Critical Exponents of the Metal-Insulator Transition in the Two-Dimensional Hubbard Model
Abstract
We study the filling-controlled metal-insulator transition in the two-dimensional Hubbard model near half-filling with the use of zero temperature quantum Monte Carlo methods. In the metallic phase, the compressibility behaves as |μ - μc|-0.580.08 where μc is the critical chemical potential. In the insulating phase, the localization length follows l |μ - μc|-l with l = 0.26 0.05. Under the assumption of hyperscaling, the compressibility data leads to a correlation length exponent = 0.21 0.04. Our results show that the exponents and l agree within statistical uncertainty. This confirms the assumption of hyperscaling with correlation length exponent = 1/4 and dynamical exponent z = 4. In contrast the metal-insulator transition in the generic band insulators in all dimensions as well as in the one-dimensional Hubbard model satisfy the hyperscaling assumption with exponents = 1/2 and z = 2.
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