X-rays, γ-rays, electrons and protons radiation-induced changes on the lifetimes of Er 3+ and Yb 3+ ions in silica-based optical fibers

Abstract The evolution of Ytterbium 2F5/2 and Erbium 4I13/2 energy level lifetimes versus doses of various radiation types (40 keV X-rays, 480 MeV protons, 1.2 MeV γ-rays and 6 MeV electrons) were investigated on samples of silica-based Rare-Earth Doped optical Fibers (REDFs). For each studied sample (Er-doped and Er/Yb-doped), a strong dependence of the lifetime value on the irradiation dose (for equivalent doses ranging from 10 Gy(SiO2) to 10 MGy(SiO2)) is observed regardless of the radiation nature. For both fiber types and luminescent ions, complex dose dependences are observed: a limited decrease of the lifetime at the lower doses, whereas a large reduction is reported at doses exceeding 100 kGy(SiO2). The results highlighted the vulnerability of REDF based systems, such as optical amplifiers and sources, for space and nuclear applications. In such harsh environments, Radiation Induced Attenuation (RIA) is also a key issue. The positive effect of Ce co-doping on both the RIA and the lifetimes is reported even at the highest dose of 10 MGy(SiO2). The basic mechanisms involved during the interaction between radiation and fiber material were also investigated through low temperature spectroscopic measurements that revealed the fundamental role of radiation-induced point defects.

[1]  A. L. Tomashuk,et al.  Radiation-resistant and radiation-sensitive silica optical fibers , 2000, Other Conferences.

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

[3]  Pak Lim Chu Nonlinear effects in rare-earth-doped fibers and waveguides , 1997, Conference Proceedings. LEOS '97. 10th Annual Meeting IEEE Lasers and Electro-Optics Society 1997 Annual Meeting.

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

[5]  Youcef Ouerdane,et al.  Optimization of rare-earth-doped amplifiers for space mission through a hardening-by-system strategy , 2017, LASE.

[6]  J. Lincoln Spectroscopy of rare earth doped glasses , 1992 .

[7]  O. Gilard,et al.  A model for the prediction of EDFA gain in a space radiation environment , 2004, IEEE Photonics Technology Letters.

[8]  D. Boivin,et al.  Radiation-resistant erbium-doped-nanoparticles optical fiber for space applications. , 2012, Optics express.

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

[10]  Youcef Ouerdane,et al.  Optimized radiation-hardened erbium doped fiber amplifiers for long space missions , 2017 .

[11]  S. Girard,et al.  Radiation-hard erbium optical fiber and fiber amplifier for both low- and high-dose space missions. , 2014, Optics letters.

[12]  S. Girard,et al.  Pulsed X-ray and /spl gamma/ rays irradiation effects on polarization-maintaining optical fibers , 2004, IEEE Transactions on Nuclear Science.

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

[14]  A D'Orazio,et al.  Refinement of Er3+-doped hole-assisted optical fiber amplifier. , 2005, Optics express.

[15]  Philippe Goldner,et al.  Impact of rare earth element clusters on the excited state lifetime evolution under irradiation in oxide glasses. , 2015, Optics express.

[16]  S. Girard,et al.  Radiation Effects on Silica-Based Optical Fibers: Recent Advances and Future Challenges , 2013, IEEE Transactions on Nuclear Science.

[17]  K. Dybdal,et al.  Detailed theoretical and experimental investigation of high-gain erbium-doped fiber amplifier , 1990, IEEE Photonics Technology Letters.

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

[19]  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 .

[20]  V. Ter-mikirtychev,et al.  Fundamentals of Fiber Lasers and Fiber Amplifiers , 2019, Springer Series in Optical Sciences.

[21]  E. J. Friebele,et al.  Radiation protection of fiber optic materials: Effect of cerium doping on the radiation‐induced absorption , 1975 .

[22]  B. Cadier,et al.  Influence of ${\rm Ce}^{3+}$ Codoping on the Photoluminescence Excitation Channels of Phosphosilicate Yb/Er-Doped Glasses , 2012, IEEE Photonics Technology Letters.

[23]  H. Henschel,et al.  Regeneration of irradiated optical fibres by photobleaching? , 1999, 1999 Fifth European Conference on Radiation and Its Effects on Components and Systems. RADECS 99 (Cat. No.99TH8471).

[24]  Yong Gyu Choi,et al.  Comparative study of energy transfers from Er3+ to Ce3+ in tellurite and sulfide glasses under 980 nm excitation , 2000 .

[25]  Paul Borgermans,et al.  Radiation effect in silica optical fiber exposed to intense mixed neutron-gamma radiation field , 2001 .

[26]  M. Gaillardin,et al.  Design of Radiation-Hardened Rare-Earth Doped Amplifiers Through a Coupled Experiment/Simulation Approach , 2013, Journal of Lightwave Technology.

[27]  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.

[28]  Michel J. F. Digonnet,et al.  Rare earth doped fiber lasers and amplifiers , 1993 .

[29]  Janet L. Barth,et al.  Space and Atmospheric Environments: From Low Earth Orbits to Deep Space , 2013 .