Magic and tune-out wavelengths for atomic francium

TL;DR

This paper calculates the polarizabilities of francium to identify magic and tune-out wavelengths, facilitating laser cooling and trapping for fundamental symmetry experiments.

Contribution

It provides the first detailed calculations of magic and tune-out wavelengths for francium, aiding experimental efforts in trapping and precision measurements.

Findings

Identified magic wavelengths suitable for trapping francium.

Calculated tune-out wavelengths where polarizability is zero.

Suggested laser wavelengths in UV, visible, and infrared for experiments.

Abstract

The frequency dependent polarizabilities of the francium atom are calculated from the available data of energy levels and transition rates. Magic wavelengths for the state insensitive optical dipole trapping are identified from the calculated light shifts of the $7s~^2S_{1/2}$, $7p~^2P_{1/2, 3/2}$ and $8s~^{2}S_{1/2}$ levels of the $7s~^{2}S_{1/2}-7p~^{2}P_{1/2,3/2}$ and $7s~^{2}S_{1/2}-8s~^{2}S_{1/2}$ transitions, respectively. Wavelengths in the ultraviolet, visible and near infrared region is identified that are suitable for cooling and trapping. Magic wavelengths between 600-700~nm and 700-1000~nm region, which are blue and red detuned with the $7s-7p$ and $7s-8s$ transitions are feasible to implement as lasers with sufficient power are available. In addition, we calculated the tune-out wavelengths where the ac polarizability of the ground $7s~^{2}S_{1/2}$ state in francium is zero. These results are beneficial as laser cooled and trapped francium has been in use for fundamental symmetry investigations like searches for an electron permanent electric dipole moment in an atom and for atomic parity non-conservation.