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NARROW
GeoRef Subject
-
all geography including DSDP/ODP Sites and Legs
-
Africa
-
East Africa (1)
-
North Africa
-
Atlas Mountains
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
Morocco
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
-
West Africa
-
Mauritanides (1)
-
-
West African Craton (2)
-
-
Arctic region
-
Greenland (1)
-
-
Asia
-
Arabian Peninsula (1)
-
Far East
-
Indochina (1)
-
Taiwan (1)
-
-
Himalayas (1)
-
Middle East
-
Cyprus (1)
-
Iran (2)
-
Syria (1)
-
Turkey
-
Anatolia (1)
-
Pontic Mountains (1)
-
Taurus Mountains (1)
-
-
-
-
Atlantic Ocean
-
North Atlantic
-
Gulf of Mexico (3)
-
Northeast Atlantic (1)
-
Northwest Atlantic (1)
-
-
-
Atlantic region (1)
-
Avalon Zone (1)
-
Caledonides (3)
-
Canada
-
Eastern Canada
-
Gander Zone (1)
-
Maritime Provinces
-
New Brunswick (1)
-
Nova Scotia
-
Cape Breton Island (2)
-
-
-
Meguma Terrane (5)
-
Newfoundland and Labrador
-
Newfoundland
-
Avalon Peninsula (1)
-
Baie Verte Peninsula (1)
-
-
-
-
-
Caribbean region (1)
-
Central America
-
Belize (1)
-
Guatemala (1)
-
Honduras (1)
-
-
Europe
-
Alps
-
Western Alps
-
Dauphine Alps
-
Belledonne Massif (1)
-
-
-
-
Baltic region (1)
-
Central Europe
-
Bohemian Massif (6)
-
Germany
-
Franconia (1)
-
-
Poland (2)
-
-
Pyrenees (2)
-
Southern Europe
-
Iberian Peninsula
-
Central Iberian Zone (2)
-
Iberian Massif (8)
-
Ossa-Morena Zone (5)
-
Portugal (5)
-
Spain
-
Asturias Spain (1)
-
Cantabrian Basin (1)
-
Cantabrian Mountains (1)
-
Galicia Spain
-
Cabo Ortegal Complex (4)
-
La Coruna Spain (1)
-
Lugo Spain (1)
-
Ordenes Complex (4)
-
-
Iberian Mountains (1)
-
-
-
Italy
-
Sardinia Italy (2)
-
-
Moesian Platform (1)
-
-
Tornquist-Teisseyre Zone (2)
-
Variscides (11)
-
Western Europe
-
Belgium (1)
-
France
-
Armorican Massif (3)
-
Central Massif (1)
-
Dauphine Alps
-
Belledonne Massif (1)
-
-
-
Iceland (1)
-
Ireland
-
Kerry Ireland
-
Dingle Peninsula (1)
-
-
-
Scandinavia (1)
-
United Kingdom
-
Great Britain
-
England
-
Cornwall England (1)
-
Devon England (1)
-
-
Scotland
-
Scottish Highlands
-
Grampian Highlands (1)
-
-
-
Wales (3)
-
-
-
-
-
Highland Boundary Fault (1)
-
Maritimes Basin (1)
-
Mediterranean region (2)
-
Mediterranean Sea
-
East Mediterranean
-
Black Sea (1)
-
Eratosthenes Seamount (1)
-
-
-
Meseta (2)
-
Mexico
-
Guerrero Mexico (1)
-
Guerrero Terrane (1)
-
Puebla Mexico (3)
-
Tamaulipas Mexico (1)
-
-
North America
-
Appalachian Basin (2)
-
Appalachians
-
Blue Ridge Province (1)
-
Northern Appalachians (3)
-
Piedmont
-
Inner Piedmont (1)
-
-
Southern Appalachians (4)
-
-
North American Cordillera (1)
-
North American Craton (1)
-
-
Pacific Ocean (1)
-
Pacific region
-
Pacific mobile belt (1)
-
-
Russian Platform (1)
-
Sierra Madre (1)
-
South America
-
Amazonian Craton (2)
-
Colombia (1)
-
-
Southern Uplands (2)
-
United States
-
Arizona (1)
-
Arkansas (1)
-
Black Warrior Basin (1)
-
Carolina Terrane (2)
-
Eastern U.S.
-
Northeastern U.S. (1)
-
-
Georgia (1)
-
Maine
-
Hancock County Maine (1)
-
Norumbega fault zone (1)
-
Penobscot Bay (1)
-
Waldo County Maine (1)
-
-
Midcontinent (1)
-
New England (3)
-
New Mexico (1)
-
New York (1)
-
North Carolina (1)
-
Oklahoma (1)
-
Ouachita Mountains (1)
-
Pennsylvania (2)
-
South Carolina (2)
-
Southwestern U.S. (1)
-
Texas
-
Midland Basin (1)
-
-
Utah (1)
-
Virginia (1)
-
West Virginia (1)
-
-
Yucatan Peninsula (1)
-
-
commodities
-
metal ores
-
gold ores (1)
-
tin ores (1)
-
tungsten ores (1)
-
uranium ores (1)
-
-
mineral deposits, genesis (1)
-
petroleum
-
natural gas (1)
-
-
placers (1)
-
-
elements, isotopes
-
carbon
-
C-13/C-12 (2)
-
-
chemical ratios (2)
-
isotope ratios (7)
-
isotopes
-
radioactive isotopes
-
Pb-206/Pb-204 (1)
-
Pb-208/Pb-204 (1)
-
Sm-147/Nd-144 (1)
-
-
stable isotopes
-
C-13/C-12 (2)
-
Pb-206/Pb-204 (1)
-
Pb-207/Pb-206 (1)
-
Pb-208/Pb-204 (1)
-
S-34/S-32 (1)
-
Sm-147/Nd-144 (1)
-
Sr-87/Sr-86 (2)
-
-
-
Lu/Hf (3)
-
metals
-
actinides
-
uranium (1)
-
-
alkaline earth metals
-
strontium
-
Sr-87/Sr-86 (2)
-
-
-
hafnium (1)
-
lead
-
Pb-206/Pb-204 (1)
-
Pb-207/Pb-206 (1)
-
Pb-208/Pb-204 (1)
-
-
manganese (1)
-
rare earths
-
lutetium (1)
-
neodymium
-
Sm-147/Nd-144 (1)
-
-
samarium
-
Sm-147/Nd-144 (1)
-
-
-
-
sulfur
-
S-34/S-32 (1)
-
-
-
fossils
-
Chordata
-
Vertebrata (1)
-
-
Invertebrata
-
Arthropoda
-
Mandibulata
-
Crustacea
-
Ostracoda
-
Beyrichicopina (1)
-
-
-
-
Trilobitomorpha
-
Trilobita (1)
-
-
-
Brachiopoda
-
Inarticulata
-
Lingula (1)
-
-
-
Echinodermata
-
Echinozoa
-
Echinoidea (1)
-
-
-
-
Metazoa (1)
-
microfossils
-
Conodonta (3)
-
-
palynomorphs
-
acritarchs (2)
-
-
-
geochronology methods
-
Ar/Ar (10)
-
fission-track dating (1)
-
Lu/Hf (3)
-
paleomagnetism (5)
-
Pb/Th (1)
-
Rb/Sr (2)
-
Sm/Nd (5)
-
Th/U (1)
-
thermochronology (2)
-
U/Pb (39)
-
U/Th/Pb (3)
-
-
geologic age
-
Cenozoic
-
Tertiary
-
Neogene (1)
-
Paleogene
-
Eocene (1)
-
-
-
-
Dalradian (1)
-
Mesozoic
-
Cretaceous
-
Lower Cretaceous
-
Cadomin Formation (1)
-
-
-
Jurassic (3)
-
Triassic (2)
-
-
Moldanubian (1)
-
Paleozoic
-
Acatlan Complex (11)
-
Cambrian
-
Acadian (2)
-
Conasauga Group (1)
-
Lower Cambrian
-
Rome Formation (1)
-
Tommotian (1)
-
-
Middle Cambrian (1)
-
Upper Cambrian
-
Furongian (1)
-
Goldenville Formation (1)
-
-
-
Carboniferous
-
Lower Carboniferous
-
Dinantian (1)
-
-
Mabou Group (1)
-
Mississippian
-
Middle Mississippian
-
Visean (1)
-
-
Stanley Group (1)
-
Windsor Group (1)
-
-
Pennsylvanian
-
Middle Pennsylvanian
-
Moscovian (1)
-
-
Pottsville Group (1)
-
Upper Pennsylvanian
-
Gzhelian (1)
-
-
-
Upper Carboniferous (2)
-
-
Devonian
-
Lower Devonian (5)
-
Middle Devonian
-
Marcellus Shale (1)
-
Onondaga Limestone (1)
-
-
Millboro Shale (1)
-
Old Red Sandstone (3)
-
Upper Devonian
-
Famennian (1)
-
-
-
Horton Group (1)
-
Knox Group (1)
-
lower Paleozoic (6)
-
middle Paleozoic (3)
-
Ordovician
-
Lower Ordovician
-
Arenigian (1)
-
Floian (1)
-
Tremadocian
-
Halifax Formation (1)
-
-
-
Meguma Group (1)
-
Middle Ordovician (1)
-
Upper Ordovician
-
Ashgillian (1)
-
Caradocian (1)
-
Hirnantian (2)
-
-
-
Permian
-
Lower Permian (1)
-
-
Silurian
-
Lower Silurian
-
Llandovery (1)
-
Wenlock (2)
-
-
Upper Silurian
-
Ludlow (1)
-
-
-
-
Phanerozoic (1)
-
Precambrian
-
Archean
-
Neoarchean (1)
-
-
upper Precambrian
-
Proterozoic
-
Coldbrook Group (1)
-
Mesoproterozoic
-
Stenian (1)
-
-
Neoproterozoic
-
Cryogenian (2)
-
Ediacaran (5)
-
Tonian (1)
-
Vendian (2)
-
-
Paleoproterozoic (3)
-
-
-
-
Rhenohercynian (2)
-
Saxothuringian (1)
-
-
igneous rocks
-
igneous rocks
-
plutonic rocks
-
diorites (1)
-
gabbros (6)
-
granites
-
I-type granites (1)
-
leucogranite (1)
-
S-type granites (2)
-
-
granodiorites (1)
-
lamprophyres (1)
-
pegmatite (1)
-
syenites
-
alkali syenites (1)
-
-
ultramafics (1)
-
-
volcanic rocks
-
basalts
-
mid-ocean ridge basalts (3)
-
-
pyroclastics
-
tuff (2)
-
-
rhyolites (2)
-
-
-
ophiolite (12)
-
-
metamorphic rocks
-
metamorphic rocks
-
amphibolites (4)
-
eclogite (4)
-
gneisses
-
orthogneiss (3)
-
-
granulites (1)
-
metaigneous rocks
-
metabasite (2)
-
metagabbro (5)
-
metagranite (1)
-
metarhyolite (1)
-
-
metasedimentary rocks
-
metapelite (1)
-
-
metavolcanic rocks (3)
-
mylonites (4)
-
schists
-
blueschist (1)
-
-
-
ophiolite (12)
-
turbidite (3)
-
-
minerals
-
native elements
-
diamond
-
microdiamond (1)
-
-
-
oxides
-
rutile (2)
-
-
phosphates
-
apatite (1)
-
monazite (1)
-
-
silicates
-
orthosilicates
-
nesosilicates
-
zircon group
-
zircon (36)
-
-
-
-
sheet silicates
-
mica group
-
muscovite (2)
-
-
-
-
sulfides
-
pyrite (1)
-
-
-
Primary terms
-
absolute age (46)
-
Africa
-
East Africa (1)
-
North Africa
-
Atlas Mountains
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
Morocco
-
Moroccan Atlas Mountains
-
Anti-Atlas (1)
-
-
-
-
West Africa
-
Mauritanides (1)
-
-
West African Craton (2)
-
-
Arctic region
-
Greenland (1)
-
-
Asia
-
Arabian Peninsula (1)
-
Far East
-
Indochina (1)
-
Taiwan (1)
-
-
Himalayas (1)
-
Middle East
-
Cyprus (1)
-
Iran (2)
-
Syria (1)
-
Turkey
-
Anatolia (1)
-
Pontic Mountains (1)
-
Taurus Mountains (1)
-
-
-
-
Atlantic Ocean
-
North Atlantic
-
Gulf of Mexico (3)
-
Northeast Atlantic (1)
-
Northwest Atlantic (1)
-
-
-
Atlantic region (1)
-
biogeography (3)
-
Canada
-
Eastern Canada
-
Gander Zone (1)
-
Maritime Provinces
-
New Brunswick (1)
-
Nova Scotia
-
Cape Breton Island (2)
-
-
-
Meguma Terrane (5)
-
Newfoundland and Labrador
-
Newfoundland
-
Avalon Peninsula (1)
-
Baie Verte Peninsula (1)
-
-
-
-
-
carbon
-
C-13/C-12 (2)
-
-
Caribbean region (1)
-
Cenozoic
-
Tertiary
-
Neogene (1)
-
Paleogene
-
Eocene (1)
-
-
-
-
Central America
-
Belize (1)
-
Guatemala (1)
-
Honduras (1)
-
-
Chordata
-
Vertebrata (1)
-
-
continental drift (8)
-
continental shelf (1)
-
crust (13)
-
crystal chemistry (1)
-
deformation (13)
-
Europe
-
Alps
-
Western Alps
-
Dauphine Alps
-
Belledonne Massif (1)
-
-
-
-
Baltic region (1)
-
Central Europe
-
Bohemian Massif (6)
-
Germany
-
Franconia (1)
-
-
Poland (2)
-
-
Pyrenees (2)
-
Southern Europe
-
Iberian Peninsula
-
Central Iberian Zone (2)
-
Iberian Massif (8)
-
Ossa-Morena Zone (5)
-
Portugal (5)
-
Spain
-
Asturias Spain (1)
-
Cantabrian Basin (1)
-
Cantabrian Mountains (1)
-
Galicia Spain
-
Cabo Ortegal Complex (4)
-
La Coruna Spain (1)
-
Lugo Spain (1)
-
Ordenes Complex (4)
-
-
Iberian Mountains (1)
-
-
-
Italy
-
Sardinia Italy (2)
-
-
Moesian Platform (1)
-
-
Tornquist-Teisseyre Zone (2)
-
Variscides (11)
-
Western Europe
-
Belgium (1)
-
France
-
Armorican Massif (3)
-
Central Massif (1)
-
Dauphine Alps
-
Belledonne Massif (1)
-
-
-
Iceland (1)
-
Ireland
-
Kerry Ireland
-
Dingle Peninsula (1)
-
-
-
Scandinavia (1)
-
United Kingdom
-
Great Britain
-
England
-
Cornwall England (1)
-
Devon England (1)
-
-
Scotland
-
Scottish Highlands
-
Grampian Highlands (1)
-
-
-
Wales (3)
-
-
-
-
-
faults (23)
-
folds (6)
-
foliation (5)
-
geochemistry (19)
-
geochronology (1)
-
glacial geology (1)
-
igneous rocks
-
plutonic rocks
-
diorites (1)
-
gabbros (6)
-
granites
-
I-type granites (1)
-
leucogranite (1)
-
S-type granites (2)
-
-
granodiorites (1)
-
lamprophyres (1)
-
pegmatite (1)
-
syenites
-
alkali syenites (1)
-
-
ultramafics (1)
-
-
volcanic rocks
-
basalts
-
mid-ocean ridge basalts (3)
-
-
pyroclastics
-
tuff (2)
-
-
rhyolites (2)
-
-
-
inclusions (1)
-
intrusions (12)
-
Invertebrata
-
Arthropoda
-
Mandibulata
-
Crustacea
-
Ostracoda
-
Beyrichicopina (1)
-
-
-
-
Trilobitomorpha
-
Trilobita (1)
-
-
-
Brachiopoda
-
Inarticulata
-
Lingula (1)
-
-
-
Echinodermata
-
Echinozoa
-
Echinoidea (1)
-
-
-
-
isotopes
-
radioactive isotopes
-
Pb-206/Pb-204 (1)
-
Pb-208/Pb-204 (1)
-
Sm-147/Nd-144 (1)
-
-
stable isotopes
-
C-13/C-12 (2)
-
Pb-206/Pb-204 (1)
-
Pb-207/Pb-206 (1)
-
Pb-208/Pb-204 (1)
-
S-34/S-32 (1)
-
Sm-147/Nd-144 (1)
-
Sr-87/Sr-86 (2)
-
-
-
lineation (2)
-
magmas (3)
-
mantle (9)
-
Mediterranean region (2)
-
Mediterranean Sea
-
East Mediterranean
-
Black Sea (1)
-
Eratosthenes Seamount (1)
-
-
-
Mesozoic
-
Cretaceous
-
Lower Cretaceous
-
Cadomin Formation (1)
-
-
-
Jurassic (3)
-
Triassic (2)
-
-
metal ores
-
gold ores (1)
-
tin ores (1)
-
tungsten ores (1)
-
uranium ores (1)
-
-
metals
-
actinides
-
uranium (1)
-
-
alkaline earth metals
-
strontium
-
Sr-87/Sr-86 (2)
-
-
-
hafnium (1)
-
lead
-
Pb-206/Pb-204 (1)
-
Pb-207/Pb-206 (1)
-
Pb-208/Pb-204 (1)
-
-
manganese (1)
-
rare earths
-
lutetium (1)
-
neodymium
-
Sm-147/Nd-144 (1)
-
-
samarium
-
Sm-147/Nd-144 (1)
-
-
-
-
metamorphic rocks
-
amphibolites (4)
-
eclogite (4)
-
gneisses
-
orthogneiss (3)
-
-
granulites (1)
-
metaigneous rocks
-
metabasite (2)
-
metagabbro (5)
-
metagranite (1)
-
metarhyolite (1)
-
-
metasedimentary rocks
-
metapelite (1)
-
-
metavolcanic rocks (3)
-
mylonites (4)
-
schists
-
blueschist (1)
-
-
-
metamorphism (21)
-
metasomatism (1)
-
Mexico
-
Guerrero Mexico (1)
-
Guerrero Terrane (1)
-
Puebla Mexico (3)
-
Tamaulipas Mexico (1)
-
-
mineral deposits, genesis (1)
-
North America
-
Appalachian Basin (2)
-
Appalachians
-
Blue Ridge Province (1)
-
Northern Appalachians (3)
-
Piedmont
-
Inner Piedmont (1)
-
-
Southern Appalachians (4)
-
-
North American Cordillera (1)
-
North American Craton (1)
-
-
ocean basins (3)
-
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Rheic Ocean
Sedimentary provenance of the Upper Devonian Old Red Sandstone of southern Ireland: an integrated multi-proxy detrital geochronology study
A trans-Iapetus transform fault control for the evolution of the Rheic Ocean: Implications for an early Paleozoic transition of accretionary tectonics: Reply
A trans-Iapetus transform fault control for the evolution of the Rheic Ocean: Implications for an early Paleozoic transition of accretionary tectonics: Comment
Tracking cycles of Phanerozoic opening and closing of ocean basins using detrital rutile and zircon geochronology and geochemistry
Tectonic evolution of the Proto-Qiangtang Ocean and its relationship with the Palaeo-Tethys and Rheic oceans
Abstract An evaluation of the potential geodynamic connections between the evolution of Paleozoic oceans in NW Gondwana and NE Gondwana is challenging. Until recently, most syntheses emphasized only two Paleozoic oceans (the Proto-Tethys and the Palaeo-Tethys) in the east Tethys realm. However, the discovery of early Paleozoic ophiolites along Palaeo-Tethys sutures located south of Proto-Tethys sutures challenges these traditional views. After a comprehensive review of relevant early Paleozoic tectonomagmatic events, we herein recognize and propose a model for the tectonic evolution of a hitherto unrecognized early Paleozoic ocean, which we call the Proto-Qiangtang Ocean. This ocean was short lived; it opened in the late Cambrian, began to subduct in the Middle Ordovician, and closed diachronously westwards between the Late Ordovician and the middle Silurian. Its closure by middle Silurian time indicates that was a spatially and temporally distinct ocean from the Palaeo-Tethys Ocean. The early tectonic evolution of the Proto-Qiangtang Ocean shares many characteristics with that of the Rheic Ocean. Both opened in the late Cambrian in the back-arc region of the Iapetus–Proto-Tethys Ocean, and the Proto-Qiangtang Ocean is considered to represent the eastern extension of the Rheic Ocean. This correlation has important implications for the Paleozoic tectonic evolution and palaeogeography of northern Gondwana.
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.
The tectonic evolution of Laurentia and the North American continent: New datasets, insights, and models
ABSTRACT The North American continent has a rich geologic record that preserves evidence for tectonic processes throughout much of Earth’s history. Within this long history, however, particular times—e.g., “turning points”—have had specific and lasting impact on the evolution of Laurentia (ancestral North America). This volume is focused on seven of these “turning points”: (1) The Neoarchean (2.7–2.5 Ga), characterized by cratonization and the Kenoran orogen(s); (2) the Paleoproterozoic (1.9–1.7 Ga) and the initial assembly of Laurentia; (3) the Mesoproterozoic (1.5–1.4 Ga) Andean-style margin on the southern edge of Laurentia with the Pinware-Baraboo-Picuris orogeny; (4) the 1.2–1.0 Ga Midcontinent rift, and the Grenville orogeny and assembly of Rodinia; (5) the 700–500 Ma Neoproterozoic breakup of Rodinia; (6) the mid-Paleozoic (420–340 Ma) closure of the Iapetus and Rheic oceans and the development of the Appalachian-Caledonian orogen; and (7) the Jurassic–Paleogene (200–50 Ma) assembly of the North American Cordilleran margin by terrane accretion and subduction. The assembled chapters provide syntheses of current understanding of the geologic evolution of Laurentia and North America, as well as new hypotheses for testing. The inclusion of work from different geological time periods within a single volume provides continent-wide perspectives on the evolution of tectonic events and processes that acted on and within Laurentia.
ABSTRACT The Paleozoic plate boundary zone between Laurussia and Gondwana in western Pangea hosts major magmatic and hydrothermal Sn-W-Ta, Au, and U mineralization. Individual mineral deposits represent the results of the superposition of a series of exogenic and endogenic processes. Exogenic processes controlled (1) the enrichment of the ore elements in sedimentary protoliths via residual enrichment during intense chemical weathering and via climatically or tectonically controlled redox traps, (2) the spatial distribution of fertile protoliths, and, thus, eventually (3) the spatial distribution of mineralization. Endogenic processes resulting in metamorphism and crustal melting controlled the mobilization of Sn-W, Au, and U from these enriched protoliths and, thus, account for the age distribution of Sn-W and Au mineralization and U-fertile granites. It is the sequence of exogenic and endogenic processes that eventually results in the formation of mineralization in particular tectonic zones. Whereas the endogenic processes were controlled by orogenic processes during the assembly of western Pangea itself, the exogenic processes were linked to the formation of suitable source rocks for later mineralization. The contrasting distribution of magmatic and hydrothermal Sn-W-Ta, Au, and U mineralization on the Laurussia and Gondwana sides of the plate boundary zone reflects the contrasting distribution of fertile protoliths and the contrasting tectonic situation on these margins. The Laurussian margin was an active margin during most of the Paleozoic, and the distribution of different mineralization types reflects the distribution of terranes of contrasting provenance. The Gondwanan margin was a passive margin during most of the Paleozoic, and the similar distribution of a wide range of different metals (Sn, W, Ta, Au, and U) reflects the fact that the protoliths for the various metals were diachronously accumulated on the same shelf, before the metals were mobilized during Acadian, Variscan, and Alleghanian orogenic processes.
ABSTRACT Avalonia and Ganderia are composite microcontinental fragments in the northern Appalachian orogen likely derived from Gondwanan sources. Avalonia includes numerous Neoproterozoic magmatic arc sequences that represent protracted and episodic subduction-related magmatism before deposition of an Ediacaran–Ordovician cover sequence of mainly siliciclastic rocks. We characterized the nature of the basement on which these arcs were constructed using zircon grains from arc-related magmatic rocks in Atlantic Canada that were analyzed for their Lu-Hf isotope composition. The majority of zircon grains from Avalonia are characterized by initial 176 Hf/ 177 Hf values that are more radiogenic than chondritic uniform reservoir, and calculated crust formation Hf T DM (i.e., depleted mantle) model ages range from 1.2 to 0.8 Ga. These data contrast with those from Ganderia, which show typically positive initial εHf values and Hf T DM model ages that imply magmatism was derived by melting of crustal sources with diverse ages ranging from ca. 1.8 to 1.0 Ga. The positive distribution of initial εHf values along with the pattern of Hf T DM model ages provide a clear record of two distinct subduction systems. Cryogenian–Ediacaran magmatism is interpreted to have resulted from reworking of an evolved Mesoproterozoic crustal component in a long-lived, subduction-dominated accretionary margin along the margin of northern Amazonia. A change in Hf isotope trajectory during the Ediacaran implies a greater contribution of isotopically evolved material consistent with an arc-arc–style collision of Ganderia with Avalonia. The shallow-sloping Hf isotopic pattern for Paleozoic Ganderian magmatism remains continuous for ~200 m.y., consistent with tectonic models of subduction in the Iapetus and Rheic Oceans and episodic accretion of juvenile crustal terranes to Laurentia.
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.
A trans-Iapetus transform fault control for the evolution of the Rheic Ocean: Implications for an early Paleozoic transition of accretionary tectonics
ABSTRACT The supercontinent of Pangea formed through the diachronous collision of Laurussia and Gondwana during the late Paleozoic. While magmatism associated with its formation is well documented in the Variscan orogeny of Europe and Alleghanian orogeny of the United States, little is known about the Sonora orogeny of northern Mexico. This paper reports geochronology (U-Pb zircon), whole-rock geochemistry, and Lu-Hf zircon isotope data on basement cores from the western Gulf of Mexico, which were used to develop a tectonomagmatic model for pre- to post-Pangea amalgamation. Our results suggest the existence of three distinct phases of magmatism, produced during different stages of continental assembly and disassembly. The first phase consists of Early Permian (294–274 Ma; n = 3) granitoids with geochemical signatures indicative of a continental arc tectonic setting. This phase formed on the margins of Gondwana during the closure of the Rheic Ocean, prior to the final amalgamation of Pangea. It likely represents a lateral analogue of late Carboniferous–Early Permian granitoids that intrude the Acatlán and Oaxacan Complexes. The second phase of magmatism includes Late Permian–Early Triassic (263–243 Ma; n = 13) granitoids with suprasubduction geochemical affinities. However, Lu-Hf isotope data indicate that these granitoids formed from crustal anatexis, with ε Hf values and two-step Hf depleted mantle model ages (T DM[Hf] ) comparable to the Oaxaquia continental crust into which they intrude. This phase of magmatism is likely related to coeval granitoids in the Oaxaca area and Chiapas Massif. We interpret it to reflect late- to postcollisional magmatism along the margin of Gondwana following the assembly of Pangea. Finally, the third phase of magmatism includes Early–Middle Jurassic (189–164 Ma; n = 2) mafic porphyries, which could be related to the synchronous suprasubduction magmatism associated with the Nazas arc. Overall, our results are consistent with Pangea assembly through diachronous collision of Laurussia and Gondwana during subduction of the Rheic Ocean. They suggest that postorogenic magmatism in the western termination of the Rheic suture occurred under the influence of a Panthalassan subduction zone, before opening of the Gulf of Mexico.
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.