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Design solutions for the hodoscope of the magnetic proton recoil neutron spectrometer of the SPARC tokamak

Authors :
Rosa, M
Mackie, S
Rigamonti, D
Tedoldi, L
Colombi, S
Molin, A
Marcer, G
Nocente, M
Gorini, G
Raj, P
Rebai, M
Carmichael, J
Reinke, M
Scioscioli, F
Tinguely, R
Tardocchi, M
Rosa, M. Dalla
Mackie, S.
Rigamonti, D.
Tedoldi, L. G.
Colombi, S.
Molin, A. Dal
Marcer, G.
Nocente, M.
Gorini, G.
Raj, P.
Rebai, M.
Carmichael, J.
Reinke, M.
Scioscioli, F.
Tinguely, R. A.
Tardocchi, M.
Rosa, M
Mackie, S
Rigamonti, D
Tedoldi, L
Colombi, S
Molin, A
Marcer, G
Nocente, M
Gorini, G
Raj, P
Rebai, M
Carmichael, J
Reinke, M
Scioscioli, F
Tinguely, R
Tardocchi, M
Rosa, M. Dalla
Mackie, S.
Rigamonti, D.
Tedoldi, L. G.
Colombi, S.
Molin, A. Dal
Marcer, G.
Nocente, M.
Gorini, G.
Raj, P.
Rebai, M.
Carmichael, J.
Reinke, M.
Scioscioli, F.
Tinguely, R. A.
Tardocchi, M.
Publication Year :
2024

Abstract

A new 14 MeV neutron spectrometer utilizing the magnetic proton recoil (MPR) technique is under development for the SPARC tokamak. This instrument measures neutrons by converting them into protons, whose momenta are subsequently analyzed using a series of magnets before detection by an array of scintillators known as the hodoscope. In this work, we explore various solutions for the hodoscope detectors through laboratory tests with radioactive sources and simulations. We present findings on light collection and pulse shape discrimination based on detector types, as well as optimal solutions for photo-detectors studying the differences between SiPM and PMT. Our results also led to the determination of a better optimized design for the hodoscope detectors, consisting of a 0.7 cm width and a 13 cm length EJ276D scintillation rod.

Details

Database :
OAIster
Notes :
STAMPA, English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1462314919
Document Type :
Electronic Resource

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