Radiation-resistant graded-index multimode optical fibers based on fluorosilicate glass
Pospelova E. A.1,2, Kashaykin P. F. 1,2, Maltsev I. A.1,2, Vokhmyanina O. L.1,2, Sharonova Yu. O.1,2, Azanova I. S. 1,2, Tomashuk A. L. 1,2
1Prokhorov General Physics Institute of the Russian Academy of Sciences, Dianov Fiber Optics Research Center, Moscow, Russia
2Perm Scientific-Industrial Instrument-Making Company, Perm, Russia
Email: pospelovaea@pnppk.ru

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Using the MCVD-technology, radiation-resistant multimode optical fibers based on fluorosilicate glass with a gradient refractive index profile were developed. Radiation-induced attenuation (RIA) of light in the fibers was compared with the literature data on analogous fibers manufactured by the PCVD-technology. It was found out that RIA in the MCVD-fibers at the wavelength λ=1310 nm under γ-irradiation at the doses of up to 10 kGy is 1-2 dB/km (19-29%) lower than RIA in the Super RadHard fiber produced by the PCVD-technology and previously supposed to have a record-high radiation resistance. Keywords: radiation-induced attenuation of light, RIA, graded-index multimode optical fiber, radiation resistance.
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