Velocity-selective EIT measurement of potassium Rydberg states

Abstract: We demonstrate a velocity selection scheme that mitigates suppression of electromagnetically induced transparency (EIT) by Doppler shifts for low--high EIT probe--coupling wavelength ordering. An optical pumping beam counter-propagating with the EIT probe beam transfers atoms between hyperfine states in a velocity selective fashion. Measurement of the transmitted probe beam synchronous with chopping of the optical pumping beam enables a Doppler-free EIT signal to be detected. Transition frequencies between 5P${1/2}$ and $n$S${1/2}$ states for $n=$26, 27, and 28 in $^{39}$K are obtained via EIT spectroscopy in a heated vapor cell with a probe beam stabilized to the 4S${1/2}\rightarrow$5P${1/2}$ transition. Using previous high-resolution measurements of the 4S${1/2}\rightarrow$nS${1/2}$ transitions, we make a determination of the absolute frequency of the 4S${1/2}\rightarrow$5P${1/2}$ transition. Our measurement is shifted by 560 MHz from the currently accepted value with a two-fold improvement in uncertainty. These measurements will enable novel experiments with Rydberg-dressed ultracold Fermi gases composed of $^{40}$K atoms.