Summary
Al-bearing stishovite is considered to be the main H2O-bearing silicate phase present in recycled subducted oceanic crust (i.e. eclogite) at uppermost lower mantle conditions, equivalent to >660 km mantle depths, and pressures above 23 GPa, where it can form 25% of the bulk. The incorporation of Al into stishovite leads to significant changes to its phase diagram and its ability to take up H2O. For instance, it halves the pressure required for its rutile- to CaCl2-type transformation, which exhibits significant elastic softening and may be seismically observable.
We currently lack any information on the influence of Fe and Ti on the elastic properties and post-stishovite transitions of Al-and/or H2O-bearing stishovite - even though we know that these defects and solid-solutions are important features of other silicate phases in the mantle; e.g. Ca(Si,Ti)O3 perovskite.
We propose a comprehensive synthesis programme, combined with on-line elastic measurements by ultrasonic interferometry and x-ray diffraction to determine the effects of defect type and concentration on the density, phase diagram and elastic response of this important suite of stishovites. This work, based at ID06LVP, The European Synchrotron, will be supplemented by examination by microscopic and spectroscopic methods at the forefront of microbeam techniques.
Understanding elastic properties of Fe-, Al-, Ti-, and H2O -bearing eclogitic stishovite will allow improvements in fundamental models used to predict and determine the observability of seismic discontinuities and velocity anomalies caused by the subduction of eclogitic material through the Earth’s mantle, particularly in the upper part of the lower mantle. This study will also help to better assess the effects of incorporation of minor amounts of FeO, Fe2O3, Al2O3 and H2O in stishovite on the lower mantle’s density.
We currently lack any information on the influence of Fe and Ti on the elastic properties and post-stishovite transitions of Al-and/or H2O-bearing stishovite - even though we know that these defects and solid-solutions are important features of other silicate phases in the mantle; e.g. Ca(Si,Ti)O3 perovskite.
We propose a comprehensive synthesis programme, combined with on-line elastic measurements by ultrasonic interferometry and x-ray diffraction to determine the effects of defect type and concentration on the density, phase diagram and elastic response of this important suite of stishovites. This work, based at ID06LVP, The European Synchrotron, will be supplemented by examination by microscopic and spectroscopic methods at the forefront of microbeam techniques.
Understanding elastic properties of Fe-, Al-, Ti-, and H2O -bearing eclogitic stishovite will allow improvements in fundamental models used to predict and determine the observability of seismic discontinuities and velocity anomalies caused by the subduction of eclogitic material through the Earth’s mantle, particularly in the upper part of the lower mantle. This study will also help to better assess the effects of incorporation of minor amounts of FeO, Fe2O3, Al2O3 and H2O in stishovite on the lower mantle’s density.
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| Web resources: | https://cordis.europa.eu/project/id/898169 |
| Start date: | 01-09-2020 |
| End date: | 31-05-2024 |
| Total budget - Public funding: | 295 061,76 Euro - 295 061,00 Euro |
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Original description
Al-bearing stishovite is considered to be the main H2O-bearing silicate phase present in recycled subducted oceanic crust (i.e. eclogite) at uppermost lower mantle conditions, equivalent to >660 km mantle depths, and pressures above 23 GPa, where it can form 25% of the bulk. The incorporation of Al into stishovite leads to significant changes to its phase diagram and its ability to take up H2O. For instance, it halves the pressure required for its rutile- to CaCl2-type transformation, which exhibits significant elastic softening and may be seismically observable.We currently lack any information on the influence of Fe and Ti on the elastic properties and post-stishovite transitions of Al-and/or H2O-bearing stishovite - even though we know that these defects and solid-solutions are important features of other silicate phases in the mantle; e.g. Ca(Si,Ti)O3 perovskite.
We propose a comprehensive synthesis programme, combined with on-line elastic measurements by ultrasonic interferometry and x-ray diffraction to determine the effects of defect type and concentration on the density, phase diagram and elastic response of this important suite of stishovites. This work, based at ID06LVP, The European Synchrotron, will be supplemented by examination by microscopic and spectroscopic methods at the forefront of microbeam techniques.
Understanding elastic properties of Fe-, Al-, Ti-, and H2O -bearing eclogitic stishovite will allow improvements in fundamental models used to predict and determine the observability of seismic discontinuities and velocity anomalies caused by the subduction of eclogitic material through the Earth’s mantle, particularly in the upper part of the lower mantle. This study will also help to better assess the effects of incorporation of minor amounts of FeO, Fe2O3, Al2O3 and H2O in stishovite on the lower mantle’s density.
Status
SIGNEDCall topic
MSCA-IF-2019Update Date
28-04-2024
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