Scaling Analysis in the Numerical Renormalization Group Study of the Sub-Ohmic Spin-Boson Model

Abstract

The spin-boson model has nontrivial quantum phase transitions in the sub-Ohmic regime. For the bath spectra exponent 0 ≤slant s<1/2, the bosonic numerical renormalization group (BNRG) study of the exponents β and δ are hampered by the boson state truncation which leads to artificial interacting exponents instead of the correct Gaussian ones. In this paper, guided by a mean-field calculation, we study the order parameter function m(τ=α-αc, ε, ) using BNRG. Scaling analysis with respect to the boson state truncation Nb, the logarithmic discretization parameter , and the tunneling strength are carried out. Truncation-induced multiple-power behaviors are observed close to the critical point, with artificial values of β and δ. They cross over to classical behaviors with exponents β=1/2 and δ=3 on the intermediate scales of τ and ε, respectively. We also find τ/1-s and ε/ scalings in the function m(τ, ε, ). The role of boson state truncation as a scaling variable in the BNRG result for 0 ≤slant s<1/2 is identified and its interplay with the logarithmic discretization revealed. Relevance to the validity of quantum-to-classical mapping in other impurity models is discussed.