Doppler-free Selective Reflection spectroscopy of the 6s 2S1/2 7p 2P3/2 transition of Cesium using a nanofabricated vapor cell

Abstract

Selective Reflection (SR) spectroscopy of the 6s 2S1/2 → 7p 2P3/2 electric dipole transition of Cesium (λ~=~456 nm) is performed for the first time using a nanometric-thin cell (L=50 - 1500~nm). We succesfully form narrow resonances corresponding to the Fg = 3,4 → Fe =2,3,4,5 hyperfine transitions. All transitions are well spectrally resolved and the geometry of the cell allows us to obtain a strong 30 times narrowing of the Doppler width with a single beam pass. For lower thicknesses (L < 400~nm), we observe a red shift of the SR lines which we attribute to atom-surface interactions, and provide estimates of the C3 interaction coefficient. The SR signal reaches several percent of the incident radiation up to a saturation intensity of 100 mW/cm2. SR is a convenient tool for laser spectroscopy of the hyperfine structure of atoms as well as for the study of Zeeman transitions in magnetic fields. Experimental measurements are in good agreement with theoretical calculations.