Global ETD Search

11	Samband mellan vulkanutbrott och klimatförändringar : Analys och värdering av teorier om vulkanisk aska och gasers påverkan på det globala klimatet Johansson, Eva January 2015 (has links) This literature review analyses and discusses different theories and results regarding impact of volcanic eruptions on climate change in Earth's history. Present global warming has been attributed to anthropogenic emissions of greenhouse gases, mainly carbon dioxide, however changes in global temperatures have occurred before the onset of anthropogenic emissions. Certain prehistoric climate changes are thought to be caused by emissions of volcanic gases to the atmosphere. Many studies have investigated the connection between volcanic events and subsequent changes in global temperatures. A majority have concluded that volcanic sulfur dioxide is the main direct and indirect climate forcing gas influencing temperatures over time. Increased volcanic activity over the last 15 years is thought to be an inhibiting factor on present global warming. This is supported by evidence of past volcanic events preceding global cooling and warming periods during Holocene and prehistoric times. Further, there are indications that factors such as geographical position, season, gas composition, magnitude and duration of an eruption influences the extent of the climate forcing.Records of climate such as ice cores and tree growth rings and isotopic characterization have made it possible to identify volcano eruptions over time and determine the identity of the erupting volcano. Past and present data from these can be used to gain a better understanding of past climate changes as well as making predictions about future changes as a result volcanic eruptions. However, accuracy regarding temporal and spatial resolution of these records is of great importance for the validity of the results. sulfur dioxide volcanic gases climate forcing stratosphere volcanoes
12	Measuring and modelling of volcanic pollutants from White Island and Ruapehu volcanoes assessment of related hazard in the North Island / Grunewald, Uwe. January 2007 (has links) Thesis (Ph. D.)--University of Canterbury, 2007. / Title from PDF title page (viewed on Feb. 23, 2008). Includes bibliographical references (p. 239-253).
13	Reactive processes during the discharge of high temperature volcanic gases Africano, Fátima 25 January 2005 (has links) This study shows how the composition of gases released from a single magmatic source may be modified during their ascending path. The main processes that influence the composition of the gases in these high temperature fumarolic environments, are: 1) interactions with wallrocks during gas ascent, which change the fugacities of the metal volatile species and affect the equilibrium between major species (fH2S/fSO2; fH2/fH2O); 2) mixing with meteoric water with consequent Cl adsorption, which may account for the Cl depletion of the gases; 3) remobilisation of previously formed sublimates and/or incrustation deposits. Comparison between the thermochemical models and the mineralogical composition of the silica tubes at Kudryavy and Satsuma-Iwojima volcanoes suggests that high fO2 due to the mixing of the gases with air during their injection into the atmosphere significantly reduces the volatility of several trace elements (As, Sb, Sn, Na, K, Tl, Te, Se and Cd). Comparisons between the enriched metals in aerosols and in the gases suggest that Mo, Pb, Bi, Na, K, Cu, Zn or Fe, which are enriched in the gases, are preferentially deposited in the gas conduits and vents whereas the highly volatile metals (Te, Tl, Sb, As and Se) and Cd condense in the plume. This study determines the reactions that may occur during the alteration of rocks in high temperature fumarolic environments. Three different processes of alteration prevail: (1) Acidic alteration which is characterized by the complete absence of clays, because the constant supply of gases to these systems allows for the pH values of the acidic fluids to be maintained low enough to prevent the precipitation of clay minerals. Complete leaching of all cations, except Si, from the primary silicates leads to important "silicification" of the wall rock. The primary mineral cations are leached in the following order: K, Na > Ca > Fe, Mg > Al > Si, Ti. The fluids enriched in these cations circulate in microcracks at different temperatures and different redox conditions and lead to the precipitation of secondary incrustations. At Kudryavy the incrustations are mainly sulfates. At Usu the lower sulfur/fluoride ratio of the gases allows the occurrence of aluminum fluoride incrustations. The order of primary minerals dissolution (olivine > plagioclase > pyroxene > matrix glass > Fe-Ti oxides) is established for both sites studied. (2) Alteration by an oxidized volcanic gas, resulting from mixing with the atmosphere (500 to 300°C). At Kudryavy, thermochemical modeling suggests that anhydrite and anhydrous sulfates, which occur at intermediate temperatures, are formed by interactions of the rock with oxidized gas. (3) The most important outcome of this work is the identification of the features of alteration by the volcanic gas that directly reacts with the rock at high temperatures (T > 500°C). The Kudryavy rocks show evidences for mineral transformations, which occur in the presence of the volcanic gas phase. Volcanic gas directly reacts with rocks at high temperatures (T > 500°C). The gas destabilizes the primary minerals, remobilizes the rock-bearing cations, and leads to the formation of second mineral assemblages. These transformations occur in situ, without significant mobility (gain or loss) of the cations. The high temperature secondary associations are characterized by the presence of andradite, hedenbergite, hercynite, tridymite/cristobalite. Anhydrite and anhydrous Al sulfate may occur within these mineral assemblages if the gas is oxidized. gas-rock alteration acidic alteration thermochemical modeling aerosols incrustations sublimates trace elements volcanic gases
14	Physical and chemical signatures of degassing in volcanic systems / Wright, Heather Michelle. January 2006 (has links) Thesis (Ph. D.)--University of Oregon, 2006. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 162-173). Also available for download via the World Wide Web; free to University of Oregon users.
15	Understanding Crustal Volatiles : Provenance, Processes and Implications Blythe, Lara S. January 2012 (has links) Knowledge of the provenance of crustal volatiles and the processes by which they are released is extremely important for the dynamics of magmatic systems. Presented here are the results of multiple investigations, which aim to understand magmatic volatile contamination from contrasting but complementary perspectives. The main methodologies used include He and C isotope values and CO2/3He ratios of volcanic gases and fluids; simulation of magma-carbonate interaction using high-pressure high-temperature experimental petrology; X-ray microtomography of vesiculated xenoliths and computer modeling. Findings show that the contribution from upper crustal volatiles can be substantial, and is dependant on the upper crustal lithology on which a volcano lies, as well as the composition of the magma supplied. Carbonate dissolution in particular is strongly controlled by the viscosity of the host magma. The details of the breakdown of vesiculated xenoliths is complex but has wide reaching implications, ranging from the dissemination of crustally derived materials through a magma body to highlighting that crustal volatiles are largely unaccounted for in both individual volcano and global volatile budgets. In synthesizing the conclusions from each of the individual perspectives presented, I propose the contribution of volatiles from crustal sources to play a significant role in many geological systems. This volatile component should be taken into consideration in future research efforts. crustal volatiles helium carbon volcanic gases and fluids xeno-pumice magma-carbonate interaction upper crustal contamination
16	Volatile release and atmospheric effects of basaltic fissure eruptions Thordarson, Thorvaldur January 1995 (has links) Thesis (Ph. D.)--University of Hawaii at Manoa, 1995. / Includes bibliographical references (leaves 556-580). / Microfiche. / 2 v. (xv, 580 leaves, bound) ill., maps, col. photos. 29 cm Lava flows -- Columbia River Valley
17	Magma degassing during the 1912 eruption of Novarupta, Alaska : textural analyses of pyroclasts representing changes in eruptive intensity and style Adams, Nancy K January 2004 (has links) Includes appendix on CD-ROM (p. 157). / Thesis (Ph. D.)--University of Hawaii at Manoa, 2004. / Includes bibliographical references (leaves 158-175). / Also available by subscription via World Wide Web / xiv, 175 leaves, bound ill. (some col., one folded), maps (some col.) 29 cm. + Magmatism Volcanic gases
18	Imaging measurements of volcanic SO2 using space and ground based sensors / Mesures imageantes du SO2 volcanique depuis l'espace et le sol Campion, Robin 17 June 2011 (has links) Sulfur dioxide (SO2) is a gas typical of high temperature magmatic degassing, being its<p>third most abundant constituent after water vapor and carbon dioxide. SO2 flux measurements<p>are used to characterized and monitor volcanic degassing. This thesis presents advanced<p>methods for measuring the SO2 emitted in the troposphere by passive degassing volcanoes.<p>These methods are based on the absorption of infrared (IR) and ultraviolet (UV) light by SO2<p>molecules. They make use of the data acquired by satellite borne sensors (ASTER, OMI and<p>MODIS), and collected in the field using a UV camera equipped with filters<p>ASTER is a multispectral sensor observing the Earth in the thermal IR with a 90 m<p>ground resolution. The developed retrieval algorithm works with band ratios<p>(B10+B12)/2B11 and B14/B11, to avoid spectral interference from other variables than SO2.<p>With this algorithm, the impact of interferers such as atmospheric water vapor, sulfate<p>aerosols and ground emissivity is minimal, as demonstrated by radiative transfer simulations<p>by applying of the algorithm to real ASTER images and by comparing the results with ground<p>based data. ASTER is a kind of unifying thread for this thesis because its high ground<p>resolution fills the gap existing between highly localized ground based SO2 measurements and<p>the global coverage of other satellites with coarser pixels such as OMI and MODIS.<p>OMI is an imaging spectrometer operating in the UV, with a daily global coverage, a<p>high sensitivity to SO2 and a ground resolution of 13x24km. The OMI-ASTER comparison<p>shows that the SO2 columns measured on OMI pixels are two orders of magnitude smaller<p>than those of ASTER, because of the huge difference in the pixel size of the two satellites.<p>The flux measurements however are generally in good agreement. The analysis of a large<p>number of images shows that ASTER is better for cloud free scenes while OMI has an<p>optimal signal to noise ratio when the plume is lying above a low cloud cover. A practical<p>detection limit for SO2 flux measurements in tropospheric plumes has also been established:<p>5kg/s.<p>The comparison between ASTER measurements of SO2 column amounts with those of<p>MODIS (a multispectral IR imager with 1km ground resolution) shed light on systematic<p>errors in MODIS measurements. These errors were quantified and their origins were separated<p>and identified. This work demonstrates the limitations of MODIS for SO2 measurements.<p>A UV camera equipped with filters has also been developed to achieve 2D SO2 from the<p>ground at a high spatial and temporal resolution. The potential provided by this new type of<p>instruments has been demonstrated during a field campaign on Turrialba Volcano (Costa<p>Rica). The integration of measurements obtained using the camera, ASTER and OMI revealed<p>a high and sustained SO2 flux, which can be explained only by the degassing of a recently<p>intruded magma body. The slow decrease of SO2 flux since January 2010 suggests a<p>progressive exhaustion of the volatile content of the magma.<p>Finally, we applied the band ratio algorithm to a series of ASTER images of the recent<p>eruption of Eyjafjallajökull in April-May 2010. The SO2 measurements provide interesting<p>insights into the complex eruptive dynamics and into the control of hydromagmatic<p>interactions on eruptive gas release into the atmosphere. /<p><p>Le dioxyde de soufre (SO2) est un gaz typique du dégazage magmatique de haute<p>température, dont il est le troisième composant le plus abondant derrière H2O et CO2. Le flux<p>de SO2 est un excellent paramètre pour caractériser le dégazage volcanique et surveiller son<p>évolution dans le temps. Cette thèse présente de nouvelles méthodes de mesures des flux de<p>SO2 émis par l’activité volcanique. Ces méthodes se basent sur l’absorption de la molécule de<p>SO2 dans l’infrarouge (IR) et l’ultraviolet (UV). Elles utilisent les données prises par des<p>senseurs embarqués sur des satellites (ASTER, OMI et MODIS) ou opérés depuis le sol<p>(caméra UV munie de filtres).<p>Le senseur ASTER opère dans l’IR thermique avec une résolution spatiale de 90 m par<p>pixel. L’algorithme de mesure développé pour ce satellite n’est sensible qu’à la concentration<p>en SO2 et pratiquement pas aux paramètres interférents qui posaient problèmes aux méthodes<p>existantes :la vapeur d’eau atmosphérique, les aérosols de sulfate dans le panache et<p>l’émissivité de la surface sous-jacente. ASTER est un peu le fil conducteur de cette thèse, car<p>sa haute résolution spatiale lui permet de faire le lien entre des mesures au sol et les mesures<p>faites par d’autres satellites comme OMI et MODIS.<p>Le satellite OMI est un spectromètre imageant qui opère dans l’UV, avec une<p>couverture globale journalière, une haute sensitivité au SO2 et une résolution spatiale de<p>13x24km. La comparaison OMI-ASTER montre que les colonnes mesurées sur les pixels<p>d’OMI sont de deux ordres de grandeur inférieurs à celles d’ASTER, à cause de la différence<p>de résolution spatiale entre les deux satellites. Les mesures de flux, par contre, montrent une<p>très bonne concordance. L’analyse d’un grand nombre d’images a permis d’établir qu’ASTER<p>est meilleur pour des scènes sans nuages tandis qu’OMI est meilleur quand une couverture<p>nuageuse présente sous le panache augmente son rapport signal sur bruit. Une limite de<p>détection pratique a aussi été établie pour les flux de SO2 dans les panaches volcaniques dans<p>la basse troposphère :5kg/s.<p>La comparaison des mesures d’ASTER avec celle de MODIS a permis de démontrer les<p>limites de MODIS pour la mesure du SO2. Des erreurs systématiques sur les mesures de<p>MODIS on été mises en évidence et quantifiées. Ces erreurs sont dues aux interférents<p>spectraux que sont la vapeur d’eau atmosphérique et les aérosols sulfatés. L’émissivité est<p>aussi un important facteur d’erreur pour MODIS.<p>Une caméra UV équipée d’un système de filtres a également été développée pour<p>mesurer le SO2 en 2D, à haute résolution spatiale et temporelle. Le potentiel offert par ce<p>nouveau type d’instrument a été démontré lors d’une campagne de mesures sur le volcan<p>Turrialba (Costa Rica). La combinaison de mesures de SO2 réalisée avec la caméra, ASTER<p>et OMI a permis de mettre en évidence des flux très élevés (30-50kg/s) qui ne peuvent<p>s’expliquer que par une intrusion récente de magma juvénile en cours de dégazage.<p>Enfin, les mesures de SO2 ont réalisées à partir des images ASTER pendant l’éruption<p>du volcan Eyjafjallajökull en avril-mai 2010. Ces mesures fournissent des informations<p>intéressantes sur les dynamismes éruptifs qui se sont succédé et sur le contrôle des émissions<p>de SO2 dans l’atmosphère par les interactions magma-eau. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Sciences de la terre et du cosmos Sciences exactes et naturelles Sulfur dioxide Volcanic gases -- Measurement Volcanic gases -- Environmental aspects Anhydride sulfureux Gaz volcaniques -- Mesure remote sensing/télédétéction ASTER volcanic degassing/dégazage volcanique OMI MODIS Camera UV
19	Reactive processes during the discharge of high temperature volcanic gases Africano, Fatima 25 January 2005 (has links) This study shows how the composition of gases released from a single magmatic source may be modified during their ascending path. The main processes that influence the composition of the gases in these high temperature fumarolic environments, are: 1) interactions with wallrocks during gas ascent, which change the fugacities of the metal volatile species and affect the equilibrium between major species (fH2S/fSO2; fH2/fH2O); 2) mixing with meteoric water with consequent Cl adsorption, which may account for the Cl depletion of the gases; 3) remobilisation of previously formed sublimates and/or incrustation deposits. Comparison between the thermochemical models and the mineralogical composition of the silica tubes at Kudryavy and Satsuma-Iwojima volcanoes suggests that high fO2 due to the mixing of the gases with air during their injection into the atmosphere significantly reduces the volatility of several trace elements (As, Sb, Sn, Na, K, Tl, Te, Se and Cd). Comparisons between the enriched metals in aerosols and in the gases suggest that Mo, Pb, Bi, Na, K, Cu, Zn or Fe, which are enriched in the gases, are preferentially deposited in the gas conduits and vents whereas the highly volatile metals (Te, Tl, Sb, As and Se) and Cd condense in the plume.<p>This study determines the reactions that may occur during the alteration of rocks in high temperature fumarolic environments. Three different processes of alteration prevail: <p>(1) Acidic alteration which is characterized by the complete absence of clays, because the constant supply of gases to these systems allows for the pH values of the acidic fluids to be maintained low enough to prevent the precipitation of clay minerals. Complete leaching of all cations, except Si, from the primary silicates leads to important "silicification" of the wall rock. The primary mineral cations are leached in the following order: K, Na > Ca > Fe, Mg > Al > Si, Ti. The fluids enriched in these cations circulate in microcracks at different temperatures and different redox conditions and lead to the precipitation of secondary incrustations. At Kudryavy the incrustations are mainly sulfates. At Usu the lower sulfur/fluoride ratio of the gases allows the occurrence of aluminum fluoride incrustations. The order of primary minerals dissolution (olivine > plagioclase > pyroxene > matrix glass > Fe-Ti oxides) is established for both sites studied. <p>(2) Alteration by an oxidized volcanic gas, resulting from mixing with the atmosphere (500 to 300°C). At Kudryavy, thermochemical modeling suggests that anhydrite and anhydrous sulfates, which occur at intermediate temperatures, are formed by interactions of the rock with oxidized gas. <p>(3) The most important outcome of this work is the identification of the features of alteration by the volcanic gas that directly reacts with the rock at high temperatures (T > 500°C). The Kudryavy rocks show evidences for mineral transformations, which occur in the presence of the volcanic gas phase. Volcanic gas directly reacts with rocks at high temperatures (T > 500°C). The gas destabilizes the primary minerals, remobilizes the rock-bearing cations, and leads to the formation of second mineral assemblages. These transformations occur in situ, without significant mobility (gain or loss) of the cations. The high temperature secondary associations are characterized by the presence of andradite, hedenbergite, hercynite, tridymite/cristobalite. Anhydrite and anhydrous Al sulfate may occur within these mineral assemblages if the gas is oxidized.<p> / Doctorat en sciences, Spécialisation géologie / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles Sciences de la terre et du cosmos Volcanism Volcanic gases Gases at high temperatures Igneous rocks Volcanisme Gaz volcaniques Gaz à haute température Roches ignées incrustations aerosols thermochemical modeling acidic alteration gas-rock alteration sublimates trace elements volcanic gases
20	The cuticle micromorphology of extant and fossil plants as indicator of environmental conditions : A pioneer study on the influence of volcanic gases on the cuticle structure in extant plants Bartiromo, Antonello 14 February 2012 (has links) (PDF) Macroscopical and microscopical observations on extant and fossil plants have been made. Observations on extant plants led to study the effects of volcanic gases on the cuticle ultrastructure of Pinus halepensis and Erica arborea sampled in the volcanic area of Phlegrean Italy. TEM observations on P. halepensis cuticles fumigated or not by volcanic gases revealed: 1) insignificant thickness variations of the cell wall plus cuticle among current- and first-year-old needles of both fumigated and not fumigated trees; 2) a calcium oxalate accumulation in fumigated leaves; 3) moreover, in respect to the cell surface, fibrils are disposed parallel to the surface of the cuticle. In specimens of E. arborea fumigated or not by volcanic gases, 1) the total thickness of cuticles varies significantly; 2) in plants experiencing chronic fumigation the A2 layer increases its thickness. As for fossil plants, the cuticles of Cretaceous Fossil-Lagertätten of Cusano Mutri and Pietraroja have been studied. In the former: 1) numerous taxa belonging to conifers have been identified; 2) the new species Frenelopsis cusanensis has been described; 3) Montsechia vidalii has been found outside of Spain. Taxonomical studies allowed the description of typical Euro-Sinian fossil plants. Sedimentological and taxonomical studies suggest semi-arid or arid conditions in a subtropical or tropical climate. It is worth noting as for Cusano Mutri locality, evidence of wildfire (fusain) suggests a periodic combination of arid periods, high temperatures and lightning strikes. Campi Flegrei Volcanic gases Pinus halepensis Erica arborea Cuticle ultrastructure Hydrogen sulphide (H2S) Cheirolepidiaceae Early Cretaceous

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