Quasi-degenerate resonant eigenstate doublets of two quantum emitters in a closed waveguide

Abstract: The physics of systems of quantum emitters is significantly influenced by the relation between their spatial separation and the wavelength of the emitted photons. If the distance that separates a pair of emitters meets specific resonance conditions, the photons produced from decay may destructively interfere. In an infinite-wavelength setting, this effect gives rise to bound states in the continuum, where a photon remains confined in between the emitter. In the case of a finite-length waveguide with two periodic boundary conditions, the relevant distances become two, leading to states in which a photon is confined in either the shorter or the longer path that connects the emitters. If the ratio of the shorter and the longer path is a rational number, these two kinds of resonant states are allowed to co-exist in the same Hamiltonian. In this paper, we investigate the existence of quasi-degenerate resonant doublets of a pair of identical emitters coupled to a linear waveguide mode. The states that form the doublet are searched among the ones in which a single excitation tends to remain bound to the emitters. We investigate the spectrum in a finite range around degeneracy points to check whether the doublet remains well separated from the closest eigenvalues in the spectrum. The identification of quasi-degenerate doublets opens the possibility to manipulate the emitters-waveguide system as an effectively two-level system in specific energy ranges, providing an innovative tool for quantum technology tasks.