Existence of Ground State Eigenvalues for the Spin-Boson Model with Critical Infrared Divergence and Multiscale Analysis

TL;DR

This paper proves the existence of ground state eigenvalues in the spin-boson model with critical infrared divergence by employing a multiscale analysis and identifying a symmetry that ensures the most singular terms vanish.

Contribution

It provides an alternative proof of binding for off-diagonal coupling in the spin-boson model using a novel multiscale method and symmetry analysis.

Findings

Ground state eigenvalues exist for off-diagonal coupling

Multiscale analysis effectively handles critical infrared divergence

A new symmetry operator simplifies the analysis

Abstract

A two-level atom coupled to the radiation field is studied. First principles in physics suggest that the coupling function, representing the interaction between the atom and the radiation field, behaves like $\vert k \vert^{- 1/2}$, as the photon momentum k tends to zero. Previous results on non-existence of ground state eigenvalues suggest that in the most general case binding does not occur in the spin-boson model, i.e., the minimal energy of the atom-photon system is not an eigenvalue of the energy operator. Hasler and Herbst have shown [12], however, that under the additional hypothesis that the coupling function be off-diagonal -which is customary to assume-binding does indeed occur. In this paper an alternative proof of binding in case of off-diagonal coupling is given, i.e., it is proven that, if the coupling function is off-diagonal, the ground state energy of the spin-boson model is an eigenvalue of the Hamiltonian. We develop a multiscale method that can be applied in the situation we study, identifying a new key symmetry operator which we use to demonstrate that the most singular terms appearing in the multiscale analysis vanish.