Metal-insulator transition in (2+1)-dimensional Hubbard model with tensor renormalization group

Abstract

We investigate the doping-driven metal-insulator transition of the (2+1)-dimensional Hubbard model in the path-integral formalism with the tensor renormalization group method. We calculate the electron density n as a function of the chemical potential μ choosing three values of the Coulomb potential with U=80, 8, and 2 as representative cases of the strong, intermediate, and weak couplings. We have determined the critical chemical potential at each U, where the Hubbard model undergoes the metal-insulator transition from the half-filling plateau with n=1 to the metallic state with n > 1. Our results indicate that the model exhibits the metal-insulator transition over the vast region of the finite coupling U.