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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Africa
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North Africa
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Egypt (1)
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West African Shield (1)
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Antarctica (1)
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Arctic Ocean
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Asia
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Kazakhstan (1)
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Atlantic Ocean
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Equatorial Atlantic (1)
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Bay of Biscay
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English Channel (3)
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Goban Spur (2)
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Gulf of Mexico (1)
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Jeanne d'Arc Basin (1)
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North Sea (1)
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Porcupine Seabight (1)
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Reykjanes Ridge (1)
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Rockall Bank (1)
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South Atlantic
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Vema Channel (1)
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Walvis Ridge (1)
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Atlantic region (2)
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Central America
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Costa Rica (1)
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Commonwealth of Independent States
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Kazakhstan (1)
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Europe
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Pyrenees
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Southern Europe
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Iberian Peninsula
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Portugal (1)
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Cameros Basin (2)
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Italy
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Variscides (2)
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Grand Banks (1)
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Mediterranean Sea
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North America (1)
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Pacific Ocean
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West Pacific
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Seymour Island (1)
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Southern Ocean
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United States
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Montana (1)
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New Jersey
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Millville New Jersey (1)
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commodities
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barite deposits (1)
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metal ores
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lead ores (2)
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lead-zinc deposits (2)
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silver ores (1)
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elements, isotopes
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carbon
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C-13/C-12 (7)
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isotopes
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radioactive isotopes
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stable isotopes
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Ar-40/Ar-39 (1)
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C-13/C-12 (7)
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Nd-144/Nd-143 (1)
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O-18/O-16 (6)
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S-34/S-32 (1)
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metals
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iron
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ferrous iron (1)
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manganese (1)
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rare earths
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neodymium
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noble gases
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argon
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Ar-40/Ar-39 (1)
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oxygen
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dissolved oxygen (2)
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O-18/O-16 (6)
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sulfur
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S-34/S-32 (1)
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fossils
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Chordata
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Vertebrata
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Tetrapoda
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Amphibia
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Anura (1)
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Reptilia
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Diapsida
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Archosauria
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dinosaurs (1)
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Invertebrata
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Arthropoda
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Mandibulata
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Crustacea
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Ostracoda
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Podocopida (1)
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Cnidaria
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Mollusca
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Cephalopoda
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Protista
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Foraminifera
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Plantae
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Tertiary
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Oligocene
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Paleocene
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Danian (2)
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K-T boundary (6)
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upper Paleocene (1)
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Paleocene-Eocene Thermal Maximum (1)
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Mesozoic
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Cretaceous
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Lower Cretaceous
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Albian (1)
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Upper Cretaceous
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Senonian (2)
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Jurassic
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Precambrian
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sheet silicates
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sulfides
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pyrite (1)
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Primary terms
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absolute age (5)
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Africa
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North Africa
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Egypt (1)
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West African Shield (1)
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Antarctica (1)
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Arctic region
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Greenland ice sheet (1)
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Asia
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Central Asia
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Kazakhstan (1)
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Atlantic Ocean
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Equatorial Atlantic (1)
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English Channel (3)
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Goban Spur (2)
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Gulf of Mexico (1)
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Northeast Atlantic
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Porcupine Seabight (1)
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Reykjanes Ridge (1)
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Rockall Bank (1)
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South Atlantic
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Vema Channel (1)
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Walvis Ridge (1)
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Atlantic region (2)
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barite deposits (1)
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biogeography (3)
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carbon
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C-13/C-12 (7)
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C-14 (1)
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Cenozoic
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Quaternary
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Holocene
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Flandrian (1)
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upper Holocene (1)
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Pleistocene
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upper Pleistocene
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Wurm (1)
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upper Quaternary (2)
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Tertiary
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lower Tertiary (2)
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Neogene
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Miocene (2)
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Paleogene
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Eocene
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lower Eocene (4)
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upper Eocene (1)
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Oligocene
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lower Oligocene (1)
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upper Oligocene (1)
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Paleocene
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lower Paleocene
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Danian (2)
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K-T boundary (6)
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upper Paleocene (1)
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Paleocene-Eocene Thermal Maximum (1)
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Central America
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Costa Rica (1)
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chemical analysis (1)
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Chordata
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Vertebrata
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Amphibia
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Anura (1)
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Reptilia
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Diapsida
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Archosauria
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clay mineralogy (2)
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continental slope (3)
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Deep Sea Drilling Project
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IPOD
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Leg 47
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DSDP Site 398 (1)
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Leg 48
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DSDP Site 400 (1)
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DSDP Site 401 (3)
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DSDP Site 403 (1)
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DSDP Site 405 (1)
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DSDP Site 406 (1)
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Leg 74
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DSDP Site 525 (1)
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Leg 80
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DSDP Site 549 (1)
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Leg 12
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DSDP Site 118 (1)
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deformation (6)
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Cameros Basin (2)
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Italy
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Variscides (2)
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Western Europe
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France
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lherzolite (1)
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volcanic rocks
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flood basalts (1)
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glasses
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volcanic glass (1)
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-
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intrusions (2)
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Invertebrata
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Arthropoda
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Mandibulata
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Crustacea
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Ostracoda
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Podocopida (1)
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-
-
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Cnidaria
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Anthozoa (1)
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Echinodermata
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Crinozoa
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Crinoidea (1)
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Echinozoa
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Echinoidea (1)
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-
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Mollusca
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Bivalvia
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Ostreoidea (1)
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Pterioida
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Pteriina
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Inocerami
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Inoceramidae
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Inoceramus (1)
-
-
-
-
-
-
Cephalopoda
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Ammonoidea
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Ammonites (1)
-
-
-
-
Protista
-
Foraminifera
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Rotaliina
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Buliminacea
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Bulimina (1)
-
-
-
-
Radiolaria (1)
-
Silicoflagellata (1)
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Tintinnidae
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Calpionellidae (1)
-
-
-
-
isotopes
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radioactive isotopes
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Ar-40/Ar-39 (1)
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C-14 (1)
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stable isotopes
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Ar-40/Ar-39 (1)
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C-13/C-12 (7)
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Nd-144/Nd-143 (1)
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O-18/O-16 (6)
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S-34/S-32 (1)
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mantle (3)
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maps (4)
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marine geology (5)
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Mediterranean Sea
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West Mediterranean
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Gulf of Lion (1)
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Mesozoic
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Cretaceous
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Lower Cretaceous
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Albian (1)
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Aptian (2)
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Berriasian (1)
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Upper Cretaceous
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K-T boundary (6)
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Maestrichtian
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lower Maestrichtian (1)
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upper Maestrichtian (1)
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Senonian (2)
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Turonian
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lower Turonian (1)
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-
-
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Jurassic
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Lower Jurassic (1)
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Middle Jurassic (1)
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Upper Jurassic
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Tithonian (1)
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Triassic
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Lower Triassic (1)
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metal ores
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lead ores (2)
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lead-zinc deposits (2)
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silver ores (1)
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zinc ores (2)
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metals
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alkaline earth metals
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barium (1)
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magnesium (1)
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strontium (1)
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iron
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ferric iron (1)
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ferrous iron (1)
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-
manganese (1)
-
rare earths
-
neodymium
-
Nd-144/Nd-143 (1)
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-
-
-
metamorphic rocks
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cataclasites (1)
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gneisses
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orthogneiss (1)
-
-
granulites (3)
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-
metamorphism (3)
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mineral deposits, genesis (2)
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noble gases
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argon
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Ar-40/Ar-39 (1)
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North America (1)
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ocean circulation (2)
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Ocean Drilling Program
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Leg 113
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ODP Site 689 (1)
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ODP Site 690 (1)
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Leg 162
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ODP Site 983 (1)
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Leg 174AX
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Millville Site (1)
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Leg 198
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ODP Site 1209 (1)
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ocean floors (14)
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ocean waves (2)
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oceanography (17)
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orogeny (8)
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oxygen
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dissolved oxygen (2)
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O-18/O-16 (6)
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Pacific Ocean
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North Pacific
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Northwest Pacific
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Shatsky Rise (1)
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West Pacific
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Northwest Pacific
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Shatsky Rise (1)
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paleoclimatology (15)
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paleoecology (12)
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paleogeography (9)
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paleomagnetism (1)
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paleontology (4)
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Paleozoic
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Permian
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Upper Permian (1)
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petroleum (1)
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petrology (1)
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Plantae
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algae
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Chlorophyta
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Charophyta (1)
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nannofossils (2)
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plate tectonics (18)
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Precambrian
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upper Precambrian
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reefs (1)
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Bay of Biscay
Early, far-field and diffuse tectonics records in the North Aquitaine Basin (France)
New Magnetic compilation and interpretation of the Bay of Biscay and surrounding continental shelves
The role of extensional detachment systems in thinning the crust and exhuming granulites: analogies between the offshore Le Danois High and the onshore Labourd Massif in the Biscay/Pyrenean rifts
The role of inheritance in forming rifts and rifted margins and building collisional orogens: a Biscay-Pyrenean perspective
Photosymbiosis in planktonic foraminifera across the Paleocene–Eocene thermal maximum
Syndepositional processes in the pigmentation of oceanic red beds: evidence from the Basque–Cantabrian Basin (northern Spain)
Formation of the Alpine Orogen by Amagmatic Convergence and Assembly of Previously Rifted Lithosphere
Post-orogenic exhumation in the western Pyrenees: evidence for extension driven by pre-orogenic inheritance
Brittle tectonics and fluids overpressure during the early stage of the Bay of Biscay opening in the Jard-sur-Mer area, (northern Aquitaine Basin, France)
Initiation and evolution of knickpoints and their role in cut-and-fill processes in active submarine channels
Enhanced surface melting of the Fennoscandian Ice Sheet during periods of North Atlantic cooling
Tectonic inversion of salt-detached ramp-syncline basins as illustrated by analog modeling and kinematic restoration
Predation on feather stars by regular echinoids as evidenced by laboratory and field observations and its paleobiological implications
Abstract: Salt is mechanically weaker than other sedimentary rocks in rift basins. It commonly acts as a strain localizer, and decouples supra- and sub-salt deformation. In the rift basins discussed in this paper, sub-salt faults commonly form wide and deep ramp synclines controlled by the thickness and strength of the overlying salt section, as well as by the shapes of the extensional faults, and the magnitudes and slip rates along the faults. Upon inversion of these rift basins, the inherited extensional architectures, and particularly the continuity of the salt section, significantly controls the later contractional deformation. This paper utilizes scaled sandbox models to analyse the interplay between sub-salt structures and supra-salt units during both extension and inversion. Series 1 experiments involved baseline models run using isotropic sand packs for simple and ramp-flat listric faults, as well as for simple planar and kinked planar faults. Series 2 experiments involved the same fault geometries but also included a pre-extension polymer layer to simulate salt in the stratigraphy. In these experiments, the polymer layer decoupled the extensional and contractional strains, and inhibited the upwards propagation of sub-polymer faults. In all Series 2 experiments, the extension produced a synclinal hanging-wall basin above the polymer layer as a result of polymer migration during the deformation. During inversion, the supra-polymer synclinal basin was uplifted, folded and detached above the polymer layer. Changes in thickness of the polymer layer during the inversion produced primary welds and these permitted the sub-polymer deformation to propagate upwards into the supra-salt layers. The experimental results are compared with examples from the Parentis Basin (Bay of Biscay), the Broad Fourteens Basin (southern North Sea), the Feda Graben (central North Sea) and the Cameros Basin (Iberian Range, Spain).
Comparison of supervised and unsupervised automatic classification methods for sediment types mapping using multibeam echosounder and grab sampling
Abstract We use the Bay of Biscay and Western Pyrenees as a natural laboratory to develop and apply an approach to characterize and identify distinctive rifted margin domains in offshore and onshore settings. The Bay of Biscay and Western Pyrenees offer access to seismically imaged, drilled and exposed parts of one and the same hyperextended rift system. Offshore, we use gravity inversion and flexural backstripping techniques combined with seismic interpretation to provide estimates of accommodation space, crustal thickness and lithosphere thinning. Onshore, we focus on key outcrops of the former rift domain to describe the nature of sediment and basement rocks, and of their interface. This qualitative and quantitative characterization provides diagnostic elements for the identification of five distinct structural domains at magma-poor rifted margins and their fossil analogues (proximal, necking, hyperthinned, exhumed mantle and oceanic domains). This new approach can be used to reconcile offshore and onshore observations, and to aid interpretation when only local observations are available. Onshore remnants can be placed in an offshore rifted-margin context, enabling the prediction of first-order crustal architecture. For the interpretation of offshore seismic reflection sections, geological insights into rift structures and basement nature can be suggested based on onshore analogies. Supplementary material: Sensitivity of backstripping results to flexural rigidity is available at http://www.geolsoc.org.uk/SUP18778 .
The geological extinction record: History, data, biases, and testing
The geological record represents the only source of data available for documenting long-term historical patterns of extinction intensity and extinction susceptibility. Such data are critical for testing hypotheses of extinction causality in the modern world as well as in deep time. The study of extinction is relatively new. Prior to 1800, extinctions were not accepted as a feature of the natural environment. Even after extinctions were recognized to have occurred in Earth's geological past, they were deemed to have played a minor role in mediating evolutionary processes until the 1950s. Global extinction events are now recognized as having been a recurring feature of the history of life and to have played an important role in promoting biotic diversification. Interpretation of the geological extinction record is rendered complex as a result of several biasing factors that have to do with the spatial and temporal resolutions at which the data used to study extinctions have been recorded: fluctuations in sediment accumulation rates, the presence of hiatuses in the stratigraphic sections/cores from which fossils are collected, and variation in the volumes of sediments that can be searched for fossils of different ages. The action of these factors conspires to render the temporal and geographic records of fossil occurrences incomplete in many local stratigraphic sections and cores. In some cases, these stratigraphic and sampling uncertainties can be quantified and taken into account in interpretations of that record. However, their effects can never be eliminated entirely. Testing hypotheses of global extinction causality requires acknowledgment of the uncertainties inherent in extinction data, the search for unique predictions of historical patterns of variation or associations that can, in principle, be preserved in the fossil record and tied logically to the operation of specific causal processes, and to adoption of an explicitly comparative approach that establishes the presence of multiple instances of the predicted cause-effect couplets within a well-documented chronostratigraphic context.
Atmospheric halogen and acid rains during the main phase of Deccan eruptions: Magnetic and mineral evidence
Environmental changes linked to Deccan volcanism are still poorly known. A major limitation resides in the paucity of direct Deccan volcanism markers and in the geologically short interval where both impact and volcanism occurred, making it hard to evaluate their contributions to the mass extinction. We investigated the low-magnetic-susceptibility interval just below the iridium-rich layer of the Bidart (France) section, which was recently hypothesized to be the result of paleoenvironmental perturbations linked to paroxysmal Deccan phase 2. Results show a drastic decrease of detrital magnetite and presence of scarce akaganeite, a hypothesized reaction product formed in the aerosols derived from reaction of a volcanic plume with water and oxygen in the high atmosphere. A weathering model of the consequences of acidic rains on a continental regolith reveals nearly complete magnetite dissolution after ~31,000 yr, which is consistent with our magnetic data and falls within the duration of the Deccan phase 2. These results highlight the nature and importance of the Deccan-related environmental changes leading up to the end- Cretaceous mass extinction.