Global ETD Search

21	Tectonic, stratigraphic and geomorphic interactions, and mobile evaporite influence, in rift basins Duffy, Oliver January 2012 (has links) This thesis examines how the growth, interaction and linkage of normal faults, and the broader structural styles within rift basins, provide first-order controls upon syn-rift sediment routing and the development of coeval syn-rift stratigraphy. To achieve this, this thesis integrates observations from an area of active extension, alongside the stratigraphic record of an ancient rift basin. The former allows greater insight into sediment erosion, transport and preservation processes during rifting, whereas the latter represents the net depositional history, hence permitting a reconstruction of rift tectono-stratigraphic evolution. Recent advances in the understanding of landscape response to active faulting, have focused predominantly on large-scale rift provinces or where fault segments are widely-spaced across-strike (~15-30 km). As such, the neotectonic portion of this study integrates field and digitial terrain analysis to examine the geomorphic response to active faulting across the Perachora Peninsula (Gulf of Corinth, Central Greece), an uplifting, faulted-terrace setting. Here, the across-strike fault-spacing is small (~2-3 km), allowing fault segments to interact across-strike, and landscape evolution to be driven by a complex configuration of perched, intermittent and marine base-levels. These base-levels have a propensity to switch, with implications for sediment-routing and hanging-wall stratigraphic development. The preservation potential of sub-aerial syn-rift landscapes and basin-fill is extremely low in settings such as Perachora, due to the aggressive headward cannibalisation driven by ongoing tectonic uplift and short downstream distances to terminal base level. The subsurface stratigraphic study examines the Triassic-Jurassic syn-rift stratigraphy of the Danish Central Graben, an area displaying lateral variability in the original thickness and mobility of Late Permian Zechstein evaporites along-strike of the bounding Coffee-Soil Fault System. This setting enables a direct comparison between evaporite-influenced and non- evaporite-influenced rifting at a range of scales. By integrating observations of variability in structural style, with a systematic seismic-stratigraphic analysis of the syn-rift interval, the study documents how interactions between normal fault evolution and mobile evaporites influence: i) the variability in rift basin structural style; ii) the development of stratal geometries; and iii) the nature and location of depositional systems. On a basin-wide scale, the evaporite-influenced rift portions display more prominent fault-related and evaporite-related folding, which in turn controls syn-rift deposition, along with variable degrees of decoupling of basement and cover fault and fold systems. Focusing on the evaporite-influenced Coffee-Soil Fault System, variations in the locations and rates of accommodation generated by both load-driven withdrawal of evaporites up the hanging-wall dip-slope, and fault-related subsidence, provide a critical, and hitherto neglected control upon dip- and strike-oriented variability in hanging-wall stratigraphic architecture. Conceptual models for the development of hanging-wall stratigraphy, incorporating the influence of sediment supply rates upon load-induced evaporite mobilisation, provide a framework which may be used in the analysis of evaporite-influenced border fault systems worldwide. Overall, the findings of this thesis have implications for understanding the controls on spatial and temporal variability in structural style, sediment routing and syn-rift stratigraphic evolution in rift basins. In particular, the study highlights that to determine a deeper understanding of the interactions which determine the evolution of syn-rift stratigraphy, it is essential to examine basin processes in both modern and ancient rift settings, as well as at a range of scales. 551.8
22	Application of 3D Salt Modeling: An Example from the Northeastern Gulf of Mexico Mattson, Adam 01 October 2019 (has links) Salt tectonics has important implications for hydrocarbon exploration in saltbearing basins since salt deformation can directly or indirectly form hydrocarbon traps, influence hydrocarbon migration, and can control deepwater depositional systems. In various basins around the globe, extensive research has been conducted on initiation of salt mobilization, subsequent deformation, and eventual cessation, mostly from subsurface two-dimensional (2D) sections. However, 3D seismic data has dominated the petroleum industry for the last 30 years. Despite the plethora of 3D seismic data acquired in salt-bearing basins, there has been hardly any published work on the 3D geometries of complex salt bodies. 3D salt mapping in the subsurface can reveal true distribution of salt bodies and their detailed intricacies of geometrical variations, aiding in the overall salt system interpretation. Using a large 3D seismic survey (3,350 km2), this study presents the first 3D salt mapping in the Gulf of Mexico, demonstrating how 3D visualization of the entire Louann Salt system within the Middle Jurassic to presentday stratigraphy can improve interpretation of salt feeder geometries, allochthonous salt canopies, initial salt distribution, and salt weld locations in the study area. Gulf of Mexico Salt Tectonics 3D Modeling Geology Geophysics and Seismology Tectonics and Structure
23	Neogene to Quaternary fault activity and salt tectonics within the Terrebonne Salt Withdrawal Basin: effect of sediment loading on subsidence and salt-fault interaction: 1) Quaternary fault activity in the Northwestern margin of the Terrebonne Salt Withdrawal Basin, southeastern Louisiana 2) Spatial and Temporal Throw Variation in the Terrebonne Salt Withdrawal Basin: Effects of sediment loading and diapiric stress perturbation 3) Geometry and characteristics of faults connecting two salt stocks: Insights from the Gulf of Mexico January 2021 (has links) archives@tulane.edu / Salt basins are complex structural systems, showing genetic relationships between salt structures, faults, and variable sediment depositional patterns. The dynamics of salt-fault interaction, the role of shale deformation, and the influence of salt evacuation on surface features have been poorly understood. A link between all these processes is the throw history of faults adjacent to and within a salt basin. In this dissertation, I interpret industry well logs and 3D seismic data from the Terrebonne Salt Withdrawal Basin (TSWB) of southeastern Louisiana, to understand these processes. The methodology includes the use of fault throw maps, throw variations along strike and with depth, and sediment expansion indices to understand fault kinematics adjacent to sediment loads and mobile material, i.e., salt or shale. I address the histories of three faults along the northern margin of the TSWB: the Lake Boudreaux, Montegut, and Isle de Jean Charles faults. Each shows Miocene and Quaternary active phases correlated with sediment loading, separated by relative inactivity during the Pliocene. The pattern of Quaternary activity and the surface projections of these faults are consistent with a fault-controlled pattern of wetland loss, suggesting that faults in southeastern Louisiana are active. Isle de Jean Charles fault and the Lake Boudreaux fault interact with the Bully Camp and Lake Barre Salt stocks, respectively. Each stock is interpreted to have grown by a different diapiric mechanism, consistent with different spatial patterns of throw variation on the two faults, despite similar temporal histories. Throw on the Isle de Jean Charles fault increases towards the Bully Camp stock, suggesting deformation inside and outside the stock. In contrast, a decrease in the throw on the Lake Boudreaux fault and an increase in diameter of the Lake Barre stock indicate that deformation exists only within the stock. Additionally, this dissertation considers throw patterns along the southern margin of the TSWB, showing that faults linking the Dog Lake and Caillou Island salt stocks are affected by shale deformation adjacent to salt. These results show that studies of fault-related subsidence and wetland loss in coastal Louisiana need to include observations from nearby salt structures. / 1 / Akinbobola Akintomide Salt tectonics in Gulf of Mexico Coastal subsidence and wetland loss Salt-Fault interaction
24	A Geophysical Study of Upper Silurian Salina Group in Northeastern Pennsylvania Harding, Matthew Ryan 26 April 2017 (has links) No description available. Geology Salina Group Salina Silurian Pennsylvania Salt Tectonics Halokinesis Upper Silurian Seismic Alleghanian Appalachian
25	Strain quantifications in different tectonic scales using numerical modelling Fuchs, Lukas January 2016 (has links) This thesis focuses on calculation of finite and progressive deformation in different tectonic scales using 2D numerical models with application to natural cases. Essentially, two major tectonic areas have been covered: a) salt tectonics and b) upper mantle deformation due to interaction between the lithosphere and asthenosphere. The focus in salt tectonics lies on deformation within down-built diapirs consisting of a source layer feeding a vertical stem. Three deformation regimes have been identified within the salt: (I) a squeezing channel flow underneath the overburden, (II) a corner flow underneath the stem, and (III) a pure channel flow within the stem. The results of the model show that the deformation pattern within the stem of a diapir (e.g. symmetric or asymmetric) can reveal information on different rates of salt supplies from the source layer (e.g. observed in Klodowa-diapir, Poland). Composite rock salt rheology results in strong localization and amplification of the strain along the salt layer boundaries in comparison to Newtonian rock salt. Flow and fold structures of passive marker lines are directly correlated to natural folds within a salt diapir. In case of the upper mantle, focus lies on deformation and resulting lattice preferred orientation (LPO) underneath an oceanic plate. Sensitivity of deformation and seismic anisotropy on rheology, grain size (d), temperature (T), and kinematics (v) has been investigated. The results of the model show that the mechanical lithosphere-asthenosphere boundary is strongly controlled by T and less so by v or d. A higher strain concentration within the asthenosphere (e.g. for smaller potential mantle temperatures, higher plate velocities, or smaller d) indicates a weaker coupling between the plate and the underlying mantle, which becomes stronger with the age of the plate. A Poiseuille flow within the asthenosphere, significantly affects the deformation and LPO in the upper mantle. The results of the model show, that deformation in the upper mantle at a certain distance away from the ridge depends on the absolute velocity in the asthenosphere. However, only in cases of a driving upper mantle base does the seismic anisotropy and delay times reach values within the range of natural data. Deformation modelling progressive and finite deformation salt tectonics down-built diapir upper mantle lithosphere-asthenosphere boundary seismic anisotropy plate-mantle (de)coupling
26	An Investigation Into the Origin, Composition, and Commercial Significance of a Sedimentary Subsalt Formation: Keathley Canyon, Gulf of Mexico Brassieur, David Aaron 16 December 2016 (has links) Sub-salt oil and gas formations in deep-water northern Gulf of Mexico are high priority targets. Advances in seismic processing allow for high-resolution, below-salt imaging. Understanding the modes of salt emplacement provide insight into sub-salt traps and potential drilling hazards. A sub-salt sedimentary unit lies in the Keathley Canyon protraction. Autosutures created the transport-parallel lineaments of the upper surface of the unit. In addition, highly variable sediment aggradation rates created ramps, flats, and basal cutoffs along the base of the allochthon as salt and sediment competed for space. Seismic models identify modes of salt emplacement, salt/sediment interactions, and mechanisms responsible for the morphology. Petrophysical assessments highlight an abnormally pressured, dirty salt environment transitioning into a gouge zone. Dirty salt adds an element of difficulty to managing borehole pressures requiring a unique mud-weight plan designed to resist formation pressures without fracturing lithology. diapirism subsalt imaging fracture gradient salt tectonics salt sheet coalescence allosuture Geology Geomorphology Geophysics and Seismology Oil, Gas, and Energy
27	3d Modeling Of Salt Related Structures In The Friesland Platform, The Netherlands Yucel, Kivanc 01 July 2010 (has links) (PDF) Southern North Sea Basin is one of the mature hydrocarbon basins in NW Europe and is shaped by a number of phases of tectonic deformations during the Phanerozoic. In addition, mobilization and halokinesis of thick Permian Zechstein Salt has enhanced and contributed to the deformation of the region since Triassic, which further complicated the geology of the region. The Friesland Platform, which is a stable platform area located in northern Netherlands, experienced the main deformation phases that Europe has been endured together with the deformation of Permian Zechstein salt. In this study a computer based 3D modeling has been carried out within the Friesland Platform with the use of 3D seismic and borehole data in order to delineate structural elements and geological development of the area with special emphasis on the salt tectonic deformation. The model was constructed by picking key horizons and major faults from the seismic sections in time domain and then migrated into depth domain. The stratigraphy of the area is correlated with horizons by well-seismic matching. The model includes major structures and seismostratigraphic units of Permian to recent, revealing salt and salt induced structures formed during the periods of active salt movements. Thick Zechstein salt layers deposited in N-S-oriented grabens and half grabens of South Permian Basin acted as the primary control for the location of salt diapirs and are reflected on the overburden without a direct continuation (unlinked) of the basement faults into the overburden. The mapped N-S oriented salt-cored anticline and a convergent conjugate transfer zone between a pair of segmented normal growth faults at the crest of the anticline are controlled by the ascent of the Zechstein salt.
28	Seismic Facies Classification of an Intraslope Minibasin in The Keathley Canyon, Northern Gulf of Mexico Meroudj, Lamine 09 August 2017 (has links) This work examines several volume attributes extracted from 3D seismic data with the goal of seismic facies classification and lithology prediction in intraslope minibasins. The study area is in the Keathley Canyon protraction (KC), within the middle slope of the Northern Gulf of Mexico (GOM). It lays within the tabular salt and minibasins province downdip of the main Pliocene and Pleistocene deltaic depocenters. Interaction between sedimentation and mobile salt substrate lead to the emergence of many stratigraphic patterns in the intraslope minibasins. Interest in subsalt formations left above salt formations poorly logged. Facies classification using Artificial Neural Network (ANN) was applied in those poorly logged areas. The resultant facies classes were calibrated and used to predict the lithology of the recognized facies patterns in an intraslope minibasin, away from well control. Three types of facies classes were identified: Convergent thinning, convergent baselaping and bypassing. The convergent baselaping are found to be the most sand rich among all other facies. Keathley Canyon, Gulf of Mexico facies classification seismic attributes intraslope minibasins salt tectonics. Geology Geophysics and Seismology Oil, Gas, and Energy
29	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 (has links) 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
30	Spatial Trends and Facies Distribution of the High-Energy Alluvial Cutler Formation, Southeastern Utah Allred, Isaac John 01 June 2016 (has links) The Cutler Formation is composed of thick, arkosic, alluvial conglomerate, sandstone, and mudstone shed southwestward from the Uncompahgre Uplift into the Paradox Basin. More basin-ward the Cutler is recognized as a group consisting of differentiable formations. Discrete formations historically have not been distinguished near the uplift, but this study identified several separate successions in the Richardson Amphitheater. Research at the Richardson Amphitheater, ~12 km southwest of the uplift and ~30 km northeast of Moab, Utah, led to a systematic subdivision of the Permian Cutler Formation proximal to the uplift. Likely driven by channel cutting and migration across the alluvial fan, six 10-20 m thick successions are partially exposed. The dominant observed facies are basal conglomerate and channel-fill trough cross-stratified sandstone overlain by finer-grained distal sheetflood and frequently pedogenically altered sandstone. Down-warping of identified successions and the presence of additional sands within the area of flexure suggest that localized salt withdrawal created a sediment depocenter in the Richardson Amphitheater, ~6 km northwest of the Onion Creek salt diapir. The identified salt withdrawal feature is more proximal to the Uncompahgre Uplift than any of the major documented salt structures in the area and was not previously documented. Six measured stratigraphic sections and hundreds of high-precision differential GPS data points outlining major lateral erosional surfaces form the basis for interpretation. Five mapped erosional surfaces (bounding surfaces based upon differential GPS point interpolation) are laterally extensive within the approximately one square kilometer study area, and as such, represent stratigraphically significant surfaces. Within the generated structural geocellular model, stratigraphic data from measured sections informed facies modeling between major surfaces. This outcrop model may serve as an analogue for subsurface systems deposited in similar settings. Alluvial fan arkosic facies bounding surface Cutler Formation conglomeratic sandstone digital outcrop model fluvial pedogenic carbonate Richardson Amphitheater salt tectonics trough cross-stratified sandstone Utah Geology

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