Perturbation study of nonequilibrium quasi-particle spectra in an infinite-dimensional Hubbard lattice

Abstract

A model for nonequilibrium dynamical mean-field theory is constructed for the infinite dimensional Hubbard lattice. We impose nonequilibrium by expressing the physical orbital as a superposition of a left-(L) moving and right-(R) moving electronic state with the respective chemical potential μL and μR. Using the second-order iterative perturbation theory we calculate the quasi-particle properties as a function of the chemical potential bias between the L and R movers, i.e. = μL - μR. The evolution of the nonequilibrium quasi-particle spectrum is mapped out as a function of the bias and temperature. The quasi-particle states with the renormalized Fermi energy scale 0QP disappear at 0QP in the low temperature limit. The second-order perturbation theory predicts that in the vicinity of the Mott-insulator transition at the Coulomb parameter U=Uc, there exists another critical Coulomb parameter Ud (<Uc) such that, for Ud<U<Uc, quasi-particle states are destroyed abruptly when (0QP)2 a(π kBTc)2+ bc2 with the critical temperature Tc, the critical bias c and the numerical constants a and b at the order of unity.