中文

Journal of Applied Sciences >

2020 , Vol. 38 >Issue 4: 579 - 594

DOI: https://doi.org/10.3969/j.issn.0255-8297.2020.04.005

Optical Fiber Communication Technology

Progress in Radiation-Resistant Erbium-Doped and Erbium-Ytterbium Co-doped Fibers for Space Optical Communication

Expand
  • 1. State Key Laboratory of Transient Optics and Photonics, Xi'an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Xi'an 710119, China;
    2. University of Chinese Academy of Sciences, Beijing 100049, China;
    3. Zhongkexin Engineering Consulting(Beijing) Co. Ltd., Beijing 100039, China

Received date: 2020-06-18

  Online published: 2020-08-01

Fold

Abstract

Erbium-doped and erbium-ytterbium co-doped fiber amplifiers play an important role in space optical communication systems because of their advantages of anti-electromagnetic interference, high efficiency of electro-optic conversion, size compactness and lightness, and free debugging and maintenance. However, when exposed to the harsh radiation environment of the earth's space orbit for long time, fiber amplifiers will be affected by charged particles and high-energy electromagnetic radiation in the space. In particular, the radiation will damage gain fiber and cause the failure of optical amplification, accordingly, seriously restricting the application of fiber amplifiers in the field of space optical communication. This study first briefly introduces the phenomena and problems of space radiation-induced deterioration of fiber amplifiers, then elaborates the research progress of radiation-resistant erbium-doped and erbium ytterbium co-doped fiber on three aspects: radiation mechanism, radiation-resistant factors in fibers, and methods of radiation reinforcement, and finally prospects the future research trend of radiation-resistant fiber amplifiers.

Key words: optical communication; rare-earth doped fiber; radiation-resistance; color center; radiation induced attenuation(RIA)

Cite this article

SHE Shengfei, MEI Lin, ZHOU Zhenyu, HOU Chaoqi, GUO Haitao . Progress in Radiation-Resistant Erbium-Doped and Erbium-Ytterbium Co-doped Fibers for Space Optical Communication[J]. Journal of Applied Sciences, 2020 , 38(4) : 579 -594 . DOI: 10.3969/j.issn.0255-8297.2020.04.005

References

[1] Zotov K V, Likhachev M E, Tomashuk A L, et al. Radiation-resistant erbium-doped silica fibre[J]. Quantum Electronics, 2007, 37(10):946-949.
[2] Fox B P, Simmons-Potter K, Thomes W 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.
[3] Wilson K, Enoch M. Optical communications for deep space missions[J]. IEEE Communications Magazine, 2000, 38(8):134-139.
[4] Jono T, Takayama Y, Shiratama K, et al. Overview of the inter-orbit and orbit-to-ground laser communication demonstration by OICETS[C]//Proceedings of the International Society for Optics and Photonics, 2007:645702-645711.
[5] Girard S, Vivona M, Lanaud L, et al. Radiation hardening techniques for Er/Yb doped optical fibers and amplifiers for space application[J]. Optics Express, 2012, 20(8):8457-8465.
[6] Artru X, Ray C. Radiation induced by charged particles in optical fibers[J]. Selected Topics on Optical Fiber Technology, 2012(1):571-575.
[7] Lezius M, Predehl K, Stower W, et al. Radiation induced absorption in rare earth doped optical fibers[J]. IEEE Transactions on Nuclear Science, 2012, 59(2):425-433.
[8] Wang Q, Tian CP, Wang YY, et al. Review of radiation hardening techniques for EDFAs in space environment[C]//Proceedings of SPIE-The International Society for Optical Engineering, 2014, 9521:95211D.
[9] 邓涛. 石英玻璃及石英光纤的抗辐射性能研究[D]. 武汉:武汉理工大学图书馆,2010.
[10] 王岩,李洪祚,郝子强. 空间光通信中EDFA的抗辐射技术的研究[J]. 激光与光电子学进展,2013, 50:070601. Wang Y, Li H Z, Hao Z Q. Research of anti-radiation technology for the EDFA systems in space environment[J]. Laser & Optoelectronics Progress, 2013, 50:070601. (in Chinese)
[11] 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.
[12] Ladaci A, Girard S, Mescia L, et al. Optimized radiation-hardened erbium doped fiber amplifiers for long space missions[J]. Journal of Applied Physics, 2017, 121(16):163104.
[13] 李密,马晶,谭立英,等. 空间光通信中空间辐射对光纤放大器性能的影响[J]. 中国激光,2008, 35(s2):42-45. Li M, Ma J, Tan L Y, et al. Space radiation effect on the characters of fiber amplifiers for space optical communication[J]. Chinses Journal of Lasers, 2008, 35(s2):42-45. (in Chinese)
[14] Ladacia, Girard S, Mescia L, et al. X-rays, γ-rays, electrons and protons radiation-induced changes on the lifetimes of Er3+ and Yb3+ ions in silica-based optical fibers[J]. Journal of Luminescence, 2018, 195:402-407.
[15] 肖中银, 王廷云, 罗文芸, 等. 高能粒子辐照二氧化硅玻璃E' 色心形成机理研究[J]. 物理学报, 2008, 57(4):2273-2277. Xiao Z Y, Wang T Y, Luo W Y, et al. Mechanism of E' center formed by irradiation with high energy, particles in silica glasses[J]. Acta Physica Sinica, 2008, 57(4):2273-2277. (in Chinese)
[16] Skuja L, Hirano M, Hosono H, et al. Defects in oxide glasses[J]. Physica Status Solidi C, 2005, 2(1):15-24.
[17] Raghavachari K, Ricci D, Pacchioni G. Optical properties of point defects in SiO2 from time-dependent density functional theory[J]. The Journal of Chemical Physics, 2002, 116(2):825-831.
[18] Griscom D L. Optical properties and structure of defects in silica glass[J]. Journal of the Ceramic Society of Japan, 1991, 99(1154):923-942.
[19] Juodkazis S, Watanabe M, Sun H B, et al. Optically induced defects in vitreous silica[J]. Applied Surface Science, 2000, 154/155:696-700.
[20] Moritani K, Teraoka Y, Takagi I, et al. Electron spin resonance measurement of irradiation defects in vitreous silica irradiated with neutrons and ion beams[J]. Journal of Nuclear Materials, 2004, 329:988-992.
[21] Fox B P, Simmons-Potter K, Simmons J H, et al. Radiation damage effects in doped fiber materials[C]//Proceedings of theInternational Society for Optics and Photonics, 2008, 6873:68731F.
[22] Girard S, Kuhnhenn J, Gusarov A, et al. Radiation effects on silica-based optical fibers:recent advances and future challenges[J]. IEEE Transactions on Nuclear Science, 2013, 60(3):2015-2036.
[23] 宋镜明,郭建华,王学勤,等. 光纤辐射致衰减效应[J]. 激光与光电子学进展,2012, 49(8):080008. Song J M, Guo J H, Wang X Q, et al. Radiation induced attenuation effect for optical fibers[J]. Laser & Optoelectronics Progress, 2012, 49(8):080008. (in Chinese)
[24] 池俊杰,姜诗琦,张琳,等. 光纤激光器辐照性能实验研究[J]. 激光与光电子学进展,2018, 55(6):061406. Chi J J, Jiang S Q, Zhang L, et al. Experimental study on radiation performance of fiber lasers[J]. Laser & Optoelectronics Progress, 2018, 55(6):061406. (in Chinese)
[25] Fox B P, Simmons-Potter K, Thomes W 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.
[26] Presland A, Wijnands T, Jonge L, et al. Gamma-ray induced optical absorption in Ge and P-doped fibers at the LHC[C]//Radiation and Its Effects on Components and Systems, 2005, PAI.
[27] Wijnands T D, Jonge L K, Kuhnhenn J, et al. Optical absorption in commercial single mode optical fibers in a high energy physics radiation field[J]. IEEE Transactions on Nuclear Science, 2008, 55(4):2216-2222.
[28] Williams G M, Putnam M A, Askins C G, et al. Radiation effects in erbium-doped optical fibres[J]. Electronics Letters, 1992, 28(19):1816-1818.
[29] Fukuda C, Chigusa Y, Kashiwada T, et al. Gamma-ray irradiation durability of erbium-doped fibres[J]. Electronics Letters, 1994, 30(16):1342-1344.
[30] Henschel H, Kohn O, Schmidt H U, et al. Radiation-induced loss of rare earth doped silica fibres[J]. IEEE Transactions on Nuclear Science, 1998, 45:439-444.
[31] Trukhin A N, Jansons J L, Truhins K. Luminescence of silica glass containing aluminum oxide[J]. Journal of Non-Crystalline Solids, 2004, 347(1/2/3):80-86.
[32] Brichard B, Fernandez A F, Fern E, et al. Gamma dose rate effect in erbium-doped fibers for space gyroscopes[C]//Proceedings Technical Digest OFS-16, WeP-9 October, 2003:336-338.
[33] Ahrens R G, Jaques J J, Luvalle M J, et al. Radiation effects on optical fibers and amplifiers[C]//Proceedings of the International Society for Optics and Photonics, 2001, 4285, 217-225.
[34] Girard S, Ouerdane Y, Vivonab M, et al. Radiation effects on rare-earth doped optical fibers[C]//Proceedings of the International Society for Optics and Photonics, 2010, 7817:781701.
[35] Régnier E, Burov E, Pastouret A, et al. Recent developments in optical fibers and how defense, security and sensing can benefit[C]//Proceedings of the International Society for Optics and Photonics, 2009, 7306, 730618.
[36] Thomas J, Myara M, Troussellier L, et al. Radiation-resistant erbium-doped-nanoparticles optical fiber for space applications[J]. Optics Express, 2012, 20:2435-2444.
[37] Ladaci A. Rare earth doped optical fibers and amplifiers for space applications[D]. Lyon, France:Universitéde Lyon, 2017.
[38] Henschel H, Köhn O, Weinand U. A new radiation hard optical fiber for high-dose values[J]. IEEE Transactions on Nuclear Science, 2002, 49(3):1432-1438.
[39] Tomashuk A L, Likhachev M E, Zotov K V, et al. H2-loaded carbon-coated Er-doped fibre with enhanced radiation resistance[C]//European Conference on Optical Communications, Cannes, France, 2006, 24-28 Sept.
[40] Girard S, Laurent A, Pinsard E, et al. Proton irradiation response of hole-assisted carbon coated erbium-doped fiber amplifiers[J]. IEEE Transactions on Nuclear Science, 2014, 61(6):3309-3314.
[41] Girard S, Laurent A, Pinsard E, et al. Radiation-hard erbium optical fiber and fiber amplifier for both low- and high-dose space missions[J]. Optics Letters, 2014, 39(9):2541-2544.
[42] Zotov K V, Likhachev M E, Tomashuk A L, et al. Radiation-resistant erbium-doped fiber for spacecraft applications[C]//European Conference on Radiation & Its Effects on Components & Systems, IEEE, 2009.
[43] Ramsey A T, Tighe W, Bartolick J, et al. Radiation effects on heated optical fibers[J]. Review of Scientific Instruments, 1997, 68(1):632-635.
[44] Friebele E J, Gingerich M E. Photobleaching effects in optical fiber waveguides[J]. Applied Optics, 1981, 20(19):3448-3452.
[45] Yeniay A, Gao R F. Radiation induced loss properties and hardness enhancement technique for ErYb doped fibers for avionic applications[J]. Optical Fiber Technology, 2013, 19(2):88-92.
[46] Mady F, Benabdesselam M, Blanc W. Thermoluminescence characterization of traps involved in the photodarkening of ytterbium-doped silica fibers[J]. Optics Letters, 2010, 35(21):3541-3543.
[47] Friebele E J, Gingerich M E. Photobleaching effects in optical fiber waveguides[J]. Applied Optics, 1981, 20(19):3448-3452.
[48] Zotov K V, Likhachev M E, Tomashuk A L, et al. Radiation resistant Er-doped fibers optimization of pump wavelength[J]. IEEE Photonics Technology Letters, 2008, 20(17):1476-1478.
[49] Vivona M, Girard S, Marcandella C, et al. Radiation hardening of rare-earth doped fiber amplifiers[C]//Proceedings of the International Society for Optics and Photonics, 2017, 10564:105641H.
[50] Ladaci A, Girard S, Mescia L, et al. Radiation hardened high-power Er3+/Yb3+-codoped fiber amplifiers for free-space optics communications[J]. Optics Letters, 2018, 43(13):3049-3052.
Options
Outlines

/