Perspectives of the disproportionation driven superconductivity in strongly correlated 3d compounds

Abstract

Disproportionation in 3d compounds can give rise to an unconventional electron-hole Bose liquid with a very rich phase diagram from a Bose metal, charge ordering insulator to an inhomogeneous Bose superfluid. Optimal conditions for the disproportionation driven high-Tc superconductivity are shown to realize only for several Jahn-Teller dn configurations that permit the formation of well defined local composite bosons. These are the high-spin d4, low-spin d7, and d9 configurations given the octahedral crystal field, and the d1, high-spin d6 configurations given the tetrahedral crystal field. The disproportionation reaction has a peculiar anti-Jahn- Teller character lifting the bare orbital degeneracy. Superconductivity in the d4 and d6 systems at variance with d1, d7, and d9 systems implies an unavoidable coexistence of the spin-triplet composite bosons and a magnetic lattice. We argue that unconventional high-Tc superconductivity observed in quasi-2D cuprates with tetragonally distorted CuO6 octahedra and iron-based layered pnictides/chalcogenides with tetrahedrally coordinated Fe2+ ions can be a key argument supporting the disproportionation scenario is at work in these compounds.