光腔中原子的定位

J4 ›› 2010, Vol. 27 ›› Issue (5): 542-546.

光腔中原子的定位

程桂平, 方立铭, 刘冬梅

皖南医学院医用物理教研室，安徽芜湖 241002

收稿日期:2009-11-23 修回日期:2010-03-26 出版日期:2010-09-28 发布日期:2010-08-31
通讯作者: 程桂平（1982- ）安徽芜湖人，毕业于华中师范大学物理科学与技术学院，现任教于皖南医学院物理教研室，主要研究领域为量子光学。 E-mail:cgp1982@yahoo.cn
基金资助:
2010年高校省级自然科学研究一般项目（KJ2010B251）

The atomic-position localization in the optical cavity

CHENG Guiping, FANG Liming, LIU Dongmei

Department of Medical Physics, Wannan Medical College, Wuhu 241002，China

Received:2009-11-23 Revised:2010-03-26 Published:2010-09-28 Online:2010-08-31

摘要/Abstract

摘要：

研究了置于一个驻波光腔中的二能级原子的定位情况，发现通过利用测量场的正交分量的方法可以很好地定位单个原子的位置。而当在腔中放入两个二能级原子，根据瑞利极限条件可知若置于腔中的两个原子距离太近，我们是很难区分出这两个原子。但同样地利用测量场的正交分量方法后仍然可以很好地分辨出这两个距离很近的原子。然而若考虑腔场的损耗时，腔损耗将会损害两原子之间的相对定位。并且随着腔的衰减系数增大，两原子之间相对定位情况也越差。

关键词: 量子光学, 原子定位, 场的正交分量, 驻波光腔, 二能级原子

Abstract:

The localization of a two-level atom placed in an optical cavity containing a standing wave is investigated, and the single atomic-position can be well-localized throngh the way of quadrature-field measurement. According to the Rayleigh Limit when two two-level atoms are put in the cavity, it is difficult to distinguish between the two atoms if they are very close to each other. Also, the two atoms can be still well-distinguished by quadrature-field measurement. However, if the cavity damping is taken into account, the two-atom relative position localization will be damaged. The larger damping rate of the cavity become, the worse the two-atom relative position localization will be.

Key words: quantum optics, atomic-localization, the field quadrature, standind wave optical cavity, two-level atom

程桂平方立铭刘冬梅. 光腔中原子的定位[J]. J4, 2010, 27(5): 542-546.

CHENG Guiping FANG Liming LIU Dongmei. The atomic-position localization in the optical cavity[J]. J4, 2010, 27(5): 542-546.

参考文献

[1] Kien F L, Rempe G, Schleich W P, and Zubairy M S . Atom localization via Ramsey interferometry[J]. Phys.Rev.A, 1997, 56: 2972
[2] Fang M F and Liu X . The entanglement character of two entangled atoms in Tavis-Cummings model[J]. Acta Phys.Sin（物理学报）2000, 49: 0435 (in Chinese)
[3] Shan C J and Xia Y J. Periodic entanglement between the internal and exteral Degree of freedom of a trapped ion in a standing wave laser [J] Acta Phys.Sin(物理学报) 2006, 55:1558 (in Chinese) [4] Yu L Z and Gong R S. Purification for entangled multi-atom states via entanglement swapping[J]. Chinese Journal of Quantum Electronics(量子电子学报), 2008, 25(3): 317～321 (in chinese)
[5] Nha H, Lee J H, Chang J S, and An K W. Atomic-position localization via dual measurement[J] Phys.Rev.A ,2002, 65: 033827
[6] Zhang J X, Zhang T C, Xie C D,and Peng K C.Interferometric detection of optical phase shift using twin beams[J] Chin .Phys., 1999, 08: 0437
[7] Zheng L, Li C, Li Y, and Sun C P. Localization of the relative position of two atoms induced by spontaneous emission[J] Phys.Rev.A, 2005, 71:062101
[8] Ma H, Tan X, Tian S F, Tong D M , and Fan X J. Effect of spontaneously generated coherence on inversionless lasing gain in an atomic system with Doppler broadening[J] Chin .Phys., 2007, 08 060903
[9] Chang J T, Evers J, and Zubaiyr M S . Distilling two-atom distance information from intensity-intensity correlation function[J] Phys. Rev. A, 2006, 74: 043820
[10] Chang J T, Evers J, Scully M O, and Zubaiyr M S. Measurement of the separation between atoms beyond diffraction limit [J] Phys.Rev. A, 2006, 73:031803
[11] Macovei M, Evers J ,and Keitel C H. Localization of atomic ensembles via superfluorescence[J] Phys.Rev.A , 2007, 75:033801
[12] Holland M J, Walls D F, and Zoller P. Quantum nondemolition measurements of photon number by atomic beam deflection[J] Phys. Rev. Lett., 1991, 67 :1716
[13] Storey P, Collet M J, and Walls D F. Measurement-induced diffraction and interference of atoms [J] 1992 Phys.Rev.Lett. 68 472 [14] Cahill K E and Glauber R J. Density operators and quasiprobability distributions[J] Phys. Rev,1969 ,177 :1882

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