Theoretical and experimental evidence of a site-selective Mott transition in Fe2O3 under pressure

Abstract

We provide experimental and theoretical evidence for a novel type of pressure-induced insulator-metal transition characterized by site-selective delocalization of the electrons. M\"ossbauer spectroscopy, X-ray diffraction and electrical transport measurements on Fe2O3 to 100 GPa, along with dynamical mean-field theory (DFT+DMFT) calculations, reveal this site-selective Mott transition between 50 and 68 GPa, such that the metallization can be described by (VIFe3+HS)2O3 [R3c structure] 50~GPa (VIIIFe3+HS~VIFeM)O3 [P21/n structure] 68~GPa (VIFeM)2O3 [Aba2 structure]. Within the P21/n crystal structure, characterized by two distinct coordination sites (VI and VIII), we observe equal abundances of ferric ions (Fe3+) and ions having delocalized electrons (FeM), and only at higher pressures is a fully metallic Aba2 structure obtained, all at room temperature. The transition is characterized by delocalization/metallization of the 3d electrons on half the Fe sites, with a site-dependent collapse of local moments. Above 50 GPa, Fe2O3 is a strongly correlated metal with reduced electron mobility (large band renormalizations) of m*/m4 and 6 near the Fermi level. Upon decompression, we observe a site-selective (metallic) to conventional Mott insulator phase transition (VIIIFe3+HS~VIFeM)O3 50~GPa (VIIIFe3+HS~VIFe3+ HS)O3 within the same P21/n structure, indicating a decoupling of the electronic and lattice degrees of freedom, characteristic of a true Mott transition. Our results show that the interplay of electronic correlations and lattice may result in rather complex behavior of the electronic structure and magnetic state.