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NARROW
GeoRef Subject
-
all geography including DSDP/ODP Sites and Legs
-
Africa
-
North Africa
-
Algeria (1)
-
Atlas Mountains
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
Morocco
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
Tindouf Basin (1)
-
Western Sahara (1)
-
-
West Africa
-
Mauritanides (1)
-
-
West African Shield (1)
-
-
Arctic region
-
Greenland (1)
-
-
Asia
-
Arabian Peninsula
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Oman (2)
-
Saudi Arabia (1)
-
-
-
Atlantic Ocean
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North Atlantic
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Georges Bank (1)
-
Gulf of Maine (1)
-
Gulf of Mexico (1)
-
Gulf of Saint Lawrence (4)
-
Northwest Atlantic (1)
-
-
-
Atlantic Ocean Islands
-
Shetland Islands
-
Unst (1)
-
-
-
Atlantic region (1)
-
Australasia (1)
-
Avalon Zone (3)
-
Bay of Islands (1)
-
Caledonides (11)
-
Canada
-
Eastern Canada
-
Gander Zone (2)
-
Maritime Provinces
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New Brunswick
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Miramichi Bay (1)
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-
-
Meguma Terrane (1)
-
Newfoundland and Labrador
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Newfoundland
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Baie Verte Peninsula (5)
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Burlington Peninsula (1)
-
Humber Arm Allochthon (7)
-
Port au Port Peninsula (3)
-
-
-
Ontario
-
Manitoulin District Ontario
-
Manitoulin Island (1)
-
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Russell County Ontario (1)
-
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Ottawa Valley (2)
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Quebec
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Anticosti Island (2)
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Beauce County Quebec (2)
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Gaspe Peninsula (16)
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Quebec City Quebec (2)
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Sherbrooke County Quebec (1)
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Thetford Mines (2)
-
-
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Elzevir Terrane (1)
-
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Caribbean region
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West Indies
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Antilles
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Greater Antilles
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Jamaica (1)
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Puerto Rico (1)
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Dunnage Melange (1)
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Dunnage Zone (5)
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Europe
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Alps
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Prealps (1)
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Jutland (1)
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Western Europe
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Ireland
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Mayo Ireland (1)
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Scandinavia
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Koli Nappe (1)
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Norway
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Nordland Norway
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Lofoten Islands (1)
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Narvik Norway (1)
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Northern Norway (1)
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United Kingdom
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Great Britain
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Scotland
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Great Glen Fault (1)
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Scottish Highlands
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Grampian Highlands (2)
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Scottish Northern Highlands (1)
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Shetland Islands
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Unst (1)
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Northern Ireland (2)
-
-
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Grand Canyon (1)
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Green Mountains (4)
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Hare Bay (2)
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Mexico (1)
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Mohawk Valley (4)
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North America
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Appalachian Basin (9)
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Appalachians
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Appalachian Plateau (1)
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Blue Ridge Mountains (9)
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Blue Ridge Province (11)
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Carolina slate belt (2)
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Central Appalachians (11)
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Great Appalachian Valley (2)
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Hudson Highlands (1)
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Northern Appalachians (64)
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Piedmont
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Inner Piedmont (2)
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-
Southern Appalachians (21)
-
Valley and Ridge Province (6)
-
-
Canadian Shield
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Grenville Province (5)
-
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Champlain Valley (1)
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Great Lakes region (1)
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Humber Zone (15)
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Michigan Basin (2)
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North American Craton (1)
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Rocky Mountains
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U. S. Rocky Mountains (1)
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Saint Lawrence Lowlands (2)
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Saint Lawrence Valley (2)
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Raleigh Belt (1)
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Russian Platform (1)
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South America
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Andes (1)
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Table Mountain (1)
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United States
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Alabama (8)
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Alaska
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Brooks Range (1)
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Arizona (1)
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Arkansas (1)
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Arkoma Basin (1)
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Atlantic Coastal Plain (2)
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Benton Uplift (1)
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Black Warrior Basin (1)
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Blue Ridge Mountains (9)
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Brevard Zone (2)
-
Bronson Hill Anticlinorium (5)
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Carolina Terrane (2)
-
Cincinnati Arch (1)
-
Connecticut
-
Fairfield County Connecticut (2)
-
Litchfield County Connecticut (1)
-
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Connecticut Valley (2)
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Delaware
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New Castle County Delaware (1)
-
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District of Columbia (1)
-
Eastern U.S. (4)
-
Georgia
-
Bartow County Georgia
-
Cartersville Georgia (1)
-
-
-
Great Smoky Fault (3)
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Great Smoky Mountains (2)
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Hayesville Fault (1)
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Hudson Valley (2)
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Illinois Basin (1)
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Kentucky (1)
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Maine
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Aroostook County Maine (1)
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Norumbega fault zone (1)
-
-
Maryland
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Baltimore County Maryland
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Baltimore Maryland (2)
-
-
-
Massachusetts
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Berkshire County Massachusetts (2)
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Franklin County Massachusetts (2)
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Hampden County Massachusetts (1)
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Hampshire County Massachusetts (1)
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Michigan (1)
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Midwest (1)
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Mississippi Valley
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Upper Mississippi Valley (1)
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Nashville Dome (1)
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New England (20)
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New Hampshire
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Coos County New Hampshire (1)
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Grafton County New Hampshire (1)
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New Jersey
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Atlantic County New Jersey (1)
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Hunterdon County New Jersey (1)
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Sussex County New Jersey
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Beemerville New Jersey (1)
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Warren County New Jersey (1)
-
-
New York
-
Adirondack Mountains (3)
-
Albany County New York (2)
-
Dutchess County New York (1)
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Fulton County New York (2)
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Hamilton County New York (1)
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Herkimer County New York (3)
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Jefferson County New York (1)
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Lewis County New York (1)
-
Montgomery County New York (3)
-
Oneida County New York (1)
-
Orange County New York (2)
-
Saratoga County New York (2)
-
Schenectady County New York (1)
-
Sullivan County New York (1)
-
Washington County New York (4)
-
Westchester County New York (3)
-
-
North Carolina
-
Caldwell County North Carolina (1)
-
Cherokee County North Carolina (1)
-
Haywood County North Carolina (1)
-
Macon County North Carolina (3)
-
Randolph County North Carolina (1)
-
Stanly County North Carolina (1)
-
Swain County North Carolina (1)
-
Watauga County North Carolina (1)
-
Wilkes County North Carolina (1)
-
-
Ohio (2)
-
Oklahoma
-
Wichita Uplift (1)
-
-
Ouachita Belt (1)
-
Ouachita Mountains (1)
-
Pennsylvania
-
Clearfield County Pennsylvania (1)
-
Dauphin County Pennsylvania (1)
-
Delaware County Pennsylvania (1)
-
-
Pine Mountain Window (2)
-
Potomac River (2)
-
Reading Prong (1)
-
South Carolina
-
Lancaster County South Carolina (1)
-
-
Talladega Front (3)
-
Tennessee
-
Cocke County Tennessee (1)
-
Grainger County Tennessee (1)
-
Knox County Tennessee (1)
-
Sevier County Tennessee (1)
-
-
Tennessee River (1)
-
Texas
-
Amarillo Uplift (1)
-
-
U. S. Rocky Mountains (1)
-
Vermont
-
Addison County Vermont (1)
-
Orange County Vermont (1)
-
Rutland County Vermont (2)
-
Windham County Vermont (1)
-
Windsor County Vermont (1)
-
-
Virginia
-
Clarke County Virginia (1)
-
Culpeper County Virginia (1)
-
Fairfax County Virginia (1)
-
Fauquier County Virginia (1)
-
Loudoun County Virginia (1)
-
Louisa County Virginia (1)
-
Madison County Virginia (1)
-
Page County Virginia (1)
-
Pittsylvania County Virginia (1)
-
Rappahannock County Virginia (1)
-
Warren County Virginia (1)
-
-
West Virginia (1)
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Yavapai Province (1)
-
-
White Mountains (1)
-
-
commodities
-
barite deposits (7)
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bitumens (1)
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brines (2)
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marble deposits (1)
-
metal ores
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arsenic ores (1)
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base metals (1)
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chromite ores (1)
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cobalt ores (1)
-
copper ores (4)
-
gold ores (2)
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iron ores (1)
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lead ores (2)
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lead-zinc deposits (4)
-
molybdenum ores (2)
-
nickel ores (2)
-
silver ores (2)
-
tin ores (1)
-
tungsten ores (1)
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uranium ores (2)
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zinc ores (5)
-
-
mineral deposits, genesis (10)
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mineral exploration (1)
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petroleum
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natural gas (4)
-
-
-
elements, isotopes
-
carbon
-
C-13/C-12 (6)
-
organic carbon (1)
-
-
chemical ratios (1)
-
halogens
-
fluorine (1)
-
-
hydrogen (1)
-
isotope ratios (22)
-
isotopes
-
radioactive isotopes
-
Ar-40/Ar-39 (1)
-
Pb-206/Pb-204 (1)
-
Pb-208/Pb-204 (1)
-
Sm-147/Nd-144 (2)
-
-
stable isotopes
-
Ar-40/Ar-39 (1)
-
C-13/C-12 (6)
-
Hf-177/Hf-176 (2)
-
Nd-144/Nd-143 (8)
-
O-18/O-16 (12)
-
Pb-206/Pb-204 (1)
-
Pb-208/Pb-204 (1)
-
S-34/S-32 (3)
-
Sm-147/Nd-144 (2)
-
Sr-87/Sr-86 (10)
-
-
-
Lu/Hf (1)
-
metals
-
actinides
-
thorium (1)
-
-
alkali metals
-
cesium (1)
-
lithium (1)
-
-
alkaline earth metals
-
strontium
-
Sr-87/Sr-86 (10)
-
-
-
chromium (2)
-
hafnium
-
Hf-177/Hf-176 (2)
-
-
iron (1)
-
lead
-
Pb-206/Pb-204 (1)
-
Pb-208/Pb-204 (1)
-
-
nickel (1)
-
niobium (1)
-
rare earths
-
neodymium
-
Nd-144/Nd-143 (8)
-
Sm-147/Nd-144 (2)
-
-
samarium
-
Sm-147/Nd-144 (2)
-
-
yttrium (1)
-
-
tantalum (1)
-
zirconium (1)
-
-
noble gases
-
argon
-
Ar-40/Ar-39 (1)
-
-
-
oxygen
-
O-18/O-16 (12)
-
-
sulfur
-
S-34/S-32 (3)
-
-
-
fossils
-
Chordata
-
Vertebrata (1)
-
-
Graptolithina (13)
-
Hemichordata (1)
-
ichnofossils (1)
-
Invertebrata
-
Brachiopoda (2)
-
Bryozoa (2)
-
Echinodermata
-
Crinozoa
-
Crinoidea (2)
-
-
-
Mollusca
-
Gastropoda (2)
-
-
-
microfossils
-
Conodonta (3)
-
-
-
geochronology methods
-
Ar/Ar (19)
-
fission-track dating (1)
-
K/Ar (5)
-
Lu/Hf (1)
-
paleomagnetism (6)
-
Pb/Pb (3)
-
Rb/Sr (8)
-
Sm/Nd (2)
-
thermochronology (3)
-
U/Pb (47)
-
U/Th/Pb (1)
-
-
geologic age
-
Cenozoic
-
Tertiary
-
Paleogene
-
Eocene (1)
-
Paleocene (1)
-
-
-
-
Dalradian (2)
-
Mesozoic
-
Cretaceous
-
Comanchean
-
Rodessa Formation (1)
-
-
Lower Cretaceous
-
Rodessa Formation (1)
-
-
-
Jurassic
-
Norphlet Formation (1)
-
Upper Jurassic
-
Haynesville Formation (1)
-
Kimmeridgian (1)
-
-
-
-
Paleozoic
-
Acatlan Complex (1)
-
Cambrian
-
Acadian (5)
-
Lower Cambrian
-
Chilhowee Group (1)
-
Murphy Marble (2)
-
Rome Formation (2)
-
-
Upper Cambrian (2)
-
-
Carboniferous
-
Lower Carboniferous (2)
-
Mississippian
-
Redwall Limestone (1)
-
-
Pennsylvanian
-
Middle Pennsylvanian
-
Allegheny Group (4)
-
-
Morrow Formation (1)
-
Pottsville Group (2)
-
Upper Pennsylvanian
-
Wescogame Formation (1)
-
-
Watahomigi Formation (1)
-
-
Upper Carboniferous (1)
-
-
Devonian
-
Lower Devonian (5)
-
Middle Devonian
-
Marcellus Shale (1)
-
Onondaga Limestone (1)
-
Tully Limestone (1)
-
-
Upper Devonian (1)
-
-
Knox Group (2)
-
lower Paleozoic
-
Ashe Formation (2)
-
Chopawamsic Formation (2)
-
Conococheague Formation (1)
-
Glenarm Series (1)
-
Wilmington Complex (3)
-
-
Matapedia Group (1)
-
middle Paleozoic
-
Hillabee Chlorite Schist (1)
-
-
Ordovician
-
Chickamauga Group (1)
-
Clays Ferry Formation (1)
-
Lexington Limestone (1)
-
Lower Ordovician
-
Arenigian (2)
-
Beekmantown Group (2)
-
-
Lushs Bight Group (1)
-
Martinsburg Formation (7)
-
Middle Ordovician
-
Ammonoosuc Volcanics (2)
-
Blackriverian (1)
-
Cloridorme Formation (3)
-
Dapingian (1)
-
Darriwilian (1)
-
Dolgeville Formation (2)
-
Normanskill Formation (3)
-
Table Head Group (1)
-
-
Tetagouche Group (2)
-
Trenton Group (8)
-
Upper Ordovician
-
Ashgillian (2)
-
Caradocian (3)
-
Cincinnatian
-
Richmondian (2)
-
-
Cortlandt Complex (1)
-
Fairview Formation (1)
-
Juniata Formation (2)
-
Katian (2)
-
Mohawkian (1)
-
Sandbian (2)
-
Trentonian (7)
-
-
Utica Shale (4)
-
-
Permian
-
Coconino Sandstone (1)
-
Kaibab Formation (1)
-
Toroweap Formation (1)
-
-
Sauk Sequence (2)
-
Shawangunk Formation (1)
-
Silurian
-
Lower Silurian
-
Llandovery (1)
-
Qalibah Formation (1)
-
Tuscarora Formation (3)
-
Wenlock (1)
-
-
Middle Silurian
-
Rose Hill Formation (1)
-
-
Upper Silurian
-
Ludlow (1)
-
Pridoli (1)
-
-
-
Supai Formation (1)
-
Talladega Group (1)
-
Tippecanoe Sequence (5)
-
upper Paleozoic
-
Kaskaskia Sequence (1)
-
-
Wissahickon Formation (3)
-
-
Phanerozoic (1)
-
Precambrian
-
Archean (1)
-
Baltimore Gneiss (4)
-
Catoctin Formation (2)
-
Great Smoky Group (1)
-
upper Precambrian
-
Proterozoic
-
Mesoproterozoic (2)
-
Neoproterozoic
-
Ediacaran (1)
-
Lynchburg Formation (1)
-
Moinian (1)
-
Tonian (1)
-
Walden Creek Group (1)
-
-
Paleoproterozoic (2)
-
-
-
-
-
igneous rocks
-
igneous rocks
-
plutonic rocks
-
anorthosite (2)
-
diorites
-
quartz diorites (1)
-
tonalite (3)
-
trondhjemite (1)
-
-
gabbros (5)
-
granites (13)
-
granodiorites (3)
-
pegmatite (3)
-
quartz monzonite (1)
-
syenites
-
nepheline syenite (1)
-
-
ultramafics (4)
-
-
volcanic rocks
-
andesites (1)
-
basalts
-
mid-ocean ridge basalts (3)
-
tholeiite (1)
-
-
glasses (1)
-
phonolites (1)
-
pyroclastics (1)
-
-
-
ophiolite (11)
-
-
metamorphic rocks
-
K-bentonite (2)
-
metamorphic rocks
-
amphibolites (8)
-
eclogite (5)
-
gneisses
-
granite gneiss (1)
-
orthogneiss (1)
-
paragneiss (1)
-
tonalite gneiss (1)
-
-
granulites (4)
-
marbles (3)
-
metaigneous rocks
-
meta-andesite (1)
-
metabasalt (1)
-
metagabbro (2)
-
metarhyolite (1)
-
serpentinite (1)
-
-
metaplutonic rocks (2)
-
metasedimentary rocks
-
metaconglomerate (1)
-
metapelite (3)
-
paragneiss (1)
-
-
metasomatic rocks
-
serpentinite (1)
-
-
metavolcanic rocks (8)
-
migmatites (3)
-
mylonites (5)
-
phyllites (2)
-
quartzites (1)
-
schists
-
blueschist (1)
-
greenstone (1)
-
-
slates (5)
-
-
ophiolite (11)
-
turbidite (9)
-
-
minerals
-
carbonates
-
dolomite (2)
-
-
K-bentonite (2)
-
minerals (2)
-
oxides
-
rutile (1)
-
-
phosphates
-
apatite (3)
-
monazite (8)
-
-
silicates
-
chain silicates
-
amphibole group
-
clinoamphibole
-
hornblende (5)
-
-
-
pyroxene group (1)
-
-
framework silicates
-
feldspar group
-
alkali feldspar
-
orthoclase (1)
-
-
plagioclase (1)
-
-
silica minerals
-
coesite (1)
-
quartz (3)
-
-
-
orthosilicates
-
nesosilicates
-
garnet group (6)
-
sillimanite (3)
-
zircon group
-
zircon (41)
-
-
-
sorosilicates
-
epidote group (1)
-
-
-
sheet silicates
-
chlorite group (1)
-
clay minerals
-
kaolinite (1)
-
-
mica group
-
biotite (3)
-
muscovite (10)
-
-
-
-
sulfates
-
barite (1)
-
-
sulfides
-
bornite (1)
-
chalcopyrite (1)
-
galena (1)
-
sphalerite (2)
-
-
-
Primary terms
-
absolute age (68)
-
Africa
-
North Africa
-
Algeria (1)
-
Atlas Mountains
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
Morocco
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
Tindouf Basin (1)
-
Western Sahara (1)
-
-
West Africa
-
Mauritanides (1)
-
-
West African Shield (1)
-
-
Arctic region
-
Greenland (1)
-
-
Asia
-
Arabian Peninsula
-
Oman (2)
-
Saudi Arabia (1)
-
-
-
Atlantic Ocean
-
North Atlantic
-
Georges Bank (1)
-
Gulf of Maine (1)
-
Gulf of Mexico (1)
-
Gulf of Saint Lawrence (4)
-
Northwest Atlantic (1)
-
-
-
Atlantic Ocean Islands
-
Shetland Islands
-
Unst (1)
-
-
-
Atlantic region (1)
-
atmosphere (1)
-
Australasia (1)
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Taconic Orogeny
Abstract The Taconian–Grampian tract was characterized by a diachronous collision of a north-facing oceanic arc–forearc terrane and associated backarc basins with an irregular Laurentian margin with hyperextended segments. Hyperextension produced outboard continental terranes, separated by exhumed subcontinental mantle from the inboard margin. The exhumed mantle facilitated continued subduction of the extended margin after it had entered the trench. Enhanced slab-rollback resulted in spreading in lenticular backarc basins, which gradually transitioned along-strike into extensional arcs where rollback was less. Obduction of the oceanic elements onto the irregular Laurentian margin was followed by diachronous slab breakoff and a subduction polarity reversal, such that south- and north-dipping subduction zones locally were coeval along-strike. The polarity flip changed the convergence obliquity from dextral to sinistral and was accompanied by shallowing of the subducting slab near the end of the Middle Ordovician. Strike-slip movements locally juxtaposed segments where tectonic events occurred at different times, producing conflicting relationships. Slab breakoff produced punctuated magmatism, largely driven by mantle-derived melts, and drove and/or enhanced metamorphism in the overlying and enveloping crustal rocks. Boninite was generated episodically over a time span of 32 myr; the oldest Cambrian phase in the Lushs Bight Oceanic Tract (LBOT) and correlatives was associated with subduction initiation.
Geochemistry and geochronology of the Bay of Islands metamorphic sole, Newfoundland, Canada: Protoliths and implications for subduction initiation
ABSTRACT The Neoproterozoic to Cambrian rifting history of Laurentia resulted in hyperextension along large segments of its Paleozoic margins, which created a complex paleogeography that included isolated continental fragments and exhumed continental lithospheric mantle. This peri-Laurentian paleogeography had a profound effect on the duration and nature of the Paleozoic collisional history and associated magmatism of Laurentia. During the initial collisions, peri-Laurentia was situated in a lower-plate setting, and there was commonly a significant time lag between the entrance of the leading edge of peri-Laurentia crust in the trench and the arrival of the trailing, coherent Laurentian landmass. The final Cambrian assembly of Gondwana was followed by a global plate reorganization that resulted in Cambrian (515–505 Ma) subduction initiation outboard of Laurentia, West Gondwana, and Baltica. Accretion of infant and mature intra-oceanic arc terranes along the Appalachian-Caledonian margin of the Iapetus Ocean started at the end of the Cambrian during the Taconic-Grampian orogenic cycle and continued until the ca. 430–426 Ma onset of the Scandian-Salinic collision between Laurentia and Baltica, Ganderia, and East Avalonia, which created the Laurussian continent and closed nearly all vestiges of the Iapetus Ocean. Closure of the Iapetus Ocean in the Appalachians was followed by the Devonian Acadian and Neoacadian orogenic cycles, which were due to dextral oblique accretion of West Avalonia, Meguma, and the Suwannee terranes following the Pridolian to Lochkovian closure of the Acadian seaway and subsequent outboard subduction of the Rheic Ocean beneath Laurentia. Continued underthrusting of Baltica and Avalonia beneath Laurentia during the Devonian indicates that convergence continued between Laurentia and Baltica and Avalonia, which, at least in part, may have been related to the motions of Laurentia relative to its converging elements. Cambrian to Ordovician subduction zones formed earlier in the oceanic realm between Laurentia and Baltica and started to enter the Arctic realm of Laurentia by the Late Ordovician, which resulted in sinistral oblique interaction of the Franklinian margin with encroaching terranes of peri-Laurentian, intra-oceanic, and Baltican provenance. Any intervening seaways were closed during the Middle to Late Devonian Ellesmerian orogeny. Exotic terranes such as Pearya and Arctic Alaska became stranded in the Arctic realm of Laurentia, while other terranes such as Alexander and Eastern Klamath were translated further into the Panthalassa Ocean. The Middle/Late Devonian to Mississippian Antler orogeny along the Cordilleran margin of Laurentia records the first interaction with an outboard arc terrane built upon a composite block preserved in the Northern Sierra and Eastern Klamath terranes. The Carboniferous–Permian Alleghanian-Ouachita orogenic cycle was due to closure of the vestiges of the Rheic Ocean and assembly of Pangea. The narrow, continental transform margin of the Ouachita embayment of southern Laurentia had escaped accretion by outboard terranes until the Mississippian, when it collided with an outboard arc terrane.
ABSTRACT The Ordovician Bronson Hill arc and Silurian–Devonian Central Maine basin are integral tectonic elements of the northern Appalachian Mountains (USA). However, understanding the evolution of, and the relationship between, these two domains has been challenging due to complex field relationships, overprinting associated with multiple phases of Paleozoic orogenesis, and a paucity of geochronologic dates. To constrain the nature of this boundary, and the tectonic evolution of the northern Appalachians, we present U-Pb zircon dates from 24 samples in the context of detailed mapping in northern New Hampshire and western Maine. Collectively, the new geochronology and mapping results constrain the timing of magmatism, sedimentation, metamorphism, and deformation. The Bronson Hill arc formed on Gondwana-derived basement and experienced prolonged magmatic activity before and after a ca. 460 Ma reversal in subduction polarity following its accretion to Laurentia in the Middle Ordovician Taconic orogeny. Local Silurian deformation between ca. 441 and 434 Ma may have been related to the last stages of the Taconic orogeny or the Late Ordovician to early Silurian Salinic orogeny. Silurian Central Maine basin units are dominated by local, arc-derived zircon grains, suggestive of a convergent margin setting. Devonian Central Maine basin units contain progressively larger proportions of older, outboard, and basement-derived zircon, associated with the onset of the collisional Early Devonian Acadian orogeny at ca. 410 Ma. Both the Early Devonian Acadian and Middle Devonian to early Carboniferous Neoacadian orogenies were associated with protracted amphibolite-facies metamorphism and magmatism, the latter potentially compatible with the hypothesized Acadian altiplano orogenic plateau. The final configuration of the Jefferson dome formed during the Carboniferous via normal faulting, possibly related to diapirism and/or ductile thinning and extrusion. We interpret the boundary between the Bronson Hill arc and the Central Maine basin to be a pre-Acadian normal fault on which dip was later reversed by dome-stage tectonism. This implies that the classic mantled gneiss domes of the Bronson Hill anticlinorium formed relatively late, during or after the Neoacadian orogeny, and that this process may have separated the once-contiguous Central Maine and Connecticut Valley basins.
ABSTRACT The Appalachian Mountains in northern Vermont host a complex rock record of the tectonic evolution of eastern Laurentia, from the opening of the Iapetus Ocean to the subsequent formation of a convergent Paleozoic margin involving multiple phases of orogenesis. Prior 40 Ar/ 39 Ar studies in Vermont and northern Massachusetts have generally interpreted two major events associated with a dominantly Ordovician Taconic orogeny and a Devonian Acadian orogeny; intermediate ages were considered to reflect Taconic metamorphism and/or deformation that was “partially reset” during the Acadian orogeny. However, recent studies have documented Salinic ages in northern Vermont, aligning with multiple lines of evidence in southern Quebec for an intervening Salinic orogeny during the Silurian. This study reports integrated microstructural and 40 Ar/ 39 Ar geochronological analyses of samples collected across the Green Mountain anticlinorium in northern Vermont. The dominant S 2 and S 3 foliations are defined in thin section by predominantly white mica/quartz microlithons and aligned mica cleavage domains in schist to graphitic schist that formed under greenschist-facies conditions. Correlation of microstructures across the field area and associated 40 Ar/ 39 Ar plateau ages reveal a spatial pattern associated with microstructural development across the anticlinorium. In the eastern limb, the oldest plateau age, 457.6 ± 2.0 Ma (1σ), is interpreted to reflect the timing of formation of S 2 . The youngest plateau age, 419.0 ± 2.4 Ma, comes from the western limb of the anticline near the trace of the Honey Hollow fault, where S 2 is completely transposed by S 3 . Intermediate ages were obtained across the axis of the anticline, where S 3 is a crenulation cleavage. While the Green Mountain anticlinorium has been previously interpreted to have formed in the Devonian during the Acadian orogeny, the typical ca. 386–355 Ma ages are notably absent in the data set, except in locally disturbed spectra. The results of this work are closely aligned with published results of 40 Ar/ 39 Ar dating in southern Quebec that reflect deformation during Taconic and Salinic orogenesis. These new data, together with recently reported ages of west-directed transport on Taconic thrusts along the western Green Mountain front at ca. 420 Ma, suggest a phase of mountain building in the New England Appalachians that has been previously unreported in Vermont. The formation of the Green Mountain anticlinorium coincided with a complex tectonic interval that overlapped temporally with (1) the transition from Salinic thrusting to normal faulting, (2) magmatism attributed to slab breakoff, and (3) syntectonic deposition in the Connecticut Valley–Gaspé Basin.
The Ordovician South Mayo Trough, a basin that recorded the passage of a triple junction along the Laurentian margin
ABSTRACT Tectonic models for arc-continent collision can be overly complex where, for example, diachronous sedimentation and deformation along a single plate boundary are attributed to separate tectonic events. Furthermore, continuous sedimentation in a single basin recording a diachronous collision along a plate margin makes it difficult to use classical unconformable relationships to date an orogenic phase. In this chapter, we describe the Ordovician South Mayo Trough of western Ireland, a remarkable example of such a basin. It originated in the late Cambrian–Early Ordovician as a Laurentia-facing oceanic forearc basin to the Lough Nafooey arc. This arc was split by a spreading ridge to form a trench-trench-ridge triple junction at the trench. The basin remained below sea level during Grampian/Taconic arc-continent collision and, following subduction flip, received sediment from an active continental margin. Sedimentation ended during Late Ordovician Mayoian “Andean”-style shortening, broadly coeval with a marked fall in global sea level. These major tectonic events are traced through the nature of the detritus and volcanism in this basin, which is preserved in a mega-syncline. The Grampian orogen is not recorded as a regional unconformity, but as a sudden influx of juvenile metamorphic detritus in a conformable sequence.
ABSTRACT Synthesis of the Ordovician Taconic orogeny in the northern Appalachians has been hindered by along-strike variations in Laurentian, Gondwanan, and arc-generated tectonic elements. The Dashwoods terrane in Newfoundland has been interpreted as a peri-Laurentian arc terrane that collided with the Laurentian margin at the onset of the Taconic orogeny, whereas along strike in New England, the Moretown terrane marks the leading edge of peri-Gondwanan arcs. The peri-Laurentian affinity of the Dashwoods terrane hinges on the correlation of its oldest metasedimentary rocks with upper Ediacaran to Lower Ordovician rift-drift deposits of the Laurentian Humber margin in western Newfoundland. Here, we report U-Pb dates and trace-element geochemistry on detrital zircons from metasedimentary rocks in the southern Dashwoods terrane that challenge this correlation and provide new insights into the Taconic orogeny. Based on age and trace-element geochemistry of detrital zircons analyzed by laser ablation–inductively coupled plasma–mass spectrometry (LA-ICP-MS) and chemical abrasion–isotope dilution–thermal ionization mass spectrometry (CA-ID-TIMS), we identified ca. 462–445 Ma sedimentary packages with a mixed provenance consisting of Laurentian, Gondwanan, and arc-derived Cambrian–Ordovician sources. These deposits overlap in age with Upper Ordovician strata of the Badger Group of the Exploits subzone, which also contain Laurentian detritus. We infer dominantly east-directed transport of Laurentian detritus from the Taconic collision zone across a postcollisional arc–back-arc complex at ca. 462–455 Ma followed by dominantly west-directed transport of detritus from the Red Indian Lake arc at ca. 455–445 Ma. Our analysis of zircon inheritance from Dashwoods igneous rocks suggests that 1500–900 Ma Laurentian crystalline basement of the Humber margin is an unlikely source of Dashwoods inherited zircon. Instead, a more cosmopolitan Laurentian inheritance may be best explained as sourced from subducted Laurentian sediment. Our results demonstrate that the sampled metasedimentary units from the southern Dashwoods terrane do not correlate with rift-drift strata of the Humber margin as previously proposed, nor with the basement of the Moretown terrane; yet, these Middle to Upper Ordovician successions suggest the potential for an alternative plate-tectonic model in which the Taconic orogeny may have been initiated by collision of Gondwanan arc terranes that closed the main tract of the Iapetus Ocean along the Baie Verte–Brompton Line.
ABSTRACT Three Silurian basin fills, the Llandovery–Wenlock Croagh Patrick and Killary Harbour–Joyce Country successions and the Ludlow–Pridoli Louisburgh–Clare Island succession, overstep the tectonic contacts between elements of the Grampian (Taconic) accretionary history of the Caledonian-Appalachian orogeny in western Ireland. New U-Pb detrital zircon data from lower strata of these Silurian rocks provide insight into basin evolution and paleogeography. The shallow-marine Croagh Patrick succession unconformably overlies the Clew Bay Complex and the northern part of the Ordovician South Mayo Trough. Two samples have zircon populations dominated by Proterozoic grains typical of the Laurentian margin, with few younger grains. Up to 13% of the grains form a cluster at ca. 950–800 Ma, which is younger than known Grenville magmatism on the local Laurentian margin and older than known magmatism from Iapetan rifting; these may be recycled grains from Dalradian strata, derived from distal Tonian intrusions. The Killary Harbour–Joyce Country succession overlies the structural contact between the Lough Nafooey arc and the Connemara Dalradian block and records a transgressive-regressive cycle. Four samples of the Lough Mask Formation show contrasting age spectra. Two samples from east of the Maam Valley fault zone, one each from above Dalradian and Nafooey arc basement, are dominated by Proterozoic grains with ages typical of a Laurentian or Dalradian source, likely in north Mayo. One sample also includes 8% Silurian grains. Two samples from west of the fault overlie Dalradian basement and are dominated by Ordovician grains. Circa 450 Ma ages are younger than any preserved Ordovician rocks in the region and are inferred to represent poorly preserved arc fragments that are exposed in northeastern North America. Cambrian to late Neoproterozoic grains in association with young Ordovician ages suggest derivation from a peri-Gondwanan source in the late stages of Iapetus closure. The Louisburgh–Clare Island succession comprises terrestrial red beds. It unconformably overlies the Clew Bay Complex on Clare Island and is faulted against the Croagh Patrick succession on the mainland. The Strake Banded Formation yielded an age spectrum dominated by Proterozoic Laurentian as well as Ordovician–Silurian ages. Although the basin formed during strike-slip deformation along the Laurentian margin in Ireland and Scotland, sediment provenance is consistent with local Dalradian sources and contemporaneous volcanism. Our results support ideas that Ganderian continental fragments became part of Laurentia prior to the full closure of the Iapetus Ocean.
ABSTRACT The Baie Verte Line in western Newfoundland marks a suture zone between (1) an upper plate represented by suprasubduction zone oceanic crust (Baie Verte oceanic tract) and the trailing continental Notre Dame arc, with related upper-plate rocks built upon the Dashwoods terrane; and (2) a lower plate of Laurentian margin metasedimentary rocks with an adjoining ocean-continent transition zone (Birchy Complex). The Baie Verte oceanic tract formed during closure of the Taconic seaway in a forearc position and started to be obducted onto the Laurentian margin between ca. 485 and 476 Ma (early Taconic event), whereas the Birchy Complex, at the leading edge of the Laurentian margin, was subducted to maximum depths as calculated by pseudosection techniques (6.7–11.2 kbar, 315–560 °C) by ca. 467–460 Ma, during the culmination of the Taconic collision between the trailing Notre Dame arc and Laurentia, and it cooled isobarically to 9.2–10.0 kbar and 360–450 °C by 454–449 Ma (M 1 ). This collisional wedge progressively incorporated upper-plate Baie Verte oceanic tract rocks, with remnants preserved in M 1 high-pressure, low-temperature greenschist-facies rocks (4.8–8.0 kbar, 270–340 °C) recording typical low metamorphic gradients (10–14 °C/km). Subsequently, the early Taconic collisional wedge was redeformed and metamorphosed during the final stages of the Taconic cycle. We relate existing and new 40 Ar/ 39 Ar ages between 454 and 439 Ma to a late Taconic reactivation of the structurally weak suture zone. The Taconic wedge on both sides of the Baie Verte suture zone was subsequently strongly shortened (D 2 ), metamorphosed (M 2 ), and intruded by a voluminous suite of plutons during the Salinic orogenic cycle. Calculated low- to medium-pressure, low-temperature M 2 conditions in the Baie Verte oceanic tract varied at 3.0–5.0 kbar and 275–340 °C, with increased metamorphic gradients of ~17–25 °C/km during activity of the Notre Dame arc, and correlate with M 2 assemblages in the Birchy Complex. These conditions are associated with existing Salinic S 2 white mica 40 Ar/ 39 Ar ages of ca. 432 Ma in a D 2 transpressional shear zone and synkinematic intrusions of comparable age. A third metamorphic event (M 3 ) was recorded during the Devonian with calculated low-pressure, low-temperature conditions of 3.2–3.8 kbar and 315–330 °C under the highest metamorphic gradients (23–30 °C/km) and associated with Devonian–early Carboniferous isotopic ages as young as 356 ± 5 Ma. The youngest ages are related to localized extension associated with a large-scale transtensional zone, which reused parts of the Baie Verte Line suture zone. Extension culminated in the formation of a Middle to Late Devonian Neoacadian metamorphic core complex in upper- and lower-plate rocks by reactivation of Baie Verte Line tectonites formed during the Taconic and Salinic cycles. The Baie Verte Line suture zone is a collisional complex subjected to repeated, episodic structural reactivation during the Late Ordovician Taconic 3, Silurian Salinic, and Early–Late Devonian Acadian/Neoacadian orogenic cycles. Deformation appears to have been progressively localized in major fault zones associated with earlier suturing. This emphasizes the importance of existing zones of structural weakness, where reactivation took place in the hinterland during successive collision events.
Paleozoic orogenies and relative plate motions at the sutures of the Iapetus-Rheic Ocean
ABSTRACT Early Ordovician to late Permian orogenies at different plate-boundary zones of western Pangea affected continental crust derived from the plates of North America (Laurentia), Europe (East European Craton including Baltica plus Arctida), and Gondwana. The diachronic orogenic processes comprised stages of intraoceanic subduction, formation and accretion of island arcs, and collision of several continents. Using established plate-tectonic models proposed for different regions and time spans, we provide for the first time a generic model that explains the tectonics of the entire Gondwana-Laurussia plate-boundary zone in a consistent way. We combined the plate kinematic model of the Pannotia-Pangea supercontinent cycle with geologic constraints from the different Paleozoic orogens. In terms of oceanic lithosphere, the Iapetus Ocean is subdivided into an older segment (I) and a younger (II) segment. Early Cambrian subduction of the Iapetus I and the Tornquist oceans at active plate boundaries of the East European Craton triggered the breakup of Pannotia, formation of Iapetus II, and the separation of Gondwana from Laurentia. Prolonged subduction of Iapetus I (ca. 530 –430 Ma) culminated in the Scandian collision of the Greenland-Scandinavian Caledonides of Laurussia. Due to plate-tectonic reorganization at ca. 500 Ma, seafloor spreading of Iapetus II ceased, and the Rheic Ocean opened. This complex opening scenario included the transformation of passive continental margins into active ones and culminated in the Ordovician Taconic and Famatinian accretionary orogenies at the peri-Laurentian margin and at the South American edge of Gondwana, respectively. Rifting along the Avalonian-Cadomian belt of peri-Gondwana resulted in the separation of West Avalonian arc terranes and the East Avalonian continent. The vast African/Arabian shelf was affected by intracontinental extension and remained on the passive peri-Gondwana margin of the Rheic Ocean. The final assembly of western Pangea was characterized by the prolonged and diachronous closure of the Rheic Ocean (ca. 400–270 Ma). Continental collision started within the Variscan-Acadian segment of the Gondwana-Laurussia plate-boundary zone. Subsequent zipper-style suturing affected the Gondwanan Mauritanides and the conjugate Laurentian margin from north to south. In the Appalachians, previously accreted island-arc terranes were affected by Alleghanian thrusting. The fold-and-thrust belts of southern Laurentia, i.e., the Ouachita-Marathon-Sonora orogenic system, evolved from the transformation of a vast continental shelf area into a collision zone. From a geodynamic point of view, an intrinsic feature of the model is that initial breakup of Pannotia, as well as the assembly of western Pangea, was facilitated by subduction and seafloor spreading at the leading and the trailing edges of the North American plate and Gondwana, respectively. Slab pull as the plate-driving force is sufficient to explain the entire Pannotia–western Pangea supercontinent cycle for the proposed scenario.