Laser cooling and trapping of potassium at magic wavelengths

TL;DR

This paper presents high-precision calculations of potassium atom polarizabilities and identifies magic wavelengths for optical cooling and trapping, aiding quantum gas experiments.

Contribution

It provides the first-principles calculated polarizabilities and identifies 20 magic wavelengths for potassium in the 1050-1130 nm range.

Findings

20 magic wavelengths identified for 4s-5p transitions

Recommended electric-dipole matrix elements provided

Uncertainties of all values estimated

Abstract

We carry out a systematic study of the static and dynamic polarizabilities of the potassium atom using a first-principles high-precision relativistic all-order method in which all single, double, and partial triple excitations of the Dirac-Fock wave functions are included to all orders of perturbation theory. Recommended values are provided for a large number of electric-dipole matrix elements. Static polarizabilities of the 4s, 4p_j, 5s, 5p_j, and 3d_j states are compared with other theory and experiment where available. We use the results of the polarizability calculations to identify magic wavelengths for the 4s-np transitions for $n = 4, 5$, i.e. those wavelengths for which the two levels have the same ac Stark shifts. These facilitate state-insensitive optical cooling and trapping. The magic wavelengths for the $4s-5p$ transitions are of particular interest for attaining a quantum gas of potassium at high phase-space density. We find 20 such wavelengths in the technically interest region of 1050-1130 nm. Uncertainties of all recommended values are estimated.