Abstract: A system and method are described for capturing and analyzing gamma rays from neutron excitation of a region in 3-space being analyzed for explosives. A processor analyzes the results, determining whether underground explosives are present in a particular region of the ground. In one embodiment, one gamma ray energy band is used to infer an amount of silicon in the region, while another indicates the combined amount of silicon and nitrogen. The concentration of nitrogen in the region is inferred and used to trigger an “explosive found” or a “no explosive found” signal. In other embodiments, the system or method uses inferences about other elemental constituents of the ground being examined, sometimes taking as input analyzes from prior scans, and providing output indicating the likelihood of the presence of explosives in the region.

Abstract: A system and method are described for capturing and analyzing gamma rays from neutron excitation of a region in 3-space being analyzed for explosives. A processor analyzes the results, determining whether underground explosives are present in a particular region of the ground. In one embodiment, one gamma ray energy band is used to infer an amount of silicon in the region, while another indicates the combined amount of silicon and nitrogen. The concentration of nitrogen in the region is inferred and used to trigger an “explosive found” or a “no explosive found” signal. In other embodiments, the system or method uses inferences about other elemental constituents of the ground being examined, sometimes taking as input analyses from prior scans, and providing output indicating the likelihood of the presence of explosives in the region.

Abstract: A system and method are described for capturing and analyzing gamma rays from neutron excitation of a region in 3-space being analyzed for explosives. A processor analyzes the results, determining whether underground explosives are present in a particular region of the ground. In one embodiment, one gamma ray energy band is used to infer an amount of silicon in the region, while another indicates the combined amount of silicon and nitrogen. The concentration of nitrogen in the region is inferred and used to trigger an “explosive found” or a “no explosive found” signal. In other embodiments, the system or method uses inferences about other elemental constituents of the ground being examined, sometimes taking as input analyzes from prior scans, and providing output indicating the likelihood of the presence of explosives in the region.

Abstract: A system for detecting explosive materials includes at least one deuterium/tritium neutron generator module, at least one germanium detector module, and an analysis module. The deuterium/tritium neutron generator module bombards an object with neutrons. The germanium detector module detects gamma rays emitted by the object in response to the neutrons. The analysis module analyzes the gamma rays detected by the germanium detector module for the presence of explosive materials on or within the object.

Abstract: A system and method for detection of special nuclear materials within a larger space is disclosed and claimed. Gamma rays emitted from special nuclear materials upon neutron interrogation detected. An associated-particle neutron generator provides interrogation neutrons.

Abstract: A radiation detection system and method suitable for use by a first responder to detect a radiological source. The system includes a container that encloses a chamber containing a pressurized inert gas. Incident gamma rays pass through walls of the container to interact with inert gas atoms within the chamber. Wavelength-shifting fiber elements are disposed within scintillator bars oriented parallel to and radially spaced from the chamber axis. At least one sensor is interconnected with the fiber elements to receive first signals therefrom in response to the scattered gamma rays. An electrically-charged wire is disposed within the container along the axis thereof. The wire is adapted to attract electrons released from atoms of the inert gas that are ionized from being impacted by an incident gamma ray, and then produce second signals in response to the released electrons.

Abstract: The patent specification and claims disclose a neutron flux source supplying both monoenergentic neutrons and a spectrum of neutron energies similar to the neutron emission of 252Cf. The neutron flux source is applied to interrogate unknown materials in closed containers for classification of the contents.

Abstract: A radiation detection system and method suitable for use by a first responder to detect a radiological source. The system includes a container that encloses a chamber containing a pressurized inert gas. Incident gamma rays pass through walls of the container to interact with inert gas atoms within the chamber. Wavelength-shifting fiber elements are disposed within scintillator bars oriented parallel to and radially spaced from the chamber axis. At least one sensor is interconnected with the fiber elements to receive first signals therefrom in response to the scattered gamma rays. An electrically-charged wire is disposed within the container along the axis thereof. The wire is adapted to attract electrons released from atoms of the inert gas that are ionized from being impacted by an incident gamma ray, and then produce second signals in response to the released electrons.

Abstract: A system and method suitable for detecting radiation in a flowing liquid, such as a water flowing in a water supply system. The system includes a closed tubular-shaped container having a hollow interior that contains an inert gas at an elevated pressure, and a tubular-shaped housing surrounding the container. The container has a wall structure comprising a cathode, and has an inner electrical element within its hollow interior that defines an anode along a longitudinal axis of the container. The housing has an inlet and an outlet at oppositely-disposed ends thereof, and the container and housing cooperate to define a flow passage generally parallel to the longitudinal axis of the container. The system detects signals generated by the container in response to electrons being released within the container as a result of atoms of the inert gas being ionized by gamma ray radiation and then traveling to the anode.