We theoretically study the frequency shift caused by the line-shape asymmetry of coherent population trapping (CPT) resonance in a bichromatic laser field. The shift depends on the intensity of the resonant fields and leads to a degradation in long-term stability. We propose a frequency stabilization method based on the harmonic modulation of two-photon detuning to significantly suppress this shift.
We theoretically study the frequency shift in atomic clocks caused by the line-shape asymmetry of coherent population trapping (CPT) resonance in a bichromatic laser field. This asymmetry arises due to the inequality of the resonant spectral components and nonzero one-photon detuning. The line-shape-asymmetry-induced shift depends on the intensity of the resonant fields, which leads to a degradation in long-term stability due to fluctuations of the laser field parameters. A frequency stabilization based on the harmonic modulation of two-photon detuning is considered. It is shown that the use of a high-frequency modulation (compared to the CPT resonance width, i.e., the Pound-Drever-Hall regime) makes it possible to significantly suppress this shift (by one to two orders of magnitude).
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