Microscopic origin of pressure-induced isosymmetric transitions in fluoromanganate cryolites

Abstract

Using first-principles density functional theory calculations, we investigate the hydrostatic pressure-induced reorientation of the Mn--F Jahn-Teller bond axis in the fluoride cryolite Na3MnF6. We find a first-order isosymmetric transition occurs between crystallographically equivalent monoclinic structures at approximately 2.15 GPa, consistent with earlier experimental studies. Analogous calculations for isostructural 3d0 Na3ScF6 show no evidence of a transition up to 6.82 GPa. Mode crystallography analyses of the pressure-dependent structures in the vicinity of the transition reveals a clear evolution of the Jahn-Teller bond distortions in cooperation with an asymmetrical stretching of the equatorial fluorine atoms in the MnF6 octahedral units. We identify a change in orbital occupancy of the eg manifold in the 3d4 Jahn-Teller active Mn(III) to be responsible for the transition, which stabilizes one monoclinic P21/n variant over the other.