Structural and sedimentological evolution of Tertiary sedimentary basins in northern Thailand

Uttamo, Wutti

January 2001

No description available.

551

Strike slip tectonics

The Late Proterozoic to Palaeozoic Tectonic Evolution of the Long Range Mountains in Southwestern Newfoundland

Brem, Arjan Gerben

January 2007

Ever since the first plate-tectonic model for the Appalachians was proposed, the Laurentian margin has been interpreted as having experienced a collision-related dynamo-thermal event during the Middle Ordovician Taconic orogeny. In the western Newfoundland Appalachians, evidence for this collision is well-preserved in the Dashwoods subzone. Nevertheless, rocks of the neighbouring Corner Brook Lake block (CBLB), which is located in the heart of the Laurentian realm, did not show evidence for such an event. Instead, it was affected by Early Silurian Salinic deformation and associated peak metamorphism. Even though this difference in Early Palaeozoic tectonic history between the Dashwoods and the CBLB is widely known, it has not been satisfactorily explained. To better understand the Early Palaeozoic history of the region, in particular to test and better explain the lack of a Taconic dynamo-thermal event in the CBLB, field mapping, microscopic work, and U-Pb and 40Ar/39Ar geochronological studies were undertaken in the western and northern part of the Dashwoods subzone, and in the southern part of the CBLB. In addition, the kinematic history of the Baie Verte-Brompton Line - Cabot Fault Zone (BCZ), the tectonic zone that separates the two unique tectonic fragments, was studied. The western and northern parts of the Dashwoods subzone contain variably foliated igneous units of Middle Ordovician age (ca. 460 Ma) that are associated with the regionally voluminous Notre Dame continental arc. A ca. 455 Ma conjugate set of late syn-tectonic pegmatite dykes in the BCZ demonstrates a dextral sense of shear along the BCZ (DBCZ-1) during the Late Ordovician to earliest Silurian, and constrains the minimum age of the main phase of ductile deformation in the Dashwoods subzone. The fault-bounded CBLB has been affected by a single west-vergent deformational event, constrained between ca. 434 and ca. 427 Ma. More importantly, no evidence – neither petrographic nor geochronological – is present that would indicate that the CBLB was affected by a significant Taconic dynamo-thermal event. Hence, the CBLB and Dashwoods could not have been juxtaposed until after the late Early Silurian. Furthermore, the basement to the CBLB is devoid of any Grenville (sensu lato; ca. 1.0-1.3 Ga) U-Pb ages, which is in sharp contrast with crystalline basement elsewhere in the region, such as the Long Range Inlier. Therefore, it is highly unlikely that the CBLB represents the para-autochthonous leading edge of the Laurentian craton in the Newfoundland Appalachians, as commonly accepted. The CBLB is interpreted as a suspect terrane that has moved over 500 km parallel to the strike of the orogen. Docking to the external Humber Zone is likely to have occurred during the Early Silurian. Final juxtaposition with the Dashwoods took place after the late Early Silurian (post-Salinic) as a result of protracted dextral movement along the BCZ (DBCZ-2 and DBCZ-5). Current tectonic models for the Newfoundland Appalachians mainly focus on well-documented Early Palaeozoic orthogonal convergence of various terranes with the Laurentian margin, but large-scale orogen-parallel movements have rarely been considered. The possibility of large-scale strike-slip tectonics documented here, in addition to the convergent motions, may have significant implications for the tectonic interpretation of the Early Palaeozoic evolution of the Newfoundland Appalachians.

Newfoundland Appalachians

Laurentian margin

Cabot Fault Zone

Corner Brook Lake block

Dashwoods subzone

Kinematic analyses

Geochronological analyses

Neoproterozoic

Palaeozoic

Strike-slip tectonics

Earth Sciences

The Late Proterozoic to Palaeozoic Tectonic Evolution of the Long Range Mountains in Southwestern Newfoundland

Brem, Arjan Gerben

January 2007

Ever since the first plate-tectonic model for the Appalachians was proposed, the Laurentian margin has been interpreted as having experienced a collision-related dynamo-thermal event during the Middle Ordovician Taconic orogeny. In the western Newfoundland Appalachians, evidence for this collision is well-preserved in the Dashwoods subzone. Nevertheless, rocks of the neighbouring Corner Brook Lake block (CBLB), which is located in the heart of the Laurentian realm, did not show evidence for such an event. Instead, it was affected by Early Silurian Salinic deformation and associated peak metamorphism. Even though this difference in Early Palaeozoic tectonic history between the Dashwoods and the CBLB is widely known, it has not been satisfactorily explained. To better understand the Early Palaeozoic history of the region, in particular to test and better explain the lack of a Taconic dynamo-thermal event in the CBLB, field mapping, microscopic work, and U-Pb and 40Ar/39Ar geochronological studies were undertaken in the western and northern part of the Dashwoods subzone, and in the southern part of the CBLB. In addition, the kinematic history of the Baie Verte-Brompton Line - Cabot Fault Zone (BCZ), the tectonic zone that separates the two unique tectonic fragments, was studied. The western and northern parts of the Dashwoods subzone contain variably foliated igneous units of Middle Ordovician age (ca. 460 Ma) that are associated with the regionally voluminous Notre Dame continental arc. A ca. 455 Ma conjugate set of late syn-tectonic pegmatite dykes in the BCZ demonstrates a dextral sense of shear along the BCZ (DBCZ-1) during the Late Ordovician to earliest Silurian, and constrains the minimum age of the main phase of ductile deformation in the Dashwoods subzone. The fault-bounded CBLB has been affected by a single west-vergent deformational event, constrained between ca. 434 and ca. 427 Ma. More importantly, no evidence – neither petrographic nor geochronological – is present that would indicate that the CBLB was affected by a significant Taconic dynamo-thermal event. Hence, the CBLB and Dashwoods could not have been juxtaposed until after the late Early Silurian. Furthermore, the basement to the CBLB is devoid of any Grenville (sensu lato; ca. 1.0-1.3 Ga) U-Pb ages, which is in sharp contrast with crystalline basement elsewhere in the region, such as the Long Range Inlier. Therefore, it is highly unlikely that the CBLB represents the para-autochthonous leading edge of the Laurentian craton in the Newfoundland Appalachians, as commonly accepted. The CBLB is interpreted as a suspect terrane that has moved over 500 km parallel to the strike of the orogen. Docking to the external Humber Zone is likely to have occurred during the Early Silurian. Final juxtaposition with the Dashwoods took place after the late Early Silurian (post-Salinic) as a result of protracted dextral movement along the BCZ (DBCZ-2 and DBCZ-5). Current tectonic models for the Newfoundland Appalachians mainly focus on well-documented Early Palaeozoic orthogonal convergence of various terranes with the Laurentian margin, but large-scale orogen-parallel movements have rarely been considered. The possibility of large-scale strike-slip tectonics documented here, in addition to the convergent motions, may have significant implications for the tectonic interpretation of the Early Palaeozoic evolution of the Newfoundland Appalachians.

Newfoundland Appalachians

Laurentian margin

Cabot Fault Zone

Corner Brook Lake block

Dashwoods subzone

Kinematic analyses

Geochronological analyses

Neoproterozoic

Palaeozoic

Strike-slip tectonics

Earth Sciences

Le gisement d’or du Tocantinzinho (province aurifère du Tapajós) relations entre déformation, hydrothermalisme et minéralisation / Tocantinzinho gold deposit (Tapajós Gold Province) relationship between deformation, hydrothermal alteration and mineralisation

Borgo, Ariadne

23 February 2017

Le gisement de Tocantinzinho est situé sur la province aurifère de Tapajós et est le plus grand gisement d'or de la province, avec 53,9 tonnes d'or estimées. Sa formation commence par un magmatisme granodioritique autour de 2005 Ma, suivi d'un magmatisme granitique. Le granite Tocantinzinho est composé de deux faciès principaux (syenogranite - 1996± 2Ma; monzogranite 1989±1 Ma), des corps d’aplite et de pegmatite, qui suggère un magmatisme enrichie en fluide et mis en place à faible profondeur. Intrusifs dans ces roches, des dykes d'andésite (1998±8Ma) ont des fragments de granite et des mélanges entre les 2 magmas suggèrent un magmatisme à la fois continu et polyphasé. Il est proposé que les premiers dykes d’andésite se sont mis en place alors que le granite n’était pas entièrement cristallisé (mingling) et les derniers lors des stades de déformation à l’état solide du granite. Utilisant la courbe de refroidissement, un âge minimum de 1975 Ma a été estimé pour l’andésite. Les taux de refroidissement des roches plutoniques varient de 3,6 à 14,7°C/Ma, avec une moyenne de 7,5°C/Ma, suggérant que les processus d'exhumation verticale sont faibles. La géométrie allongée du granite ainsi que la tectonique syn-magmatique de l'andésite corroborent la prédominance des mouvements horizontaux. L’affinité calc-alcaline fortement potassique et des anomalies en niobium définissent deux configurations possibles pour le cadre géotectonique: arc continental de type Andin ou Post-collisionnel. Compte tenue la relation génétique entre magmatisme, cisaillement décrochant et les faibles taux de refroidissement, l’environnement post-collisionnel est plus probable. Cela ensemble avec les âges nous permettent de comparer ces roches avec celles de la Suite Intrusive Creporizão (1997-1957Ma). La dacite (1992 ± 2 Ma) recoupe les autres roches, cependant, la signature géochimique comparable aux roches anorogéniques suggère qu’elle appartient à une série magmatique distinct. La zone minéralisée est limitée par deux failles majeures senestres de direction N100°-130E°. Le granite Tocantinzinho et les roches hypo-volcaniques déformées sont dans ce couloir, altérées par de fluides hydrothermaux et minéralisées pendant deux phases tectoniques distinctes. La première est caractérisée par des brèches et des microfractures remplies par muscovite (1864±5Ma) et pyrite, associées à de faibles teneur d’or (<1,5ppm) restreintes au granite. La deuxième phase a été contrôlée par le cisaillement décrochant senestre normal générant des fentes de tension et des brèches remplies par quartz, chlorite, calcite, albite, rutile, pyrite, galène, sphalérite, chalcopyrite et or. La teneur en or peut atteindre jusqu'à 70 ppm dans les veines riches en sulfures. Ces structures de remplissage syntectonique sont parallèles entre elles et orientées N30-60°E. Deux hypothèses ont été proposées pour expliquer la genèse du gisement: la première considère une relation génétique entre magmatisme et minéralisation au moins pour le premier stage de minéralisation selon un modèle porphyrique et la seconde alternative considère une réactivation des failles préexistantes par une tectonique transtensive liée au magmatisme Maloquinha (ca. 1880Ma) pour les deux stades minéralisateurs. Les deux phases dans les deux hypothèses, ont été classées comme des minéralisations de type magmato-hydrothermale qui pourraient être classées soit comme des systèmes d'or liés à l'intrusion. De nouveaux travaux sur le terrain et en laboratoire seraient nécessaires pour identifier et caractériser la nature et la source des fluides hydrothermaux, pour dater la minéralisation et mieux comprendre le rôle des roches hypo-volcaniques. Toutefois, les premiers résultats, et notamment le rôle fondamental du contrôle tectonique pour la minéralisation sont très significatifs et peuvent aider de manière conséquente à l'établissement des programmes d'exploration et d'exploitation futurs. / The Tocantinzinho deposit is located on the Tapajós Gold Province and is the largest gold deposit within Province, with 53,9 tons of gold. Its formation begins with a granodioritic magmatism around 2005Ma, followed by a granitic magmatism 10 Ma latter. The Tocantinzinho granite is composed by two main facies, syenogranite (1996±2Ma) and monzogranite (1989±1Ma), and by aplite and pegmatite bodies, suggesting a fluid-rich magmatism at shallow depth. Andesite dikes (1998±8Ma) are intrusive in both rocks. Sharp fragments of those rocks along contacts and minor mingling with granitic magma suggest a multiphase magmatism at distinct timing. The first dikes have intruded within granite when it was crystalizing, thus a minimum age of 1975Ma was estimated. Cooling rates of plutonic rocks vary from 3.6 to 14.7°C/Ma, with an average of 7.5°C/Ma, suggesting vertical exhumation processes were minor. The elongated geometry of granite along with sin-magmatic strike-slip tectonics of andesite corroborate the predominance of horizontal movements. Geochemical analysis show high-K calk-alkaline affinity and niobium anomaly indicator of two possible geotectonic settings for these rocks: Andean-type continental arc or post-collisional one. Considering the genetic relationship between magmatism, strike-slip faults, and low cooling rates, a post-collisional setting is more likely. The geochemical signature, ages and style of tectonism allow us to compare those rocks with the ones from Creporizão Intrusive Suite (1997-1957Ma). Dacite dikes (1992±2Ma) cut across all other rocks, but the temporal relationship among them remains misunderstood, due to the geochemical signature similar to the anorogenic rocks, suggesting it belongs to a distinct and latter magmatic series. Indeed, the dated zircons were probably inherited from host rocks. The mineralized area is restricted to a domain constrained by two major sinistral strike-slip N100°-130E°E faults that comprises the Tocantinzinho granite and sub-volcanic rocks, which were hydrothermally altered, brittle deformed and mineralized during two phases. The first one is characterized by breccias and microfractures infilled with muscovite (1864±5Ma) and pyrite, which contains low gold grades and are restricted to the Tocantinzinho granite. The second phase was controlled by strike-slip and normal tectonics generating tension gashes veins and pull apart breccias infilled with quartz, chlorite, calcite, albite, rutile, pyrite, galena, sphalerite, chalcopyrite, and gold. The gold grade can reach up to 70 ppm in some sulfide-rich veins. These structures are parallel and mainly trends N30-60°E, showing textures and orientated minerals typical of syn-tectonic infilling. Based on petrographical features and argon ages two hypothesis were proposed for the ore genesis: the first one consider a genetic relationship between magmatism and ore fluids for first mineralization stage and the second hypothesis consider a reactivation of pre-existing faults by an extensional tectonism related to the Maloquinha Intrusive Suite magmatism (ca.1880Ma) for this phase. The second mineralization phase is considered as formed as consequence of tectonic reactivation at ca. 1880Ma, in both hypothesis. Both phases in both hypothesis were classified as magmatic-hydrothermal ore mineralization and might be classified as intrusion-related gold systems. However, new field works are important in order to identify and characterize the nature and source of hydrothermal fluids, as well as ore dating and new geochemical and geochronological data of sub-volcanic rocks are imperative to better understand the genesis and evolution of the Tocantinzinho gold deposit. Such results, strongly linked to the fact that the tectonic control seem significant, may help for future exploration and exploitation programs.

Domaine Tapajós

Tectonique décrochante

Minéralisation magmato-Hydrothermale

Géochronologie U-Pb sur zircon

Géochronologie Ar/Ar

Tapajós Domain

Strike-Slip tectonics

Magmatic-Hydrothermal mineralization

Zircon U-Pb geochronology

Ar/Ar geochronology

Source to sine relations between the Qaidam basin (Tibet) and the surrounding mountains / Relations érosion : sédimentation entre le bassin du Qaidam (Tibet) et les chaines associées

Cheng, Feng

25 May 2016

Le basin du Qaidam, situé sur la bordure nord du Plateau Tibétain est unique au monde en ce qu’il représente le bassin intracontinental le plus profond bien que situé sur le plus haut plateau et la plus épaisse croute continentale actuels. Comprendre le développement et l’évolution de ce bassin en lien avec la collision Inde-Asie a des implications multiples pour la géologie du Tibet en particulier et la tectonique continentale en général. De nombreuses études incluant de la thermochronologie, de la paléobotanique, du paléomagnétisme, de la paléoaltimétrie, de la sédimentologie et de la géologie structurale se sont intéressées à l’histoire tectonique et topographique de cette région. Toutefois la topographie initiale de la région actuellement représentée par le Plateau Tibétain ainsi que les premiers stades de développement du plateau restent méconnus et très débattus. Les travaux présentés ici sont basés sur des données de terrain, de sismique 2D et 3D, de géochimie, de géochronologie détritique, de sédimentologie et d’analyse d’images satellitaires. Ils décrivent: 1) l’évolution cénozoïque conjointe du bassin du Qaidam et de la chaine des Eastern Kunlun ; 2) les relations entre la sédimentation dans le bassin du Qaidam et la tectonique le long de la faille de l’Altyn Tagh ; 3) une estimation quantitative de l’extrusion latérale du nord Tibet les long du système Altyn Tagh – Qilian Shan ; 4) la nature et la typologie du bassin du Qaidam. Je démontre que la chaîne du Kunlun formait un relief en érosion au Paléocène et que la zone de dépôt du bassin du Qaidam s’est élargie vers le sud jusqu’à l’Oligocène. Dès le Miocène inférieur le SO du bassin du Qaidam était limité par un système tectonique décrochant. L’accroissement du relief dans les chaines du Kunlun et de l’Altyn Tagh entraine alors un isolement puis un rétrécissement du bassin. Je suggère que la faille de l’Altyn Tagh qui forme la bordure nord du Plateau, a accommodé environs 360 km de déplacement depuis sont initiation au Miocène inférieur. Cette déformation est prise en compte par du décrochement et de l’épaississement dans les Qilian Shan, de l’épaississement crustal dans les Qinling et de l’extension dans le système de grabens de Chine du Nord. Enfin, je conclu que le bassin du Qaidam est contrôlé conjointement par les failles décrochantes de l’Altyn Tagh et du Kunlun Est. La superposition dans le temps et l’espace des effets de ces deux décrochements majeurs durant le Cénozoïque a contrôlé l’évolution du bassin et la répartition des réserves d’huile et de gaz. / The Qaidam basin, located within the northern Tibetan plateau, is the deepest intracontinental basin, yet located in the highest plateau with the thickest continental crust. Understanding how this peculiar basin developed has broad implications for the Tibetan geology in particular and for continental tectonics in general. Many approaches have been used to decipher the tectonic and topographic history of that region, however, the initial topography of the area now represented by the northern Tibetan plateau, as well as the early stages of development of the present day topography remain poorly constrained and highly debated. In order to better understand the Cenozoic evolution of the Qaidam basin and its surrounding regions (including Eastern Kunlun Range to the south, Altyn Tagh Range to the northwest, and Qilian Shan to the northeast), four critical issues are addressed in this thesis: 1) the Cenozoic joint tectonic evolution of the Qaidam basin and the Eastern Kunlun Range; 2) the interplay between the sedimentation within the Qaidam basin and the active tectonics within the Altyn Tagh Range; 3) a quantitative estimate of the lateral extrusion along the Altyn Tagh Fault-Qilian Shan tectonic system; 4) the nature and classification of the Qaidam basin. I suggest that the SW Qaidam basin has been bordered by a series of strike-slip faults to the south since the Early Miocene, rather than, as previously suggested by a continuous northward or southward thrusting system. Based on U-Pb dating (LA-ICP-MS) of detrital zircons collected from 4 sections (Paleocene to Holocene) within the southwestern Qaidam basin combined with provenance analysis and new seismic profile interpretation, I demonstrated that the Eastern Kunlun Range was already exhumed prior to the Paleocene. I show that the Qaidam basin was widening southward during thet early Cenozoic period (Paleocene to Oligocene). From Oligocene the relief of the Eastern Kunlun and Altyn Tagh ranges increased, leading to isolation and narrowing of the Qaidam basin from Miocene to the present. Along the northern edge of the basin, I identified the Tula-Huatugou and Anxi-Eboliang regions as residual parts of the original Qaidam basin. I suggest that the Altyn Tagh Fault has experienced a total of ~360 km of displacement since its Early Eocene initiation. Based on this ~360 km northeastward migration of the relatively rigid Qaidam block along the Altyn Tagh Fault and 3D isovolumetric balance of the crustal deformation within the Altyn Tagh Fault – Qilian Shan system, I demonstrate that 250 ± 28 km (43.8~49.4 %) of N20E directed crustal shortening and an additional ~250 to ~370 km of eastward motion of the Qilian Shan crust must be accounted for by strike-slip faulting in the Qilian Shan and crustal thickening in the Qinling area, as well as extension in the adjoining North China block graben systems.

Bassin du Qaidam

Plateau Tibétain

Géochronologie détritique sur zircon

Interprétation de lignes sismiques

Relations érosion - sédimentation

Décrochement

Raccourcissement

Extrusion

Qaidam basin

Tibetan plateau

Detrital zircon geochronolgy

Seismic profile interprétation

Source to sine relation

Strike-Slip tectonics

Compression

Extrusion