Abstract: A gamma-ray detector includes a plurality of modular one-dimensional arrays of monolithic detector sub-modules. Each monolithic detector sub-module includes a scintillator layer, a light-spreading layer, and a photodetector layer. The photodetector layer comprises a two-dimensional array of photodetectors that are arranged in columns and rows. A common printed circuit board is electrically coupled to the two-dimensional array of photodetectors of the plurality of modular one-dimensional arrays of monolithic detector sub-modules of a corresponding modular one-dimensional array. The two-dimensional array of photodetectors can be electrically coupled in a split-row configuration or in a checkerboard configuration. The two-dimensional array of photodetectors can also have a differential readout.

Abstract: A position-sensitive photodetector device includes a grid of series-connected photodetectors that are electrically coupled to either a vertical photodetector array (VA photodetectors) or to a horizontal photodetector array (HA photodetectors). The VA and HA photodetectors are arranged in an alternating sequence along rows and/or columns throughout the grid. A horizontal-position readout line is electrically coupled to a termination of each vertical photodetector array, and a vertical-position readout line is electrically coupled to a termination of each horizontal photodetector array.

Abstract: A gamma-ray detector includes a plurality of modular one-dimensional arrays of monolithic detector sub-modules. Each monolithic detector sub-module includes a scintillator layer, a light-spreading layer, and a photodetector layer. The photodetector layer comprises a two-dimensional array of photodetectors that are arranged in columns and rows. A common printed circuit board is electrically coupled to the photodetectors of the monolithic detector sub-modules of a corresponding modular one-dimensional array. The photodetectors can be electrically coupled in a split-row configuration or in a checkerboard configuration. The photodetectors can also have a differential readout.

Abstract: This disclosure is directed to devices and systems and methods comprising virtual negative beveled facets including to isolate adjacent devices from one another. Aspects hereof are directed to integrated photon detectors or photodetector devices incorporating implant isolation mesas and resistors, and in particular to methods and structures for isolating such detectors or devices from neighboring detectors or devices.

Abstract: A position-sensitive photodetector device includes a grid of series-connected photodetectors that are electrically coupled to either a vertical photodetector array (VA photodetectors) or to a horizontal photodetector array (HA photodetectors). The VA and HA photodetectors are arranged in an alternating sequence along rows and/or columns throughout the grid. A horizontal-position readout line is electrically coupled to a termination of each vertical photodetector array, and a vertical-position readout line is electrically coupled to a termination of each horizontal photodetector array.

Abstract: This disclosure is directed to devices and systems and methods comprising virtual negative beveled facets including to isolate adjacent devices from one another. Aspects hereof are directed to integrated photon detectors or photodetector devices incorporating implant isolation mesas and resistors, and in particular to methods and structures for isolating such detectors or devices from neighboring detectors or devices.

Abstract: This disclosure is directed to devices and systems and methods comprising virtual negative beveled facets including to isolate adjacent devices from one another. Aspects hereof are directed to integrated photon detectors or photodetector devices incorporating implant isolation mesas and resistors, and in particular to methods and structures for isolating such detectors or devices from neighboring detectors or devices.

Abstract: This disclosure is directed to devices and systems and methods comprising virtual negative beveled facets including to isolate adjacent devices from one another. Aspects hereof are directed to integrated photon detectors or photodetector devices incorporating implant isolation mesas and resistors, and in particular to methods and structures for isolating such detectors or devices from neighboring detectors or devices.

Abstract: This disclosure is directed to devices and systems and methods comprising virtual negative beveled facets including to isolate adjacent devices from one another. Aspects hereof are directed to integrated photon detectors or photodetector devices incorporating implant isolation mesas and resistors, and in particular to methods and structures for isolating such detectors or devices from neighboring detectors or devices.

Abstract: Systems and methods for detection of spoofed sensor measurements in a microgrid are provided. A system can include a control agent that is configured to determine whether an isolated or continuing intrusion of measurement data received from the primary sensors has occurred, and transmit forecasted measurement data to the controller rather than suspected corrupt measurement data for a suspected isolated intrusion. The control agent and a clone agent can be configured to communicate and work in parallel to confirm a continuing intrusion is occurring, and the control agent can be further configured to transmit measurement data from the redundant sensors to the controller if a continuing intrusion is confirmed.

Abstract: This disclosure is directed to devices and systems and methods comprising virtual negative beveled facets including to isolate adjacent devices from one another. Aspects hereof are directed to integrated photon detectors or photodetector devices incorporating implant isolation mesas and resistors, and in particular to methods and structures for isolating such detectors or devices from neighboring detectors or devices.

Abstract: A photodetector includes an array of pixels, each pixel comprising a defined doped region defined in a doped semiconductor layer. The defined doped region is defined by selected regions of ion implants to provide resistive isolation between each defined doped region. A capacitor is formed by the defined doped region and a metal layer disposed above the doped semiconductor layer. A contact metal line is disposed above the doped semiconductor layer. The capacitor metal and contact metal lines are electrically coupled together and are in electrical communication with the output of the photodetector array.

Abstract: A photodetector includes an array of pixels, each pixel comprising a defined doped region defined in a doped semiconductor layer. The defined doped region is defined by selected regions of ion implants to provide resistive isolation between each defined doped region. A capacitor is formed by the defined doped region and a metal layer disposed above the doped semiconductor layer. A contact metal line is disposed above the doped semiconductor layer. The capacitor metal and contact metal lines are electrically coupled together and are in electrical communication with the output of the photodetector array.

Abstract: A fuel for splitting water into hydrogen and an oxide component comprises a substantially solid pellet formed from a solid-like mixture of a solid-state source material capable of oxidizing in water to form hydrogen and a passivation surface layer of the oxide component, and a passivation preventing agent that is substantially inert to water in an effective amount to prevent passivation of the solid-state material during oxidation. The pellets may be introduced into water or other suitable oxidizer in a controlled rate to control the rate of reaction of the source material with the oxidizer, and thereby control the rate of formation of hydrogen. Methods are described for producing the solid-like mixture in varying weight percent of source material to passivation preventing agent.

Abstract: A novel technique for manufacturing nanostructures and nanostructure is disclosed. The invention exploits techniques to deposit a second semiconductor material on a first semiconductor material with incomplete coverage of the second layer, and forming the nanostructures by filling the holes in the second semiconductor layer with a third semiconductor material. This allows the production of nanowires, nanorods, nanocylinders, and nanotubes with a controllable density and size distribution. Additionally, contact can be made to the bottom of the nanostructures through the first semiconductor layer allowing large area contacts to arrays of nanostructures to be formed. Similarly, contact can be made to the top of the nanostructure by direct deposition of a large area contacting layer. This allows the formation of nanostructure diodes and other nanostructure interconnections.

Abstract: The invention, called hypercontacting, achieves a very high level of activated doping at an exposed surface region of a compound semiconductor. This enables production of low resistance ohmic contacts by creating a heavily doped region near the contact. Such region lowers the contact's tunneling barrier by decreasing the extent of the depletion region at the contact, thereby reducing resistance.

Abstract: The structure and growth method are disclosed for a novel heterojunction diode structure. The invention exploits the Fermi level pinning properties of dislocations and defects in compound semiconductors to achieve heterojunctions with nonlinear current-voltage characteristics despite highly defected, polycrystalline, or amorphous semiconductors. The invention enable new diode, photodetector, and transistor devices to be implemented using highly lattice-mismatched semiconductors. The invention additionally enables thin film diodes, photodetectors, and transistors to be realized.

Abstract: The invention discloses a method of passivating compound semiconductor surfaces aligned to the {110} crystal planes, and devices incorporating said passivated surfaces.

Abstract: The structure and growth method are disclosed for a novel heterojunction diode structure. The invention exploits the Fermi level pinning properties of dislocations and defects in compound semiconductors to achieve heterojunctions with nonlinear current-voltage characteristics despite highly defected, polycrystalline, or amorphous semiconductors. The invention enable new diode, photodetector, and transistor devices to be implemented using highly lattice-mismatched semiconductors. The invention additionally enables thin film diodes, photodetectors, and transistors to be realized.

Abstract: A solid state photodetector is disclosed comprising a multiplicity of photodetector elements, each element using clamped Geiger mode gain to achieve high sensitivity and high speed. The elements are connected together using a common anode to sum their outputs, allowing operation with gray-scale response over a large total photosensitive area. In the preferred embodiment, high speed performance is achieved by isolating each element from the bias supply by means of an integrated series resistor.