Collapse and revival of a Dicke-type coherent narrowing in potassium vapor confined in a nanometric-thin cell

Abstract

A nanometer-thin-cell (in the direction of laser beam propagation) has been elaborated with the thickness of the atomic vapor column varying smoothly in the range of L = [50-1500]nm. The cell allows one to study the behavior of the resonance absorption over the D1 line of potassium atoms by varying the laser intensity and the cell thickness from L = λ / 2 to L = 2 λ with the step λ/2 (λ =[770]nm is the resonant wavelength of the laser). It is shown that despite the huge Doppler broadening (>[0.9]GHz at the cell temperature [170]C), at low laser intensities a narrowing of the resonance absorption spectrum is observed for L = λ/2 ( [120] MHz at FWHM) and L = 3/2 λ, whereas for L = λ and L =2λ the spectrum broadens. At moderate laser intensities narrowband velocity selective optical pumping (VSOP) resonances appear at L = λ and L=2λ with the linewidth close to the natural one. A comparison with saturated absorption spectra obtained in a 1-cm-sized K cell is presented. The developed theoretical model well describes the experiment.