Mott transition, magnetic and orbital orders in the ground state of the two-band Hubbard model using variational slave-spin mean field formalism

Abstract

We study the ground state of the Hubbard model on a square lattice with two degenerate orbitals per site and at integer fillings as a function of onsite Hubbard repulsion U and Hund's intra-atomic exchange coupling J. We use a variational slave-spin mean field (VSSMF) method which allows symmetry broken states to be studied within the computationally less intensive slave-spin mean field formalism, thus making the method more powerful to study strongly correlated electron physics. The results show that at half-filling, the ground state at smaller U is a Slater antiferromagnet (AF) with substantial local charge fluctuations. As U is increased, the AF state develops a Heisenberg behavior, finally undergoing a first order transition to a Mott insulating AF state at a critical interaction Uc which is of the order of the bandwidth. Introducing the Hund's coupling J correlates the system more and reduces Uc drastically. At quarter-filling with one electron per site, the ground state at smaller U is paramagnetic metallic. At finite Hund's coupling J, as interaction is increased above a lower critical value Uc1, it goes to a fully spin polarized ferromagnetic state coexisting with an antiferro-orbital order. The system eventually becomes Mott insulating at a higher critical value Uc2. The results as a function of U and J are thoroughly discussed.