Global ETD Search

1	Seismic Structure of the Western U.S. Mantle and Its Relation to Regional Tectonic and Magmatic Activity Schmandt, Brandon, 1984- 09 1900 (has links) xii, 95 p. : ill. (some col.) / Vigorous convective activity in the western U.S. mantle has long been inferred from the region's widespread intra-plate crustal deformation, volcanism, and high elevations, but the specific form of convective activity and the degree and nature of lithospheric involvement have been strongly debated. I design a seismic travel-time tomography method and implement it with seismic data from the EarthScope Transportable Array and complementary arrays to constrain three-dimensional seismic structure beneath the western U.S. Tomographic images of variations in compressional velocity, shear velocity, and the ratio of shear to compressional velocity in the western U.S. mantle to a depth of 1000 km are produced. Using these results I investigate mantle physical properties, Cenozoic subduction history, and the influence of small-scale lithospheric convection on regional tectonic and magmatic activity, with particular focus on southern California and the Pacific Northwest. This dissertation includes previously published co-authored material. Chapter II presents a travel-time tomography method I designed and first implemented with data from southern California and the surrounding southwestern U.S. The resulting images provide a new level of constraint on upper mantle seismic anomalies beneath the Transverse Ranges, southern Great Valley, Salton Trough, and southwestern Nevada volcanic field. Chapter III presents tomographic images of the western U.S. mantle, identifies upper mantle volumes where partial melt is probable, and discusses implications of the apparently widespread occurrence of gravitational instabilities of continental lithsophere and the complex geometry and buoyancy of subducted ocean lithosphere imaged beneath the western U.S. In Chapter IV, tomography images are used in conjunction with geologic constraints on major transitions in crustal deformation and magmatism to construct a model for Pacific Northwest evolution since the Cretaceous. Accretion in the Pacific Northwest at 55-50 Ma is suggested to stimulate roll-back of the flat subducting Farallon slab. This change in convergent margin structure is further suggested to drive the short-lived Challis magmatic trend and trigger the southward propagating Eocene-Oligocene transition from the Laramide orogeny to widespread crustal extension and ignimbrite magmatism. / Committee in charge: Eugene Humphreys, Chair; Douglas Toomey, Member; Emilie Hooft Toomey, Member; John Conery, Outside Member Geophysics Earth sciences Seismic structure Western U.S. mantle Regional tectonic activity Magmatic activity
2	Structure profonde de la croûte et potentiel pétrolier des bassins sédimentaires à l'ouest de l'Algérie / Deep structure of the crust and petroleum potential of sedimentary basins of West Algeria Badji, Rabia 25 June 2014 (has links) La marge algérienne borde le bassin algérien, formé en position de bassin arrière-arc de la subduction Téthysienne. L'importance de l'étude du segment de marge qui s'étend de Ténès à Mostaganem sur environ 250 km, réside dans sa position charnière entre le domaine continental d'Alborán à l'Ouest et le bassin océanique algérien à l'Est. Dans ce travail nous avons déterminé pour la première fois, la structure et la nature de la croûte de ce segment, à partir de l'inversion tomographique des données de sismique grand-angle d'un profil N-S perpendiculaire à la marge. Grâce aux traitements des données de sismique réflexion multitrace acquises pendant la campagne SPIRAL et aux données industrielles, nous avons pu proposer un schéma tectonique régional et une cartographie de l'extension possible du socle Kabyle en mer. Les résultats révèlent une marge caractérisée par la juxtaposition d'une croûte océanique peu épaisse au nord et d'une croûte continentale amincie au sud de part et d'autre d'un accident vertical. L'ouverture du bassin océanique résulterait de la réponse à la déchirure du panneau lithosphérique en subduction sous Gibraltar, accompagné par la migration du bloc Alborán vers l'Ouest. La propagation de cette déchirure (STEP) a généré une zone de cisaillement qui se focalise dans zone de transition océan-continent. L'inversion tectonique qui affecte plus à l'Est la marge semble s'arrêter à la latitude de Ténès. Cette absence de déformation en mer coïncide avec une lacune de sismicité liée à la résistance mécanique de la marge. Par comparaison à d'autres régions du monde, seules les zones situées sur la croûte continentale pourraient présenter un potentiel pétrolier. / Located in North Africa, the Algerian margin is bordering the Algerian basin, formed in the back of the Tethyan subduction. The importance of the study of the segment extending from Tenes to Mostaganem over 250 km, lies in its pivotal position between the continental Alborán domain to the West and the Algerian Basin to the East. In this work, we determined for the first time, the structure and the crustal nature of this segment using the tomographic inversion of the seismic data recorded along a N-S wide-angle seismic profile shot perpendicular to the margin. Thanks to the multichannel reflection seismic data acquired during SPIRAL (2009), and to industrial data, we have proposed a regional tectonic pattern and the possible offshore extension of the kabylian basement The results reveal a margin characterized by the juxtaposition of a thin oceanic crust to the North and a slightly thinned continental crust to the South on either side of a major vertical accident. This suggests that the margin is formed in a strike-slip context. The opening of the oceanic basin should result from the response to the retreat and to the tear of the lithospheric slab beneath the Gibraltar subduction, accompanied by the westward migration of the Alborán block. The propagation of this lithospheric tearing (STEP) generated a zone of strike-slip along the narrow ocean-continent transition. The offshore absence of seismicity along our segment is connected to the mechanical resistance of the margin due to rapid change of crust nature. Owing the results and compared with other regions of the world, the areas which can likely present oil potential are the ones located on the continental crust. Marge algérienne Mostaganem Structure sismique Faille STEP Tomographie sismique Sismique réflexion Algerian margin Mostaganem Seismic structure STEP fault Seismic tomography Multichannel seismic
3	Investigation sismique du domaine avant-arc Égéen du segment Sud-Ouest de la zone de subduction Hellénique / Seismic investigation of the forearc domain of the southwestern segment of the Hellenic subduction zone Vitard, Clément 01 December 2016 (has links) La zone de subduction Hellénique, en Méditerranée orientale, est caractérisée par le taux de sismicité le plus important d’Europe. Des séismes de forte magnitude (Mw 7,5-8) ont eu lieu le long du segment Sud-Ouest de la zone de subduction Hellénique, au large du Péloponnèse, au cours du 19ème et 20ème siècle. Ce segment de 400 km de long a également été le lieu de nucléation du plus important séisme d’Europe, en 365 ap J.C, avec une magnitude supérieure à 8, ayant entraîné un tsunami dévastateur. Deux principaux modèles scientifiques s’opposent sur la question du couplage sismique de l’interface de subduction, allant d’un couplage sismique total au niveau de l’interface, à l’hypothèse opposée d’un couplage quasi inexistant. Cependant, ces modèles opposés considèrent des géométries approximatives et parfois extrêmes, fautes de contraintes disponibles sur la structure et la géométrie de l’interplaque sous l’avant-arc dans cette zone. La localisation de la faille responsable du séisme de 365 ap J.C est également débattue, en l’absence de données géophysiques permettant d’identifier les interfaces potentiellement responsables de cet événement dévastateur. La faille de méga-chevauchement et le domaine avant-arc du segment Sud-Ouest de l’arc Hellénique ont été l’objet d’étude de la campagne océanographique Ulysse en Novembre 2012 afin de déterminer la géométrie des structures et unités majeures dans cette portion de la zone de subduction, mais également d’apporter un éclairage sur la tectonique récente qui affecte cette zone / The Hellenic subduction zone, in the eastern part of the Mediterranean sea, is characterized by the highest rate of current seismicity in Europe. In the southwestern segment, several earthquakes of large magnitude (Mw 7,5-8) occured a the turn of the 19th to 20th century. This segment of 400 km long, has also been the nucleation site of the largest historical earthquake in Europe, named the 365 AD earthquake, with a magnitude of Mw 8. This event generates a devastating tsunami, which spread along the Adriactic Sea and in the Nile Delta region. Two main models differ about the interplate seismic coupling question in this region, from a total seismic coupling at the interplate, at the opposite assumption of a very weak seismic coupling. However, these opposing models consider an approximate geometry, mostly because of the lack of information available on the geometry and the localization of the interplate in this region of the forearc domain. The localization of the fault responsible of the 365 AD event is also debated, because, there is no available data who provides imagery of the interfaces potentially responsible of this devastating earthquake. The megathrust fault and the forearc domain of the southwestern segment of the Hellenic subduction zone has been the target of the Ulysse marine survey in November 2012. The aim of this survey was to provide information of the structural geometry of the main units in this part of the subduction zone, and to bring information on the recent tectonic activity in this region Zone de subduction Hellénique Structure sismique Faille de méga-chevauchement Tomographie sismique Sismique réflexion Hellenic subduction zone Seismic structure Megathrust fault Seismic tomography Seismic reflection
4	Seismic structure, gas hydrate, and slumping studies on the Northern Cascadia margin using multiple migration and full waveform inversion of OBS and MCS data Yelisetti, Subbarao 05 November 2014 (has links) The primary focus of this thesis is to examine the detailed seismic structure of the northern Cascadia margin, including the Cascadia basin, the deformation front and the continental shelf. The results of this study are contributing towards understanding sediment deformation and tectonics on this margin. They also have important implications for exploration of hydrocarbons (oil and gas) and natural hazards (submarine landslides, earthquakes, tsunamis, and climate change). The first part of this thesis focuses on the role of gas hydrate in slope failure observed from multibeam bathymetry data on a frontal ridge near the deformation front off Vancouver Island margin using active-source ocean bottom seismometer (OBS) data collected in 2010. Volume estimates (∼ 0.33 km^3) of the slides observed on this margin indicate that these are capable of generating large (∼ 1 − 2 m) tsunamis. Velocity models from travel time inversion of wide angle reflections and refractions recorded on OBSs and vertical incidence single channel seismic (SCS) data were used to estimate gas hydrate concentrations using effective medium modeling. Results indicate a shallow high velocity hydrate layer with a velocity of 2.0 − 2.1 km/s that corresponds to a hydrate concentration of 40% at a depth of 100 m, and a bottom simulating reflector (BSR) at a depth of 265 − 275 m beneath the seafloor (mbsf). These are comparable to drilling results on an adjacent frontal ridge. Margin perpendicular normal faults that extend down to BSR depth were also observed on SCS and bathymetric data, two of which coincide with the sidewalls of the slump indicating that the lateral extent of the slump is controlled by these faults. Analysis of bathymetric data indicates, for the first time, that the glide plane occurs at the same depth as the shallow high velocity layer (100±10 mbsf). In contrast, the glide plane coincides with the depth of the BSR on an adjacent frontal ridge. In either case, our results suggest that the contrast in sediments strengthened by hydrates and overlying or underlying sediments where there is no hydrate is what causing the slope failure on this margin. The second part of this dissertation focuses on obtaining the detailed structure of the Cascadia basin and frontal ridge region using mirror imaging of few widely spaced OBS data. Using only a small airgun source (120 cu. in.), our results indicate structures that were previously not observed on the northern Cascadia margin. Specifically, OBS migration results show dual-vergence structure, which could be related to horizontal compression associated with subduction and low basal shear stress resulting from over-pressure. Understanding the physical and mechanical properties of the basal layer has important implications for understanding earthquakes on this margin. The OBS migrated image also clearly shows the continuity of reflectors which enabled the identification of thrust faults, and also shows the top of the igneous oceanic crust at 5−6 km beneath the seafloor, which were not possible to identify in single-channel and low-fold multi-channel seismic (MCS) data. The last part of this thesis focuses on obtaining detailed seismic structure of the Vancouver Island continental shelf from MCS data using frequency domain viscoacoustic full waveform inversion, which is first of its kind on this margin. Anelastic velocity and attenuation models, derived in this study to subseafloor depths of ∼ 2 km, are useful in understanding the deformation within the Tofino basin sediments, the nature of basement structures and their relationship with underlying accreted terranes such as the Crescent and the Pacific Rim terranes. Specifically, our results indicate a low-velocity zone (LVZ) with a contrast of 200 m/s within the Tofino basin sediment section at a depth 600 − 1000 mbsf over a lateral distance of 10 km. This LVZ is associated with high attenuation values (0.015 − 0.02) and could be a result of over pressured sediments or lithology changes associated with a high porosity layer in this potential hydrocarbon environment. Shallow high velocities of 4 − 5 km/s are observed in the mid-shelf region at depths > 1.5 km, which is interpreted as the shallowest occurrence of the Eocene volcanic Crescent terrane. The sediment velocities sharply increase about 10 km west of Vancouver Island, which probably corresponds to the underlying transition to the Mesozoic marine sedimentary Pacific Rim terrane. High attenuation values of 0.03 − 0.06 are observed at depths > 1 km, which probably corresponds to increased clay content and the presence of mineralized fluids. / Graduate / 0373 / 0372 / 0605 / subbarao@uvic.ca seismic structure gas hydrate submarine landslides or slumps Northern Cascadia margin multiple migration full waveform inversion visco-acoustic wave equation tomography fluid flow earth quakes hydrocarbon exploration tectonics bottom simulating reflection or BSR seismic attenuation ocean bottom seismic data mutli-channel seismic data single-channel seismic data airgun source dual-vergence structure low velocity zone high velocity region Crescent terrane Pacific Rim terrane normal faults frontal thrusts and backthrust

1

Page generated in 0.0635 seconds