Pseudogap, non-Fermi-liquid behavior, and particle-hole asymmetry in the 2D Hubbard model

Abstract

The effect of doping in the two-dimensional Hubbard model is studied within finite temperature exact diagonalization combined with cluster dynamical mean field theory. By employing a mixed basis involving cluster sites and bath molecular orbitals for the projection of the lattice Green's function onto 2x2 clusters, a considerably more accurate description of the low frequency properties of the self-energy is achieved than in a pure site picture. The transition from Fermi-liquid to non-Fermi-liquid behavior for decreasing hole doping is studied as a function of Coulomb energy, next-nearest neighbor hopping, and temperature. In particular, the self-energy component SigmaX associated with X=(pi,0) is shown to exhibit an onset of non-Fermi-liquid behavior as the hole doping decreases below a critical value deltac. The imaginary part of SigmaX(omega) then develops a collective mode above EF, which exhibits a distinct dispersion with doping. Accordingly, the real part of SigmaX(omega) has a positive slope above EF, giving rise to an increasing particle-hole asymmetry as the system approaches the Mott transition. This behavior is consistent with the removal of spectral weight from electron states close to EF and the opening of a pseudogap which increases with decreasing doping. The phase diagram reveals that deltac = 0.15 ... 0.20 for various system parameters. For electron doping, the collective mode of SigmaX(omega) and the concomitant pseudogap are located below the Fermi energy which is consistent the removal of spectral weight from hole states just below EF. The critical doping which marks the onset of non-Fermi-liquid behavior, is systematically smaller than for hole doping.