounts of fluoride in drinking water have affected the health of humans and livestock for centuries, if not millennia. For example some historical report tells that Pliny the Elder was dispatched by fluoride-containing fumes from a Vesuvian eruption, although other state that the cause of its death had actually no relation to volcanic activity. Whether the story is true or not,fluoride was certainly the agent responsible for the death of sheep after the volcanic eruption described in the Icelandic sagas, and fluoride emissions from volcanoes continue to affect the health of humans and livestock today (Georgsson and Petursson, 1972; Fridriksson, 1983; Araya et al.,1990; Cronin et al., 2002). Fluorine is emitted by volcanoes mostly as HF, but emissions from Vesuvius and Vulcano in Italy have been shown to contain also NH4F, SiF4, (NH4)2SiF6, NaSiF6, K2SiF6 and KBF4 (Weinstein and Davison, 2003). Volcanoes are also an important source of organo-fluorides, including some CFCs (Schwandner et al., 2004). Estimations of the global release of fluorine to the atmosphere by volcanic activity ranges from 50 to 8600 Gg/a (Cadle, 1980; Symonds et al., 1988; Halmer et al., 2002) with the lowest figures being probably an underestimate. Average HF emission rates from Mt. Etna can be estimated to about 75 Gg/a (Aiuppa et al., 2004a). This makes Mt. Etna the largest known point atmospheric source of fluorine (Francis et al., 1998), even stronger than todays estimated anthropogenic release over whole Europe (Preunkert et al., 2001). The environmental impact of anthropogenic fluorine emissions have long been studied considering all main type of activity, for example coal burning (Ando et al., 2001), aluminium smelters (Egli et al., 2004) or phosphate fertiliser production (Klumpp et al, 1996) and all types of receptors (air – Liu, 1995; glaciers - Preunkert et al., 2001; surface waters – Skjelkvale, 1994; vegetation – Weinstein, 1977; Weinstein and Davison, 2003; soils – Polomski et al., 1982; wildlife – Kierdorf and Kierdorf, 2000; etc.). Considerably fewer studies have been devoted to the consequences of volcanic fluorine emissions and most of them were focussed on the impact of fluorine released through explosive volcanic eruptions (Georgsson and Petursson, 1972; Oskarsson, 1980; Thorarinsson, 1979; Cronin et al., 2002). Recent researches have highlighted that passive degassing – quietly but persistently releasing volcanogenic pollutants - may also have profound impact on the ecosystems downwind, sometimes disrupting the social and economic activities of populations (Delmelle et. al., 2002; Delmelle, 2003). In this context, the impact of volcanogenic fluorine has been assessed on vegetation growing along the flanks of volcanoes (Guadeloupe – Garrec et al., 1977; Masaya – Garrec et al., 1984; Etna – Garrec et al., 1984; Notcutt and Davies, 1989; La Palma – Davies and Nottcut, 1989; Hawaii - Notcutt and Davies, 1993; Furnas - Notcutt and Davies, 1999) on rainwater chemistry (Hawaii - Harding & Miller, 1982; Vulcano Island – Capasso et al., 1993; Etna – Aiuppa et al., 2001; Stromboli Island – Bellomo et al., 2003) and on soils (Delmelle et al.,2003). The aim of the present PhD thesis is to provide original data on the geochemical cycling of fluorine of an active volcanic system like Mt. Etna. An assessment of the impact of volcanic fluorine on the local environment is also attempted by analysing different media (atmospheric air, rainwater, volcanic ashes, vegetation and soil).

Description: -Università degli Studi di Palermo, Italy -Istituto Nazionale di Geofisica e Vulcanologia, Sezione di Palermo - Unione Europea, Fondo Sociale Europeo

Description: Published

Description: open

Description: The Florina basin, being the main commercial source of CO2 in Greece, represents a good natural analogue for the study of the impact of geologic carbon storage. It is part of a NNW-SSE trending graben filled with ~600 m Plio-Pleistocene fluvial and lacustrine deposits. The area is characterized by the upflow of great quantities of geogenic CO2 probably associated to presently extinct Quaternary volcanic activity. The gas originates mainly from crustal sources but has also a minor (~10%) mantle contribution. This strong upflow of nearly pure CO2 can be recognized in industrially exploitable gas reservoirs, high pCO2 shallow groundwaters and surface gas manifestations. But the increased CO2 content has a deleterious impact on groundwater quality. Due to the increased aggressiveness of the low-pH CO2-rich waters with respect to the aquifer rocks, EU drinking water limits are exceed for many parameters (e.g. Electric conductivity, pH, Na+, SO42-, F-, Al, B, Ba, Fe, Mn and Ni). Considering the additional impact of widespread agricultural activities, which is recognizable in sometimes elevated NO3- contents, only few of the sampled waters (4 out of 40) could be used for potable purposes. Aquifer waters are also characterized by high REE contents with ΣREE up to ~12 µg/l. Shale-normalized profiles show positive La and Y anomalies and Ce negative anomalies probably indicating a main derivation from iron oxyhydroxide dissolution. The positive Eu anomaly evidences also carbonate dissolution while the enrichment in HREE is probably due to the abundant presence of HCO3-, which increases HREE solubility through complexation. Future developments of carbon capture and storage programs in the nearby sedimentary basin of Ptolemais and Servia have to carefully take in account the possible deterioration of their groundwater resources due to CO2 leaks from the storage reservoirs.

Description: Published

Description: Bari, Italy

Description: 4.5. Studi sul degassamento naturale e sui gas petroliferi

Description: open

Description: Biomonitoring may be defined as the use of organisms and biomaterials (biomonitors) to obtain informations on certain characteristics of a particular medium (atmosphere, hydrosphere etc.). In particular, mosses accumulate large amounts of trace metals, making them good bioaccumulators to estimate atmospheric pollution. The moss-bags technique, introduced in the early 1970’, has become very popular. Such active biomonitoring technique is particularly useful in highly polluted areas and has been extensively used in industrial and/or urban areas to examine deposition patterns and to recognize point sources of pollution. The main objective of this study, which represents the first application of the moss-bags technique in an active volcanic area, was to test its efficacy in such environment. Complementary objectives were: to determine the different behavior and the geographic dispersion of volcanogenic elements emitted from Mt. Etna; to check the usefulness of a simpler analytical techniques (leaching instead of mineralization of the moss samples). A mixture of Sphagnum species was picked in a clean area, treated in laboratory (washed, dried and packed) and exposed in field for 1 month. Sites were chosen considering the prevailing wind at Mt. Etna’s summit. Milled samples were analyses for major and trace elements concentrations, after microwave digestion (HNO3 + H2O2), by ICP-MS and ICP-OES techniques. The same elements were also analyzed after simple leaching with deionized water (1/50 weight ratio for 4 hours). Leaching solutions were also analyzed by IC for F, Cl and SO4. Analyses clearly showed the efficacy of the moss-bags technique also in this peculiar environment. Several elements were strongly enriched in the mosses exposed to the volcanic emissions. The highest enrichment was measured close to the summit crater, but evidences of metals bioaccumulation were also found in down wind sites, at several km from the volcanic source. The accumulation factor (exposed/unexposed moss) allowed us to distinguish a group of elements (Tl, Bi, Se, Cu, As, Cd, S), which are highly mobile in the high temperature volcanic environment. Also alkali metals showed a significant increase in their concentrations, probably because of their affinity for the halide species carried by the volcanic plume. Also the simple and cheap leaching technique gave important indications on the plume dispersion pattern, especially for highly volatile elements (F, Cl, S, Tl).

Description: Published

Description: Torino, Italia

Description: 4.5. Studi sul degassamento naturale e sui gas petroliferi

Description: open

Description: Fluorine adsorption experiments were performed on 28 samples of the first 5 cm of topsoil collected on the flanks of Mt. Etna. The soil samples were equilibrated with F-rich rainwater (3.25 mg/L) at a soil/water weight ratio of 1/25. Aliquots of the supernatant were collected after 1, 7, 72, 720 and 5640 h and analysed for F content. The soil samples could be subdivided into three groups based on their F-adsorption behaviours after 1 h and at the end of the experiment: (1) negative adsorption (F released from the soil to the solution) after 1 h and negative or moderately positive adsorption at the end, (2) from negative after 1 h to strongly positive adsorption at the end, and (3) always strong positive adsorption. The adsorption capacity of the soils was positively correlated with the soil pH, the contents of finer granulometric fractions (clay and silt) and the weathering stage (as quantified by the chemical alteration index). The most F adsorbing soils are found at the periphery of the volcano where aquifers are more vulnerable to contamination due to the shallower depth of the water table. This study further evidences the importance of the Etnean soils in protecting groundwater from an excessive magmatic F input.

Description: Published

Description: 1179–1188

Description: 4.4. Scenari e mitigazione del rischio ambientale

Description: JCR Journal

Description: restricted

Description: Volcanic and geothermal areas are one of the major natural sources of sulphur gases to the atmosphere. Hydrogen sulphide (H2S) is a toxic gas mainly associated to geothermal systems while sulphur dioxide (SO2) is released in huge quantities from volcanoes characterized by open conduit activity. Apart from being one of the most impressive geodynamic expressions, volcanoes are also an important tourist attraction. During the summer season the number of tourists visiting the crateric areas each day is on average many tens at Stromboli, hundreds at Vulcano, Santorini and Nisyros and thousands at Etna. Touristic exploitation of active volcanic areas cannot exempt from warranting a reasonable security to the visiting persons. But while many risks in these areas have been since long time considered, gas hazard, a very subtle risk, is often disregarded. The atmospheric concentrations and dispersion pattern of naturally emitted SO2 were measured at three volcanoes of southern Italy (Etna, Vulcano and Stromboli) while that of H2S at four volcanic/geothermal areas of Greece (Sousaki, Milos, Santorini and Nisyros). Measurements were made with a network of passive samplers positioned at about 1.5 m above the ground, which gave time-integrated values for periods from few days to 1 month. Samplers were placed in zones of the volcanoes with high tourist frequentation. Measured concentrations and dispersion pattern depend on the strength of the source (craters, fumaroles), meteorological conditions and geomorphology of the area. At Etna, Vulcano, Stromboli and Nisyros measured concentrations reach values that are absolutely dangerous to people affected by bronchial asthma or lung diseases. But considering that these are average values over periods from few days up to one month, concentrations could have reached much higher peak values dangerous also to healthy people. The present study evidences a peculiar volcanic risk connected to the touristic exploitation of volcanic areas. Such risk is particularly enhanced at Etna where elderly and not perfectly healthy people can easily reach, with cableway and off-road vehicles, areas with dangerous SO2 concentrations.

Description: Published

Description: Bari, Italy

Description: 4.5. Studi sul degassamento naturale e sui gas petroliferi

Description: open

Description: Biomonitoring may be defined as the use of organisms and biomaterials (biomonitors) to obtain informations on certain characteristics of a particular medium (atmosphere, hydrosphere etc.). In particular, mosses accumulate large amounts of trace metals, making them good bioaccumulators to estimate atmospheric pollution. The moss-bags technique, introduced in the early 1970’, has become very popular. Such active biomonitoring technique is particularly useful in highly polluted areas and has been extensively used in industrial and/or urban areas to examine deposition patterns and to recognize point sources of pollution. The main objective of this study, which represents the first application of the moss-bags technique in an active volcanic area, was to test its efficacy in such environment. Complementary objectives were: to determine the different behaviour and the areal dispersion of volcanogenic elements emitted from Mt. Etna; to characterize the morphology and mineralogy of particles transported in the plume-system, basing on microscopy investigation. A mixture of Sphagnum species was picked in a clean area, treated in laboratory (rinsed, dried and packed) and exposed in field for 1 month. Sites were chosen considering the prevailing wind at Mt. Etna’s summit. Milled samples were analyses for major and trace elements concentrations, after microwave digestion (HNO3 + H2O2), by ICP-MS and ICP-OES techniques. Morphology and mineralogy of volcanic particulate were investigated by using a SEM with EDS. Analyses clearly showed the efficacy of the moss-bags technique also in this peculiar environment. Several elements were strongly enriched in the mosses exposed to the volcanic emissions. The highest enrichment was measured close to the summit crater, but evidences of metals bioaccumulation were also found in down wind sites, at several km from the volcanic source. The accumulation factor (exposed/unexposed moss) allowed us to distinguish a group of elements (Tl, Bi, Se, Cu, As, Cd, S), which are highly mobile in the high temperature volcanic environment. Also alkali metals showed a significant increase in their concentrations, probably because of their affinity for the halide species carried by the volcanic plume. Microscopic observations evidenced sulphate and halide crystals on particles trapped by the mosses. Mosses exposed at sites directly fumigated by the volcanic plume showed crystal growth also directly on the moss surface.

Description: Published

Description: Bari, Italy

Description: 4.5. Studi sul degassamento naturale e sui gas petroliferi

Description: open

Description: Fumarolic alteration crusts and efflorescences have been sampled at the Sousaki solfataric field. Samples have been analysed for mineralogical (XRD) and chemical composition (HNO3 digestion and leaching with distilled water). Results show that mineralogical and chemical compositions (major, minor and trace metals) are controlled by microenvironmental conditions. The sample collected in the anoxic part of a cave is composed almost exclusively by native sulfur. The samples collected in the oxidizing part of the cave and outside in relatively sheltered position are mainly composed by very soluble sulfates. Chemical composition evidence strong enrichments in Al, Ca, Cr, Fe, Mg and Ni which are present in highly soluble form and derive from the fumarolic alteration of the outcropping rocks (Marls and peridotites). One sample collected outside the cave, well exposed to atmospheric agents, is composed almost exclusively of gypsum and the chemical composition reveals, with respect to the previous samples, a relative enrichment of elements (Ba, Ca, K, Pb and Sr) forming less soluble sulfates. The presence of toxic metals like Al, Cr and Ni in high concentrations and highly soluble form evidences the potential impact of the fumarolic activity on the local environment.

Description: Published

Description: Myconos, Greece

Description: 4.4. Scenari e mitigazione del rischio ambientale

Description: open

Description: Sousaki (Corinthia, Greece), is a presently inactive volcanic area hosting a geothermal reservoir. Geothermal activity, still recognizable by a series of low temperature gas manifestation, is responsible of the widespread alteration of the outcropping rocks in the area. The main manifestations are hosted within caves whose walls are covered by alteration products in the form of crusts and efflorescences. This study presents the results of mineralogical and chemical analyses of the alteration products collected in the area. Leaching experiments with distilled water were also performed to get insights on the mobility of the elements incorporated in the alteration products. X-ray diffractometry allowed us to recognize a series of secondary minerals deriving from the alteration of the ophiolithic host rocks (altered peridotites to serpentinites) and whose composition depends mainly on the microenvironmental conditions in which they were formed. Elemental sulphur is the main mineral phase at the bottom of the caves where the atmosphere is anoxic. In the upper part of the caves, where oxygen is readily available, efflorescences are composed of many highly soluble acid sulphate minerals. In the oxidised part of the cave the stability of the mineral phases is mainly controlled by the relative humidity. The most hydrous mineral phases occur in the lower part of the cave, which is characterised by higher humidity values. Outside the caves highly soluble sulphates have been found in two samples collected in relatively sheltered position while a further sample collected outside the caves, but exposed to atmospheric agents, is composed almost exclusively by gypsum. Chemical analyses (ICP-MS after digestion with HNO3) revealed high contents of Al (up to 55,000 µg/g), Co (up to 655 µg/g), Cr (up to 7400 µg/g), Fe (up to 105,000 µg/g), Mg (up to 147,000 µg/g), Mn (up to 3700 µg/g) and Ni (up to 8800 µg/g) in the sample collected in the oxidised part of the caves. These strong enrichments confirm that the alteration products derive from the ophiolithic rocks. Leaching experiments evidenced the high mobility of these elements. Due to the extreme solubility of the mineral phases, on average between 70 and 94% of Al, Ca, Co, Cr, Cs, Cu, Fe, Li, Mg, Mn, Ni, Rb, Sr, U and Zn is in water soluble form. On the contrary, As, B, Ba, K, Mo, Na, Pb and V display lower solubilities (4 – 56%). Toxic elements’ mobility, favoured by the strongly acidic environment of the fumarolic area, may have severe environmental consequences.

Description: Published

Description: Myconos, Greece

Description: 4.4. Scenari e mitigazione del rischio ambientale

Description: open