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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Arctic region
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Greenland
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East Greenland (1)
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Jameson Land (1)
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Asia
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Indian Peninsula
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India
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Andhra Pradesh India (1)
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Chhattisgarh India (1)
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Gujarat India (1)
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Madhya Pradesh India (1)
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Maharashtra India (1)
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Narmada Valley (1)
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Europe
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Central Europe
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Germany (1)
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United States
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Montana (1)
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fossils
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Chordata
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Mammalia
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dinosaurs
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Theropoda (2)
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Thecodontia
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Testudinata (6)
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coprolites (1)
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lower Paleocene
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Tullock Member (1)
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Jurassic
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Primary terms
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Arctic region
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Greenland
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East Greenland (1)
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Jameson Land (1)
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Asia
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Indian Peninsula
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India
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Andhra Pradesh India (1)
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Chhattisgarh India (1)
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Gujarat India (1)
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Madhya Pradesh India (1)
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Maharashtra India (1)
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Narmada Valley (1)
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biogeography (2)
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Cenozoic
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Tertiary
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Paleogene
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Paleocene
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lower Paleocene
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K-T boundary (2)
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Tullock Member (1)
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Chordata
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Vertebrata
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Pisces (1)
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Tetrapoda
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Amphibia
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Labyrinthodontia
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Temnospondyli (1)
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Mammalia
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Theria
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Eutheria (1)
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Reptilia
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Anapsida
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Testudines
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Chelonia (1)
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Cryptodira (1)
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Diapsida
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Archosauria
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Crocodilia (1)
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dinosaurs
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Saurischia
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Sauropodomorpha
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Sauropoda (1)
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Theropoda (2)
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Thecodontia
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Phytosauria (1)
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Testudinata (6)
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climate change (1)
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coprolites (1)
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data processing (1)
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Europe
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Central Europe
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Germany (1)
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ichnofossils (1)
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Mesozoic
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Cretaceous
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Upper Cretaceous
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Hell Creek Formation (1)
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K-T boundary (2)
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Lameta Formation (1)
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Maestrichtian (1)
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Jurassic
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Triassic
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sedimentation (1)
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stratigraphy (1)
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United States
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Montana (1)
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rock formations
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Deccan Traps (1)
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Fort Union Formation (1)
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Intertrappean Beds (1)
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sedimentary structures
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coprolites (1)
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sedimentary structures
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biogenic structures
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stromatolites (1)
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thrombolites (1)
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tracks (1)
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Testudinata
Abstract In Late Triassic (Norian–Rhaetian) times, the Jameson Land Basin lay at 40° N on the northern part of the supercontinent Pangaea. This position placed the basin in a transition zone between the relatively dry interior of the supercontinent and its more humid periphery. Sedimentation in the Jameson Land Basin took place in a lake–mudflat system and was controlled by orbitally forced variations in precipitation. Vertebrate fossils have consistently been found in these lake deposits (Fleming Fjord Formation), and include fishes, dinosaurs, amphibians, turtles, aetosaurs and pterosaurs. Furthermore, the fauna includes mammaliaform teeth and skeletal material. New vertebrate fossils were found during a joint vertebrate palaeontological and sedimentological expedition to Jameson Land in 2012. These new finds include phytosaurs, a second stem testudinatan specimen and new material of sauropodomorph dinosaurs, including osteologically immature individuals. Phytosaurs are a group of predators common in the Late Triassic, but previously unreported from Greenland. The finding includes well-preserved partial skeletons that show the occurrence of four individuals of three size classes. The new finds support a late Norian–early Rhaetian age for the Fleming Fjord Formation, and add new information on the palaeogeographical and palaeolatitudinal distribution of Late Triassic faunal provinces.
During the last two decades, extensive paleontological research in the main Deccan volcanic province has led to a better understanding of biodiversity close to the Cretaceous-Paleogene boundary. Several infratrappean localities exposed in Jabalpur, Kheda, Balasinor, Rahioli, Dohad, and Bagh in the Narmada Valley (India) preserve one of the most geographically widespread dinosaur nesting sites known in the world. The well-studied intertrappean beds, such as those of Naskal on the southern margin, Asifabad and Nagpur on the eastern margin, Kisalpuri and Mohgaon Kalan on the northeastern margin, and Anjar on the northwestern margin of the main Deccan volcanic province, have yielded Maastrichtian fish ( Igdabatis ) and dinosaur remains and palynofossils ( Aquilapollenites - Gabonisporites - Ariadnaesporites ), either separately or in association, that suggest a Maastrichtian age for these beds. Only two intertrappean sections, Papro on the northern margin and Jhilmili on the northeastern margin of the main Deccan volcanic province, have produced Paleocene fossils. The fossil record from the infratrappean and intertrappean beds demonstrates that the dinosaurs survived the early phase of volcanism, though there was an apparent decline in their diversity, and that freshwater vertebrate fauna was least affected by the initial volcanic activity. The episodic nature of Deccan volcanism may possibly explain the survival of many freshwater and terrestrial communities during the periods of quiescence. In addition, as in the case of the late Maastrichtian sections in eastern Montana, North America, detritus-feeding freshwater vertebrate communities possibly had greater potential for survival than the terrestrial communities dependent on primary productivity. A close examination of the vertebrate faunal distribution across the two stratigraphic intervals (infratrappean and intertrappean) suggests that sampling bias in the infratrappean beds may have also masked the actual diversity of these beds.
Temporal changes within the latest Cretaceous and early Paleogene turtle faunas of northeastern Montana
Climate change has been suggested to be a factor in the distribution of reptiles in the Cretaceous and Paleogene, but comparatively few studies have examined the possible role of climate within lithostratigraphically or biostratigraphically constrained local areas. Here, we reexamine the role of climatic change on the distribution of turtles within the Late Cretaceous–earliest Paleogene record of the Hell Creek area of northeastern Montana, where long-term field studies have produced a relatively dense record of faunal change during a period of climatic fluctuation. An improved stratigraphic record allows us to document previously unavailable range data for the Hell Creek–Tullock turtle taxa and assess changes in richness and abundance through approximately the last 1.9 m.y. of the Cretaceous and the first 750 k.y. of the Paleocene and provide revised estimates for survivorship and extinction across the Cretaceous-Paleogene boundary.