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NARROW
GeoRef Subject
-
all geography including DSDP/ODP Sites and Legs
-
Africa
-
Southern Africa
-
Karoo Basin (1)
-
South Africa
-
Cape fold belt (1)
-
-
-
-
Asia
-
Altai Mountains (1)
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Far East
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China
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Xizang China
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Lhasa China (1)
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Himalayas
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High Himalayan Crystallines (1)
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Indus-Yarlung Zangbo suture zone (1)
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Tibetan Plateau (2)
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Atlantic Ocean
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Mid-Atlantic Ridge (1)
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North Atlantic
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Gulf of Mexico (9)
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-
Australasia
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Australia
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South Australia
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Flinders Ranges (1)
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New Zealand
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Otago Schist (1)
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Torlesse Terrane (1)
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Black Rock Desert (1)
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Blue Mountains (2)
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Canada
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Western Canada
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British Columbia (1)
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Canterbury Basin (1)
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Central America
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Belize (1)
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Central Cordillera (1)
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Chicxulub Crater (1)
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Coast Ranges (4)
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Cook Inlet (1)
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Cordillera de la Costa (1)
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El Paso Mountains (1)
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Europe
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Western Alps
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Ligurian Alps (1)
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Southern Europe
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Iberian Peninsula
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Spain
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Catalonia Spain (1)
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Ebro Basin (1)
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Italy
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Apennines
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Northern Apennines (1)
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Liguria Italy
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Piemonte Italy (1)
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Western Europe
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France
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Mexico
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Sonora Mexico (6)
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Tabasco Mexico (1)
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Veracruz Mexico (2)
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North America
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Appalachians (3)
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Basin and Range Province (1)
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Canadian Shield
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Methow Basin (1)
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North American Cordillera (10)
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North Slope (1)
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Pacific Ocean
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West Pacific
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Pacific region (1)
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South Island (1)
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United States
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Alaska
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Anadarko Basin (1)
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Arizona
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Cochise County Arizona (1)
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California
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Salinian Block (1)
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Colorado (2)
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Idaho
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Oklahoma
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Arbuckle Uplift (1)
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Kay County Oklahoma (1)
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Wichita Uplift (1)
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Oregon
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Crook County Oregon (1)
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Grant County Oregon (1)
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Ouachita Belt (1)
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Paradox Basin (2)
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Sevier orogenic belt (6)
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Texas
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U. S. Rocky Mountains
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Emery County Utah (1)
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Kaiparowits Plateau (1)
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Western U.S. (2)
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Yavapai Province (2)
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Veracruz Basin (2)
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commodities
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petroleum (3)
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elements, isotopes
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isotopes
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Pb-206/Pb-204 (1)
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Pb-207/Pb-204 (1)
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Pb-208/Pb-204 (1)
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stable isotopes
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Hf-177/Hf-176 (2)
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Nd-144/Nd-143 (2)
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Pb-206/Pb-204 (1)
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Pb-207/Pb-204 (1)
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Pb-208/Pb-204 (1)
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Sr-87/Sr-86 (1)
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metals
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strontium
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Sr-87/Sr-86 (1)
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chromium (1)
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cobalt (1)
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hafnium
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Hf-177/Hf-176 (2)
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iron (1)
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lead
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Pb-206/Pb-204 (1)
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Pb-207/Pb-204 (1)
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Pb-208/Pb-204 (1)
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-
nickel (2)
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rare earths
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neodymium
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Nd-144/Nd-143 (2)
-
-
-
-
-
fossils
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Invertebrata
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Mollusca
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Bivalvia
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Pterioida
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Pteriina
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Inocerami
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Inoceramidae
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Inoceramus (1)
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-
-
-
-
-
Cephalopoda
-
Ammonoidea
-
Ammonites (1)
-
-
-
-
Protista
-
Foraminifera
-
Rotaliina
-
Rotaliacea
-
Nummulitidae
-
Nummulites (1)
-
-
-
-
-
-
-
microfossils (2)
-
-
geochronology methods
-
Ar/Ar (4)
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K/Ar (1)
-
paleomagnetism (3)
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thermochronology (1)
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U/Pb (39)
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geologic age
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Cenozoic
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lower Cenozoic (2)
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Quaternary
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Tertiary
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Challis Volcanics (1)
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Neogene
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Miocene
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middle Miocene (2)
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upper Miocene
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Punchbowl Formation (1)
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Pliocene (2)
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-
Paleogene
-
Eocene
-
Colton Formation (2)
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lower Eocene (2)
-
upper Eocene (1)
-
-
Oligocene
-
Hemlock Conglomerate (1)
-
-
Paleocene
-
lower Paleocene
-
K-T boundary (2)
-
-
upper Paleocene (1)
-
-
Sespe Formation (1)
-
Tyonek Formation (1)
-
-
-
upper Cenozoic (1)
-
-
Mesozoic
-
Bisbee Group (2)
-
Cretaceous
-
Lower Cretaceous
-
Albian (6)
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Aptian (3)
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Bear River Formation (1)
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Mural Limestone (1)
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Valanginian (1)
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Middle Cretaceous (1)
-
Upper Cretaceous
-
Campanian
-
lower Campanian (1)
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Castlegate Sandstone (1)
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Cenomanian (2)
-
Codell Sandstone Member (1)
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Coniacian (3)
-
Frontier Formation (1)
-
Hornbrook Formation (2)
-
Kaiparowits Formation (1)
-
K-T boundary (2)
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Maestrichtian (2)
-
Mesaverde Group (2)
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Santonian (1)
-
Senonian (2)
-
Straight Cliffs Formation (1)
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Turonian (2)
-
Wahweap Formation (1)
-
-
-
Franciscan Complex (4)
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Glen Canyon Group (1)
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Great Valley Sequence (4)
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Jurassic
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Arapien Shale (1)
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Lower Jurassic
-
Hettangian (1)
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Sinemurian (1)
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Toarcian (2)
-
-
Middle Jurassic
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Bajocian (1)
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San Rafael Group (2)
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Upper Jurassic
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Galice Formation (1)
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La Casita Formation (1)
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Tithonian (2)
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-
-
lower Mesozoic (3)
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middle Mesozoic (1)
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Orocopia Schist (1)
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Triassic
-
Lower Triassic (2)
-
Middle Triassic (1)
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Moenkopi Formation (1)
-
Upper Triassic
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Carnian (2)
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Chinle Formation (1)
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Norian (1)
-
-
-
upper Mesozoic (1)
-
-
Paleozoic
-
Cambrian
-
Acadian (1)
-
-
Carboniferous
-
Mississippian
-
Upper Mississippian
-
Chesterian
-
Golconda Formation (1)
-
-
-
-
Pennsylvanian
-
Lower Pennsylvanian
-
Haymond Formation (1)
-
-
Middle Pennsylvanian
-
Paradox Formation (1)
-
-
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Devonian
-
Upper Devonian
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Famennian (1)
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-
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Ordovician
-
Upper Ordovician
-
Katian (1)
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Sandbian (1)
-
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Utica Shale (1)
-
-
Permian
-
Cutler Formation (1)
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Guadalupian (1)
-
Lower Permian
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Cisuralian
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Kungurian (1)
-
-
-
Lyons Sandstone (1)
-
McCloud Limestone (1)
-
Upper Permian
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Lopingian (1)
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Wellington Formation (1)
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upper Paleozoic (5)
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Phanerozoic (2)
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Precambrian
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Archean (1)
-
upper Precambrian
-
Proterozoic
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Neoproterozoic (2)
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Paleoproterozoic (4)
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-
-
-
-
igneous rocks
-
igneous rocks
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plutonic rocks
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diorites
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quartz diorites (1)
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tonalite (2)
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gabbros (1)
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granites (2)
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granodiorites (1)
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quartzolite (1)
-
ultramafics
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peridotites
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harzburgite (1)
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pyroxenite
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orthopyroxenite (1)
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-
-
volcanic rocks
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andesites (3)
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basalts (1)
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pyroclastics
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ignimbrite (2)
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tuff (1)
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rhyolites (1)
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-
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ophiolite (2)
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volcanic ash (1)
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metamorphic rocks
-
metamorphic rocks
-
metaigneous rocks
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metabasite (1)
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metasedimentary rocks (1)
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quartzites (2)
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ophiolite (2)
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turbidite (4)
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-
minerals
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alloys
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arsenides
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carbonates
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oxides
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rutile (1)
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phosphates
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apatite (1)
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monazite (1)
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silicates
-
framework silicates
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-
alkali feldspar
-
K-feldspar (1)
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plagioclase (1)
-
-
silica minerals
-
quartz (4)
-
-
-
orthosilicates
-
nesosilicates
-
garnet group (1)
-
olivine group
-
olivine (1)
-
-
zircon group
-
zircon (41)
-
-
-
-
sheet silicates
-
clay minerals
-
kaolinite (1)
-
smectite (1)
-
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illite (1)
-
mica group
-
muscovite (1)
-
-
serpentine group
-
serpentine (1)
-
-
-
-
sulfates
-
barite (1)
-
gypsum (2)
-
-
sulfides
-
bismuthinite (1)
-
bornite (1)
-
heazlewoodite (1)
-
pentlandite (1)
-
pyrrhotite (1)
-
-
-
Primary terms
-
absolute age (41)
-
Africa
-
Southern Africa
-
Karoo Basin (1)
-
South Africa
-
Cape fold belt (1)
-
-
-
-
Asia
-
Altai Mountains (1)
-
Far East
-
China
-
Xizang China
-
Lhasa China (1)
-
-
-
-
Himalayas
-
High Himalayan Crystallines (1)
-
-
Indus-Yarlung Zangbo suture zone (1)
-
Tibetan Plateau (2)
-
-
Atlantic Ocean
-
Mid-Atlantic Ridge (1)
-
North Atlantic
-
Gulf of Mexico (9)
-
-
-
Australasia
-
Australia
-
South Australia
-
Flinders Ranges (1)
-
-
-
New Zealand
-
Otago Schist (1)
-
Torlesse Terrane (1)
-
-
-
biography (1)
-
Canada
-
Western Canada
-
British Columbia (1)
-
-
-
Cenozoic
-
lower Cenozoic (2)
-
middle Cenozoic (1)
-
Quaternary
-
Holocene (2)
-
Pleistocene (1)
-
-
Tertiary
-
Challis Volcanics (1)
-
lower Tertiary (1)
-
Neogene
-
Miocene
-
middle Miocene (2)
-
upper Miocene
-
Punchbowl Formation (1)
-
-
-
Pliocene (2)
-
-
Paleogene
-
Eocene
-
Colton Formation (2)
-
lower Eocene (2)
-
upper Eocene (1)
-
-
Oligocene
-
Hemlock Conglomerate (1)
-
-
Paleocene
-
lower Paleocene
-
K-T boundary (2)
-
-
upper Paleocene (1)
-
-
Sespe Formation (1)
-
Tyonek Formation (1)
-
-
-
upper Cenozoic (1)
-
-
Central America
-
Belize (1)
-
Guatemala (1)
-
Honduras (1)
-
-
continental drift (1)
-
crust (6)
-
crystal growth (1)
-
deformation (6)
-
diagenesis (1)
-
economic geology (1)
-
energy sources (1)
-
Europe
-
Alps
-
Western Alps
-
Ligurian Alps (1)
-
-
-
Southern Europe
-
Iberian Peninsula
-
Spain
-
Catalonia Spain (1)
-
Ebro Basin (1)
-
-
-
Italy
-
Apennines
-
Northern Apennines (1)
-
-
Liguria Italy
-
Ligurian Alps (1)
-
-
Piemonte Italy (1)
-
-
-
Western Europe
-
France
-
Corsica (1)
-
-
-
-
faults (14)
-
folds (10)
-
geochemistry (3)
-
geochronology (1)
-
geophysical methods (2)
-
igneous rocks
-
plutonic rocks
-
diorites
-
quartz diorites (1)
-
tonalite (2)
-
-
gabbros (1)
-
granites (2)
-
granodiorites (1)
-
quartzolite (1)
-
ultramafics
-
peridotites
-
harzburgite (1)
-
-
pyroxenite
-
orthopyroxenite (1)
-
-
-
-
volcanic rocks
-
andesites (3)
-
basalts (1)
-
pyroclastics
-
ignimbrite (2)
-
tuff (1)
-
-
rhyolites (1)
-
-
-
inclusions (1)
-
Integrated Ocean Drilling Program
-
Expedition 317
-
IODP Site U1351 (1)
-
IODP Site U1353 (1)
-
IODP Site U1354 (1)
-
-
-
intrusions (4)
-
Invertebrata
-
Mollusca
-
Bivalvia
-
Pterioida
-
Pteriina
-
Inocerami
-
Inoceramidae
-
Inoceramus (1)
-
-
-
-
-
-
Cephalopoda
-
Ammonoidea
-
Ammonites (1)
-
-
-
-
Protista
-
Foraminifera
-
Rotaliina
-
Rotaliacea
-
Nummulitidae
-
Nummulites (1)
-
-
-
-
-
-
-
isotopes
-
radioactive isotopes
-
Pb-206/Pb-204 (1)
-
Pb-207/Pb-204 (1)
-
Pb-208/Pb-204 (1)
-
-
stable isotopes
-
Hf-177/Hf-176 (2)
-
Nd-144/Nd-143 (2)
-
Pb-206/Pb-204 (1)
-
Pb-207/Pb-204 (1)
-
Pb-208/Pb-204 (1)
-
Sr-87/Sr-86 (1)
-
-
-
lava (1)
-
mantle (2)
-
Mediterranean region (1)
-
Mediterranean Sea
-
West Mediterranean (1)
-
-
Mesozoic
-
Bisbee Group (2)
-
Cretaceous
-
Lower Cretaceous
-
Albian (6)
-
Aptian (3)
-
Bear River Formation (1)
-
Mural Limestone (1)
-
Valanginian (1)
-
-
Middle Cretaceous (1)
-
Upper Cretaceous
-
Campanian
-
lower Campanian (1)
-
-
Castlegate Sandstone (1)
-
Cenomanian (2)
-
Codell Sandstone Member (1)
-
Coniacian (3)
-
Frontier Formation (1)
-
Hornbrook Formation (2)
-
Kaiparowits Formation (1)
-
K-T boundary (2)
-
Maestrichtian (2)
-
Mesaverde Group (2)
-
Santonian (1)
-
Senonian (2)
-
Straight Cliffs Formation (1)
-
Turonian (2)
-
Wahweap Formation (1)
-
-
-
Franciscan Complex (4)
-
Glen Canyon Group (1)
-
Great Valley Sequence (4)
-
Jurassic
-
Arapien Shale (1)
-
Lower Jurassic
-
Hettangian (1)
-
Sinemurian (1)
-
Toarcian (2)
-
-
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Impact of Mexican Border rift structural inheritance on Laramide rivers of the Tornillo basin, west Texas (USA): Insights from detrital zircon provenance
Modern sand provenance and transport across the western Gulf of Mexico margin
Reconstructing source-to-sink systems from detrital zircon core and rim ages
Early Cretaceous to Paleogene sandstone provenance and sediment-dispersal systems of the Cuicateco terrane, Mexico
ABSTRACT Sandstone petrography, detrital zircon geochronology, and sedimentology of Lower Cretaceous to Paleocene strata in the Cuicateco terrane of southern Mexico indicate an evolution from extensional basin formation to foreland basin development. The Early Cretaceous extensional basin is characterized by deposition of deep-marine fans and channels, which were mainly sourced from Mesoproterozoic and Permian crystalline rocks of the western shoulder of the rift basin. Some submarine fans, especially in the northern Cuicateco terrane, record an additional source in the Early Cretaceous (ca. 130 Ma) continental arc. The fans were fed by fluvial systems in updip parts of the extensional basin system. The transition from middle Cretaceous tectonic quiescence to Late Cretaceous shortening is recorded by the Turonian–Coniacian Tecamalucan Formation. The Tecamalucan Formation is interpreted as pre-orogenic deposits that represent submarine-fan deposits sourced from Aptian–Albian carbonate platform and pre-Mesozoic basement. The foreland basin in the Cuicateco terrane was established by the Maastrichtian, when foredeep strata of the Méndez Formation were deposited in the Cuicateco terrane, Veracruz basin, and across the western Gulf of Mexico, from Tampico to Tabasco. In the Zongolica region, these strata were derived from a contemporaneous volcanic arc (100–65 Ma) located to the west of the basin, the accreted Guerrero terrane (145–120 Ma), and the fold belt itself. By the Paleocene, sediments were transported to the foreland basin by drainages sourced in southwestern Mexico, such as the Late Cretaceous magmatic rocks of the Sierra Madre del Sur, and the Chortis block.
ABSTRACT Jurassic northward migration of Mexico, which lay on the southern part of the North America plate, resulted in temporal evolution of climate-sensitive depositional environments. Lower–Middle Jurassic rocks in central Mexico contain a record of warm-humid conditions, indicated by coal, plant fossils, and compositionally mature sandstone deposited in continental environments. Paleomagnetic data for central Oaxaca and other regions of central and eastern Mexico indicate that Lower and Middle Jurassic rocks were deposited at near-equatorial paleolatitudes. In the Late Jurassic, the Gulf of Mexico formed as a subsidiary basin of the Atlantic Ocean when the Pangea supercontinent ruptured. Upper Jurassic strata across Mexico, including eolianite and widespread evaporite deposits, indicate dry-arid conditions. Available paleomagnetic data (compaction-corrected) from southern and northeast Mexico for Upper Jurassic strata indicate deposition at ~15°N–20°N. As North America moved northward during Jurassic opening of the Atlantic Ocean, different latitudinal regions experienced coeval Middle–Late Jurassic climatic shifts. Climate transitions have been widely recognized in the Colorado Plateau region. The plateau left the horse latitudes in the late Middle Jurassic to reach temperate humid climates at ~40°N in the latest Jurassic. Affected by the same northward drift, the southern end of the North America plate represented by central Mexico gradually reached the arid horse latitudes in the late Middle Jurassic as the Colorado Plateau was leaving them. As a result, Late Jurassic epeiric platforms developed in the circum–Gulf of Mexico region after a long period of margin extension and were surrounded by arid land masses. We propose that hydrocarbon source-rock deposition was facilitated by arid conditions and wind-induced coastal upwelling.
ABSTRACT The Gulf of Mexico is best understood as a subsidiary basin to the Atlantic, resulting from breakup of Pangea. The rifting process and stratigraphy preceding opening of the gulf are, however, not fully understood. We present new stratigraphic, sedimentologic, and provenance data for the Todos Santos Formation (now Todos Santos Group) in southern Mexico. The new data support a two-stage model for rifting in the Gulf of Mexico. Field and analytical evidence demonstrate that strata assigned to the Todos Santos Group in Mexico belong to two unrelated successions that were juxtaposed after rotation of the Yucatán block. An Upper Triassic fluvial siliciclastic succession in the western Veracruz basin is intruded by the San Juan del Río pluton (194 Ma, U-Pb) along the Valle Nacional fault. We refer to this succession as the Valle Nacional formation (informal) of the Todos Santos Group, and correlate it with El Alamar Formation of northeast Mexico and the Eagle Mills Formation of the northern Gulf of Mexico. Triassic red beds register an early rifting phase in western equatorial Pangea. Sandstone composition indicates that the Valle Nacional formation is mostly arkoses derived from multiple sources. Paleocurrent indicators in fluvial strata of the Valle Nacional formation are S-SW directed, but restoration of paleomagnetically determined counterclockwise rotation indicates a W-SW–flowing fluvial system. Triassic rifting in the Valle Nacional formation and the Central Cordillera of Colombia Triassic extensional event, the record of which is preserved in mid-crustal levels, may represent conjugate margins. The Early–Middle Jurassic Nazas continental volcanic arc predated the Jurassic rifting phase that led to opening of the gulf. A record of arc magmatism is present in eastern Mexico underlying Middle Jurassic synrift successions, and it is present in La Boca and Cahuasas formations in the Sierra Madre Oriental and La Silla Formation north of the Chiapas Massif. These units have a similar age range between ca. 195 and 170 Ma. Arc magmatism in eastern Mexico is correlated with the Jurassic Cordilleran arc of Sonora, California, and Arizona, as well as the Jurassic arc of the Central Cordillera of Colombia. La Boca and La Silla units record intra-arc extension driven by slab rollback. The Jurassic rifting phase is recorded in the Jiquipilas formation of the Todos Santos Group and is younger than ca. 170 Ma, based on young zircon ages at multiple locations. The informal El Diamante member of the Jiquipilas formation records the maximum displacement rift stage (rift climax). Coarse-grained, pebbly, arkosic sandstones with thin siltstone intercalations and thick conglomerate packages of the Jericó member of the Jiquipilas formation are interpreted as deposits of a high-gradient, axial rift fluvial system fed by transverse alluvial fans. These rivers flowed north to northeast (restored for ~35° rotation of Yucatán). The Concordia member of the Jiquipilas formation records the postrift stage. Thick synrift successions are preserved in the subsurface in the Tampico-Misantla basin, but they cannot be easily assigned to the Triassic or the Jurassic rifting stages because of insufficient study. The Todos Santos Group at its type locality in Guatemala marks the base of the Lower Cretaceous transgression. Overall, three regional extensional events are recognized in the western Gulf of Mexico Mesozoic margin. These include Upper Triassic early rifting, an extensional continental arc, and Middle Jurassic main rifting events that culminated with rotation of Yucatán and formation of oceanic crust in the gulf.
ABSTRACT A comprehensive correlation chart of Pennsylvanian–Eocene stratigraphic units in Mexico, adjoining parts of Arizona, New Mexico, south Texas, and Utah, as well as Guatemala, Belize, Honduras, and Colombia, summarizes existing published data regarding ages of sedimentary strata and some igneous rocks. These data incorporate new age interpretations derived from U-Pb detrital zircon maximum depositional ages and igneous dates that were not available as recently as 2000, and the chart complements previous compilations. Although the tectonic and sedimentary history of Mexico and Central America remains debated, we summarize the tectonosedimentary history in 10 genetic phases, developed primarily on the basis of stratigraphic evidence presented here from Mexico and summarized from published literature. These phases include: (1) Gondwanan continental-margin arc and closure of Rheic Ocean, ca. 344–280 Ma; (2) Permian–Triassic arc magmatism, ca. 273–245 Ma; (3) prerift thermal doming of Pangea and development of Pacific margin submarine fans, ca. 245–202 Ma; (4) Gulf of Mexico rifting and extensional Pacific margin continental arc, ca. 200–167 Ma; (5) salt deposition in the Gulf of Mexico basin, ca. 169–166? Ma; (6) widespread onshore extension and rifting, ca. 160–145 Ma; (7) arc and back-arc extension, and carbonate platform and basin development (ca. 145–116 Ma); (8) carbonate platform and basin development and oceanic-arc collision in Mexico, ca. 116–100 Ma; (9) early development of the Mexican orogen in Mexico and Sevier orogen in the western United States, ca. 100–78 Ma; and (10) late development of the Mexican orogen in Mexico and Laramide orogeny in the southwestern United States, ca. 77–48 Ma.
Transition from Late Jurassic rifting to middle Cretaceous dynamic foreland, southwestern U.S. and northwestern Mexico
Orogen proximal sedimentation in the Permian foreland basin
Detrital zircons and sediment dispersal from the Coahuila terrane of northern Mexico into the Marathon foreland of the southern Midcontinent
Role of subducted sediments in plate interface dynamics as constrained by Andean forearc (paleo)topography
ABSTRACT Forearc topography and inferred paleotopography are key constraints on the processes acting at plate interfaces along subduction margins. We used along-strike variations in modern topography, trench sediment thickness, and instrumental seismic data sets over >2000 km of the Chilean margin to test previously proposed feedbacks among subducted sediments, plate interface rheology, megathrust seismicity, and forearc elevation. Observed correlations are consistent with subducted sediments playing a prominent role in controlling plate interface rheology, which, in turn, controls the downdip distribution of megath-rust seismicity and long-term forearc elevation. High (low) rates of trench sedimentation promote long-term interseismic coupled offshore forearc uplift (subsidence) and onshore forearc platform subsidence (uplift). Low trench sedimentation rates also promote deeper megathrust seismic slip, enhancing short-wavelength coastal zone uplift. Shallowing of subducting slabs contributes to a reduction in coastal zone–onshore forearc relief, in turn preventing formation of onshore forearc basins. The extremely low denudation rates of hyperarid northern Chile have allowed better reconstructions of the histories of paleoel-evations and paleoclimate compared to other sections of the forearc. Even if these histories are not sufficiently resolved to unequivocally assign causality among climate variability, changes in plate interface frictional properties, and forearc elevation, they are consistent with the onset of hyperaridity in the coastal zone at 25–20 Ma (1) triggering long-term, long-wavelength offshore forearc subsidence and onshore forearc uplift, and (2) accelerating short-wavelength coastal zone uplift.
ABSTRACT Cretaceous forearc strata of the Ochoco basin in central Oregon may preserve a record of regional transpression, magmatism, and mountain building within the Late Cretaceous Cordillera. Given the volume of material that must have been eroded from the Sierra Nevada and Idaho batholith to result in modern exposures of mid-and deep-crustal rocks, Cretaceous forearc basins have the potential to preserve a record of arc magmatism no longer preserved within the arc, if forearc sediment can be confidently linked to sources. Paleogeographic models for mid-Cretaceous time indicate that the Blue Mountains and the Ochoco sedimentary overlap succession experienced postdepositional, coast-parallel, dextral translation of less than 400 km or as much as 1700 km. Our detailed provenance study of the Ochoco basin and comparison of Ochoco basin provenance with that of the Hornbrook Formation, Great Valley Group, and Methow basin test paleogeographic models and the potential extent of Cretaceous forearc deposition. Deposition of Ochoco strata was largely Late Cretaceous, from Albian through at least Santonian time (ca. 113–86 Ma and younger), rather than Albian–Cenomanian (ca. 113–94 Ma). Provenance characteristics of the Ochoco basin are consistent with northern U.S. Cordilleran sources, and Ochoco strata may represent the destination of much of the mid- to Late Cretaceous Idaho arc that was intruded and eroded during and following rapid transpression along the western Idaho shear zone. Our provenance results suggest that the Hornbrook Formation and Ochoco basin formed two sides of the same depositional system, which may have been linked to the Great Valley Group to the south by Coniacian time, but was not connected to the Methow basin. These results limit northward displacement of the Ochoco basin to less than 400 km relative to the North American craton, and suggest that the anomalously shallow paleomagnetic inclinations may result from significant inclination error, rather than deposition at low latitudes. Our results demonstrate that detailed provenance analysis of forearc strata complements the incomplete record of arc magmatism and tectonics preserved in bedrock exposures, and permits improved understanding of Late Cretaceous Cordilleran paleogeography.
ABSTRACT The Great Valley forearc basin records Jurassic(?)–Eocene sedimentation along the western margin of North America during eastward subduction of the Farallon plate and development of the Sierra Nevada magmatic arc. The four-dimensional (4-D) basin model of the northern Great Valley forearc presented here was designed to reconstruct its depositional history from Tithonian through Maastrichtian time. Based on >1200 boreholes, the tops of 13 formations produce isopach maps and cross sections that highlight the spatial and temporal variability of sediment accumulation along and across the basin. The model shows the southward migration of depocenters within the basin during the Cretaceous and eastward lapping of basin strata onto Sierra Nevada basement. In addition, the model presents the first basement map of the entire Sacramento subbasin, highlighting its topography at the onset of deposition of the Great Valley Group. Minimum volume estimates for sedimentary basin fill reveal variable periods of flux, with peak sedimentation corresponding to deposition of the Sites Sandstone during Turonian to Coniacian time. Comparison of these results with flux estimates from magmatic source regions shows a slight lag in the timing of peak sedimentation, likely reflecting the residence time from pluton emplacement to erosion. This model provides the foundation for the first three-dimensional subsidence analysis on an ancient forearc basin, which will yield insight into the mechanisms driving development of accommodation along convergent margins.
ABSTRACT We investigated the relationship between tectonism and sedimentation in the Karoo Basin by integrating U-Pb single-grain detrital zircon analyses from seven sandstones with U-Pb zircon analyses from 30 volcanic tuffs. U-Pb detrital zircon data from the Karoo Supergroup strata indicate that the source of the turbiditic, deltaic, and fluvial sediments included an active volcanic province, with increasing contribution from the nearby Cape fold belt through time. The depositional ages obtained from the turbiditic strata of the Karoo Basin, based on U-Pb zircon tuff ages, and the published ages for Cape fold belt deformation suggest that the influx of coarse clastic sediment was synchronous with active deformation of the fold belt during the Gondwanan orogeny. Our tuff ages indicate that peak magmatism began prior to a major deformation event and predated turbidite deposition; initial sedimentation in Karoo turbidite systems coincided with a major deformational phase in the Cape fold belt. U-Pb detrital zircon ages reveal that mid-Permian Karoo turbidites are largely composed of Permian volcaniclastic sediment, whereas the Late Permian and Early Triassic sediment was increasingly sourced from the Cape Supergroup, now exposed in the Cape fold belt. While structural development of the Cape fold belt likely controlled the entry points of sediment into the basin, orogenic uplift may have partitioned the sediment routing systems, severing the connectivity between the active magmatic arc and the basin. We present a model in which a combination of volcanic ejecta, transported via atmospheric suspension, and the formation of entrenched drainages in the catchment areas allowed partial bypassing of continental drainage divides and deposition onto the leeward side of the Cape fold belt.
ABSTRACT Orogenic belts, the main factories of continental crust and the most efficient agents of continental deformation, are commonly extremely complex structures. Every orogenic belt is unique in detail, but they are generally similar to each other, having mainly been products of subduction and continental collision. Because of that common origin, they all share common functional organs, such as magmatic arcs, various back-arc and retro-arc features, and multifarious fore-arc environments, collisional sutures, etc. The modern orogenic belts usually display adequate detail about these organs, enabling us to identify them even when they are deformed or otherwise dislocated. In reconstructing now-disrupted orogenic belts, we are after one or more Ariadne’s threads to follow the original structure from one package of rock to another. The most prominent, laterally persistent, and easy-to-follow structures among the major orogenic features are the magmatic arcs. As they are the common expression of their subduction zones, they form linear or arcuate lines along the strike, and they usually move episodically inwards or outwards, being located behind sharply defined magmatic fronts. Present-day dating techniques provide high-resolution dates from magmatic rocks, and the migration of the magmatic front is easily detectable. They form the main Ariadne’s thread in orogenic studies. Where they are absent, the most helpful structures possessing lateral persistence are the now-deformed Atlantic-type continental margins and suture zones. We chose two major fossil orogenic belts, namely, the Tethysides, and the Altaids, to emphasize the methodology of comparative anatomy of orogenic belts. There have been many theories regarding the evolution of these orogenic belts. However, they are either local, only dealing with a small portion of orogen, or they are in conflict with presently active processes. We underline the importance of magmatic fronts as reliable witnesses of the geodynamic evolution of major orogenic collages. This paper aims to disperse the mist upon the reconstructions of complexly deformed orogenic belts with the simplest possible interpretations that help us to form testable hypotheses that can be checked with a variety of geological databases.
Provenance and alteration of feldspathic and quartzose sediments in southern Mexico: An application of Krynine’s hypothesis on second-cycle arkose
ABSTRACT In 1935, Krynine postulated that first-cycle arkose in the humid tropical setting of southern Mexico can be rapidly eroded with minimal chemical weathering and redeposited as second-cycle arkose. Modern quantitative data confirm this hypothesis and highlight exceptions where first-cycle arkosic sediments have been diagenetically altered by intense weathering to yield second-cycle quartz arenites. In this study, extensive sampling of upland source rocks and their derived sediments provided a robust data set with which to quantitatively evaluate the composition and provenance of Holocene sediments. Three upland source terrains were identified: Paleozoic crystalline basement of the Chiapas Massif; Mesozoic to Cenozoic siliciclastic and carbonate rocks of the Chiapas fold belt; and Cenozoic sedimentary rocks in the foothills of the fold belt. Holocene sediments from these source terrains are grouped into seven facies (A–G) based on their provenance and geographic location. Facies A consists of feldspathic sediments from the Mezcalapa-Grijalva River that are sourced from the Chiapas Massif. Facies B consists of lithic-rich sediments from the same area that are derived from the Chiapas fold belt. Facies A and B consist predominantly of first-cycle sand capable of yielding arkosic deposits. Facies C represents a mixture of Facies A and B sands deposited along the course of the Mezcalapa-Grijalva River. Facies D (from Rio Sierra) and Facies E (from Rio Pedregal) represent second-cycle feldspathic sands of the coastal-plain delta and were derived from Cenozoic sedimentary rocks of the foothills. Mild chemical weathering due to rapid mechanical erosion enabled the creation of these arkosic deposits. They are less feldspathic than their parents and have limited occurrence due to mixing with less feldspathic first-cycle sands downstream from their sources. Facies F (from Rio Zanapa) and Facies G (from Lagunas Rosario and Enmedio) represent second-cycle quartzose sands of the low-lying savanna that were also derived from Cenozoic sedimentary rocks in the foothills of the fold belt. Intense, long-term (>10,000 yr) chemical weathering of these sands has precluded the formation of arkoses, instead yielding quartz arenites. They are more weathered than the delta sands (Facies D, E) with a greater loss of feldspar and carbonate detritus. They are enriched in silica and depleted in alumina, CaO, Na 2 O, and K 2 O relative to Facies A arkoses due to loss of feldspars and mafic minerals. Second-cycle sediments eroded from Tertiary sedimentary rocks in the foothills (Facies D–G) contain detrital serpentine and chromite with high abundances of Cr and Ni, suggesting an ultramafic component in their provenance. Cr and Ni are effective tracers for second-cycle components in sands of mixed provenance.
Paleomagnetism and rotation history of the Blue Mountains, Oregon, USA
ABSTRACT An important element in reconstructions of the Cordilleran margin of North America includes longstanding debate regarding the timing and amount of rotation of the Blue Mountains in eastern Oregon, and the origin of geometric features such as the Columbia Embayment, which was a subject of some of Bill Dickinson’s early research. Suppositions of significant clockwise rotation of the Blue Mountains derived from Dickinson’s work were confirmed in the 1980s by paleomagnetic results from Late Jurassic–Early Cretaceous plutonic rocks, and secondary directions from Permian–Triassic units of the Wallowa–Seven Devils arc that indicate ~60° clockwise rotation of the Blue Mountains. This study reports new paleomagnetic data from additional locations of these Late Jurassic–Early Cretaceous plutonic rocks, as well as Jurassic sedimentary rocks of the Suplee-Izee area. Samples from three sites from the Bald Mountain Batholith, two sites from small intrusive bodies near Ritter, Oregon, and six sites from the Wallowa Batholith have well-defined magnetization components essentially identical to those found by previous workers. The combined mean direction of both sets of data from these Late Jurassic to Early Cretaceous intrusive rocks is D = 30, I = 63, α 95 = 6°. Samples from Jurassic sedimentary rocks in the Suplee-Izee area include four sites of the Lonesome Formation, three sites of andesitic volcanics in the Snowshoe Formation, and three sites from the Trowbridge Formation. The Lonesome and Trowbridge samples all had very well-defined, two component magnetizations. The in-situ mean of the combined Lonesome and Trowbridge Formations is D = 28, I = 63, α 95 = 15°. Upon tilt-correction, the site means of these units scatter and fail the paleomagnetic fold test in spectacular fashion. The similarity between the directions obtained from the remagnetized Jurassic rocks, and from the Late Jurassic to Early Cretaceous plutonic rocks suggests that a widespread remagnetization accompanied emplacement of the intrusives. Similar overprints are found in Permian and Triassic rocks of the Blue Mountains. Directions from 64 sites of these rocks yields a mean of D = 33°, I = 64°, k= 26, α 95 = 3.7°. Comparing the directions with North America reference poles, a clockwise rotation of 60° ± 9° with translation of 1000 ± 500 km is found. Together with data from Cretaceous and Eocene rocks, clockwise rotation of the Blue Mountains has occurred throughout the past ca. 130 Ma, with long-term rotation rates of 0.4 to 1 °/Ma. Approximately 1000 km of northward translation also occurred during some of this time.
ABSTRACT The Sierra Nevada batholith of California represents the intrusive footprint of composite Mesozoic Cordilleran arcs built through pre-Mesozoic strata exposed in isolated pendants. Neoproterozoic to Permian strata, which formed the prebatholithic framework of the Sierran arc, were emplaced against the tectonically reorganized SW Laurentian continental margin in the late Paleozoic, culminating with final collapse of the fringing McCloud arc against SW Laurentia. Synthesis of 22 new and 135 existing detrital zircon U/Pb geochronology sample analyses clarifies the provenance, affinity, and history of Sierra Nevada framework rocks. Framework strata comprise terranes with distinct postdepositional histories and detrital zircon provenance that form three broad groups: allochthonous Neoproterozoic to lower Paleozoic strata with interpreted sediment sources from Idaho to northern British Columbia; Neoproterozoic to Permian strata parautochthonous to SW Laurentia; and middle to upper Paleozoic deposits related to the fringing McCloud arc. Only three sedimentary packages potentially contain detritus from rocks exotic to western Laurentia: the Sierra City mélange, chert-argillite unit, and Twin Lakes assemblage. We reject previous correlations of eastern Sierra Nevada strata with the Roberts Mountains and Golconda allochthons and find no evidence that these allochthons ever extended westward across Owens Valley. Snow Lake terrane detrital ages are consistent with interpreted provenance over a wide range from the Mojave Desert to central Idaho. The composite detrital zircon population of all analyses from pre-Mesozoic Sierran framework rocks is indistinguishable from that of the Neoproterozoic to Permian SW Laurentian margin, providing a strong link, in aggregate, between these strata and western Laurentia. These findings support interpretations that the Sierran arc was built into thick sediments underpinned by transitional to continental western Laurentian lithosphere. Thus, the Mesozoic Sierra Nevada arc is native to the SW Cordilleran margin, with the Sierran framework emplaced along SW Laurentia prior to Permian–Triassic initiation of Cordilleran arc activity.
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.
ABSTRACT The Coast Ranges Province of central California provides an important record for the timing of convergence of the North American–Pacific plate boundary along the San Andreas fault system. The sedimentary record, in conjunction with seismic interpretation and backstripping methods, constrains the age of onset of Diablo and Temblor Range uplift and concurrent subsidence of the San Joaquin Basin along the San Andreas fault to 6.2–5.4 Ma. This age of convergence and uplift of the Coast Ranges is compatible with plate-tectonic circuit models, where clockwise rotation of Pacific–North American plate motion produced plate convergence at this latitude. However, changes in plate motion do not explain a widespread structural and sedimentary event at ca. 3.5 Ma that is evident in the western San Joaquin Basin and other basins in California. Possible drivers for the 3.5 Ma event include eustatic sea-level change, geomorphic forcing, epeirogeny related to mantle lithosphere removal, and flexural tilt of the Sierra Nevada–Great Valley microplate.