Equilibrium Dynamics of the Sub-Ohmic Spin-boson Model Under Bias

Abstract

Using the bosonic numerical renormalization group method, we studied the equilibrium dynamical correlation function C(ω) of the spin operator σz for the biased sub-Ohmic spin-boson model. The small-ω behavior C(ω) ωs is found to be universal and independent of the bias ε and the coupling strength α (except at the quantum critical point α =αc and ε=0). Our NRG data also show C(ω) 2ωs for a wide range of parameters, including the biased strong coupling regime (ε ≠ 0 and α > αc), supporting the general validity of the Shiba relation. Close to the quantum critical point αc, the dependence of C(ω) on α and ε is understood in terms of the competition between ε and the crossover energy scale ω0 of the unbiased case. C(ω) is stable with respect to ε for ε ε. For ε ε, it is suppressed by ε in the low frequency regime. We establish that ε (ω0)1/θ holds for all sub-Ohmic regime 0 ≤slant s < 1, with θ=2/(3s) for 0 < s ≤slant 1/2 and θ = 2/(1+s) for 1/2 < s < 1. The variation of C(ω) with α and ε is summarized into a crossover phase diagram on the α-ε plane.