Ultrahigh-pressure minerals and metamorphic terranes - The view from China

J. G. Liou, W. G. Ernst, R. Y. Zhang, T. Tsujimori, B. M. Jahn

    Research output: Contribution to journalArticle

    226 Citations (Scopus)

    Abstract

    Ultrahigh-pressure (UHP) metamorphism refers to mineralogical modifications of continental and oceanic crustal protoliths ± associated mafic-ultramafic rocks initially formed or emplaced in shallow levels of the lithosphere, but which subsequently have experienced P-T conditions within or above the coesite stability field (>∼2.7 GPa, ∼700 °C). Typical products include eclogite, garnet peridotite, and UHP varieties of metapelite, quartzite, marble, paragneiss, and orthogneiss. UHP metamorphic assemblages require relatively cold lithospheric subduction to mantle depths; some recrystallization even occurs under "forbidden" P-T conditions, characterized by a geotherm of 2 with α-PbO2 structure, supersilicic clinopyroxene, high-P clinoenstatite, K-cymrite and stishovite. Globally, at least 20 coesite-bearing eclogitic, eight diamond-bearing, and five majoritic garnet-bearing UHP regions have been documented thus far; they are mostly of Phanerozoic ages. The presence of majoritic garnet, and even apparent stishovite pseudomorph in supracrustal rocks suggests continental subduction to mantle depths exceeding 300 km; such UHP metamorphic terranes should be distinguished from deep-seated mantle xenoliths that contain UHP minerals. Cold subduction zones may be sites of major recycling of H2O back into the mantle; high-P experiments on mafic-ultramafic bulk compositions reveal that many important hydrous and formally anhydrous phases are stable under such UHP conditions. The current explosion of research on continental UHP terranes reflects their significance for mantle dynamics and the tectonics of continental subduction, collision, exhumation, mantle-slab interactions, and geochemical recycling. A further characterization of UHP phases and positive identification of UHP minerals requires new experimental studies coupled with state-of-the-art analyses. For example, the very rare occurrence of microdiamond inclusions in zircons from Dabie-Sulu UHP rocks may reflect high fO2 attending recrystallization inasmuch as epidote is rather common. Rutile needles within garnets from Sulu UHP eclogitic rocks may not be the result of exsolution, so in such cases the apparent UHP pressure may have been over estimated. Hadean igneous microdiamond inclusions in Jack Hills detrital zircons could have originated from mantle xenoliths whereas abundant detrital Phanerozoic diamonds containing inclusions of coesite and other eclogitic minerals from New South Wales might have been derived from unexposed UHP metamorphic terranes. Micro-mineral intergrowth and nano-size minerals may hold important key to deciphering the actual P-T paths of subduction and mantle return flow. Although most exhumed terranes have returned surfaceward relatively rapidly after short time of UHP condition, the long duration of storage at great depth and slow exhumation for the largest UHP terranes remain as major problems.

    Original languageEnglish
    Pages (from-to)199-231
    Number of pages33
    JournalJournal of Asian Earth Sciences
    Volume35
    Issue number3-4
    DOIs
    Publication statusPublished - Jul 1 2009

    Fingerprint

    terrane
    mineral
    mantle
    coesite
    garnet
    subduction
    stishovite
    P-T conditions
    Phanerozoic
    exhumation
    diamond
    zircon
    recycling
    pseudomorph
    Hadean
    ultrahigh pressure metamorphism
    orthogneiss
    supracrustal rock
    metapelite
    new mineral

    Keywords

    • Garnet peridotite
    • Global UHP terranes
    • Majoritic garnet
    • Microdiamond
    • SHRIMP U-Pb ages
    • Sulu

    ASJC Scopus subject areas

    • Earth-Surface Processes
    • Geology

    Cite this

    Liou, J. G., Ernst, W. G., Zhang, R. Y., Tsujimori, T., & Jahn, B. M. (2009). Ultrahigh-pressure minerals and metamorphic terranes - The view from China. Journal of Asian Earth Sciences, 35(3-4), 199-231. https://doi.org/10.1016/j.jseaes.2008.10.012

    Ultrahigh-pressure minerals and metamorphic terranes - The view from China. / Liou, J. G.; Ernst, W. G.; Zhang, R. Y.; Tsujimori, T.; Jahn, B. M.

    In: Journal of Asian Earth Sciences, Vol. 35, No. 3-4, 01.07.2009, p. 199-231.

    Research output: Contribution to journalArticle

    Liou, J. G. ; Ernst, W. G. ; Zhang, R. Y. ; Tsujimori, T. ; Jahn, B. M. / Ultrahigh-pressure minerals and metamorphic terranes - The view from China. In: Journal of Asian Earth Sciences. 2009 ; Vol. 35, No. 3-4. pp. 199-231.
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    AU - Liou, J. G.

    AU - Ernst, W. G.

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