Holes' character and bond versus charge disproportionation in s-p ABX3 perovskites

Abstract

We use density functional theory methods to study the electronic structures of a series of s-p cubic perovskites ABX3: the experimentally available SrBiO3, BaBiO3, BaSbO3, CsTlF3, and CsTlCl3, as well as the hypothetical MgPO3, CaAsO3, SrSbO3, and RaMcO3. We use tight-binding modeling to calculate the interatomic hopping integrals tspσ between the B-s and X-p atomic orbitals and charge-transfer energies , which are the two most important parameters that determine the low-energy electron and hole states of these systems. Our calculations elucidate several trends in tspσ and as one moves across the periodic table, such as the relativistic energy lowering of the B-s orbital in heavy B cations leading to strongly negative values. Our results are discussed in connection with the general phase diagram for s - p cubic perovskites proposed in Ref. 26, where the parent superconductors SrBiO3 and BaBiO3 are found to be in the regime of negative and large tspσ. Here, we explore this further and search for new materials with similar parameters, which could lead to the discovery of new superconductors. Also, some considerations are offered regarding a possible relation between the physical properties of a given s - p compound (such as its tendency to bond disproportionate and the maximal achievable superconducting transition temperature) and its electronic structure.