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Second Harmonic Generation from Ultracold Bosons in an Optical Cavity (2401.05929v1)

Published 11 Jan 2024 in cond-mat.quant-gas, cond-mat.mes-hall, physics.optics, and quant-ph

Abstract: Within a cavity quantum electrodynamics description, we characterize the fluorescent spectrum from ultracold bosons atoms, in the second harmonic generation (SHG) and resonant cases. Two situations are considered: i) bosons loaded into an optical lattice and ii) in a trapped two-component dilute Bose-Einstein Condensate (BEC), in the regime where the Bogoliubov approximation is often employed. Atom and photon degrees of freedom are treated on equal footing within an exact time-dependent configuration interaction scheme, and cavity leakage is included by including classical oscillator baths. For optical lattices, we consider few bosons in short chains, described via the Bose-Hubbard model with two levels per site, and we find that the spectral response grows on increasing the number of atoms at weak interactions, but diminishes at high interactions (if the number of chain sites does not exceed the number of atoms), and is shifted to lower frequency. In the BEC regime, the spectra display at noticeable extent a scaling behavior with the number of particles and a suitable rescaling of the BEC-cavity and inter-particle interactions, whilst the SHG spectrum redshifts at large atom-atom correlations. Overall, our results provide some general trends for the fluorescence from ultracold bosons in optical cavities, which can be of reference to experimental studies and further theoretical work.

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