Michel López scite author profile

Based on high-resolution 3D seismic data sets, we document the subsurface reservoir architecture and organization of a portion of the Oligocene-Miocene stratigraphy within the Congo Basin, offshore southwestern Africa. Within the 3D seismic volume, we have identified four levels of turbiditic palaeochannels, which are separated by low-amplitude continuous reflectors interpreted as hemipelagic sediments. Geochemical analyses on sediment samples taken within overlying seafloor pockmarks reveal the presence of thermogenic gases and oils, suggesting that deep-seated fluids have migrated through both the channel deposits and the impermeable layers between them, forming a conduit to the surface. Deep thermogenic fluids produced within Cretaceous source rocks are preferentially entrapped within coarse-grained turbiditic Oligocene-Miocene palaeochannels. We show in this study that the vertical stacking pattern of turbiditic palaeochannels allows the best pathway for fluids migration. Once the fluids migrate to the upper layer (i.e., Upper Miocene) of palaeochannels, they can reach the seafloor via migration along a highly faulted interval composed of polygonal faults. They are temporarily inhibited below an interpreted 300-m-thick gas hydrate layer marked by a strong BSR on seismic profiles. Fluids accumulate under the hydrate stability zone to form a thick layer of free gas. The generation of excess pore fluid pressure in the free gas accumulation leads to the release of fluids along faults of the highly faulted interval forming pockmarks on the seafloor. Ultimately, we show in this study that fluids are progressively concentrated in the sedimentary column and aligned pockmarks on the seafloor may represent a focused fluid flow from stacked turbiditic palaeochannels.

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Polygonal faults‐furrows system related to early stages of compaction – upper Miocene to recent sediments of the Lower Congo Basin

López

2004

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A new polygonal fault system has been identi¢ed in the Lower Congo Basin.This highly faulted interval (HFI), 700 AE 50 m thick, is characterized by small extensional faults displaying a polygonal pattern in plan view.This kind of fracturing is attributed to volumetric contraction of sediments during early stages of compaction at shallow burial depth. 3-D seismic data permitted the visualization of the progressive deformation of furrows during burial, leading to real fractures, visible on seismic sections at about 78 m below sea£oor.We propose a new geometrical model for volumetrical contraction of mud-dominated sediments. Compaction starts at the water^sediment interface by horizontal contraction, creating furrows perpendicular to the present day slope. During burial, continued shrinkage evolves to radial contraction, generating hexagonal cells of dewatering at 21m below sea£oor.With increasing contraction, several faults generations are progressively initiated from 78 to 700 m burial depth. Numerous faults of the HFI act as highly permeable pathways for deeper £uids.We point out that pockmarks, which represent the imprint of gas, oil or pore water escape on the sea£oor, are consistently located at the triple-junction of three neighbouring hexagonal cells.This is highly relevant for predictive models of the occurrence of seepage structures on the sea£oor and for the sealing capacity of sedimentary cover over deeper petroleum reservoirs.

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Architecture of an active mud-rich turbidite system: The Zaire Fan (Congo–Angola margin southeast Atlantic)

et al. 2003

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Michel López

Geological controls on focused fluid flow associated with seafloor seeps in the Lower Congo Basin

Isolated seafloor pockmarks linked to BSRs, fluid chimneys, polygonal faults and stacked Oligocene–Miocene turbiditic palaeochannels in the Lower Congo Basin

Polygonal faults‐furrows system related to early stages of compaction – upper Miocene to recent sediments of the Lower Congo Basin

Architecture of an active mud-rich turbidite system: The Zaire Fan (Congo–Angola margin southeast Atlantic)

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