D. Rodriguez, F. Rossi, Tohn Takahashi
Jun 1, 2019
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Applied radiation and isotopes : including data, instrumentation and methods for use in agriculture, industry and medicine
Abstract
Delayed gamma-ray spectroscopy (DGS) is an active-interrogation nondestructive assay technique that can be used to determine the composition of a nuclear material sample by comparing the ratios of fission product gamma-ray peak intensities. However, high-radioactivity nuclear material (HRNM) contains long-lived fission products that can overwhelm a detector and shielding must be used to reduce the count rate, while minimally affecting those gamma rays from short-lived fission products with energy above 3-MeV. To compensate for the signal loss through the shielding, low-energy neutrons are required to induce more fission events from the high thermal cross-section of fissile nuclides. To improve practical safeguards DGS capabilities, we are developing a compact interrogation system to moderate ∼ 2-MeV neutrons that are easier to moderate than 14-MeV neutrons from standard deuterium-tritium generators. This work describes the optimization of an ideal moderator system for a 252Cf neutron point source that results in a neutron fluence of 25.9×10-4 cm-2nsource-1 passing through the sample space with ≳ 70% of those below 1-eV. Modifications for practical fabrication resulted in ⩽20% reductions of the flux compared to the optimized ideal design. Finally, evaluations made of HRNM DGS signals and backgrounds conclude that a 252Cf source intensity of 8.9×107 neutrons per second is required for a single-pass interrogation within this ideal moderator system. However, this can be as low as 3.6×106 neutrons per second using smaller samples that require less shielding.