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Advanced microstructured semiconductor neutron detectors: design, fabrication, and performanceBellinger, Steven Lawrence January 1900 (has links)
Doctor of Philosophy / Department of Mechanical and Nuclear Engineering / Douglas S. McGregor / The microstructured semiconductor neutron detector (MSND) was investigated and previous designs were improved and optimized. In the present work, fabrication techniques have been refined and improved to produce three-dimensional microstructured semiconductor neutron detectors with reduced leakage current, reduced capacitance, highly anisotropic deep etched trenches, and increased signal-to-noise ratios. As a result of these improvements, new MSND detection systems function with better gamma-ray discrimination and are easier to fabricate than previous designs. In addition to the microstructured diode fabrication improvement, a superior batch processing backfill-method for 6LiF neutron reactive material, resulting in a nearly-solid backfill, was developed. This method incorporates a LiF nano-sizing process and a centrifugal batch process for backfilling the nanoparticle LiF material. To better transition the MSND detector to commercialization, the fabrication process was studied and enhanced to better facilitate low cost and batch process MSND production.
The research and development of the MSND technology described in this work includes fabrication of variant microstructured diode designs, which have been simulated through MSND physics models to predict performance and neutron detection efficiency, and testing the operational performance of these designs in regards to neutron detection efficiency, gamma-ray rejection, and silicon fabrication methodology. The highest thermal-neutron detection efficiency reported to date for a solid-state semiconductor detector is presented in this work. MSNDs show excellent neutron to gamma-ray (n/γ) rejection ratios, which are on the order of 106, without significant loss in thermal-neutron detection efficiency. Individually, the MSND is intrinsically highly sensitive to thermal neutrons, but not extrinsically sensitive because of their small size. To improve upon this, individual MSNDs were tiled together into a 6x6-element array on a single silicon chip. Individual elements of the array were tested for thermal-neutron detection efficiency and for the n/γ reject ratio. Overall, because of the inadequacies and costs of other neutron detection systems, the MSND is the premier technology for many neutron detection applications.
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Analysis and characterization of perforated neutron detectorsSolomon, Clell J. Jr. January 1900 (has links)
Master of Science / Department of Mechanical and Nuclear Engineering / J. Kenneth Shultis / Perforated neutron detectors suffer the unfortunate effect that their efficiency is a strong function of the direction of neutron incidence. It is found, by Monte Carlo simulation of many perforation shapes, that sinusoidal-type perforations greatly reduce the variation of detector efficiency. Detectors with rod-type perforations are modeled using a hybrid transport
method linking the MCNP transport code and a specialized ion-transport code to
calculate the probability that a neutron is detected. Channel, chevron, and sinusoidal perforations
are modeled using other customized transport codes. Detector efficiency calculations
are performed for neutrons incident at various polar and azimuthal angles. It is discovered
that the efficiency losses of the detectors result from the decreasing solid angle subtended
by the detector from the source and streaming through the detector at specific azimuthal
angles. Detectors achieving an efficiency in excess of 10% and having a relatively flat ± 1%
angular dependence in all azimuthal angles and polar angles between 0 and 60 degrees are predicted. Efficiencies up to 25% are achievable at the loss of directional independence.
In addition to minimizing the directional dependence of the perforated detectors, the
feasibility of developing a neutron detector for deployment in cargo containers to locate
nuclear weapon pits is investigated using the MCNP transport code. The detector considered
is a 7-mm diameter, 6LiF, rod-perforated detector surrounded in a cylinder of polyethylene.
The optimum thicknesses of surrounding polyethylene, to maximize the response of the
detector, is determined to be 10 cm of radial, 5 cm of front, and 5 cm of back polyethylene
for end-on neutron incidence. Such a detector is predicted to produce a count rate between 12
and 15 cpm from a nuclear-weapon pit composed of 90% 239Pu and 10% 240Pu at a distance
of 3 m. Side incidence is also considered, and the optimum moderator dimensions are 8 cm
of radial, 10 cm of front, and 10 cm of back polyethylene that produce approximately the
same count rate.
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Gamma Rays Rejection in a Gadolinium based Semiconductor Neutron DetectorKandlakunta, Praneeth 21 May 2014 (has links)
No description available.
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A Proof-of-Principle Investigation for a Neutron-Gamma Discrimination Technique in a Semiconductor Neutron DetectorKandlakunta, Praneeth 20 June 2012 (has links)
No description available.
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