Quantum defects of $n$F$_J$ levels of Cs Rydberg atoms

Abstract: We present precise measurements of the quantum defects of cesium $n$F$J$ Rydberg levels. We employ high-precision microwave spectroscopy of $(n+2)\mathrm{D}{5/2}\rightarrow n\mathrm{F}{5/2,7/2}$ transitions for $n=45$ to 50 in a cold-atom setup. Cold cesium $(n+2)$D${5/2}$ atoms, prepared via two-photon laser excitation, are probed by scanning weak microwave fields interacting with the atoms across the $n\mathrm{F}{5/2,7/2}$ resonances. Transition spectra are acquired using state-selective electric-field ionization and time-gated ion detection. Transition-frequency intervals are obtained by Lorentzian fits to the measured spectral lines, which have linewidths ranging between 70~kHz and 190~kHz, corresponding to about one to three times the Fourier limit. A comprehensive analysis of relevant line-shift uncertainties and line-broadening effects is conducted. We find quantum defect parameters $\delta{0}(\mathrm{F}{5/2})=0.03341537(70)$ and $\delta{2}(\mathrm{F}{5/2})=-0.2014(16)$, as well as $\delta{0}(\mathrm{F}{7/2})=0.0335646(13)$ and $\delta{2}(\mathrm{F}{7/2})=-0.2052(29)$, for $J=5/2$ and $J=7/2$, respectively. Fine structure parameters $A{FS}$ and $B_{FS}$ for Cs $n{\rm{F}}_J$ are also obtained. Results are discussed in context with previous works, and the significance of the results is discussed.