Quantum integrability and nonintegrability in the spin-boson model

Abstract

We study the spectral properties of a spin-boson Hamiltonian that depends on two continuous parameters 0≤<∞ (interaction strength) and 0≤α≤π/2 (integrability switch). In the classical limit this system has two distinct integrable regimes, α=0 and α=π/2. For each integrable regime we can express the quantum Hamiltonian as a function of two action operators. Their eigenvalues (multiples of ) are the natural quantum numbers for the complete level spectrum. This functional dependence cannot be extended into the nonintegrable regime (0<α<π/2). Here level crossings are prohibited and the level spectrum is naturally described by a single (energy sorting) quantum number. In consequence, the tracking of individual eigenstates along closed paths through both regimes leads to conflicting assignments of quantum numbers. This effect is a useful and reliable indicator of quantum chaos -- a diagnostic tool that is independent of any level-statistical analysis.