Stellar MgSiO3 perovskite:: A shock-transformed stardust silicate found in a meteorite

We have discovered an isotopically highly anomalous MgSiO3 grain in the ungrouped carbonaceous chondrite Acfer 094 with a perovskite-like crystal structure resembling the dominant high-pressure mineral of the Earth's lower mantle. Oxygen isotopic ratios of the silicate grain are O-17/O-16 = (4.91 +/- 0.36) x 10(-3) (12 times the solar value) and O-18/O-16(1.36 +/- 0.19) x 10(-3) (0.4 times the solar value). This signature points to condensation in the ejecta of a similar to 2 M-circle dot close-to-solar metallicity red giant branch (RGB) or asymptotic giant branch(AGB), star. Alternatively, the grain could have formed in the ejecta of a nova, in which O-17 is highly overabundant. TEM analysis of the grain revealed a high pressure perovskite-like crystal structure not predicted by equilibrium condensation in low-pressure stellar environments. A possible formation scenario is transformation of a silicate precursor triggered by a shock wave, either in the interstellar medium (ISM) or originating from the grain's parent star. Shock waves must thus be considered as a potential mechanism to recrystallize silicates, or even convert them into high-pressure structures. Alternatively, nonequilibrium condensation or crystallization by a chemical vapor deposition (CVD)-like process, also invoked for the formation of nanodiamonds, is a distinct possibility, although more speculative.