Designing an extended energy range single-sphere multi-detector neutron spectrometer

This communication describes the design specifications for a neutron spectrometer consisting of 31 thermal neutron detectors, namely Dysprosium activation foils, embedded in a 25cm diameter polyethylene sphere which includes a 1cm thick lead shell insert that degrades the energy of neutrons through...

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Bibliographic Details
Published in:Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment Accelerators, spectrometers, detectors and associated equipment, 2012-06, Vol.677, p.4-9
Main Authors: Gómez-Ros, J.M., Bedogni, R., Moraleda, M., Esposito, A., Pola, A., Introini, M.V., Mazzitelli, G., Quintieri, L., Buonomo, B.
Format: Article
Language:English
Subjects:
Activation energy
Computer simulation
Detectors
Dysprosium foils
Monte Carlo methods
Neutron dosimetry
Neutron spectrometers
Neutron spectrometry
Shells
Spectra
Spectrometers
Unfolding
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Summary:This communication describes the design specifications for a neutron spectrometer consisting of 31 thermal neutron detectors, namely Dysprosium activation foils, embedded in a 25cm diameter polyethylene sphere which includes a 1cm thick lead shell insert that degrades the energy of neutrons through (n,xn) reactions, thus allowing to extension of the energy range of the response up to hundreds of MeV neutrons. The new spectrometer, called SP2 (SPherical SPectrometer), relies on the same detection mechanism as that of the Bonner Sphere Spectrometer, but with the advantage of determining the whole neutron spectrum in a single exposure. The Monte Carlo transport code MCNPX was used to design the spectrometer in terms of sphere diameter, number and position of the detectors, position and thickness of the lead shell, as well as to obtain the response matrix for the final configuration. This work focuses on evaluating the spectrometric capabilities of the SP2 design by simulating the exposure of SP2 in neutron fields representing different irradiation conditions (test spectra). The simulated SP2 readings were then unfolded with the FRUIT unfolding code, in the absence of detailed pre-information, and the unfolded spectra were compared with the known test spectra. The results are satisfactory and allowed approving the production of a prototypal spectrometer.
ISSN:0168-9002
1872-9576
DOI:10.1016/j.nima.2012.02.033