Global ETD Search

121	Geochemical and petrologic study of the Fries-Rockfish Valley Fault near Roanoke, Virginia Holmstad, Erin Frances 01 November 2008 (has links) The Blue Ridge Province in southern and central Virginia is a complex slice of Precambrian basement emplaced on the margin of Laurentia during collisional events in the Paleozoic. This allochthonous basement is composed of Middle Proterozoic continental crust, Late Proterozoic intrusives, and Late Proterozoic-early Paleozoic metasediments and metavolcanics. Two distinct terranes within the Blue Ridge are separated by the northeast-trending and southeast dipping Fries-Rockfish Valley Fault Zone, exposed as a 1-10 km wide shear zone, formed during the middle Paleozoic Taconic Orogeny (425-450 Ma.). These terranes are referred to as the Pedlar massif, a high-grade granulite terrane, to the northwest and the Lovingston massif, a lower-grade amphibolite terrane to the southeast. The connection between these terranes has been debated for decades. A combined petrologic and geochemical approach has been applied in two transects across the shear zone, four kilometers apart along strike near Roanoke, Virginia, to study the geochemical and petrologic evidence of shearing along the fault and constrain the nature and timing of possible retrogressive and fluid infiltration events that affected these rocks. Mineral assemblages and microstructures at the northeastern Horsepen Mountain and at the southwestern Explore Park transects indicate that deformation occurred along the fault under greenshist facies conditions. / Master of Science geochemistry shear metamorphic petrology LD5655.V855 1996.H656
122	Structure, metamorphism, and tectonics of the northern Oman-UAE ophiolite and underlying metamorphic sole Ambrose, Tyler January 2017 (has links) Ophiolites - thrust sheets of oceanic lithosphere that have been emplaced onto the continental margin - provide the opportunity to explore the structure and genesis of oceanic crust. As many ophiolites formed above subduction zones, they also allow for the investigation of mantle wedge and subduction interface processes. This the- sis examines the Oman-United Arab Emirates (UAE) ophiolite, which is the largest and most intensely studied ophiolite on Earth. Three distinct problems are addressed. (1) Recent research has proposed that the architecture and tectonic evolution of the ophiolite in the UAE differs from in Oman. In Chapter 2, I test this hypothesis by integrating new geological mapping and field observations with previously published maps of the ophiolite in the UAE. My results indicate that the ophiolite is gently folded, but otherwise largely intact. I demonstrate that the architecture of the ophi- olite in the UAE is not significantly different from in Oman. Thus, there is no basis for a different tectonic evolution as recently proposed. (2) Observations from exper- iments and small-scale natural shear zones indicate that volumetrically-minor phases can control strain localization. In Chapter 3, I test the hypothesis that minor phases control strain-localisation at plate boundaries. To do so, I analyzed peridotites from the base of the ophiolite, a palaeosubduction interface. My results demonstrate that minor phases limited olivine grain growth, which led to rheological weakening. (3) The mechanisms by which metamorphic soles detached from the downgoing slab and accreted to the hanging-wall mantle is unclear. In Chapter 4, I examine a transect across the metamorphic sole in the UAE. My results reveal that granulite formation was more extensive than is typically considered. I propose that granulite formation resulted in rheological strengthening, which caused the subduction interface to migrate into the downgoing slab and accrete the metamorphic sole.
123	Igneous and metamorphic rocks from SW Cyprus and NW Syria: evidence for Cretaceous microplate collision andsubsequent tectonic events in the Eastern Mediterranean Chan, Heung-ngai., 陳向毅. January 2004 (has links) published_or_final_version / abstract / toc / Earth Sciences / Master / Master of Philosophy Igneous rocks - Cyprus. Rocks, Metamorphic - Cyprus. Igneous rocks - Syria. Rocks, Metamorphic - Syria. Geology, Structural - Cyprus. Geology, Structural - Syria.
124	The nature and origin of the polymetallic Salt River massive sulfide deposit, Northern Cape Province, South Africa Osburn, Keith Craig 07 June 2012 (has links) M.Sc. / The Salt River deposit is a poly-metallic base metal deposit with a Zn-Cu-Pb metal content that occurs southwest of the town of Kakamas within the Northern Cape Province, South Africa. The Salt River deposit occurs within the Geelvloer Formation of the Bushmanland Subprovince of the Proterozoic Namaqua Metamorphic Province (NMP). This study constitutes the first detailed study of the host rock succession to the Salt River deposit, by investigating the lithostratigraphy, petrography geochemistry and geochronology. During the course of the study, various styles of wall-rock alteration were identified and investigated to determine their effect on the host rock succession. A further aim of this study was to classify the Salt River deposit and compare it to neighboring deposits occurring in the NMP. Geochronological studies were undertaken to define the age of mineralization. Detailed logging of exploration diamond drill core combined with petrographic investigation was used to define thirteen distinct lithotypes. The stratigraphy is dominated by felsic grey gneisses and mafic amphibolites, minor calc-silicate rocks, granitic augen gneisses, pegmatites and two lithologies that represent the metamorphosed equivalents of hydrothermally-altered host rock. Lithostratigraphic investigations yielded a rather uniform succession containing four distinct marker beds defined by their common occurrence and ease of correlation across various boreholes. Namaqua Metamorphic Province Sedimentation and deposition Geology (Kakamas, South Africa) Salt River sulfide deposit Petrology Metamorphic rocks Geology, Stratigraphic
125	Geologic and petrologic evidence for granulite facies partial melting in the Garies-Platbakkies supracrustal gneiss belt, Namaqualand metamorphic complex, South Africa / Geologic and petrologic evidence for granulite facies partial melting in the Garies-Platbakkies supracrustal gneiss belt, Namaqualand metamorphic complex, South Africa Baars, Franciscus Jacobus, Baars, Franciscus Jacobus 22 November 2016 (has links) The Namaqua Province of southwestern Africa is comprised of a number of distinct tectonostratigraphic subprovinces and terranes, which have in common a 1100-1200Ma structural and metamorphic imprint. In the western Bushmanland Subprovince, E-Wtrending belts of supracrustal gneisses are intruded by and infolded with granitic gneisses of varying ages. A central zone of rocks metamorphosed in the granulite facies is bordered to the north and south by amphibolite facies rocks. A portion of the Garies-Platbakkies supracrustal gneiss belt has been mapped on a 1:15 000 scale. The supracrustal succession was deposited on an unconfirmed basement. It is structurally juxtaposed and infolded with three different granitic augen gneisses. Large bodies of orthopyroxene-bearing granite are syntectonically emplaced in the succession. A wide variety of anatectic granites crop out as sills, dykes and pods varying in size between a few metres and a few hundred metres. These bodies commonly truncate pre-existing foliations. The metamorphosed supracrustal succession contains gneissic equivalents of felsic, mafic and intermediate volanics; pelitic, semi-pelitic, magnesian and granitic composition sediments; feldspathic quartzites; and subordinate quartzites, banded iron formation and calc-silicates. The mineral assemblages of all the rocks indicate metamorphism in the granulite facies. A variety of field evidence exists which suggests that the metamorphic peak was responsible for generating significant quantities of partial melt. The rocks of the study area contain an early Dl fabric. This is refolded in tight, E-plunging D2 crenulation folds. D2 mineral fabrics pre-date the metamorphic peak. D3 open, asymmetric folds are N-vergent and fold the crystalline products partial melting. The southern limbs of D3-folds are attenuated in 04 shear zones. The whole belt is cut by steep, N-S-trending faults. A wide variety of thermobarometers are tested for their applicability to mineral assemblages in the supracrustal rocks. The results of this application suggest that the metamorphic peak occurred at 780 ± 30°C and 5.0 ± 0.4 kbar. Assemblages in shear zones indicate an isobaric retrograde cooling path. The phase relations of melting near the solidus are reviewed with reference to common assemblages in the leucosomes of rocks with granitic and peraluminous bulk compositions. Isobaric T-a(H₂O) sections are constructed from available experimental and thermochemical data. Biotite dehydration and dehydration melting reactions are balanced using natural mineral compositions. The predicted results are compared with the modal abundances of natural product assemblages. The results suggest that dehydration melting was responsible for migmatization, and the consequent reduction of water activity. The amount of melt produced was controlled by the amount of water available from the dehydration of biotite. There is no evidence for the control of water activity by an external fluid reservoir. Limited amounts of water-undersaturated melts were extracted from their sites of generation. This process was responsible for the depletion of some leucosome assemblages with respect to K₂O, H₂O and in peraluminous rocks Na₂O. The partial melts were emplaced locally in developing shear zones. Gneiss - South Africa - Namaqualand Granulite - South Africa - Namaqualand Gneiss Metamorphic rocks Granulite
126	Metamorphic fluids at extreme pressure conditions and their significance for element transfer in subduction zones / A multidisciplinary study on metamorphic veins in UHP/HP eclogites from Dabieshan, China Albrecht, Nina 05 April 2017 (has links) No description available. 910 550 UHP/HP metamorphism Dabieshan deep subduction HIMU Nb/Ta paradox metamorphic fluid evolution metamorphic veins high pressure fluid-rock interaction fluid inclusions in metamorphic rocks
127	Anomalie thermique et sous-placage en zone d'avant-arc : exemple du massif Triasique de El Oro, Equateur / Thermal anomaly in forearc position : the Triassic andean margin of Ecuador Riel, Nicolas 20 January 2012 (has links) Depuis au moins 540 Ma deux grands systèmes de subduction coexistent sur Terre : d'une part, les systèmes de subduction-collision (chaînes Hercynienne, Himalayenne ou Alpine) et d'autre part, les systèmes de subduction de type péri-pacifique. Pour ces derniers, l'avant-arc constitue une zone clef pour retracer l'évolution de la subduction au cours du temps. En effet ces zones au contact avec le slab peuvent enregistrer des événements tectoniques et/ou des conditions métamorphiques variées (e.g. formation de « paired metamorphic belts »), qui sont autant d'indicateurs du contexte géodynamique. Le massif métamorphique de El Oro en Equateur est un exemple exeptionnel où une section complète et basculée de l'avant-arc Triasique est préservée. L'ensemble est constitué d'une série métasédimentaire de bas à haut grade métamorphique intrudée par des granitoïdes de type S, juxtaposé avec un laccolithe gabbroïque et des schistes bleus. Ce travail de thèse s'est concentré sur l'étude du métamorphisme de haute-température basse-pression et ses relations les schistes bleu. Afin de contraindre l'événement tectono-métamorphique affectant l'avant-arc Equatorien au Trias et la formation d'une "paired metamorphic belt", nous avons utilisé des outils structuraux, métamorphiques, géochimiques, géochronologiques et de modélisation thermique. Nos résultats montrent que durant cette période l'avant-arc Equatorien connait un intense épisode de fusion partielle en régime extensif. La base de la croûte est migmatisée sur une épaisseur de 10km. Les estimations Pression-Température indiquent que les conditions de fusion partielle varient de 4.5 kbar et 650°C pour la partie supérieure métaxitique et jusqu'à 7.5 kbar et 720°C pour la partie inférieure diatexitique. La gradient géothermique inféré est divisé en deux segments : un segment supérieur caractérisé par un gradient de 40°C/km et un segment inférieur caractérisé par un gradient quasi-isothermique. L'absence de paragénèse de ultra-haute température est attribuée à la grande fertilité du protolithe métasédimentaire. Les résultats géochimiques montrent que les plutons granodioritiques sont issus d'un mélange entre : (1) les liquides de fusion partielle produit par la réaction de deshydration de la muscovite des métasédiments et (2) un magma basique. Les âges U-Pb sur zircons et monazites révèlent que l'événement anatectique fût bref entre 229 et 225 Ma. La source de chaleur à l'origine de l'événement thermique est attribuée à la mise en place d'un pluton gabbroïque à ~ 230 Ma en base de croûte. Successivement, se sous-plaque les schistes-bleu refroidissant rapidement l'avant-arc. L'événement anatectique observé dans le massif de El Oro au Trias s'insrit à plus grande échelle au sein d'une large anomalie thermique affectant l'ensemble du continent sud Américain entre 260 et 220 Ma. Durant cette période la marge est un soumise à un régime extensif accompagné d'un important magmatisme d'origine crustal, principalement en position d'arc et d'avant-arc. Nous attribuons cette anomalie thermique d'ampleur continental à une "avalanche mantellique". A la lumière du contexte géodynamique globale nous inteprétons la formation de la paired metamorphic belt de El Oro à la rupture du slab. / Since about 540 Ma, two subductions systems co-exist on Earth: the subduction-collision systems (Hercynian, Himalayan or Alpin belts) and the circum-pacific subduction system. For the last the forearc region constitutes a key zone to understand the dynamic of the subduction. Indeed the forearc region in contact with the slab may records various tectonics events and/or metamorphic conditions (e.g. formation of paired metamorphic belt). Theses geological records are direct evidences of the linked geodynamical context. The El Oro metamorphic complex in Ecuador is a unique example where a whole Triassic forearc section is tilted and well preserved. The complex is made of low to high grade metasedimentary rocks intruded by S-type granitoids, juxtaposed with gabbroic rocks and blueschists. This study is focused on the high-temperature metamorphism and its retionaships with the high-pressure metamorphism. In order to constrain the tectono-metamorphic affecting the forearc region and the formation of a paired metamorphic belt we used strutural, metamorphic, geochemical, geochronological and themal modeling studies. Our results show that during Triassic times the Ecuadorian forearc underwent a strong episode of partial melting in extentional context. The migmatized part of crust is 10 km thick. Pressure-Temperature estimates indicate that partial melting started at 4.5 kbar and 650°C for the upper metatexitic part until 7.5 kbar and 720 °C for the lower diatexitic part. The resulting geothermal gradient exhibits two parts: an upper part caracteristed by a thermal gradient of 40°C/km and a lower part caractérized by a near-adiabatic gradient. The absence of ultra-high tempetature paragenesis is attributed to the high fertility of the metasedimentary protolith. Geochemical results show that granodiorite made of a miwing between: (1) the melt extacted under muscovite dehydration melting and (2) a basic magma. U-Pb ages on zircon and monazite reveal that the anatectic event was short, between 229 and 225 Ma. The origin of the thermal anomaly is attributed to the emplacement of the gabbroic plutonic unit at ~230 at root level. Successively, the blueschites are underplating triggering a strong coolng of the forearc region. The anatectic recorded in the El Oro metamorphic complex at Triassic times is part of a larger thermal anomaly affecting the whole south american margin between 260 and 220 Ma. During this period the margin is under extentional conditions and exhibit a strong S-type magmatic activity. This magmatism is mainly located in arc and forearc position. We attribute this large-scale thermal anomaly to slab fall in the lower mantle. In the light of the geodynamical context, we suggest that the formation of the El Oro paired metamorphic belt is related to slab breakoff. Migmatites U-Pb geochronology Métamorphisme HT-BP Pseudosections Paired metamorphic belt Equateur Migmatites U/Pb geochronology HT-LP metamorphism Pseudosections Paired metamorphic belt Ecuador
128	Using metamorphic modelling techniques to investigate the thermal and structural evolution of the Himalayan-Karakoram-Tibetan orogen Palin, Richard Mark January 2013 (has links) Metamorphic rocks constitute a vast volumetric proportion of the Earth’s continental lithosphere and are invaluable recorders of the mechanisms and rates of deformation and metamorphism that occur at the micro-, meso- and macro-scale. As such, they have the potential to provide detailed insight into important tectonic processes such as the subductive transport of material into, and back from, mantle depths and also folding, faulting and thickening of crust that occurs during collisional orogeny. The Himalayan-Karakoram-Tibetan orogen is the youngest and most prominent example of a continent-continent collisional mountain belt on Earth today and is a product of the on-going convergence of the Indian and Asian plates that initiated in the Early Eocene. Thus, it provides an exceptional natural laboratory for the investigation of such processes. Recent advances in the computational ability to replicate natural mineral assemblages through a variety of metamorphic modelling techniques have led to improvements in the amount (and quality) of petrographic data that may be obtained from a typical metamorphic rock. In this study, phase equilibria modelling (pseudosection construction) using THERMOCALC, amongst other techniques, has been integrated with in-situ U–Pb and Th–Pb geochronology of accessory monazite in order to constrain the tectonothermal evolution of four regions intimately associated with the Himalayan-Karakoram-Tibetan orogen. These regions comprise the Karakoram metamorphic complex (north Pakistan), the Tso Morari massif (north-west India), the eastern Himalayan syntaxis (south-east Tibet) and the Day Nui Con Voi metamorphic core complex of the Red River shear zone (North Vietnam). Each case study documents previously unreported metamorphic, magmatic or deformational events that are associated with the India-Asia collision. These data have allowed original interpretations to be made regarding the tectonic evolution of each individual region as well as the large-scale evolution of the Himalayan-Karakoram-Tibetan orogenic system as a whole. 552.4
129	Spot U-Pband Hf isotope analyses of detrital zircons from the khondalites in the western block of the North China craton Xia, Xiaoping., 夏小平. January 2005 (has links) published_or_final_version / abstract / Earth Sciences / Doctoral / Doctor of Philosophy Zircon - China. Isotope geology - China. Rocks, Metamorphic. Geology, Structural - China. Geochronometry - China.
130	Post-Mineral Normal Faulting in Arizona Porphyry Systems Nickerson, Phillip Anson January 2012 (has links) In the Basin and Range province of southwestern North America, Oligocene and Miocene normal faults are superimposed upon the Late Cretaceous-early Tertiary magmatic arc. This study examines tilted fault blocks containing dismembered pieces of porphyry systems, including pieces below and peripheral to ore bodies, that are exposed at the modern surface. Features in the magmatic-hydrothermal porphyry systems are used to place constraints on the style of extension in Arizona, and reconstructions of extension are used to examine the deep and peripheral portions of porphyry systems to provide a more complete understanding of porphyry systems as a whole. The Eagle Pass, Tea Cup, and Sheep Mountain porphyry systems of Arizona are examined in this study. In all the study areas, previous interpretations of the style of extension involved strongly listric normal faults. However, similar amounts of tilting observed in hanging wall and footwall rocks, as well as structure contour maps of fault planes, require that down dip curvature on faults was minimal (<1°/km. Instead, extension is shown here to have occurred as sets of nearly planar, "domino-style" normal faults were superimposed upon one another, including in the Pinaleño metamorphic core complex. Reconstructions of Tertiary extension reveal that sodic (-calcic) alteration is occurs 2-4 km peripheral to, and greisen alteration is found structurally below and overlapping with, potassic alteration. In addition, a preliminary reconstruction of extension across the Laramide magmatic arc reveals that the geometry, as revealed by known porphyry systems, is of similar scale to that of other magmatic arcs. These results help further the debate surrounding competing models of continental extension, and combine with previous work to provide a more complete understanding of the geometries of Arizona porphyry systems at the district and arc scale. Normal Fault Palinspastic Reconstruction Porphyry Copper Geosciences Laramide Magmatic Arc Metamorphic Core Complex

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