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全光纤结构掺镱超荧光光纤光源实验研究

Experimental Research on All-fiber Ytterbium-doped Superfluorescent Fiber Source
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摘要 利用掺镱双包层光纤,建立了一套全光纤结构超荧光光纤光源的实验系统。研究了在正向泵浦情况下,单程双向输出超荧光光源的特性,并讨论了不同长度掺镱光纤对超荧光光源性能的影响。实验结果表明,反向输出超荧光光源具有更高的效率和更宽的带宽。当增益光纤长度较短时,其激光振荡阈值更高,可产生更高的输出功率;而当增益光纤长度增加后,虽然最大输出功率下降,但其能产生更宽的输出光谱。 Based on a segment of Ytterbium-doped dual-cladding fiber(YDF), an all-fiber superfluorescent fi-ber source(SFS) experimental system is demonstrated. The characteristics of double- ended output SFS is re-searched under forward pump condition. And the effects of YDF with different length on the performances of SFSare discussed. Experimental result shows that backward output SFS has higher conversion efficiency and broaderbandwidth. When the length of gain fiber becomes shorter, the laser oscillation threshold is higher and thus higheroutput power can be obtained. With the increasing of gain fiber length, the maximum output power decreases, butthe bandwidth of the output spectrum increases at the same time.
作者 院楚君 娄淑琴
机构地区 北京交通大学电子信息工程学院
出处 《光电技术应用》 2015年第6期31-36,共6页 Electro-Optic Technology Application
基金 国家自然科学基金项目资助(61475016)
关键词 超荧光光纤光源 掺镱光纤 转换效率 带宽 superfluorescent fiber source(SFS) Ytterbium-doped fiber conversion efficiency bandwidth
分类号 O433 [机械工程—光学工程]
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参考文献11

  • 1韩旭,冯国英,韩敬华,武传龙,周寿桓.3dB带宽达80nm的双包层掺镱超荧光光纤光源[J].光谱学与光谱分析,2012,32(11):3040-3043. 被引量:1
  • 2Hsu Z C,Peng Z S.Gamma ray effects on double pass backward superfluorescent fiber sources for gyroscope applications[J].Proc.SPIE 7004,2008,70044M.
  • 3Park H G,Digonnet M.Er-doped superfluorescent fiber source with a [±]0.5-ppm long-term mean-wavelength stability[J].Journal of Lightwave Technology,2003,21(12):3427-3433.
  • 4Bashkansky M,Duncan M D.Characteristics of a Yb-doped superfluorescent fiber source for use in optical coherence tomography[J].Optics Letters,1998,3:305-310.
  • 5Trifanov I,Caldas P.Combined Neodymium Ytterbium-doped ASE fiber-optic source for optical coherence tomography applications[J].IEEE Photonics Technology Letters,2011,23(1):21-23.
  • 6Levit B,Bekker A.Amplified-spontaneous-emission pumped raman fiber laser[J].Conference on Lasers and Electro-Optics/International Quantum Electronics Conference,OSA Technical Digest Series,2009,JThE73.
  • 7Wysocki P F,Digonnet M J F.Characteristics of Erbium-doped superfluorescent fiber fources for interferometric sensor applications[J].Journal of Lightwave Technology,1994,12(3):550-567.
  • 8Wang P,Sahu J K.Power scaling of Ytterbium-doped fiber superfluorescent sources[J].IEEE Journal of Selected Topics in Quantum Electronics,2007,13(3):580-587.
  • 9Liu J,Liu K.High-power Thulium-doped all-fiber superfluorescent sources[J].IEEE Journal of Selected Topics in Quantum Electronics,2014,20(5):3100306.
  • 10Duling I N,Burns W K.High-power superfluorescent fiber source[J].Optics Express,1990,15(1):33-35.

二级参考文献19

  • 1Morkel P, Laming R, Payne D. Electronics Letters, 1990, 26(2): 96.
  • 2Digonnet M. Lightwave Technology, 1986, 4(11): 1631.
  • 3Bashkansky M, Duncan M, Goldberg L, et al. Optics Express, 1998, 3(8): 305.
  • 4Digonnet M J F, Liu K. Lightwave Technology, 1989, 7(7): 1009.
  • 5Hall D C, Burns W K, Moeller R P. Lightwave Technology, 1995, 13(7) : 1452.
  • 6Goldberg L, Koplow J P, Moeller R P, et al. Optics Letters, 1998, 23(13) : 1037.
  • 7Su C, Wang L, Lightwave Technology, 1999, 17(10): 1896.
  • 8Nandi P, Jose G. Optical Fiber Technology, 2008, 14(4) : 275.
  • 9Shen D, Pearson L, Wang P, et al. Optics Express, 2008, 16(15) : 11021.
  • 10Chen S P, Li Y G, Zhu J P, et al. Optics Express, 2005, 13(5) : 1531.
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2015年 第6期

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