Coupled experiment/simulation approach for the design of radiation-hardened rare-earth doped optical fibers and amplifiers

We developed an approach to design radiation-hardened rare earth -doped fibers and amplifiers. This methodology combines testing experiments on these devices with particle swarm optimization (PSO) calculations. The composition of Er/Yb-doped phosphosilicate fibers was improved by introducing Cerium inside their cores. Such composition strongly reduces the amplifier radiation sensitivity, limiting its degradation: we observed a gain decreasing from 19 dB to 18 dB after 50 krad whereas previous studies reported higher degradations up to 0°dB at such doses. PSO calculations, taking only into account the radiation effects on the absorption efficiency around the pump and emission wavelengths, correctly reproduce the general trends of experimental results. This calculation tool has been used to study the influence of the amplifier design on its radiation response. The fiber length used to ensure the optimal amplification before irradiation may be rather defined and adjusted to optimize the amplifier performance over the whole space mission profile rather than before integration in the harsh environments. Both forward and backward pumping schemes lead to the same kind of degradation with our active fibers. By using this promising coupled approach, radiation-hardened amplifiers nearly insensitive to radiations may be designed in the future.

[1]  A. Bjarklev Optical Fiber Amplifiers: Design and System Applications , 1993 .

[2]  B. Cadier,et al.  Radiation Effects on Ytterbium- and Ytterbium/Erbium-Doped Double-Clad Optical Fibers , 2009, IEEE Transactions on Nuclear Science.

[3]  Melanie Ott Radiation Effects Expected for Fiber Laser / Amplifier Rare Earth Doped Optical Fiber , 2004 .

[4]  W. Torruellas,et al.  Fiber amplifier performance in γ-radiation environment , 2007, OFC/NFOEC 2007 - 2007 Conference on Optical Fiber Communication and the National Fiber Optic Engineers Conference.

[5]  Amos A. Hardy,et al.  Efficiency optimization of high-power, Er 3+ –Yb 3+ -codoped fiber amplifiers for wavelength-division-multiplexing applications , 2003 .

[6]  Martin A. Putnam,et al.  Radiation effects in erbium-doped optical fibres , 1992 .

[7]  Kelly Simmons-Potter,et al.  Gamma-Radiation-Induced Photodarkening in Unpumped Optical Fibers Doped With Rare-Earth Constituents , 2010, IEEE Transactions on Nuclear Science.

[8]  Francesco Prudenzano,et al.  A neural network model of erbium-doped photonic crystal fibre amplifiers , 2009 .

[9]  Jing Ma,et al.  Experimental investigation of radiation effect on erbium-ytterbium co-doped fiber amplifier for space optical communication in low-dose radiation environment. , 2009, Optics express.

[10]  H. Henschel,et al.  Radiation-induced loss of rare earth doped silica fibres , 1997 .

[11]  Virginie Nazabal,et al.  Feasibility of Er3+-doped, Ga5Ge20Sb10S65 chalcogenide microstructured optical fiber amplifiers , 2009 .

[12]  F. Berghmans,et al.  Radiation Sensitivity of EDFAs Based on Highly Er-Doped Fibers , 2009, Journal of Lightwave Technology.

[13]  F. Berghmans,et al.  Proton- and Gamma-Induced Effects on Erbium-Doped Optical Fibers , 2007, IEEE Transactions on Nuclear Science.

[14]  S. Girard,et al.  Radiation hardening techniques for Er/Yb doped optical fibers and amplifiers for space application. , 2012, Optics express.

[15]  E. J. Friebele,et al.  Fundamental defect centers in glass: Electron spin resonance and optical absorption studies of irradiated phosphorus‐doped silica glass and optical fibers , 1983 .

[16]  M. Cannas,et al.  Influence of Ce codoping and H2 pre-loading on Er/Yb-doped fiber: Radiation response characterized by Confocal Micro-Luminescence , 2011 .

[17]  G. C. Valley,et al.  Gamma and proton radiation effects in erbium-doped fiber amplifiers: active and passive measurements , 2001 .

[18]  G Fornarelli,et al.  Particle swarm optimization-based approach for accurate evaluation of upconversion parameters in Er3+-doped fibers. , 2011, Optics letters.

[19]  F.. Prudenzano,et al.  Optimization and Characterization of Rare-Earth-Doped Photonic-Crystal-Fiber Amplifier Using Genetic Algorithm , 2007, Journal of Lightwave Technology.

[20]  H. Henschel,et al.  Radiation-induced loss of rare earth doped silica fibres , 1997, RADECS 97. Fourth European Conference on Radiation and its Effects on Components and Systems (Cat. No.97TH8294).

[21]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[22]  G. Kuyt,et al.  Low-Dose Radiation-Induced Attenuation at InfraRed Wavelengths for P-Doped, Ge-Doped and Pure Silica-Core Optical Fibres , 2007, IEEE Transactions on Nuclear Science.

[23]  Liying Tan,et al.  Investigation of the irradiation effect on erbium-doped fiber amplifiers composed by different density erbium-doped fibers , 2009 .

[24]  E. J. Friebele,et al.  Space radiation effects on erbium-doped fiber devices: sources, amplifiers, and passive measurements , 1997 .

[25]  K. Simmons-Potter,et al.  Temperature and dose-rate effects in gamma irradiated rare-earth doped fibers , 2008, Optical Engineering + Applications.