Abstract: A method of manufacturing an integrated circuit (IC) device includes forming a photoresist layer on a substrate, and exposing the photoresist layer to light by using a photolithographic apparatus including a light generator. The light generator includes a chamber having a plasma generation space, an optical element in the chamber, and a debris shielding assembly between the optical element and the plasma generation space in the chamber, and the debris shielding assembly includes a protective film facing the optical element and being spaced apart from the optical element with a protective space therebetween, the protective space including an optical path, and a protective frame to support the protective film and to shield the protective space from the plasma generation space.

Abstract: A readout circuit that allows on-chip bias calibration of a microbolometer focal plane array (FPA). The readout circuit includes a memory for storing one or more biasing values for a plurality of pixels within the FPA, the plurality of pixels being arranged in one or more columns and one or more rows within the FPA. The readout circuit further includes a column readout connected to the memory and configured to search for the one or more biasing values and to apply a bias adjustment based on the one or more biasing values to a signal received from the FPA. The readout circuit further includes a column multiplexer connected to the column readout and configured to perform dynamic column selection for one or more columns of pixels within the FPA.

Abstract: Disclosed herein is a material, comprising a first metal halide that is operative to function as a scintillator; where the first metal halide excludes cesium iodide, strontium iodide, and cesium bromide; and a surface layer comprising a second metal halide that is disposed on a surface of the first metal halide; where the second metal halide has a lower water solubility than the first metal halide.

Abstract: An image pickup device according to the present technology that includes an on-chip lens, a low-refractive index layer, and an infrared absorption layer. The on-chip lens is formed of a high-refractive index material. The low-refractive index layer is formed to be flat on the on-chip lens, the low-refractive index layer being formed of a low-refractive index material. The infrared absorption layer is formed of an infrared absorption material including at least one kind of organic infrared absorption dye and binder resin, a glass transition temperature of the binder resin being not less than 100° C., a concentration of the infrared absorption dye in the infrared absorption material being not less than 15 wt % and not more than 50 wt %, the infrared absorption layer being laminated above the low-refractive index layer.

Abstract: Methods and systems are provided for imaging assemblies including different layers. The layers include a planar layer positioned on imaging components. A scintillator layer is positioned above the planar layer and a sealing layer is positioned above the scintillator layer.

Abstract: A scintillator panel includes a substrate made of an organic material, a barrier layer formed on the substrate and including thallium iodide as a main component, and a scintillator layer formed on the barrier layer and including cesium iodide as a main component. According to this scintillator panel, moisture resistance can be improved by providing the barrier layer between the substrate and the scintillator layer.

Abstract: A radiation detection device includes: a radiation detection panel; a supporting member having a first surface and a second surface being opposite to the first surface, wherein the radiation detection panel is provided at a side of the first surface; first and second power supply units that supply operating electric power of the radiation detection panel; a housing that accommodates the radiation detection panel, the supporting member, and the first power supply unit; and a holder portion which is provided on the second surface of the supporting member and to which the second power supply unit is detachably attached, the holder portion includes a pair of frames that protrude toward a bottom of the housing which faces the second surface of the supporting member and a concave portion as defined herein, and the bottom of the housing has an opening portion through which the concave portion is exposed.

Abstract: A radiographic imaging apparatus, includes: a planar-shaped flexible scintillator board that emits light at an intensity according to a radiation dose of received radiation; a flexible photoelectric conversion panel that includes a plurality of photodetection elements formed so as to be distributed two-dimensionally on a surface of a flexible support board, and is arranged such that an element-formed surface on which the photodetection elements are formed faces the scintillator board, the photodetection elements generating charges according to an intensity of the received radiation; and a moisture barrier layer that is formed of a material having characteristics of preventing moisture from passing therethrough, and covers a surface of the scintillator board opposite to a surface facing the photodetection elements, a side surface of the scintillator board, and a surface of the photoelectric conversion panel opposite to the element-formed surface.

Abstract: Detector module designs for radiographic include first and second layers of scintillator rods or pixel arrays oriented in first and second directions. The first and second directions are transversely oriented to define a light sharing region between the first and second layers. Encoding features may be disposed in, on or between the first and second layers, and configured to modulate propagation of optical signals therealong or therebetween.

Abstract: A photoelectric conversion element capable of reducing a specific dark current. In a photoelectric conversion element (10) including an anode (12), a cathode (16), and an active layer (14) provided between the anode and the cathode, the active layer contains a p-type semiconductor material having a band gap of 0.5 eV to 1.58 eV, and an n-type semiconductor material, the n-type semiconductor material is a C60 fullerene derivative, and on an image obtained by binarizing an image of the active layer observed by a transmission electron microscope, the junction length between a phase of the n-type semiconductor material and a phase of the p-type semiconductor material is 120 ?m to 170 ?m per square micrometer of the area of the binarized image.

Abstract: Disclosed herein is a scintillator for use in an x-ray backscattering system. The scintillator comprises an inorganic scintillator portion made of inorganic scintillating material and comprising one or more inorganic material elements. Each inorganic material element of the one or more inorganic material elements comprises an outer surface, and an inner surface opposite the outer surface. The outer surface is configured to be proximate to a subject to be scanned, such that the outer surface is configured to receive x-ray photons scattered by the subject. The scintillator also comprises an organic scintillator portion made of an organic scintillating material and comprising a front surface. At least a portion of the front surface abuts the inner surface of at least one of the one or more inorganic material elements.

Abstract: There is provided an x-ray detector having a number of x-ray detector sub-modules. Each detector sub-module is an edge-on detector sub-module having an array of detector elements extending in at least two directions, wherein one of the directions has a component in the direction of incoming x-rays. The detector sub-modules are stacked one after the other and/or arranged side-by-side. For at least part of the detector sub-modules, the detector sub-modules are arranged for providing a gap between adjacent detector sub-modules, where at least part of the gap is not directed linearly towards the x-ray focal point of an x-ray source.

Abstract: An apparatus, system and method suitable for detecting X-ray are disclosed. In one example, the apparatus comprises: an X-ray absorption layer and a mask; wherein the mask comprises a first window and a second window, and a portion between the first window and the second window; wherein the first and second windows are not opaque to an incident X-ray; wherein the portion is opaque to the incident X-ray; and wherein the first and second windows are arranged such that charge carriers generated in the X-ray absorption layer by an X-ray photon propagating through the first window and charge carriers generated in the X-ray absorption layer by an X-ray photon propagating through the second window do not spatially overlap.

Abstract: A system identifying a source of radiation is provided. The system includes a radiation source detector and a radiation source identifier. The radiation source detector receives measurements of radiation; for one or more sources, generates a detection metric indicating whether that source is present in the measurements; and evaluates the detection metrics to detect whether a source is present in the measurements. When the presence of a source in the measurements is detected, the radiation source identifier for one or more sources, generates an identification metric indicating whether that source is present in the measurements; generates a null-hypothesis metric indicating whether no source is present in the measurements; evaluates the one or more identification metrics and the null-hypothesis metric to identify the source, if any, that is present in the measurements.

Abstract: Provided are an X-ray inspection apparatus and an X-ray inspection method. The X-ray inspection apparatus includes: an X-ray source; a sample moving mechanism; the TDI sensor; and a TDI computing unit. The TDI computing unit includes a data transfer unit configured to transfer, to an outside, data of accumulated charges obtained by accumulating and transferring the charges, and has a function of setting in advance, as a determination region, a plurality of columns of line sensors with which the sample is detectable, and of detecting the sample in the determination region. The data transfer unit is configured to set, as detecting rows, rows of the pixels with which the sample has been detected in the determination region and rows around the rows, and transfer, to the outside, the data of accumulated charges only for pixels in the detecting rows.

Abstract: A scintillator panel includes a substrate, a resin protective layer formed on the substrate and made of an organic material, a barrier layer formed on the resin protective layer and including thallium iodide as a main component, and a scintillator layer formed on the barrier layer and including cesium iodide with thallium added thereto as a main component. According to this scintillator panel, moisture resistance can be improved due to the barrier layer provided therein.

Abstract: A semiconductor device, sensor, and array of SPAD cubes are described. One example of the disclosed semiconductor device includes an array of single-photon avalanche diodes, each single-photon avalanche diode including an undepleted anode region, an undepleted cathode region, an active depleted region positioned between the anode region and cathode region, and at least one conductive trench extending between the anode region and cathode region. In some examples, the at least one conductive trench surrounds the active depleted region and reflects light back into the active depleted region such that one or more photons can be absorbed within the active depleted region even though an absorption coefficient of the light is greater than a thickness of the active depleted region.

Abstract: A chip-scale sensor package structure includes a sensor chip, a ring-shaped support disposed on a top surface of the sensor chip, a light permeable member disposed on the ring-shaped support, a package body, and a redistribution layer (RDL). The package body surrounds outer lateral sides of the sensor chip, the ring-shaped support and the light permeable member. A bottom surface of the sensor chip and a surface of the light permeable member are exposed from the package body. The RDL is directly formed on the bottom surface of the sensor chip and a bottom side of the package body. The RDL includes a plurality of external contacts arranged on a bottom surface thereof and electrically coupled to the sensor chip. A portion of the external contacts are arranged outside of a projection region defined by orthogonally projecting the sensor chip onto the bottom surface of the RDL.

Abstract: A pixel of an imager device includes a photosensitive area configured to integrate a light signal. A first capacitive storage node is configured to receive a signal representative of the number of charges generated by the photosensitive area. A second capacitive storage node is configured to receive a reference signal. A first transfer transistor is coupled between the first capacitive storage node and the photosensitive area. A second transfer transistor is coupled between the second capacitive storage node and a terminal which supplied the reference signal. The first and second two transfer transistors have a common conduction electrode and a common substrate, wherein the common substrate is coupled to the first capacitive storage node.

Abstract: Time of flight (TOF) corrections for radiation detector elements of a TOF positron emission tomography (TOF PET) scanner are generated by solving an over-determined set of equations defined by calibration data acquired by the TOF PET scanner from a point source located at an isocenter of the TOF PET scanner, suitably represented as matrix equation at ?t=CS where ?t represents TOF time differences, C is a relational matrix encoding the radiation detector elements, and S represents the TOF corrections. A pseudo-inverse C?1 of relational matrix C may be computed to solve S=C?1 ?t. TOF corrections can be generated for a particular type of detector unit by identifying the radiation detector elements in C by detector unit. Further, multi-photon triggering time stamps can be adjusted to first-photon triggering based on ?{square root over (P1/Pm)} where P1 is average photon count using first-photon triggering and Pm is a photon count using multi-photon triggering.

Abstract: The invention relates to a ceramic material (14) for generating light when irradiated with radiation, wherein the ceramic material comprises a stack of layers (15, 16) having different compositions and/or different dopings. The ceramic material may be used in a spectral computed tomography (CT) detector, in order to spectrally detect x-rays, or it may be used as a ceramic gain medium of a laser such that temperature gradients and corresponding thermo-mechanical stresses within the gain medium can be reduced.

Abstract: A device includes a first biosensor of a biosensor array; a second biosensor of a biosensor array; a readout circuit electrically connected to the biosensor array; a decoder electrically connected to the biosensor array; a voltage generator electrically connected to the biosensor array; and a decision system electrically connected to the voltage generator and the readout circuit.

Abstract: A transmissive ionizing-radiation beam monitoring system includes an enclosure structure with at least one ultra-thin window to an incident ionizing-radiation beam, where the ultra-thin window is highly transmissive to ionizing-radiation. Embodiments include at least one thin or ultra-thin scintillator within the enclosure structure that is substantially directly in an incident ionizing-radiation beam path and transmissive to the incident radiation beam, and at least one ultraviolet (UV) illumination source within the enclosure structure facing the scintillator. Embodiments include at least one machine vision camera within the enclosure structure located out of an incident ionizing-radiation beam path and including a camera body and lens having a projection of its optical axis oriented at an angle of incidence of 45±35 degrees to a surface of the scintillator.

Abstract: Described here are tileable block detectors for use in nuclear medicine applications, such as in positron emission tomography (“PET”] systems and positron emission mammography (“PEM”] systems. The block detectors described here are four-side tileable such that seamless arrays of block detectors can be constructed for use in PET or PEM systems. When so arrayed, the block detectors allow for a full-size seamless detector that achieves full coverage of an object (e.g., a gently immobilized breast), improves data collection, and enables high-resolution imaging with a significantly lower radiation dose than with other currently available PEM systems.

Abstract: An array substrate for a digital X-ray detector can include a base substrate; a thin film transistor disposed on the base substrate; a PIN diode including a lower electrode electrically connected to the thin film transistor, a first PIN layer disposed on the lower electrode, and an upper electrode disposed on the first PIN layer; a second PIN layer spaced apart from the PIN diode, the second PIN layer being disposed on the thin film transistor; and a bias electrode electrically connected to the upper electrode.

Abstract: A radiation detection apparatus can include a scintillator to emit scintillating light in response to absorbing radiation; a photosensor to generate an electronic pulse in response to receiving the scintillating light; an analyzer to determine a characteristic of the radiation; and a housing that contains the scintillator, the photosensor, and the analyzer, wherein the radiation detection apparatus to is configured to allow functionality be changed without removing the analyzer from the housing. The radiation detection apparatus can be more compact and more rugged as compared to radiation detection apparatuses that include a photomultiplier tube.

Abstract: There is disclosed an X-ray detector that includes a detection section, an addition rate determination section, an addition section, and a position information storage section in order to enhance the accuracy of interpolation of an output signal from a defective element and suppress artifacts with ease without increasing, for example, the length of processing time, the number of processing circuits, and the amount of interpolation data. The detection section includes a plurality of arrays of detection element groups that are each formed of a plurality of detection elements in correspondence with one pixel. The addition rate determination section determines addition rates for output signals of the detection elements. The addition section calculates the signal value of each pixel of a projection image by adding the output signals of the detection elements belonging to the detection element groups in accordance with the addition rates.

Abstract: An electronic cassette has a configuration in which a first sensor panel and a second sensor panel are sequentially arranged in a thickness direction. The first sensor panel includes a first light detection substrate and a first scintillator. The periphery of the first scintillator is covered by a moisture-proof sealing layer. The sealing layer is made of a conductive material. The sealing layer is connected to the inner surface of a housing made of a conductive material through a connection portion. Therefore, the sealing layer has the same potential as the ground potential of the housing which is a reference potential and functions as a conductor layer.

Abstract: An imaging panel includes an active matrix substrate having pixels each with a photoelectric conversion element, a scintillator provided on a surface of the active matrix substrate, a damp-proof material entirely covering the scintillator, and an adhesive layer bonding the damp-proof material to the scintillator and the active matrix substrate. The active matrix substrate includes a first flattening film that is configured as a photosensitive resin film and is provided inside and outside a pixel region, and a first inorganic film that is provided between the first flattening film and the scintillator, is overlapped in a planar view with an entire region of the scintillator, and is in contact with the first flattening film, at least outside the pixel region. At least partial region on the first inorganic film, outside the region overlapped in a planar view with the scintillator, is covered with the adhesive layer.

Abstract: An optical device includes a substrate, a light receiving component, an encapsulant, a coupling layer and a light shielding layer. The light receiving component is disposed on the substrate. The encapsulant covers the light receiving component. The coupling layer is disposed on at least a portion of the encapsulant. The light shielding layer is disposed on the coupling layer.

Abstract: A radiation detection device includes: a radiation detection panel; a supporting member that supports the radiation detection panel at a side of a first surface of the supporting member; and a housing that accommodates the radiation detection panel and the supporting member, and the supporting member has one or more concave portions at the first surface.

Abstract: The invention belongs to the field of novel photocatalytic materials, and particularly relates to a ZnWO4 photocatalytic material containing oxygen vacancy. According to the material, absorption exists in a near infrared region of an ultraviolet-visible light diffuse reflection spectrum, wherein the wavelength range of the near infrared region is 780-2500 nm. The invention further relates to a preparation method of the ZnWO4 photocatalytic material containing oxygen vacancy. Na2WO4 and soluble zinc salt are used as raw materials, ZnWO4 crystals are formed through a hydrothermal crystallization reaction and then roasted in the presence of hydrogen so as to achieve partial reduction of ZnWO4, and then the ZnWO4 photocatalytic material containing oxygen vacancy is obtained.

Abstract: A radiation therapy system is equipped with a combined imaging system, such as an imaging system combining computed tomography (CT), spectral CT, and single photon emission tomography imaging (SPECT), for guidance of radiation beams providing radiotherapy. The system can include at least one x-ray source that emits an x-ray beam at a low energy level for imaging and/or an x-ray beam at a high energy level for radiation therapy. The system can also include at least one imager, such as a cadmium zinc telluride (CZT) or cadmium telluride (CdTe) flat-panel imager that receives x-ray beams traversing a subject from the x-ray source and gamma rays emitted by radioisotope tracers injected into the subject. Based on the guidance of the triple images (CT, spectral CT, and SPECT), a computer system can control the radiation therapeutic beam delivery to target areas, such as lesions and/or tumors.

Abstract: [Problem] Provided is a layered structure in which a non-scintillator layer is utilized as a light transmission path to a sensor so as to transmit light in a vertical direction through the non-scintillator layer without allowing the light to re-enter a scintillator layer. [Means for Solution] Provided is a scintillator panel having a structure in which a scintillator layer and a non-scintillator layer are repeatedly arranged in a direction substantially parallel to a radiation incident direction. In this scintillator panel, the scintillator layer contains at least a phosphor, a binder resin, and voids; the non-scintillator layer is radiolucent; the scintillator layer and the non-scintillator layer have an irregular structure at their interface; and an arithmetic surface roughness Ra attributed to irregularities is 1/400 to 1/10 of the width of the non-scintillator layer.

Abstract: The invention achieves preventing from moisture penetration into an imaging panel without deterioration in detection accuracy of scintillation light. An imaging panel includes an active matrix substrate having a plurality of pixels each provided with a photoelectric conversion element, a scintillator provided on a surface of the active matrix substrate, a damp-proof material covering the active matrix substrate and the scintillator, and an adhesive layer bonding the damp-proof material to the scintillator and the active matrix substrate. The active matrix substrate includes a first flattening film overlapped in a planar view with the scintillator and configured as a photosensitive resin film. The first flattening film is entirely disposed, in a planar view, inside an adhesive layer region provided with the adhesive layer.

Abstract: A radiation detection device includes: a radiation detection panel; a support member that supports the radiation detection panel; and a housing in which the radiation detection panel and the support member are housed, the housing includes a first housing portion, a second housing portion that supports the support member, and an intermediate member that is disposed between the first housing portion and the second housing portion and that has lower rigidity than the first housing portion, and a peripheral portion of the housing is formed by the first housing portion.

Abstract: Disclosed herein is an apparatus suitable for detecting x-ray, comprising: an X-ray absorption layer configured to generate an electrical signal from an X-ray photon incident on the X-ray absorption layer; an electronics layer comprising an electronics system configured to process or interpret the electrical signal; wherein at least one of the X-ray absorption layer and the electronics layer is embedded in a board of an electrically insulating material.

Abstract: A scintillator panel includes a laminated scintillator having a structure obtained by repeatedly disposing a scintillator layer and a non-scintillator layer in a direction substantially parallel to an incident direction of a radiation, wherein the scintillator layer contains at least a phosphor, a binder resin, and voids, and the non-scintillator layer is transparent, and an average refractive index n1 of the binder resin and the voids of the scintillator layer and a refractive index n2 of the non-scintillator layer satisfy a relationship of formula (A) 0.9?(n2/n1).

Abstract: Some embodiments provide an image sensor that includes (i) quanta image sensor having an array of jots and configured for spatial and temporal oversampling, and (ii) a polarization filter array monolithically integrated with the quanta image sensor, so as to provide for a polarization image sensor. The image sensor may also include a color filter array.

Abstract: Provided is a light emitting device comprising an optical member provided on a light extracting surface side of a semiconductor light emitting element via a first light transmissive layer, wherein bonding surfaces of the semiconductor light emitting element and the first light transmissive layer are roughened surfaces, bonding surfaces of the first light transmissive layer and the optical member are flat, and the first light transmissive layer and the optical member are directly bonded.

Abstract: A method and an apparatus for detecting photons are disclosed. The apparatus includes a scintillator single crystal and an avalanche photodiode coupled to the scintillator single crystal. The scintillator single crystal is at a temperature greater than about 175° C. and at a shock level in a range from about 20 Grms to about 30 Grms. The scintillator single crystal includes a praseodymium doped composition selected from (LaxY1-x)2Si2O7:Pr, ABCl3-yXy:Pr, A2(Li,Na)LaCl6-yXy:Pr, or any combinations thereof. As used herein A is cesium, rubidium, potassium, sodium, or a combination thereof, B is calcium, barium, strontium, magnesium, cadmium, zinc, or a combination thereof, and X is bromine, iodine, or a combination thereof. Further, (0<x<1), and (0<y<3).

Abstract: An x-ray detecting apparatus having a housing, a detecting panel provided at an inside the housing as to detect x-rays, and a circuit board having a first surface thereof bordering with the detecting panel and a second surface thereof provided with at least one electronic component installed thereto is provided.

Abstract: An image pickup device includes: a first electrode film; an organic photoelectric conversion film; a second electrode film; and a metal wiring film electrically connected to the second electrode film, the first electrode film, the organic photoelectric conversion film, and the second electrode film all provided on a substrate in this order, and the metal wiring film coating an entire side of the organic photoelectric conversion film.

Abstract: Disclosed embodiments are related to a method of forming an elpasolite scintillator. In one nonlimiting embodiment, a method of forming an elpasolite scinitillator may comprise forming an elpasolite crystal from a nonstoichiometric melt.

Abstract: An enclosure for a radiographic device includes a bottom panel, a plurality of sidewalls integrally formed with the bottom panel, whereby the plurality of sidewalls and the bottom panel define a unitary body, and a top panel joined to the plurality of sidewalls and defining an internal space therebetween for housing a radiographic device.

Abstract: A device is for the spatially resolved measurement of photons, in particular x-ray photons. In an embodiment, the device includes a first plurality of photoelectric converters, a second plurality of current measuring apparatuses and a third plurality of voltage conditioners. Each current measuring apparatus is electrically connected to at least one photoelectric converter; each voltage conditioner is electrically connected to at least one current measuring apparatus; and each photoelectric converter is configured to generate a photocurrent from an incident photon. Each voltage conditioner is connectable to a supply bar, configured to provide a supply voltage. The voltage conditioner is configured to down-convert the supply voltage to an operating voltage of a current measuring apparatus. Each current measuring apparatus is configured to measure a photocurrent under operating voltage when this is generated in a photoelectric converter, electrically connected to the respective current measuring apparatus.

Abstract: A system of particle detectors can determine the location of a source without rotations or iterations. Embodiments of the system may include a middle detector flanked by two side detector panels, without shields or collimators. The middle detector may be positioned toward the front and orthogonal to the side detectors. By comparing a ratio of the detector data to a predetermined angular correlation function, the system can determine both the sign and magnitude of the source angle in real-time. Embodiments of the system can rapidly and automatically localize sources including industrial, medical, and other benign sources as well as nuclear and radiological weapons materials, whether in vehicles or cargo containers, and can provide improved sensitivity in walk-through personnel portal applications, enable enhanced detection of hidden weapons by a mobile area scanner, and enable a hand-held survey meter that indicates the radiation level as well as the location of the source of radiation.

Abstract: A method can include providing a scintillator structure. Providing the scintillator structure can include providing a scintillator support layer, providing a scintillator layer, and coupling the scintillator layer to the scintillator support layer. Meanwhile, the scintillator support layer has a substantially non-planar surface, the scintillator layer having a first surface and a second surface opposite the first surface and being configured to scintillate, and the first surface of the scintillator layer is coupled to the substantially non-planar surface of the scintillator support layer such that the second surface of the scintillator layer has a contour of the substantially non-planar surface of the scintillator support layer.

Abstract: A silicon photomultiplier array including a plurality of microcells arranged in rows and columns. A plurality of circuit traces connecting microcell output ports to the array pixel output port, with one or more impedance matching networks connected to at least one of the circuit traces. The impedance matching networks can be connected between each row circuit trace and the pixel output port. Impedance matching networks can be located between junctions of adjacent microcell output ports and row circuit traces.

Abstract: Disclosed are a scintillator using semiconductor quantum dots, a method of manufacturing the scintillator, and a digital image diagnostic system employing the scintillator. In one aspect, the scintillator includes a metallic reflection film made of a metal configured to transmit an X-ray and reflecting visible light and having a plurality of voids formed in a thickness direction. The scintillator also includes a polymer film formed inside the plurality of voids and being configured to include a plurality of columnar structures to convert the X-ray into the visible light. The scintillator further includes semiconductor quantum dots dispersed in the polymer film and having a decay time of tens of nanoseconds.