Global ETD Search

11	An assessment of heterogeneity within the lithospheric mantle, Marie Byrd Land, West Antarctica Cohen, Shaina Marie January 2016 (has links) Thesis advisor: Seth C. Kruckenberg / The West Antarctic rift system is one of the most expansive regions of extended continental crust on Earth, but relatively little is known about the structure of the mantle lithosphere in this region. This research aims to examine a suite of ultramafic mantle xenoliths from several volcanic centers located throughout Marie Byrd Land, West Antarctica. Through the use of several complementary analytical methods, the deformational and compositional heterogeneity of the lithospheric mantle in this region is characterized. The Marie Byrd Land xenoliths have equilibration temperatures between 779 and 1198°C, which is a range that corresponds to extraction depths between 39 and 72 km. These samples preserve significant mineralogical and microstructural heterogeneities that document both lateral and vertical heterogeneities within the Marie Byrd Land mantle lithosphere. The modal mineralogy of spinel peridotites varies between 40 – 99% olivine, 0 – 42% diopside, 0 – 45% enstatite and 0 – 5% chromite. Minimum olivine grain sizes range from 60 to 110 µm and maximum olivine grain sizes range from 2.5 to 10.0 mm. The geometric mean grain size of olivine in these samples ranges from 100 µm to 2 mm and has an average of 694 µm. The geometric mean grain size of diopside ranges from 90 to 865 µm and has an average of 325 µm, whereas that of enstatite ranges from 120 µm to 1.2 mm and has an average of 625 µm. Comparatively, the pyroxenites contain 0 – 29% olivine, 29 – 95% diopside, 1 – 36% enstatite and 1 – 11% chromite. Deformation mechanism maps suggest that the olivine within the MBL peridotite xenoliths primarily accommodate strain through the operation of dislocation-accommodated grain-boundary sliding at strain rates between 10-19/s and 10-11/s. This is consistent with microstructural observations of the suite made using optical microscopy (e.g., deformation bands and subgrains in olivine; aligned grain boundaries between contrasting phases). Application of the olivine grain size piezometer indicates that the suite preserves differential stresses ranging from 0.5 MPa to 50 MPa, with mean differential stresses ranging from 4 to 30 MPa. Values of mean differential stress only vary slightly throughout the field area, but generally decrease in magnitude towards the east with maximum values migrating upwards in the lithospheric mantle along this transect. The samples from some volcanic centers are highly homogenous with respect to their microstructural characteristics (e.g., Mount Avers – Bird Bluff), whereas others display heterogeneities on the sub-five-kilometer-scale (e.g., Demas Bluff). Comparatively, mineralogical heterogeneities are more consistent throughout the sample suite with variations generally being observed between the sub-five-kilometer-scale and the sub-ten-kilometer-scale. Most samples within the MBL peridotite suite display axial-[010] or A-type olivine textures. Although less dominant, axial-[100], B-type and random olivine textures are also documented within the suite. Axial-[010] textures have J-indices and M-indices ranging from 1.7 – 4.1 and 0.08 – 0.21, respectively. The average value of the J-index for axial-[010] textures is 2.9, whereas the average M-index of these samples is equal to 0.15. Overall, A-type textures tend to be stronger with J- and M-indices ranging from 1.4 – 9.0 and 0.07 – 0.37, respectively. The olivine crystallographic textures of the MBL xenolith suite are heterogeneous on scales that are smaller than the highest resolution that is attainable using contemporary geophysical methods, which implies that patterns of mantle flow and deformation are far more complex than these studies suggest. / Thesis (MS) — Boston College, 2016. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Earth and Environmental Sciences. crystallographic preferred orientation deformation lithospheric rheology mantle xenolith Marie Byrd Land Antarctica
12	Les quatre isotopes du soufre dans les kimberlites de Sibérie, traceurs du recyclage de croûte océanique et de sédiments Archéens dans le manteau terrestre / Quadruple sulfur isotopes in Siberian kimberlites, tracers of Archean oceanic crust and sediments recycled into the Earth's mantle Kitayama, Yumi 16 November 2018 (has links) Héritées de l’atmosphère primitive, des anomalies dans les abondances relatives des isotopes du soufre (32S, 33S, 34S et 36S) sont enregistrées dans les sédiments terrestres d’il y a plus de 2,5 milliards d’années (i.e. archéens). Nous évaluons ici la robustesse des isotopes du soufre à tracer le recyclage précoce de croûte océanique et de sédiments, transférés dans le manteau profond ou stockés dans le manteau lithosphérique depuis la mise en place de la subduction. En Sibérie, le manteau lithosphérique a été naturellement échantillonné par l’éruption de la kimberlite d’Udachnaya-Est. Extrêmement bien préservée, riche en Na, K, Cl, S et contenant des reliques de croûte océanique Archéenne, cette kimberlite nous permet de tester : (1) l’hypothèse du recyclage de soufre atmosphérique Archéen dans le manteau lithosphérique et/ou la source de cette kimberlite ; (2) la cohérences entre les méthodes in situ (SIMS dans les minéraux de sulfure) et bulk (extraction chimique du soufre et spectrométrie de masse à source gazeuse) pour les mesures multi-isotopiques du soufre. Nos résultats, complétés par des mesures isotopiques en Rb-Sr, Sm-Nd et plomb (204Pb, 206Pb, 207Pb, 208Pb), montrent que : (1) les sulfates de la kimberlite et des nodules composés de chlorure-carbonate ont une origine magmatique profonde, non-contaminée par les sédiments encaissants, suggérant la présence de domaines oxydés et riches en sulfates dans le manteau ; (2) les mesures isotopiques du soufre par méthode bulk sont cohérentes avec les populations de sulfures observées in situ ; (3) les sulfures des kimberlites salées sont appauvris en 34S par rapport à la valeur chondritique et enregistrent de faibles anomalies isotopiques en soufre ; (4) les péridotites déformées contiennent d’autres sulfures appauvris en 34S, qui eux préservent des anomalies en 33S et 36S héritées de la surface archéenne, malgré un équilibrage isotopique du chronomètre U-Pb lors de l’éruption de la kimberlite / Inherited from the early atmosphere, anomalies in the relative abundances of sulfur isotopes (32S, 33S, 34S and 36S) are recorded in sediments older than 2.5 billion year (i.e. Archean). Here we test the robustness of sulfur isotopes to trace the early recycling of oceanic crust and sediments that may have been transferred to the deep mantle or stored in the lithospheric mantle since the onset of subduction. In Siberia, the lithospheric mantle has been naturally sampled by the Udachnaya-East kimberlite while it was erupting. Because it is extremely well preserved, rich in Na, K, Cl, S and contains remnants of oceanic crust recycled during the Archean, this kimberlite enables us to test : (1) the hypothesis of an early recycling of Archean atmospheric sulfur in the lithospheric mantle and/or the deeper source of the kimberlite; (2) the coherence between in situ (SIMS in sulfide minerals) and bulk methods (chemical extraction of sulfur from powdered rocks, followed by gas source mass-spectrometry) for measuring multiple sulfur isotopes. Our results, combined with measurements of Rb-Sr, Sm-Nd and lead (204Pb, 206Pb, 207Pb, 208Pb) isotopes, show that: (1) sulfates from the Udachnaya-East kimberlite and its nodules composed of chloride-carbonate have a deep, magmatic origin, uncontaminated by host sediments, suggesting the presence of sulfate-rich, oxidized domains in the mantle; (2) measurements of sulfur isotopes by bulk methods are consistent with the sulfide populations observed in situ; (3) sulfides from salty kimberlites are depleted in 34S with respect to the chondritic value and record small anomalies in sulfur isotopes ; (4) sheared peridotites contain another population of sulfides that are depleted in 34S and preserve 33S and 36S anomalies inherited from the Archean surface, despite resetting of the U-Pb chronometer during kimberlite eruption Isotopes du soufre Kimberlite Archéen Manteau lithosphérique Sulfur isotopes Kimberlite Archean Lithospheric mantle 551.9
13	Controle de mudanças estruturais sob altas pressões e altas temperaturas da esmectita saturada em potássio Carniel, Larissa Colombo January 2013 (has links) O manto litosférico é depletado em elementos incompatíveis como potássio, rubídio e estrôncio, confinado sob altas condições de pressão e caracterizado por uma composição e mineralogia específicas: espinélios anidros e/ou granada lherzolitos e harzburgitos. Esta região pode ser hidratada e enriquecida em elementos incompatíveis (ex. potássio) através de processos de subducção, onde a placa oceânica subductada leva consigo material pelágico composto de argilominerais e filossilicatos. A transferência de massa entre a placa subductada com os sedimentos e a cunha mantélica ocorre primeiramente através da liberação de fluidos aquosos gerados pela devolatilização de minerais hidratados. Neste contexto, a esmectita destaca-se como um dos mais importantes minerias responsáveis pelo enriquecimento do manto litosférico em água e elementos incompatíveis, quando sua estrutura é desestabilizada. Com o aumento da pressão e temperatura, esmectitas perdem sua água interlamelar, ao mesmo tempo em que se transformam em camadas mistas esmectita-ilita. Nestas condições de desidratação, e com o aumento da pressão, mudanças estruturais ocorrem e, havendo potássio disponível no sistema, o argilomineral evolui para uma mica muscovita. Considerando este contexto, o presente trabalho tem como objetivo verificar o comportamento estrutural da esmectita saturada em potássio modificando as variáveis pressão e temperatura: (1) sob pressão atmosférica em diferentes temperaturas (100º a 700ºC); (2) sob pressão de até 11.5 GPa sem temperatura - Diamond Anvil Cell (DAC); (3) sob diferentes pressões com aplicação de temperatura: 2.5GPa (400º a 700ºC) e 4.0GPa (200º a 700ºC). Os resultados das técnicas de análise de Difração de raios X, Microscopia Eletrônica de Varredura (MEV), Microscopia Eletrônica de Transmissão (MET) e Espectroscopia por Infravermelho (FTIR) sugerem que, sob uma pressão de 2.5 GPa, que é cerca de 75km de profundidade no manto, e a aproximadamente 500ºC, a esmectita transforma-se em muscovita, enquanto sob a pressão de 4.0 Gpa, equivalente a cerca de 120 km de profundidade, a mesma transformação ocorre a 400ºC. Estes resultados contribuem significativamente para o entendimento de como a desidratação do sedimento pelágico ocorre em um processo de subducção, bem como o comportamento da esmectita sob a influência do aumento de pressão e temperatura. / The lithospheric mantle is depleted regarding to incompatible elements as potassium, rubidium and strontium, confined under pressure conditions and characterized by a specific mineralogy and composition, basically as anhydrous spinel and/or garnet lherzolite and harzburgite. This region can be hydrated and enriched in incompatible elements (e.g. potassium) through subduction processes that bring pelagic material, composed of clay minerals and other phyllosilicates, together with the hydrated subducted oceanic slab. A mass transfer from the subducted slab plus sediments into the mantle wedge occurs primarily through the release of aqueous fluids produced by devolatilization of hydrated minerals. In this context, smectite stands out as one of the most important minerals responsible for enriching the lithospheric mantle with water and incompatible elements when its structure is destabilized. By pressure and temperature increasing smectite lose its interlayer water, at the same time that it transforms into a mixed-layer illite-smectite. In this condition of dehydration and with increasing pressure, structural changes occur and, having potassium available on the system, the clay mineral evolves into a muscovite mica. Considering this context, we verified the structural behavior of potassium saturated smectite modifying variables pressure and temperature: (1) under atmospheric pressure at different temperatures (100º to 700º C); (2) under pressure up 11.5 GPa without temperature - Diamond Anvil Cell (DAC); (3) under different pressures with temperature application: 2.5 GPa (400º to 700º C) and 4.0 GPa (200º to 700º C). The results of the analysis techniques of X-ray diffraction, Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM) and Infrared Spectroscopy (FTIR), suggest that under the pressure of 2.5 GPa, which is about 75km depth in the mantle, and at around 500ºC smectite transforms into muscovite, while under the pressure of 4.0 GPa, equivalent to around 120km depth, the same transformation occurs at 400ºC. These results contribute significantly to understanding how pelagic sediment dehydration occurs in a subduction process, as well as the behavior of smectite under the influence of increasing pressure and temperature. Geologia Petrologia experimental Geoquímica Altas pressões Lithospheric mantle Smectite Dehydration Subduction High pressure
14	Petrology Of Eocene Volcanism In The Central Anatolia:implications For The Early Tertiary Evolution Of The Central Anatolian Crystalline Complex Geneli, Fatma 01 February 2011 (has links) (PDF) In the Central Anatolian Crystalline Complex (CACC) the Late Cretaceous post-collisional granitic magmatism is followed by Eocene extension, resulting in formation of roughly E-W trending transtensional basins. Formation of these basins was accompanied by calc- alkaline- mildly alkaline volcanism. The volcanic rocks, mainly subaques lava flows and subareal domes are concentrated along these basins and associated with Middle Eocene (Bartonian) Mucur Formation. They are basic to intermediate and are classified as basalt, basaltic andesite and rarely alkali basalt and trachy-andesite. All studied samples are strongly and variably LREE enriched relative to chondrite with the (La/Sm)N ratio of 2.26- to 6.17. They have negative Nb-Ta and Ti anomalies in the primitive mantle normalized diagram, and are characterized by low Nb/La (0.21 to 0.62), Ce/Pb (3.70-34.90) and Nb/U ratios (1.11-30), which may indicate an interaction with the Late Cretaceous granitic host rocks in the course of their ascent. The volcanic rocks display similar but variable ranges of Sr, Nd and Pb isotope values. Relatively high values of &epsilon / Nd (0.53 to 4.33) indicate an isotopically depleted mantle source. Combined trace element and isotope compositions of the Eocene samples suggest that they were derived from a heterogeneous lithospheric mantle source that had been metasomatized by subduction related agents such as fluids and/or melts during a previous geodynamic event. Geochemistry and geotectonic setting point out that lithospheric delamination was the most likely mechanism to generate these calc-alkaline to mildly alkaline volcanic rocks in the CACC. QE Petrology 420-499
15	Dynamics of the eastern edge of the Rio Grande Rift Xia, Yu 05 November 2013 (has links) The Western U.S. has experienced widespread extension during the past 10’s of millions of years, largely within the Basin and Range and Rio Grande Rift provinces. Tomography results from previous studies revealed narrow fast seismic velocity anomalies in the mantle on either side of the Rio Grande Rift as well as at the western edge of the Colorado Plateau. The fast mantle anomalies have been interpreted as down-welling that is part of small scale mantle convection at the edge of extending provinces. It was also found that crust was thicker than average ab¬¬ove the possible mantle down-welling, indicating that mantle dynamics may influence crustal flow. We present results from P/S conversion receiver functions using SIEDCAR (Seismic Investigation of Edge Driven Convection Associated with the Rio Grande Rift) data to determine crustal and lithospheric structure beneath the east flank of the Rio Grande Rift. Crustal and lithosphere thickness are estimated using P-to-S and S-to-P receiver functions respectively. Receiver function migration methods were applied to produce images of the crust and lithosphere. The results show variable crustal thickness through the region with an average thickness of 45 km. The crust achieves its maximum thickness of 60km at 105W longitude, between 33.5N and 32.2N latitude. This observation confirms previous receiver function results from Wilson et al, 2005. Body wave tomography (Rocket, 2011; Schmandt and Humphreys, 2010) using similar data to what we used for the receiver function analysis, shows mantle downwelling closely associated with the thickened crust. We believe that the thickened crust might be due to lower crustal flow associated with mantle downwelling or mantle delamination at the edge of the Rio Grande Rift. In this model the sinking mantle pulls the crust downward causing a pressure gradient within the crust thus causing the flow. Our S-P images show signal from the lithosphere-asthenosphere boundary (LAB) with an average LAB thickness of 100 km but with a sharp transition at about 1050 W from 75 km to over 100 km. The region with abnormally thick crust overlies a region where the lithosphere appears to have a break. We interpret our results as showing that lower lithosphere has and is delaminating near the edge of the Great Plains accompanied by lower crustal flow in some places determined by lower crustal viscosity. / text Crust thickness Mantle dynamics Crust flow Lithospheric structure Receiver function Crustal viscosity
16	Conditions of diamond formation and preservation from on- and off-craton settings Hunt, Lucy Unknown Date No description available. Diamond Lithospheric mantle thermobarometry Superior Craton Amazon Craton Xenocryst Xenolith metasomatism
17	Heterogeneidades do manto litosférico subcontinental sob a Patagônia : influências de subducção na cunha mantélica e de interações litosfera-astenosfera Gervasoni, Fernanda January 2012 (has links) A região sul da placa Sul-Americana, hoje pertencente à região da Patagônia Argentina e Chilena, formou-se por consequência de acreções continentais desde o Proterozóico. Atualmente, a região é caracterizada por um complexo sistema de placas tectônicas, no qual as placas oceânicas de Nazca, Antártica e Scotia interagem diretamente com a placa continental Sul-Americana através dos processos de subducção e transcorrência. Entre as placas de Nazca e Antártica, ocorre a dorsal do Chile, e a subducção desta dorsal sob a placa Sul-Americana forma a Junção Tríplice do Chile, ocorrendo o soerguimento da astenosfera na região. O magmatismo Cenozóico de composição alcalina que ocorre na região da Patagônia Argentina e Chilena hospeda xenólitos mantélicos ultramáficos de classificação espinélio- e granada-peridotitos. Estes xenólitos são de extrema importância para a caracterização e identificação dos processos atuantes no manto superior abaixo dessa complexa região que hoje é a Patagônia. Estudos do sistema isotópico Re-Os nos xenólitos de Prahuaniyeu (41°20’09.4”S, 67°54’08.1”W), e Chenque (43°38’39.3”S, 68°56’22”W), na região norte da Patagônia Argentina, sugerem que a litosfera abaixo de Prahuaniyeu (TRD ~ 1.69 Ga) é mais antiga que Chenque (TRD ~ 0.71 Ga). Dados de Rb-Sr mostram que a litosfera da região norte da Patagônia possui altas razões 87Sr/86Sr (Prahuaniyeu: 0,7037 a 0,7041; Chenque: 0.7037 a 0.7086), devido fluidos relacionados a desidratação de uma placa de subducção. Através destes dados e dos dados geoquímicos, o manto litosférico subcontinental da região norte da Patagônia sofreu metassomatismo relacionado a slabs derivados de antigas placas de subducção e que proporcionou características de metassomatismo por líquidos/fluidos do tipo-OIB, e atualmente sofreu metassomatismo relacionado aos fluidos derivados da desidratação da placa de subducção atual (Nazca), caracterizados pelo enriquecimento em calcófilos. Todos os peridotitos de Laguna Timone (52°01’39” S, 70°12’53” W), no Campo Vulcânico de Pali Aike, região sul da Patagônia Chilena, também apresentam expressivo enriquecimento nos elementos calcófilos sugerindo que o manto litosférico subcontinental da região sul da Patagônia também foi metasomatisado pelos fluidos derivados da desidratação da placa de subducção atual (Antártica). Em Laguna Timone também há a ocorrência de um glimerito entre os xenólitos e a presença de flogopita e pargasita nos peridotitos classificados como gr-sp lherzolitos, sp-lherzolitos e gr-sp harzburgitos. A presença de um glimerito, de peridotitos com minerais hidratados (flogopita e pargasita) e as similaridades com peridotitos metassomatisados por líquidos astenosféricos (peridotitos do distrito de Manzaz, Argélia e do campo vulcânico Vitim, no lago de Baikal, Sibéria) com baixas razões Ba/Nb, Ba/La e U/Nb, indicam que a litosfera da região sul da Patagônia sofreu metassomatismo por fluidos astenosféricos, ocasionado devido o soerguimento da astensofera durante a passagem da Junção Tríplice do Chile pela região de Pali Aike. / The southern of the South-American plate, today is the Chile and Argentina Patagonia region, was formed as a result of continental accretions since the Proterozoic.Currently, this region is characterized for a complex tectonic plates system, in which Nazca, Antartica and Scotia oceanic plates interact directly to the South-American continental plate by subduction and transcorrent process. Between Nazca and Antartica plate occurs the Chile Ridge, and the Chile Ridge subduction under the South-American plate creates the Chile Triple Junction and the upwelling of underlying asthenospheric mantle in this region. The Cenozoic alkali magamtism that occurs in Patagonia Argentina and Chilena hosts ultramafic mantle xenoliths (spinel- and garnet-peridotites). These xenoliths are extremely important to characterization and identification of the processes that occurred in the upper mantle underneath the Patagonia region. The Re-Os isotopic studies in Prahuaniyeu (41°20’09.4”S, 67°54’08.1”W), and Chenque (43°38’39.3”S, 68°56’22”W) xenoliths, in north Patagonia Argentina, suggests the Prahuaniyeu lithosphere (TRD ~ 1.69 Ga) were formed previously to Chenque (TRD ~ 0.71 Ga). Rb-Sr data show high 87Sr/86Sr ratio (Prahuaniyeu: 0.7037 to 0.7041; Chenque: 0.7037 to 0.7086), suggesting interactions with subduction plate dehydration related fluids. Trough this data, and geochemistry data, the sucontinental lithospheric mantle underneath the north Patagonia region suffered two metasomatic events: one related to the OIB-like melt/fluids from slabs derived by ancient subductions; and another related to the fluids derived from the current subducted plate (Nazca) dehydration, characterized by the chalcophiles enrichment. Peridotites from Laguna Timone (52°01’39” S, 70°12’53” W), in the Pali Aike Volcanic Field, southern Patagonia Chilena region, also shows expressive enrichment in chalcophile elements suggesting metasomatism by fluids from currently subduction (Antartica plate). Another kind of metasomatism occurs in subcontinental lithospheric mantle underneath Pali Aike due the glimmerite occurrence, hydrated minerals (phlogopite and pargasite) in peridotites and similarities with peridotites that suffered metasomatism by asthenospheric melts (Manzaz, Argelia peridotites and Vitim Volcanic Field, Baikal, Siberia peridotites), with low Ba/Nb, Ba/La and U/Nb. All these carachteristics suggest that lithosphere suffered interactions between asthenosphere-lithosphere due upwelling of underlying asthenospheric mantle when the Chile Triple Junction was on the same latitude of Pali Aike. Geoquímica Metassomatismo Patagônia (Argentina e Chile) Subcontinental lithospheric mantle Mantle xenoliths Metasomatism Subduction
18	Controle de mudanças estruturais sob altas pressões e altas temperaturas da esmectita saturada em potássio Carniel, Larissa Colombo January 2013 (has links) O manto litosférico é depletado em elementos incompatíveis como potássio, rubídio e estrôncio, confinado sob altas condições de pressão e caracterizado por uma composição e mineralogia específicas: espinélios anidros e/ou granada lherzolitos e harzburgitos. Esta região pode ser hidratada e enriquecida em elementos incompatíveis (ex. potássio) através de processos de subducção, onde a placa oceânica subductada leva consigo material pelágico composto de argilominerais e filossilicatos. A transferência de massa entre a placa subductada com os sedimentos e a cunha mantélica ocorre primeiramente através da liberação de fluidos aquosos gerados pela devolatilização de minerais hidratados. Neste contexto, a esmectita destaca-se como um dos mais importantes minerias responsáveis pelo enriquecimento do manto litosférico em água e elementos incompatíveis, quando sua estrutura é desestabilizada. Com o aumento da pressão e temperatura, esmectitas perdem sua água interlamelar, ao mesmo tempo em que se transformam em camadas mistas esmectita-ilita. Nestas condições de desidratação, e com o aumento da pressão, mudanças estruturais ocorrem e, havendo potássio disponível no sistema, o argilomineral evolui para uma mica muscovita. Considerando este contexto, o presente trabalho tem como objetivo verificar o comportamento estrutural da esmectita saturada em potássio modificando as variáveis pressão e temperatura: (1) sob pressão atmosférica em diferentes temperaturas (100º a 700ºC); (2) sob pressão de até 11.5 GPa sem temperatura - Diamond Anvil Cell (DAC); (3) sob diferentes pressões com aplicação de temperatura: 2.5GPa (400º a 700ºC) e 4.0GPa (200º a 700ºC). Os resultados das técnicas de análise de Difração de raios X, Microscopia Eletrônica de Varredura (MEV), Microscopia Eletrônica de Transmissão (MET) e Espectroscopia por Infravermelho (FTIR) sugerem que, sob uma pressão de 2.5 GPa, que é cerca de 75km de profundidade no manto, e a aproximadamente 500ºC, a esmectita transforma-se em muscovita, enquanto sob a pressão de 4.0 Gpa, equivalente a cerca de 120 km de profundidade, a mesma transformação ocorre a 400ºC. Estes resultados contribuem significativamente para o entendimento de como a desidratação do sedimento pelágico ocorre em um processo de subducção, bem como o comportamento da esmectita sob a influência do aumento de pressão e temperatura. / The lithospheric mantle is depleted regarding to incompatible elements as potassium, rubidium and strontium, confined under pressure conditions and characterized by a specific mineralogy and composition, basically as anhydrous spinel and/or garnet lherzolite and harzburgite. This region can be hydrated and enriched in incompatible elements (e.g. potassium) through subduction processes that bring pelagic material, composed of clay minerals and other phyllosilicates, together with the hydrated subducted oceanic slab. A mass transfer from the subducted slab plus sediments into the mantle wedge occurs primarily through the release of aqueous fluids produced by devolatilization of hydrated minerals. In this context, smectite stands out as one of the most important minerals responsible for enriching the lithospheric mantle with water and incompatible elements when its structure is destabilized. By pressure and temperature increasing smectite lose its interlayer water, at the same time that it transforms into a mixed-layer illite-smectite. In this condition of dehydration and with increasing pressure, structural changes occur and, having potassium available on the system, the clay mineral evolves into a muscovite mica. Considering this context, we verified the structural behavior of potassium saturated smectite modifying variables pressure and temperature: (1) under atmospheric pressure at different temperatures (100º to 700º C); (2) under pressure up 11.5 GPa without temperature - Diamond Anvil Cell (DAC); (3) under different pressures with temperature application: 2.5 GPa (400º to 700º C) and 4.0 GPa (200º to 700º C). The results of the analysis techniques of X-ray diffraction, Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM) and Infrared Spectroscopy (FTIR), suggest that under the pressure of 2.5 GPa, which is about 75km depth in the mantle, and at around 500ºC smectite transforms into muscovite, while under the pressure of 4.0 GPa, equivalent to around 120km depth, the same transformation occurs at 400ºC. These results contribute significantly to understanding how pelagic sediment dehydration occurs in a subduction process, as well as the behavior of smectite under the influence of increasing pressure and temperature. Geologia Petrologia experimental Geoquímica Altas pressões Lithospheric mantle Smectite Dehydration Subduction High pressure
19	Controle de mudanças estruturais sob altas pressões e altas temperaturas da esmectita saturada em potássio Carniel, Larissa Colombo January 2013 (has links) O manto litosférico é depletado em elementos incompatíveis como potássio, rubídio e estrôncio, confinado sob altas condições de pressão e caracterizado por uma composição e mineralogia específicas: espinélios anidros e/ou granada lherzolitos e harzburgitos. Esta região pode ser hidratada e enriquecida em elementos incompatíveis (ex. potássio) através de processos de subducção, onde a placa oceânica subductada leva consigo material pelágico composto de argilominerais e filossilicatos. A transferência de massa entre a placa subductada com os sedimentos e a cunha mantélica ocorre primeiramente através da liberação de fluidos aquosos gerados pela devolatilização de minerais hidratados. Neste contexto, a esmectita destaca-se como um dos mais importantes minerias responsáveis pelo enriquecimento do manto litosférico em água e elementos incompatíveis, quando sua estrutura é desestabilizada. Com o aumento da pressão e temperatura, esmectitas perdem sua água interlamelar, ao mesmo tempo em que se transformam em camadas mistas esmectita-ilita. Nestas condições de desidratação, e com o aumento da pressão, mudanças estruturais ocorrem e, havendo potássio disponível no sistema, o argilomineral evolui para uma mica muscovita. Considerando este contexto, o presente trabalho tem como objetivo verificar o comportamento estrutural da esmectita saturada em potássio modificando as variáveis pressão e temperatura: (1) sob pressão atmosférica em diferentes temperaturas (100º a 700ºC); (2) sob pressão de até 11.5 GPa sem temperatura - Diamond Anvil Cell (DAC); (3) sob diferentes pressões com aplicação de temperatura: 2.5GPa (400º a 700ºC) e 4.0GPa (200º a 700ºC). Os resultados das técnicas de análise de Difração de raios X, Microscopia Eletrônica de Varredura (MEV), Microscopia Eletrônica de Transmissão (MET) e Espectroscopia por Infravermelho (FTIR) sugerem que, sob uma pressão de 2.5 GPa, que é cerca de 75km de profundidade no manto, e a aproximadamente 500ºC, a esmectita transforma-se em muscovita, enquanto sob a pressão de 4.0 Gpa, equivalente a cerca de 120 km de profundidade, a mesma transformação ocorre a 400ºC. Estes resultados contribuem significativamente para o entendimento de como a desidratação do sedimento pelágico ocorre em um processo de subducção, bem como o comportamento da esmectita sob a influência do aumento de pressão e temperatura. / The lithospheric mantle is depleted regarding to incompatible elements as potassium, rubidium and strontium, confined under pressure conditions and characterized by a specific mineralogy and composition, basically as anhydrous spinel and/or garnet lherzolite and harzburgite. This region can be hydrated and enriched in incompatible elements (e.g. potassium) through subduction processes that bring pelagic material, composed of clay minerals and other phyllosilicates, together with the hydrated subducted oceanic slab. A mass transfer from the subducted slab plus sediments into the mantle wedge occurs primarily through the release of aqueous fluids produced by devolatilization of hydrated minerals. In this context, smectite stands out as one of the most important minerals responsible for enriching the lithospheric mantle with water and incompatible elements when its structure is destabilized. By pressure and temperature increasing smectite lose its interlayer water, at the same time that it transforms into a mixed-layer illite-smectite. In this condition of dehydration and with increasing pressure, structural changes occur and, having potassium available on the system, the clay mineral evolves into a muscovite mica. Considering this context, we verified the structural behavior of potassium saturated smectite modifying variables pressure and temperature: (1) under atmospheric pressure at different temperatures (100º to 700º C); (2) under pressure up 11.5 GPa without temperature - Diamond Anvil Cell (DAC); (3) under different pressures with temperature application: 2.5 GPa (400º to 700º C) and 4.0 GPa (200º to 700º C). The results of the analysis techniques of X-ray diffraction, Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM) and Infrared Spectroscopy (FTIR), suggest that under the pressure of 2.5 GPa, which is about 75km depth in the mantle, and at around 500ºC smectite transforms into muscovite, while under the pressure of 4.0 GPa, equivalent to around 120km depth, the same transformation occurs at 400ºC. These results contribute significantly to understanding how pelagic sediment dehydration occurs in a subduction process, as well as the behavior of smectite under the influence of increasing pressure and temperature. Geologia Petrologia experimental Geoquímica Altas pressões Lithospheric mantle Smectite Dehydration Subduction High pressure
20	Heterogeneidades do manto litosférico subcontinental sob a Patagônia : influências de subducção na cunha mantélica e de interações litosfera-astenosfera Gervasoni, Fernanda January 2012 (has links) A região sul da placa Sul-Americana, hoje pertencente à região da Patagônia Argentina e Chilena, formou-se por consequência de acreções continentais desde o Proterozóico. Atualmente, a região é caracterizada por um complexo sistema de placas tectônicas, no qual as placas oceânicas de Nazca, Antártica e Scotia interagem diretamente com a placa continental Sul-Americana através dos processos de subducção e transcorrência. Entre as placas de Nazca e Antártica, ocorre a dorsal do Chile, e a subducção desta dorsal sob a placa Sul-Americana forma a Junção Tríplice do Chile, ocorrendo o soerguimento da astenosfera na região. O magmatismo Cenozóico de composição alcalina que ocorre na região da Patagônia Argentina e Chilena hospeda xenólitos mantélicos ultramáficos de classificação espinélio- e granada-peridotitos. Estes xenólitos são de extrema importância para a caracterização e identificação dos processos atuantes no manto superior abaixo dessa complexa região que hoje é a Patagônia. Estudos do sistema isotópico Re-Os nos xenólitos de Prahuaniyeu (41°20’09.4”S, 67°54’08.1”W), e Chenque (43°38’39.3”S, 68°56’22”W), na região norte da Patagônia Argentina, sugerem que a litosfera abaixo de Prahuaniyeu (TRD ~ 1.69 Ga) é mais antiga que Chenque (TRD ~ 0.71 Ga). Dados de Rb-Sr mostram que a litosfera da região norte da Patagônia possui altas razões 87Sr/86Sr (Prahuaniyeu: 0,7037 a 0,7041; Chenque: 0.7037 a 0.7086), devido fluidos relacionados a desidratação de uma placa de subducção. Através destes dados e dos dados geoquímicos, o manto litosférico subcontinental da região norte da Patagônia sofreu metassomatismo relacionado a slabs derivados de antigas placas de subducção e que proporcionou características de metassomatismo por líquidos/fluidos do tipo-OIB, e atualmente sofreu metassomatismo relacionado aos fluidos derivados da desidratação da placa de subducção atual (Nazca), caracterizados pelo enriquecimento em calcófilos. Todos os peridotitos de Laguna Timone (52°01’39” S, 70°12’53” W), no Campo Vulcânico de Pali Aike, região sul da Patagônia Chilena, também apresentam expressivo enriquecimento nos elementos calcófilos sugerindo que o manto litosférico subcontinental da região sul da Patagônia também foi metasomatisado pelos fluidos derivados da desidratação da placa de subducção atual (Antártica). Em Laguna Timone também há a ocorrência de um glimerito entre os xenólitos e a presença de flogopita e pargasita nos peridotitos classificados como gr-sp lherzolitos, sp-lherzolitos e gr-sp harzburgitos. A presença de um glimerito, de peridotitos com minerais hidratados (flogopita e pargasita) e as similaridades com peridotitos metassomatisados por líquidos astenosféricos (peridotitos do distrito de Manzaz, Argélia e do campo vulcânico Vitim, no lago de Baikal, Sibéria) com baixas razões Ba/Nb, Ba/La e U/Nb, indicam que a litosfera da região sul da Patagônia sofreu metassomatismo por fluidos astenosféricos, ocasionado devido o soerguimento da astensofera durante a passagem da Junção Tríplice do Chile pela região de Pali Aike. / The southern of the South-American plate, today is the Chile and Argentina Patagonia region, was formed as a result of continental accretions since the Proterozoic.Currently, this region is characterized for a complex tectonic plates system, in which Nazca, Antartica and Scotia oceanic plates interact directly to the South-American continental plate by subduction and transcorrent process. Between Nazca and Antartica plate occurs the Chile Ridge, and the Chile Ridge subduction under the South-American plate creates the Chile Triple Junction and the upwelling of underlying asthenospheric mantle in this region. The Cenozoic alkali magamtism that occurs in Patagonia Argentina and Chilena hosts ultramafic mantle xenoliths (spinel- and garnet-peridotites). These xenoliths are extremely important to characterization and identification of the processes that occurred in the upper mantle underneath the Patagonia region. The Re-Os isotopic studies in Prahuaniyeu (41°20’09.4”S, 67°54’08.1”W), and Chenque (43°38’39.3”S, 68°56’22”W) xenoliths, in north Patagonia Argentina, suggests the Prahuaniyeu lithosphere (TRD ~ 1.69 Ga) were formed previously to Chenque (TRD ~ 0.71 Ga). Rb-Sr data show high 87Sr/86Sr ratio (Prahuaniyeu: 0.7037 to 0.7041; Chenque: 0.7037 to 0.7086), suggesting interactions with subduction plate dehydration related fluids. Trough this data, and geochemistry data, the sucontinental lithospheric mantle underneath the north Patagonia region suffered two metasomatic events: one related to the OIB-like melt/fluids from slabs derived by ancient subductions; and another related to the fluids derived from the current subducted plate (Nazca) dehydration, characterized by the chalcophiles enrichment. Peridotites from Laguna Timone (52°01’39” S, 70°12’53” W), in the Pali Aike Volcanic Field, southern Patagonia Chilena region, also shows expressive enrichment in chalcophile elements suggesting metasomatism by fluids from currently subduction (Antartica plate). Another kind of metasomatism occurs in subcontinental lithospheric mantle underneath Pali Aike due the glimmerite occurrence, hydrated minerals (phlogopite and pargasite) in peridotites and similarities with peridotites that suffered metasomatism by asthenospheric melts (Manzaz, Argelia peridotites and Vitim Volcanic Field, Baikal, Siberia peridotites), with low Ba/Nb, Ba/La and U/Nb. All these carachteristics suggest that lithosphere suffered interactions between asthenosphere-lithosphere due upwelling of underlying asthenospheric mantle when the Chile Triple Junction was on the same latitude of Pali Aike. Geoquímica Metassomatismo Patagônia (Argentina e Chile) Subcontinental lithospheric mantle Mantle xenoliths Metasomatism Subduction

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