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Investigating Crustal Deformation Associated With The North America-Pacific Plate Boundary In Southern California With GPS GeodesySpinler, Joshua C. January 2014 (has links)
The three largest earthquakes in the last 25 years in southern California occurred on faults located adjacent to the southern San Andreas fault, with the M7.3 1992 Landers and M7.1 1999 Hector Mine earthquakes occurring in the eastern California shear zone (ECSZ) in the Mojave Desert, and the M7.2 2010 El Mayor-Cucapah earthquake occurring along the Laguna Salada fault in northern Baja California, Mexico. The locations of these events near to but not along the southern San Andreas fault (SSAF) is unusual in that the last major event on the SSAF occurred more than 300 years ago, with an estimated recurrence interval of 215± 25 years. The focus of this dissertation is to address the present-day deformation field along the North America-Pacific plate boundary in southern California and northern Baja California, through the analysis of GPS data, and elastic block and viscoelastic earthquake models to determine fault slip rates and rheological properties of the lithosphere in the plate boundary zone. We accomplish this in three separate studies. The first study looks at how strain is partitioned northwards along-strike from the southern San Andreas fault near the Salton Sea. We find that estimates for slip-rates on the southern San Andreas decrease from ~23 mm/yr in the south to ~8 mm/yr as the fault passes through San Gorgonio Pass to the northwest, while ~13-18 mm/yr of slip is partitioned onto NW-SE trending faults of the ECSZ where the Landers and Hector Mine earthquakes occurred. This speaks directly to San Andreas earthquake hazards, as a reduction in the slip rate would require greater time between events to build up enough slip deficit in order to generate a large magnitude earthquake. The second study focuses on inferring the rheological structure beneath the Salton Trough region. This is accomplished through analysis of postseismic deformation observed using a set of the GPS data collected before and after the 2010 El Mayor-Cucapah earthquake. By determining the slip-rates on each of the major crustal faults prior to the earthquake, we are able to model the pre-earthquake velocity field for comparison with velocities measured using sites constructed post-earthquake. We then determine how individual site velocities have changed in the 3 years following the earthquake, with implications for the rate at which the lower crust and upper mantle viscously relax through time. We find that the viscosity of the lower crust is at least an order of magnitude higher than that of the uppermost mantle, and hypothesize that this is due to mafic material emplaced at the base of the crust as the spreading center developed beneath the Salton Trough since about 6 Ma. The final study investigates crustal deformation and fault slip rates for faults in the northern Mojave and southern Walker Lane regions of the ECSZ. Previous geodetic studies estimated slip-rates roughly double those inferred via geological dating methods in this region for NW striking strike-slip faults, but significantly smaller than geologic estimates for the Garlock fault. Through construction of a detailed elastic block model, which selects only active fault structures, and applying a new, dense GPS velocity field in this region, we are able to estimate slip-rates for the strike-slip faults in the ECSZ that are much closer to those reported from geology.
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Mechanical Models of Coontinental Plate Boundaries Fault Slip Rates and Interseismic Stress Rotation RatesLangstaff, Meredith Avery 04 June 2015 (has links)
We first describe the methodology for a two-dimensional, elastic deformable microplate modeling approach for continental plate boundaries. Deformable microplate models combine discrete slip on microplate boundaries (faults) with continuous deformation in block interiors. Two idealized models simulating continental collision are presented, one with two microplates and one with four microplates. / Earth and Planetary Sciences
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Architecture of a Classification System to Evaluate Fault Slip Risk in a Mining EnvironmentVatcher, Jessica Lauren 02 June 2012 (has links)
As the depth of mining increases, so does the risk of fault slip related rockbursts. Currently, there is no way to evaluate this risk, however the need for such a system is clear. Fault behaviour in mining environments is the result of a complex interaction between the mining system and the geological system. Although numerous models exist, the wide spectrum of fault behaviour cannot be fully explained. Additionally, these models are phenomenological, resulting in a disconnect between observable parameters and the models of faults. Fault behaviour is dependent upon the strength of the fault, the stresses acting along the fault, the boundary conditions and fault-system stiffness. Significant work exists in the field of earth science attempting to relate properties of the geological system to fault behaviour. In mining environments, these relationships become increasingly difficult to determine due to the time variable nature of mining activities. In order of importance, the following factors influence fault behaviour: excavations, tectonic history and in situ stress, fault system, fault zone geometry, pore pressure, fault zone slip surface and core, blasting, fault zone damage zone and wall rock and temperature.
Numerical stress analysis models were created to evaluate the influence of excavations, tectonic history and in situ stress and the fault system on fault behaviour. Excavations were placed in various locations in a fault system. Results showed that there was no clear relationship between excavation location and fault behaviour; small perturbations in the initial state caused significantly different outcomes.
The architectures of many classification and decision support systems were evaluated for purposes of a fault slip classification system. Due to the chaotic nature of fault behaviour and the time variable nature of the factors that influence fault slip, a typical classification system is not an appropriate architecture. Instead, it is recommended that a fault slip risk identification system be created, allowing for the incorporation of historical and live data to create a real time response. Artificial neural networks, numerical stress analysis, data from the identified important factors, and seismic data is recommended to form the basis of the fault slip risk identification system. / Thesis (Master, Mining Engineering) -- Queen's University, 2012-06-01 13:17:08.453
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Caractérisation du fonctionnement des failles actives à l'Est de l'Iran par approches couplées géodésiques (GPS et InSAR) et tectoniques; implications sur l'aléa sismique / Characterization of active fault behavior in eastern Iran using a combined geodetic (GPS and InSAR) and tectonic approach; implications on seismic hazardMousavi, Zahra 08 November 2013 (has links)
Nous avons utilisé deux techniques de géodésie spatiale (Global Navigation Satellite System, GNSS, et Interférométrie d'images radar satellite, InSAR) pour estimer la cinématique actuelle et les taux de glissement de la plupart des failles de l'Est et du Nord-Est de l'Iran. En Iran de l'Est, 14 mm/an de cisaillement dextre est accommodé sur les failles décrochantes dextres Est-Lut, West-Lut, Kuhbanan, Anar et Dehshir. Ces failles glissent latéralement à 5.6 ± 0.6, 4.4 ± 0.4, 3.6 ± 1.3, 2.0 ± 0.7 et 1.4 ± 0.9 mm/an, respectivement, de l'est à l'ouest. Au nord de ces failles, nos vitesses GNSS suggèrent une rotation de block rigide du bassin Sud Caspien (SCB) autour d'un pôle qui se trouve plus loin qu'on ne le pensait précédemment. Ce mouvement NW de SCB implique un glissement dextre de jusqu'à 7 mm/an sur la faille Ashkabad, et jusqu'à 4-6 mm/an de glissement senestre à travers le système des failles de Shahroud (SFS). L'analyse InSAR en séries temporelles localise 4.75 ± 0.5 mm/an de glissement senestre plus spécifiquement sur les failles d'Abr et Jajarm. / Eastern Iran has a crucial role in accommodating the Arabia-Eurasia convergence. We used permanent and campaign Global Positioning System (GPS) networks to estimate the present-day kinematics and the slip rates on most faults in Central-Eastern Iran and Kopeh Dagh. Also we used differential Synthetic Aperture Radar (SAR) interferometry to estimate the interseismic deformation along two major faults in Eastern Iran, the Shahroud and Doruneh faults. In Eastern Iran, 14 mm/yr of right-lateral shear is accommodated on the East-Lut, West-Lut, Kuhbanan, Anar and Dehshir right-lateral faults. These faults slip laterally at 5.6 ± 0.6, 4.4 ± 0.4, 3.6 ± 1.3, 2.0 ± 0.7 and 1.4 ±0.9 mm/yr, respectively from east to west and they divide the Central-Eastern Iranian crust in five blocks that are moving northwards at 6-13 mm/yr with respect to Eurasia. The NS faults accommodate additional NS shortening by rotating counterclockwise in the horizontal plane, at current rates of up to 0.8°Ma. In the North of theses faults is situated the EW orientated left-lateral Doruneh fault. We obtain less than 4 mm/yr of slip rate using SAR ENVISAT data which correspond to the GPS results from average velocity differences to each side of the fault. North of Doruneh, our GPS velocities suggest a rigid-body rotation of the South Caspian Basin (SCB) about an Euler pole that is located further away than previously thought. This NW motion of SCB is accommodated by right-lateral slip on the Ashkabad fault (at a rate of up to 7 mm/yr) and by up to 4-6 mm/yr of summed left-lateral slip across the Shahroud left-lateral strike-slip system. The time series analysis of two ENVISAT SAR images covering the Shahroud faults system helps localizing the left-lateral slip on individual faults. We perform a 2-D elastic half-space modeling of two tracks. The modeling results yield 4.75 ± 0.5 mm/yr of left-lateral slip rate on the Abr (~ longitude 55°) and Jajarm (~longitude 56°) strand of the Shahroud fault system with a 10 ± 4 km locking depth, highlighting the important contribution of these faults to seismic hazard in the highly populated NE Iran.
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Tectonomorphic and kinematic characterization of Neogene deformation in the southern Central Andes (23˚-28˚S, NW Argentina)Daxberger, Heidi 10 1900 (has links)
<p>This thesis focuses on the tectonomorphologic evolution of the Central Andean Puna Plateau and its eastern foreland. The collective findings of fault-slip and tectonomorphic analyes help in understanding the mechanical behavior of non-collisional orogens at convergent plate boundaries and result in an improved Neogene tectonic record of the Central Andes.</p> <p>Fault-slip analysis indicates Neogene WNW-ESE horizontal shortening of the thickened crust of the Puna Plateau and Eastern Cordillera and simultaneous lateral gravitational spreading. The less thickened of Pampean Ranges continue to undergo horizontal shortening only. The importance of N-S extension in the kinematics of elevated parts of the Central Andes is underscored by the strike-slip components on prominent dip-slip faults. Strain axis configurations in the southern Central Andes are generally controlled by (1) overall WNW-ESE horizontal shortening imposed by plate convergence and (2) differences in crustal thickness, i.e., gravitational potential energy. Therefore, a geodynamic interpretations in which still increasing elevation and crustal thickness significantly influence upper-crustal kinematics of the southern Central Andes is suggested.</p> <p>To allow regional-scale tectonomorphic studies, including Valley-Width-to-Valley-Height (Vf) ratio and the Transverse-Topographic-Symmetry (T-) factor, an Esri ArcGIS compatible software tool was developed. This Geographical Information System (GIS)-based tool, was coded in Python to enable conversion to other ArcGIS versions. This herein presented first version of the tool is fully functioning and drastically reduces the otherwise long processing times.</p> <p>A qualitative main basin symmetry description, Mountain-Front-Sinuosity (Smf) indices, and Vf-ratios of second-order drainage basins, indicate ubiquitous Quaternary deformation on reverse and thrust faults in the southern Central Andes. The recorded Quaternary deformation strongly influences Quaternary landform development, as shown by main drainage basin asymmetries and second-order drainage basins shapes. However, non-systematic T-factor distribution for second-order basins indicates that basin asymmetry is subject to litholigcal variations.</p> / Doctor of Philosophy (PhD)
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Vers la compréhension des séquences sismiques sur un système de failles : de l’observation spatiale à la modélisation numérique. Application à la séquence du Nord-Est Lut, Iran / Toward the understanding of seismic sequences : from spatial observation to numerical modeling. Application to the NE Lut earthquake sequence, IranMarchandon, Mathilde 02 July 2018 (has links)
De nombreuses études montrent que les transferts de contrainte co- et postsismiques jouent un rôle majeur dans l’occurrence des séquences de séismes. Cependant, la grande majorité de ces études implique des systèmes de failles à la configuration géométrique simple (e.g. failles parallèles ou colinéaires). Dans cette thèse, nous étudions une séquence de séismes s’étant produite au sein d’un système de failles à la configuration géométrique plus complexe (i.e. failles conjuguées), la séquence du NE Lut (1939-1997, NE Iran), afin d’évaluer (1) si les transferts de contrainte favorisent la succession de séismes de la séquence et (2) s’ils permettent sur le long-terme de synchroniser les ruptures des failles du système. Pour cela, nous mesurons d’abord les déformations de surface produites par la séquence afin de mieux contraindre par la suite la modélisation des transferts de contrainte. A partir de la technique de corrélation subpixel d'images optiques, nous mesurons les champs de déplacements de surface horizontaux produits par les séismes de Khuli-Boniabad (Mw 7.1, 1979) et de Zirkuh (Mw 7.2, 1997). Nous montrons que ces séismes sont caractérisés par la rupture de plusieurs segments dont les limites sont corrélées avec les complexités géométriques des failles. Nous interprétons les différences de leurs caractéristiques de rupture (longueur de rupture, glissement moyen, nombre de segments rompus) comme étant dues à des différences de maturité des failles de Dasht-e-Bayaz et d’Abiz. Nous détectons également les déplacements produits par un séisme historique modéré, le séisme de Korizan (Mw 6.6, 1979). C’est la première fois que les déplacements produits par un séisme historique de si petite taille sont mesurés par corrélation d’images optiques. Ensuite, en combinant le champ de déplacements InSAR déjà publié avec les données optiques proche-faille précédemment acquises, nous estimons un nouveau modèle de source pour le séisme de Zirkuh (Mw 7.2, 1997). Nous montrons que les données proche-faille sont essentielles pour mieux contraindre la géométrie de la rupture et la distribution du glissement en profondeur. Le modèle estimé montre que le séisme de Zirkuh a rompu trois aspérités séparées par des barrières géométriques où les répliques du séisme se localisent. Seul le segment central de la faille présente un déficit de glissement en surface que nous interprétons comme étant dû à de la déformation distribuée dans des dépôts quaternaires non consolidés. Enfin, à partir des informations précédemment acquises, nous modélisons les transferts de contrainte au cours de la séquence du NE Lut. Nous montrons que ceux-ci ont favorisé l’occurrence de 7 des 11 séismes de la séquence et que modéliser précisément la géométrie des ruptures est essentiel à une estimation robuste des transferts de contrainte. De plus, nous montrons que l’occurrence du séisme de Zirkuh (Mw 7.2, 1992) est principalement favorisée par les séismes modérés de la séquence. Pour finir, la simulation d’une multitude de cycles sismiques sur les failles du NE Lut montre que les transferts de contrainte, en particulier les transferts postsismiques liés à la relaxation viscoélastique de la lithosphère, sont le principal processus permettant la mise en place répétée de séquences de séismes sur les failles du NE Lut. Enfin, d'après les simulations réalisées, l'ordre dans lequel se sont produits les séismes majeurs durant la séquence du NE Lut est assez exceptionnel. / Many studies show that static and postseismic stress transfers play an important role in the occurrence of seismic sequences. However, a large majority of these studies involves seismic sequences that occurred within fault systems having simple geometric configurations (e.g. collinear or parallel fault system). In this thesis, we study a seismic sequence that occurred within a complex fault system (i.e. conjugate fault system), the NE Lut seismic sequence (1939-1997, NE Iran), in order to assess if (1) stress transfers can explain the succession of earthquakes in the sequence and (2) stress transfers can lead to the synchronization of the NE Lut faults over multiple seismic cycles. To this end, we first measure the surface displacement field produced by the sequence in order to precisely constrain the stress transfer modeling afterwards. We use optical correlation technique to measure the surface displacement fields of the Khuli-Boniabad (Mw 7.1, 1979) and Zirkuh earthquake (Mw 7.2, 1997). We find that these earthquakes broke several segments limited by geometrical complexities of the faults. We interpret the differences in failure style of these earthquakes (i.e. rupture length, mean slip and number of broken segments) as being due to different level of structural maturity of the Dasht-e-Bayaz and Abiz faults. Furthermore, we succeed to detect offsets produced by the 1979 Mw 6.6 Korizan earthquake. It is the first time that surface displacements for such a small historical earthquake have been measured using optical correlation. Then, combining previously published intermediate-field InSAR data and our near-field optical data, we estimate a new source model for the Zirkuh earthquake (Mw 7.2, 1997). We show that near-field data are crucial to better constrain the fault geometry and the slip distribution at depth. According to our source model, the Zirkuh earthquake broke three asperities separated by geometrical barriers where aftershocks are located. No shallow slip deficit is found for the overall rupture except on the central segment where it could be due to off-fault deformation in quaternary deposits. Finally, we use the information acquired in the first parts of this work to model the stress transfers within the NE Lut sequence. We find that 7 out of 11 earthquakes are triggered by the previous ones and that the precise modeling of the rupture geometry is crucial to robustly estimate the stress transfers. We also show that the Zirkuh earthquake is mainly triggered by the moderate earthquakes of the NE Lut sequence. Lastly, the simulation of multiple seismic cycles on the NE Lut fault system shows that stress transfers, in particular postseismic stress transfers due to viscoelastic relaxation, enhance the number of seismic sequences and synchronize the rupture of the faults. The simulations also show that the order in which the Mw>7 earthquakes occurred during the NE Lut sequence is quite exceptional.
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