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Physical Volcanology of the 1666 C.E. Cinder Cone Eruption, Lassen Volcanic National Park, CAMarks, Jessica, Marks, Jessica January 2012 (has links)
Cinder Cone is the most recent cinder cone eruption in the continental United States at ~350 years old. This study examines the physical characteristics of the explosive deposit of the volcano in order to infer eruption timing, style, and mechanisms. Building on previous work and using spatial extent, field relationships, and grain size, componentry, and textural data of ten samples from one column, this study demonstrates that Cinder Cone erupted in at least two distinct phases with at least two distinct eruption styles. This speaks to the changing magma supply and transport processes occurring beneath the volcano. Curiosities about the eruption include the extensive degree of contamination that contributed abundant quartz xenocrysts to all the deposits. Future work includes determining the extent and mechanism/s of contamination and tephra component creation. These data are important for informing hazard assessments of areas with abundant cinder cone volcanoes.
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Magmatic volatile contents and explosive cinder cone eruptions in the High Cascades: Recent volcanism in Central Oregon and Northern California / Recent volcanism in Central Oregon and Northern CaliforniaRuscitto, Daniel M., 1981- 03 1900 (has links)
xvi, 182 p. : col. ill. / Volatile components (H 2 O, CO 2 , S, Cl) dissolved in magmas influence all aspects of volcanic activity from magma formation to eruption explosivity. Understanding the behavior of volatiles is critical for both mitigating volcanic hazards and attaining a deeper understanding of large-scale geodynamic processes. This work relates the dissolved volatile contents in olivine-hosted melt inclusions from young volcanics in the Central Oregon and Northern California Cascades to inferred magmatic processes at depth and subsequent eruptive activity at the surface.
Cinder cone eruptions are the dominant form of Holocene volcanism in the Central Oregon segment of the High Cascades. Detailed field study of deposits from three cinder cones in Central Oregon reveals physical and compositional similarities to explosive historic eruptions characterized as violent strombolian. This work has important implications for future hazard assessments in the region. Based on melt inclusion data, pre-eruptive volatile contents for seven calc-alkaline cinder cones vary from 1.7-3.6 wt.% H 2 O, 1200-2100 ppm S, and 500-1200 ppm Cl. Subarc mantle temperatures inferred from H 2 O and trace elements are similar to or slightly warmer than temperatures in other arcs, consistent with a young and hot incoming plate.
High-magnesium andesites (HMA) are relatively rare but potentially important in the formation of continental crust. Melt inclusions from a well-studied example of HMA from near Mt. Shasta, CA were examined because petrographic evidence for magma mixing has stimulated a recent debate over the origin of HMA magmas. High volatile contents (3.5-5.6 wt.% H 2 O, 830-2900 ppm S, 1590-2580 ppm Cl), primitive host crystals, and compositional similarities with experiments suggest that these inclusions represent mantle-derived magmas.
The Cascades arc is the global end member, warm-slab subduction zone. Primitive magma compositions from the Cascades are compared to data for arcs spanning the global range in slab thermal state to examine systematic differences in slab-derived components added to the mantle wedge. H 2 O/Ce, Cl/Nb, and Ba/La ratios negatively correlate with inferred slab surface temperatures predicted by geodynamic models. Slab components become increasingly solute-rich as slab surface temperatures increase from ∼550 to 950°C at 120 km depth.
This dissertation includes previously published and unpublished co-authored material. / Committee in charge: Dr. Paul J. Wallace, Chair and Advisor;
Dr. Katharine Cashman, Member;
Dr. Ilya Bindeman, Member;
Dr. Richard Taylor, Outside Member
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Budgets éruptifs et origine des paroxysmes explosifs andésitiques en système ouvert : l'éruption d'août 2006 du Tungurahua en Equateur / Eruptive budgets and origin of andesitic explosive paroxysms in open systems : the August 2006 eruption of the Tungurahua in EcuadorEychenne, Julia 13 January 2012 (has links)
Plusieurs volcans andésitiques dans le monde connaissent des périodes d’activité en système ouvert pendant plusieurs années, décennies voire siècles, qui sont caractérisées par des manifestations éruptives persistantes d’intensité fluctuante et ponctuées de phases explosives violentes et dangereuses, souvent accompagnées d’écoulements pyroclastiques. La compréhension de la dynamique et de l’origine de ces paroxysmes en système ouvert est un enjeu majeur de la recherche volcanologique dans le but d’améliorer la surveillance de ce type d’activité. Le Tungurahua en Equateur est un excellent exemple pour étudier un système andésitique ouvert : entré en activité en 1999, le volcan a connu une phase paroxysmale en août 2006, avec l’émission d’un panache éruptif de 15 km de hauteur et la mise en place d’écoulements pyroclastiques. Les objectifs de cette thèse sont, à partir de l’étude du dépôt de retombée, d’explorer la dynamique d’un volcan andésitique fonctionnant en système ouvert en étudiant le cas du paroxysme explosif du Tungurahua et de développer une méthode de suivi haute-résolution des budgets éruptifs massiques, transposable à différentes phases éruptives et différents volcans. A l’aide d’une déconvolution automatique des distributions granulométriques bimodales du dépôt, deux sous-populations ont été caractérisées et quantifiées. Ces dernières reflètent la syn-sédimentation de particules grossières depuis le panache éruptif, et de particules fines depuis des nuages co-écoulements pyroclastiques. Cette analyse granulométrique couplée à l’étude de l’amincissement du dépôt indiquent un volume total minimum de 42×106 m3 et un panache de 16-18 km au dessus du cratère. Cette éruption est classée comme une VEI 3 de type subplinien. Un nouveau protocole d’analyses de type et densité de clastes révèle une distribution sigmoïdale des densités des particules vésiculées avec la granulométrie. Cette loi empirique permet de déterminer la charge massique de chaque classe de constituants latéralement dans le dépôt à partir des données de comptage de grains. L’intégration des lois de décroissance massique exponentielle et puissance de chaque classe de constituant dans le dépôt permet d’estimer leur masse totale. Ces budgets massiques indiquent une magnitude~3,5 et une intensité ~9,2. La faible masse de ponces acides (<0.4 wt.%) exclus une origine par mélange de magma. Une proportion de ~98 wt.% et la faible densité de produits juvéniles révèle le caractère magmatique de l’éruption et l’absence d’interactions phréato-magmatiques. Les xénoclastes témoignent d’une fragmentation et d’une érosion des 2 km supérieurs du conduit. Des analyses morphologiques de particules menées avec un outil automatique et innovant (Morphologi G3 de Malvern) montrent le caractère hautement vésiculé des particules juvéniles et la faible viscosité de la lave. L’explosivité élevée d’août 2006 apparaît comme une manifestation extrême d’un système ouvert alimenté par des injections irrégulières de magma andésitique profond. L’activité du Tungurahua depuis 1999 définit un système caractérisé par un conduit très ouvert, une lave peu visqueuse et un dégazage par le biais d’explosions stromboliennes de faibles à hautes intensités. La méthode de détermination des budgets éruptifs est un atout majeur pour le suivi et la surveillance des phases éruptives en système ouvert. / Many andesitic volcanoes at subduction plate margins can experience in the course of their evolution periods of continuous eruption during years, decades, or centuries characterized by a fluctuation of the activity interrupted by explosive events of varying size and duration, with possible production of pyroclastic density currents. Magmatic activity lasts for long periods of time before violent explosive eruptions occur, which makes the forecasting of such events a real challenge. I focus on the case of Tungurahua, one of Ecuador’s most active volcanoes, which started an open-vent eruptive period in 1999. The paroxysmal phase occurred in August 2006 and resulted in a sustained eruption column associated with pyroclastic flows and surges. From the study of the tephra fall deposit, the aims of this work are to understand the origin and the dynamics of the August 2006 explosive paroxysmal phase and to develop a transposable method of high-resolution analysis of eruptive mass budgets. Based on a new grainsize deconvolution algorithm, two subpopulations of grains were distinguished, characterized and quantified in the bimodal distributions of the tephra fall deposit. These subpopulations result from the syn-deposition of coarse grains from the main volcanic plume and fine-grained ash elutriated from pyroclastic flows. A bulk minimum tephra volume ~42×106 m3 and a column height of 16-18 km above the vent are assessed. These data support a VEI 3 event of subplinian type. Detailed componentry counting and particle density analyses allow to propose a sigmoidal law to describe the particle density variations with grainsize of vesicular grains. This law is used to calculate the mass per unit area of the componentry classes laterally in the deposit, from the results of the componentry analyses. Integrating the mass decay rates of the componentries in the deposit, we infer their total mass. Results point to a mass magnitude of~3.5 and an intensity of ~9.2. The pumice mass fraction is far too small (< 0.4 %) to account for the high explosivity of the 2006 event. The high juvenile content in the deposit (~98 wt.%)supports a magmatic origin of the eruption, and no phreatic influence on the overall explosivity. The nature and content of non-magmatic material imply that fragmentation and erosional behaviour occurred in the upper ~2 km of the plumbing system. Morphological analyses performed with Morphologi G3 instrument (Malvern) show a high vesicularity of the products and a low viscosity of the lava. These results support an explosive event fed by a deep gas-rich andesitic reinjection, which would have incorporated a pocket of older differentiated magma and eroded the upper conduit during the sub-plinian event. Tungurahua activity describes a eruptive system characterized by an open-vent, a low lava viscosity and a degassing behaviour through strombolian explosions of weak to high intensity. The high-resolution mass-based approach reveals useful to decipher the origin of the violent 2006 paroxysm and has potential to improve magnitude determinations of ancient eruption by considering componentry mass instead of volume. It is also applicable for monitoring purposes in the context of on-going crises at many andesitic eruptive worldwide.
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