Hyperfine interaction in the Autler-Townes effect II: control of two-photon selection rules in the Morris-Shore basis

Abstract

We investigated the absence of certain bright peaks in Autler-Townes laser excitation spectra of alkali metal atoms. Our research revealed that these dips in the spectra are caused by a specific architecture of adiabatic (or ``laser-dressed'') states in hyperfine (HF) components. The dressed states' analysis pinpointed several cases where constructive and destructive interference between HF excitation pathways in a two-photon excitation scheme limits the available two-photon transitions. This results in a reduction of the conventional two-photon selection rule for the total angular momentum F, from F= 0, 1 to F 0. Our discovery presents practical methods for selectively controlling the populations of unresolvable HF F-components of ns1/2 Rydberg states in alkali metal atoms. Using numerical simulations with sodium and rubidium atoms, we demonstrate that by blocking the effects of HF interaction with a specially tuned auxiliary control laser field, the deviations from the ideal selectivity of the HF components population can be lower than 0.01\% for Na and 0.001\% for Rb atoms.

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