Nonreciprocal conventional photon blockade in driven dissipative atom-cavity

In this Letter, we propose a scheme to achieve a nonreciprocal conventional photon blockade in a nonlinear device consisting of an atom and spinning cavity by manipulating the detuning between the atom and the cavity. We show that the single-photon blockade can be generated by driving the spinning r...

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Veröffentlicht in:	Optics letters 2020-08, Vol.45 (16), p.4424-4427
Hauptverfasser:	Xue, W. S., Shen, H. Z., Yi, X. X.
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Sprache:	eng
Schlagworte:	Photons
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description	In this Letter, we propose a scheme to achieve a nonreciprocal conventional photon blockade in a nonlinear device consisting of an atom and spinning cavity by manipulating the detuning between the atom and the cavity. We show that the single-photon blockade can be generated by driving the spinning resonator from one side, while photon-induced tunneling is driven by the other side with the same driving strength. This nonreciprocal conventional photon blockade effect originates from the Fizeau–Sagnac drag, which leads to different splitting of the resonance frequencies for the counter-circulating modes. We give four optimal solutions for Fizeau–Sagnac shifts to generate a nonreciprocal conventional photon blockade with the arbitrary detunings between atom and cavity.
doi_str_mv	10.1364/OL.398247
format	Article
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title	Nonreciprocal conventional photon blockade in driven dissipative atom-cavity
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