Pressure induced Insulator-Metal transition in LaMnO3

Abstract

The recent observation of a insulator to metal transition (IMT) [I. Loa et al, PRL 87, 125501 (2001)] in pure LaMnO3 at 32 GPa and room temperature, well above the Neel temperature (145 K) and below the Jahn-Teller transition temperature (780 K), opens the way to a study of the role of the orbital degrees of freedom on the electronic structure in a stoichiometric material. In this paper we focus our attention in the orbital aspects of the insulator to metal transition. We use a model Hamiltonian for the eg orbitals of Mn that includes the on site Coulomb repulsion U, the hopping t, and its dependence with pressure. In order to include in an appropriate way the strong correlations induced by the dominant electron-electron interactions we introduce auxiliary fields (Slave Bosons,SB) to the description of the low energy states. We use a O-Mn distance (d) dependence of t and the pressure-d relation from the experimental data to describe the evolution of the electronic structure with pressure. Our results confirm and make transparent the conclusion reached in previous ab-initio calculations: the inclusion of the Coulomb energy is necessary and constitutes an important factor enhancing the orbital polarization in these compounds.