Selective reflection from a Potassium atomic layer with a thickness as small as λ /13

Abstract

We demonstrate that a method using the derivative of the selective reflection signal from a nanocell is a convenient and robust tool for atomic laser spectroscopy, achieving a nearly Doppler-free spectral resolution. The recorded linewidth of the signal from a potassium-filled cell, whose thickness lies in the range 350-500 nm, is 18 times smaller than the Doppler linewidth ( 900 MHz full width at half maximum) of potassium atoms. We also show experimentally a sign oscillation of the reflected signal's derivative with a periodicity of λ/2 when varies from 190 to 1200~nm confirming the theoretical prediction. We report the first measurement of the van der Waals atom-surface interaction coefficient C3 = 1.9 0.3 kHz·μm3 of potassium 4S1/2 → 4P3/2 transitions with the nanocell's sapphire windows, demonstrating the usefulness and convenience of the derivative of selective reflection technique for cell thicknesses in the range 60 -120~nm.