Neutron detection performance of gallium nitride based semiconductors

AbstractNeutron detection is crucial for particle physics experiments, nuclear power, space and international security. Solid state neutron detectors are of great interest due to their superior mechanical robustness, smaller size and lower voltage operation compared to gas detectors. Gallium nitride (GaN), a mature wide bandgap optoelectronic and electronic semiconductor, is attracting research interest for neutron detection due to its radiation hardness and thermal stability. This work investigated thermal neutron scintillation detectors composed of GaN thin films with and without conversion layers or rare-earth doping. Intrinsic GaN-based neutron scintillators are demonstrated via the intrinsic 14N(n, p) reaction, which has a small thermal neutron cross-section at low neutron energies, but is comparable to other reactions at high neutron energies (>1 MeV). Gamma discrimination is shown to be possible with pulse-height in intrinsic GaN-based scintillation detectors. Additionally, GaN-based scintillation detector with a 6LiF neutron conversion layer and Gd-doped GaN detector are compared with intrinsic GaN detectors. These results indicate GaN scintillator is a suitable candidate neutron detector in high-flux applications.

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Improving thermal-neutron detection efficiency of silicon neutron detectors using the combined layers of 10B4C on 6LiF

Nuclear Instruments and Methods in Physics Research Section A Accelerators Spectrometers Detectors and Associated Equipment ◽

10.1016/j.nima.2019.04.051 ◽

2019 ◽

Vol 932 ◽

pp. 50-55 ◽

Cited By ~ 1

Author(s):

Yong Jiang ◽

Jian Wu ◽

Yanpeng Yin ◽

Yi Lu ◽

Kunlin Wu ◽

...

Keyword(s):

Thermal Neutron ◽

Detection Efficiency ◽

Neutron Detection ◽

Neutron Detectors ◽

Neutron Detection Efficiency

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Thin Film Polymer Composite Scintillators for Thermal Neutron Detection

Journal of Composites ◽

10.1155/2013/539060 ◽

2013 ◽

Vol 2013 ◽

pp. 1-8 ◽

Cited By ~ 9

Author(s):

Andrew N. Mabe ◽

John D. Auxier ◽

Matthew J. Urffer ◽

Stephen A. Young ◽

Dayakar Penumadu ◽

...

Keyword(s):

Thin Film ◽

Thermal Neutron ◽

Gamma Ray ◽

Detection Efficiency ◽

Fluorescence Emission ◽

Neutron Detection ◽

Fluorescent Sensors ◽

Neutron Detectors ◽

Neutron Detection Efficiency ◽

Film Polymer

Thin film polystyrene composite scintillators containing LiF6 and organic fluors have been fabricated and tested as thermal neutron detectors. Varying fluorescence emission intensities for different compositions are interpreted in terms of the Beer-Lambert law and indicate that the sensitivity of fluorescent sensors can be improved by incorporating transparent particles with refractive index different than that of the polymer matrix. Compositions and thicknesses were varied to optimize the fluorescence and thermal neutron response and to reduce gamma-ray sensitivity. Neutron detection efficiency and neutron/gamma-ray discrimination are reported herein as functions of composition and thickness. Gamma-ray sensitivity is affected largely by changing thickness and unaffected by the amount of LiF6 in the film. The best neutron/gamma-ray discrimination characteristics are obtained for film thicknesses in the range 25–150 μm.

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THE USE OF FAST NEUTRON DETECTION FOR MATERIALS ACCOUNTABILITY

International Journal of Modern Physics Conference Series ◽

10.1142/s2010194514601409 ◽

2014 ◽

Vol 27 ◽

pp. 1460140 ◽

Cited By ~ 3

Author(s):

L. F. NAKAE ◽

G. F. CHAPLINE ◽

A. M. GLENN ◽

P. L. KERR ◽

K. S. KIM ◽

...

Keyword(s):

Thermal Neutron ◽

Fast Neutron ◽

Liquid Scintillator ◽

Neutron Detection ◽

Nuclear Material ◽

Detector Response ◽

Surprising Result ◽

Neutron Detectors ◽

Detection Techniques ◽

Fast Neutron Detection

For many years at LLNL, we have been developing time-correlated neutron detection techniques and algorithms for applications such as Arms Control, Threat Detection and Nuclear Material Assay. Many of our techniques have been developed specifically for the relatively low efficiency (a few percent) inherent in man-portable systems. Historically, thermal neutron detectors (mainly 3 He ) were used, taking advantage of the high thermal neutron interaction cross-sections, but more recently we have been investigating the use of fast neutron detection with liquid scintillators, inorganic crystals, and in the near future, pulse-shape discriminating plastics that respond over 1000 times faster (nanoseconds versus tens of microseconds) than thermal neutron detectors. Fast neutron detection offers considerable advantages, since the inherent nanosecond production timescales of fission and neutron-induced fission are preserved and measured instead of being lost in the thermalization of thermal neutron detectors. We are now applying fast neutron technology to the safeguards regime in the form of high efficiency counters. Faster detector response times and sensitivity to neutron momentum show promise in measuring, differentiating, and assaying samples that have modest to very high count rates, as well as mixed neutron sources (e.g., Pu oxide or Mixed Cm and Pu ). Here we report on measured results with our existing liquid scintillator array and promote the design of a nuclear material assay system that incorporates fast neutron detection, including the surprising result that fast liquid scintillator becomes competitive and even surpasses the precision of 3 He counters measuring correlated pairs in modest (kg) samples of plutonium.

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Thermal neutron detection using thin PEN film doped with high cross section materials

Energetika ◽

10.6001/energetika.v63i3.3563 ◽

2017 ◽

Vol 63 (3) ◽

Author(s):

Jevgenij Garankin ◽

Artūras Plukis ◽

Elena Lagzdina

Keyword(s):

Thermal Neutron ◽

Cross Section ◽

Energy Deposition ◽

Gamma Ray ◽

Recoil Proton ◽

Neutron Cross Section ◽

Neutron Detection ◽

Deep Blue ◽

Neutron Reaction ◽

Poly Ethylene

Poly(ethylene 2,6-naphthalate) (PEN) is promising as a new plastic scintillator, which emits deep-blue photons. Its photoluminescence emission peak (434–436 nm) and the decay time is of the order of 3 ns, as well as it is resistant to harsh environment. In this study, thin PEN film with high neutron cross section dopants was used for the thermal neutron detection. Iron boride, lithium tetraborate and lithium metaborate layers were coated on a 125 µm PEN film. Reaction particles from the boron neutron and lithium neutron reaction were detected by scintillation in PEN, and photomultiplier (PMT) pulses were registered and analysed. Energy deposition in the film samples was calculated using MCNP6 code taking into account losses in the source and air gap for the alpha particle source and incomplete energy deposition for the electrons. It was found that a small quantity of particles from the thermal neutron reaction could be detected in the strong neutron, gamma ray and recoil proton background.

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Response to Neutrons and γ-rays of Two Liquid Scintillators

Journal of Nuclear Physics Material Sciences Radiation and Applications ◽

10.15415/jnp.2019.62025 ◽

2019 ◽

Vol 6 (2) ◽

pp. 171-178

Author(s):

Hector Rene Vega-Carrillo ◽

Martha Isabel Escalona-Llaguno ◽

Luis Hernandez-Adame ◽

Sergio M. Sarmiento-Rosales ◽

Claudia A. Márquez-Mata ◽

...

Keyword(s):

Neutron Source ◽

Photon Energy ◽

Gamma Rays ◽

Pulse Shape ◽

Pulse Height ◽

Scintillation Detectors ◽

Neutron Detectors ◽

Multichannel Analyzer ◽

Γ Rays ◽

G Company

UltimaGoldTM AB and OptiphaseTrisafe are two liquid scintillators made by Perkin Elmer and EG & G Company respectively. Both are commercially promoted as scintillation detectors for α and β particles. In this work, the responses to γ-rays and neutrons of UltimaGoldTM AB and OptiphaseTriSafe liquid scintillators, without and with reflector, have been measured aiming to use these scintillators as γ-rays and neutron detectors. Responses to γ-rays and neutrons were measured as pulse shape spectra in a multichannel analyzer. Scintillators were exposed to gamma rays produced by 137Cs, 54Mn, 22Na and 60Co sources. The response to neutrons was obtained with a 241AmBe neutron source that was measured to 25 and 50 cm from the scintillators. The pulse height spectra due to gamma rays are shifted to larger channels as the photon energy increases and these responses are different from the response due to neutrons. Thus, UltimaGoldTM AB and OptiphaseTrisafe can be used to detect γ-rays and neutrons.

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