Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
4677713 | Earth and Planetary Science Letters | 2011 | 7 Pages |
The formation and properties of the post-perovskite (CaIrO3-type) phase were studied in Fe-rich compositions along the pyrope–almandine ((Mg,Fe)3Al2Si3O12) join. Natural and synthetic garnet starting materials with almandine fractions from 38 to 90 mol% were studied using synchrotron X-ray diffraction in the laser-heated diamond anvil cell. Single-phase post-perovskite could be successfully synthesized from garnet compositions at pressures above 148 GPa and temperatures higher than 1600 K. In some cases, evidence for a minor amount of Al2O3 post-perovskite was observed for Alm38 and Alm54 compositions in the perovskite + post-perovskite two-phase region. Pressure–volume data for the post-perovskite phases collected during decompression show that incorporation of Fe leads to a systematic increase of unit cell volume broadly similar to the variation observed in the (Mg,Fe)SiO3 system. The presence of Al2O3 increases the stability of perovskite relative to post-perovskite, requiring higher pressures (> 148 GPa) for synthesis of pure post-perovskites. Our data together with those of Tateno et al. (2005) also suggest that in the Al-rich system the presence of Fe has no strong effect on the pressure required to synthesize the pure post-perovskite phase, but the two-phase perovskite and post-perovskite region may be broad and its width dependent on Fe content. Our results suggest that any regions highly enriched in Al2O3 may consist of either the perovskite phase or a mixture of perovskite and post-perovskite phases throughout the entire thickness of the D″ region. The observed synthesis pressures (> 148 GPa) for a pure post-perovskite phase are beyond that at the Earth's core–mantle boundary (~ 135 GPa).
► Single-phase post-perovskite was synthesized at P > 148 GPa and T > 1600 K. ► Two-phase mixture perovskite + post-perovskite was found between 118 and 148 GPa. ► Enriched in Al2O3 extends the stability field of perovskite to core–mantle boundary.