Non-magnetic insulating phase induced by Jahn-Teller effect in RNiO3

Abstract

We propose a three-dimensional multi-orbital tight-binding model for rare-earth nickelates RNiO3 that treats charge, spin, orbital, and lattice degrees of freedom on equal footing. All model parameters, including the on-site interactions U and J and the electron-phonon (el-ph) coupling to the breathing mode, are extracted from hybrid-functional DFT calculations for the small-bandwidth nickelate LuNiO3. The model describes three competing insulating phases governed by the interplay of U-3J and el-ph coupling to the breathing and Jahn--Teller (JT) modes. For large U-3J, the insulating state is stabilized by local JT distortions on high-spin Ni3+ sites. For smaller U-3J, the system undergoes charge disproportionation, 2Ni3+→Ni2++Ni4+, resulting in the spin-polarized charge-ordered state observed experimentally below the N\'eel temperature in small-bandwidth RNiO3. When the JT energy on the Ni2+ site exceeds Hund's exchange 3J, a distinct charge- and orbital-ordered insulating phase emerges in which the two eg-electrons occupy the same orbital with opposite spin. The stability of this phase is further confirmed by self-consistent calculations within the full three-dimensional tight-binding model. This newly predicted metastable state, characterized by JT distortions in a nonmagnetic charge-ordered RNiO3 phase, shows that the onset of magnetic order is not required for the metal-insulator transition in RNiO3.