光谱学与光谱分析 |
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Spectral Repeatability of Regenerated Fiber Gratings Prepared by High Temperature Annealing |
WANG Tao, HE Da-wei*, WANG Yong-sheng, QUAN Yu, WANG Peng-fei, YIN Ze-lin |
Key Laboratory of Luminescence and Optical Information, Ministry of Education, Institute of Optoelectronic Technology, Beijing Jiaotong University, Beijing 100044, China |
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Abstract Two groups of fiber Bragg gratings were fabricated by using UV laser, and group one was annealed at 850 ℃ in the high temperature furnace. Grating regeneration occurred after the initial grating vanished. For the regenerated gratings from group one, the variation in Bragg wavelength is 0.22 nm and the average transmissions strength is 2.57 dB, while the variation of transmission among ten gratings is 0.52 dB. Group two underwent post-annealing at 1 100 ℃ after the process of grating regeneration at 850 ℃. For the regenerated gratings from group two, the variation in Bragg wavelength is 0.41 nm and the average transmissions strength is 0.69 dB, while the variation of transmission among ten gratings is 0.16 dB. The variation in Bragg wavelength of grating with post-annealing is notably larger than that of the regenerated gratings in group one, which is caused by the small difference in fixed tension among the ten gratings. The process of grating regeneration has good reproducibility. The mass production of the regenerated gratings by high temperature annealing is feasible.
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Received: 2013-01-28
Accepted: 2013-03-18
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Corresponding Authors:
HE Da-wei
E-mail: dwhe@bjtu.edu.cn
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[1] JIANG De-sheng, HE Wei(姜德生,何 伟). Journal of Optoelectronics·Laser(光电子·激光), 2002,3(4): 420. [2] ZHOU Zhi, OU Jin-ping(周 智,欧进萍). Journal of Transducer Technology(传感器技术), 2001,20(11): 1. [3] Othonos A. Review of Scientific Instruments, 1997, 68: 4309. [4] Hjelme D R, Bjerkan L, Neegard S, et al. Applied Optics, 1997, 36: 328. [5] Inaudi D, Glisic B. Optical Fiber Sensors, OSA, 2006, paper FB3. [6] Mihailov S J. Sensors, 2012, 12(2): 1898. [7] Baker S R, Rourke H N, Baker V, et al. Journal of Lightwave Technology, 1997, 15: 1470. [8] Kannan S, Guo J Z Y, Lemaire P J. Journal of Lightwave Technology, 1997, 15: 1478. [9] Dong L, Cruz J L, Tucknott J A, et al. Optics Letters, 1995, 20: 1982. [10] Nguyen L V, Hwang D, Moon S, et al. Optics. Express, 2008, 16(15): 11369. [11] Shen Y, Xia J, Sun T, et al. Optics Letters, 2004,29:554. [12] Shen Y, Xia J, Sun T, et al. IEEE Photonic Technology Letters, 2004, 16:1319. [13] Trpkovski S, Kitcher D J, Baxter G W, et al. Optics Letters, 2005,30(6): 607. [14] Bandyopadhyay S, Canning J, Stevenson M, et al. Optics Letters, 2008, 33 (16): 1917. [15] Bandyopadhyay S, Canning J, Biswas P, et al. Optics. Express, 2011, 19: 1198. [16] Canning J, Stevenson M, Bandyopadhyay S, et al. Sensors, 2008, 8: 1. [17] Wang T, Shao L, Canning J, et al. Optics Letters, 2013, 38: 247. |
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