Effects of field distribution on the tunneling time of ultracold atoms through high-quality cavities

Abstract

We explore the traversal essence of the ultracold atoms propagating through high-quality cavities in vacuum, Fock state and coherent field distribution. The atom-field interaction is considered for a two-photon resonance process which transforms into a scattering-like venture with non-zero reflection/transmission probabilities. Here the field statistics strongly effects the interaction process and hence the tunneling time of the incident atoms through the cavity. We examine the propagation of the wave packet peaks associated with the atoms and referred it as the phase time of tunneling. It is found that for suitable field distributions, demeanor of the tunneling time might be smartly transposed from sub- to the super-classical nature. Further, extent and site of the sub- and superclassical peaks on the energy axis can be vigorously managed via the field intensity of the mazer cavity. Moreover, the mazer action (scattering like behavior) can be accomplished even for thermal atoms while using somewhat higher intensities of the field.