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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Arctic Ocean
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Barents Sea (3)
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Norwegian Sea
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More Basin (1)
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Voring Basin (2)
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Arctic region
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Greenland (1)
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Atlantic Ocean
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North Atlantic
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North Sea
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Viking Graben (1)
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Central Graben (1)
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Europe
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Pyrenees (1)
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Western Europe
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Scandinavia
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Norway (3)
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Lusitanian Basin (1)
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commodities
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bitumens (1)
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oil and gas fields (2)
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petroleum (5)
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geologic age
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Cenozoic
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Quaternary
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Pleistocene (1)
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Mesozoic
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Cretaceous
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Lower Cretaceous (1)
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Upper Cretaceous
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Cenomanian (1)
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Turonian (1)
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metamorphic rocks
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turbidite (1)
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Primary terms
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Arctic Ocean
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Barents Sea (3)
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Norwegian Sea
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More Basin (1)
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Voring Basin (2)
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Arctic region
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Greenland (1)
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Atlantic Ocean
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North Atlantic
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North Sea
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Viking Graben (1)
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bitumens (1)
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Cenozoic
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Quaternary
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Pleistocene (1)
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continental shelf (3)
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data processing (1)
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deformation (1)
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Europe
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Pyrenees (1)
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Western Europe
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Scandinavia
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Norway (3)
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faults (1)
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folds (1)
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geophysical methods (2)
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ground water (1)
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Mesozoic
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Cretaceous
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Lower Cretaceous (1)
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Upper Cretaceous
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Cenomanian (1)
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Turonian (1)
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oil and gas fields (2)
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petroleum (5)
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plate tectonics (1)
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sedimentary rocks
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chemically precipitated rocks
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evaporites
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salt (1)
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sedimentation (1)
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sediments (1)
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tectonics
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salt tectonics (1)
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sedimentary rocks
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sedimentary rocks
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chemically precipitated rocks
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evaporites
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salt (1)
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turbidite (1)
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sediments
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sediments (1)
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turbidite (1)
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Grinda Graben
Abstract Deep-marine gravity-driven deposits represent one of the more investigated depositional systems owing to their potential interest as targets for exploration and carbon capture and storage activities, as well as an important record of the depositional history of a basin through time. Although the Halten Terrace (Norwegian Sea) is one of the main successful exploration areas, we still have poor understanding of the post-rift Cretaceous interval. Here, 3D seismic reflection and borehole data are integrated to investigate the stratigraphic distribution and sedimentological characteristics of the Cenomanian–Turonian intra Lange Sandstones in the Gimsan Basin and Grinda Graben. The Lange Fm records the deposition in a deep-marine environment of a 1000 m-thick shale unit punctuated by gravity-driven coarse-grained sandstone intervals that are tens of metres-thick and sourced from the Norwegian mainland. The presence of gravity-driven deposits and the deep-marine setting are supported by seismic interpretation, architectural elements and the facies analysis of cored material acquired within the studied stratigraphic interval. Borehole data indicate the presence of both turbidites and hybrid-event beds rich in mud content. The results of this study have implications for understanding the distribution and reservoir potentiality of the Late Cretaceous Lange Fm in the Halten Terrace.
Structural maps of key stratigraphic surfaces that define the base and the ...
Seismic cross sections showing detailed architectures associated with the L...
Stratal slice set B: Lange Formation (see Figure 6 E for relative stratigr...
(A) Northwest-southeast three-dimensional seismic line showing the main str...
Seismic geomorphological analysis and hydrocarbon potential of the Lower Cretaceous Cromer Knoll Group, Heidrun field, Norway
Different examples discussed in the text of areas showing deformation decou...
Analogue modeling of domino-style extensional basement fault systems with prekinematic salt
Ages of Norwegian oils and bitumen based on age-specific biomarkers
Cross-border subsurface geology in the Atlantic Margin and the Barents Sea: an introduction
Abstract Over the last 50 years, the North Sea and the Atlantic Margin and, more recently the Barents Sea, represented key study areas for academic and professionals interested in the exploration for and production of hydrocarbon from the Earth's subsurface. Nowadays, these areas may play a major role in the so-called ‘energy transition’, with the energy industry now seeking to reduce emissions related to hydrocarbon consumption, and leading the development of carbon capture and storage activities, such as the Northern Light project ( https://northernlightsccs.com ). Consequently, there is an increasing interest in advancing our knowledge regarding the stratigraphy, sedimentology and tectonic development of the North Sea, Atlantic Margin and Barents Sea with a cross-border approach.
Abstract A dataset with pore pressures from more than 1000 exploration wells has been used to investigate the dynamics of aquifer systems in the Norwegian Continental Shelf (NCS). Variations in aquifer pressures reflect flow of porewater through permeable rocks over geological time. Strongly overpressured regimes are formed within confined aquifers in subsiding areas, where fluid flow out of the aquifer is controlled by vertical seepage. In transitional pressure regimes, fluid flows within permeable beds towards areas with hydrostatic pressures. In the hydrostatic regime, pressure differences result from density differences due to varying formation water salinity and by hydrocarbon columns. An underpressured regime has been encountered in confined aquifers in the platform areas of the Barents Sea, and is related to net uplift and erosion. In the case studies, pressure differences are interpreted in the context of the relevant pressure regime, and with a dynamic approach where segment boundaries and cap rocks are regarded as low-permeability restrictions rather than barriers. The present distribution of pressure regimes was developed over the last few million years due to rapid Pleistocene sedimentation and erosion processes.