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Proterozoic accretionary belts of the Amazonian Craton Umberto G. Cordani Institute of Geosciences University of Sao Paulo, Brazil.

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Presentation on theme: "Proterozoic accretionary belts of the Amazonian Craton Umberto G. Cordani Institute of Geosciences University of Sao Paulo, Brazil."— Presentation transcript:

1 Proterozoic accretionary belts of the Amazonian Craton Umberto G. Cordani Institute of Geosciences University of Sao Paulo, Brazil

2 TECTONIC EVOLUTION OF THE AMAZONIAN CRATON IN THE PROTEROZOIC -- The SW part of the Amazonian craton was formed by continuous amalgamation of magmatic arcs, largely juvenile, the roots of which are now exhumed. - Accretionary belts, driven by subduction, formed a very large domain, at least 2700 km long and about 1300 km wide -- Duration of the process is about 700 m.y., starting at 2.0 Ga. An ocean basin was closed, to the SW of a large continent formed by the Guyana Shield plus the West African craton. -- The units decrease in age from NE to SW, and lithologies are practically only granitic (s.l.). Basement was not detected.

3 EARTH THERMAL EVOLUTION Layered mantle convection Subduction slabs restricted to upper mantle Whole-mantle convection Oceanic lithosphere down to lower mantle SUPERPLUMES AVALANCHES SUPERCONTINENT CYCLE

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5 PALEOPROTEROZIC Woopmay Orogen ARCHEAN Slave Craton

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7 INTRA-OCEANIC MAGMATIC ARCS WITHIN ACCRETIONARY BELTS Absence of continental basement rocks Stacking, “Soft-collision” and accretion processes Positive or slightly negative on granitoids Sm-Nd model ages similar or slightly older than radiometric ages of rocks (U-Pb on Zircon)  Nd

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10 Províncias tectônicas da parte NW do Craton Amazônico

11 Províncias tectônicas da parte SW do Craton Amazônico

12 VENTUARI-TAPAJÓS and RIO NEGRO-JURUENA MAGMATIC ARCS Predominantly granitoid material, deformed and undeformed Archean basement not detected Radiometric ages roughly between 2.0 and 1.5 Ga, decreasing from NE to SW Post-orogenic volcanic-sedimentary basins with similar or slightly younger ages. Sm – Nd model ages always younger than 2.1 Ga from slightly negative to about (+3)  Nd (T)

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14 Reconstrução da posição relativa de Laurentia, Baltica, Amazonia e Australia há 1.65 Ga. Y-M=Yavapai-Mazatzal Lb=Labradorian G=Gothian R-J=Rio Negro-Juruena (a) - Pesonen et al (2001) (b) - Modelo alternativo (c) - Ahäll & Larson (2000) e Geraldes et al. (2001)

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16 RONDONIAN-SAN IGNACIO PROVINCE and SUNSAS BELT

17 RONDONIAN-SAN IGNACIO PROVINCE Presence of Paleoproterozoic basement Large metamorphic belts of Mesoproterozoic age Volcanic-sedimentary units of Meso-Neoproterozoic age Juvenile magmatic arcs (Pensamiento complex and related rocks) Radiometric ages between 1.3 and 1.5 Ga Sm – Nd model ages between 1.7 and 2.2 Ga between (-3) and (+2)  Nd (T) U-Pb radiometric ages between 1.4 and 1.5 Ga Sm – Nd model ages between 1.5 and 1.7 Ga about (+4)  Nd (T)

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19 MAIN CONCLUSIONS -- The SW part of the Amazonian craton was formed by continuous amalgamation of magmatic arcs, largely juvenile, the roots of which are now exhumed. - Accretionary belts, driven by subduction, formed a very large domain, at least 2700 km long and about 1300 km wide -- Duration of the process is about 700 m.y., starting at 2.0 Ga. An ocean basin was closed, to the SW of a large continent formed by the Guyana Shield plus the West African craton. -- The units decrease in age from NE to SW, and lithologies are practically only granitic (s.l.). Basement was not detected.

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