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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 (1)
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Avalon Zone (1)
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Caledonides (1)
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Canada
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Eastern Canada
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Gander Zone (1)
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Maritime Provinces
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New Brunswick
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Gloucester County New Brunswick
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Bathurst mining district (1)
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Restigouche County New Brunswick (2)
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Nova Scotia (1)
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Newfoundland and Labrador
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Newfoundland
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Port au Port Peninsula (1)
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-
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Quebec
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Beauce County Quebec (1)
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Gaspe Peninsula (10)
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Sherbrooke County Quebec (1)
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Thetford Mines (1)
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-
-
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Canterbury Basin (1)
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Chaleur Bay (1)
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Dunnage Zone (6)
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Eel River (1)
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North America
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Appalachians
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Northern Appalachians (10)
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Humber Zone (4)
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United States
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Bronson Hill Anticlinorium (1)
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Connecticut Valley (1)
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Maine
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Aroostook County Maine (1)
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Chain Lakes Massif (1)
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Lincoln County Maine (1)
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Piscataquis County Maine (1)
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Sagadahoc County Maine (1)
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Merrimack Synclinorium (1)
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New England (1)
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New Hampshire (1)
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Vermont (1)
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-
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commodities
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metal ores
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copper ores (2)
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gold ores (3)
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lead ores (1)
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silver ores (2)
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zinc ores (1)
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mineral deposits, genesis (3)
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mineral exploration (2)
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petroleum
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natural gas (1)
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-
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elements, isotopes
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carbon
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C-13/C-12 (2)
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isotope ratios (2)
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isotopes
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stable isotopes
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C-13/C-12 (2)
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O-18/O-16 (2)
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metals
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rare earths
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neodymium (1)
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oxygen
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O-18/O-16 (2)
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fossils
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Graptolithina (1)
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ichnofossils
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Chondrites ichnofossils (1)
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Nereites (1)
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Ophiomorpha (1)
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Planolites (1)
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Thalassinoides (1)
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Zoophycos (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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Malacostraca (1)
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Trilobitomorpha
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Trilobita (1)
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-
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Brachiopoda (2)
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microfossils
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Chitinozoa (1)
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palynomorphs
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Chitinozoa (1)
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geochronology methods
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Ar/Ar (1)
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Sm/Nd (1)
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U/Pb (6)
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geologic age
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Paleozoic
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Cambrian
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Acadian (1)
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Lower Cambrian (1)
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Devonian
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Lower Devonian
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Emsian (1)
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Middle Devonian (2)
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lower Paleozoic (1)
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Matapedia Group (2)
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middle Paleozoic (1)
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Ordovician
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Middle Ordovician (1)
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Upper Ordovician (2)
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Permian (2)
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Silurian
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Lower Silurian (2)
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Upper Silurian
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Pridoli (1)
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Phanerozoic (2)
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Precambrian
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upper Precambrian
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Proterozoic
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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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gabbros (1)
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granites (2)
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granodiorites (1)
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volcanic rocks
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basalts
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mid-ocean ridge basalts (1)
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tholeiite (2)
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pyroclastics
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tuff (2)
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rhyolites (2)
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metamorphic rocks
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metamorphic rocks
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metaigneous rocks
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serpentinite (1)
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metasomatic rocks
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serpentinite (1)
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turbidite (1)
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minerals
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phosphates
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monazite (1)
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silicates
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orthosilicates
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nesosilicates
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zircon group
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zircon (7)
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sheet silicates
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mica group
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muscovite (1)
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sulfides (1)
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Primary terms
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absolute age (7)
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Atlantic Ocean
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North Atlantic (1)
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Canada
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Eastern Canada
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Gander Zone (1)
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Maritime Provinces
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New Brunswick
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Gloucester County New Brunswick
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Bathurst mining district (1)
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Restigouche County New Brunswick (2)
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Nova Scotia (1)
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Newfoundland and Labrador
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Newfoundland
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Port au Port Peninsula (1)
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-
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Quebec
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Beauce County Quebec (1)
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Gaspe Peninsula (10)
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Sherbrooke County Quebec (1)
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Thetford Mines (1)
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carbon
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C-13/C-12 (2)
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crust (3)
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deformation (5)
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diagenesis (1)
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faults (7)
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folds (4)
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fractures (1)
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geochemistry (9)
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geophysical methods (1)
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Graptolithina (1)
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ichnofossils
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Chondrites ichnofossils (1)
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Nereites (1)
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Ophiomorpha (1)
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Planolites (1)
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Thalassinoides (1)
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Zoophycos (1)
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igneous rocks
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plutonic rocks
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gabbros (1)
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granites (2)
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granodiorites (1)
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volcanic rocks
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basalts
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mid-ocean ridge basalts (1)
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tholeiite (2)
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pyroclastics
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tuff (2)
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rhyolites (2)
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-
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inclusions
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fluid inclusions (3)
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intrusions (4)
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Invertebrata
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Arthropoda
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Mandibulata
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Crustacea
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Malacostraca (1)
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-
-
Trilobitomorpha
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Trilobita (1)
-
-
-
Brachiopoda (2)
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isotopes
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stable isotopes
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C-13/C-12 (2)
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O-18/O-16 (2)
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-
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lava (1)
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magmas (6)
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mantle (2)
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metal ores
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copper ores (2)
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gold ores (3)
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lead ores (1)
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silver ores (2)
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zinc ores (1)
-
-
metals
-
rare earths
-
neodymium (1)
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-
-
metamorphic rocks
-
metaigneous rocks
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serpentinite (1)
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metasomatic rocks
-
serpentinite (1)
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-
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metamorphism (2)
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mineral deposits, genesis (3)
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mineral exploration (2)
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North America
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Appalachians
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Northern Appalachians (10)
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Humber Zone (4)
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orogeny (5)
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oxygen
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O-18/O-16 (2)
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paleoecology (2)
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paleogeography (3)
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paleontology (1)
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Paleozoic
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Cambrian
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Acadian (1)
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Lower Cambrian (1)
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Devonian
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Lower Devonian
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Emsian (1)
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Middle Devonian (2)
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lower Paleozoic (1)
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Matapedia Group (2)
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middle Paleozoic (1)
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Ordovician
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Middle Ordovician (1)
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Upper Ordovician (2)
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Permian (2)
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Silurian
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Lower Silurian (2)
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Upper Silurian
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Pridoli (1)
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-
-
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palynomorphs
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Chitinozoa (1)
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petroleum
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natural gas (1)
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Phanerozoic (2)
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plate tectonics (9)
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Precambrian
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upper Precambrian
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Proterozoic
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Neoproterozoic (1)
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sea-floor spreading (1)
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sea-level changes (1)
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sedimentary rocks
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carbonate rocks (1)
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clastic rocks
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black shale (1)
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conglomerate (3)
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sandstone (2)
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sedimentary structures
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biogenic structures
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lebensspuren (1)
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sedimentation (1)
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stratigraphy (2)
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tectonics (10)
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United States
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Bronson Hill Anticlinorium (1)
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Connecticut Valley (1)
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Maine
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Aroostook County Maine (1)
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Chain Lakes Massif (1)
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Lincoln County Maine (1)
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Piscataquis County Maine (1)
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Sagadahoc County Maine (1)
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-
Merrimack Synclinorium (1)
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New England (1)
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New Hampshire (1)
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Vermont (1)
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-
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sedimentary rocks
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flysch (1)
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sedimentary rocks
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carbonate rocks (1)
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clastic rocks
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black shale (1)
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conglomerate (3)
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sandstone (2)
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siliciclastics (1)
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turbidite (1)
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volcaniclastics (2)
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sedimentary structures
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sedimentary structures
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biogenic structures
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lebensspuren (1)
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sediments
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siliciclastics (1)
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turbidite (1)
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volcaniclastics (2)
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Aroostook-Matapedia Belt
Late Ordovician sedimentary rocks and trace fossils of the Aroostook-Matapedia Carbonate Belt at Runnymede, Restigouche River, northern New Brunswick
Location Runnymede is a small hamlet located 1,640 ft (500 m) north of the confluence of the Upsalquitch and Restigouche rivers,4.3 mi (7 km) south of Matapedia, on the northwestern New Brunswick-eastern Quebec border. Like its more famous historicalcounterpart on the Thames River, southern England, wherethe Magna Carta was granted by King John in 1215, Runnymede, Quebec, is also located on the inside of a large meanderbut on the Restigouche River. The Runnymede site is situated onthe outside, the New Brunswick side, of the same meander, the Quebec-New Brunswick border being situated along the centreof the Restigouche River. The site is subdivided into two majorsections separated by the Rafting Ground Brook, a small tributaryof the Restigouche River. Location and geological details areindicated in Figures 1 and 2. The site is accessible by any sized vehicle at any time of theyear. A car park with picnic tables is located just to the southeastof the confluence of the Rafting Ground Brook and Restigouche River (Fig. 2). Permission is not required to examine the site, which can be done thoroughly in approximately three hours.
Phanerozoic flysch trace fossil diversity—observations based on an Ordovician flysch ichnofauna from the Aroostook–Matapedia Carbonate Belt of northern New Brunswick
The Acadian orogeny in the North Atlantic region is assessed in this chapter in the light of mid-Paleozoic tectonics; throughout, plate tectonic nomenclature is used, and cycles are avoided. In North America nine regions bearing the imprint of the Acadian orogeny are recognized. In Newfoundland, in the Maritime Provinces of Canada, and in Vermont and New Hampshire a continuous sequence of lithotectonic belts correlates along the orogen. The Bronson Hill belt, although a continuous structure in southern New England, is not recognized as such but splits into two structures northeast of the Maine-New Hampshire border: the Boundary Mountain anticlinorium and the Lobster Mountain anticlinorium. Other lithotectonic belts are partly continuous from Canada into the United States; they include: (1) North-Central Maine belt, (2) Aroostook-Matapedia belt, (3) Miramichi belt, (4) Fredericton-Central Maine belt, (5) Richmond belt, (6) Casco Bay belt, (7) Benner Hill belt, (8) St. Croix-Ellsworth belt, (9) Mascarene belt, and (10) Avalon belt. The decision as to whether each of these belts represents a separate terrane is at present reserved. In the coastal Maine zone the situation is particularly complex, and belts 6 through 10 can be recognized there. In Massachusetts, we interpret the Merrimack Trough belt as in fault contact with both the Kearsarge-Central Maine and Bronson Hill belts to the northwest, and in Connecticut, with the Bronson Hill belt alone. Additionally, the Merrimack Trough belt is in fault contact with the Putnam-Nashoba belt to the southeast. The latter shows mainly a Taconian metamorphism and extensive intrusion of granites; clear evidence for Acadian orogenic effects in the Putnam-Nashoba belt is lacking. In Newfoundland the main orogeny appears to be Silurian in age, and the same is true of New Brunswick, whereas in the Meguma of Nova Scotia the Devonian deformation and intrusive activity continue from the Devonian to the Carboniferous. Correlations with the south-central Appalachians indicate a possibility of significant Acadian transpressional effects. The most recent evidence of a new microfossil find, however, implies that considerable Acadian deformation occurred in the Southern Appalachians, although it may have been directly continuous with earlier Taconian events. The Acadian metamorphism in the Northern Appalachians is associated with numerous granites, in general ranging in age from the Silurian to the Carboniferous. The earlier Silurian granites may have originated along the Iapetus suture or may be associated with transcurrent faults. The plate tectonic interpretation of the orogenic system is based on a model of successive blocks (terranes) approaching and colliding with North America and squeezing intervening sediments and volcanics. This took place over a fairly prolonged period of time.
Figure 1. Generalized geology of the northern Appalachians. Pre-Devonian un...
Nature of the Acadian orogeny in eastern Maine
New insight into the nature of the Acadian orogeny in eastern Maine has been gained by combining detailed field studies in six lithotectonic belts with geochemical data from the igneous rocks of the region. Revised stratigraphies and deformation histories of the tracts reveal their sedimentological and structural evolution from Ordovician through Early Devonian times, and variations in the isotope geochemistry of the igneous rocks permit delineation of the basement blocks beneath the supracrustal belts. Combined, these results yield a model for plate interactions that followed Taconian deformation and culminated in the Acadian orogeny. Large basins (e.g., Aroostook-Matapedia, Central Maine) formed immediately after the Taconic orogeny on the recently accreted eastern margin of ancestral North America. These filled with thick clastic sequences derived from post-Taconian highlands during Late Ordovician through at least Middle Silurian times and characteristically preserve complex facies patterns at their margins. At the same time, sedimentation continued in the Fredericton Trough, inferred to be the only remaining oceanic crust in the region. This ocean basin separated the composite North American terrane from an equally complex Avalonian continent. Closing of this basin resulted in the Acadian orogeny. The onset of the Acadian suturing of Avalon to North America is indicated by a change from local basin filling to a more homogeneous blanket of sandstones whose deposition appears to have begun in the east (Flume Ridge Formation) and migrated westward. Collision of basement blocks led first to westward thrusting of parts of the Avalonian continent over the Fredericton belt. Later Acadian thrusting caused by final collision between Avalon and ancestral North America transported supracrustal Miramichi belt strata eastward over the Fredericton belt and parts of the Fredericton belt eastward over the western edge of the Avalonian allochthon. Acadian thrusting has displaced the original boundaries between supracrustal belts in southeastern Maine so that they no longer coincide with boundaries between the basement blocks that originally lay beneath them.