Confinement-driven transitions between topological and Mott phases in (LaNiO3)N/(LaAlO3)M(111) superlattices

Abstract

A set of broken symmetry two-dimensional ground states are predicted in (111)-oriented (LaNiO3)N/(LaAlO3)M (N/M) superlattices, based on density functional theory (DFT) calculations including a Hubbard U term. An unanticipated Jahn-Teller distortion with dz2 orbital polarization and a FM Mott insulating (and multiferroic) phase emerges in the double perovskite (1/1), that shows strong susceptibility to strain-controlled orbital engineering. The LaNiO3 bilayer with graphene topology has a switchable multiferroic (ferromagnetic (FM) and ferroelectric) insulating ground state with inequivalent Ni sites. Beyond N=3 the confined LaNiO3 slab undergoes a metal-to-insulator transition through a half-semimetallic phase with conduction originating from the interfaces. Antiferromagnetic arrangements allow combining motifs of the bilayer and single trigonal layer band structures in designed artificial mixed phases.