Pulsed X‐Ray Radiation Response of Ultralow Loss Pure‐Silica‐Core Optical Fibers

Michele, Vincenzo De; Marcandella, Claude; Morana, Adriana; Campanella, Cosimo; Vidalot, Jeoffray; Paillet, Philippe; Gaillardin, M.; Marin, Emmanuel; Ouerdane, Y.; Boukenter, Aziz; Girard, Sylvain

doi:10.1002/pssa.202100519

Cited by 5 publications

(2 citation statements)

References 33 publications

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“…In this case though, a careful choice of light injection source is needed to obtain enough regeneration of the fiber transmission. Recently, multiple publications have been devoted to the study of a particular ultra-low-loss PSC fiber (ULL-PSCF) [19][20][21][22][23]. The RIA response of this OF differs from most other PSC fibers, which are among the most radiation-resistant under steady-state radiation [24,25].…”

Section: A Regenerating Detector: the Vascade Optical Fibermentioning

confidence: 99%

Distributed Optical Fiber-Based Radiation Detection Using an Ultra-Low-Loss Optical Fiber

Weninger,

Morana,

Ouerdane

et al. 2024

Radiation

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The combination of an ultra-low-loss optical fiber sensitive to ionizing radiation and an optical time domain reflectometer (OTDR) is investigated to explore the feasibility of a single-ended distributed radiation detector. The peculiarity of the tested fiber resides in its regenerative high radiation-induced attenuation (RIA) response in the infrared spectrum (1310 nm), which returns to a low value once the irradiation has ended, combined to its sensitivity, highly increasing with the dose rate. In this work, only some sections of the fiber line were irradiated with 100 kV X-rays at room temperature, to prove the spatially resolved radiation detection capabilities of the system. The transient RIA response of the fiber was characterized at different pre-irradiation doses. A pre-irradiation treatment was shown to stabilize the optical fiber response, improving its RIA vs. dose rate linearity and repeatability. This improved response, in terms of radiation quantification, comes at the cost of a lower detection threshold. This work lays the bases for a distributed radiation detector, with some capabilities in dose rate evaluation.

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Section: A Regenerating Detector: the Vascade Optical Fibermentioning

confidence: 99%

Distributed Optical Fiber-Based Radiation Detection Using an Ultra-Low-Loss Optical Fiber

Weninger,

Morana,

Ouerdane

et al. 2024

Radiation

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“…These localized irregularities of the network are characterized by one or more energy levels lying in the band gap of the dielectric and are responsible for the shift in the optical absorption edge of the glass to lower energies. The phenomenon is known as photodarkening (or solarization) and is even more pronounced in silica optical fibers (OFs) which, due to their strained glass structure, exhibit a higher sensitivity to radiation as compared to the respective preforms [12][13][14][15][16][17][18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Intrinsic Point Defects in Silica for Fiber Optics Applications

2021

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Due to its unique properties, amorphous silicon dioxide (a-SiO2) or silica is a key material in many technological fields, such as high-power laser systems, telecommunications, and fiber optics. In recent years, major efforts have been made in the development of highly transparent glasses, able to resist ionizing and non-ionizing radiation. However the widespread application of many silica-based technologies, particularly silica optical fibers, is still limited by the radiation-induced formation of point defects, which decrease their durability and transmission efficiency. Although this aspect has been widely investigated, the optical properties of certain defects and the correlation between their formation dynamics and the structure of the pristine glass remains an open issue. For this reason, it is of paramount importance to gain a deeper understanding of the structure–reactivity relationship in a-SiO2 for the prediction of the optical properties of a glass based on its manufacturing parameters, and the realization of more efficient devices. To this end, we here report on the state of the most important intrinsic point defects in pure silica, with a particular emphasis on their main spectroscopic features, their atomic structure, and the effects of their presence on the transmission properties of optical fibers.

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Temperature and polarization dependence of radiation-induced attenuation in pure-silica-core PANDA optical fiber

et al. 2022

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Pulsed X‐Ray Radiation Response of Ultralow Loss Pure‐Silica‐Core Optical Fibers

Cited by 5 publications

References 33 publications

Distributed Optical Fiber-Based Radiation Detection Using an Ultra-Low-Loss Optical Fiber

Distributed Optical Fiber-Based Radiation Detection Using an Ultra-Low-Loss Optical Fiber

Intrinsic Point Defects in Silica for Fiber Optics Applications

Temperature and polarization dependence of radiation-induced attenuation in pure-silica-core PANDA optical fiber

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