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61	Tectonostratigraphic analysis of the Proterozoic Kangdian iron oxide - copper province, South-West China Greentree, Matthew Richard January 2007 (has links) The Cenozoic Ailaoshan Red River shear zone marks the present day western margin of the South China Block. Along this margin are well preserved late Paleoproterozoic to early Neoproterozoic sedimentary and volcanic successions. This work examines the ages and tectonic environments for the formation of the successions, as well as significance of the regional tectono-magmatic events on the formation of widespread iron oxide-copper deposits. The oldest succession is the Paleoproterozoic Dahongshan Group. A new SHRIMP UPb age of 1675 ± 8 Ma for a tuffaceous schist unit confirms its Paleoproterozoic age. Detrital zircon ages of the Dahongshan Group range between Archean to Paleoproterozoic (ca. 2780 1860 Ma). They include a population of ca. 2400 2100 Ma grains, which have no known source region on the exposed Yangtze Block. Previous geochemical studies of metavolcanic rocks from the Dahongshan Group have suggested that these rocks were erupted in an oceanic setting. However, this study shows that the metavolcanics are extremely altered and cannot be used for reliable tectonic discrimination. Based on the characteristics of sedimentary rocks in the Dahongshan Group, it is suggested that these rocks were deposited in a continental setting. Overlying the Dahongshan Group is a thick sedimentary sequence which has been variably termed the Kunyang, Dongchuan, Huili or Xide Groups. In the past, these rocks have been considered as a Mesoproterozoic rift succession. However, no precise age constraints were available for the succession. In this study, this sequence is found to contain at least two separate tectonostratigraphic units. The oldest (ca.1140 Ma) is comprised of alkaline basalt with a geochemical and isotopic character similar to that of modern intracontinental rift basalts. The presence of Cathaysia-derived sediments in this unit indicates sedimentary transportation from the southerly Cathaysia Block to the northerly Yangtze Block (in present coordinates) in South China at that time, which suggests an impactogen scenario. The thick sedimentary sequence of what has traditionally been defined as the Kunyang Group has been found to have significantly younger depositional age of ca.1000 960 Ma. The composition of sedimentary rocks and the provenance of detrital zircons from the Kunyang Group are consistent with a foreland basin setting. The depositional age of this sequence coincides with the timing of Sibao Orogeny as determined elsewhere in the South China Block. Summary Page ii Numerous iron oxide - copper (gold) deposits occur within the rocks of the Dahongshan and Kunyang Groups. Previous studies have classified these deposits into two deposit styles: the Dahongshan-type Paleoproterozoic VMS mineralisation hosted within the Dahongshan Group, and the Dongchuan-type diagenetic carbonate and shale-hosted deposits hosted within the Kunyang Group. However, both deposit types share similarities with the iron oxide copper (gold) deposit class, such as stratabound disseminated and massive copper ores, abundance of iron oxide occurring mostly as low Ti - magnetite and haematite, and variable enrichments in Au, Ag, Co, F, Mo, P and REE. 40Ar/39Ar data from both deposit types indicate mineralisation ages of ca. 850 830 Ma and 780 740 Ma. Geological time Geology, Stratigraphic -- Proterozoic Geology, Structural -- China, Southwest Iron oxides -- China, Southwest Copper ores -- China, Southwest South China block Geochronology Tectonics Mesoproterozoic Paleoproterozoic Rodinia Copper mineral deposits
62	Developing a tectonic framework for the Southern Curnamona Cu - Au Province : geochemical and radiogenic isotope applications Rutherford, Lachlan Stuart January 2006 (has links) "Two independent geochronological techniques specifically targeting post-kinematic or late-stage growth of kyanite, staurolite and late-stage garnet in the southern Curnamona Province has found that these minerals grew during the Delamerian Orogeny (~530-500 Ma). Prograde metamorphism during the Delamerian Orogeny attained kyanite-staurolite-garnet grade (amphibolite-facies). Previous interpretations of an anticlockwise P-T path for the Olarian Orogeny need revising, as these interpretations have been shown in this study to be based on textural relationships spanning ~1100 million years. This highlights the importance of in situ geochronological techniques in defining robust P-T-t paths for a region." --p. 121 of source document. / Thesis (Ph.D.)--School of Earth and Environmental Sciences, 2006. Geology, Stratigraphic Proterozoic
63	Iron-oxide and carbonate formation and transformations from banded iron formations 2.7 to 2.4 Ga Morgan, Rachael 13 December 2012 (has links) (PDF) It is the study of banded iron formations (BIFs) that provides understanding into the conditions of the Earth's oceans and atmosphere during the Archean and Early Proterozoic. The aim of this thesis is to provide a detailed mineralogical and geochemical understand of BIFs from two separate localities separated by the Archean Proterozoic boundary. Close attention is paid to their carbonate and iron oxide mineralogy.The BIFs of the 2.7 Ga Manjeri Formation, Zimbabwe and 2.4 Ga Itabira Group, Brazil were both precipitated from oxygenated mixed marine-hydrothermal fluids. This is demonstrated by the presence of nano-hematite inclusions in the chert (Itabira and Manjeri) and dolomite (Itabira only) laminae, which is interpreted as the oldest mineral phase within the samples. Additionally, focused ion beam transmission electron microscopy (FIB-TEM) reveals the presence of nano ferrihydrite platelets within the dolomitic BIFs (carbonate itabirite). The dolomite is interpreted to be a primary phase precipitated at higher temperatures (~100°C) from CO2-rich hydrothermal fluids. Positive Eu anomalies in both formations indicate a hydrothermal component, likely to be the source of the reduced iron. Facies changes in both units are the result of transgression/regression and post depositional hydrothermal events mask primary conditions. Iron-rich carbonates in both facies have different origins; diagenetic (Itabira) and post depositional hydrothermal (Manjeri). However, the iron-rich carbonates of both formations have negative ∂13C values, indicating that at least part of the carbon in the carbonates is of organic origin. Curie Balance analyses into the carbonate itabirite reveals that maghemite is the transformation product of the ferrihydrite when dolomite decomposes at ~790°C. The maghemite has a Curie temperature between 320 and 350°C and is stable up to temperatures of 925°C.FIB-TEM investigations into the martitisation process revealed two possible mechanisms from two martite samples, from Brazil and India. Depending of the cause of the martitisation, here found to be deformation and hydrothermalism, the martitisation occurs respectively via either: 1. Ordering of point defects caused by vacancies in the spinel structure of maghemite, due to the removal of excess Fe3+ ions during the oxidation of magnetite, to form twins. It is in this twinning that the martitisation mechanism occurs.2. Grain boundary migration by hematite at the expense of magnetite is due to the presence of fluid along the crystal interfaces, where maghemite forms due to excess Fe3+ produced during martitisation of the magnetite, moving towards the surface of the magnetite crystals. Banded Iron Formations Archean Proterozoic Carbonate Martitisation FIB-TEM Curie Balance Cauê Formation Manjeri Formation Maghemite Ferrihydrite
64	Characteristics, distribution and timing of gold mineralisation in the Pine Creek Orogen, Northern Territory, Australia Sener, A. K. January 2005 (has links) Over the last two decades, gold occurrences in the Palaeoproterozoic Pine Creek Orogen (PCO) have been cited as type-examples of high-temperature contact-metamorphic or thermal-aureole deposits associated with granitoid magmatism. Furthermore, spatial relationships between these gold occurrences and the granitoids have led to inclusion of these deposits in the intrusion-related gold deposit group. Research on the characteristics, distribution and timing of these gold deposits tests these classifications and supports an alternative interpretation. The deposits display many similarities to well-described ‘turbidite-hosted’ orogenic gold deposits described from several Palaeozoic orogens. As in most ‘turbidite-hosted’ orogenic deposits, the gold mineralisation is dominantly epigenetic, sediment-hosted (typically greywacke and siltstone) and fold-controlled. Most gold is hosted by concordant or discordant veins, with limited alteration halos in host rocks, except where they occur in silicate-facies BIF or other Fe-rich rocks. The domal culminations of major doubly-plunging anticlines, and/or fold-limb thrust-faults, are important structural controls at the camp- and deposit-scales. Many deposits are sited in parts of the lithostratigraphy where there is significant competency and/or chemical contrast between units or sequences. In particular, the complex interdigitated stratigraphy of euxinic and transitional high-energy sedimentary rocks of the c.1900-1880Ma South Alligator Group is important for the localisation of gold deposits. The distribution of deposits is influenced further by the location and shape of granitoids and their associated contact-metamorphic aureole. Approximately 90% of gold deposits lie within the ∼2.5km wide contact-aureole, and most of these are concentrated in, and just beyond, the biotite-albite-epidote zone (0.5-1.0km from granitoid), with few deposits located in the inner hornblende-hornfels zone. At the deposit scale, gold is commonly associated with arsenopyrite-loellengite and pyrite, native-Bi and Bi-bearing minerals, and is confined to a variety of extensional quartz-sulphide ± carbonate veins. Such veins formed typically at 180-320°?C and ∼1kbar from low- to moderate salinity, two-phase aqueous fluids. Isotopic studies of the deposits are equivocal in terms of the source of hydrothermal fluid. Most δD and δ18O values fall within the range defined for contact-metamorphic and magmatic fluids, and sulphur isotopes indicate that the fluids are within the range of most regional sources. Significantly, lead isotope ratios show that the goldbearing fluid does not have a felsic magmatic-source signature, but instead suggest a homogenous regional-scale lead source. Excluding a few outliers, the relative uniformity of deposit characteristics, including host rocks, structural style, alteration, sulphide paragenesis and fluid P-T-X conditions, suggests that most deposits represent a continuum of broadly coeval mineralisation that formed under similar geological conditions Geology, Stratigraphic -- Proterozoic Gold mineralisation SHRIMP U-Pb Pine Creek Orogen
65	The tectonic evolution and volcanism of the Lower Wyloo Group, Ashburton Province, with timing implications for giant iron-ore deposits of the Hamersley Province, Western Australia Muller, Stefan G. January 2006 (has links) [Truncated abstract] Banded iron formations of the ~27702405 Ma Hamersley Province of Western Australia were locally upgraded to high-grade hematite ore during the Early Palaeoproterozoic by a combination of hypogene and supergene processes after the initial rise of atmospheric oxygen. Ore genesis was associated with the stratigraphic break between Lower and Upper Wyloo Groups of the Ashburton Province, and has been variously linked to the Ophthalmian orogeny, late-orogenic extensional collapse, and anorogenic continental extension. Small spot PbPb dating of in situ baddeleyite by SHRIMP (sensitive highresolution ion-microprobe) has resolved the ages of two key suites of mafic intrusions constraining for the first time the tectonic evolution of the Ashburton Province and the age and setting of iron-ore formation. Mafic sills dated at 2208 ± 10 Ma were folded during the Ophthalmian orogeny and then cut by the unconformity at the base of the Lower Wyloo Group. A mafic dyke swarm that intrudes the Lower Wyloo Group and has close genetic relationship to iron ore is 2008 ± 16 Ma, slightly younger than a new syneruptive 2031 ± 6 Ma zircon age for the Lower Wyloo Group. These new ages constrain the Ophthalmian orogeny to the period <2210 to >2030 Ma, before Lower Wyloo Group extension, sedimentation, and flood-basalt volcanism. The ~2010 Ma dykes present a new maximum age for iron-ore genesis and deposition of the Upper Wyloo Group, thereby linking ore genesis to a ~21002000 Ma period of continental extension similarly recorded by Palaeoproterozoic terrains worldwide well after the initial oxidation of the atmosphere at ~2320 Ma. The Lower Wyloo Group contains, in ascending order, the fluvial to shallow-marine Beasley River Quartzite, the predominantly subaqueously emplaced Cheela Springs flood basalt and the Wooly Dolomite, a shelf-ramp carbonate succession. Field observations point to high subsidence of the sequence, rather than the mainly subaerial to shallow marine depositional environment-interpretation described by earlier workers. Abundant hydro-volcanic breccias, including hyaloclastite, peperite and fluidal-clast breccia all indicate quench-fragmentation processes caused by interaction of lava with water, and support the mainly subaqueous emplacement of the flood basalt which is also indicated by interlayered BIF-like chert/mudstones and below-wave-base turbiditic mass-flows. Geology, Stratigraphic -- Proterozoic Baddeleyite SHRIMP-geochronology Physical volcanology Carbonate sequence stratigraphy Precambrian tectonics
66	Micropaleontologia aplicada na interpretação estratigráfica e paleoclimática da transição entre o Grupo Paranoá e o Supergrupo São Francisco (Neoproterozóico, Cabeceiras, GO) / Micropaleontolgy applied to the stratigraphic and paleoclimatic interpretation of the transition between the Paranoá Group and São Francisco Supergroup (Neoproterozoic, Cabeceiras, Goiás) Evelyn Aparecida Mecenero Sanchez 26 March 2010 (has links) O registro proterozóico da Fazenda Funil, região de Cabeceiras, GO, inclui três unidades sedimentares: carbonatos do topo do Grupo Paranoá, níveis de diamictito da Formação Jequitaí, e um pacote de folhelhos, ritmitos de margas e folhelhos e carbonatos da Formação Sete Lagoas. As três unidades registram ocorrência de sílex microfossilífero, encontrados na forma de lentes no Grupo Paranoá, seixos na Formação Jequitaí e uma camada de aproximadamente 600 m de extensão na Formação Sete Lagoas. A semelhança do sílex nas três unidades levou ao questionamento da estratigrafia da Fazenda Funil e da origem dos seixos na Formação Jequitaí, se esta origem foi, de fato, sedimentar (glacial) ou se teria sido tectônico. Foram comparadas as tramas petrográficas (fabrics) do sílex das três unidades, aspectos inorgânicos (minerais, estruturas sedimentares e estruturas diagenéticas) e o seu conteúdo orgânico (microfósseis e características da matéria orgânica). A análise das amostras revelou grande semelhança entre as tramas e seus microfósseis. Nas três unidades foram identificados os mesmos tipos de tramas cinco tipos e 12 táxons de microfósseis, sendo que dois deles ainda não haviam sido identificados na região. Conclui-se que a camada de sílex atualmente atribuída à Formação Sete Lagoas foi a fonte dos seixos de sílex do diamictito da Formação Jequitaí e representa, na verdade, uma lasca tectônica do Grupo Paranoá colocada dentro do Grupo Bambuí durante a deformação brasiliana. Esta camada teria sido erodido e o diamictito depositado presumivelmente durante a glaciação Sturtiana, embora outras evidências glaciais não fossem observadas na Fazenda Funil. Este trabalho, além de esclarecer as relações estratigráficas na Fazenda Funil, demonstrou que microfósseis pré-cambrianos podem ser uma ferramenta muito útil no entendimento de bacias proterozoicas. / The Proterozoic record of the Fazenda Funil, near Cabeceiras, GO, includes three sedimentary units: carbonate at the top of Paranoá Group, diamictite of the Jequitaí Formation, and a succession of shale, marl-shale rhythmites, and carbonate of the Sete Lagoas Formation. Microfossiliferous chert occurs in these three units in the form of lenses in the Paranoá Group, clasts within the diamictites of the Jequitaí Formation and as a persistent, 600 meter-long layer in the Sete Lagoas Formation. The similarity of the chert from these three units brings up crucial questions as to the stratigraphy of the Fazenda Funil and the origin of the clasts in the Jequitaí Formation : are they, in fact, of sedimentary (glacial) or tectonic origin? Comparisons among the three units were made of chert fabrics, inorganic aspects (minerals, sedimentary and diagenetic structures), and organic content (microfossils and general characteristics of the organic matter). The analysis of several samples revealed great similarity between the fabrics and microfossils in the three units. Five fabrics and 12 microfossil taxons were identified, two taxons for the first time in the region. These observations led to the conclusion that the chert layer presently attributed to the Sete Lagoas Formation was the source of the chert clasts in the Jequitaí Formation and represents is a slice of the Paranoá Group introduced tectonically within the Bambuí Group during Brasiliano deformation. This layer was eroded and the diamictite deposited presumably during the Sturtian glaciation, even though other evidence of glaciation were not observed on Fazenda Funil. This research, besides clarifying stratigraphic relationships on Fazenda Funil, also demonstrates that Precambrian microfossils can be a very useful tool in research on Proterozoic basins. Formação Jequitaí Formação Sete Lagoas Grupo Paranoá Microfósseis Proterozoico Tramas petrográficas Fabrics Jequitaí Formation Microfossils Paranoá Group Proterozoic Sete Lagoas Formation
67	Système d'altération et minéralisation en uranium le long du faisceau structural Kiggavik-Andrew Lake (Nunavut, Canada) : modèle génétique et guides d'exploration / Alteration system and uranium mineralization along the Kiggavik-Andrew Lake structural trend (Nunavut, Canada) : metallogenic model and exploration pathfinders Riegler, Thomas 10 December 2013 (has links) Ce travail présente une étude multi-échelle des relations entre altération et minéralisation en uranium le long de la bordure Sud Est du bassin Méso-Protérozoïque du Thelon, au Nunavut, Canada. Les altérations associées aux minéralisations sont développées dans une série volcano-sédimentaire Archéenne appartenant à la ceinture de roche verte du Woodburn Lake Group (WLG). Elles s'expriment majoritairement par un assemblage à illite (polytypes 1Mcis & 1Mtrans) ± sudoite ± hématite et phosphates sulfates d'aluminium hydratés (APS). De plus des composés carbonés, cogénétiques des minéralisations, ont été identifiés comme des produits des réactions hydrothermales. La signature de l'altération, fortement guidées par les structures Est-Ouest du corridor de Kiggavik-Andrew Lake, apparaît alors très similaire à celle rencontrée dans les roches de socles des parties profondes des autres gisements d'uranium de type discordance du bassin d'Athabasca (Canada) ou de la Kombolgie (Australie). L'étude des marqueurs minéralogiques tels que les APS ont permis de mettre en évidence les transferts élémentaires au cours des processus métallogéniques et de distinguer les caractéristiques pétrographique et chimiques des processus diagénétiques et hydrothermaux. Enfin la compréhension fine de l'expression de marqueurs cristallographiques issus de l'irradiation naturelle des minéraux argileux donne de nouvelles pistes pour le traçage et la compréhension des circulations des radios-éléments à l'échelle géologique. / This work presents a multi-scale study of the relationships between alteration and uranium mineralization along the South Eastern margin of the Meso-Proterozoic Thelon Basin, Nunavut, Canada. The ore associated alterations are hosted in an Archean volcano-sedimentary sequence belonging to the Woodburn Lake Group (WLG). Their main expression is a mineral assemblage composed of dominant illite (1Mcis & 1Mtrans polytypes) together with sudoite ± hematite and aluminum phosphate sulfate minerals. Moreover carbonaceous materials cogenetic with the uranium mineralization have been identified as potential indicators of the hydrothermal conditions. At a regional scale, alteration is strongly controlled via East-West faults forming the main frame of the Kiggavik-Andrew Lake structural trend. Then from the regional to the mineral scale, alterations signatures at Kiggavik are similar to the ones described in deep basement rocks of unconformity type uranium deposits in both Athabasca (Canada) and Kombolgie (Australia) Paleoproterozoic basins. In addition mineralogical markers studies (APS minerals) lead to the distinction between hydrothermal and diagenetic processes as well as elemental transfers during fluid rock interaction. Finally, detailed studies on radiation induced defects on illite revealed new ways to tracing and better understanding the radio elements mobility in such deep seated natural systems. Bassin Méso-Protérozoique du Thelon Altération Minéraux argileux Pétrographie Cristallochimie Métallogénie de l'uranium Meso-Proterozoic Thelon basin Alteration Clay minerals Petrography 553.4
68	Les changements géodynamiques à la transition Archéen-Protérozoïque : étude des granitoïdes de la marge Nord du craton du Kaapvaal (Afrique du Sud) / Geodynamic changes at the Archaean-Proterozoic transition : study of the granitoids from the northern part of the Kaapvaal craton (South Africa) Laurent, Oscar 10 December 2012 (has links) La composition chimique de la croûte continentale a significativement évolué à la transition Archéen-Protérozoïque (3000–2500 Ma), témoignant de changements géodynamiques majeurs à cette époque. Afin d’étudier l’expression et les origines de ces changements, qui sont encore mal contraints, j’ai étudié une diversité de granitoïdes qui se sont mis en place dans cette gamme d’âges à la marge Nord du craton du Kaapvaal, en Afrique du Sud. Ce travail a permis de préciser la typologie et l’origine des granitoïdes tardi-archéens ; ceux-ci peuvent être classés dans trois grands groupes : (1) Les sanukitoïdes, représentés en Afrique du Sud par le pluton de Bulai, sont des magmas dérivant de l’interaction entre une péridotite mantellique et un composant riche en éléments incompatibles (TTG, liquide issu de la fusion de sédiments, et, plus rarement, fluide aqueux). Les sanukitoïdes peuvent être classés en deux groupes distincts, selon les mécanismes de cette hybridation : les low-Ti sanukitoids proviennent d’une simple hybridation du liquide silicaté avec la péridotite, alors que les high-Ti sanukitoids sont issus de la fusion d’un assemblage métasomatique à amphibole et phlogopite, résultant de ces interactions. Enfin, les mécanismes de différenciation des suites sanukitoïdes au niveau de la croûte sont contrôlées par des mécanismes de cristallisation fractionnée ou (moins vraisemblablement) de fusion partielle. (2) Les sanukitoïdes « marginaux », représentés dans le craton du Kaapvaal par les plutons de Mashashane, Matlala, Matok et Moletsi, sont des granitoïdes résultant de l’interaction entre des sanukitoïdes et des magmas provenant de la fusion de croûte préexistante. Etant donné la large gamme de sources possibles (TTG, métasédiments, roches mafiques) d’un craton à l’autre, ce groupe est extrêmement diversifié. Leurs mécanismes de différenciation sont contrôlés par la cristallisation fractionnée. (3) Certains granites, tels que le batholite de Turfloop en Afrique du Sud, sont directement issus de la fusion de lithologies crustales (TTG, métasédiments et amphibolites). Au sein du craton du Kaapvaal, l’évolution spatio-temporelle du magmatisme tardi-archéen suit un schéma très caractéristique : les TTG se mettent en place entre ~3300 et ~2800 Ma, puis laissent la place à la genèse de l’ensemble des granitoïdes présentés ci-dessus, qui se déroule entre 2780 et 2590 Ma. Cette séquence d’évènements est reproduite au sein de tous les cratons du monde à la fin de l’Archéen. Elle témoigne de l’avènement des processus de recyclage crustal, puisque, par opposition aux TTG archéennes qui dérivent de métabasaltes juvéniles, les magmas tardi-archéens sont issus à la fois de la différenciation intracrustale et de l’interaction entre une péridotite et du matériel continental introduit dans le manteau. Cette dualité de processus pétrogénétiques est aussi très typique des épisodes magmatiques qui ont lieu à la fin des cycles de subduction-collision post-archéens. Ainsi, l’évolution de la composition des granitoïdes entre 3000 et 2500 Ma traduit vraisemblablement l’initiation d’une forme de tectonique des plaques proche du régime actuel. Celle-ci serait liée au refroidissement planétaire global, qui a probablement entraîné un « effet de seuil » dans l’évolution de l’épaisseur de la croûte océanique ainsi que la rhéologie et le volume de la croûte continentale, permettant ainsi à la subduction et à la collision de ne devenir thermo-mécaniquement stables qu’à partir de la fin de l’Archéen. / The chemical composition of continental crust significantly evolved though time, in particular at the Archaean-Proterozoic transition (3000–2500 Ma), which witnesses major geodynamic changes at that time. The nature and origin of these changes are poorly constrained so far. To better constrain them, I studied a range of granitoid emplaced at that time at the northern margin of the Kaapvaal Craton, in South Africa. In the light of my work, the typology and origin of this magmatism has been reappraised; in particular, the late-archaean granitoids can be split in three different groups : (1) Sanukitoids are represented in South Africa by the Bulai pluton. They are hybrid magmas derived from interaction between mantle peridotite and a component rich in incompatible elements (generally a melt derived from either metabasalts or metasediments). They can be separated in two groups, depending on the hybridation process: low-Ti sanukitoids derive from one-step interaction of silicate melt with peridotite, while high-Ti sanukitoids result from melting of a metasomatic, amphibole- and phlogopite-bearing assemblage equilibrated during the interactions. Finally, the differentiation mechanisms of sanukitoid suites at crustal levels are mainly controlled by fractional crystallization or, less likely, partial melting. (2) « Marginal » sanukitoids, as represented in the Kaapvaal craton by Mashashane, Matlala, Matok and Moletsi plutons, are produced by interactions between sanukitoids and crust-derived melts. Because the source of the latter can be very different from a craton to another, this group of granitoids is extremely diverse. Their magmatic evolution is mostly controlled by fractional crystallization, such as sanukitoids. (3) Some granites, such as those from the Turfloop batholith in South Africa, directly derive from melting of older crustallithologies (TTGs, metasediments, mafic rocks). The evolution of late-archaean magmatism in the Kaapvaal craton follows a very typical sequence: genesis of TTG took place between ~3300 and ~2800 Ma, and give way to the emplacement of all granitoid types presented above, which occurs in a short time span between 2780 and 2590 Ma. This succession of events is identical within every craton worldwide at the end of the Archaean. It witnesses the advent of crust recycling processes, as late-archaean magmas derive from both intracrustal differentiation and interactions between peridotite and continental material introduced within the mantle. This sharply contrasts with the genesis of TTG through melting of juvenile metabasalts only. This duality of petrogenetic processes is also typical of magmatic events in late- to post-orogenic settings, at the end of present-day subduction-collision cycles. As a result, the evolution of the crust composition between 3000 and 2500 Ma likely reflects the initiation of modernstyle plate tectonics. This would be the consequence of global cooling of Earth, which has induced a threshold effect in parameters such as (1) the thickness of oceanic crust and (2) the rheology and volume of continental crust. Indeed, these parameters exert a primary control on the thermo-mechanical stability of subduction and collision, and both became possible at the end of the Archaean only. Transition Archéen-Protérozoïque Géochimie des granitoïdes Modélisation géochimique Sanukitoïdes Croissance crustale Différenciation crustale Craton du Kaapvaal Archaean-Proterozoic transition Granitoid geochemistry Geochemical modelling Sanukitoids Crustal growth Crustal differentiation Kaapvaal craton
69	Fluid-induced charnockite formation post-dating prograde granulite facies anatexis in southern Natal metamorphic province, South Africa Saunders, Brenton Mark 24 April 2014 (has links) M.Sc. (Geology) / The Proterozoic Namaqua-Natal Mobile Belt of southern Africa represents a succession of high grade metamorphosed igneous and sedimentary rocks rimming the southern and western extents of the Kaapvaal craton. Different petrological processes associated with the onset of granulite facies metamorphism were investigated with the emphasis on the processes on anatexis and migmatitization and the influence of the fluid phase on these processes. The investigation took place in the Margate Terrane of the Southern Natal Metamorphic Province. The Umzimkulu and Louisiana Quarries near Port Shepstone formed the bulk of the field area for this investigation. The Umzimkulu and Louisiana quarries expose two s-type granitic lithologies, namely, the Glenmore Biotite Gneiss (GBGn) and the slightly younger, intrusive Margate Leucogranite (MLGn), both of which have been metamorphosed to granulite facies. Geothermobarometric calculations on the metamorphism of the Margate Terrane all indicate temperatures and pressures of peak metamorphism be 850oC+50oC at +6 kbar. The high grade metamorphic history of the lithologies is recorded by the formation of concordant, lens-shaped, prograde anatectic leucosomes. The leucosomes are concentrically surrounded by biotite selvage zones, followed by melanosomes, and lastly undisturbed host rock material. This investigation revealed that the formation of both the charnockite veins and the prograde leucosomes occurred through processes of anatexis. Field relations suggest that the charnockitic veins formed in situ, and were structurally controlled, which is evident from their linearity. Petrographic and geochemical data provide evidence for melt involvement. This is in strong contrast to theories of charnockite formation ascribed to subsolidus granulite formation by the flushing of host lithologies by a pervasive, carbonic fluid, as has been suggested to have occurred in Southern India. The so-called "incipient charnockites" of Southern India are both morphologically and geochemically similar to the charnockite veins described in the SNMP, suggesting that an anatectic origin may be common to both. Stratigraphic geology - Proterozoic Geology - Kwazulu-Natal - Port Shepstone Charnokite - Namaqua-Natal mobile belt
70	Paleoproterozoic crustal evolution and Fe-Cu metallogeny of the western Yangtze Block, SW China Zhao, Xinfu, 赵新福 January 2010 (has links) published_or_final_version / Earth Sciences / Doctoral / Doctor of Philosophy Iron ores - China - Yunnan Sheng Metallogeny - China - Yunnan Sheng Copper ores - China - Sichuan Sheng. Metallogeny - China - Sichuan Sheng. Geochemistry - China - Sichuan Sheng. Geochemistry - China - Yunnan Sheng. Geology, Stratigraphic - Proterozoic.

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