• Title of article

    Evidence for low viscosity garnet-rich layers in the upper mantle

  • Author/Authors

    Barnhoorn، نويسنده , , Auke and Drury، نويسنده , , Martyn R. and van Roermund، نويسنده , , Herman L.M.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2010
  • Pages
    14
  • From page
    54
  • To page
    67
  • Abstract
    The rheological properties of upper mantle rocks play an important role in controlling the dynamics of the lithosphere and mantle convection. Experimental studies and microstructures in naturally deformed mantle rocks usually imply that olivine controls the upper mantle rheology. Here we show for the first time evidence from the geometry of folded compositional layers in mantle rocks from Western Norway that garnet-rich rocks can have lower solid-state viscosities than olivine-rich rocks. Modeling of melt-free and dry rheology of garnet and olivine confirms that the reversed viscosity contrast between garnet-rich and olivine-rich layers for this folding event can be achieved over a relatively wide range of temperatures at low stress conditions when the fine-grained garnet deforms by diffusion creep while the coarse-grained olivine deforms by dislocation creep and/or diffusion creep. eral, modeling of the fold viscosity contrast shows that in the stable subcontinental lithospheric mantle or convecting mantle such a reversed viscosity contrast can be formed due to diffusion creep processes in fine-grained garnets in a dry mantle environment or at conditions where the garnet-pyroxene layer is partially molten, i.e. close to solidus–liquidus conditions in the upper mantle. Alternatively in cold plate tectonic settings, e.g. in subduction zones, some water-weakening is a feasible mechanism to create the reversed viscosity contrast between garnet and olivine.
  • Keywords
    strength contrast , diffusion creep , rheology , Peridotite , Microstructures , Ultra-high pressure metamorphism
  • Journal title
    Earth and Planetary Science Letters
  • Serial Year
    2010
  • Journal title
    Earth and Planetary Science Letters
  • Record number

    2327901