Study of iron oxides under laser-driven shock compression
Céline Crépisson [webpage]
Department of Physics, Clarendon Laboratory, University of Oxford
ABSTRACT
Iron oxides are of significance within the Earth lower mantle. They are present both as a major (Mg,Fe)O phase or within subducted material such as Banded Iron Formations (with the presence of FeOOH, Fe2O3, Fe3O4). Their electronic and structural properties under pressure could explain seismological heterogeneities in the lower mantle [1] and Ultra-Low Velocity Zones at the Core Mantle Boundary [2]. Moreover, iron oxides melts can provide information on the Fe-O bonding environment within the Earth’s outer-core of possible interest for the Geodynamo [3]. Laser-driven shock compression probed by an X-ray Free Electron Laser makes it possible to access the high-pressure regime of Earth’s lower mantle and outer-core, and to study the evolution of both electronic and structural properties of iron oxides. In this talk I will present results on Fe2O3 and FeO using in-situ x-ray diffraction (XRD) under laser-driven shock compression up to 209 GPa. Electronic and structural evolutions of Fe2O3 and FeO at lower-mantle pressures under shock are compared to previous static compression data. The behaviour of Fe2O3 above 122 GPa, shown to undergo amorphization and melting, is reported for the first time. I will also present some preliminary work looking at accessing directly the electronic structure of FeO (via Resonant Inelastic X-ray Scattering) and FeO elastic constants (via XRD) under pressure.
REFERENCES
[1] Lin et al., Science 317, (2007)
[2] Dobson et al., Nature 434, (2005)
[3] Ozawa et al., Science 334, (2011)