Magnetic field--induced modification of selection rules for Rb D2 line monitored by selective reflection from a vapor nanocell

Abstract

Magnetic field-induced giant modification of the probabilities of five transitions of 5S1/2, Fg=2 → 5P3/2, Fe=4 of 85Rb and three transitions of 5S1/2, Fg=1 → 5P3/2, Fe=3 of 87Rb forbidden by selection rules for zero magnetic field has been observed experimentally and described theoretically for the first time. For the case of excitation with circularly-polarized (σ+) laser radiation, the probability of Fg=2, ~mF=-2 → Fe=4, ~mF=-1 transition becomes the largest among the seventeen transitions of 85Rb Fg=2 → Fe=1,2,3,4 group, and the probability of Fg=1,~mF=-1 → Fe=3,~mF=0 transition becomes the largest among the nine transitions of 87Rb Fg=1 → Fe=0,1,2,3 group, in a wide range of magnetic field 200 -- 1000 G. Complete frequency separation of individual Zeeman components was obtained by implementation of derivative selective reflection technique with a 300 nm-thick nanocell filled with Rb, allowing formation of narrow optical resonances. Possible applications are addressed. The theoretical model is perfectly consistent with the experimental results.