Spectral characterization of fiber Bragg grating with etched fiber cladding 被引量：2

Spectral characterization of fiber Bragg grating with etched fiber cladding

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摘要 A new method is presented to tune Bragg wavelength slightly by using hydrofluoric acid to etch fiber cladding.The spectral characteristics before and after etching and the change properties of Bragg wavelength are studied.Cladding modes are reduced during the etching process.High-order cladding modes are converted into radiation modes,and energy of cladding modes is coupled to the outside.As the cladding radius decreases,the Bragg wavelength shifts to longer direction.Experimental results show that this method can tune Bragg wavelength slightly,and the tunable range is 0.002-0.120 nm.

作者周倩宁提纲裴丽李超

机构地区 Key Lab.of All Optical Network and Advanced Telecommunication Network

出处《Optoelectronics Letters》 EI 2012年第5期328-331,共4页 光电子快报（英文版）

基金 supported by the National Natural Science Foundation of China (Nos.60837002 and 61177069) the Ph.D. Programs Foundation of Ministry of Education of China (No.20090009110003) the Fundamental Research Funds for the Central Universities (No.2011YJS219)

关键词 ETCHING Fiber Bragg gratings Hydrofluoric acid Spectrum analyzers WAVELENGTH 光纤布拉格光栅光谱特性包层模蚀刻 Bragg波长辐射模式能量耦合可调范围

分类号 TN253 [电子电信—物理电子学] TN244 [电子电信—物理电子学]

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参考文献19

1A. D. Kersey, M. A. Davis, H. J. Patrick, M. LeBlanc, K. P. Koo, C. G. Askins, M.A. Putnam and E. J. Friebele, J. Lightwave Technol. 15, 1442 (1997).
2B.O. Guan, H.Y. Tam, S.L. Ho, H.C. WengandX. Y. Dong, Electron. Lett. 26, 1018 (2000).
3Q. Y. Chen, S. H. Shi, Z. Y. Zhang, K. Fang and X. J. Zhou, Joumal ofOptoelectronics · Laser 22,677 (2011). (in Chinese).
4K. Zhang and S. Wang, Journal of Optoelectronics· Laser 23, 15 (2012). (in Chinese).
5W. Guo, K. Liu and Y. Q. Huang, Journal of Optoelectronics · Laser 11, 23 (2000). (in Chinese).
6D. Z. Yang, D. J. Feng, J. Wang, M. S. Jiang and Q. M. Sui, Tunable Chirped Fiber Bragg Grating based on Two-fixedend Compressive Bar without Central Wavelength Shift, the Pacific Rim Conference on Lasers and Electro-Optics, 1 (2009).
7P. Lu, L. Q. Men and Q. Y. Chen, Journal of Applied Physics 106, 013111 (2009).
8G. R. Vargas and R. R. Panepucci, Wavelength Monitoring using a Thermally Tuned Micro-ring Resonator, 10th International Conference on Numerical Simulation of Optoelectronic Devices (NUSOD), 83 (2010).
9X. N. Yu, C. C. Sun and Q. Zhang, Journal of Tsinghua Univ-ersity (Science and Technology) 45, 456 (2005). (in Chinese).
10W. G. Zhang, G. Y. Kai, X. Y. Dong, S. Z. Yuan and Q. D. Zhao, Acta Optica Sinica 23, 164 (2003). (in Chinese).

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1王本宇,闫卫平,张玉书,杜国同.结构封装式光纤Bragg光栅温度补偿研究[J].仪器仪表学报,2006,27(z1):4-6. 被引量：1
2王艳,闫卫平,张玉书,王聪.基于负膨胀材料的光纤Bragg光栅温度补偿研究[J].仪器仪表学报,2006,27(z1):10-11. 被引量：5
3童利民,潘欣云.亚波长直径光纤的光学传输特性及其应用[J].物理,2007,36(8):626-630. 被引量：14
4Liang R B,Sun Q Z,Wo J H,et al. Investigation on micro/nanofiber Bragg grating for refractive index sensing[J].Optics Communications,2012,285(6):1128-1133.
5Dwivedi R P,Lee E H. A compact plasmonic tunable filterusing elasto-optic effects [J]. Optics & Laser Technolo-gy,2012,44(7) :2130-2134.
6Zhong C,Shen C Y,Li K,et al. Temperature-insensitivefiber Bragg grating tiny displacement sensor [J]. SensorLetters,2012,10(7) :1470-1473.
7Iwashima T,Inoue A. Temperature compensation tech-nique for fiber Bragg gratings using liquid crystalline poly-mer tubes[J]. Electronics Letters, 1997,33(5) -417-419.
8Richter A,Andritschke T. Passive temperature compensa-tion of piezo-tunable fibre Bragg gratings[J]. ElectronicsLetters,1999,35(15) :1267-1271.
9Ni K,Chi C C,Dong X Y,et al. Temperature-independentaccelerometer using a fiber Bragg grating incorporating abiconical taper [J]. Optical Fiber Technology,2013,19(5)-410-413.
10Wang T,He D W,Wang Z Q,et al. A novel temperatureself-compensation FBG vibration sensor [J]. Journal ofPhysics,2011,276(1):012146.

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2WangRui-Rong WangWei WangChen DongJia-Qin SunJin-Ren WanBing-Gen.Spectral characterization of double—driven x—ray laser plasmas[J].Chinese Physics B,2003,12(5):569-569.
3许彬,郑链,王克勇,宋承天.基于多小波的信号奇异性分析方法[J].系统仿真学报,2006,18(11):3217-3219. 被引量：12
4马波,裘正定.小波变换的分形特性[J].铁道学报,1998,20(6):74-80. 被引量：4
5胡俊江,杨镜新,陈伟,周常河.Experimental investigation of enhancing the subsurface damage threshold of Nd-doped phosphate glass[J].Chinese Optics Letters,2008,6(9):681-684. 被引量：3
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7赵松楠,吕海兵,晏良宏,袁晓东,郑万国.不同化学蚀刻法对石英基片激光损伤阈值的影响[J].材料导报（纳米与新材料专辑）,2009,23(1):262-264.
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9孙雪铮,顾培夫,刘旭.厚度递减的光子晶体多通道群延迟的实现[J].浙江大学学报（工学版）,2007,41(3):533-536.
10韩勋,杜兰,刘宏伟.基于窄带微多普勒调制的锥体目标参数估计[J].电子与信息学报,2015,37(4):961-968. 被引量：19

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2012年第5期

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Spectral characterization of fiber Bragg grating with etched fiber cladding 被引量：2

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