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Juvenile versus recycled crust in the Central Asian Orogenic Belt : Implications from ocean plate stratigraphy, blueschist belts and intra-oceanic arcs. / Safonova, Inna.

в: Gondwana Research, Том 47, 01.07.2017, стр. 6-27.

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@article{1abd12ed8e6347ebbcfba7e1cea868af,
title = "Juvenile versus recycled crust in the Central Asian Orogenic Belt: Implications from ocean plate stratigraphy, blueschist belts and intra-oceanic arcs",
abstract = "New or “juvenile” crust forms and grows mainly through mafic to andesitic magmatism at Pacific-type or accretionary type convergent margins as well as via tectonic accretion of oceanic and island-arc terranes and translation of continental terranes. During the last decades the juvenile or recycled nature of crust has been commonly evaluated using whole-rock isotope and Hf-in-zircon isotope methods. However, evidence for the accretionary or Pacific-type nature of an orogenic belt comes from geological data, for example, from the presence of accretionary complexes (AC), intra-oceanic arcs (IOA), oceanic plate stratigraphy units (OPS), and MORB-OIB derived blueschist belts (BSB). The Central Asian Orogenic Belt (CAOB) represents the world's largest province of Phanerozoic juvenile crustal growth during ca. 800 m.y. between the East European, Siberian, North China and Tarim cratons. From geological point of view, the CAOB is a typical Pacific-type belt as it hosts numerous occurrences of accretionary complexes, intra-oceanic arcs, OPS units, and MORB-OIB derived blueschist belts. In spite of its accretionary nature, supported by positive whole rock Nd isotope characteristics in CAOB granitoids, the Hf-in-zircon isotope data reveal a big portion of recycled crust. Such a controversy can be explained by presence of accreted microcontinents, isotopically mixed igneous reservoirs and by the tectonic erosion of juvenile crust. The most probable localities of tectonic erosion in the CAOB are the middle and southern Tienshan and southern Transbaikalia because these regions comprise a predominantly recycled crust (based on isotope data), but the geological data show the presence of intra-oceanic arcs, blueschist belts and accreted OPS with oceanic island basalts (OIB) and tectonically juxtaposed coeval arc granitoids and accretionary units. This warrants combination of detailed geological studies with isotopic results, as on their own they may not reflect such processes as tectonic erosion of juvenile crust and/or arc subduction.",
keywords = "Accretionary complex, Geological mapping, Nd and Hf isotopes, Pacific-type orogeny, Tectonic erosion, ISLAND-ARC, ZIRCON U-PB, INNER-MONGOLIA, ND ISOTOPIC EVIDENCE, CONTINENTAL-CRUST, GORNY-ALTAI, PAIRED METAMORPHIC BELTS, MANTLE TRANSITION ZONE, MONGOL-OKHOTSK OCEAN, TECTONIC EVOLUTION",
author = "Inna Safonova",
note = "Publisher Copyright: {\textcopyright} 2016 International Association for Gondwana Research",
year = "2017",
month = jul,
day = "1",
doi = "10.1016/j.gr.2016.09.003",
language = "English",
volume = "47",
pages = "6--27",
journal = "Gondwana Research",
issn = "1342-937X",
publisher = "Elsevier Science Inc.",

}

RIS

TY - JOUR

T1 - Juvenile versus recycled crust in the Central Asian Orogenic Belt

T2 - Implications from ocean plate stratigraphy, blueschist belts and intra-oceanic arcs

AU - Safonova, Inna

N1 - Publisher Copyright: © 2016 International Association for Gondwana Research

PY - 2017/7/1

Y1 - 2017/7/1

N2 - New or “juvenile” crust forms and grows mainly through mafic to andesitic magmatism at Pacific-type or accretionary type convergent margins as well as via tectonic accretion of oceanic and island-arc terranes and translation of continental terranes. During the last decades the juvenile or recycled nature of crust has been commonly evaluated using whole-rock isotope and Hf-in-zircon isotope methods. However, evidence for the accretionary or Pacific-type nature of an orogenic belt comes from geological data, for example, from the presence of accretionary complexes (AC), intra-oceanic arcs (IOA), oceanic plate stratigraphy units (OPS), and MORB-OIB derived blueschist belts (BSB). The Central Asian Orogenic Belt (CAOB) represents the world's largest province of Phanerozoic juvenile crustal growth during ca. 800 m.y. between the East European, Siberian, North China and Tarim cratons. From geological point of view, the CAOB is a typical Pacific-type belt as it hosts numerous occurrences of accretionary complexes, intra-oceanic arcs, OPS units, and MORB-OIB derived blueschist belts. In spite of its accretionary nature, supported by positive whole rock Nd isotope characteristics in CAOB granitoids, the Hf-in-zircon isotope data reveal a big portion of recycled crust. Such a controversy can be explained by presence of accreted microcontinents, isotopically mixed igneous reservoirs and by the tectonic erosion of juvenile crust. The most probable localities of tectonic erosion in the CAOB are the middle and southern Tienshan and southern Transbaikalia because these regions comprise a predominantly recycled crust (based on isotope data), but the geological data show the presence of intra-oceanic arcs, blueschist belts and accreted OPS with oceanic island basalts (OIB) and tectonically juxtaposed coeval arc granitoids and accretionary units. This warrants combination of detailed geological studies with isotopic results, as on their own they may not reflect such processes as tectonic erosion of juvenile crust and/or arc subduction.

AB - New or “juvenile” crust forms and grows mainly through mafic to andesitic magmatism at Pacific-type or accretionary type convergent margins as well as via tectonic accretion of oceanic and island-arc terranes and translation of continental terranes. During the last decades the juvenile or recycled nature of crust has been commonly evaluated using whole-rock isotope and Hf-in-zircon isotope methods. However, evidence for the accretionary or Pacific-type nature of an orogenic belt comes from geological data, for example, from the presence of accretionary complexes (AC), intra-oceanic arcs (IOA), oceanic plate stratigraphy units (OPS), and MORB-OIB derived blueschist belts (BSB). The Central Asian Orogenic Belt (CAOB) represents the world's largest province of Phanerozoic juvenile crustal growth during ca. 800 m.y. between the East European, Siberian, North China and Tarim cratons. From geological point of view, the CAOB is a typical Pacific-type belt as it hosts numerous occurrences of accretionary complexes, intra-oceanic arcs, OPS units, and MORB-OIB derived blueschist belts. In spite of its accretionary nature, supported by positive whole rock Nd isotope characteristics in CAOB granitoids, the Hf-in-zircon isotope data reveal a big portion of recycled crust. Such a controversy can be explained by presence of accreted microcontinents, isotopically mixed igneous reservoirs and by the tectonic erosion of juvenile crust. The most probable localities of tectonic erosion in the CAOB are the middle and southern Tienshan and southern Transbaikalia because these regions comprise a predominantly recycled crust (based on isotope data), but the geological data show the presence of intra-oceanic arcs, blueschist belts and accreted OPS with oceanic island basalts (OIB) and tectonically juxtaposed coeval arc granitoids and accretionary units. This warrants combination of detailed geological studies with isotopic results, as on their own they may not reflect such processes as tectonic erosion of juvenile crust and/or arc subduction.

KW - Accretionary complex

KW - Geological mapping

KW - Nd and Hf isotopes

KW - Pacific-type orogeny

KW - Tectonic erosion

KW - ISLAND-ARC

KW - ZIRCON U-PB

KW - INNER-MONGOLIA

KW - ND ISOTOPIC EVIDENCE

KW - CONTINENTAL-CRUST

KW - GORNY-ALTAI

KW - PAIRED METAMORPHIC BELTS

KW - MANTLE TRANSITION ZONE

KW - MONGOL-OKHOTSK OCEAN

KW - TECTONIC EVOLUTION

UR - http://www.scopus.com/inward/record.url?scp=85006106486&partnerID=8YFLogxK

U2 - 10.1016/j.gr.2016.09.003

DO - 10.1016/j.gr.2016.09.003

M3 - Review article

AN - SCOPUS:85006106486

VL - 47

SP - 6

EP - 27

JO - Gondwana Research

JF - Gondwana Research

SN - 1342-937X

ER -

ID: 16337276