Momentum structure of the self-energy and its parametrization for the two-dimensional Hubbard model

Abstract

We compute the self-energy for the half-filled Hubbard model on a square lattice using lattice quantum Monte Carlo simulations and the dynamical vertex approximation. The self-energy is strongly momentum dependent, but it can be parametrized via the non-interacting energy-momentum dispersion k, except for pseudogap features right at the Fermi edge. That is, it can be written as (k,ω), with two energy-like parameters (, ω) instead of three (kx, ky and ω). The self-energy has two rather broad and weakly dispersing high energy features and a sharp ω= k feature at high temperatures, which turns to ω= -k at low temperatures. Altogether this yields a Z- and reversed-Z-like structure, respectively, for the imaginary part of (k,ω). We attribute the change of the low energy structure to antiferromagnetic spin fluctuations.