Prediction of a new potential high-pressure structure of FeSiO3

Abstract

We predict a new candidate high-temperature high-pressure structure of FeSiO3 with space-group symmetry Cmmm by applying an evolutionary algorithm within DFT+U that we call post-perovskite II (PPv-II). An exhaustive search found no other competitive candidate structures with ABO3 composition. We compared the X-ray diffraction (XRD) pattern of FeSiO3 PPv-II with experimental results of the recently reported H-phase of (Fe,Mg)SiO3. The intensities and positions of two main X-ray diffraction peaks of PPv-II FeSiO3 compare well with those of the H-phase. We also calculated the static equation of state, the enthalpy and the bulk modulus of the PPv-II phase and compared it with those of perovskite (Pv) and post-perovskite (PPv) phases of FeSiO3. According to the static DFT+U computations the PPv-II phase of FeSiO3 is less stable than Pv and PPv phases under lower mantle pressure conditions at 0 K and has a higher volume. PPv-II may be entropically stabilized, and may be a stable phase in Earth's lower mantle, coexisting with α-PbO2 (Columbite-structured) silica and perovskite, or with magnesiowustite or ferropericlase, depending on bulk composition.