Above-ground antineutrino detection for nuclear reactor monitoring

Antineutrino monitoring of nuclear reactors has been demonstrated many times (Klimov et al., 1994 [1]; Bowden et al., 2009 [2]; Oguri et al., 2014 [3]), however the technique has not as of yet been developed into a useful capability for treaty verification purposes. The most notable drawback is the...

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Bibliographic Details
Published in:	Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment Vol. 769; pp. 37 - 43
Main Authors:	Sweany, M., Brennan, J., Cabrera-Palmer, B., Kiff, S., Reyna, D., Throckmorton, D.
Format:	Journal Article
Language:	English
Published:	United States Elsevier B.V 01-01-2015 Elsevier
Subjects:	Antineutrino detection Antineutrinos Correlation Detectors INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY Media Monitoring Nuclear reactor components Nuclear reactor monitoring Nuclear reactors Segments Antineutrino detection Nuclear reactor monitoring
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Summary:	Antineutrino monitoring of nuclear reactors has been demonstrated many times (Klimov et al., 1994 [1]; Bowden et al., 2009 [2]; Oguri et al., 2014 [3]), however the technique has not as of yet been developed into a useful capability for treaty verification purposes. The most notable drawback is the current requirement that detectors be deployed underground, with at least several meters-water-equivalent of shielding from cosmic radiation. In addition, the deployment of liquid-based detection media presents a challenge in reactor facilities. We are currently developing a detector system that has the potential to operate above ground and circumvent deployment problems associated with a liquid detection media: the system is composed of segments of plastic scintillator surrounded by 6LiF/ZnS:Ag. ZnS:Ag is a radio-luminescent phosphor used to detect the neutron capture products of 6Li. Because of its long decay time compared to standard plastic scintillators, pulse-shape discrimination can be used to distinguish positron and neutron interactions resulting from the inverse beta decay (IBD) of antineutrinos within the detector volume, reducing both accidental and correlated backgrounds. Segmentation further reduces backgrounds by identifying the positron׳s annihilation gammas, a signature that is absent for most correlated and uncorrelated backgrounds. This work explores different configurations in order to maximize the size of the detector segments without reducing the intrinsic neutron detection efficiency. We believe that this technology will ultimately be applicable to potential safeguards scenarios such as those recently described by Huber et al. (2014) [4,5].
Bibliography:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23 AC04-94AL85000 USDOE National Nuclear Security Administration (NNSA) SAND-2014-17017J
ISSN:	0168-9002 1872-9576
DOI:	10.1016/j.nima.2014.09.073