On the design of experiments based on plastic scintillators using Geant4 simulations

TL;DR

This paper uses GEANT4 simulations to optimize plastic scintillator detector designs for space applications, analyzing factors like size ratios, reflective coatings, and decay properties to improve light collection efficiency.

Contribution

It provides a comprehensive simulation-based analysis of various design parameters for plastic scintillator detectors in space, offering guidance for future experimental setups.

Findings

Reflective coatings significantly increase light collection efficiency.

Larger scintillator volume relative to the photo-detector improves detection performance.

Multiple decay components influence pulse shape and timing characteristics.

Abstract

Plastic scintillators are widely used as particle detectors in many fields, mainly, medicine, particle physics and astrophysics. Traditionally, they are coupled to a photo-multplier (PMT) but now silicon photo-multipliers (SiPM) are evolving as a promising robust alternative, specially in space born experiments since plastic scintillators may be a light option for low Earth orbit missions. Therefore it is timely to make a new analysis of the optimal design for experiments based on plastic scintillators in realistic conditions in such a configuration. We analyze here their response to an isotropic flux of electron and proton primaries in the energy range from 1 MeV to 1 GeV, a typical scenario for cosmic ray or space weather experiments, through detailed GEANT4 simulations. First, we focus on the effect of increasing the ratio between the plastic volume and the area of the photo-detector itself and, second, on the benefits of using a reflective coating around the plastic, the most common technique to increase light collection efficiency. In order to achieve a general approach, it is necessary to consider several detector setups. Therefore, we have performed a full set of simulations using the highly tested GEANT4 simulation tool: several parameters have been analyzed such as the energy lost in the coating, the deposited energy in the scintillator, the optical absorption, the fraction of scintillation photons that are not detected, the light collection at the photo-detector, the pulse shape and its time parameters and finally, other design parameters as the surface roughness, the coating reflectivity and the case of a scintillator with two decay components. This work could serve as a guide on the design of future experiments based on the use of plastic scintillators.