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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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Beaufort Sea (1)
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Chukchi Sea (1)
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Arctic region
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Arctic Coastal Plain (1)
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North America
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Disturbed Belt (1)
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North Slope (4)
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United States
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Alaska
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Arctic National Wildlife Refuge (4)
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Brooks Range
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Sadlerochit Mountains (2)
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Demarcation Point Quadrangle (1)
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Mount Michelson Quadrangle (1)
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commodities
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petroleum
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natural gas (2)
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fossils
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Invertebrata
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Arthropoda
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Mandibulata
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Neoptera
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Primary terms
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Arctic Ocean
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Beaufort Sea (1)
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Arctic region
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Arctic Coastal Plain (1)
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Greenland
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East Greenland (1)
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Svalbard (1)
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Canada
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Arctic Archipelago (2)
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Nunavut
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Ellesmere Island (1)
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Queen Elizabeth Islands
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Ellesmere Island (1)
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Western Canada
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Northwest Territories (1)
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Yukon Territory (2)
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Cenozoic
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crust (2)
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deformation (3)
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inclusions
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fluid inclusions (1)
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Invertebrata
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Arthropoda
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Mandibulata
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Insecta
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Pterygota
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Neoptera
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Endopterygota
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Coleoptera (1)
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Mesozoic
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Cretaceous
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Lower Cretaceous (2)
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Jurassic
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Kingak Shale (1)
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Lower Jurassic (1)
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Middle Jurassic (1)
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Triassic
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Shublik Formation (2)
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Upper Triassic
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Sag River Sandstone (1)
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metamorphic rocks
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metasedimentary rocks (1)
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North America
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Disturbed Belt (1)
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orogeny (1)
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paleoclimatology (1)
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paleogeography (1)
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Endicott Group (1)
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Permian
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Echooka Formation (1)
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petroleum
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United States
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Alaska
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Arctic National Wildlife Refuge (4)
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Brooks Range
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Sadlerochit Mountains (2)
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Demarcation Point Quadrangle (1)
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Mount Michelson Quadrangle (1)
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Seward Peninsula (1)
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rock formations
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Ivishak Formation (1)
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Sadlerochit Group (1)
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sedimentary rocks
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sedimentary rocks
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clastic rocks
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sandstone (1)
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siliciclastics (1)
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sediments
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Niguanak High
Abstract Beneath the Arctic coastal plain (commonly referred to as "the 1002 area") in the Arctic National Wildlife Refuge, northeastern Alaska, United States, seismic reflection data show that the northernmost and youngest part of the Brookian orogen is preserved as a Paleogene to Neogene system of blind and buried thrust-related structures. These structures involve Proterozoic to Miocene (and younger?) rocks that contain several potential petroleum reservoir facies. Thermal maturity data indicate that the deformed rocks are mature to overmature with respect to hydrocarbon generation. Oil seeps and stains in outcrops and shows in nearby wells indicate that oil has migrated through the region; geochemical studies have identified three potential petroleum systems. Hydrocarbons that were generated from Mesozoic source rocks in the deformed belt were apparently expelled and migrated northward in the Paleogene, before much of the deformation in this part of the orogen. It is also possible that Neogene petroleum, which was generated in Tertiary rocks offshore in the Arctic Ocean, migrated southward into Neogene structural traps at the thrust front. However, the hydrocarbon resource potential of this largely unexplored region of Alaska’s North Slope remains poorly known. In the western part of the 1002 area, the dominant style of thin-skinned thrusting is that of a passive-roof duplex, bounded below by a detachment (floor thrust) near the base of Lower Cretaceous and younger foreland basin deposits and bounded above by a north-dipping roof thrust near the base of the Eocene. East-west-trending, basement-involved thrusts produced the Sadlerochit Mountains to the south, and buried, basement-involved thrusts are also present north of the Sadlerochit Mountains, where they appear to feed displacement into the thin-skinned system. Locally, late basement-involved thrusts postdate the thin-skinned thrusting. Both the basement-involved thrusts and the thin-skinned passive-roof duplex were principally active in the Miocene. In the eastern part of the 1002 area, a northward-younging pattern of thin-skinned deformation is apparent. Converging patterns of Paleocene reflectors on the north flank of the Sabbath syncline indicate that the Aichilik high and the Sabbath syncline formed as a passive-roof duplex and piggyback basin, respectively, just behind the Paleocene deformation front. During the Eocene and possibly the Oligocene, thin-skinned thrusting advanced northward over the present location of the Niguanak high. A passive-roof duplex occupied the frontal part of this system. The Kingak and Hue shales exposed above the Niguanak high were transported into their present structural position during the Eocene to Oligocene motion on the long thrust ramps above the present south flank of the Niguanak high. Broad, basement-cored subsurface domes (Niguanak high and Aurora dome) formed near the deformation front in the Oligocene, deforming the overlying thin-skinned structures and feeding a new increment of displacement into thin-skinned structures directly to the north. Deformation continued through the Miocene above a detachment in the basement. Offshore seismicity and Holocene shortening documented by previous workers may indicate that contractional deformation continues to the present day.
Crustal insights from gravity and aeromagnetic analysis: Central North Slope, Alaska
Arctic North American seasonal temperatures from the latest Miocene to the Early Pleistocene, based on mutual climatic range analysis of fossil beetle assemblages
Toward a better understanding of northern Alaska’s petroleum systems: Deconstructing the Barrow arch
Out-of-sequence, basement-involved structures in the Sadlerochit Mountains region of the Arctic National Wildlife Refuge, Alaska: Evidence and implications from fission-track thermochronology
Deformation and the timing of gas generation and migration in the eastern Brooks Range foothills, Arctic National Wildlife Refuge, Alaska
Multiple Phases of Tertiary Uplift and Erosion in the Arctic National Wildlife Refuge, Alaska, Revealed by Apatite Fission Track Analysis
Detrital geochronology of pre-Mississippian strata in the northeastern Brooks Range, Alaska: Insights into the tectonic evolution of northern Laurentia
Abstract The Pliocene ( c. 5.3–1.8 Myr BP) was the last epoch of geological time in which global temperatures were generally higher than modern. It is important if we are to understand the dynamics of warm climates. This is particularly true of the interaction of climate and cryosphere, where the Pliocene may represent the first epoch in which ice sheets, at least on Antarctica, were a permanent feature. In this paper, we review the available evidence for the state of ice sheets during the Pliocene as well as previous attempts to model them. We then present new models and sensitivity studies of the mid-Pliocene East Antarctic Ice Sheet (EAIS) and consider the implications for the debate on ice-sheet stability during the Pliocene. These new reconstructions suggest that the mid-Pliocene EAIS was significantly smaller than modern, but the modelled average mid-Pliocene climate is not sufficient to cause the widespread deglaciation suggested by Sirius Group diatom evidence.