Quantum phase transition of the sub-Ohmic rotor model

Abstract

We investigate the behavior of an N-component quantum rotor coupled to a bosonic dissipative bath having a sub-Ohmic spectral density J(ω) ωs with s<1. With increasing dissipation strength, this system undergoes a quantum phase transition from a delocalized phase to a localized phase. We determine the exact critical behavior of this transition in the large-N limit. For 1>s>1/2, we find nontrivial critical behavior corresponding to an interacting renormalization group fixed point while we find mean-field behavior for s<1/2. The results agree with those of the corresponding long-range interacting classical model. The quantum-to-classical mapping is therefore valid for the sub-Ohmic rotor model.