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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Blue Mountains (1)
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Canada
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Western Canada
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British Columbia
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Kamloops British Columbia (1)
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Vancouver Island (1)
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-
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Cascade Range (3)
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Green River basin (2)
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North America
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Basin and Range Province (1)
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North American Cordillera (3)
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Rocky Mountains
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Northern Rocky Mountains (2)
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U. S. Rocky Mountains
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Bitterroot Range (2)
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Pacific Coast (1)
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Pioneer Mountains (1)
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Salmon River (2)
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Sierra Nevada (1)
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Snake River (1)
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United States
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California
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Central California (1)
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Mariposa County California (1)
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Northern California (1)
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Sierra Nevada Batholith (1)
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Colorado (1)
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Idaho
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Blaine County Idaho (1)
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Custer County Idaho (5)
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Idaho County Idaho (1)
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Lemhi County Idaho (1)
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Snake River plain (2)
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Valley County Idaho (2)
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Idaho Batholith (6)
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Klamath Mountains (1)
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Montana (4)
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Oregon (2)
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U. S. Rocky Mountains
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Bitterroot Range (2)
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Washington (2)
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Western U.S. (2)
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Wyoming (2)
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Wind River basin (1)
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commodities
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metal ores
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antimony ores (3)
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cobalt ores (1)
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copper ores (1)
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gold ores (4)
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mercury ores (1)
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silver ores (1)
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tungsten ores (2)
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mineral deposits, genesis (4)
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mineral exploration (1)
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placers (1)
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elements, isotopes
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chemical ratios (1)
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isotope ratios (3)
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isotopes
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radioactive isotopes
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Pb-206/Pb-204 (2)
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Pb-207/Pb-204 (2)
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Pb-208/Pb-204 (2)
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stable isotopes
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Nd-144/Nd-143 (1)
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O-18/O-16 (1)
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Pb-206/Pb-204 (2)
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Pb-207/Pb-204 (2)
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Pb-208/Pb-204 (2)
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S-34/S-32 (1)
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Sr-87/Sr-86 (1)
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-
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Lu/Hf (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 (1)
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antimony (1)
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lead
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Pb-206/Pb-204 (2)
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Pb-207/Pb-204 (2)
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Pb-208/Pb-204 (2)
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precious metals (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 (1)
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sulfur
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S-34/S-32 (1)
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geochronology methods
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(U-Th)/He (1)
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Ar/Ar (2)
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Lu/Hf (1)
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thermochronology (1)
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U/Pb (3)
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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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upper Holocene (1)
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Tertiary
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Challis Volcanics (21)
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Neogene
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Miocene
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upper Miocene (1)
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-
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Paleogene
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Eocene
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Absaroka Supergroup (1)
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Chumstick Formation (1)
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Lake Gosiute (1)
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middle Eocene
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Lutetian (1)
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Swauk Formation (1)
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Paleocene
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upper Paleocene
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Thanetian (1)
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Renova Formation (1)
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Mesozoic
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Cretaceous
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Upper Cretaceous
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Hornbrook Formation (1)
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Franciscan Complex (1)
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Great Valley Sequence (1)
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Jurassic
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Upper Jurassic
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Galice Formation (1)
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middle Mesozoic (1)
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Paleozoic
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lower Paleozoic (1)
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Precambrian
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upper Precambrian
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Proterozoic
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Mesoproterozoic
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Belt Supergroup (1)
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Neoproterozoic (1)
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igneous rocks
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igneous rocks
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plutonic rocks
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diorites
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tonalite (1)
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granites (2)
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volcanic rocks
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adakites (1)
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basalts
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tholeiitic basalt (1)
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pyroclastics
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ash-flow tuff (1)
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tuff (1)
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rhyolites (1)
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ophiolite (1)
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metamorphic rocks
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metamorphic rocks
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metaigneous rocks
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metabasite (1)
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metasedimentary rocks (1)
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ophiolite (1)
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minerals
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phosphates
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apatite (1)
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silicates
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framework silicates
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feldspar group
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alkali feldspar
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sanidine (1)
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silica minerals
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quartz (1)
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orthosilicates
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nesosilicates
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garnet group (1)
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zircon group
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zircon (3)
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sulfides
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stibnite (2)
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tungstates
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scheelite (1)
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Primary terms
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absolute age (6)
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Canada
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Western Canada
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British Columbia
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Kamloops British Columbia (1)
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Vancouver Island (1)
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-
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Cenozoic
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Quaternary
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Holocene
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upper Holocene (1)
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-
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Tertiary
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Challis Volcanics (21)
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Neogene
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Miocene
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upper Miocene (1)
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-
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Paleogene
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Eocene
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Absaroka Supergroup (1)
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Chumstick Formation (1)
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Lake Gosiute (1)
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middle Eocene
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Lutetian (1)
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Swauk Formation (1)
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Paleocene
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upper Paleocene
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Thanetian (1)
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Renova Formation (1)
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crust (1)
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dams (1)
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deformation (1)
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diagenesis (1)
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faults (8)
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folds (1)
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fractures (1)
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geochemistry (4)
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igneous rocks
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plutonic rocks
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diorites
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tonalite (1)
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granites (2)
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volcanic rocks
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adakites (1)
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basalts
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tholeiitic basalt (1)
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pyroclastics
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ash-flow tuff (1)
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tuff (1)
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rhyolites (1)
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inclusions
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fluid inclusions (1)
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intrusions (6)
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isotopes
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radioactive isotopes
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Pb-206/Pb-204 (2)
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Pb-207/Pb-204 (2)
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Pb-208/Pb-204 (2)
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stable isotopes
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Nd-144/Nd-143 (1)
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O-18/O-16 (1)
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Pb-206/Pb-204 (2)
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Pb-207/Pb-204 (2)
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Pb-208/Pb-204 (2)
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S-34/S-32 (1)
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Sr-87/Sr-86 (1)
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lava (3)
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magmas (2)
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mantle (1)
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Mesozoic
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Cretaceous
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Upper Cretaceous
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Hornbrook Formation (1)
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-
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Franciscan Complex (1)
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Great Valley Sequence (1)
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Jurassic
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Upper Jurassic
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Galice Formation (1)
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-
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middle Mesozoic (1)
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metal ores
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antimony ores (3)
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cobalt ores (1)
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copper ores (1)
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gold ores (4)
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mercury ores (1)
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silver ores (1)
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tungsten ores (2)
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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 (1)
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-
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antimony (1)
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lead
-
Pb-206/Pb-204 (2)
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Pb-207/Pb-204 (2)
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Pb-208/Pb-204 (2)
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precious metals (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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-
-
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metamorphic rocks
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metaigneous rocks
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metabasite (1)
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metasedimentary rocks (1)
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metamorphism (2)
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metasomatism (3)
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mineral deposits, genesis (4)
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mineral exploration (1)
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North America
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Basin and Range Province (1)
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North American Cordillera (3)
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Rocky Mountains
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Northern Rocky Mountains (2)
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U. S. Rocky Mountains
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Bitterroot Range (2)
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oxygen
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O-18/O-16 (1)
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Pacific Coast (1)
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paleogeography (3)
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Paleozoic
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lower Paleozoic (1)
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paragenesis (2)
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petrology (1)
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placers (1)
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plate tectonics (6)
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Precambrian
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upper Precambrian
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Proterozoic
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Mesoproterozoic
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Belt Supergroup (1)
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Neoproterozoic (1)
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sedimentary rocks
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clastic rocks
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arkose (1)
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mudstone (1)
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sandstone (3)
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sedimentary structures
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planar bedding structures
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laminations (2)
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sedimentation (1)
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sediments
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clastic sediments (1)
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structural geology (1)
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sulfur
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S-34/S-32 (1)
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tectonics (6)
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United States
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California
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Central California (1)
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Mariposa County California (1)
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Northern California (1)
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Sierra Nevada Batholith (1)
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Colorado (1)
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Idaho
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Blaine County Idaho (1)
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Custer County Idaho (5)
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Idaho County Idaho (1)
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Lemhi County Idaho (1)
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Snake River plain (2)
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Valley County Idaho (2)
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Idaho Batholith (6)
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Klamath Mountains (1)
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Montana (4)
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Oregon (2)
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U. S. Rocky Mountains
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Bitterroot Range (2)
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Washington (2)
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Western U.S. (2)
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Wyoming (2)
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sedimentary rocks
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sedimentary rocks
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clastic rocks
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arkose (1)
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mudstone (1)
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sandstone (3)
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volcaniclastics (4)
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sedimentary structures
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sedimentary structures
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planar bedding structures
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laminations (2)
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stratification (1)
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sediments
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sediments
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clastic sediments (1)
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volcaniclastics (4)
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Challis Volcanics
Timing of Hydrothermal Alteration and Au-Sb-W Mineralization, Stibnite-Yellow Pine District, Idaho
Stratigraphic and geochronologic investigation of the Muddy Creek Basin: Implications for the Eocene tectonic evolution of southwest Montana, USA
Regional Geologic Framework of Mineral Deposits in the Stibnite-Edwardsburg Area, Central Idaho
U-Pb Scheelite Ages of Tungsten and Antimony Mineralization in the Stibnite-Yellow Pine District, Central Idaho
ABSTRACT Failure-prone Cenozoic volcanic rocks distributed across central Idaho, USA, promote large landslides, consequent drainage impoundment, and the formation of regionally asynchronous landslide-dammed lakes. Examination of sedimentary records shows that extant lakes formed in this way exhibit high primary productivity relative to other lakes in the region, apparently sustained through relatively elevated watershed phosphorous loading and the contribution of nitrogen-fixing cyanobacteria. The resulting high rates of sediment and carbon accumulation exceed those found in regional lakes formed by other processes and underlain by other bedrock lithologies lower in phosphorous. These unusually high biogenic sediment accumulation rates produce highly resolved, often annually laminated sedimentary sequences. The result is a high-resolution temporal matrix for the runoff-intensity signal of episodically delivered, watershed-derived clastic sediment. Elemental analysis by core-scanning X-ray fluorescence (XRF) effectively highlights these clastic pulses, and spectral analysis of lithogenic elemental intensities indicates they carry spectral power (including significant harmonic signals) concentrated in the 3–5 yr period. Patterns shown by episodic sediment delivery events support winter snowpack as a modulator of late Holocene sediment export from these watersheds.
Review of mid-Mesozoic to Paleogene evolution of the northern and central Californian accretionary margin
ABSTRACT Spatial distributions of widespread igneous arc rocks and high-pressure–low-temperature (HP/LT) metamafic rocks, combined with U-Pb maximum ages of deposition from detrital zircon and petrofacies of Jurassic–Miocene clastic sedimentary rocks, constrain the geologic development of the northern and central Californian accretionary margin: (1) Before ca. 175 Ma, transpressive plate subduction initiated construction of a magmatic arc astride the Klamath-Sierran crustal margin. (2) Paleo-Pacific oceanic-plate rocks were recrystallized under HP/LT conditions in an east-dipping subduction zone beneath the arc at ca. 170–155 Ma. Stored at depth, these HP/LT metamafic blocks returned surfaceward mainly during mid- and Late Cretaceous time as olistoliths and tectonic fragments entrained in circulating, buoyant Franciscan mud-matrix mélange. (3) By ca. 165 Ma and continuing to at least ca. 150 Ma, erosion of the volcanic arc supplied upper-crustal debris to the Mariposa-Galice and Myrtle arc-margin strata. (4) By ca. 140 Ma, the Klamath salient had moved ~80–100 km westward relative to the Sierran arc, initiating a new, outboard convergent plate junction, and trapping old oceanic crust on the south as the Great Valley Ophiolite. (5) Following end-of-Jurassic development of a new Farallon–North American east-dipping plate junction, terrigenous debris began to accumulate as the seaward Franciscan trench complex and landward Great Valley Group plus Hornbrook forearc clastic rocks. (6) Voluminous deposition and accretion of Franciscan Eastern and Central belt and Great Valley Group detritus occurred during vigorous Sierran igneous activity attending rapid, nearly orthogonal plate subduction starting at ca. 125 Ma. (7) Although minor traces of Grenville-age detrital zircon occur in other sandstones studied in this report, they are absent from post–120 Ma Franciscan strata. (8) Sierra Nevada magmatism ceased by ca. 85 Ma, signaling transition to subhorizontal eastward underflow attending Laramide orogeny farther inland. (9) Exposed Paleogene Franciscan Coastal belt sandstone accreted in a tectonic realm unaffected by HP/LT recrystallization. (10) Judging by petrofacies and zircon U-Pb ages, Franciscan Eastern belt rocks contain clasts derived chiefly from the Sierran and Klamath ranges. Detritus from the Sierra Nevada ± Idaho batholiths is present in some Central belt strata, whereas clasts from the Idaho batholith, Challis volcanics, and Cascade igneous arc appear in progressively younger Paleogene Coastal belt sandstone.
Miocene regional hotspot-related uplift, exhumation, and extension north of the Snake River Plain: Evidence from apatite (U-Th)/He thermochronology
Tertiary stratigraphy and structure of the eastern flank of the Cascade Range, Washington
Abstract A ruling hypothesis for the central Cascade Range in Washington is that the Eocene arkosic formations, which are kilometers thick, were deposited in local grabens, such as the Chumstick Formation in the putative Chiwaukum graben. However, the formations are regional in extent and are preserved in less extensive northwesttrending synclines. The Chumstick Formation in the Peshastin syncline is a more proximal equivalent of the Roslyn Formation, which is preserved in the Kittitas Valley syncline 25 km to the southwest. The Chiwaukum structural low is partially bounded on the southwest by the Leavenworth fault zone, which consists of northwesterly striking, northeasterly verging reverse faults (with associated northwest-striking folds). The reverse faults and the hinges of the folds are cut by N-S, dextral strike-slip faults, which also partially bound the Chiwaukum structural low. Conglomeratic units in the Chumstick Formation are not proximal to either set of bounding faults. The Leavenworth fault occurs on the steeper northeastern limb of a northwesterly trending, basement-cored anticline. The Eagle Creek and Ainsley Canyon anticlines also have reverse faults on their steeper northeastern limbs. In the Puget Lowland, the Seattle reverse fault is in a similar anticline. The regional distribution of the Eocene formations and uplift of the Cascade Range are caused by folding of the Miocene Columbia River Basalt Group since 4 Ma. The remnant of a 4 Ma andesite on Natapoc Mountain shows that the present low topography of the Chiwaukum structural low is erosional and young.
Hells Canyon to the Bitterroot front: A transect from the accretionary margin eastward across the Idaho batholith
Abstract This field guide covers geology across north-central Idaho from the Snake River in the west across the Bitterroot Mountains to the east to near Missoula, Montana. The regional geology includes a much-modified Mesozoic accretionary boundary along the western side of Idaho across which allochthonous Permian to Cretaceous arc complexes of the Blue Mountains province to the west are juxtaposed against autochthonous Mesoproterozoic and Neoproterozoic North American metasedimentary assemblages intruded by Cretaceous and Paleogene plutons to the east. The accretionary boundary turns sharply near Orofino, Idaho, from north-trending in the south to west-trending, forming the Syringa embayment, then disappears westward under Miocene cover rocks of the Columbia River Basalt Group. The Coolwater culmination east of the Syringa embayment exposes allochthonous rocks well east of an ideal steep suture. North and east of it is the Bitterroot lobe of the Idaho batholith, which intruded Precambrian continental crust in the Cretaceous and Paleocene to form one of the classical North American Cordilleran batholiths. Eocene Challis plutons, products of the Tertiary western U.S. ignimbrite flare-up, intrude those batholith rocks. This guide describes the geology in three separate road logs: (1) The Wallowa terrane of the Blue Mountains province from White Bird, Idaho, west into Hells Canyon and faults that complicate the story; (2) the Mesozoic accretionary boundary from White Bird to the South Fork Clearwater River east of Grangeville and then north to Kooskia, Idaho; and (3) the bend in the accretionary boundary, the Coolwater culmination, and the Bitterroot lobe of the Idaho batholith along Highway 12 east from near Lewiston, Idaho, to Lolo, Montana.
Eocene extension in Idaho generated massive sediment floods into the Franciscan trench and into the Tyee, Great Valley, and Green River basins
Reconnaissance Lead Isotope Characteristics of the Blackbird Deposit: Implications for the Age and Origin of Cobalt-Copper Mineralization in the Idaho Cobalt Belt, United States
Seismically imaged relict slab from the 55 Ma Siletzia accretion to the northwest United States
Paleogeographic reconstruction of the Eocene Idaho River, North American Cordillera
Geochemical confirmation of the Kula-Farallon slab window beneath the Pacific Northwest in Eocene time
Eocene Challis-Kamloops volcanism in central British Columbia: an example from the Buck Creek basin
Sedimentary record of caldera-forming eruptions, Eocene Challis volcanic field, Idaho
Lacustrine sedimentation processes and patterns during effusive and explosive volcanism, Challis volcanic field, Idaho
Geology of the Sunbeam and Grouse Creek gold-silver deposits, Yankee Fork mining district, Eocene Challis volcanic field, Idaho; a volcanic dome- and volcaniclastic-hosted epithermal system
Cretaceous and Cainozoic granites and rhyolites in the northwestern U.S.A. provide a record of silicic magmatism related to diverse tectonic settings and large-scale variations in crustal structure. The Late Cretaceous Idaho Batholith is a tonalitic to granitic Cordilleran batholith that was produced during plate convergence. Rocks of the batholith tend to be sodic (Na 2 O>K 2 O), with fractionated HREE, negligible Eu anomalies, and high Sr contents, suggesting their generation from relatively mafic sources at a depth sufficient to stabilise garnet. In contrast, Neogene rhyolites of the Snake River Plain, which erupted in an extensional environment, are potassic (K 2 O>Na 2 O), with unfractionated HREE patterns, negative Eu anomalies, and low Sr contents, suggesting a shallower, more feldspathic source with abundant plagioclase. Eocene age volcanic and plutonic rocks have compositions transitional between those of the Cretaceous batholith and the Neogene rhyolites. These data are consistent with a progressively shallowing locus of silicic magma generation as the tectonic regime changed from convergence to extension.