The radiation induced attenuation of optical fibres below −20°C exposed to lifetime HL-LHC doses at a dose rate of 700 Gy(Si)/hr

Abstract: The radiation induced attenuation of optical fibres below −20°C exposed to lifetime HL-LHC doses at a dose rate of 700 Gy(Si)/hrTo cite this article: D Hall et al 2012 JINST 7 C01047 View the article online for updates and enhancements. Related contentThe radiation hardness of specific multimode and single-mode optical fibres at -25°C beyond a full SLHC dose to a dose of 500 kGy(Si) B T Huffman, C Issever, N C Ryder et al. -The radiation tolerance of MTP and LC optical fibre connectors to 500 kGy(Si) of gamma … Show more

“…The radiation tolerance of MTP ribbon fibre connectors and LC single fibre connectors has been tested up to 500 kGy(Si) of γ radiation. A dose of 500 kGy(Si) is a factor of two higher than the lifetime dose expected within an inner tracker detector at the HL-LHC [2]. Neither type of connector exhibited evidence for any significant radiation damage.…”

“…Consequently, electronics within HL-LHC detectors will be exposed to higher doses. For example, by simply scaling simulated ATLAS radiation flux maps [1], the expected lifetime HL-LHC dose at a radius of 30 cm from the beampipe is found to be about 250 kGy(Si) [2]. Upgrade designs of inner detectors minimise cost and material by utilising a high-speed (5-10 Gb/s) optical readout system, which must be capable of operating within the harsh radiation environment present at the HL-LHC.…”

The radiation tolerance of MTP and LC optical fibre connectors to 500 kGy(Si) of gamma radiation

“…The radiation tolerance of MTP ribbon fibre connectors and LC single fibre connectors has been tested up to 500 kGy(Si) of γ radiation. A dose of 500 kGy(Si) is a factor of two higher than the lifetime dose expected within an inner tracker detector at the HL-LHC [2]. Neither type of connector exhibited evidence for any significant radiation damage.…”

“…Consequently, electronics within HL-LHC detectors will be exposed to higher doses. For example, by simply scaling simulated ATLAS radiation flux maps [1], the expected lifetime HL-LHC dose at a radius of 30 cm from the beampipe is found to be about 250 kGy(Si) [2]. Upgrade designs of inner detectors minimise cost and material by utilising a high-speed (5-10 Gb/s) optical readout system, which must be capable of operating within the harsh radiation environment present at the HL-LHC.…”

The radiation tolerance of MTP and LC optical fibre connectors to 500 kGy(Si) of gamma radiation

“…There are three reasons why optical conversion is located some distance away from pixel modules: radiation, geometry, and reliability. Fibers and active optical elements both suffer radiation damage [135,136] and are not currently suitable for environments exceeding 100 Mrad. For the laser drivers, but not the fibers, there have been promising developments in silicon photonic systems using Mach-Zehnder interferometers rather than switching lasers, following the trend in commercial high speed optical links [137].…”

A review of advances in pixel detectors for experiments with high rate and radiation

“…A critical design parameter of the link is to minimize the aggregated Radiation Induced Attenuation (RIA) which is a function of accumulated dose, irradiation dose-rate, fibre temperature and transmitted power over the fibre [3]. Figure 2 shows the simulated radiation map inside the ATLAS and CMS detector cross-section over a 10-year interval [4].…”

Fibre Optics Cabling Design for LHC Detectors Upgrade Using Variable Radiation Induced Attenuation Model