Dose rate effects in radiation-induced changes to phenyl-based polymeric scintillators

TL;DR

This study investigates how different dose rates and material compositions affect radiation damage in phenyl-based plastic scintillators, revealing dose rate-dependent damage mechanisms and material resilience.

Contribution

It provides the first detailed analysis of dose rate effects on radiation-induced changes in phenyl-based scintillators, including the dependence of the dose constant on dose rate and material type.

Findings

Dose rate influences the exponential dose constant $D$ linearly on a logarithmic scale.

PVT scintillators are more resistant to high dose rates than PS, especially with EJ-200 fluors.

Damage to initial light output exceeds color center formation for scintillators ≤1 cm thick.

Abstract

Results on the effects of ionizing radiation on the signal produced by plastic scintillating rods manufactured by Eljen Technology company are presented for various matrix materials, dopant concentrations, fluors (EJ-200 and EJ-260), anti-oxidant concentrations, scintillator thickness, doses, and dose rates. The light output before and after irradiation is measured using an alpha source and a photomultiplier tube, and the light transmission by a spectrophotometer. Assuming an exponential decrease in the light output with dose, the change in light output is quantified using the exponential dose constant $D$. The $D$ values are similar for primary and secondary doping concentrations of 1 and 2 times, and for antioxidant concentrations of 0, 1, and 2 times, the default manufacturer's concentration. The $D$ value depends approximately linearly on the logarithm of the dose rate for dose rates between 2.2 Gy/hr and 70 Gy/hr for all materials. For EJ-200 polyvinyltoluene-based (PVT) scintillator, the dose constant is approximately linear in the logarithm of the dose rate up to 3400 Gy/hr, while for polystyrene-based (PS) scintillator or for both materials with EJ-260 fluors, it remains constant or decreases (depending on doping concentration) above about 100 Gy/hr. The results from rods of varying thickness and from the different fluors suggest damage to the initial light output is a larger effect than color center formation for scintillator thickness $\leq1$ cm. For the blue scintillator (EJ-200), the transmission measurements indicate damage to the fluors. We also find that while PVT is more resistant to radiation damage than PS at dose rates higher than about 100 Gy/hr for EJ-200 fluors, they show similar damage at lower dose rates and for EJ-260 fluors.