TY - JOUR
T1 - Overview of Radiation Effects on Silica-Based Optical Fibers and Fiber Sensors
AU - Girard, S.
AU - Kuhnhenn, J.
AU - Goussarov, Andrei
AU - Morana, A.
AU - Paillet, P.
AU - Robin, T.
AU - Weninger, L.
AU - Fricano, F.
AU - Roche, M.
AU - Campanella, C.
AU - Melin, G.
AU - Lambert, D.
AU - Marin, E.
AU - Boukenter, A.
AU - Ouerdane, Y.
N1 - Score=10
Publisher Copyright:
© 1963-2012 IEEE.
PY - 2024/12
Y1 - 2024/12
N2 - This review focuses on silica-based optical fibers, guiding light through the total internal reflection mechanism, that are currently used in telecommunications and sensor networks. Section I briefly introduces the fiber and fiber sensor technologies. Section II presents their various applications in radiation environments. In section III, the radiation effects on optical fibers are explained, first at a microscopic scale, with the description of point defects generated by irradiation. Then, the macroscopic consequences of the appearance of these point defects are discussed, in particular the phenomena of radiation-induced attenuation (RIA), radiation-induced emission (RIE) and radiation-induced refractive index change (RIRIC). RIA impacts nearly all applications under irradiation. We then detail the various parameters, intrinsic or extrinsic to the optical fibers that influence their amplitudes and kinetics. This improved knowledge paved the way for the radiation hardening of optical fibers through various approaches, either at material, component or system levels, that are described in section IV. Recent advances are presented for passive and for active rare-earth doped optical fibers and systems. Then, the use of fiber optic sensors is introduced, starting in section V with the latest advances in radiation-hardened point or distributed sensors. Then, the potential of this technology for radiation detection, beam instrumentation and dosimetry applications is assessed in section VI. Finally, the future prospects and the main challenges to be met in order to accelerate the implementation of this technology in the harshest environments are discussed.
AB - This review focuses on silica-based optical fibers, guiding light through the total internal reflection mechanism, that are currently used in telecommunications and sensor networks. Section I briefly introduces the fiber and fiber sensor technologies. Section II presents their various applications in radiation environments. In section III, the radiation effects on optical fibers are explained, first at a microscopic scale, with the description of point defects generated by irradiation. Then, the macroscopic consequences of the appearance of these point defects are discussed, in particular the phenomena of radiation-induced attenuation (RIA), radiation-induced emission (RIE) and radiation-induced refractive index change (RIRIC). RIA impacts nearly all applications under irradiation. We then detail the various parameters, intrinsic or extrinsic to the optical fibers that influence their amplitudes and kinetics. This improved knowledge paved the way for the radiation hardening of optical fibers through various approaches, either at material, component or system levels, that are described in section IV. Recent advances are presented for passive and for active rare-earth doped optical fibers and systems. Then, the use of fiber optic sensors is introduced, starting in section V with the latest advances in radiation-hardened point or distributed sensors. Then, the potential of this technology for radiation detection, beam instrumentation and dosimetry applications is assessed in section VI. Finally, the future prospects and the main challenges to be met in order to accelerate the implementation of this technology in the harshest environments are discussed.
KW - Dosimetry
KW - Optical fiber sensors
KW - Optical fibers
KW - Point defects
KW - Radiation effects
KW - Silica
UR - http://www.scopus.com/inward/record.url?scp=85211464155&partnerID=8YFLogxK
U2 - 10.1109/TNS.2024.3511455
DO - 10.1109/TNS.2024.3511455
M3 - Article
AN - SCOPUS:85211464155
SN - 0018-9499
JO - IEEE transactions on nuclear Science
JF - IEEE transactions on nuclear Science
ER -