Post-Orogenic Exhumation and Glacial Erosion on the Flanks of the North Atlantic

Fame, Michelle Leigh

19 July 2017

Many passive margins experience pulsed exhumation events late in their history as a result of plate boundary distal geodynamic mechanisms or climatic events. The onset of late Cenozoic glaciation, often associated with enhanced rates of erosion, is one such possible cause of passive margin rejuvenation. However, along passive margins the effectiveness of Plio-Pleistocene glaciers at eroding the landscape may be limited by low tectonic rock uplift rates or as a result of erosionally inefficient cold based continental ice-sheets. In this dissertation the evolution of post-orogenic topography and the effect of glaciations on denuding landscapes along the North Atlantic Passive Margin, in the White Mountains of New Hampshire and the western Scottish Highlands, was investigated. Background exhumation rates averaged over 106-7 yr timescale were determined using apatite (U-Th)/He thermochronology. To resolve whether or not a change in exhumation rate occurred coincident with glaciation these background exhumation rates were compared to magnitudes of erosion averaged over the glacially relevant 103-4 yr timescale using the in situ terrestrial cosmogenic nuclide 10Be. In chapter two, 106-7 yr timescale exhumation and burial histories across the western Scottish Highlands were determined. The results show that post-orogenic burial and exhumation is mostly a result of plate margin distal tectonic and magmatic factors that are variable across short distances (i.e., <100 km). In chapter three, patterns and magnitudes of erosion during glaciation and following deglaciation in the Scottish Highlands were investigated. The results indicate that polythermal glacial erosion denuded low elevation portions of the Scottish Highlands and preserved summits. This produced relief but did not significantly lower the maximum elevation of the landscape. Following deglaciation Scotland's sediment budget remains dominated by glaciogenic sediment. In the fourth chapter, magnitudes of background exhumation in the Presidential and Carter Ranges of the White Mountains, New Hampshire were compared to magnitudes of glacial erosion. The results indicate that most relief was produced prior to glaciation and that background exhumation rates in the Cenozoic are low (<0.01 mm yr-1). In the late-Cenozoic, cold- based glaciation prevented an acceleration of erosion in the White Mountains. The post- glacial sediment budget is made up of dominantly glaciogenic sediment. Overall, the main findings of this dissertation are; (1) post-orogenic burial, exhumation, and relief production are mainly the result of spatially heterogeneous plate margin distal vertical crustal motions; across passive margins covered by large continental ice sheets; (2) cold-based ice limits the magnitudes of late Cenozoic glacial erosion sediment budgets continue to be dominated by glaciogenic sediment, >10 ka after and (3) post-glacial deglaciation. / Ph. D.

Geomorphology

Passive Margins

Glacial Erosion

Low Temperature Thermochronology

Les marges passives volcaniques : origine, structure et développement / Volcanic passive margins : origin, structure and development

Guan, Huixin

12 July 2018

Une marge passive est une zone de transition non-active entre lithosphère continentale et lithosphère océanique. De nombreuses marges passives présentent un fort développement magmatique (>50%). Ces marges passives volcaniques (MPVs) marquent la rupture lithosphérique au-dessus d’un manteau en fusion (partielle) et sont typiquement caractérisées par l’intrusion et l’extrusion d’un volume significatif de produits magmatiques dans la croûte lors des périodes ante-rift, syn-rift et post-rift. A partir d’une compilation bibliographique, de données sismiques (profils de sismique réflexion ION-GXT, sismique 3D) et d’observations réalisées sur le terrain à l’Est et à l’Ouest du Groenland, les objectifs de cette thèse étaient : (1) de mieux caractériser les modes tectoniques d’accommodation des flexures de la croûte supérieure sous les SDRs (seaward dipping reflectors) et l’interprétation des SDRs externes et, (2), de placer la rupture magmatique à l’échelle de la fragmentation d’un supercontinent. Les principaux résultats obtenus sont: 1) La rupture d’un supercontinent est toujours synmagmatique. Cette rupture se propage ensuite de manière non-magmatique (article en préparation); 2) Les SDRs externes sont découplés tectoniquement d’une croûte inférieure d’origine continentale exhumée. Du matériel d’origine continental pourrait exister en profondeur de manière continue au niveau de rides asismiques transverses (comme GIFR) (article soumis); 3) La flexure crustale est aussi accommodée par du magma qui circule dans les failles de détachement sous SDRs. Un découplage existe à l’extrados des flexures accommodé par des injections de magma syn-tectoniques sous forme de laccolithes à la base des SDRs internes. / A passive margin is a non-active transition zone between the continental lithosphere and the oceanic lithosphere. Most of passive margins (>50%) show a strong magmatic development. These volcanic passive margins (VPMs) mark the lithospheric breakup over a melted mantle and they are typically characterized by a huge volume of intrusive and extrusive magmatism into the crust during ante-rift, syn-rift, and post-rift periods.Based on bibliographies, seismic data (IONGXT seismic reflection profiles, 3D seismic) and observations and results gained from fieldtrips on East and West Greenland coast, the objectives of this thesis were: (1) to better characterize the tectonic accommodation of the flexure of the upper crust which beneath inner SDRs and the signification of outer SDRs, and (3) to place the magmatic breakup on the scale of the fragmentation of a supercontinent.The main results obtained are: 1) the breakup of a supercontinent is always syn-magmatic. This breakup then propagates in a non-magmatic way (paper in preparation); 2) the outer SDRs are tectonically decoupled from an exhumed continental lower crust.The material of continental origin could exist deeply continuously across a transverse aseismic ridge such as the GIFR (paper submitted); 3) The crustal flexure is also accommodated by the magma that circulate in detachment faults beneath the inner SDRs. There is a decoupling at the extrados zone of the flexure which is accommodated by syn-tectonic magma injections in the form of laccoliths between inner SDRs and upper crust.

Marge passive volcanique

SDRs

Intrusions

Extension lithosphérique

Fragmentation continentale

Volcanic passive margins

SDRs

Polyphase lithospheric extension

Fragmentation of Pangea

La lithosphère du point triple Aden - Afar - sud mer Rouge et du golfe d'Aden : magmatisme et rupture continentale / The Aden-Afar-southern Red sea triple junction lithosphere : magmatism and continental breakup

Korostelev, Felicie

23 April 2015

La jonction triple des Afars relie la mer Rouge, le golfe d'Aden et le rift éthiopien. Il est possible d'y étudier les différents stades d'extension depuis le rifting actif jusqu'aux marges continentales passives. Si l'extension et l'activité magmatique sont généralement considérées comme étant restreintes aux segments actifs des rifts ou aux dorsales océaniques, il existe pourtant une activité magmatique sur les flancs des marges continentales passives de l'Afar, du sud de la mer Rouge et du golfe d'Aden. La tomographie de bruit et la tomographie télésismique sont des méthodes complémentaires qui permettent d'imager la croûte ou le manteau supérieur et de mettre en évidence des systèmes magmatiques. Nos études de tomographie ont mis en évidence la présence de systèmes magmatiques complexes sous les flancs du rift Afar, en lien avec des sources hydrothermales en surface. La mise en place de matériel magmatique dense sous forme d'intrusions ou sous-plaqué au niveau de la croûte inférieure de l'Afar accommode l'extension en dehors des segments magmatiques actifs. De plus, les flancs de la marge de la mer Rouge au Yémen sont affectés par un magmatisme provoqué par des remontées localisées de matériel mantellique depuis une large zone de manteau anormalement chaud. Nous suggérons également, sous les épaules des marges passives de l'est du golfe d'Aden, la présence de systèmes magmatiques avec ou sans expression volcanique à la surface. Ces systèmes pourraient être alimentés par des cellules de convection petite échelle se mettant en place à la faveur de variations d'épaisseur de la lithosphère, en bordure de marge et à proximité des grandes zones de fracture du golfe d'Aden. / The Afar triple junction is a unique region that links the Red Sea, the Gulf of Aden and the Ethiopian rift, and where it is possible to study the different stages of continental breakup, from early rifting to seafloor spreading and development of continental passive margins. Extension and magmatic activity are generally thought to be restricted to the active volcanic segments of the rift or to oceanic ridges. However, magmatic activity is also present on the continental margins flanks of the Afar rift, southern Red Sea and Gulf of Aden. The ambient noise tomography and teleseismic body-wave tomography are complementary methods that allow imaging the crust and upper mantle, and help to reveal magmatic systems. Our tomographic studies of the Afar region provide evidence for the presence of complex magmatic systems under the Afar rift flanks, currently modifying the crust and linked with hydrothermal systems near the surface. The emplacement of intruded or under-plated dense magmatic material in the Afar lower crust accommodates the extension outside of the active magmatic segments. In addition, the Red Sea margin flanks in Yemen are affected by magmatism caused by localized small-scale upwellings of mantle material, from a broad abnormally hot mantle zone located beneath Afar and southwestern Yemen. We also suggest the presence of magmatic systems with or without a volcanic expression at the surface, beneath the passive margins shoulders of the eastern Gulf of Aden. We propose that these systems could be fed by small-scale convection caused by lithosphere thickness variations at the edge of the Arabian plate and near the Gulf of Aden main fracture zones.

Yémen

Marge continentale passive

Tomographie

Golfe d'Aden

Afar

Mer Rouge

Panache mantellique

Continental passive margins

Tomography

551.8

Restauration structurale de la tectonique salifère de la partie centrale du bassin de Santos et des implications pour les systèmes pétroliers / 3D structural restoration of halokinesis in the central portion in the Santos Basin. Implications for the Petroleum Systems

De melo garcia, Savio francis

14 September 2012

The present thesis consists in a real complex case study of halotectonic deformation in the central portion of the Santos Basin passive margin, investigating the complex interactions between deformation and sedimentation and evaluating its impacts on the petroleum systems.Seismic data set and exploration wells were input to the study, which cover an area where halokinetics affect the active petroleum systems. The thickest depocenter of the Santos basin is partially in the study area. The sedimentary infilling history is associated with the Cabo Frio Fault development, linked with a gap of tens of kilometers in the Albian sediments occurrence. Minibasins are under halotectonic compression towards deep waters. The challenges of this work consists in find methods to build and then to restore the structural model in an effective way.Fifteen interpreted horizons were used to build a surface model. Five geological cross-sections were restored and interpolated to get salt and overburden volumes. The restoration successively removes the uppermost layer and decompacts the remaining layers through sedimentary unloading. Restoration also considers the unloading isostatic compensation by flexure of an elastic weak layered lithosphere. The isostasy plays an important role in the tectono-sedimentary control. Its interaction with bathymetry, faults geometry and deposition surface profile constrains the local and regional subsidence. Biostratigraphic data and seismic pattern defined trough time the absolute paleobathymetry.The cross-section restoration has differentiated the major rift phase sequence deformation from three other drift phase sequences above the sal layer.Several 1D geo-histories were reconstructed for different points along the main direction of transport, to control the thickness variations in the 2D sections. 1D and 2D restorations clearly show that salt moves out of the study area and that there is strong coupling between the halotectonic dynamic and the change in the accommodation space.The extrapolation of the restoration results to 3D allows a better compartmentalization between the hemigrabens in the rift phase; highlights the role of structural high in the center of the investigated area and confirms the relation between structural evolution and sedimentation. Two major depocenters were amalgamated by salt deposition over the accentuated relief inherited from the larger vertical tectonic subsidence of the rift phase. The sedimentary infilling reveals the temporal relations of NE-SW and NNW-SSE oriented structures within the higher subsidence compartment in the western sector of the area. Two different ways to restore the sections allowed the uncertainty estimation of the bathymetry and isostatic relationships.The salt layer material conservation assumption, an operational tool, was consistent with the results. The salt volume balance over time showed a good correlation to lateral extension of the continental drift stage.The implications of the restoration scenario on the petroleum systems were only qualitatively interpreted and then compared to the classical backstripping approach. Three main sectors appear: the proximal shelf, the slope and the deepwater sector of the continental rise. The relatively early halotectonics of the proximal sector induces a more fast and short generation whereas, beyond the continental slope region, the petroleum systems is distally more heterogeneous, develops slower, dissipated and differentiated by the halokinesis, with longer refills fronts. The direct impact of salt restoration on the maturity evaluation is actually relatively small, because about 90% of ductile deformation occurred before 65 Ma and a significant part of the generation is ongoing after 65 Ma. On the other hand, the halotectonic restoration is fundamental regarding its impact on the petroleum systems. / Ce travail étudie la déformation salifère dans la partie centrale du Bassin de Santos sur la marge Atlantique brésilienne et examine l'interaction complexe entre cette déformation et la sédimentation, ainsi que ses effets sur les systèmes pétroliers. Les données sismiques et les puits disponibles couvrent une zone où l'halocinèse affecte les systèmes pétroliers actifs. Le principal dépôt-centre du bassin est partiellement dans la zone d'étude. L'histoire de remplissage sédimentaire est liée au développement de la faille de Cabo Frio, qui induit un absence des sédiments de l'Albien sur des dizaines de kilomètres. Des mini-bassins dus à la compression salifère se produisent dans la partie la plus distale.Il s'agit dans ce travail de trouver une méthode effective de construire et de restaurer le modèle structural. Quinze horizons stratigraphiques ont été interprétés. Cinq coupes géologiques ont été restaurées et interpolées pour analyser l'évolution temporelle des volumes du sel et des unités encaissantes. La restauration enlève successivement la couche la plus récente et décompacte les couches sous-jacentes en fonction de la charge enlevée. La procédure de restauration prend aussi en compte la compensation flexurale d'une lithosphère élastique et peu épaisse. L'isostasie joue un rôle important dans le contrôle tectono-sédimentaire. Son interaction avec la profondeur d'eau, la géométrie des failles et la surface de dépôt contrôle la subsidence locale et régionale. Des données des puits et les facies sismiques aident à calibrer la paléo-profondeur d'eau.La restauration de coupes différencie la déformation verticale de la phase anté sel des trois autres séquences qui ont été déposées au-dessus du sel. Plusieurs reconstructions 1D illustrent différentes situations le long de la direction principale de transport et permettent de contrôler l'épaisseur des coupes restaurées. Les restaurations 1D et 2D ont clairement montré que le sel s'échappe vers l'est au-delà de la région d'étude. La dynamique du sel se corrèle fortement avec l'espace d'accommodation disponible. L'extrapolation de la restauration au domaine 3D a permis de mieux configurer les demi-grabens de la phase rift, a accentué le rôle des hauts structuraux au centre de la zone étudiée et a montré comment les relations structurales contrôlent la sédimentation. Deux dépôt-centres ont été unis par le déposition de sel sur une topographie escarpée héritée du rifting. Le remplissage du compartiment le plus subsident à l'ouest du modèle a permis des interprétations temporelles par rapport aux structures orientées NE-SW et NNW-SSE. Deux façons de restaurer les coupes ont permis d'évaluer l'incertitude sur la paléo-profondeur d'eau et ses relations avec l'isostasie. L'hypothèse d'une préservation volumique du sel s'est avérée cohérente avec les résultats, puisqu'elle a montré une bonne corrélation avec la distension latérale lors de la dérive continentale.Les implications du scénario restauré sur les systèmes pétroliers ont été interprétées qualitativement et comparées ensuite avec l'approche classique de backstripping. Trois secteurs sont distingués : plateforme, pente et l'eau profonde. La tectonique salifère relativement précoce a induit une génération plus rapide et plus courte pour le secteur plus proche tandis que, au-delà de la pente continentale les systèmes pétroliers distaux sont plus hétérogènes avec un développement ralenti, dissipé et différencié par l'halocinèse, avec de recharges sur des temps plus longs. L'impact direct de la restauration de sel sur l'évaluation de la maturité est relativement faible, puisque 90% de la déformation ductile se produit avant 65 Ma et une partie importante de roches mères ont maturé plus tard. Mais la restauration de la tectonique salifère est essentielle par son impact sur le système pétrolier post déformation.

Tectonique salifère

Restauration structurale

Bassin de Santos

Marges passives

Atlantique Sud

Offshore profond

Salt tectonics

Structural restoration

Santos basin

Passive margins

South Atlantic

Deep offshore

Mouvements verticaux des marges passives d’Afrique australe depuis 130 Ma, étude couplée : stratigraphie de bassin : analyse des formes du relief / Post-rift vertical movements of the southern African passive margins since 130 Ma : a combined approach : basin analysis, landforms study

Baby, Guillaume

23 March 2017

Le plateau sud-africain (ou Kalahari) est le plateau anorogénique le plus grand au monde. Sa très grande longueur d’onde (×1000 km) et son altitude moyenne élevée (1000-1500 m) impliquent des processus mantelliques. La cinétique et l’origine de ce relief sont mal comprises. D’un côté, les études géomorphologiques le considèrent comme un relief mis en place à la fin de l’intervalle Cénozoïque (<30 Ma). A l’inverse, les données thermochronologiques montrent deux phases de dénudation pendant l’intervalle crétacé, corrélées à des phases d’accélération du flux silicoclastique sur les marges, qui suggèrent qu’il s’agirait d’un relief plus ancien hérité du Crétacé supérieur. Peu d’études ont porté sur l’évolution du système terre-mer depuis le bassin versant en érosion aux marges en sédimentation. Ce travail de thèse repose donc sur une double approche : une analyse géomorphologique des formes du relief (surfaces d’aplanissement) à terre, basée sur leur (i) cartographie, (ii) chronologie relative, (iii) relation avec les profils d’altération et (iv) datation au moyen des placages sédimentaires et du volcanisme datés qui les fossilisent ; une analyse stratigraphique de l’intervalle post-rift des marges, basée sur l’interprétation de données de sub-surface (lignes sismiques et puits), réévaluées en âge (biostratigraphie), pour (i) identifier, dater et mesurer les déformations des marges et de leur relief amont , (ii) mesurer les flux silicoclastiques, produits de l’érosion continentale. Un calendrier et une cartographie des déformations ont été obtenus sur les marges et mis en relation avec les différentes générations de surfaces d’aplanissement étagées qui caractérisent le relief du plateau sud-africain. Au moins deux périodes de déformation ont été identifiées au Crétacé supérieur (92-70 Ma) et à l’Oligocène (30-15 Ma). L’évolution est la suivante : 100 - 70 Ma (Cénomanien à Campanien) : plateau à très grande longueur d’onde, peu élevé (0-500 m), bordé à l’est par des reliefs plus hauts et plus anciens le long des marges indiennes, qui agissent comme une ligne de partage des eaux entre l’océan Atlantique et l’océan Indien. La déformation est initiée à l’est avec une flexuration brève, à grande longueur d’onde, des marges indiennes aux alentours de ~92Ma. Cette première surrection marque un paroxysme d’érosion enregistré par la mise en place d’un delta géant sur la marge atlantique (delta de l’Orange). La déformation migre ensuite vers l’ouest avec la croissance du bourrelet marginal atlantique entre 81 et 70 Ma. Le relief acquiert sa configuration actuelle comme l’indique une diminution du flux silicoclastique sur la marge atlantique qui traduit un changement majeur du système de drainage ; 70-30 Ma (Crétacé terminal-Paléogène) : période d’apparente non déformation. Le relief est fossilisé et intensément altéré (latérites) ; 30-15 Ma (Oligocène - Miocène inférieur) : deuxième surrection du plateau sud-africain qui acquière sa topographie actuelle. La déformation semble plus importante à l’est du plateau - flexure des marges nord indiennes initiée à ~25 Ma qui alimente les grands deltas de l’océan Indien (Zambèze, Limpopo, Tugela) ; le relief est fossilisé à partir du Miocène moyen, synchrone d’une aridification majeure de l’Afrique australe. / The South African (Kalahari) Plateau is the world's largest non-orogenic plateau. It forms a large-scale topographic anomaly (×1000 km) which rises from sea level to > 1000 m. Most mechanisms proposed to explain its elevation gain imply mantle processes. The age of the uplift and the different steps of relief growth are still debated. On one hand, a Late Cretaceous uplift is supported both by thermochronological studies and sedimentary flux quantifications. On the other hand, geomorphological studies suggest a Late Cenozoic uplift scenario (<30 Ma). However few attentions were paid to the evolution of the overall geomorphic system, from the upstream erosional system to the downstream depositional system. This study is based on two different approaches : onshore, on the mapping and chronology of all the macroforms (weathering surfaces and associated alterites, pediments and pediplains, incised rivers, wave-cut platforms) dated by intersection with the few preserved sediments and the volcanics (mainly kimberlites pipes) ; offshore, on a more classical dataset of seismic lines and petroleum wells, coupled with biostratigraphic revaluations (characterization and dating of vertical movements of the margins - sediment volume measurement). The main result of this study is that the South African Plateau is an old Upper Cretaceous relief (90-70 Ma) reactivated during Oligocene (30-15 Ma) times. Its evolution can be summarized as follows : 100-70 Ma (Cenomanian to Campanian): low elevation plateau (0-500 m) with older and higher reliefs located along the Indian side, acting as a main divide between the Atlantic and the Indian Oceans. First uplift occurred in the east at ~92 Ma, with a fast flexuration of the Indian margins. This initiates a paroxysm of the erosion (90-80 Ma) with the growth of a large delta along the Atlantic margin (Orange delta). Deformation migrated progressively westward and resulted on the growth of the Atlantic marginal bulge between 81 and 70 Ma. Most of the present-day relief was probably created at this time. This is supported by the decrease of the sedimentary flux which suggests a reorganisation of the interior drainage pattern ; 70-30 Ma (Uppermost Cretaceous-Paleogene): most of the relief is fossilized and weathered - relative tectonic quiescence ; 0-15 Ma (Oligocene-Early Miocene): second period of the South African Plateau uplift. Most of the deformation took place along the Indian side of the Plateau (strike flexure) feeding the Zambezi, Limpopo and Tugela deltas ; since at least Middle Miocene times, all those reliefs have been fossilized, with very low erosion rates (x1m/Ma), in response to the major aridification of southern Africa.

Plateau sud-Africain

Marges passives

Stratigraphie sismique

Géomorphologie

Bilans érosion-Sédimentation

South-African Plateau

Passive margins

Seismic stratigraphy

Geomorphology

Source to sink approach

Arcabouço crustal profundo da parte Centro-Norte da margem de Angola: modelo de afinamento e contato de crostas / Deep crustal framework of North-Central margin of Angola: a model for thinning and crustal transition

Luiz Carlos Lucena Empinotti

27 October 2011

Este trabalho tem como objetivo a identificação de feições que permitam (1) a construção do arcabouço crustal profundo e da porção superior do manto em parte da Costa de Angola, (2) a comparação deste arcabouço com o embasamento aflorante e (3) a tentativa de adequar estes resultados aos modelos de ruptura continental já publicados. Para alcançar estes objetivos foi feita a interpretação de cinco linhas sísmicas de reflexão profundas (25 Km de profundidade) na costa de Angola, nas Bacias de Kwanza e Baixo Congo, adquiridas pela ION-GXT. As feições identificadas na sísmica de reflexão auxiliaram na determinação dos limites da crosta continental superior e inferior, no reconhecimento das camadas que compõem a crosta oceânica e na identificação da Descontinuidade de Mohorovicic (que marca o limite entre crosta e manto). A interpretação sísmica associada a dados da literatura (que proporcionaram valores de densidade para os pacotes identificados na interpretação sísmica) permitiram a realização de uma modelagem gravimétrica que foi comparada ao dado gravimétrico adquirido durante a aquisição sísmica. A modelagem gravimétrica serviu para validar a interpretação sísmica, atuando como um controle de qualidade para a interpretação. Caso a anomalia gravimétrica gerada pela modelagem não estivesse de acordo com a anomalia medida, a interpretação sísmica era revista na tentativa de um melhor ajuste entre o resultado modelado e o medido. Este ajuste, no entanto, sempre foi feito honrando os refletores que estavam bem marcados na sísmica. Somado a isto, ainda foi utilizado o dado magnético adquirido no campo, no auxilio da interpretação. O arcabouço crustal obtido com a utilização deste método permitiu a comparação dos resultados da interpretação com os modelos de evolução de margens passivas existentes na literatura, mostrando muitos pontos em comum aos modelos que defendem a possibilidade de ocorrência de manto exumado em margens passivas pobres em magmatismo. A interpretação final destes dados mostrou um domínio proximal marcado por uma crosta continental espessa porém pouco afinada em contato com um domínio distal marcado por uma crosta continental muito afinada (crosta hiper-estirada) e, em direção ao centro do oceano, uma região em que ocorre a exumação do manto. A passagem do domínio proximal para o distal ocorre de forma rápida em uma região denominada Zona de Estrangulamento. À oeste do manto exumado é possível identificar a crosta oceânica. O cruzamento dos resultados obtidos neste trabalho com dados do embasamento aflorante no continente africano sugerem um controle do deste nos valores finais de afinamento da crosta continental sob a bacia e nas regiões de manto exumado. Trabalhos recentes realizados na costa de Angola e do Brasil mostram feições semelhantes às identificadas nesta dissertação. / The main objectives of this study are to identify features on seismic data that allow (1) the building of a deep crustal framework and of the upper portion of the mantle, in part of the Angolan margin; (2) to compare this framework with the adjacent outcropping basement of the African continent and; (3) to try to fit these results to the published continental breakup models. In order to achieve these objectives, five deep reflection seismic lines (25 km of depth) situated in the in Kwanza and Lower Congo Basins on the passive margin of Angola were interpreted. The features identified on seismic were useful to recognize the tripartite division that caracterize the oceanic crust and in defining the Mohorovicic Discontinuity (that represents the limit between crust and mantle). The seismic interpretation associated with the data obtained from the scientific literature (that provided density values for the packages identified on seismic interpretation) allowed the establishment of a gravity modeling that was compared to the gravity data acquired during the seismic acquisition. The gravity model was useful to validate the seismic interpretation, acting as a quality control of the latter. In case of the gravity anomaly generated by the modeling not being in accordance with the measured anomaly, the seismic interpretation was revised in order to obtain a better adjustment between the modeled and the measured result. This adjustment, however, was always done honoring the reflectors that were clearly positioned on seismic. In addition, the magnetic data acquired on the field was used to help on interpretation. The crustal framework obtained by the methodology described above was compared with the passive margin evolution models found on scientific literature, showing some points in common with the models that postulate the occurrence of exhumed mantle in magma-poor passive margins. The final interpretation of these data showed the existence of a proximal domain characterized by a thick continental crust slightly thinned in contact with a distal domain marked by a hyper-extended continental crust. Oceanwards there is a region where the exhumation of the mantle took place. The passage of the proximal to the distal domain is abrupt, here termed as a Necking Zone. Oceanic crust is identified to the west of exhumed mantle. The comparison of the results obtained in this study with data from the outcropping basement on the African continent suggests a basement control on the vales of continental crust thinning attained under the basins and on the regions of exhumed mantle. Recent works done on the Angolan and Brazilian margins show features similar to the ones identified on this dissertation.

Arcabouço crustal

Sísmica profunda de reflexão

Modelagem gravimétrica

Modelo de ruptura continental

Margem passiva

Manto exumado

Angola

Crustal structures

Deep seismic reflection

Gravity modeling

Continental breakup models

Passive margins

Exhumed mantle

Angola

GEOLOGIA

Structure profonde de la marge Nord-Ouest Africaine / Deep crustal structure of the North-West African margin

Biari, Youssef

04 December 2015

La marge NE Américaine est une des marges les mieux étudiées au monde, elle a fait l’objet de plusieurs études géophysiques. En comparaison, la marge africaine reste peu étudiée car uniquement deux campagnes océanographiques y ont été menées : la campagne Sismar (2001) au large de la Meseta et la campagne Dakhla (2002) au large du Sahara. La structure profonde de la marge canadienne est connue grâce aux profils de sismique grand-angle SMART-1, 2 et 3. Le premier objectif du projet MIRROR était d’acquérir des profils combinant sismique grand-angle et sismique réflexion sur un segment homologue au profil SMART-1. La comparaison entre les segments homologues de ces deux marges ayant pour but de mieux comprendre le mode d’ouverture de l'océan Atlantique Central. Une comparaison entre les modèles Sismar, Dakhla et Mirror montre que la croûte continentale est plus épaisse au nord et s'amincit vers le sud. La largeur de la zone de transition est plus étroite au sud et les profils Sismar sont localisés sur un bassin sédimentaire posé sur une croûte continentale très amincie. La comparaison avec la marge homologue montre que l'épaisseur, la structure de la croûte continentale et la zone d'amincissement sont très semblables. Par contre, il existe une zone de manteau exhumé et serpentinisé sur le profil Canadien qui n'a pas d’homologue sur la marge africaine. De plus, l'épaisseur de la croûte océanique est différente avec 8 km sur la côte africaine et seulement 3-4 km sur la marge canadienne. Plusieurs hypothèses ont été proposées pour expliquer cette différence (a) une différence d’âge entre les deux croûtes (b) un épaississement lié au passage du point chaud des Canaries (c) une accrétion asymétrique. / The NE American margin represents one of the best studied margins in the world, it was the subject of several scientific programs. In comparison, the conjugate NW African margin remains fairly unknown, only two deep seismic cruises were acquired: the SISMAR cruise (2001) offshore the Meseta and the DAKHLA cruise (2002) offshore the Sahara. The deep structure of the Canadian margin is known due to the SMART wide-angle seismic profiles 1, 2 and 3. The first objective of the MIRROR project was to acquire combined wide-angle and deep reflection seismic data offshore a segment conjugate to the SMART-1 profile. The comparison between the homologous segments of these two margins aimed to better understand the opening mechanism of the Central Atlantic Ocean. A comparison between Sismar, Dakhla and Mirror models shows that the continental crust is thicker in the north and thins toward the south. The width of the transition zone is narrower south and Sismar profiles are located on a sedimentary basin placed on a very thinned continental crust. Comparing the Mirror profile with that of the Canadian conjugate margin (Smart 1) shows that the thickness, the structure of the continental crust and the thinning is very similar. However, zones of exhumed and serpentinized mantle were imaged along the Canadian profile that have no conjugate on the African margin. Moreover, the thickness of the oceanic crust is variable with 8 km on the African side and only 3-4 km on the Canadian margin. Several hypotheses have been proposed to explain this difference (a) an age difference between the two types of crust (b) thickening associated with the passage of the Canary hotspot (c) an asymmetric accretion or (d) an accretion at slow to ultra-slow speading centers.

Marge NO-Africaine

Structures profondes

Sismique-réflexion marine

Sismique grand-angle

NW African margin

NE American margin

Deep crustal structure

Wide-angle seismic

Reflection seismic

Passive margins

Plate reconstruction

Arcabouço crustal profundo da parte Centro-Norte da margem de Angola: modelo de afinamento e contato de crostas / Deep crustal framework of North-Central margin of Angola: a model for thinning and crustal transition

Luiz Carlos Lucena Empinotti

27 October 2011

Este trabalho tem como objetivo a identificação de feições que permitam (1) a construção do arcabouço crustal profundo e da porção superior do manto em parte da Costa de Angola, (2) a comparação deste arcabouço com o embasamento aflorante e (3) a tentativa de adequar estes resultados aos modelos de ruptura continental já publicados. Para alcançar estes objetivos foi feita a interpretação de cinco linhas sísmicas de reflexão profundas (25 Km de profundidade) na costa de Angola, nas Bacias de Kwanza e Baixo Congo, adquiridas pela ION-GXT. As feições identificadas na sísmica de reflexão auxiliaram na determinação dos limites da crosta continental superior e inferior, no reconhecimento das camadas que compõem a crosta oceânica e na identificação da Descontinuidade de Mohorovicic (que marca o limite entre crosta e manto). A interpretação sísmica associada a dados da literatura (que proporcionaram valores de densidade para os pacotes identificados na interpretação sísmica) permitiram a realização de uma modelagem gravimétrica que foi comparada ao dado gravimétrico adquirido durante a aquisição sísmica. A modelagem gravimétrica serviu para validar a interpretação sísmica, atuando como um controle de qualidade para a interpretação. Caso a anomalia gravimétrica gerada pela modelagem não estivesse de acordo com a anomalia medida, a interpretação sísmica era revista na tentativa de um melhor ajuste entre o resultado modelado e o medido. Este ajuste, no entanto, sempre foi feito honrando os refletores que estavam bem marcados na sísmica. Somado a isto, ainda foi utilizado o dado magnético adquirido no campo, no auxilio da interpretação. O arcabouço crustal obtido com a utilização deste método permitiu a comparação dos resultados da interpretação com os modelos de evolução de margens passivas existentes na literatura, mostrando muitos pontos em comum aos modelos que defendem a possibilidade de ocorrência de manto exumado em margens passivas pobres em magmatismo. A interpretação final destes dados mostrou um domínio proximal marcado por uma crosta continental espessa porém pouco afinada em contato com um domínio distal marcado por uma crosta continental muito afinada (crosta hiper-estirada) e, em direção ao centro do oceano, uma região em que ocorre a exumação do manto. A passagem do domínio proximal para o distal ocorre de forma rápida em uma região denominada Zona de Estrangulamento. À oeste do manto exumado é possível identificar a crosta oceânica. O cruzamento dos resultados obtidos neste trabalho com dados do embasamento aflorante no continente africano sugerem um controle do deste nos valores finais de afinamento da crosta continental sob a bacia e nas regiões de manto exumado. Trabalhos recentes realizados na costa de Angola e do Brasil mostram feições semelhantes às identificadas nesta dissertação. / The main objectives of this study are to identify features on seismic data that allow (1) the building of a deep crustal framework and of the upper portion of the mantle, in part of the Angolan margin; (2) to compare this framework with the adjacent outcropping basement of the African continent and; (3) to try to fit these results to the published continental breakup models. In order to achieve these objectives, five deep reflection seismic lines (25 km of depth) situated in the in Kwanza and Lower Congo Basins on the passive margin of Angola were interpreted. The features identified on seismic were useful to recognize the tripartite division that caracterize the oceanic crust and in defining the Mohorovicic Discontinuity (that represents the limit between crust and mantle). The seismic interpretation associated with the data obtained from the scientific literature (that provided density values for the packages identified on seismic interpretation) allowed the establishment of a gravity modeling that was compared to the gravity data acquired during the seismic acquisition. The gravity model was useful to validate the seismic interpretation, acting as a quality control of the latter. In case of the gravity anomaly generated by the modeling not being in accordance with the measured anomaly, the seismic interpretation was revised in order to obtain a better adjustment between the modeled and the measured result. This adjustment, however, was always done honoring the reflectors that were clearly positioned on seismic. In addition, the magnetic data acquired on the field was used to help on interpretation. The crustal framework obtained by the methodology described above was compared with the passive margin evolution models found on scientific literature, showing some points in common with the models that postulate the occurrence of exhumed mantle in magma-poor passive margins. The final interpretation of these data showed the existence of a proximal domain characterized by a thick continental crust slightly thinned in contact with a distal domain marked by a hyper-extended continental crust. Oceanwards there is a region where the exhumation of the mantle took place. The passage of the proximal to the distal domain is abrupt, here termed as a Necking Zone. Oceanic crust is identified to the west of exhumed mantle. The comparison of the results obtained in this study with data from the outcropping basement on the African continent suggests a basement control on the vales of continental crust thinning attained under the basins and on the regions of exhumed mantle. Recent works done on the Angolan and Brazilian margins show features similar to the ones identified on this dissertation.

Arcabouço crustal

Sísmica profunda de reflexão

Modelagem gravimétrica

Modelo de ruptura continental

Margem passiva

Manto exumado

Angola

Crustal structures

Deep seismic reflection

Gravity modeling

Continental breakup models

Passive margins

Exhumed mantle

Angola

GEOLOGIA