English

Virtual Processes and Superradiance in Spin-Boson Models

Quantum Physics 2009-02-10 v1

Abstract

We consider spin-boson models composed by a single bosonic mode and an ensemble of NN identical two-level atoms. The situation where the coupling between the bosonic mode and the atoms generates real and virtual processes is studied, where the whole system is in thermal equilibrium with a reservoir at temperature β1\beta^{-1}. Phase transitions from ordinary fluorescence to superradiant phase in three different models is investigated. First a model where the coupling between the bosonic mode and the jthj-th atom is via the pseudo-spin operator σ(j),z\sigma^{,z}_{(j)} is studied. Second, we investigate the generalized Dicke model, introducing different coupling constants between the single mode bosonic field and the environment, g1g_{1} and g2g_{2} for rotating and counter-rotating terms, respectively. Finally it is considered a modified version of the generalized Dicke model with intensity-dependent coupling in the rotating terms. In the first model the zero mode contributes to render the canonical entropy a negative quantity for low temperatures. The last two models presents phase transitions, even when only Hamiltonian terms which generates virtual processes are considered.

Keywords

Cite

@article{arxiv.0807.0639,
  title  = {Virtual Processes and Superradiance in Spin-Boson Models},
  author = {M. Aparicio Alcalde and R. Kullock and N. F. Svaiter},
  journal= {arXiv preprint arXiv:0807.0639},
  year   = {2009}
}
R2 v1 2026-06-21T10:57:20.080Z