Phase diagram of the Hubbard model on a honeycomb lattice: A cluster slave-spin study

Abstract

The cluster slave-spin method is implemented to research the ground state properties of the honeycomb lattice Hubbard model with doping δ and coupling U being its parameters. At half-filling, a single direct and continuous phase transition between the semi-metal and antiferromagnetic (AFM) insulator is found at UAFM=2.43t that is in the Gross-Neveu-Yukawa universality class, where a relation between the staggered magnetization M and the AFM energy gap AFM is established as M AFM, compared to M AFM ( AFM)2 in the square lattice case. A first-order semi-metal to the underlying paramagnetic (PM) insulator Mott transition is corroborated at UMott=8.36t, which is responsible for a broad crossover around Uc = 5.4t between the weak- and strong-coupling regimes in the AFM state that increases with δ, in contrast to the square lattice case. In the doped system, the compressibility near the van Hove singularity at δ=1/4 is suppressed substantially by the interaction before the semi-metal to AFM transition occurs, whereas near the Dirac points is very close to the noninteracting one, indicating that the Dirac cone structure of the energy dispersion is rather robust. An overall phase diagram in the U-δ plane is presented, consisting of four regimes: the AFM insulator at δ=0 for U> UAFM, the AFM metal with compressibility >0 or <0, and the PM semi-metal, and the AFM metal with <0 only exists in an extremely small area near the phase boundary between the AFM and PM state.