Criticality of the Mean-Field Spin-Boson Model: Boson State Truncation and Its Scaling Analysis

Abstract

The spin-boson model has nontrivial quantum phase transitions at zero temperature induced by the spin-boson coupling. The bosonic numerical renormalization group (BNRG) study of the critical exponents β and δ of this model is hampered by the effects of boson Hilbert space truncation. Here we analyze the mean-field spin boson model to figure out the scaling behavior of magnetization under the cutoff of boson states Nb. We find that the truncation is a strong relevant operator with respect to the Gaussian fixed point in 0<s<1/2 and incurs the deviation of the exponents from the classical values. The magnetization at zero bias near the critical point is described by a generalized homogeneous function (GHF) of two variables τ=α-αc and x=1/Nb. The universal function has a double-power form and the powers are obtained analytically as well as numerically. Similarly, m(α=αc) is found to be a GHF of ε and x. In the regime s>1/2, the truncation produces no effect. Implications of these findings to the BNRG study are discussed.