Chip-Based Square Wave Dynamic Micro Atom Trap 被引量：1

Chip-Based Square Wave Dynamic Micro Atom Trap

下载PDF

导出

摘要 We propose a scheme for a chip-based dynamic micro atom trap where the trap potentials are created by square wave radiation and an inhomogeneoas static magnetic field. The parameters of this kind of trap array can be modulated dynamically. Both one-dimensional （I-D） and two-dimensional （2-D） trap array potentials for 6Li atoms are discussed. The 1-D trap is combined by a square wave radiation （6 kHz） and a gradient magnetic field （300G/cm）, the array constant of 1-D trap is 0.85 μm. Since the trap array does not require any laser field, it can be easily integrated on a chip and it is useful in applications of scalable quantum information processing. We propose a scheme for a chip-based dynamic micro atom trap where the trap potentials are created by square wave radiation and an inhomogeneoas static magnetic field. The parameters of this kind of trap array can be modulated dynamically. Both one-dimensional （I-D） and two-dimensional （2-D） trap array potentials for 6Li atoms are discussed. The 1-D trap is combined by a square wave radiation （6 kHz） and a gradient magnetic field （300G/cm）, the array constant of 1-D trap is 0.85 μm. Since the trap array does not require any laser field, it can be easily integrated on a chip and it is useful in applications of scalable quantum information processing.

作者但林颜辉王谨詹明生

机构地区 State Key Laboratory of Magnetic and Atomic and Molecular Physics Center for Cold Atom Physics Laboratory of Quantum Information Technology Graduate School of Chinese Academy of Sciences

出处《Chinese Physics Letters》 SCIE CAS CSCD 2010年第5期80-83,共4页 中国物理快报（英文版）

基金 Supported by the National Basic Research Program of China under Grant Nos 2005CB724505/1 and 2006CB921203, the National Natural Science Foundation of China under Grant No 10774160, and Wuhan National Laboratory for Optoelectronics under Grant No P080001.

分类号 TP303 [自动化与计算机技术—计算机系统结构] O562.1 [理学—原子与分子物理]

引文网络
相关文献

参考文献28

1Fortagh J and Zimmermann C 2007 Rev. Mod. Phys. 79 235.
2Folman R, Kruger P, Schmiedmayer J, Denschlag J and Henkel C 2002 Adv. At. Mol. Opt. Phys. 48 263.
3Schumm T, Hofferberth S, Andersson L M, Wildermuth S, Groth S, Bar-Joseph I, Schmiedmayer J and Kruger P 2005 Nature Phys. 1 57.
4Jo C B, Shin Y, Will S, Pasquini T A, Saba M, Ketterle W, Pritchard D E, Vengalattore M and Prentiss M 2007 Phys. Rev. Left. 98 0300407.
5Hofferberth S, Lesanovsky I, Fischer B, Verdu J and Schmiedmayer J 2006 Nature Phys. 2 710.
6Lesanovsky-I and von Klitzing W 2007 Phys. Rev. Lett. 99 083001.
7Lesanovsky I, Schumm T, Hofferberth S, Andersson L M, Kruger P and Schmiedmayer J 2006 Phys. Rev. A ~3 033619.
8Trebbia J B, Alzar C L G, Cornelussen R, Westbrook C I and Bouchoule I 2007 Phys. Rev. Lett. 98 263201.
9Courteille P W, Deh B, Fortagh J, Gunther A, Kraft S, Marzok C, Slama S and Zimmermann C 2006 J. Phys. B: At. Mol. Opt. Phys. 39 1055.
10Cirone M A, Negretti A, Calarco T, Kruger P and Schmiedmayer J 2005 Eur. Phys. J. D 35 165.

同被引文献28

1Igor Lesanovsky,Wolf von Klitzing.Time-Averaged Adiabatic Potentials: Versatile Matter-Wave Guides and Atom Traps. Physical Review . 2007
2Sherlock, B.E.,Gildemeister, M.,Owen, E.,Nugent, E.,Foot, C.J.Time-averaged adiabatic ring potential for ultracold atoms. Physical Review A - Atomic, Molecular, and Optical Physics . 2011
3Anderson MH,Ensher JR,Matthews MR,Wieman CE,Cornell EA.Observation of Bose-Einstein Condensation in a Dilute Atomic Vapor. Science . 1995
4Davis, K.B.,Mewes, M.-O.,Andrews, M.R.,van Druten, N.J.,Durfee, D.S.,Kurn, D.M.,Ketterle, W.Bose-Einstein condensation in a gas of sodium atoms. Physical Review . 1995
5Lee T,Das T P,Sternheimer R M.Perturbation theory for the Stark effect in the hyperfine structure of alkalimetal atoms. Physical Review . 1975
6Dalibard J,Cohen-Tannoudji C.Dressed-atom approach to atomic motion in laser light:the dipole force revisited. Journal of the Optical Society of America B . 1985
7Cohen-Tannoudji,C,Dupont-Roc,J,Grynberg,G.Photons and atoms:introduction to quantum electrodynamics. . 2001
8Cheng,Nicholas,Lawless,Ashenford,Lunn.Magneto-optical studies of the type-I/type-II crossover and band offset in ZnTe/Zn1-xMnxTe superlattices in magnetic fields up to 45 T. Physical review. B, Condensed matter . 1995
9Courteille, Ph.W.,Deh, B.,Fortágh, J.,Günther, A.,Kraft, S.,Marzok, C.,Slama, S.,Zimmermann, C.Highly versatile atomic micro traps generated by multifrequency magnetic field modulation. Journal of Physics B: Atomic, Molecular and Optical Physics . 2006
10C. Cohen-Tannoudji,J. Dupont-Roc,and G. Grynberg.Atom-Photo Interactious. Basic Processes and Applications . 1992

引证文献1

1Tiffany Harte,Elliot Bentine,Edward Owen,XU Dongyang,Benjamin Yuen,Christopher Foot.An introduction to dressed-atom adiabatic potentials for ultracold atoms[J].Instrumentation,2015,2(4):76-84.

1房卫东,石志东,单联海,李凤荣,熊勇.一种基于多参数模型的无线传感器网络能耗评估方法[J].高技术通讯,2015,25(8):753-759.
2李长红,田慧平,郑翠,纪越峰.非线性一维光子晶体特性的动态调制[J].光子学报,2007,36(12):2239-2242. 被引量：1
3陈勰宇,田震.石墨烯太赫兹波动态调制的研究进展[J].中国光学,2017,10(1):86-97. 被引量：8
4DONG Haijiang,DONG Haijiang,QIU Xuesong,QIU Xuesong,CHENG Lu,CHENG Lu,LI Zhiqing,LI Zhiqing,QIAO Yan,QIAO Yan.Fast Fault Localization for Large-scale IP-based Communication Systems Using Bayesian Networks[J].Chinese Journal of Electronics,2009,18(4):735-740.
5Xi-Zeng Zhao.Validation of a CIP-based tank for numerical simulation of free surface flows[J].Acta Mechanica Sinica,2011,27(6):877-890. 被引量：2
6经农,李晓明,金燕.全台网架构下广电办公网的定位与安全策略[J].广播与电视技术,2014,41(5). 被引量：1
7宏正自动科技推出全新企业级IP-Based Cat 5 KVM多电脑切换器[J].电信技术,2009(3):35-35.
8张永顺,徐长亮,迟明路,白建卫,程存欣.三维梯度旋转磁场内胶囊机器人磁力[J].机械工程学报,2014,50(17):1-7. 被引量：2
9符立亚,郭鸿钧.静态磁场的Einstein－Maxwell方程严格解及其引力效应[J].长沙铁道学院学报,1996,14(3):96-100.
10李芳昱,唐孟希,李一川.在一静态磁场中强电磁波束对引力波的谐振响应[J].中国科学（A辑）,2000,30(9):847-855.

Chinese Physics Letters

2010年第5期

浏览历史

内容加载中请稍等...

Chip-Based Square Wave Dynamic Micro Atom Trap 被引量：1

参考文献28

同被引文献28

引证文献1

相关作者

相关机构

相关主题

浏览历史