RIPTIDE: a novel recoil-proton track imaging detector for fast neutrons

TL;DR

RIPTIDE is a new recoil-proton track imaging detector designed for fast neutron detection, utilizing scintillation and advanced imaging sensors to improve efficiency and enable neutron spectrometry.

Contribution

It introduces a novel recoil-proton imaging system combining scintillation and CMOS or MCP sensors for enhanced neutron detection and spectrometry.

Findings

Successful reconstruction of recoil-proton tracks in space and time.

Enhanced detection efficiency for fast neutrons.

Potential for neutron spectrometry through stereoscopic imaging.

Abstract

Neutron detectors are an essential tool for the development of many research fields, as nuclear, particle and astroparticle physics as well as radiotherapy and radiation safety. Since neutrons cannot directly ionize, their detection is only possible via nuclear reactions. Consequently, neutron-based experimental techniques are related to the detection of charged particle or electromagnetic radiation originating from neutron-induced reactions. The study of fast neutrons is often based on the neutron-proton elastic scattering reaction. In this case, the ionization induced by the recoil protons in a hydrogenous material constitutes the basic information for the design and development of neutron detectors. Although experimental techniques have continuously improved and refined, so far, proton-recoil track imaging is still weak in laboratory rate environments because of the extremely small detection efficiency. To address this deficiency, we propose a novel recoil-proton track imaging system in which the light deriving from a fast scintillation signal is used to perform a complete reconstruction in space and time of the event. In particular, we report the idea of RIPTIDE (RecoIl Proton Track Imaging DEtector): an innovative system which combines a plastic scintillator coupled to imaging devices, based on CMOS technology, or Micro Channel Plate sensors. The proposed apparatus aims at providing neutron spectrometry capability by stereoscopically imaging the recoil-protons tracks, correlating the spatial information with the time information.