Single-Particle Dispersion and Density of States of the Half-Filled 2D Hubbard Model

Implementing an improved method for analytic continuation and working with imaginary-time correlation functions computed using quantum Monte Carlo simulations, we resolve the single-particle dispersion relation and the density of states (DOS) of the two-dimensional Hubbard model at half-filling. At intermediate interactions of $U/t = 4,6$, we find quadratic dispersion around the gap minimum at wave-vectors $\mathbf{k} = (\pm \pi/2, \pm \pi/2)$ (the $\Sigma$ points). We find saddle points at $\mathbf{k} = (\pm \pi,0),(0,\pm \pi)$ (the X points) where the dispersion is quartic, leading to a sharp DOS maximum above the almost flat ledge arising from the states close to $\Sigma$. The fraction of quasi-particle states within the ledge is $n_{\rm ledge} \approx 0.15$. Upon doping, within the rigid-band approximation, these results support Fermi pockets around the $\Sigma$ points, with states around the X points becoming filled only at doping fractions $x \ge n_{\rm ledge}$. The high density of states and the associated onset of $(\pi,\pi)$ scattering may be an important clue for a finite minimum doping level for superconductivity in the cuprates.