Short range Coulomb correlations render massive Dirac fermions massless

Abstract

Tight binding electrons on a honeycomb lattice are described by an effective Dirac theory at low energies. Lowering symmetry by an alternate ionic potential () generates a single-particle gap in the spectrum. We employ the dynamical mean field theory (DMFT) technique, to study the effect of on-site electron correlation (U) on massive Dirac fermions. For a fixed mass parameter , we find that beyond a critical value Uc1() massive Dirac fermions become massless. Further increasing U beyond Uc2(), there will be another phase transition to the Mott insulating state. Therefore the competition between the single-particle gap parameter, , and the Hubbard U restores the semi-metallic nature of the parent Hamiltonian. The width of the intermediate semi-metallic regime shrinks by increasing the ionic potential. However, at small values of , there is a wide interval of U values for which the system remains semi-metal.