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Cenozoic Evolution of the Sierras Pampeanas Tectonomorphic Zone Between 27.5°S and 30.5°S, ArgentinaStevens, Andrea Lynn, Stevens, Andrea Lynn January 2017 (has links)
The Andean Cordilleran orogenic system stretches over 7,000 km along the western margin of South America and serves as a useful laboratory to evaluate the causes of spatial and temporal variations in orogenic processes. Although the geology of the Andean margin is fundamentally controlled by the subduction of the Nazca plate beneath the South American plate, the style of deformation, basin morphology, exhumation history, and volcanic activity along this margin are remarkably heterogeneous in both time and space.
My Ph.D. work presents new data from the Miocene – Pliocene along-strike depocenters bounding the basement block uplifts of the Sierras Pampeanas and the fold and thrust belt of the Andean Precordilleran in the south Central Andes between ca. 27.5°S and 30.5°S. I use new observations from sedimentology, detrital zircon U-Pb data, and low-temperature thermochronology to evaluate the mechanisms driving basin organization, sedimentation, and exhumation. Geohistory analysis supports flexurally controlled basins between ca. 18 and 6 Ma with detritus derived exclusively from the active Precodillera to the west. Accelerated deformation in the Precordillera produced accelerated sedimentation from ca. 10 – 8.5 Ma. A deceleration of sedimentation from ca. 6 – 5 Ma was most likely controlled by heightened aridity. Around the same time, low-temperature thermochronometers record the widespread exhumation of the foreland basin system for over 300 km along strike, this may be driven by dynamically controlled uplift related to Miocene flat-slab subduction. Low-temperature thermochronometers suggest that the geothermal gradient throughout the late Miocene was ca. 35°C/km – 25°C/km and had not been significantly depressed as previously proposed.
Granite-cored ranges in the Sierras Pampeanas were sampled for low-temperature thermochronology to constrain the exhumation history of the region. Modeling of both apatite fission track and apatite (U-Th-Sm)/He thermochronometers demonstrates that these rocks have been close to the surface since the late Paleozoic. Reheating during the Cretaceous is attributed to elevated geothermal gradients due to back-arc rifting. Final exhumation (1- 2 km) occurred in the mid to late Miocene and may have been controlled by the onset of flat-slab subduction. These results suggest that the Sierras Pampeanas may have had inherited positive topography that has controlled basin organization and sediment distribution patterns since the Paleozoic.
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Investigations of the Crust and Upper Mantle of Modern and Ancient Subduction Zones, using Pn Tomography and Seismic Receiver FunctionsGans, Christine January 2011 (has links)
Advances in seismology allow us to obtain "high-resolution" images of the Earth's subsurface. This dissertation summarizes the results of three seismic studies on three different continents, with the aim of better understanding the crust and upper mantle structure of seemingly disparate yet ultimately related regions. The seismic techniques of Pn tomography and P-wave receiver function (RF) analysis are applied to central Turkey (Pn tomography), western Argentina and southwestern Wyoming, USA (RF analysis). These studies look at both a present-day convergent margin (Andean subduction zone, Argentina) and two ancient ones (Bitlis-Zagros collision zone of Arabia-Africa with Eurasia, Turkey; Farallon subduction zone, Wyoming).Using Pn tomography, we were able to detect the limit of the slab rupture edge along the Central Anatolian Fault Zone, Turkey. Slab break-off is an important process that modifies the mantle in tectonically active regions, and the limit of the oceanic Arabian slab break-off along the Bitlis-Zagros Suture Zone, thought to have begun at 11 Ma, was previously undetermined.Using RF analysis, we obtained high-resolution images of the subducting slab beneath the Sierras Pampeanas, Argentina. Continental Moho contours roughly follow terrane boundaries, suggesting that ancient terranes continue to exert control over present-day continental deformation. Overthickened oceanic crust is often cited as a cause of flat slab subduction; our RF results indicate that the crust is moderately overthickened, around 11-16 km. Further, we image offsets in the RF arrivals that indicate the subducted slab is broken or offset in along trench-subparallel fractures.The crustal structure beneath southwestern Wyoming, the location of ancient Farallon flat slab subduction, was studied using RF analysis. Looking at regional crustal structure, results include a new depth to Moho map. Coherency of the seismic signal across the dense LaBarge array (55 stations, ~250 m spacing) was investigated, with results showing that complicated shallow structure can greatly impact the resulting RF signal. Modeling of RFs using synthetics helped to separate the complex signal containing multiple primary conversions and their reverberations, which interact constructively and destructively. The dense spacing of the LaBarge array allowed unique opportunities to investigate coherency of waveforms across very short distances.
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Provenance response to flat-slab subduction as recorded in detrital zircon signatures from the southern Alaskan forearc basin systemHedeen, Tyler 01 May 2016 (has links)
Strata in the Cook Inlet forearc basin in south-central Alaska record the effects of tectonic events related to normal subduction and two flat-slab subduction events. Through detrital zircon geochronology we track provenance changes of strata deposited in a forearc basin in conjunction with these different subduction processes. Our data from strata deposited concurrent with normal subduction help to confirm previous provenance models of forearc basins that suggest provenance is sourced primarily from a proximal, coeval arc. However, compared to these models, our data from strata deposited coincident to flat-slab events show markedly different provenance signatures dependent upon: (1) geographic position relative to the flat-slab event; (2) pre-established, or lack thereof, topography; and (3) type of flat-slab event. Detrital zircon signatures of strata deposited in the Cook Inlet after flat-slab subduction of a mid-ocean ridge diversify to include older detritus found in the distal inboard region. This distal signature is then incrementally cut-off in younger strata due to deformation of the upper-plate from progressive insertion of a shallowly subducted oceanic plateau. Detrital zircon signatures for strata associated with each flat-slab event are largely older than depositional age due to the lack of coeval arc activity. Our data may help to improve the ability to recognize other flat-slab events through detrital zircon geochronology. In particular, changes in detrital zircon signatures found in strata deposited during flat-slab subduction of an oceanic plateau correlate well with the exhumation of rocks associated with the propagation of deformation in the over-riding plate due to plate coupling.
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INVESTIGATING EOCENE TO ACTIVE TECTONICS OF THE ALASKAN CONVERGENT MARGIN THROU GH GEOLOGIC STUDIES AND 3-D NUMERICAL MODELINGHannah Grace Weaver (10692984) 07 May 2021 (has links)
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<p>The combination of field-based studies and numerical modeling provides a robust tool for
evaluating geologic and geodynamic processes along a convergent margin. Complex and persistent
tectonic activity and a novel suite of geophysical observations make the southern Alaskan
convergent margin a key region to evaluate these processes through both basin analysis studies
and geodynamic modeling. This conceptual approach is utilized to explore the active driving forces
of surface deformation throughout southcentral Alaska, as well as the geologic record of regional
Cenozoic tectonic processes.
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<p>New sedimentologic, chronostratigraphic, and provenance data from strata that crop out
within the central Alaska Range document a previously unrecognized stage of Eocene – early
Miocene strike-slip basin development along the northern side of the central Denali fault system.
This stage was followed by Miocene-Pliocene deformation and exhumation of the central Alaska
Range, and basin development and northward sediment transport into the Tanana foreland basin.
This portion of the study provides insight into Cenozoic tectonics and basin development in the
central Alaska Range.
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<p>How transpressional tectonics are manifest in the modern-day, in combination with shallow
subduction processes, are not well understood for the southern Alaskan convergent margin.
Simulations of the 3-D deformation of this region allow for investigation of the complex
relationship between these tectonic processes and surface deformation. Results from this study
display the far-field affect that strong plate coupling along the shallowly subducting Yakutat slab
has on the surface deformation of southcentral Alaska. Our models also show that partitioning of
this convergence is observed along the Denali fault system. Additionally, our results indicate the
subducting slab is segmented into separate Pacific, Yakutat and Wrangell slab segments. This
variation in slab structure exerts control on the upper plate response to shallow subduction.</p>
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Upper plate response to varying subduction styles in the forearc Cook Inlet basin, south-central AlaskaSanchez Lohff, Sonia K. January 2018 (has links)
No description available.
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