Radiation Protection Dosimetry Advance Access published online on August 17, 2007
Radiation Protection Dosimetry, doi:10.1093/rpd/ncm395
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WORKPLACE CHARACTERISATION IN MIXED NEUTRON-GAMMA FIELDS. SPECIFIC REQUIREMENTS AND AVAILABLE METHODS AT HIGH-ENERGY ACCELERATORS
CERN, 1211 Geneva 23, Switzerland
Corresponding author: marco.silari{at}cern.ch
A good knowledge of the radiation field present outside the shielding of high-energy particle accelerators is very important to be able to select the type of detectors (active and/or passive) to be employed for area monitoring and the type of personal dosemeter required for estimating the doses received by individuals. Around high-energy electron and proton accelerators the radiation field is usually dominated by neutrons and photons, with minor contributions from other charged particles. Under certain circumstances, muon radiation in the forward beam direction may also be present. Neutron dosimetry and spectrometry are of primary importance to characterise the radiation field and thus to correctly evaluate personnel exposure. Starting from the beam parameters important for radiation monitoring, the paper first briefly reviews the stray radiation fields encountered around high-energy accelerators and then addresses the relevant techniques employed for their monitoring. Recent developments to increase the response of neutron measuring devices beyond 10–20 MeV are illustrated. Instruments should be correctly calibrated either in reference monoenergetic radiation fields or in a field similar to the field in which they are used (workplace calibration). The importance of the instrument calibration is discussed and available neutron calibration facilities are briefly reviewed.