参考文献/References:
[1] Wysocki P F,Digonnet M J F,Kim B Y,等.干涉式光纤传感应用的掺铒超荧光光纤光源特性研究[J].光波技术杂志,1994,12(3):550-567.(英文版)
[2] Hall D C,Burns W K,Moeller R P.高稳定掺铒超荧光光纤光源[J].光波技术杂志,1995,13(7):1452-1460.(英文版)
[3] Hsu Z C,Peng Z S,Wang L A,等.对于光纤陀螺应用的双程后向超荧光光纤光源的伽马射线辐射效应[C]// 第19届国际光纤传感会议.珀斯(澳大利亚):国际光学工程学会,2008,7004:70044M-1-70044M-4.(英文版)
[4] Girard S,Tortech B,Regnier E,等.掺铒光纤的离子和伽马辐射效应[J].IEEE核科学汇刊,2007,54(6):2426-2434.(英文版)
[5] Girard S,Ouerdane Y,Tortech B,等.铒镱共掺双包层光纤的辐射效应[J].IEEE核科学汇刊,2009,56(6):3293-3299.(英文版)
[6] Zotov K V,Likhachev M E,Tomashuk A L,等.用于飞船应用的耐辐射掺铒光纤[J].IEEE核科学汇刊,2008,55(4):2213-2215.(英文版)
[7] Tortech B,Uffelen M V,Gusarov A,等.掺铒光纤受伽马辐射引起的损耗[J].非晶性固体杂志,2007,353(5/6/7):477-480.(英文版)
[8] Tortech B,Gusarov A,Uffelen M V,等.掺铒光纤受脉冲X光和连续伽马辐射引起的辐射效应[J].IEEE核科学汇刊,2007,54(6):2598-2603.(英文版)
[9] Henschel H,Kohn O,Schmidt H U,等.掺稀土光纤受辐射引起的损耗[J].IEEE核科学汇刊,1998,45(3):1552-1557.(英文版)
[10] Brian P F,Kelly S P,William J,等.伽马辐射引起未泵浦的掺稀土光纤产生光变暗效应[J].IEEE核科学汇刊,2010,57(3):1618-1625.(英文版)
[11] Knight J C,Birks T A,Russel P St J,等.具有光子晶体包层的纯石英单模光纤[J].光学快报,1996 ,21(19):1547-1549.(英文版)
[12] Birks T A,Knight J C,Russel P St J.无限单模光子晶体光纤[J].光学快报,1997,22(13):961-963.(英文版)
[13] 郭媛,阮双琛. 含空气小孔芯光子晶体光纤的色散特性研究[J].深圳大学学报理工版,2010,27(4):386-390.(英文版)
[14] 郭春雨,阮双琛,闫培光,等. 调Q掺Yb大模面积光子晶体光纤激光器研究[J].深圳大学学报理工版,2007,24(1):79-84.
[15] Girard S,Yahya A,Boukenter A,等.光子晶体光纤的伽马辐射衰减[J].电子学快报,2002,38(20):1169-1171.(英文版)
[16] Girard S,Baggio J,Leray J L.新型光波导的辐射效应:空气孔导光光子晶体光纤[J].IEEE核科学汇刊,2005,52(6):2683-2688.(英文版)
[17] Kosolapov A F,Semjonov S L,Tomashuk A L.改进多模硅芯多孔光纤的抗辐射性[C]// 光纤元件、设备、系统及网络国际会议.斯特拉斯堡(法国):国际光学工程学会,2006,6193:61931E-1-61931E-7.(英文版)
[18] Alfeeli B,Pickrell G,Garland M A,等.伽马射线辐射下随机孔光纤的特性及用于辐射传感领域的潜能[J].传感,2007,7(5):676-688.(英文版)
[19] 刘承香,张力,吴旭,等.光子晶体光纤的耦合技术[J].中国惯性技术学报,2009,17(3):366-369.
[1] Wysocki P F,Digonnet M J F,Kim B Y,et al.Characteristics of erbium-doped superfluorescent fiber sources for interferometric sensor applications[J].Journal of Lightwave Technology,1994,12(3):550-567.
[2] Hall D C,Burns W K,Moeller R P.High-stability Er3+ doped superfluorescent fiber sources[J].Journal of Lightwave Technology,1995,13(7):1452-1460.
[3] Hsu Z C,Peng Z S,Wang L A,et al.Gamma ray effects on double pass backward superfluorescent fiber sources for gyroscope applications[C]// Proceeding of the 19th International on Optical Fibre Sensors.Perth(Australia):SPIE,2008,7004:70044M-1-70044M-4.
[4] Girard S,Tortech B,Regnier E,et al.Proton- and gamma-induced effects on erbium-doped optical fibers[J].IEEE Transactions on Nuclear Science,2007,54(6):2426-2434.
[5] Girard S,Ouerdane Y,Tortech B,et al.Radiation effects on ytterbium- and ytterbium/erbium-doped double-clad optical fibers[J].IEEE Transactions on Nuclear Science,2009,56(6):3293-3299.
[6] Zotov K V,Likhachev M E,Tomashuk A L,et al.Radiation-resistant Erbium-doped fiber for spacecraft applications[J].IEEE Transactions on Nuclear Science,2008,55(4):2213-2215.
[7] Tortech B,Uffelen M V,Gusarov A,et al.Gamma radiation induced loss in erbium doped optical fibers[J].Journal of Non-Crystalline Solids,2007,353(5/6/7):477-480.
[8] Tortech B,Gusarov A,Uffelen M V,et al.Pulsed X-ray and continuous gamma radiation effects on erbium doped optical fibers properties[J].IEEE Transactions on Nuclear Science.2007,54(6):2598-2603.
[9] Henschel H,Kohn O,Schmidt H U,et al.Radiation-induced loss of rare earth doped silica fibers[J].IEEE Transactions on Nuclear Science,1998,45(3):1552-1557.
[10] Brian P F,Kelly S P,William J,et al.Gamma-radiation-induced photodarkening in unpumped optical fibers doped with rare-earth constituents[J].IEEE Transactions on Nuclear Science,2010,57(3):1618-1625.
[11] Knight J C,Birks T A,Russel P St J,et al.All silica single mode optical fiber with photonic crystal cladding[J].Optics Letters,1996,21(19):1547-1549.
[12] Birks T A,Knight J C,Russel P St J.Endlessly single-mode photonic crystal fiber[J].Optics Letters,1997,22(13):961-963.
[13] GUO Yuan,RUAN Shuang-chen. Analysis on the dispersion properties of photonic crystal fiber with an air-hole defect core[J].Journal of Shenzhen University Science and Engineering, 2010, 27(4): 386-390.
[14] GUO Chun-yu, RUAN Shuang-chen, YAN Pei-guang,et al. Research on the Q-switched large mode area Yb-doped photonic crystal fiber laser[J].Journal of Shenzhen University Science and Engineering, 2007, 24(1): 79-84.(in Chinese)
[15] Girard S,Yahya A,Boukenter A,et al.γ-radiation-induced attenuation in photonic crystal fibre[J].Electronics Letters,2002,38(20):1169-1171.
[16] Girard S,Baggio J,Leray J L.Radiation-induced effects in a new class of optical waveguides:the air-guiding photonic crystal fibers[J].IEEE Transactions on Nuclear Science,2005,52(6):2683-2688.
[17] Kosolapov A F,Semjonov S L,Tomashuk A L.Improvement of radiation resistance of multimode silica-core holey fibers[C]// Proceedings of International Conference on Reliability of Optical Fiber Components,Devices,Systems,and Networks.Strasbourg(France):SPIE,2006,6193:61931E-1- 61931E-7.
[18] Alfeeli B,Pickrell G,Garland M A,et al.Behavior of random hole optical fibers under gamma ray irradiation and its potential use in radiation sensing applications[J].Sensors,2007,7(5):676-688.
[19] LIU Cheng-xiang,ZHANG Li,WU Xu,et al.Coupling technique of photonic crystal fiber[J].Journal of Chinese Inertial Technology,2009,17(3):366-369.(in Chinese)