Atomic transitions of Rb, D2 line in strong magnetic fields: hyperfine Paschen-Back regime

Abstract

An efficient λ/2-method (λ is the resonant wavelength of laser radiation) based on nanometric-thickness cell filled with rubidium is implemented to study the splitting of hyperfine transitions of 85Rb and 87Rb D2 lines in an external magnetic field in the range of B =3~kG -- 7~kG. It is experimentally demonstrated that at B > 3~kG from 38 (22) Zeeman transitions allowed at low B-field in 85Rb (87Rb) spectra in the case of σ+ polarized laser radiation there remain only 12 (8) which is caused by decoupling of the total electronic momentum J and the nuclear spin momentum I (hyperfine Paschen-Back regime). Note that at B > 4.5~kG in the absorption spectrum these 20 atomic transitions are regrouped in two completely separate groups of 10 atomic transitions each. Their frequency positions and fixed (within each group) frequency slopes, as well as the probability characteristics are determined. A unique behavior of the atomic transitions of 85Rb and 87Rb labeled 19 and 20 (for low magnetic field they could be presented as transitions Fg=3, mF=+3 → Fe=4, mF=+4 and Fg=2, mF=+2 → Fe=3, mF=+3, correspondingly) is stressed. The experiment agrees well with the theory. Comparison of the behavior of atomic transitions for D2 line compared with that of D1 line is presented. Possible applications are described.