Advances in gamma-ray spectroscopy : compton suppression and gamma-gamma coincidence / Compton suppression and gamma-gamma coincidence

Horne, Steven Michael

04 June 2012

This project aims to improve research in gamma-ray spectroscopy by using advanced detector systems. These systems are designed to reduce interference inherent in gamma-ray spectroscopy by rejecting Compton scattering events from high-energy gamma-rays, as well as look at cascading decays of gamma-rays through gamma-gamma coincidence counting. By combining these methods, one is able to lower detection limits for many elements than would otherwise be possible. This work also takes advantage of neutron activation analysis, which allows stable elements to be analyzed by activating them with neutrons, causing them to become unstable and decay with radioactive signatures. By analyzing these signatures, one is able to detect trace levels of elements with relatively small samples sizes (< 1g) and in a nondestructive manner. / text

Gamma spectroscopy

Compton suppression

Gamma-gamma coincidence

Neutron activation analysis

Mercury

Selenium

Uranium

Development of PYRAMDS (Python for Radioisotope Analysis and Multi-Detector Suppression) code used in fission product detection limit improvements with the DGF Pixie-4 digital spectrometer

Weaver, Christopher Jordan

06 July 2011

The work presented here develops a gamma-ray spectral construction and analysis software tool that was used to analyze multi-detector data collected using a digital spectrometer with list mode capabilities. The tool was used to parse the output from three detectors and generate new spectra that the user chooses from post-processing suppression routines, such as simulated anticoincidence and coincidence spectra. Part of this research was also to characterize the improvements in the detection limits and the various detector efficiencies from this method as opposed to creating these spectra using traditional electronic gating systems. A focus is placed on the detection capability improvements for nuclear forensics purposes, particularly the identification and quantification of fission product samples, and structuring the code framework for handling these types of time-dependent samples while increasing the versatility of the detector system. Improvements to the minimum detectable activity for a series of fission products was accomplished through post-processing suppression methods and multi-dimensional spectral data structures are now achievable. / text

Python (Computer program language)

Fission product

Digital spectrometer

Spectrometry

Nuclear forensics

Detection limits

Compton suppression

Minimum detectable activity

Identification of the radionuclides in spent nuclear fuel that may be detected by Compton suppression and gamma-gamma coincidence methods

Schreiber, Samuel Stuart

01 August 2011

The nuclides present in spent nuclear fuel are categorized according to their capacity for detection by Compton suppression or gamma-gamma coincidence methods. The fifty nuclides with the highest activities in spent fuel are identified, their decay schemes analyzed, and the best detection scheme for each is recommended. / text

Spent nuclear fuel

Compton suppression

Gamma-gamma coincidence

Multi-isotope process monitor

MIP

nonprolNferation

Gamma ray signatures

Digital Signal Processing Methods for Safety Systems Employed in Nuclear Power Industry

Popescu, George

January 2016

No description available.

Nuclear Engineering

Nuclear Reactor Safety Systems

Roller Bearings Failure Onset

Predictive Maintenance

Gamma Spectroscopy

Compton Suppression

Pulse Shape Discrimination