Ground effects on magnetooptic Bragg cells

Ground effects on magnetooptic Bragg cells

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摘要 Propagation equation of magnetostatic waves in an arbitrarily magnetized yttrium-iron-garnet/gadolinium- gallium-garnet waveguide coated with perfect metal planes is obtained using the method of the surface magnetic permeability. And ground effects on magnetooptic Bragg cells are investigated with the magnetooptic coupled-mode theory. Theoretical analysis indicates that, diffraction efficiency of guided optical waves can be improved by adjusting the spacing of the metal plane from the ferrite film, and ground effects on the diffraction efficiency will be enhanced using an appropriately tilted bias magnetic field. In the metal clad waveguide system, the magnetostatic wave frequency at which the diffraction efficiency peak is obtained corresponds to the "zero-dispersion" point. Performance of RF spectrum analyzers in this system can also be improved by comparing with the case of the sandwich waveguide. Therefore, magnetooptic Bragg cells with the metal clad waveguide are potential applications to the microwave communication and optical signal processing. Propagation equation of magnetostatic waves in an arbitrarily magnetized yttrium-iron-garnet/gadolinium-gallium-garnet waveguide coated with perfect metal planes is obtained using the method of the surface magnetic permeability. And ground effects on magnetooptic Bragg cells are investigated with the magnetooptic coupled-mode theory. Theoretical analysis indicates that, diffraction efficiency of guided optical waves can be improved by adjusting the spacing of the metal plane from the ferrite film, and ground effects on the diffraction efficiency will be enhanced using an appropriately tilted bias magnetic field. In the metal clad waveguide system, the magnetostatic wave frequency at which the diffraction efficiency peak is obtained corresponds to the “zero-dispersion” point, Performance of RF spectrum analyzers in this system can also be improved by comparing with the case of the sandwich waveguide. Therefore, magnetooptic Bragg cells with the metal clad waveguide are potential applications to the microwave communication and optical signal processing.

作者 WEN Feng WU BaoJian QIU Kun

机构地区 Key Laboratory of Broadband Optical Fiber Transmission and Communication Networks of the Ministry of Education of China

出处《Chinese Science Bulletin》 SCIE EI CAS 2008年第18期2753-2757,共5页

基金 the National Natural Science Foundation of China (Grant No. 60671027)

关键词地面效应静磁波磁光衍射 ground effects, magnetooptic Bragg diffraction, magnetostatic wave

分类号 O44 [理学—电磁学]

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1刘公强,ChenS.Tsai.斜向静磁场中的薄膜磁光效应和静磁波传播特性[J].物理学报,1998,47(6):997-1005. 被引量：7
2Kolokoltsev O V,,Vountesmeri V.Optimization of MO Bragg diffrac- tion of guided optical waves by MSW in YIG films by using inclined magnetic bias field[].Journal of Magnetism and Magnetic Materials.2001
3Matyushev V V,Stashkevich A A,Desvignes J M.Collinear interaction of the optical waveguide modes and surface magnetostatic waves in a Lu2.14Bi0.86 Fe4.94Mg0.06O12 film[].Journal of Applied Physics.1991
4Tuff C S.Integrated acoustooptic and magnetooptic devices for optical information processing[].Proceeding of the IEEE.1996
5Su J,Tuff C S.Nonlinear characteristics of magnetooptic Bragg diffraction in bismuth substituted yttrium iron garnet films[].Journal of Applied Physiology.2000
6Wu B J,Wen F,Qiu K.Mode-conversion enhancement of guided optical waves by magnetostatic surface waves propagating col-linearly in obliquely magnetized bismuth-doped yttrium-iron-garnet film waveguide[].Journal of Applied Physics.2006
7Zhang W K,Liu G Q.Bragg diffraction of guided optical waves by magnetostatic backward volume waves in a double-layered mag-netic film structure[].Journal of Applied Physics.2004
8Fetisov Y F,Klimov A A.Waveguide-light-spin-wave interaction in nonuniformly magnetized yttrium iron garnet films[].Journal of the Optical Society of America B Optical Physics.2005
9C. L. Wang,C. S. Tsai.Integrated magnetooptic Bragg cell modulator in yttrium iron garnet-gadolinium gallium garnet taper waveguide and applications[].Journal of Lightwave Technology.1997
10Noguchi A,Goto N,Miyazaki Y.FDTD analysis of switching characteristics in magnetooptic functional devices using magnetostatic surface waves[].Electr Eng Jpn.2008

二级参考文献3

1刘公强，物理学报，1998年，47卷
2Pu Y，Int J High-Speed Electronics，1991年，2卷，185页
3Tsai C S，IEEE Trans Microwave Theor Technol，1990年，38卷，560页

共引文献6

1夏天,张国营,张学龙,薛刘萍.晶场二级效应与交换作用对PrF_3晶体磁性及磁光性质的影响[J].物理学报,2007,56(3):1741-1745. 被引量：1
2文峰,武保剑,邱昆.磁光Bragg衍射中的接地效应[J].科学通报,2008,53(8):877-881.
3ChenS.Tsai,刘公强.不均匀磁场中的静磁波传播和导波光衍射理论[J].光学学报,1999,19(1):63-71. 被引量：2
4武保剑,刘公强.斜向磁化的YIG波导中静磁波传播特性[J].物理学报,1999,48(S1):286-290. 被引量：2
5司新文,刘公强,孟凡英.双层YIG波导中静磁体波的传播特性[J].电子学报,2001,29(3):417-419.
6史庆藩,闫学群.非线性激发的磁激子对的振荡特性[J].物理学报,2003,52(1):225-228. 被引量：1

1江叔通,徐义华,史卫成.具有地面效应理想车体三维绕流的研究[J].南昌航空工业学院学报,2005,19(2):20-22.
2辜小安.国外关于地面声吸收的理论研究与实践[J].环境工程,1994,12(1):29-33. 被引量：3
3Jie Wu,Chang Shu,Ning Zhao,Weiwei Yan.Fluid Dynamics of Flapping Insect Wing in Ground Effect[J].Journal of Bionic Engineering,2014,11(1):52-60. 被引量：5
4何琨,陈坚强,毛枚良.Level Set方法在地面效应数值模拟中的应用[J].应用力学学报,2013,30(3):328-333. 被引量：1
5杨忠志,牛淑云.一种描绘原子大小尺寸的半径[J].科学通报,1991,36(2):159-159. 被引量：2
6Jorge M.M. Barata,Pedro J.C.T. Santos,André R.R. Silva,Diamantino F.G. Durāo.Turbulent Energy Budgets of a Ground Vortex Flow[J].Journal of Mechanics Engineering and Automation,2013,3(5):311-324.
7王继成,王月媛,王跃科,方光宇,刘树田.Measurements of total absolute collision cross section of ultracold Rb atom using magneto-optic and pure magnetic traps[J].Chinese Optics Letters,2011,9(6):9-12.
8卡尔帕娜·乔拉[J].载人航天信息,2009(3):125-128.
9孙茂.昆虫飞行的空气动力学[J].力学学报,2015,47(2):384-384. 被引量：5
10杨勇,尹欢,彭婧.FSAE赛车底盘尾流扩散器仿真分析与设计[J].机械科学与技术,2017,36(4):632-636. 被引量：3

Chinese Science Bulletin

2008年第18期

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Ground effects on magnetooptic Bragg cells

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