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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
31

Evolução petrogenética e geotectônica do Ofiolito Arroio Grande, SE do Cinturão Dom Feliciano (Brasil)

Ramos, Rodrigo Chaves January 2018 (has links)
O Ofiolito Arroio Grande, localizado no sudeste do Cinturão Dom Feliciano, próximo à fronteira Brasil/Uruguai, entre Arroio Grande e Jaguarão (RS), é uma associação metaultramáfica-máfica-sedimentar que representa fragmentos de uma mélange ofiolítica, relacionada à amalgamação do paleocontinente Gondwana Ocidental durante os estágios finais do ciclo orogênico Brasiliano-Panafricano. As rochas do Ofiolito Arroio Grande se encontram circundadas por rochas metassiliciclásticas do Complexo Arroio Grande, do qual o ofiolito faz parte, e também como xenólitos em meio a granitoides da Suíte Pinheiro Machado e do Granito Três Figueiras (os quais integram o Batólito Pelotas-Aiguá). A unidade metaultramáfica do ofiolito compreende serpentinitos e xistos magnesianos cromíferos. Sua unidade metamáfica é constituída por anfibolitos, metagabros e metadioritos. A unidade metassedimentar compreende mármores calcíticos, intrudidos por enxame de diques máficos. O Ofiolito Arroio Grande está posicionado ao longo da Zona de Cisalhamento Ayrosa Galvão-Arroio Grande (transcorrente, dúctil, alto ângulo), responsável pela milonitização da maioria das rochas dessa associação. As investigações desenvolvidas no ofiolito tiveram o objetivo de identificar as fontes magmáticas dos protólitos e os processos que ocorreram desde sua geração no manto/crosta oceânica até sua incorporação no continente, além de obter idades (absolutas e relativas) referentes a esses processos. Para os metaultramafitos, a geoquímica de rocha total (e.g. Ni >1000 ppm; Cr > 1500 ppm), em conjunto com a química mineral de cromitas (e.g. Cr# 0,6-0,8; TiO2 0,01-0,20 %peso; Fe2+/Fe3+ ± 0,9), sugeriu protólitos harzburgíticos mantélicos, cuja fonte é um manto depletado sob uma região de espalhamento oceânico de retroarco, que experimentou altas taxas de fusão parcial. Esses harzburgitos foram posteriormente serpentinizados em ambiente oceânico, sugerido pelas razões 87Sr/86Sr630 de um serpentinito (ca. 0,707). Para os metamafitos, a geoquímica de rocha total e isotópica sugeriram protólitos toleíticos oceânicos, gerados em um contexto de suprassubducção em ambiente de retroarco (e.g. Cr 260-600 ppm; Nb/Y 0,1-0,5; Ti/Y ± 500; La/Nb 2-5; Th/Yb 0,1-5 e Nb/Yb 1-5; padrões de REE; razões 87Sr/86Sr630 variando de MORB – 0,703 – a IAT – 0,705-0,707), cuja fonte magmática foi enriquecida por material crustal e fluidos relacionados à subducção. A idade mínima para a obducção e metamorfismo das unidades ofiolíticas foi estimada em 640 Ma, a partir da datação (U-Pb SHRIMP) de um quartzo sienito. Esse último é o resultado de fusões relacionadas a intrusões diorítico-tonalíticas, atribuídas ao magmatismo de arco continental da Suíte Pinheiro Machado. Essas intrusões afetaram os mármores e os anfibolitos (fragmentos dos enxames de diques máficos), de maneira que, em pelo menos 640 Ma, rochas da mélange ofiolítica (já metamorfizadas) estavam alojadas em ambiente continental. Um evento metassomático posterior (relacionado à intrusão do Granito Três Figueiras, sincinemática à zona de cisalhamento acima referida) afetou os serpentinitos, gerando zonas de talcificação, tremolitização e cloritização, essa última representando um blackwall que também envolveu unidades metassiliciclásticas do Complexo Arroio Grande. O Ofiolito Arroio Grande foi inserido no contexto geotectônico da bacia de retroarco Marmora, cujos fragmentos são encontrados na Namíbia (Terreno Marmora) e no Uruguai (Complexo Paso del Dragón e Bacia Rocha – Terreno Punta del Este). / The Arroio Grande Ophiolite, located in the southeastern region of the Dom Feliciano Belt, near the Brazil/Uruguay border, is a metaultramafic-mafic-sedimentary association which represents slices of an ophiolitic mélange, related to the Western Gondwana amalgamation during the late stages of the Brasiliano-Panafrican orogenic cycle. The Arroio Grande Ophiolite rocks are enveloped by metasiliciclastic units of the Arroio Grande Complex and occur as xenolyths within granitoids of the Pinheiro Machado Suite and within the Três Figueiras Granite (units of the Pelotas-Aiguá Batholith). The metaultramafites of the ophiolite comprise serpentinites and Cr-rich magnesian schists. The metamafites comprise amphibolites, metagabbros and metadiorites. The metasedimentary unit comprises calcitic marbles, which are intruded by mafic dykes. The ophiolite is found along the Ayrosa Galvão- Arroio Grande Shear Zone (transcurrent, ductile, high angle), responsible for the mylonitization of this association. The investigations developed in this ophiolite had the objective of identify the magmatic sources of the protoliths and the processes that occurred since their generation within the mantle/oceanic crust until their incorporation into the continental crust, including their absolute and relative ages. The bulk-rock chemistry of the metaultramafites (e.g. Ni >1000 ppm; Cr > 1500 ppm), together with the mineral chemistry of the chromites (e.g. Cr# 0.6-0.8; TiO2 0.01-0.20 wt%; Fe2+/Fe3+ ± 0.9), suggested harzburgitic protoliths, attributed to a depleted mantle source under a back-arc spreading region, which experienced high degrees of partial melting. These harzburgites were serpentinized in an oceanic setting, as suggested by the 87Sr/86Sr630 ratio of a serpentinite (ca. 0.707). The bulkrock chemistry of the metamafites suggested oceanic tholeiitic protoliths, generated in a supra-subduction setting in a back-arc environment (e.g. Cr 260-600 ppm; Nb/Y 0.1-0.5; Ti/Y ± 500; La/Nb 2-5; Th/Yb 0.1-5 and Nb/Yb 1-5; REE patterns; 87Sr/86Sr630 ratios ranging from MORB – 0.703 – to IAT – 0.705-0.707), whose magmatic source was contaminated by crustal material and subduction-related fluids. The minimum age for the obduction and metamorphism of the Arroio Grande Ophiolite rocks was estimated around 640 Ma from the U-Pb age of a quartz-syenite. The latter is the result of melting, related to dioritic-tonalitc intrusions, attributed to the continental magmatism of the Pinheiro Machado Suite. These intrusions affected both the marbles and the amphibolites (fragments of the mafic dykes), in order that, at least around 640 Ma, rocks of the ophiolitic mélange (already metamorphosed) were emplaced on the continent. A late metasomatic event (related to the emplacement of the Três Figueiras Granite, syn-kinematic to the abovementioned shear zone) affected the serpentinites, generating zones of talcification, tremolitization and chloritization, the latter representing a blackwall which also involved metasiliciclastic rocks of the Arroio Grande Complex. The Arroio Grande Ophiolite was inserted in the geotectonic context of the Marmora back-arc basin, whose fragments are found in Namibia (Marmora Terrane) and Uruguay (Paso del Dragón Complex and Rocha Basin – Punta del Este Terrane).
32

Evolução petrogenética e geotectônica do Ofiolito Arroio Grande, SE do Cinturão Dom Feliciano (Brasil)

Ramos, Rodrigo Chaves January 2018 (has links)
O Ofiolito Arroio Grande, localizado no sudeste do Cinturão Dom Feliciano, próximo à fronteira Brasil/Uruguai, entre Arroio Grande e Jaguarão (RS), é uma associação metaultramáfica-máfica-sedimentar que representa fragmentos de uma mélange ofiolítica, relacionada à amalgamação do paleocontinente Gondwana Ocidental durante os estágios finais do ciclo orogênico Brasiliano-Panafricano. As rochas do Ofiolito Arroio Grande se encontram circundadas por rochas metassiliciclásticas do Complexo Arroio Grande, do qual o ofiolito faz parte, e também como xenólitos em meio a granitoides da Suíte Pinheiro Machado e do Granito Três Figueiras (os quais integram o Batólito Pelotas-Aiguá). A unidade metaultramáfica do ofiolito compreende serpentinitos e xistos magnesianos cromíferos. Sua unidade metamáfica é constituída por anfibolitos, metagabros e metadioritos. A unidade metassedimentar compreende mármores calcíticos, intrudidos por enxame de diques máficos. O Ofiolito Arroio Grande está posicionado ao longo da Zona de Cisalhamento Ayrosa Galvão-Arroio Grande (transcorrente, dúctil, alto ângulo), responsável pela milonitização da maioria das rochas dessa associação. As investigações desenvolvidas no ofiolito tiveram o objetivo de identificar as fontes magmáticas dos protólitos e os processos que ocorreram desde sua geração no manto/crosta oceânica até sua incorporação no continente, além de obter idades (absolutas e relativas) referentes a esses processos. Para os metaultramafitos, a geoquímica de rocha total (e.g. Ni >1000 ppm; Cr > 1500 ppm), em conjunto com a química mineral de cromitas (e.g. Cr# 0,6-0,8; TiO2 0,01-0,20 %peso; Fe2+/Fe3+ ± 0,9), sugeriu protólitos harzburgíticos mantélicos, cuja fonte é um manto depletado sob uma região de espalhamento oceânico de retroarco, que experimentou altas taxas de fusão parcial. Esses harzburgitos foram posteriormente serpentinizados em ambiente oceânico, sugerido pelas razões 87Sr/86Sr630 de um serpentinito (ca. 0,707). Para os metamafitos, a geoquímica de rocha total e isotópica sugeriram protólitos toleíticos oceânicos, gerados em um contexto de suprassubducção em ambiente de retroarco (e.g. Cr 260-600 ppm; Nb/Y 0,1-0,5; Ti/Y ± 500; La/Nb 2-5; Th/Yb 0,1-5 e Nb/Yb 1-5; padrões de REE; razões 87Sr/86Sr630 variando de MORB – 0,703 – a IAT – 0,705-0,707), cuja fonte magmática foi enriquecida por material crustal e fluidos relacionados à subducção. A idade mínima para a obducção e metamorfismo das unidades ofiolíticas foi estimada em 640 Ma, a partir da datação (U-Pb SHRIMP) de um quartzo sienito. Esse último é o resultado de fusões relacionadas a intrusões diorítico-tonalíticas, atribuídas ao magmatismo de arco continental da Suíte Pinheiro Machado. Essas intrusões afetaram os mármores e os anfibolitos (fragmentos dos enxames de diques máficos), de maneira que, em pelo menos 640 Ma, rochas da mélange ofiolítica (já metamorfizadas) estavam alojadas em ambiente continental. Um evento metassomático posterior (relacionado à intrusão do Granito Três Figueiras, sincinemática à zona de cisalhamento acima referida) afetou os serpentinitos, gerando zonas de talcificação, tremolitização e cloritização, essa última representando um blackwall que também envolveu unidades metassiliciclásticas do Complexo Arroio Grande. O Ofiolito Arroio Grande foi inserido no contexto geotectônico da bacia de retroarco Marmora, cujos fragmentos são encontrados na Namíbia (Terreno Marmora) e no Uruguai (Complexo Paso del Dragón e Bacia Rocha – Terreno Punta del Este). / The Arroio Grande Ophiolite, located in the southeastern region of the Dom Feliciano Belt, near the Brazil/Uruguay border, is a metaultramafic-mafic-sedimentary association which represents slices of an ophiolitic mélange, related to the Western Gondwana amalgamation during the late stages of the Brasiliano-Panafrican orogenic cycle. The Arroio Grande Ophiolite rocks are enveloped by metasiliciclastic units of the Arroio Grande Complex and occur as xenolyths within granitoids of the Pinheiro Machado Suite and within the Três Figueiras Granite (units of the Pelotas-Aiguá Batholith). The metaultramafites of the ophiolite comprise serpentinites and Cr-rich magnesian schists. The metamafites comprise amphibolites, metagabbros and metadiorites. The metasedimentary unit comprises calcitic marbles, which are intruded by mafic dykes. The ophiolite is found along the Ayrosa Galvão- Arroio Grande Shear Zone (transcurrent, ductile, high angle), responsible for the mylonitization of this association. The investigations developed in this ophiolite had the objective of identify the magmatic sources of the protoliths and the processes that occurred since their generation within the mantle/oceanic crust until their incorporation into the continental crust, including their absolute and relative ages. The bulk-rock chemistry of the metaultramafites (e.g. Ni >1000 ppm; Cr > 1500 ppm), together with the mineral chemistry of the chromites (e.g. Cr# 0.6-0.8; TiO2 0.01-0.20 wt%; Fe2+/Fe3+ ± 0.9), suggested harzburgitic protoliths, attributed to a depleted mantle source under a back-arc spreading region, which experienced high degrees of partial melting. These harzburgites were serpentinized in an oceanic setting, as suggested by the 87Sr/86Sr630 ratio of a serpentinite (ca. 0.707). The bulkrock chemistry of the metamafites suggested oceanic tholeiitic protoliths, generated in a supra-subduction setting in a back-arc environment (e.g. Cr 260-600 ppm; Nb/Y 0.1-0.5; Ti/Y ± 500; La/Nb 2-5; Th/Yb 0.1-5 and Nb/Yb 1-5; REE patterns; 87Sr/86Sr630 ratios ranging from MORB – 0.703 – to IAT – 0.705-0.707), whose magmatic source was contaminated by crustal material and subduction-related fluids. The minimum age for the obduction and metamorphism of the Arroio Grande Ophiolite rocks was estimated around 640 Ma from the U-Pb age of a quartz-syenite. The latter is the result of melting, related to dioritic-tonalitc intrusions, attributed to the continental magmatism of the Pinheiro Machado Suite. These intrusions affected both the marbles and the amphibolites (fragments of the mafic dykes), in order that, at least around 640 Ma, rocks of the ophiolitic mélange (already metamorphosed) were emplaced on the continent. A late metasomatic event (related to the emplacement of the Três Figueiras Granite, syn-kinematic to the abovementioned shear zone) affected the serpentinites, generating zones of talcification, tremolitization and chloritization, the latter representing a blackwall which also involved metasiliciclastic rocks of the Arroio Grande Complex. The Arroio Grande Ophiolite was inserted in the geotectonic context of the Marmora back-arc basin, whose fragments are found in Namibia (Marmora Terrane) and Uruguay (Paso del Dragón Complex and Rocha Basin – Punta del Este Terrane).
33

A geochemical and geothermometric study of the Nahlin ophiolite, northwestern British Columbia

McGoldrick, Siobhan S.G. 22 August 2017 (has links)
The Nahlin ophiolite represents one of the largest (~80 km long) and best-preserved ophiolites in the Cordillera of British Columbia and Yukon, Canada, yet it has been understudied compared to other ophiolites worldwide. Bedrock mapping at 1:20,000 scale in the Menatatuline Range area shows that the ophiolite is structurally disrupted with mantle bodies divisible into two massifs: Hardluck and Menatatuline. Studies of 30 samples show that both massifs consist of spinel harzburgites and minor lherzolites that have been strongly depleted by melt extraction (<2 wt % Al2O3 and ~45 wt % MgO). Clinopyroxene REE abundances determined by LA-ICP-MS illustrate different extents of depletion between the two massifs, with YbN varying from 2.3 – 5.0 and 1.7 – 2.2 in the Hardluck and Menatatuline massifs, respectively. Inversion modelling of the clinopyroxene REE abundances yields ~10 – 16% melting in the Hardluck massif and ~16 – 20% melting in the Menatatuline massif, with melt compositions that are compositionally similar to the gabbros and basalts proximal to the mantle rocks. All these extrusive and intrusive rocks in the ophiolite have an arc-signature, implying that the Nahlin ophiolite formed in a supra-subduction zone (SSZ) environment. The Nahlin peridotites document a two-stage evolution: depletion of a locally heterogeneous mantle source by hydrous fractional melting, followed by refertilization of the refractory harzburgite in the mantle wedge evidenced by LREE enrichment in clinopyroxene and whole-rock chemistry. This two-stage evolution is also recorded by the thermal history of the harzburgites. The REE-in-two-pyroxene thermometry has been reset following cryptic and modal metasomatism and relatively slow cooling, whereas major element two pyroxene geothermometry records temperatures varying from near solidus (~1290 °C) to ~800 °C, with the highest temperatures recorded in samples from the Menatatuline massif. The refractory nature of the Menatatuline harzburgites in combination with the arc-influenced volcanic geochemistry provides overwhelming evidence for a SSZ origin. Peridotite from the Hardluck massif displays characteristics of both abyssal and SSZ peridotites. These geochemical and geothermometric constraints can be reconciled by evolution of the Hardluck and Menatatuline massifs as two separate segments along a backarc ridge system, later juxtaposed by dextral strike-slip faulting. Alternatively, the Nahlin ophiolite may represent proto-forearc seafloor spreading associated with subduction initiation akin to the proposed origins of the Izu-Bonin-Mariana arc (Stern et al. 2012; Maffione et al. 2015). In any case, the geochemical data for peridotites and magmatic rocks herein require that the SSZ-type Nahlin ophiolite reside in the upper plate at an intraoceanic convergent margin. This interpretation has strong implications for models of northern Cordilleran tectonics, where the Cache Creek terrane is typically shown as a subducting ocean basin during Cordilleran orogenesis. / Graduate
34

Significance of Stress Interactions Related to the Occurrence of Shallow Slow Earthquakes / 浅部スロー地震の発生に関連した応力変化とその相互作用

Katakami, Satoshi 23 March 2020 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第22258号 / 理博第4572号 / 新制||理||1656(附属図書館) / 京都大学大学院理学研究科地球惑星科学専攻 / (主査)准教授 伊藤 喜宏, 教授 James Mori, 教授 岩田 知孝 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
35

Evolution of the Mio-Pleistocene forearc basin induced by the plate subduction in the Boso Peninsula, central Japan / プレート沈み込みによる房総半島新第三系および第四系前弧海盆の形成過程

Kamiya, Nana 23 March 2020 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第22424号 / 工博第4685号 / 新制||工||1731(附属図書館) / 京都大学大学院工学研究科都市社会工学専攻 / (主査)教授 林 為人, 教授 小池 克明, 准教授 村田 澄彦 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM
36

Discovery of Paleotsunami Deposits along Eastern Sunda Arc: Potential for Megathrust Earthquakes in Bali

Sulaeman, Hanif Ibadurrahman 01 December 2018 (has links)
Several laterally extensive candidate tsunami deposits are preserved along coastlines facing the eastern Java Trench, indicating it has experienced mega-thrust earthquakes in the past. We investigated 37 coastal sites in Bali, Lombok, Sumba and Timor islands, many of which preserve course sand and pebble layers that overlie sharp basal contacts with scour marks into the mud, fine upward in grain size, and have bimodal grain size distributions. Other unique features are the common occurrence of marine fossils and concentrations of heavy minerals. The occurrence of these high-energy deposits interlayered with clay-rich units indicates the coarse clastics are anomalous because they were deposited in what is normally a very low-energy depositional environment. The lateral extent and paucity of thin, coarse clastic layers with marine organisms are inconsistent with local stream flood event, and the proximity to the equator of the sites diminishes the possibility of marine flood events from cyclones. The sparse, but consistent, the occurrence of at least two candidate tsunami deposits at depths of 1 and 2 meters over 950 km along the strike of the Java Trench may reveal that mega-thrust earthquakes have occurred there and generated giant tsunamis in the recent past. Five widely scattered imbricated boulder deposits are also found on Bali, Lombok, and Sumba. The boulders consist of slabs of hardpan up to 2.5 m in length and 80 cm thick that was torn from a near-shore seabed and stacked on top of one another. Some of the boulders were carried over the erosional coastal bank and deposited up to 100 meters inland. Comparisons with imbricated boulder ridges formed during the 1994 tsunami in east Java indicate that these deposits are from one or multiple tsunamis sourced by the Java Trench. Experiments in effective ways to communicate and implement tsunami disaster mitigation strategies have led us to train local communities about the 20-20-20 rule. If coastal communities experience more than 20 seconds of shaking from an earthquake, even if it is not intense, they should evacuate the coast. The time delay between the earthquake and arrival of tsunami waves is around 20 minutes, which is the time window for evacuation. Some tsunami waves may be as high as 20 meters, which is the target elevation for evacuation. Adopting the 20-20-20 rule could save thousands of lives throughout the region, especially in Bali where nearly 1 million people inhabit likely tsunami inundation zones.
37

Metamorphic P-T Path and Multiple Fluid Events During Burial and Exhumation of the Tso Morari UHP Terrane, NW Himalaya

Pan, Ruiguang 11 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The Tso Morari terrane within the Himalayan orogenic belt underwent ultrahigh-pressure (UHP) coesite-eclogite metamorphism due to northward subduction of the Indian continent under the Eurasian continent during the early Eocene. In this study we optimized a best protocol for thermodynamically modelling pressure-temperature (P-T) paths of high-grade metabasites using the Tso Morari eclogite as a case study through evaluating the effects of employing commonly used thermodynamic modeling techniques (e.g., programs, thermodynamic datasets, a-X relations). A “fishhook” shaped clockwise P-T path was obtained with a peak pressure of ~28.5 kbar at ~563 °C, followed by a peak temperature of ~613 °C at ~24.5 kbar. The peak pressures predicted by modelling protocols are consistent with the conventional thermobarometry results and petrographic observations from the Tso Morari eclogites. Secondly, thermodynamic modelling using P-M(H2O) pseudosections on Tso Morari UHP rocks indicates three distinct fluid events during the prograde and retrograde metamorphism. Fluid Event 1 caused the fluid-assisted homogenization of prograde garnet cores in eclogite at ~18.5 kbar and ~555 °C; Fluid Event 2 is evidenced by the formation of poikiloblastic epidote (~23.5 kbar and ~610 °C, at the expense of lawsonite) and amphibole (from ~19.0 to ~14.5 kbar at ~610 °C, at the expense of omphacite and talc), and symplectite association (~8.7 kbar and ~625 °C) in the eclogite matrix without external fluid supply. Fluid Event 3 was determined through modelling the amphibolitization of eclogites with external fluid infiltration at ~9.0–12.5 kbar and ~608 °C. This fluid phase most likely derived from the mixing of dehydrated host orthogneiss and/or metasediments during exhumation through the amphibolite-facies zone in the subduction channel. This study demonstrates the need for using careful petrographic observations in parallel with thermodynamic modelling to achieve realistic results. / 2023-12-02
38

Effects of biogenic amorphous silica component in materials entering subduction zones on frictional properties of interplate megathrust / 沈み込み帯に持ち込まれる物質に含まれる生物起源非晶質シリカがプレート境界断層の摩擦特性に与える影響

Namiki, Yuka 26 March 2018 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20925号 / 理博第4377号 / 新制||理||1628(附属図書館) / 京都大学大学院理学研究科地球惑星科学専攻 / (主査)教授 田上 高広, 教授 下林 典正, 准教授 河上 哲生 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
39

SPATIAL AND TEMPORAL PATTERNS OF NON-VOLCANIC TREMOR ALONG THE SOUTHERN CASCADIA SUBDUCTION ZONE

Boyarko, Devin C. 11 December 2009 (has links)
No description available.
40

Compressible Convection and Subduction: Kinematic and Dynamic Modeling

Lee, Changyeol 25 October 2010 (has links)
Subduction is a dynamic and time-dependent process which requires time-dependent models for its study. In addition, due to the very high pressures within the Earth's interior, an evaluation of the role of compressibility in subduction studies should be undertaken. However, most subduction studies have been conducted by using kinematic, steady-state, and/or incompressible mantle convection models; these simplifications may miss important elements of the subduction process. In this dissertation, I evaluate the effects of time-dependence and compressibility on the evolution of subduction by using 2-D Cartesian numerical models. The effect of compressibility on the thermal and flow structures of subduction zones is evaluated by using kinematically prescribed slab and steady-state models. The effect of compressibility is primarily expressed as an additional heat source created by viscous dissipation. The heat results in thinner thermal boundary layer on the subducting slab and increases slab temperatures. With that exception, the effect of compressibility is relatively small compared with, for example, the effect of the mantle rheology on the thermal and flow structures of the mantle wedge. Plate reconstruction models show that the convergence rate and age of the incoming plate to trench vary with time, which poses a problem for steady-state subduction models. Thus, I consider the time-dependent convergence rate and age of the incoming plate in the kinematic-dynamic subduction models in order to understand the localization of high-Mg# andesites in the western Aleutians. The results show that the localization of high-Mg# andesites is a consequence of the time-dependent convergence rate and slab age along the Aleutian arc. The influence of mantle and slab parameters as well as compressibility on the slab dynamics is evaluated by using 2-D dynamic subduction models. The results demonstrate that periodic slab buckling in the mantle results in periodic convergence rate and dip of the subducting slab; time-dependence is a natural expression of subduction. The effect of compressibility on the slab dynamics is not significant. The periodic convergence rate and dip of the subducting slab explain time-dependent seafloor spreading at the mid-ocean ridge, convergence rate of the oceanic plate at trench and arc-normal migration of arc volcanoes. / Ph. D.

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