Assessing the Feasibility of Interrogating Nuclear Waste Storage Silos using Cosmic-ray Muons

TL;DR

This study evaluates the potential of muon radiography to non-invasively inspect nuclear waste silos, demonstrating its ability to detect uranium objects and density variations, with implications for nuclear industry safety and monitoring.

Contribution

First assessment of muon radiography feasibility for UK nuclear waste silos using simulation and experimental data, highlighting detection capabilities and limitations.

Findings

Able to detect uranium objects >5cm thick within weeks

Density variations hinder resolution of 2cm objects

Detection effectiveness depends on object and detector positioning

Abstract

Muon radiography is a fast growing field in applied scientific research. In recent years, many detector technologies and imaging techniques using the Coulomb scattering and absorption properties of cosmic-ray muons have been developed for the non-destructive assay of various structures across a wide range of applications. This work presents the first results that assess the feasibility of using muons to interrogate waste silos within the UK Nuclear Industry. Two such approaches, using different techniques that exploit each of these properties, have previously been published, and show promising results from both simulation and experimental data for the detection of shielded high-Z materials and density variations from volcanic assay. Both detector systems are based on scintillator and photomultiplier technologies. Results from dedicated simulation studies using both these technologies and image reconstruction techniques are presented for an intermediate-sized nuclear waste storage facility filled with concrete and an array of uranium samples. Both results highlight the potential to identify uranium objects of varying thicknesses greater than 5cm within real-time durations of several weeks. Increased contributions from Coulomb scattering within the concrete of the structure hinder the ability of both approaches to resolve objects of 2cm dimensions even with increased statistics. These results are all dependent on both the position of the objects within the facility and the locations of the detectors. Results for differing thicknesses of concrete, which reflect the unknown composition of the structures under interrogation, are also presented alongside studies performed for a series of data collection durations. It is anticipated that with further research, muon radiography in one, or both of these forms, will play a key role in future industrial applications within the UK Nuclear Industry.