Abstract: A fabrication method is provided for making a high efficiency neutron detector using a scintillator medium coupled with fiber optic light guides. The light guides provide light pulses to photo sensor and thereby to high speed analog to digital conversion and digital electronics that perform digital pulse shape discrimination for near zero gamma cross talk. Optionally, microwave curing techniques are used for fabricating a high performance neutron detector with high reliability and homogenous distribution of the particles encapsulated in a polymer to produce a high performance neutron detector.

Abstract: A radiation shielding system includes at a first shielding member and at least a second shielding member that is coupled to the first shielding member. Each of the first and second shielding member includes a moderator material. At least the first shielding member includes at least one locking member extending from a surface of a region where the at least one locking member is disposed. At least the second shielding member includes at least one recessed area on a side of the second shielding member corresponding to the side of the first shielding member. The second shielding member is coupled to the first shielding member by the recessed area receiving the locking member.

Abstract: A chemical and biological sensor system (200) includes at least one micro-cantilever sensing element (202) and a mechanism for collecting aerosol, liquid, and solid particles, and depositing the particles as a film layer (146) on a stack (140) formed with the cantilever. The deposited particles include chemical or biological species to be analyzed. A polarized light (242) illuminates the stack (140) at a grazing incidence angle to a specific wavelength of light. The light is polarized in a plane parallel to the stack (140). The polarized light (242) heats the cantilever with different wavelengths of the light spectrum. Readout electronics detect movement of the cantilever (202) as a result of heat transfer from the light and provide spectral data signals corresponding to the detected movement. A spectral analyzer (840) analyzes the spectral data signals, compares spectral images of the materials present to spectral images of known materials, and identifies one or more chemical or biological species present.

Abstract: A multi-stage process utilizing one or more radiation sensors on a distributed network for the detection and identification of radiation, explosives, and special materials within a shipping container. The sensors are configured as nodes on the network. The system collects radiation data from one or more nodes. The collected radiation data is dynamically adjusted according to at least one of a plurality of background radiation data based on a determined background environment about the container. The collected and adjusted radiation data is compared to one or more stored spectral images representing one or more isotopes to identify one or more isotopes present. The identified one or more isotopes present are corresponded to possible materials or goods that they represent.

Abstract: A system detects at least one of nuclear and fissile materials. The system includes a plurality of high speed scintillator detectors. Each high speed scintillator detector in the plurality of high speed scintillator detectors includes at least one photo sensor and a pre-amp circuit adapted to eliminate pulse stretching and distortion of detected light pulses emitted from scintillation material when interacting with neutron particles and/or gamma particles. An isotope database includes a plurality of spectral images corresponding to different known isotopes. An information processing system is adapted to compare spectral data received from each high speed scintillator detector to one or more of the spectral images and identify one or more isotopes present in an object or container being monitored.

Abstract: A scintillator system is provided to detect the presence of fissile material and radioactive material. One or more neutron detectors are based on 6LiF mixed in a binder medium with scintillator material, and are optically coupled to one or more wavelength shifting fiber optic light guide media that have a tapered portion extending from the scintillator material to guide light from the scintillator material to a photosensor at the tapered portion. An electrical output of the photosensor is connected to an input of a first pre-amp circuit designed to operate close to a pulse shape and duration of a light pulse from the scintillator material, without signal distortion. The scintillator material includes a set of scintillation layers connected to the wavelength shifting fiber optic light guide media that guide light to the photosensor. Moderator material is applied around the set of scintillation layers increasing detector efficiency.

Abstract: Sensor arrays arranged in a detection system provide high performance detection of the presence of fissile material and radioactive material in cargo containers and at moderate cost. One or more sensor arrays operate to detect gamma and/or neutron radiation from one or more sides of a container that can be in transport relative to at least one of a spreader bar, a gantry crane, a self-propelled frame structure, and a transport vehicle. A combined use of any two or more of the following: a spreader bar radiation detector array, radiation detectors deployed on the frame of a gantry crane, extended radiation detectors, and a detector array deployed on a BOM cart, truck bed, or bottom area of the container, as the container is moved at a port enables comprehensive coverage of the container under inspection.

Abstract: A multi-stage process utilizing one or more radiation sensors on a distributed network for the detection and identification of radiation, explosives, and special materials within a shipping container. The sensors are configured as nodes on the network. The system collects radiation data from one or more nodes and compares the collected data to one or more stored spectral images representing one or more isotopes to identify one or more isotopes present. The identified one or more isotopes present are corresponded to possible materials or goods that they represent. The possible materials or goods are compared with the manifest relating to the container to confirm the identity of materials or goods contained in the container or to detect and/or identify unauthorized materials or goods in the container. For shielded materials, explosives and other types of material detection, a neutron pulse device could be incorporated into the system.

Abstract: A multi-stage process utilizes one or more sensors, including radiation sensors, on a distributed network for the detection and identification of radiation, explosives, and unauthorized hazardous materials within a shipping container. The sensors can be configured as nodes on the network. The system collects data, such as radiation data, from one or more sensors. The system spectrally analyzes the collected radiation data. The system identifies one or more isotopes based on the spectrally analyzed radiation data. A central monitoring station can monitor radiation data received from the sensors. Communication of sensor data can be done using TCP/IP communication over the network.

Abstract: A neutron detection device (100) includes a semiconductor substrate including a gallium arsenide substrate region (102) having a back surface, and a high purity gallium arsenide active region (104) having a front surface. A back contact layer (118) is disposed on the back surface for providing a first voltage potential at the back surface. Elongated tube cavities extend from respective openings in the front surface into the active region (104) and almost through, but not totally through, the active region. A front contact layer is disposed on the front surface for providing a second voltage potential at the front surface. Neutron reactive material, e.g., pulverized Boron-10 powder, fills the elongated tube cavities to a high packing density. Optionally, spherical holes are formed into the substrate. The spherical holes are filled with neutron reactive material to enhance the efficiency of the neutron detection device.

Abstract: A semi-closed loop diesel photobioreactor system and method are provided for producing diesel fuel from wild algae or from specialized algae that has been biologically modified for high efficiency oil production using waste water as a primary food source. The diesel photobioreactor provides a semi-closed loop system with an opening to acquire waste water below the surface to obtain waste water nutrients and to protect the algae species from contamination. The semi-closed loop diesel photobioreactor includes a container that can be designed in a variety of shapes with a tube design preferred, and containing a liquid culture medium for cultivating photosynthetic organisms. The system can utilize natural light and can also deploy an innovative lighting system integrated into the photobioreactor container. The diesel photobioreactor system also has one or more cleaning devices mounted within the container for cleaning the surface of the photobioreactor container.

Abstract: An integrated chemical, biological, metals, radiation, nuclear, explosives sensor system I-CBMRNE deployed on a common platform supports chemical, biological, metals, radiation, nuclear, explosives (CBMRNE) surveillance systems. The common platform provides a database for collected sensor and video data, spectral analysis for sensor data, pattern recognition systems, data analysis and communications. An I-CBMRNE sensor system provides modular sensor interfaces to enable integration of any commercial off the shelf or proprietary sensor, and provides for ease of integration for new sensor technologies as they emerge. An I-CBMRNE sensor system provides critical functions for sensor support enabling accurate calibrated data to be presented for analysis.

Abstract: A system, method, and floating intelligent perimeter sensor, provide protection for waterways and critical infrastructures. The system and method utilize one or more floating intelligent perimeter sensors to detect, and in some cases identify, hazardous materials associated with vessels in the waterways. The hazardous materials detected, and optionally identified, can include radiological materials, fissile materials, explosives, chemicals and biological materials (CBRNE). A set of radiation data associated with a radiation source in a vessel is received from the one or more floating intelligent perimeter sensors. At least one histogram is generated based on the set of radiation data. The at least one histogram is compared to multiple spectral images associated with known materials. The at least one histogram is determined to substantially match at least one of the multiple spectral images. A determination is made whether a material associated with the radiation source is a hazardous material.

Abstract: A system and method determine a direction associated with gamma and/or neutron radiation emissions. A first radiation photon count associated with a first detector in a detector set is received from the first detector. The first radiation photon count is associated with at least one radiation source. A second radiation photon count associated with a second detector in the detector set is received from the second detector. The first radiation photon count is compared to the second radiation photon count. One of the first detector and the second detector is identified to have detected a larger number of radiation photons than the other. The at least one radiation source is determined to be substantially in a direction in which the one of the first detector and the second detector that has detected the larger number of radiation photons is facing.

Abstract: A system, method, and frame structure detect radiation and identify materials associated with radiation that has been detected. An entity to be examined is determined to have entered between a frame structure. A set of radiation data is received from a set of radiation sensors mechanically coupled to a portion of the frame structure. The set of radiation sensors includes multiple radiation sensors situated in a horizontal configuration with respect to each other and a direction of travel through the frame structure associated with the entity currently being examined. At least one histogram is generated based on the set of radiation data. The at least one histogram is compared to a plurality of spectral images associated with known materials. The at least one histogram is determined to substantially match at least one of the plurality of spectral images. Personnel are notified that the at least one radiation source is a hazardous material.

Abstract: A system, method, and mobile vehicle, identify materials associated with radiation that has been detected. A set of radiation data associated with radiation from at least one radiation source is received from a set of radiation sensors mechanically coupled to the mobile vehicle. At least one histogram is generated based on the set of radiation data. The at least one histogram represents a spectral image of radiation from the radiation source. The at least one histogram is compared to multiple spectral images associated with known materials. The at least one histogram is determined to substantially match at least one of the multiple spectral images. A determination is made as to whether the material is a hazardous material. Personnel are notified that the at least one radiation source is a hazardous material in response to determining that the material associated with the at least one of the multiple spectral images is a hazardous material.

Abstract: A neutron detection device (100) includes a semiconductor substrate including a gallium arsenide substrate region (102) having a back surface, and a high purity gallium arsenide active region (104) having a front surface. A back contact layer (118) is disposed on the back surface for providing a first voltage potential at the back surface. A plurality of elongated tube cavities extend from a plurality of respective openings in the front surface into the high purity gallium arsenide active region (104) and almost through, but not totally through, the high purity gallium arsenide active region (104). A front contact layer is disposed on the front surface for providing a second voltage potential at the front surface. Neutron reactive material, e.g., pulverized Boron-10 powder, fills the plurality of elongated tube cavities to a high packing density. A radiation detection system and a method of fabricating the neutron detection device are also disclosed.

Abstract: A method and water analysis system are provided to automatically, and without manual intervention, detect and identify contamination and/or hazardous material within one or more water samples from a potable and/or effluent water system. The method includes collecting a water sample from a potable and/or effluent water system; monitoring, in response to the collecting, sensors-detectors that are located in proximity to the collected water sample and receiving sensor-detector data from the sensors-detectors. The sensors-detectors include: laser induced breakdown spectrometry (LIBS) sensor technology, gas chromatography sensor technology, mass spectroscopy sensor technology, calorimetric spectroscopy sensor technology, and radiation detection technology. The method further includes spectrally analyzing, in response to the monitoring, the received sensor-detector data to detect, identify, and quantify, metals, chemicals, radiological materials, and biological materials, within the collected water sample.

Abstract: A multi-stage process utilizing one or more radiation sensors on a distributed network for the detection and identification of radiation, explosives, and special materials within a shipping container. The sensors are configured as nodes on the network. The system supports extended time options at each node and the ability to combine data from multiple nodes for the data acquisition and analysis of shipping containers. The system collects radiation data from one or more nodes and compares the collected data to one or more stored spectral images representing one or more isotopes to identify one or more isotopes present. The identified one or more isotopes present are corresponded to possible materials or goods that they represent. The possible materials or goods are compared with the manifest relating to the container to confirm the identity of materials or goods contained in the container or to detect and/or identify unauthorized materials or goods in the container.

Abstract: A communication link arrangement for a cargo moving device comprises an electrical infrastructure that is mechanically coupled to a cargo moving device. The cargo moving device includes a cargo retaining structure and a main body coupled to the cargo retaining structure. The electrical infrastructure includes a single conductor electrically coupling the cargo retaining structure and the main body for delivering power and data signals between the cargo retaining structure and the main body. The electrical infrastructure further includes one or more conductors. A first networking element is mechanically coupled to the cargo retaining structure and is electrically coupled to the single conductor. A second networking element is mechanically coupled the main body and is also electrically coupled to the single conductor. A high-speed network link over power line carries data over the single conductor in the electrical infrastructure that supplies power between the main body and the cargo retaining structure.