中文

Journal of Applied Sciences >

2020 , Vol. 38 >Issue 4: 520 - 541

DOI: https://doi.org/10.3969/j.issn.0255-8297.2020.04.002

Optical Fiber Communication Technology

Progress in Near Infrared Ultra-Broadband Fiber Amplification

Expand
  • 1. Key Laboratory of Materials for High Power Laser, Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800, China;
    2. University of Chinese Academy of Sciences, Beijing 100049, China;
    3. Hangzhou Institute for Advanced Study, University of Chinese Academy of Sciences, Hangzhou 310024, China

Received date: 2020-06-08

  Online published: 2020-08-01

Fold

Abstract

With the rapid development of optical communications, expanding the gain bandwidth of fiber amplifiers has become an urgent problem to be solved. However, the present gain bandwidth of conventional fiber amplifiers cannot meet the needs of communication capacity, thus bringing serious challenges to the speed and capacity of optical communication. This study briefly introduces the latest research achievements of broadband amplifiers based on Bi-doped fiber, Bi/Er co-doped fiber and quantum dot-doped fiber. And the future researches of ultra-broadband amplifying materials are prospected as well.

Key words: ultra-broadband amplification; optical gain; bismuth-doped fiber; bismuth and erbium co-doped fiber; quantum dot(QD)

Cite this article

JIAO Yan, SHAO Chongyun, HU Lili . Progress in Near Infrared Ultra-Broadband Fiber Amplification[J]. Journal of Applied Sciences, 2020 , 38(4) : 520 -541 . DOI: 10.3969/j.issn.0255-8297.2020.04.002

References

[1] Foroni M, Poli F, Cucinotta A, et al. All-silica double-pass S+C+L band EDFA[J]. Electronics Letters, 2007, 43(6):21-22.
[2] Maity A, Varshney S K. Temperature-insensitive, gain flattened erbium-doped photonic crystal fiber amplifier:a compatible solution[J]. Optical and Quantum Electronics, 2016, 48(8):373.
[3] Sen R, Paul M, Pal M, et al. Erbium doped optical fibers-fabrication technology[J]. Journal of Optics, 2004, 33(4):257-275.
[4] Dianov E M. Bismuth-doped optical fibers:a challenging active medium for near-IR lasers and optical amplifiers[J]. Light:Science & Applications, 2012, 1(5):e12.
[5] Fujimoto Y, Nakatsuka M. Infrared luminescence from bismuth-doped silica glass[J]. Japanese Journal of Applied Physics, 2001, 40(3B):L279.
[6] Meng X, Qiu J, Peng M, et al. Near infrared broadband emission of bismuth-doped aluminophosphate glass[J]. Optics Express, 2005, 13(5):1628-1634.
[7] Sokolov V O, Plotnichenko V G, Dianov E M. Origin of broadband near-infrared luminescence in bismuth-doped glasses[J]. Optics Letters, 2008, 33(13):1488-1490.
[8] Denker B, Galagan B, Osiko V, et al. The IR emitting centers in Bi-doped Mg-Al-Si oxide glasses[J]. Laser Physics, 2009, 19(5):1105-1111.
[9] Lakshminarayana G, Yang R, Mao M, et al. Spectral analysis of optical centres formed in Bi-, Bi/Yb-, Pb-, Pb/Yb-, Sb-, Sb/Yb-and Sn-, Sn/Yb-co-doped germanate glasses[J]. Journal of Physics D:Applied Physics, 2009, 42(14):145108.
[10] Peng M, Dong G, Wondraczek L, et al. Discussion on the origin of NIR emission from Bi-doped materials[J]. Journal of Non-Crystalline Solids, 2011, 357(11/12/13):2241-2245.
[11] Sokolov V O, Plotnichenko V G, Dianov E M. The origin of near-IR luminescence in bismuth-doped silica and Germania glasses free of other dopants:first-principle study[J]. Optical Materials Express, 2013, 3(8):1059-1074.
[12] Dianov E M. On the nature of near-IR emitting Bi centres in glass[J]. Quantum Electronics, 2010, 40(4):283.
[13] Bufetov I A, Dianov E M. Bi-doped fiber lasers[J]. Laser Physics Letters, 2009, 6(7):487.
[14] Dvoyrin V V, Mashinsky V M, Dianov E M, et al. Absorption, fluorescence and optical amplification in MCVD bismuth-doped silica glass optical fibers[C]//200531st European Conference on Optical Communication, Glasgow, 2005, 4:949-950.
[15] Seo Y S, Lim C H, Fujimoto Y, et al. 9.6 dB Gain at a 1310 nm wavelength for a bismuth-doped fiber amplifier[J]. Journal of the Optical Society of Korea, 2007, 11(2):63-66.
[16] Seo Y S, Fujimoto Y, Nakatsuka M. Optical amplification in a bismuth-doped silica fiber[C]//Passive Components and Fiber-Based Devices Ⅲ, South Korea, 2006, 6351:63512C.
[17] Chapman B H, Kelleher E J R, Golant K M, et al. Amplification of picosecond pulses and gigahertz signals in bismuth-doped fiber amplifiers[J]. Optics Letters, 2011, 36(8):1446-1448.
[18] Thipparapu N K, Jain S, Umnikov A A, et al. 1120 nm diode-pumped Bi-doped fiber amplifier[J]. Optics Letters, 2015, 40(10):2441-2444.
[19] Bufetov I A, Firstov S V, Khopin V F, et al. Bi-doped fiber lasers and amplifiers for a spectral region of 1300~1470 nm[J]. Optics Letters, 2008, 33(19):2227-2229.
[20] Norizan S F, Chong W Y, Harun S W, et al. O-band bismuth-doped fiber amplifier with double-pass configuration[J]. IEEE Photonics Technology Letters, 2011, 23(24):1860-1862.
[21] Bufetov I A, Melkumov M A, Khopin V F, et al. Efficient Bi-doped fiber lasers and amplifiers for the spectral region 1300~1500 nm[C]//Fiber Lasers VⅡ:Technology, Systems, and Applications, California, 2010, 7580:758014.
[22] Thipparapu N K, Umnikov A A, Barua P, et al. Bi-doped fiber amplifier with a flat gain of 25 dB operating in the wavelength band 1320~1360 nm[J]. Optics Letters, 2016, 41(7):1518-1521.
[23] Khegai A, Ososkov Y, Firstov S, et al. O-band bismuth-doped fiber amplifier with 67 nm bandwidth[C]//2020 Optical Fiber Communications Conference and Exhibition, California, 2020:1-3.
[24] Wang Y, Thipparapu N K, Richardson D J, et al. Broadband bismuth-doped fiber amplifier with a record 115 nm bandwidth in the O and E bands[C]//Optical Fiber Communication Conference, California, 2020:Th4B. 1.
[25] Bufetov I A, Melkumov M A, Firstov S V, et al. Optical gain and laser generation in bismuth-doped silica fibers free of other dopants[J]. Optics Letters, 2011, 36(2):166-168.
[26] Melkumov M A, Bufetov I A, Shubin A V, et al. Laser diode pumped bismuth-doped optical fiber amplifier for 1430 nm band[J]. Optics Letters, 2011, 36(13):2408-2410.
[27] Mikhailov V, Melkumov M A, Inniss D, et al. Simple broadband bismuth doped fiber amplifier (BDFA) to extend O-band transmission reach and capacity[C]//Optical Fiber Communication Conference, California, 2019:M1J. 4.
[28] Dvoyrin V V, Mashinsky V M, Turitsyn S K. Bismuth-doped fiber amplifier operating in the spectrally adjacent to EDFA range of 1425~1500 nm[C]//Optical Fiber Communication Conference, California, 2020:W1C. 5.
[29] Firstov S V, Alyshev S V, Riumkin K E, et al. A 23 dB bismuth-doped optical fiber amplifier for a 1700 nm band[J]. Scientific Reports, 2016, 6:28939.
[30] Firstov S V, Alyshev S V, Riumkin K E, et al. Laser-active fibers doped with bismuth for a wavelength region of 1.6~1.8μm[J]. IEEE Journal of Selected Topics in Quantum Electronics, 2018, 24(5):1-15.
[31] Dianov E M, Firstov S V, Khopin V F, et al. Bismuth-doped fibers and fiber lasers for a new spectral range of 1600~1800 nm[C]//Fiber Lasers XⅢ:Technology, Systems, and Applications, California, 2016:9728-97280.
[32] Kalita M P, Yoo S, Sahu J. Bismuth doped fiber laser and study of unsaturable loss and pump induced absorption in laser performance[J]. Optics Express, 2008, 16(25):21032-21038.
[33] Thipparapu N K, Wang Y, Wang S, et al. Bi-doped fiber amplifiers and lasers[J]. Optical Materials Express, 2019, 9(6):2446-2465.
[34] Dianov E M. Amplification in extended transmission bands using bismuth-doped optical fibers[J]. Journal of Lightwave Technology, 2012, 31(4):681-688.
[35] Kuwada Y, Fujimoto Y, Nakatsuka M. Ultrawideband light emission from bismuth and erbium doped silica[J]. Japanese Journal of Applied Physics, 2007, 46(4R):1531.
[36] Hau T M, Wang R, Yu X, et al. Near-infrared broadband luminescence and energy transfer in Bi-Tm-Er co-doped lanthanum aluminosilicate glasses[J]. Journal of Physics and Chemistry of Solids, 2012, 73(9):1182-1186.
[37] Luo Y, Wen J, Zhang J, et al. Bismuth and erbium codoped optical fiber with ultrabroadband luminescence across O-, E-, S-, C-, and L-bands[J]. Optics Letters, 2012, 37(16):3447-3449.
[38] Sathi Z M, Zhang J, Luo Y, et al. Improving broadband emission within Bi/Er doped silicate fibres with Yb co-doping[J]. Optical Materials Express, 2015, 5(10):2096-2105.
[39] Zhang J, Sathi Z M, Luo Y, et al. Toward an ultra-broadband emission source based on the bismuth and erbium co-doped optical fiber and a single 830 nm laser diode pump[J]. Optics Express, 2013, 21(6):7786-7792.
[40] Yan B, Luo Y, Zareanborji A, et al. Performance comparison of bismuth/erbium co-doped optical fibre by 830 nm and 980 nm pumping[J]. Journal of Optics, 2016, 18(10):105705.
[41] Firstov S V, Riumkin K E, Khegai A M, et al. Wideband bismuth-and erbium-codoped optical fiber amplifier for C+ L+ U-telecommunication band[J]. Laser Physics Letters, 2017, 14(11):110001.
[42] Zhao Q, Zhang J, Luo Y, et al. Energy transfer enhanced near-infrared spectral performance in bismuth/erbium codoped aluminosilicate fibers for broadband application[J]. Optics Express, 2018, 26(14):17889-17898.
[43] Zhao Q, Luo Y, Hao Q, et al. Effect of thermal treatment parameters on the spectral characteristics of BAC-Al in bismuth/erbium-codoped aluminosilicate fibers[J]. Optics Letters, 2019, 44(18):4594-4597.
[44] Sathi Z M, Zhang J, Luo Y, et al. Spectral properties and role of aluminium-related bismuth active centre (BAC-Al) in bismuth and erbium co-doped fibres[J]. Optical Materials Express, 2015, 5(5):1195-1209.
[45] Klimov V I, Mikhailovsky A A, Xu S, et al. Optical gain and stimulated emission in nanocrystal quantum dots[J]. Science, 2000, 290(5490):314-317.
[46] Bufetov I A, Firstov S V, Khopin V F, et al. Luminescence and optical gain in Pb-doped silica-based optical fibers[J]. Optics Express, 2009, 17(16):13487-13492.
[47] Pang F, Sun X, Guo H, et al. A PbS quantum dots fiber amplifier excited by evanescent wave[J]. Optics Express, 2010, 18(13):14024-14030.
[48] Sun X, Dai R, Chen J, et al. Enhanced thermal stability of oleic-acid-capped PbS quantum dot optical fiber amplifier[J]. Optics Express, 2014, 22(1):519-524.
[49] Wu Y, Shang Y, Kang Y, et al. Tapered optical fiber deposited with PbS as an optical fiber amplifier based on atomic layer deposition[J]. Optical Engineering, 2018, 57(6):066102.
[50] Zheng J, Dong Y, Pan X, et al. Ultra-wideband and flat-gain optical properties of the PbS quantum dots-doped silica fiber[J]. Optics Express, 2019, 27(26):37900-37909.
[51] Dardaillon R, Thomas J, Myara M, et al. Broadband radiation-resistant erbium-doped optical fibers for space applications[J]. IEEE Transactions on Nuclear Science, 2017, 64(6):1540-1548.
Options
Outlines

/