Quantum properties of atomic laser in system of binomial states field interacting with Bose-Einstein condensate of two-level atoms

Abstract

Abstract:

The quantum correlation properties and squeezing properties of atomic laser are studied in the system of the binomial states field interacting with Bose-Einstein Condensate of two-level atoms, and the amplitude-squared squeezing effects of atomic laser are also discussed. The influence of field parameter and atom parameter on the depth and duration of squeezing are mainly investigated by solving the Heisenberg equation，based on the entire quantum theory. The results show that the quantum correlation properties of atomic laser keep invariant in the process of interaction between light and atomic BEC. The two quadrature components of atomic laser evolve periodically with time and can be squeezed. The depth of squeezing is determined by the binomial states field. The duration of squeezing depends on the coupling constant between light field and atoms. The relations and differences are briefly discussed between the squeezing effects and amplitude-squared squeezing effects.

Key words: quantum optics, Bose-Einstein condensate, quantum correlation properties, squeezing properties, amplitude-squared squeezing

CLC Number:

O431

WANG Lei, SUN Changyong . Quantum properties of atomic laser in system of binomial states field interacting with Bose-Einstein condensate of two-level atoms[J]. J4, 2011, 28(5): 571-576.

References

[1] Anderson M H, Enscher J R, Methews M R et al. Observation of Bose-Einstein condensation in a dilute atomic vapor [J]. Science, 1995, 269: 198～201
[2] Davis K B, Mewes M O. Anderson M R et al. Bose-Einstein condensation in a gas of sodium atoms [J]. Phys. Rev. Lett. , 1995, 75: 3969～3973
[3] Mewes M O, Andrews M R, Kurn D M et al. Output Coupler for Bose-Einstein Condensed Atoms [J]. Phys. Rev. Lett., 1997, 78(4): 582-585
[4] Bradley C C, Sacket C A, Tollent J J et al. Evidence of Bose-Einstein condensation in an gas with attractive interfactions[J]. Phys. Rev. Lett. , 1995, 75: 1687～1691
[5] You L, Lewenstein M, Cooper J. Quantum field theory of atoms interacting with photons. II. Scattering of short laser pulses from trapped bosonic atoms [J]. Phys.Rev.A, 1995, 51: 4712～4727
[6] Jing H, Chen J L and Ge M L. Quantum-dynamical theory for squeezing the output of a Bose-Einstein condensate [J]. Phys.Rev. A, 2001, 63: 015601
[7] Zhou Ming, Huang Chunjia. Squeezing properties of two-mode squeezed field interacting with Bose-Einstein condensate of V-type three-level atoms [J]. Acta Physical Sinica（物理学报），2002, 51(11): 2514～2516 (in Chinese)
[8] Zhou Yuxin, Xia Qingfeng, Sun Changyong. Influence of the interactiong between atoms on the squeezing properties of V-type three-level atomic lasers [J]. Journal of Atomic and Molecular Physics（原子与分子物理学报）2008, 25(3), 633～637 (in Chinese)
[9] Zhao Jiangang, Sun Changyong, Wen LingHua, Liang Baolong. Influence of the Virtual Photon Field on the Squeezing Properties of Atom Laser [J]. Chinese Physics B, 2009, 18(6): 2294-2299.
[10] Chunjia Huang,Huiyong He,Lijun Tang. Generating ofsqueezed atom laser via stimulated Raman transition [J] .Optics Communications, 2009, 26(282):3177-3180.

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