ALBERT

Description: Analysis of three-dimensional seismic data from the lower Congo Basin, offshore Angola, reveals numerous fluid-flow features in the Miocene to Holocene succession and the potential for large, shielded traps underneath basinward overhanging salt structures. The fluid-flow evidence includes present-day sea floor pockmarks clustered above salt structures, Pliocene-Pleistocene stacked paleopockmarks and Miocene pockmark fields. Other fluid-flow features include high-amplitude cylindrical pipe structures 60 to 300 m (197-984 ft) wide and 25 to 300 m (82-984 ft) high within lower and middle Miocene strata, thick ( 1 km [0.6 mi] beneath the sea floor). The Miocene pockmark fields occur at a specific horizon, suggesting a regional fluid expulsion event at ca. 12 Ma, and the Miocene fluid-flow regime is interpreted to be dominated by thermogenic fluids supplied via carrier beds and leaking vertically above structural highs. The Pliocene-Pleistocene fluid-flow regime was dominated by short-distance vertical fluid migration and expulsion related to early stage diagenetic processes involving biogenic methane and pore water. The present-day fluid-flow regime is inferred to be dominated by thermogenic fluids primarily controlled by kilometer-scale salt-flank-controlled migration. The study emphasizes the use of seismically imaged fluid-flow features in hydrocarbon systems analysis by documenting the evolution of an overburden plumbing system through time, involving several fluid types and flow regimes, depending on the spatiotemporal availability of thermogenic and diagenetic fluids and the tectonostratigraphic occurrence of aquifers, traps, and seals.

Description: Analysis of three-dimensional seismic data from the lower Congo Basin, offshore Angola, reveals numerous fluid-flow features in the Miocene to Holocene succession and the potential for large, shielded traps underneath basinward overhanging salt structures. The fluid-flow evidence includes present-day sea floor pockmarks clustered above salt structures, Pliocene–Pleistocene stacked paleopockmarks and Miocene pockmark fields. Other fluid-flow features include high-amplitude cylindrical pipe structures 60 to 300 m (197–984 ft) wide and 25 to 300 m (82–984 ft) high within lower and middle Miocene strata, thick (〈150 m [492 ft]) high-reflectivity zones within the Pliocene succession associated with bottom-simulating reflections, and subvertical low-amplitude chimneys originating from the deeper section (〉1 km [0.6 mi] beneath the sea floor). The Miocene pockmark fields occur at a specific horizon, suggesting a regional fluid expulsion event at ca. 12 Ma, and the Miocene fluid-flow regime is interpreted to be dominated by thermogenic fluids supplied via carrier beds and leaking vertically above structural highs. The Pliocene–Pleistocene fluid-flow regime was dominated by short-distance vertical fluid migration and expulsion related to early stage diagenetic processes involving biogenic methane and pore water. The present-day fluid-flow regime is inferred to be dominated by thermogenic fluids primarily controlled by kilometer-scale salt-flank-controlled migration. The study emphasizes the use of seismically imaged fluid-flow features in hydrocarbon systems analysis by documenting the evolution of an overburden plumbing system through time, involving several fluid types and flow regimes, depending on the spatiotemporal availability of thermogenic and diagenetic fluids and the tectonostratigraphic occurrence of aquifers, traps, and seals. Katrine Juul Andresen has B.Sc. (2004) and M.Sc. (2007) degrees in geology (Aarhus University) and is currently finishing her Ph.D. studies at Aarhus University, dealing with the 3-D seismic expression of fluid-flow features that originated in hydrocarbon plumbing systems in the North Sea and the Angola Basin, including a description of elongated and stacked paleopockmarks and sand and chalk remobilization. Mads Huuse is a reader in geophysics at the University of Manchester. After a Ph.D. from Aarhus University (1999), he undertook postdoctoral research at Aarhus, Aberdeen, and Cardiff, focusing on basin analysis, sediment remobilization, and fluid flow, before taking up a lectureship at the University of Aberdeen. His interests include the seismic interpretation of basins, their evolution, structures, depositional elements, reservoirs, seals, and fluids. Niels Schødt is a team lead for Angola Regional Studies and New Ventures at Maersk Oil in Copenhagen. He has an M.Sc. degree in geology (Aarhus University) and has worked in the oil industry since 1989. He started at Schlumberger as a wireline engineer and since 1996 has worked in exploration projects in Maersk Oil, primarily focusing on seismic interpretation. Lene F. Clausen is head of the New Ventures Study Teams in Exploration, Maersk Oil, Copenhagen. She has worked with exploration since 1998 mainly in the North and South Atlantic. She received a graduate diploma in geology in 1991 (Australian National University, Canberra), M.Sc. degree in 1993, and a Ph.D. in 1997 (University of Copenhagen). Lars Seidler is a project manager for the Angolan Chissonga Development at Maersk Oil Houston. Seidler has worked in upstream research, development, and production, starting with ExxonMobil in 2000. Since 2006, he has worked in exploration and development with Maersk Oil. He received a Ph.D. in geology in 1999 (University of Copenhagen).