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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 (1)
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Cascade Range (2)
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Cascadia subduction zone (2)
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Channeled Scabland (1)
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Coast Ranges (11)
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Columbia River (1)
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Pacific Coast (3)
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Pacific Ocean
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East Pacific
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Northeast Pacific (1)
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North Pacific
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Northeast Pacific (1)
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Northwest Pacific (1)
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West Pacific
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Northwest Pacific (1)
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United States
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California
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Northern California (1)
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Idaho Batholith (2)
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Klamath Mountains (5)
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Oregon
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Benton County Oregon (1)
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Coos County Oregon
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Coos Bay (4)
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Curry County Oregon (2)
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Douglas County Oregon (1)
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Klamath County Oregon (1)
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Lane County Oregon (1)
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Lincoln County Oregon
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Newport Oregon (1)
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Mount Hood (1)
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Polk County Oregon (1)
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Rogue River (1)
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Willamette River (1)
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Washington (1)
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Western U.S. (3)
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commodities
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petroleum
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natural gas (1)
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water resources (1)
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elements, isotopes
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carbon
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C-14 (1)
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isotope ratios (1)
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isotopes
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radioactive isotopes
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C-14 (1)
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Pb-206/Pb-204 (1)
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stable isotopes
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Nd-144/Nd-143 (1)
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O-18/O-16 (2)
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Pb-206/Pb-204 (1)
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Sr-87/Sr-86 (3)
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metals
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alkaline earth metals
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strontium
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Sr-87/Sr-86 (3)
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lead
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Pb-206/Pb-204 (1)
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rare earths
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neodymium
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Nd-144/Nd-143 (1)
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oxygen
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O-18/O-16 (2)
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fossils
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burrows (1)
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Invertebrata
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Mollusca (1)
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Protista
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Foraminifera
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Rotaliina
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Globigerinacea (1)
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microfossils (2)
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geochronology methods
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Ar/Ar (1)
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K/Ar (2)
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Rb/Sr (2)
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Sm/Nd (2)
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tree rings (1)
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U/Pb (2)
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geologic age
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Cenozoic
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Quaternary (2)
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Tertiary
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Neogene
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Miocene
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Astoria Formation (1)
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Columbia River Basalt Group (1)
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lower Miocene
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Saucesian (1)
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Paleogene
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Eocene
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Clarno Formation (1)
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Flournoy Formation (4)
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Lookingglass Formation (2)
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lower Eocene (1)
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Matilija Formation (2)
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middle Eocene
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Tyee Formation (27)
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Narizian (1)
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Umpqua Formation (4)
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Yamhill Formation (2)
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Oligocene (2)
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Refugian (1)
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Mesozoic
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Franciscan Complex (1)
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Great Valley Sequence (1)
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igneous rocks
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igneous rocks
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plutonic rocks
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gabbros (1)
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volcanic rocks
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basalts
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flood basalts (1)
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pyroclastics
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tuff (1)
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metamorphic rocks
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turbidite (8)
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minerals
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carbonates
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calcite (1)
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silicates
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framework silicates
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zeolite group
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clinoptilolite (1)
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laumontite (1)
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orthosilicates
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nesosilicates
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zircon group
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zircon (2)
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sheet silicates
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mica group
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muscovite (1)
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Primary terms
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absolute age (5)
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Atlantic Ocean
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North Atlantic
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North Sea (1)
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carbon
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C-14 (1)
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Cenozoic
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Quaternary (2)
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Tertiary
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Neogene
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Miocene
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Astoria Formation (1)
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Columbia River Basalt Group (1)
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lower Miocene
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Saucesian (1)
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Paleogene
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Eocene
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Clarno Formation (1)
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Flournoy Formation (4)
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Lookingglass Formation (2)
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lower Eocene (1)
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Matilija Formation (2)
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middle Eocene
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Tyee Formation (27)
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Narizian (1)
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Umpqua Formation (4)
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Yamhill Formation (2)
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Oligocene (2)
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Refugian (1)
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continental shelf (1)
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continental slope (1)
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deformation (1)
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diagenesis (3)
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faults (1)
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folds (1)
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geochemistry (3)
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geochronology (2)
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geomorphology (3)
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hydrology (1)
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igneous rocks
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plutonic rocks
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gabbros (1)
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volcanic rocks
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basalts
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flood basalts (1)
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pyroclastics
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tuff (1)
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intrusions (1)
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Invertebrata
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Mollusca (1)
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Protista
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Foraminifera
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Rotaliina
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Globigerinacea (1)
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-
-
-
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isotopes
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radioactive isotopes
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C-14 (1)
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Pb-206/Pb-204 (1)
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stable isotopes
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Nd-144/Nd-143 (1)
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O-18/O-16 (2)
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Pb-206/Pb-204 (1)
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Sr-87/Sr-86 (3)
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land use (1)
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mantle (1)
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Mesozoic
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Franciscan Complex (1)
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Great Valley Sequence (1)
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metals
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alkaline earth metals
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strontium
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Sr-87/Sr-86 (3)
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-
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lead
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Pb-206/Pb-204 (1)
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rare earths
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neodymium
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Nd-144/Nd-143 (1)
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mineralogy (3)
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oxygen
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O-18/O-16 (2)
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Pacific Coast (3)
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Pacific Ocean
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East Pacific
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Northeast Pacific (1)
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North Pacific
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Northeast Pacific (1)
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Northwest Pacific (1)
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West Pacific
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Northwest Pacific (1)
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paleogeography (6)
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paleontology (1)
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petroleum
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natural gas (1)
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plate tectonics (2)
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roads (1)
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sea-level changes (1)
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sedimentary petrology (7)
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sedimentary rocks
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clastic rocks
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arenite (1)
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conglomerate (1)
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graywacke (1)
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mudstone (1)
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sandstone (11)
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shale (1)
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siltstone (1)
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sedimentary structures
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bedding plane irregularities
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ripple marks (2)
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planar bedding structures
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bedding (2)
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cross-bedding (1)
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cross-stratification (1)
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hummocky cross-stratification (2)
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laminations (1)
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soft sediment deformation (1)
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sedimentation (12)
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sediments
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clastic sediments
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alluvium (1)
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colluvium (1)
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slope stability (3)
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soil mechanics (1)
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soils (1)
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stratigraphy (2)
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tectonics (3)
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tectonophysics (1)
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United States
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California
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Northern California (1)
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Idaho Batholith (2)
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Klamath Mountains (5)
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Oregon
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Benton County Oregon (1)
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Coos County Oregon
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Coos Bay (4)
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Curry County Oregon (2)
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Douglas County Oregon (1)
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Klamath County Oregon (1)
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Lane County Oregon (1)
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Lincoln County Oregon
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Newport Oregon (1)
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Mount Hood (1)
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Polk County Oregon (1)
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Rogue River (1)
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Willamette River (1)
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Washington (1)
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Western U.S. (3)
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water resources (1)
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weathering (1)
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rock formations
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Empire Formation (2)
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sedimentary rocks
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sedimentary rocks
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clastic rocks
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arenite (1)
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conglomerate (1)
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graywacke (1)
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mudstone (1)
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sandstone (11)
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shale (1)
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siltstone (1)
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-
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turbidite (8)
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sedimentary structures
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burrows (1)
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channels (1)
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sedimentary structures
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bedding plane irregularities
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ripple marks (2)
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planar bedding structures
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bedding (2)
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cross-bedding (1)
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cross-stratification (1)
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hummocky cross-stratification (2)
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laminations (1)
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soft sediment deformation (1)
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sediments
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sediments
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clastic sediments
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alluvium (1)
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colluvium (1)
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turbidite (8)
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soils
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soils (1)
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Tyee Formation
Organic geochemical characterization of deltaic Paleogene rock units in Coos Bay, Oregon: Kerogen type and richness in response to depositional environments
Oligocene onset of uplift and inversion of the Cascadia forearc basin, southern Oregon Coast Range, USA
ABSTRACT The Eocene Tyee Formation of west central Oregon, USA, records deposition in a forearc basin. With outcrop exposures of fluvial/deltaic to shelf and submarine fan depositional environments and known sediment sourcing constrained by detrital zircon dating and mineralogy linked to the Idaho Batholith, it is possible to place deposits of the Tyee Formation in a source-to-sink context. A research program carried out by the Department of Geological Sciences at The University of Texas at Austin and ExxonMobil Research Company’s Clastic Stratigraphy Group has reconstructed the Eocene continental margin from shelf to slope to basin floor using outcrop and subsurface data. This work allows us to put observations of individual outcrops into a basin-scale context. This field trip will visit examples of depositional environments across the entire preserved source-to-sink system, but it will focus on the deep-water deposits of the Tyee Formation that range from slope channels to proximal and distal basin-floor fans. High-quality roadcuts reveal the geometry of slope channel-fills in both depositional strike and dip orientations. Thick, sand-rich medial fan deposits show vertical amalgamation and a high degree of lateral continuity of sandstones and mudstones. Distal fan facies with both classic Bouma-type turbidites and combined flow or slurry deposits are well exposed along a series of new roadcuts east of Newport, Oregon. The larger basin-scale context of the Tyee Formation is illustrated at a quarry in the northern end of the basin where the contact between the oceanic crust of the underlying Siletzia terrane and submarine fan deposits of the Tyee Formation is exposed. The Tyee Formation provides an excellent opportunity to see the facies and three-dimensional geometry of deep-water deposits, and to show how these deposits can be used to help reconstruct ancient continental margins.
Developing landslide chronologies using landslide-dammed lakes in the Oregon Coast Range
ABSTRACT The Oregon Coast Range is a dynamic landscape that is continually shaped by shallow and deep-seated landslides that can have disastrous consequences to infrastructure and human lives. Searching for evidence of potentially coseismic mass wasting is incredibly difficult, particularly when historical observations are limited. Landslide-dammed lakes with submerged “ghost forests” in the Oregon Coast Range present the unique opportunity to establish landslide chronologies with subannual accuracy when dendrochronology is applied. This field guide will visit the unique landslide-dammed Klickitat Lake and explore a drowned ‘ghost forest’ to discuss methods used to establish a prehistoric landslide chronology in western Oregon, USA. After exploring the lake and exposing its geomorphic secrets, the guide will end with a stop on Marys Peak, a mafic volcanic intrusion composed of gabbroic dikes and pillow basalt that forms the highest point in the Oregon Coast Range. With the landscape of western Oregon laid out before us, we will discuss short- and long-term geomorphic evolution of the Oregon Coast Range and Willamette Valley.
The eight field trips in this volume, associated with GSA Connects 2021 held in Portland, Oregon, USA, reflect the rich and varied geological legacy of the Pacific Northwest. The western margin of North America has had a complex subduction and transform history throughout the Phanerozoic, building a collage of terranes. The terrain has been modified by Cenozoic sedimentation, magmatism, and faulting related to Cascadia subduction, passage of the Yellowstone hot spot, and north and westward propagation of the Basin and Range province. The youngest flood basalt province on Earth also inundated the landscape, while the mighty Columbia watershed kept pace with arc construction and funneled epic ice-age floods from the craton to the coast. Additional erosive processes such as landslides continue to shape this dynamic geological wonderland.
Landslide Susceptibility and Soil Loss Estimates for Drift Creek Watershed, Lincoln County, Oregon
Eocene initiation of the Cascadia subduction zone: A second example of plume-induced subduction initiation?
Paleo-landslides in the Tyee Formation and highway construction, central Oregon Coast Range
ABSTRACT Investigation and design-build construction of the Highway 20 realignment through the Oregon Coast Range provides new insight into paleo-landslides of the Tyee Formation and their slope stability. They are widespread, often extending outside of current drainage basins, and much of their morphology has been almost completely hidden by surficial processes. Radiocarbon tests indicate that some of the slide features are older than the testing limits, while other results range from approximately 18,000 to 40,000 yr B.P. The depth of erosion suggests that the paleo-slides may be as old as Pliocene. Geotechnical models of the paleo-slides, needed to analyze potential construction impacts, are developed from subsurface explorations, construction outcrops, radiocarbon testing, monitoring of geotechnical instruments, and geomorphology revealed by light detection and ranging (LIDAR). The process of predicting landslide boundaries (head scarps, toes, lateral and basal shear zones, etc.) for stability analysis of specific landslides has revealed details of their geologic evolution. This field trip provides background on (a) the investigations that have exposed numerous giant paleo-landslides, (b) findings and interpretations of the age of the landslides and (c) methods that are being employed to mitigate landslide reactivation.