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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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Norwegian Sea
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Haltenbanken (1)
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Atlantic Ocean
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North Atlantic
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North Sea
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East Shetland Basin (3)
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Oseberg Field (1)
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Viking Graben (5)
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Atlantic Ocean Islands
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Shetland Islands (1)
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Europe
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Western Europe
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Scandinavia
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Denmark (2)
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Norway (1)
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United Kingdom
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Great Britain
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England (1)
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Scotland
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Shetland Islands (1)
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North Sea region (2)
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commodities
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oil and gas fields (6)
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petroleum (7)
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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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fossils
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Invertebrata
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Porifera (1)
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Protista
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Foraminifera (1)
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microfossils (2)
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Plantae
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algae
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diatoms (1)
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geologic age
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Cenozoic
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Quaternary
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Holocene
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Boreal (1)
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Tertiary
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Paleogene
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Eocene (1)
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Oligocene (1)
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Paleocene (1)
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Mesozoic
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Cretaceous
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Viking Formation (1)
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Jurassic
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Heather Formation (3)
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Lower Jurassic
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Dunlin Group (11)
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Hettangian (1)
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lower Liassic (1)
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middle Liassic (1)
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Pliensbachian (2)
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Sinemurian (2)
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Toarcian (1)
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Middle Jurassic
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Bajocian
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Brent Group (7)
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Broom Formation (2)
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Etive Formation (1)
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Ness Formation (2)
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Rannoch Formation (2)
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Tarbert Formation (2)
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Upper Jurassic
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Kimmeridge Clay (1)
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Statfjord Formation (3)
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Triassic
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Upper Triassic
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Norian (1)
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Rhaetian (1)
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minerals
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silicates
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framework silicates
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feldspar group
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plagioclase (1)
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silica minerals
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opal
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opal-CT (1)
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quartz (1)
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sheet silicates
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clay minerals
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smectite (1)
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illite (1)
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Primary terms
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Arctic Ocean
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Norwegian Sea
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Haltenbanken (1)
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Atlantic Ocean
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North Atlantic
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North Sea
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East Shetland Basin (3)
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Oseberg Field (1)
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Viking Graben (5)
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Atlantic Ocean Islands
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Shetland Islands (1)
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carbon
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C-13/C-12 (1)
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Cenozoic
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Quaternary
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Holocene
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Boreal (1)
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Tertiary
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Paleogene
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Eocene (1)
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Oligocene (1)
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Paleocene (1)
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data processing (1)
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diagenesis (1)
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Europe
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Western Europe
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Scandinavia
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Denmark (2)
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Norway (1)
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United Kingdom
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Great Britain
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England (1)
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Scotland
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Shetland Islands (1)
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-
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faults (2)
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geochemistry (1)
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geophysical methods (3)
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Invertebrata
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Porifera (1)
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Protista
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Foraminifera (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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Mesozoic
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Cretaceous
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Viking Formation (1)
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Jurassic
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Heather Formation (3)
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Lower Jurassic
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Dunlin Group (11)
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Hettangian (1)
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lower Liassic (1)
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middle Liassic (1)
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Pliensbachian (2)
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Sinemurian (2)
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Toarcian (1)
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Middle Jurassic
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Bajocian
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Brent Group (7)
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Broom Formation (2)
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Etive Formation (1)
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Ness Formation (2)
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Rannoch Formation (2)
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Tarbert Formation (2)
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Upper Jurassic
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Kimmeridge Clay (1)
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Statfjord Formation (3)
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Triassic
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Upper Triassic
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Norian (1)
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Rhaetian (1)
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oil and gas fields (6)
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oxygen
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O-18/O-16 (1)
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paleoecology (1)
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paleogeography (1)
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petroleum (7)
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Plantae
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algae
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diatoms (1)
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plate tectonics (1)
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sea-level changes (1)
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sedimentary rocks
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carbonate rocks (1)
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clastic rocks
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mudstone (2)
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sandstone (3)
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shale (2)
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siltstone (2)
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sedimentary structures
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biogenic structures
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bioturbation (1)
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sedimentation (1)
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stratigraphy (1)
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well-logging (1)
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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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carbonate rocks (1)
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clastic rocks
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mudstone (2)
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sandstone (3)
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shale (2)
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siltstone (2)
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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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Dunlin Group
The use of a multi-sensor core scanner workflow as the backbone of a digital core repository
Abstract A core repository is a physical record of a country's or commercial organization's subsurface wealth. Some of the largest core repositories hold thousands of kilometres of core material and it is a challenge to turn this physical archive into an accessible digital resource for all. Non-destructive multi-sensor core logger, hyperspectral and X-ray imaging techniques offer a unique chance to rescue valuable data trapped within core samples, improving the way that a core repository delivers data to academic or industrial end users. Here we present a case study of an archived petroleum core acquired in 1985 at the Osprey Field, UK Continental Shelf. Data from the UK National Data Repository are augmented by a multi-sensor core logger, hyperspectral and X-ray dataset that is uploaded into a cloud-based digital repository. The data were analysed using a multi-variant analysis to reclassify the original lithological interpretations, uncovering a greater proportion of clay and cemented horizons than was previously interpreted. A workflow is established to optimize the use of legacy cores and exploit the abundance of data trapped within the core repository using continuous multi-sensor core scanning and imaging data, which are stored within the virtual environment for visualization and access to all.
Abstract This chapter describes Lower Jurassic second-order sequences J00 and J10, and their component third-order sequences J1–J6 and J12–J18. Two sequences (J1 and J3) are new, four sequences (J2, J4, J12 and J16) are amended and one sequence (J17) is renamed. A significant unconformity at the base of the J12 sequence (Upper Sinemurian) is present near the base of the Dunlin Group in the North Viking Graben–East Shetland Platform and in the Danish Central Graben, and correlates with an equivalent unconformity around the margins of the London Platform, onshore UK. A marked unconformity at the base of the J16 sequence is recognized in the North Viking Graben and onshore UK, where it is related to structural movements on the Market Weighton High, eastern England. Several levels of carbon enrichment (carbon isotope excursions (CIEs)) and associated geochemical changes tie to J sequences defining maximum flooding surfaces: the Upper Sinemurian CIE equates to the base J6 maximum flooding surface (MFS), the basal Pliensbachian CIE ties to the base J13 MFS, the basal Toarcian CIE relates to the base J17 MFS and the Toarcian Ocean Anoxic Event corresponds with the base J18 MFS.
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 The Penguins Cluster of fields are owned jointly (50:50) by Shell UK Ltd (Shell) and Esso Exploration and Production UK Ltd (Esso), with Shell as the operator. The cluster was discovered in 1974 and is composed of a combination of oil and gas condensate accumulations located 50–65 km north of the Brent Field, at the northern end of the North Viking Graben. Two main producing reservoirs are present: the Penguins West Field (Penguin A) consists of an Upper Jurassic Magnus Sandstone Member reservoir, while the Penguins East Field (Penguin C, D and E) consists of a Middle Jurassic Brent Group reservoir, underlain by currently undeveloped Statfjord and Triassic (Cormorant) reservoirs. The Magnus reservoir is composed of turbidite sands with an average porosity of 15% and permeabilities of 0.10–300 mD. The Brent reservoirs are composed of deltaic shoreface deposits with an average porosity of 14% and permeabilities of 0.01–1000 mD. The fields were brought on stream in 2003 as a subsea development via what at the time was the world's longest comingled tieback to the Brent Charlie facility. A total of nine producing wells have been drilled from four subsea manifolds, producing c. 78 MMboe to date through depletion drive.