Optimizing the light output of a plastic scintillator and SiPM based detector through optical characterization and simulation: A case study for POLAR-2

TL;DR

This study combines optical characterization and simulation to optimize the light output of a plastic scintillator and SiPM-based detector, specifically for the POLAR-2 gamma-ray burst polarimeter, highlighting the importance of surface roughness and innovative optical coupling techniques.

Contribution

It introduces a comprehensive optical simulation and characterization approach for detector optimization, including the impact of surface roughness and a new silicone-based optical coupling method.

Findings

Surface roughness significantly affects light collection efficiency.

A softer, higher-efficiency scintillator with rougher surface is not always optimal.

Developed a reusable, thin silicone optical coupling pad for improved channel crosstalk.

Abstract

The combination of plastic scintillators with Silicon Photo-Multipliers (SiPMs) is widely used for detecting radiation in high-energy astrophysics, particle physics, neutrino physics, or medical physics. An example of application for this kind of detectors are Compton polarimeters such as POLAR-2 or LEAP, for which a low-Z material is needed for the Compton effect to be dominant down to as low energy as possible. Such detectors aim to measure low energy Compton depositions which produce small amounts of optical light, and for which optimizing the instrumental optical properties consequently imperative. The light collection efficiency of such a device was studied with a focus on the POLAR-2 GRB polarimeter, in which the conversion of incoming $\gamma$-rays into readable signal goes through the production and collection of optical light, which was to be optimized both through measurements and simulations. The optical elements of the POLAR-2 polarimeter prototype module were optically characterized and an optical simulation based on Geant4 was developed to fully model its optical performances. The results from simulations were used to optimize the design and finally to verify its performance. The study resulted in a detector capable of measuring energy depositions of several keV. In addition an important finding of this work is the impact of the plastic scintillator surface roughness on the light collection. It was found that a plastic scintillator with a higher scintillation efficiency but made of a softer material, hence with a rougher surface, was not necessarily the best option to optimize the light collection. Furthermore, in order to optimize the optical crosstalk between different channels, a production technique for very thin ($\sim$150$~\mu$m) and reusable silicone-based optical coupling pads, which can be applied for other experiments, was developed.