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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Atlantic Ocean
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North Atlantic
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North Sea
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Brent Field (1)
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East Shetland Basin (3)
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Gullfaks Field (2)
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Oseberg Field (1)
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Viking Graben (5)
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Europe
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Western Europe
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Scandinavia
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Denmark (1)
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Norway (4)
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United Kingdom
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Great Britain
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England
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Yorkshire England (1)
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North Sea region (1)
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United States
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Book Cliffs (1)
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Utah (1)
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commodities
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oil and gas fields (10)
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petroleum
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natural gas (2)
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elements, isotopes
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carbon
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C-13/C-12 (1)
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isotope ratios (1)
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isotopes
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stable isotopes
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C-13/C-12 (1)
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O-18/O-16 (1)
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oxygen
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O-18/O-16 (1)
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geologic age
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Mesozoic
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Cretaceous
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Upper Cretaceous
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Blackhawk Formation (1)
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Jurassic
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Heather Formation (2)
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Lower Jurassic
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Dunlin Group (2)
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Middle Jurassic
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Aalenian (1)
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Bajocian
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Brent Group (14)
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Broom Formation (6)
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Etive Formation (8)
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Ness Formation (8)
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Rannoch Formation (16)
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Tarbert Formation (6)
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Upper Jurassic
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Kimmeridge Clay (2)
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Statfjord Formation (3)
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minerals
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carbonates
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calcite (1)
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Primary terms
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Atlantic Ocean
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North Atlantic
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North Sea
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Brent Field (1)
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East Shetland Basin (3)
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Gullfaks Field (2)
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Oseberg Field (1)
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Viking Graben (5)
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carbon
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C-13/C-12 (1)
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clay mineralogy (2)
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data processing (1)
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diagenesis (7)
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economic geology (1)
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Europe
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Western Europe
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Scandinavia
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Denmark (1)
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Norway (4)
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United Kingdom
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Great Britain
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England
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Yorkshire England (1)
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-
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faults (4)
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fractures (1)
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geophysical methods (4)
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inclusions
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fluid inclusions (1)
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isotopes
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stable isotopes
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C-13/C-12 (1)
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O-18/O-16 (1)
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-
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Mesozoic
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Cretaceous
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Upper Cretaceous
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Blackhawk Formation (1)
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-
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Jurassic
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Heather Formation (2)
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Lower Jurassic
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Dunlin Group (2)
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Middle Jurassic
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Aalenian (1)
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Bajocian
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Brent Group (14)
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Broom Formation (6)
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Etive Formation (8)
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Ness Formation (8)
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Rannoch Formation (16)
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Tarbert Formation (6)
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-
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Upper Jurassic
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Kimmeridge Clay (2)
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-
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Statfjord Formation (3)
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oil and gas fields (10)
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oxygen
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O-18/O-16 (1)
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petroleum
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natural gas (2)
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sea-level changes (3)
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sedimentary petrology (2)
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sedimentary rocks
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clastic rocks
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mudstone (3)
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sandstone (11)
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shale (3)
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siltstone (1)
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sedimentary structures
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biogenic structures
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bioturbation (1)
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planar bedding structures
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bedding (2)
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sand bodies (1)
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United States
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Book Cliffs (1)
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Utah (1)
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weathering (1)
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well-logging (2)
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rock formations
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Nansen Formation (1)
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sedimentary rocks
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sedimentary rocks
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clastic rocks
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mudstone (3)
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sandstone (11)
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shale (3)
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siltstone (1)
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sedimentary structures
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sedimentary structures
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biogenic structures
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bioturbation (1)
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planar bedding structures
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bedding (2)
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sand bodies (1)
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Rannoch Formation
Abstract The most important North Sea Jurassic–lowermost Cretaceous lithostratigraphic units, as developed in the UK, Norway and Danish sectors, are summarized in this chapter (55 units from the UK, 25 from Norway and 10 from Denmark). Some significant issues remain with the use and application of lithostratigraphic terminology in the Jurassic of the North Sea Basin. In particular, there are inconsistencies in unit definition and nomenclature changes across country sector boundaries that obscure the recognition of regional stratigraphic patterns that exist across the region. To aid clarity and to overcome some issues of definition, some revisions are made to the existing lithostratigraphic schemes. Several informal lithostratigraphic units are described, a number of unit definitions are revised and various formerly informal units are formalized (Buzzard Sandstone Member, Ettrick Sandstone Member and Galley Sandstone Member). It is recommended that use of the Heno Formation in offshore Denmark is discontinued. In addition, four new lithostratigraphic member terms are introduced (Home Sandstone Member, North Ettrick Sandstone Member, Gyda Sandstone Member and Tambar Sandstone Member). All described units are placed into a sequence stratigraphic context. All significant lithostratigraphic boundaries conform with key sequence stratigraphic surfaces.
The Dunlin, Dunlin SW, Osprey and Merlin fields, Blocks 211/23 and 211/24, UK North Sea
Abstract Located 160 km NE of the Shetland Islands in the East Shetland Basin, the Dunlin Cluster comprises four produced fields, Dunlin, Dunlin SW, Osprey and Merlin, in addition to some near-field satellite discoveries, Skye and Block 6. Dunlin was discovered in July 1973 and production began in August 1978. The field was developed using a concrete gravity-base platform, Dunlin Alpha, which also served as the production facility for the rest of the Dunlin Cluster. Osprey was discovered in 1974 but not tied-in until January 1991. Dunlin SW was discovered in 1973 but not brought onto production until 1996. Merlin was discovered in February 1997 and tied-in later that same year. Fairfield Energy acquired the Dunlin Cluster in 2008, and a programme of investment and facilities improvements, primarily in fuel gas infrastructure and power generation, sought to boost water-injection rates and bolster production, thereby extending the life of the asset. Ultimately, the Dunlin Cluster ceased production on 15 June 2015 after having maximized economic hydrocarbon recovery. The total Dunlin Cluster production exceeded 500 MMbbl of oil (Dunlin and Dunlin SW, 395 MMbbl oil; Osprey, 92 MMbbl oil; and Merlin, 27 MMbbl oil).
Abstract Wireline and seismic acoustic impedance imaging show that the marine part of the clastic Brent Group reservoir in the Heather Field, northern North Sea, contains much calcite cement in the flank parts of the structure. The non-marine Ness Formation and crest parts of the structure contain negligible calcite cement. This localized calcite cement has led to relatively poor reservoir performance since first oil in 1978, although a new suite of wells has boosted production with plans to keep the field active until 2030. Understanding the origin and distribution of calcite cement would help the development of more realistic reservoir models and boost production rates through optimum well location. We have thus used a suite of techniques, including standard point counting, SEM-EDS mineralogy, BSE microscopy, fluid inclusion thermometry and stable isotope analysis, to develop new and improved models of calcite distribution. Calcite seems to have attributes of both early and late diagenetic cement. A 30–40% intergranular volume in calcite cemented beds seems to support pre-compactional growth but high-temperature fluid inclusions and the presence of primary oil inclusions suggest late growth. Much calcite may have developed early but it seems to have recrystallized, and possibly undergone redistribution, at close to maximum burial or had a late growth event. Calcite cement probably originated as marine-derived micrite, bioclasts or early marine cement but adopted the isotopic characteristics of high-temperature growth as it recrystallized. Quartz grains have corroded outlines in calcite-cemented areas with one sample, with 79% calcite cement, displaying signs of nearly total replacement of quartz grains by calcite. The flank localization of calcite cement remains to be explained, although it could be due to primary depositional factors, early diagenetic loss of calcite from crestal regions or late diagenetic loss of calcite from crestal regions. Controversially, the growth of calcite seems to be associated with quartz dissolution, although the geochemical and petrophysical cause of this remains obscure. Diagenetic loss of quartz from sandstones cannot easily be explained by conventional modelling approaches and yet seems to be an important phenomenon in Heather sandstones.