Scintillator screen development for fast neutron radiography and tomography and its application at the beamline of the 10 MW BNC research reactor

• Published in: Applied radiation and isotopes Vol. 140; pp. 215 - 223
• Main Authors: Zboray, R., Adams, R., Kis, Z.
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 01.10.2018
• Subjects: Beamline; Fast neutron imaging; Tomography; ZnS-based scintillator; Tomography; Beamline; ZnS-based scintillator; Fast neutron imaging
• ISSN: 0969-8043; 1872-9800
• DOI: 10.1016/j.apradiso.2018.07.016

Simple and inexpensive ZnS-based fast neutron imaging screens have been developed and their performance has been tested and compared to a commercially available one using the RAD beamline of the 10 MW research reactor of the Budapest Neutron Centre (BNC), Hungary. ZnS(Ag) and ZnS(Cu) powders have been mixed with optical epoxy, deaerated and casted into sheet form using an aluminum frame. The ZnS concentration and the screen thickness have been optimised using sample screen pieces. The in-house screens have been tested in camera-based neutron imaging detectors in a reactor beamline and compared with a commercially available polypropylene/ZnS(Cu) fast neutron imaging screen and with a BC400 plastic scintillator slab screen. It has been found that the in-house screen produces only about 60% of light intensity of the commercial polypropylene/ZnS screen, which is mainly due to the lower hydrogen density of the optical epoxy compared to polypropylene by the same amount. The BC400 performs inferior compared to any ZnS-based scintillator tested here. Fast neutron tomography has been performed with both the commercial and the in-house screens on the reactor beamline. A spatial resolution of around 1.6 mm has been achieved. Typically 10–15 min exposures were needed to obtain good quality radiographic images, whereas several hours of acquisition were needed to obtain the full tomographic set images. High quality imaging results have been obtained on large (150 mm in diameter) and dense objects (hydraulic couplings) proving the feasibility and utility of fast neutron imaging for such samples. •Inexpensive, simple ZnS-based fast neutron imaging screens have been developed.•The screen performance has been compared with that of commercial counterparts at a 10-MW research reactor beamline and 70% efficiency of the best commercial one can be achievable.•Radiographic and tomographic imaging has been performed using the different screens.•High quality fast neutron imaging capabilities have been demonstrated on dense and robust objects.