Model-based Design Evaluation of a Compact, High-Efficiency Neutron Scatter Camera

TL;DR

This paper models and evaluates a compact neutron scatter camera using segmented scintillator pillars, achieving high precision in neutron direction and energy estimation through optical and timing techniques.

Contribution

It introduces a novel single-volume scintillator design with optical segmentation and models its performance for neutron detection and direction estimation.

Findings

Position estimation error < 1 cm RMS for proton recoils > 1 MeV

Energy estimation error < 50 keV RMS for proton recoils > 1 MeV

Optimal design uses EJ-204 scintillator with MCP-PM photodetectors

Abstract

This paper presents the model-based design and evaluation of an instrument that estimates incident neutron direction using the kinematics of neutron scattering by hydrogen-1 nuclei in an organic scintillator. The instrument design uses a single, nearly contiguous volume of organic scintillator that is internally subdivided only as necessary to create optically isolated pillars. Scintillation light emitted in a given pillar is confined to that pillar by a combination of total internal reflection and a specular reflector applied to the four sides of the pillar transverse to its long axis. The scintillation light is collected at each end of the pillar using a photodetector. In this optically segmented design, the (x, y) position of scintillation light emission (where the x and y coordinates are transverse to the long axis of the pillars) is estimated as the pillar's (x, y) position in the scintillator "block", and the z-position (the position along the pillar's long axis) is estimated from the amplitude and relative timing of the signals produced by the photodetectors at each end of the pillar. For proton recoils greater than 1 MeV, we show that the (x, y, z)-position of neutron-proton scattering can be estimated with < 1 cm root-mean-squared [RMS] error and the proton recoil energy can be estimated with < 50 keV RMS error by fitting the photodetectors' response time history to models of optical photon transport within the scintillator pillars. Finally, we evaluate several alternative designs of this proposed single-volume scatter camera made of pillars of plastic scintillator (SVSC-PiPS), studying the effect of pillar dimensions, scintillator material, and photodetector response vs. time. Specifically, we conclude that an SVSC-PiPS constructed using EJ-204 and an MCP-PM will produce the most precise estimates of incident neutron direction and energy.