Global ETD Search

1	Fold-and-thrust belt deformation of the Hongliuhe Group: a Permian tectonic closure record of the Central Asian Orogenic Belt, NW China Cleven, Nathan January 2011 (has links) The Early Permian strata of the Hongliuhe Group, NW China, experienced a thin-skinned fold-and-thrust belt style of deformation that recorded the final stages of amalgamation of the Beishan orogenic collage, a part of the Central Asian Orogenic Belt. The Hongliuhe Group was syn-orogenically deposited on an undetermined foreland, with the Mazongshan arc terrane acting as the hinterland. In this study results from detailed mapping combined with a regional analysis elucidate involvement of a northward-dipping subduction system with the collision. Well-preserved fold-and-thrust belt style deformation mapped in the upper stratigraphy of the Hongliuhe Group exhibits dominantly south-southeast verging structure, including shear folding, low-angle thrust ramping, imbrication and duplexing. Restoration of a portion of a mapped outcrop-scale cross-section estimates the accommodation of a minimum of 24% shortening. Lower stratigraphy shows discrete, steeper, north-over-south dip-slip ductile shear zones that bound packages of less deformed Hongliuhe Group strata. Fault displacement is considered to have been prolonged enough to juxtapose basal formations in northerly hangingwalls against upper formations in southerly footwalls. Faulting is closely associated with the creation of large-scale brittle-ductile eye-fold structures that are postulated to be sheath folds. The most examined and mapped structure, 16km wide, is a synclinal structure with axes plunging steeply towards its center. The ellipticity of the exposed bedding traces increases towards the center of the eye-fold, implying a structural relationship with metamorphic shear zones. Except for large-scale folding, the bulk of its strata remain relatively undeformed and have preserved primary soft-sediment deformation structures indicating younging towards the center on both limbs of the synclinal structure. Stratigraphic reconstruction of the Hongliuhe Group that considers the significant faulting shows that the Group's basal conglomerates unconformably overlie a Late-Carboniferous volcanic assemblage. The clast lithotypes of the conglomeratic successions change from polymictic metamorphic rocks at the base to monomictic granitoid clasts mid-section, showing the gradual unroofing sequence of the provenance. The stratigraphic reconstruction shows a general fining upward sequence, transitioning from terrestrial to nearshore marine depositional environments that, and in conjunction with the conglomeratic successions, suggests that the tectonic setting for deposition of the Hongliuhe Group is a foreland basin. Considering the deformation styles reported in this study, the Hongliuhe Group is interpreted to be a foreland fold-and-thrust belt. Stratigraphic reconstruction of the Hongliuhe Group that considers the significant faulting shows that the Group’s basal conglomerates unconformably overlie a Late Carboniferous volcanic assemblage. The clast lithotypes of the conglomeratic successions change from polymictic metamorphic rocks at the base to monomictic granitoid mid-section, showing the gradual unroofing sequence of the provenance. The stratigraphic reconstruction shows a general fining upward sequence through nearshore depositional environments that, and in conjunction with the conglomeratic successions, give interpretation that the tectonic setting for deposition of the Hongliuhe Group is a foreland basin. Considering the deformation styles reported in this study the Hongliuhe Group is interpreted to be a foreland fold-and-thrust belt. Central Asian Orogenic Belt Altaids Fold-thrust-belt Structural geology Beishan Orogeny Earth Sciences
2	Fold-and-thrust belt deformation of the Hongliuhe Group: a Permian tectonic closure record of the Central Asian Orogenic Belt, NW China Cleven, Nathan January 2011 (has links) The Early Permian strata of the Hongliuhe Group, NW China, experienced a thin-skinned fold-and-thrust belt style of deformation that recorded the final stages of amalgamation of the Beishan orogenic collage, a part of the Central Asian Orogenic Belt. The Hongliuhe Group was syn-orogenically deposited on an undetermined foreland, with the Mazongshan arc terrane acting as the hinterland. In this study results from detailed mapping combined with a regional analysis elucidate involvement of a northward-dipping subduction system with the collision. Well-preserved fold-and-thrust belt style deformation mapped in the upper stratigraphy of the Hongliuhe Group exhibits dominantly south-southeast verging structure, including shear folding, low-angle thrust ramping, imbrication and duplexing. Restoration of a portion of a mapped outcrop-scale cross-section estimates the accommodation of a minimum of 24% shortening. Lower stratigraphy shows discrete, steeper, north-over-south dip-slip ductile shear zones that bound packages of less deformed Hongliuhe Group strata. Fault displacement is considered to have been prolonged enough to juxtapose basal formations in northerly hangingwalls against upper formations in southerly footwalls. Faulting is closely associated with the creation of large-scale brittle-ductile eye-fold structures that are postulated to be sheath folds. The most examined and mapped structure, 16km wide, is a synclinal structure with axes plunging steeply towards its center. The ellipticity of the exposed bedding traces increases towards the center of the eye-fold, implying a structural relationship with metamorphic shear zones. Except for large-scale folding, the bulk of its strata remain relatively undeformed and have preserved primary soft-sediment deformation structures indicating younging towards the center on both limbs of the synclinal structure. Stratigraphic reconstruction of the Hongliuhe Group that considers the significant faulting shows that the Group's basal conglomerates unconformably overlie a Late-Carboniferous volcanic assemblage. The clast lithotypes of the conglomeratic successions change from polymictic metamorphic rocks at the base to monomictic granitoid clasts mid-section, showing the gradual unroofing sequence of the provenance. The stratigraphic reconstruction shows a general fining upward sequence, transitioning from terrestrial to nearshore marine depositional environments that, and in conjunction with the conglomeratic successions, suggests that the tectonic setting for deposition of the Hongliuhe Group is a foreland basin. Considering the deformation styles reported in this study, the Hongliuhe Group is interpreted to be a foreland fold-and-thrust belt. Stratigraphic reconstruction of the Hongliuhe Group that considers the significant faulting shows that the Group’s basal conglomerates unconformably overlie a Late Carboniferous volcanic assemblage. The clast lithotypes of the conglomeratic successions change from polymictic metamorphic rocks at the base to monomictic granitoid mid-section, showing the gradual unroofing sequence of the provenance. The stratigraphic reconstruction shows a general fining upward sequence through nearshore depositional environments that, and in conjunction with the conglomeratic successions, give interpretation that the tectonic setting for deposition of the Hongliuhe Group is a foreland basin. Considering the deformation styles reported in this study the Hongliuhe Group is interpreted to be a foreland fold-and-thrust belt. Central Asian Orogenic Belt Altaids Fold-thrust-belt Structural geology Beishan Orogeny Earth Sciences
3	Birth, life, and demise of the Andean-syn-collisional Gissar arc: Late Paleozoic tectono-magmatic-metamorphic evolution of the southwestern Tian Shan, Tajikistan Worthington, James R., Kapp, Paul, Minaev, Vladislav, Chapman, James B., Mazdab, Frank K., Ducea, Mihai N., Oimahmadov, Ilhomjon, Gadoev, Mustafo 10 1900 (has links) The amalgamation of the Central Asian Orogenic Belt in the southwestern Tian Shan in Tajikistan is represented by tectono-magmatic-metamorphic processes that accompanied late Paleozoic ocean closure and collision between the Karakum-Tarim and Kazakh-Kyrgyz terranes. Integrated U-Pb geochronology, thermobarometry, pseudosection modeling, and Hf geochemistry constrain the timing and petro-tectonic nature of these processes. The Gissar batholith and the Garm massif represent an eastward, along-strike increase in paleodepth from upper-batholith (similar to 21-7km) to arc-root (similar to 36-19km) levels of the Andean-syn-collisional Gissar arc, which developed from similar to 323-288Ma in two stages: (i) Andean, I-type granitoid magmatism from similar to 323-306Ma due to northward subduction of the Gissar back-arc ocean basin under the Gissar microcontinent, which was immediately followed by (ii) syn-collisional, I-S-type granitoid magmatism in the Gissar batholith and the Garm massif from similar to 304-288Ma due to northward subduction/underthrusting of Karakum marginal-continental crust under the Gissar microcontinent. A rapid isotopic pull-up from similar to 288-286Ma signals the onset of juvenile, alkaline-syenitic, post-collisional magmatism by similar to 280Ma, which was driven by delamination of the Gissar arclogite root and consequent convective asthenospheric upwelling. Whereas M-HT/LP prograde metamorphism in the Garm massif (650-750 degrees C/6-7kbar) from similar to 310-288Ma was associated with subduction-magma inundation and crustal thickening, HT/LP heating and decompression to peak-metamorphic temperatures (similar to 800-820 degrees C/6-4kbar) at similar to 2886Ma was driven by the transmission of a post-collisional, mantle-derived heat wave through the Garm-massif crust. Tian Shan Gissar arc postcollisional magmatism Carboniferous Permian Central Asian Orogenic Belt
4	Polycyclic evolution of the Eastern Central-Asia orogenic belt : microtectonic analysis, geochronology and tectonics in central Inner Mongolia / Evolution polycyclique de la partie orientale de la ceinture orogénique d'Asie Centrale : analyse microtectonique, géochronologie et tectonique dans le centre de la Mongolie Intérieure, Chine Shi, Guanzhong 29 September 2013 (has links) Il est débattue sur le temps closural finale de l'océan paléo-asiatique et la position. Certains géologues ont préconisé la suture "Solonker" marque la zone closural finale du Permien , tandis que d'autres insistent sur le fait Paléozoïque milieu. Nos trois domaines d'étude, le Hongqi , le Ondor Somme et le Mandula ont essentiel et important de résoudre ces controverses. Les unités litho-tectonique reconnus dans le domaine Hongqi-Ondor Sum sont le mélange Belt de Hongqi-Ondor Sum, la Belt de l'arc Bainaimiao, craton du Nord de Chine et les roches sédimentaires post-orogéniques. Le mélange Belt de Hongqi-Ondor Sum connu déformation ductile en deux phases et une phase de la déformation ductile-fragile. D1 est responsable de la S1 foliation, linéation minérale L1, et intrafolial pli F1. Les critères cinématiques indiquent un sens cisaillement de top-to-the-NW. D2 est caractérisée par divers taille de plis asymétriques avec axe presque NE correspondant à la poussée NW cisaillement. D3 formé le cadre régional dans le Hongqi et les zones Ondor Sum. La zone Mandula contient les sédiments olistostrome, les sédiments turbiditiques et roches volcanosédimentaires. Grains de zircons détritiques dans des échantillons sédimentaires indiquent la zone d'étude Mandula reçu des matériaux d'arc Bainaimiao et matières contemporaines de l'éruption volcanique du Permien. Les sédiments et les roches volcaniques dans la région Mandula soumettent un NW-SE ou près de N-S du raccourcissement. Les données géologiques indiquent qu'une subduction et collsion dans Paléozoïque inférieur, et rifting et fermeture rift dans Palezoic supérieur. Les fragments ophiolitiques "Solonker" sont en effet olistostrome. Composants ophiolitiques typiques ne sont pas observés dans la région Mandula. / It is hotly debated about the final closural time and position of the Paleo-Asian Ocean. Some geologists advocated the “Solonker” suture marks the final closural zone in Permian, whereas others insist in middle Paleozoic. Our three study areas, the Hongqi, the Ondor Sum and the Mandula is essential and important to solve those controversies. The litho-tectonic units recognized in the Hongqi-Ondor Sum area include the Hongqi-Ondor Sum mélange belt, the Bainaimiao arc belt, North China Craton and post-orogenic unconformably sedimentary rocks. The Hongqi-Ondor Sum mélange belt experienced two phase ductile deformation and one phase ductile-brittle deformation. D1 is responsible for the regional greenschist foliation S1, elongated mineral lineation L1, and intrafolial fold F1. The kinematic criteria indicates a top-to-the-NW shearing sense. D2 is characterized by various sized of unsymmetrical folds with nearly NE axis corresponding to the NW thrust shearing. D3 formed the regional framework in the Hongqi and the Ondor Sum areas. The Mandula area contains olistostrome sediments, turbiditic sediments and volcano-sedimentary rocks. Detrital zircon grains in sedimentary samples argue the Mandula study area received the southern Bainaimiao arc materials and coeval Permian volcanic erupting materials nearby. The sediments and volcanic rocks in Mandula area subject a nearly NW-SE or N-S compressional shortening. The geological data support that an Early Paleozoic subduction and collsioan, Late Palezoic rifting and rift closure model. The so called “Solonker” ophiolitic fragments indeed are olistostrome. Typical ophiolite components are not observed in the Mandula area. Centrale de la Mongolie intérieure Asie ceinture orogénique centrale Déformation polyphasée Sédimentaire faciès analyse Évolution tectonique Central Inner Mongolia Central Asian orogenic belt Polyphase deformation Sedimentary facies analysis Tectonic evolution
5	L'évolution tectonique du Paléozoïque supérieur de la ceinture orogénique de l'Asie centrale du Centre-Oriental de la Mongolie intérieure / The Late Paleozoic tectonic evolution of Central Asian orogenic belt in Central-Eastern inner Mongolia Zhao, Pan 17 October 2014 (has links) Le Centre-Est de la Mongolie intérieure, faisant la partie sud-est de la Ceinture Orogénique de l'Asie Centrale (CAOB), est une zone de clé pour étudier l'histoire de l’accrétion-collision entre la Chine du Nord (NCC) et les blocs continentaux du Nord. Les contraintes du cadre tectonique et de la connaissance de l’évolution tectonique sont importantes pour comprendre l’accrétion de la CAOB car il n’y a pas de consensus sur le mode et la période de l'accrétion entre NCC et les blocs du Nord. Par conséquent, des études pluridisciplinaires ont été effectuées sur les roches sédimentaires et magmatiques du Paléozoïque supérieur dans le centre-oriental de la Mongolie Intérieure. Sur la base de nos études sédimentologiques, géochronologiques, géochimiques et paléomagnétiques, et compte tenu des résultats précédents en pétrographie, géochimie et paléontologie, l'évolution sédimentaire et tectonique du Paléozoïque supérieur du Centre-Oriental de la Mongolie Intérieure a été bien établie. Les études détaillées en sédimentologie et géochimie montrent une transition entre les dépôts molassiques du Dévonien à la dénudation du Carbonifère inférieur et les sédiments marins du Carbonifère supérieure vers les dépôts de bassin d'extension au Permien. D’après nos analyses détaillées des faciès sédimentaires, des caractéristiques géochimiques des roches magmatiques et nos données paléomagnétiques, nous proposons un modèle géodynamique de subduction-collision-extension post-orogénique pour le Paléozoïque au Centre-Oriental de la Mongolie Intérieure. / Central-eastern Inner Mongolia, located in the southeastern part of the Central Asian Orogenic Belt (CAOB), is a key area to study the collisional-accretionary history between the North China Craton (NCC) and the northern continental blocks. The establishment of precise constraints of this tectonic framework and evolutional history are important to understand the accretion of CAOB. However, no any consensus has been achieved about the way and the timing of the accretion between NCC and the northern blocks. Therefore, multidisciplinary studies have been carried out on the Late Paleozoic strata and magmatic rocks in central-eastern Inner Mongolia. Based on our sedimentological analyses, detrital zircon geochronological constraints, geochemical studies and paleomagnetic investigations, integrating the previous results in petrology, geochemistry and paleontology, the Late Paleozoic sedimentary-tectonic evolution of the central-eastern Inner Mongolia has been established. Detailed sedimentological and geochemical studies show a transition from the Devonian molassic deposits to the Early Carboniferous denudation and from the Late Carboniferous inland-sea sediments to the Permian extensional basin deposits. According to the comprehensive analyses on sedimentary facies, geochemical characteristics and paleomagnetic data, we propose a Paleozoic subduction-collision- post-orogenic extension tectonic model for central-eastern Inner Mongolia. Paléozoïque supérieure Sédimentologie Paléomagnétisme Central Asian orogenic belt Central-East inner Mongolia Late Paleozoic Sedimentology Paleomagnetism 555
6	Geological and geophysical characterization of accretionary and collisional systems : the Central Asian Orogenic Belt and the Bohemian Massif Guy, Alexandra 14 December 2012 (has links) (PDF) Large-scale accretionary and collisional crustal orogenic architecture is studied combining structural geology, lithostratigraphy, geochronology and magmatic petrology with gravity, magnetic and seismic data. This multidisciplinary approach allows characterizing the structure and composition of the orogenic crust in two accretionary-collisional systems. The Central Asian Orogenic Belt (CAOB) constituting one third of the Asia continent and the Bohemian Massif are two Palaeozoic orogens formed by accretion followed by collision. It is proposed that the CAOB formed by successive Paleozoic accretion of oceanic and continental fragments followed by a late Palaeozoic to early Mesozoic N-S convergence of North Chinese and Siberian Cratons. The comparison between the potential fields and the geological data reveals an incorrect compartmentalization into different lithostratigraphic terranes. In contrast to geology the geophysical approach allows the analysis of the crustal structures on a complete thickness of crustal column. This thesis presents a compilation of geological data combined with unique gravity and magnetic results which are integrated into a preliminary model for the architecture of the continental crust. Conversely, an important collection of complementary data is available for the Bohemian Massif, allow more precise 3D geophysical forward modeling. In this area, geophysical data reveal the occurrence of an allochtonous lower crustal layer with a felsic composition. This indicates that the Variscan orogenic crust actually resulted from the accretion of contrasted crustal fragments. Accretionary and collisional orogens Central Asian Orogenic Belt Bohemian Massif Structural geology Gravity Magnetism Modeling
7	Polycyclic evolution of the Eastern Central-Asia orogenic belt : microtectonic analysis, geochronology and tectonics in central Inner Mongolia Shi, Guanzhong 29 September 2013 (has links) (PDF) It is hotly debated about the final closural time and position of the Paleo-Asian Ocean. Some geologists advocated the "Solonker" suture marks the final closural zone in Permian, whereas others insist in middle Paleozoic. Our three study areas, the Hongqi, the Ondor Sum and the Mandula is essential and important to solve those controversies. The litho-tectonic units recognized in the Hongqi-Ondor Sum area include the Hongqi-Ondor Sum mélange belt, the Bainaimiao arc belt, North China Craton and post-orogenic unconformably sedimentary rocks. The Hongqi-Ondor Sum mélange belt experienced two phase ductile deformation and one phase ductile-brittle deformation. D1 is responsible for the regional greenschist foliation S1, elongated mineral lineation L1, and intrafolial fold F1. The kinematic criteria indicates a top-to-the-NW shearing sense. D2 is characterized by various sized of unsymmetrical folds with nearly NE axis corresponding to the NW thrust shearing. D3 formed the regional framework in the Hongqi and the Ondor Sum areas. The Mandula area contains olistostrome sediments, turbiditic sediments and volcano-sedimentary rocks. Detrital zircon grains in sedimentary samples argue the Mandula study area received the southern Bainaimiao arc materials and coeval Permian volcanic erupting materials nearby. The sediments and volcanic rocks in Mandula area subject a nearly NW-SE or N-S compressional shortening. The geological data support that an Early Paleozoic subduction and collsioan, Late Palezoic rifting and rift closure model. The so called "Solonker" ophiolitic fragments indeed are olistostrome. Typical ophiolite components are not observed in the Mandula area. Central Inner Mongolia Central Asian orogenic belt Polyphase deformation Sedimentary facies analysis Tectonic evolution
8	Geological and geophysical characterization of accretionary and collisional systems : the Central Asian Orogenic Belt and the Bohemian Massif / Caractérisation géologique et géophysique de système d’accrétion et de collision : application à la ceinture orogénique d’Asie centrale et au Massif de Bohême Guy, Alexandra 14 December 2012 (has links) L’architecture crustale d’orogènes d’accrétion et de collision à grande échelle est étudiée en combinant géologie structurale, litho-stratigraphie, géochronologie et pétrologie magmatique avec les données gravimétriques, magnétiques et sismiques. Cette approche pluridisciplinaire permet de caractériser la structure et la composition de la croûte orogénique dans deux systèmes d’accrétion-collision : la Ceinture Orogénique d’Asie Centrale (CAOC) et le Massif de Bohême. La CAOC représente près d’un tiers du continent asiatique actuel. Ce système orogénique s’est construit par une accrétion continue de matériel depuis le Paléozoïque jusqu’au début du Mésozoïque, suivie par une collision durant le Mésozoïque. La comparaison des champs de potentiels avec les données géologiques met en évidence une compartimentation erronée de l’orogène en unités litho-stratigraphiques. Par rapport à la géologie, la géophysique permet une analyse directe des structures de la croûte orogénique sur toute son épaisseur. Le travail de thèse présente une compilation de données géologiques et de traitements gravimétriques et magnétiques inédits, dont la modélisation préliminaire pour contraindre l’architecture de la croûte continentale est proposée. Le Massif de Bohême possède quant à lui un catalogue de données complémentaires plus conséquent, ce qui permet une modélisation géophysique 3D plus précise. Dans cette zone, les données géophysiques mettent en évidence l’existence d’une croûte inférieure allochtone de composition felsique. Ceci indique que la croûte orogénique hercynienne est également le résultat d’une accrétion de portions crustales contrastées. / Large-scale accretionary and collisional crustal orogenic architecture is studied combining structural geology, lithostratigraphy, geochronology and magmatic petrology with gravity, magnetic and seismic data. This multidisciplinary approach allows characterizing the structure and composition of the orogenic crust in two accretionary-collisional systems. The Central Asian Orogenic Belt (CAOB) constituting one third of the Asia continent and the Bohemian Massif are two Palaeozoic orogens formed by accretion followed by collision. It is proposed that the CAOB formed by successive Paleozoic accretion of oceanic and continental fragments followed by a late Palaeozoic to early Mesozoic N-S convergence of North Chinese and Siberian Cratons. The comparison between the potential fields and the geological data reveals an incorrect compartmentalization into different lithostratigraphic terranes. In contrast to geology the geophysical approach allows the analysis of the crustal structures on a complete thickness of crustal column. This thesis presents a compilation of geological data combined with unique gravity and magnetic results which are integrated into a preliminary model for the architecture of the continental crust. Conversely, an important collection of complementary data is available for the Bohemian Massif, allow more precise 3D geophysical forward modeling. In this area, geophysical data reveal the occurrence of an allochtonous lower crustal layer with a felsic composition. This indicates that the Variscan orogenic crust actually resulted from the accretion of contrasted crustal fragments. Orogène d’accrétion Orogène de collision Ceinture orogénique d’Asie Centrale Massif de Bohême Géologie structurale Gravimétrie Magnétisme Modélisation Sismologie Accretionary and collisional orogens Central Asian Orogenic Belt Bohemian Massif Structural geology Gravity Magnetism Modeling 551.8 551.22

Search results