Nuclear fuel imaging using position-sensitive detectors

TL;DR

This paper evaluates the performance of advanced position-sensitive CZT detectors in a gamma-ray imaging device for nuclear fuel inspection, demonstrating improved efficiency and potential for enhanced imaging accuracy.

Contribution

It introduces the use of larger, pixelated CZT detectors and explores Compton imaging to improve nuclear fuel assembly characterization.

Findings

Increased gamma-ray absorption efficiency with larger CZT detectors.

Pixelation enhances spatial resolution of the imaging system.

Simulation shows significant efficiency improvements over current detectors.

Abstract

We are evaluating the performance of a Passive Gamma Emission Tomography (PGET) device equipped with 3D position-sensitive cadmium zinc telluride (CZT) gamma-ray detectors when used for inspecting spent nuclear fuel assemblies (SFAs). Recent advancements in imaging detector technology may offer a method to extend the capabilities of such devices beyond standard safeguards applications, allowing an efficient non-invasive way to accurately characterise the properties of nuclear fuel assemblies. The efficiency of the currently used small CZT detectors is restricted by the limited likelihood of full gamma-ray absorption, which is needed for optimal imaging information. Employing larger CZT detectors would increase the probability of capturing the full energy of gamma rays, thereby enhancing the sensitivity of the PGET device and the quality of the reconstructed images. Large CZT detectors need to be position-sensitive to determine through which collimator slit a gamma ray travelled. Position sensitivity results from the pixelated readout of the CZT crystals. Pixelation potentially increases the spatial resolution of the system, which is currently determined by the collimator used. Pixelation allows resolving the position of arrival up to (readout pitch)/$\sqrt{12}$. We are additionally exploring the potential of utilising Compton imaging to provide information on the origin of gamma rays along the SFA. A simulation is created using Geant4 to compare the full photon absorption efficiency of large and current, small, crystals. Gamma rays of energy 661.7 keV and 1274 keV are targeted to the model describing the approved apparatus now equipped with 22 mm x 22 mm x 10 mm crystals of CZT. It is observed that the efficiency for photon absorption in this case is greatly increased when compared to the existing detectors.