Fluorescence by a polar quantum system in a polychromatic field

• URL: http://arxiv.org/abs/2412.11243v1
• Date: Sun, 15 Dec 2024 16:48:21 GMT
• Title: Fluorescence by a polar quantum system in a polychromatic field
• Authors: Nikolai N. Bogolyubov, Jr., Andrey V. Soldatov,
• Abstract summary: Spectral properties of fluorescent radiation from a two-level quantum system with broken inversion spatial symmetry were studied. The fluorescent behavior of the system in question reveals a kind of an optoelectronic transistor effect.
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• Abstract: Spectral properties of fluorescent radiation from a two-level quantum system with broken inversion spatial symmetry, which can be described by a model of an one-electron two-level atom whose electric dipole moment operator has permanent unequal diagonal matrix elements, were studied. The case of the excitation of this system by a polychromatic laser field, comprised of $N-1$ high-frequency components with the frequencies close to or being in resonance with the atomic transition frequency, and a low-frequency component whose frequency coincides with the Rabi frequency of the high-frequency components, was considered. Special attention was given to the resonant bichromatic and nearly resonant trichromatic excitation. In the former case it was shown that by changing the intensity of the low-frequency component, one can efficiently alter spectral properties of the fluorescent radiation of the system in the high-frequency range, while in the latter case it was found that the fluorescent behavior of the system in question reveals a kind of an optoelectronic transistor effect. Options for the experimental detection and practical usage of the effects under study were discussed.

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