掺铥全光纤结构2.0μm波段宽带超荧光光源被引量：7

Thulium-Doped All-Fiber Broadband Superfluorescent Source at 2 μm Wavelength

导出

摘要报道了高功率全光纤结构2.0μm波段宽带超荧光光源。超荧光种子源采用双包层掺铥光纤作为增益介质,中心波长为790nm的多模半导体激光器作为抽运源,获得了稳定的中心波长为1952nm的宽带超荧光输出,最大输出功率为220mW,3dB光谱带宽为40nm。超荧光种子源经过一级双包层掺铥光纤放大器后,输出功率达到了2.6W,光纤放大器斜率效率为46%,相应的光谱范围为1900～2100nm,3dB光谱带宽为33nm。 A high power 2.0 μm thulium-doped broadband amplified spontaneous emission （ASE） source is reported by using an all-fiber master oscillator power-amplifer （MOPA） configuration. The ASE seed source produces average output power of about 220 mW by using a segment of thulium-doped double-clad fiber pumped by fiber-pigtailed multimode diodes at 790 nm. The center wavelength and the 3 dB bandwidth are 1952 nm and 40 nm, respectively. A thulium-doped all-fiber amplifier is used to boost average output power to 2.6 W with a slope efficiency of 46 % with respect to the launched pump power. The emission spans the wavelength range from 1900 nm to 2100 nm with a 3 dB bandwidth of 33 nm, and the maximum output power of the ASE fiber amplifier is currently limited by available pump power.

作者刘江王璞

机构地区北京工业大学激光工程研究院国家产学研激光技术中心

出处《中国激光》 EI CAS CSCD 北大核心 2013年第2期57-60,共4页 Chinese Journal of Lasers

基金国家自然科学基金(61235010 61177048) 北京市自然科学基金(KZ2011100050011)资助课题

关键词光纤光学光纤放大器超荧光掺铥光纤 fiber optics fiber amplifier superfluorescence thulium-doped fiber

分类号 TN248 [电子电信—物理电子学]

引文网络
相关文献

参考文献12

1S. P. Chen, Z. J. Liu, Y. G. Li et al.. Resonantly pumped high power flat L-band erbium-doped superfluorescent fiber source[J].Opt. Express, 2008, 16(1): 207-212.
2Q. Xiao, P. Yan, Y. Wang et al.. High-power all-fiber superfluorescent source with fused angle-polished side-pumping configuration[J].Appl. Opt., 2011, 50(8): 1164-1169.
3V. Filippov, Y. Chamorovskii, J. Kerttula et al.. Double clad tapered fiber for high power applications[J].Opt. Express, 2008, 16(3): 1929-1944.
4P. Wang, W. A. Clarkson. High-power, single-mode, linearly polarized, ytterbium-doped fiber superfluorescent source[J].Opt. Lett., 2007, 32(17): 2605-2607.
5W. Chen, D. Shen, T. Zhao et al.. High power Er, Yb-doped superfluorescent fiber source with over 16 W output near 1.55 μm[J].Opt. Express, 2012, 20(13): 14542-14546.
6P. Wang, J. K. Sahu, W. A. Clarkson. High-power broadband ytterbium-doped helical-core fiber superfluorescent source[J].IEEE Photon. Technol. Lett., 2007, 19(5): 300-302.
7P. Wang, J. K. Sahu, W. A. Clarkson. 110 W double-ended ytterbium-doped fiber superfluorescent source with M2=1.6[J].Opt. Lett., 2006, 31(21): 3116-3118.
8刘江,王璞.60W全光纤结构宽带超荧光光源[J].中国激光,2011,38(5):8-8. 被引量：3
9曹镱,刘江,王科,王璞.基于掺镱双包层光纤的百瓦级全光纤结构宽带超荧光光源[J].中国激光,2012,39(8):35-39. 被引量：4
10O. Schmidt, M. Rekas, C. Wirth et al.. High power narrow-band fiber-based ASE source[J].Opt. Express, 2011, 19(5): 4421-4427.

二级参考文献14

1Z. C. Hsu, Z. S. Peng, L. A. Wang et al.. Gamma ray effects on double pass backward superfluorescent fiber sources for gyroscope applications[C]. SPIE, 2008, 7004.. 70044M.
2B. Levit, A. Bekker, V. Smulakovsky et al.. Amplified- spontaneous-emission pumped Raman fiber laser [ C]. CLEO/ QELS, June 2009, Baltimore, MD.
3I. Trifanov, P. Caldas, L. Neagu et al.. 20 mW, 70 nm bandwidth ASE fibre optic source at 1060 nm wavelength region for optical coherence tomography [ C ]. SPIE, 2008, 7580:7580000.
4W. Fan, S. Fu, X. Yang et al.. High power broadband superfluorescent source with a Yb-doped double-cladding fiber [C]. SPIE, 2004, 5280: 225-228.
5P. Wang, J. K. Sahu, W. A. Clarkson. 110 W double-ended ytterbium-doped fiber superfluorescent source with M 2 : 1.6[J]. Opt. Lett. , 2006, 31(21): 3116-3118.
6P. Wang, W. A. Clarkson. High power, single-mode, linearly polarized, ytterbium-doped fiber superfluorescent source [ J ]. Opt. Lett., 2007, 32(17): 2605-2607.
7P. Wang, J. K. Sahu, W. A. Clarkson. Power scaling of ytterbium-doped fiber superfluorescent sources[J]. IEEE J. Sel. Top. Quantum Electron., 2007, 13(3): 580-587.
8O. Schmidt, M. Rekas, C. Wirth et al.. High power narrow- band fiber based ASE source[J]. Opt. Ea'press, 2011, 19 (5) : 4421-4427.
9Qirong Xiao, Ping Yan, Mali Gong et al.. High-power all fiber superfluorescent source with fused angle-polished side pumping configuration[J]. Appl. Opt., 2011, 50(8): 1164-1169.
10S.P. Chen, Y. G. Li, J. P. Zhu et al.. Dualstage superfluorescent fiber source with 1.16 W output power centered at 1561 nmFl7. 09t. Enene. , 2006, 45(5), 055003.

共引文献4

1曹镱,刘江,王科,王璞.基于掺镱双包层光纤的百瓦级全光纤结构宽带超荧光光源[J].中国激光,2012,39(8):35-39. 被引量：4
2曹镱,魏守宇,刘江,王璞.高功率掺镱光纤超荧光源的研究进展[J].北京工业大学学报,2015,41(12):1789-1798. 被引量：1
3魏守宇,金东臣,孙若愚,曹镱,侯玉斌,王静,刘江,王璞.基于高功率窄线宽掺镱全光纤超荧光源的光谱合束[J].中国激光,2016,43(4):28-34.
4娄淑琴,院楚君,王鑫.全光纤同带泵浦宽带掺镱超荧光光纤光源的实验研究[J].红外与激光工程,2016,45(8):1-6. 被引量：4

同被引文献67

1陈晓燕.光纤激光器的发展与应用[J].电子元器件应用,2004,6(11):1-3. 被引量：4
2李成,曹余惠,刘福云,黄明芳,许保健,邬承就.Tm∶YAG晶体的光谱及激光特性研究[J].光学学报,1996,16(8):1087-1091. 被引量：9
3张新陆,崔金辉.激光二极管端面抽运2μm Tm,Ho:YLF连续激光器的激光特性[J].哈尔滨工程大学学报,2006,27(2):301-304. 被引量：3
4陆燕玲,王俊,杨扬,李胜华,孙宝德,袁清习.Tm:YAP晶体生长及光谱特性研究[J].无机材料学报,2006,21(4):838-842. 被引量：5
5杨扬,陆燕玲,王俊,李胜华,孙宝德.2μm波段激光晶体Tm:YAP的生长缺陷[J].人工晶体学报,2007,36(1):114-118. 被引量：3
6X M Duan, B Q Yao, Y J Zhang, et al.. Diode-pumped high efficient Tm:YLF laser output at 1908 nm with near- diffraction limited beam quality [J]. Laser Phys Lett, 2008, 5(5): 347-349.
7M Schellhorn. Performance of a Ho:YAG thin-disc laser pumped by a diode-pumped 1.9 μm thulium laser [J]. Appl Phys B, 2006, 4(85): 549-552.
8Y F Li, Y Z Wang, B Q Yao. Comparative optical study of thulium- doped YA1O3 and GdVO4 single crystals [J]. Laser Phys Lett, 2008, 5(1): 37-40.
9X M Duan, B Q Yao, C W Song, et al.. Room temperature efficient continuous wave and Q-switched Ho:YAG laser double-pass pumped by a diode-pumped Tm:YLF laser [J]. Laser Phys Lett, 2008, 5(11): 800-803.
10Y F Li, Y Z Wang, B Q Yao, et al.. Upconversion spectrum of Tm,Ho:GdVO4 pumped by pulse and CW laser at 800 nm [J]. Laser Phys Lett, 2008, 5(8): 597-599.

引证文献7

1刘江,刘昆,谭方舟,王璞(指导).百瓦级全光纤掺铥光纤激光器及超荧光光源[J].中国激光,2014,41(4):22-26. 被引量：4
2李林军,杨曦凝,白云峰,张治国.激光二极管抽运10.5Wc轴切割Tm,Ho:YAP连续激光器的研究[J].激光与光电子学进展,2014,51(5):128-132. 被引量：1
3李林军,张治国,白云峰,杨曦凝.2μm波段Tm,Ho:YAlO_3激光器研究进展及展望[J].激光与光电子学进展,2014,51(7):15-22. 被引量：4
4刘广柏,杨依枫,雷敏,胡曼,郑也,刘驰,漆云凤,何兵,周军,魏运荣,楼祺洪.1.5kW近衍射极限全光纤窄带超荧光光源[J].中国激光,2015,42(12):59-63. 被引量：8
5魏守宇,金东臣,孙若愚,曹镱,侯玉斌,王静,刘江,王璞.基于高功率窄线宽掺镱全光纤超荧光源的光谱合束[J].中国激光,2016,43(4):28-34.
6何巍,王大博,董明利,祝连庆.基于Sagnac环形滤波器的多波长掺铥光纤激光器[J].纳米技术与精密工程,2016,14(3):206-210. 被引量：2
7曾江辉,张培晴,张倩,李杏,许银生,王训四,戴世勋.啁啾光纤光栅在硫系光纤激光器中的色散补偿[J].红外与激光工程,2017,46(10):79-85. 被引量：4

二级引证文献23

1张美,延凤平,刘硕,尹智.高功率掺铥光纤放大器中受激布里渊散射效应研究[J].中国激光,2015,42(4):151-158. 被引量：5
2李路,郭磐,张寅超,陈思颖,陈和.先验平滑方法在相干测风激光雷达中的应用[J].光学学报,2015,35(7):345-353. 被引量：6
3师红星,刘江,刘昆,谭方舟,王璞.基于半导体激光器调制技术的百瓦级线偏振纳秒掺铥光纤激光器[J].中国激光,2015,42(8):23-27. 被引量：1
4朱国利.高重频Ho∶YAG激光器转换效率理论分析与计算[J].中国激光,2015,42(8):84-91. 被引量：2
5田亮,李林军,于晓洋,王微,楚琳琳,吴海滨.高光束质量连续波Tm,Ho:YAP激光器的研究[J].黑龙江大学自然科学学报,2016,33(1):124-128.
6魏守宇,金东臣,孙若愚,曹镱,侯玉斌,王静,刘江,王璞.基于高功率窄线宽掺镱全光纤超荧光源的光谱合束[J].中国激光,2016,43(4):28-34.
7李腾龙,李阳,彭万敬,王小军,马毅,张凯.1.1kW窄光谱随机光纤激光放大[J].中国激光,2017,44(2):169-174. 被引量：3
8陈晓龙,郑也,李璇,皮浩洋,赵纯,刘恺,全昭,沈辉,杨依枫,何兵,周军.10．6GHz线宽保持随机光纤激光种子源[J].中国激光,2017,44(7):263-268. 被引量：3
9刘茵紫,邢颍滨,徐中巍,李进延.高功率掺铥石英光纤激光器研究进展[J].激光与光电子学进展,2018,55(5):21-35. 被引量：9
10郑也,李磐,朱占达,刘小溪,王军龙,王学锋.高功率窄线宽光纤激光器研究进展[J].激光与光电子学进展,2018,55(8):80-98. 被引量：8

1冯高锋,杨军勇,马静,葛锡良.双包层掺铥光纤的研制[J].现代传输,2013(4):59-61. 被引量：2
2冯高锋,章海峰,葛锡良.高效率双包层掺铥光纤的研制[J].现代传输,2015(6):72-74.
3王巍,张云军,李东明,王月珠,葛辉良.运用泵浦耦合器和飞秒刻蚀光栅制作的全光纤化掺铥光纤激光器(英文)[J].光子学报,2010,39(S1):80-82.
4刘江,王璞.瓦级输出全光纤结构2.0μm掺铥皮秒脉冲光纤激光器[J].中国激光,2012,39(8):17-20. 被引量：5
5刘江,刘晨,师红星,王璞.203W全光纤全保偏结构皮秒掺铥光纤激光器[J].物理学报,2016,65(19):122-127. 被引量：4

中国激光

2013年第2期

浏览历史

内容加载中请稍等...

掺铥全光纤结构2.0μm波段宽带超荧光光源被引量：7

参考文献12

二级参考文献14

共引文献4

同被引文献67

引证文献7

二级引证文献23

相关作者

相关机构

相关主题

浏览历史

掺铥全光纤结构2.0μm波段宽带超荧光光源 被引量：7

参考文献12

二级参考文献14

共引文献4

同被引文献67

引证文献7

二级引证文献23

相关作者

相关机构

相关主题

浏览历史

掺铥全光纤结构2.0μm波段宽带超荧光光源被引量：7