Abstract: A temperature-regulated radio frequency management system for use in a mass spectrometer is described. The temperature-regulated radio frequency management system having one or more radio frequency components disposed in a vacuum environment. The temperature-regulated radio frequency management system including a radio frequency detection circuit configured to provide feedback indicative of a radio frequency signal in one or more of the radio frequency components. In addition, the temperature-regulated radio frequency management system includes a temperature regulation circuit disposed in the vacuum environment and configured to reduce temperature-induced variations in the detection circuit.

Abstract: Field balancing may be performed with an irradiation system including a plurality of adjustable radiant-energy emitters. The irradiation system powers the radiant-energy emitters from a power source and radiant energy is emitted from the radiant-energy emitters, where an amount of radiant energy emitted from each emitter is capable of being varied based on power received from the power source. A plurality of radiant-energy sensors detects an amount of radiant energy which includes radiant energy created directly by at least one of the radiant-energy emitters. The amount of radiant energy detected at at least two of the radiant-energy sensors is compared, and at least one of the radiant-energy emitters is adjusted by varying the power received from the power source so that the amount of radiant energy detected at each of the radiant-energy sensors tends towards becoming approximately equal.

Abstract: A nuclear reactor fuel integrity monitor includes: a ?-ray detector which detects ?-ray of a specific radionuclide of a subject measurement medium of a nuclear reactor; a sample container which retains the subject measurement medium therein and surrounds the circumference of the ?-ray detector; and a measurement control device which performs a control so that a predetermined amount of the subject measurement medium is introduced into the sample container and calculates a concentration of the specific radionuclide from ?-ray data per each unit time detected by the ?-ray detector and a volume of the subject measurement medium introduced into the sample container.

Abstract: The present invention relates to a high-energy secondary electron detector comprising a collector P supporting only three electrodes that are insulated from one another and that are biased relative to the collector: a first repulsion electrode A1 for repelling charges of a first predetermined sign that are to be repelled, this negatively-biased electrode being provided with at least one opening for passing electrons; a second repulsion electrode A2 for repelling charges of the opposite sign that are to be repelled, this positively-biased electrode also being provided with at least one opening for passing electrons; and a selection electrode A3, this electrode also being provided with at least one opening for passing electrons; the openings in said electrodes being in alignment along a conduction cylinder D. Furthermore, the selection electrode A3 is negatively biased. The invention also provides a method of detecting secondary electrons by means of the detector.

Abstract: For examining objects, in particular for inspecting persons for suspicious items, devices having a scanning system for scanning the object and having an evaluating system are known. An optical marking system is provided, which indicates the position of an item classified as suspicious on the object itself or in a mirror image of the object by means of visible light.

Abstract: An active detector and methods for detecting molecules, including large molecules such as proteins and oligonucleotides, at or near room temperature based on the generation of electrons via field emission (FE) and/or secondary electron emission (SEE). The detector comprises a semiconductor membrane having an external surface that is contacted by one or more molecules, and an internal surface having a thin metallic layer or other type of electron emitting layer. The kinetic energy of molecules contacting the semiconductor membrane is transferred through the membrane and induces the emission of electrons from the emitting layer. An electron detector, which optionally includes means for electron amplification, is positioned to detect the emitted electrons.

Abstract: A three dimensional scanning beam system (100) and method (500) enable economical and efficient three dimensional scans of an environment. The system (100) includes a ranging apparatus (105), and a reactive linkage mechanism (110) having a first end (115) and a second end (120). The first end (115) is connected to the ranging apparatus (105) and the second end (120) is connected to an object (125) that moves the system (100) through an environment. In use acceleration of the object (125) with respect to the environment is converted by the reactive linkage mechanism (110) to motion of the ranging apparatus (105) with respect to the object (125), which increases the field of view of the ranging apparatus (105) with respect to the environment.

Abstract: A surface mountable radiation guide for a radiation path between a measurement volume (1) and an electro-optical component has a first radiation interface in a radiation path towards the measurement volume, a third radiation interface in a radiation path towards the electro-optical component, and a reflecting portion forming a first radiation path between the first and the third radiation interface, said first radiation path providing a focus region at the measurement volume.

Abstract: A CT system includes a rotatable gantry having an opening to receive an object to be scanned, the rotatable gantry having a detector mounting surface, an x-ray source attached to the gantry and configured to project an x-ray beam toward the object, a plurality of detector modules each mounted within one field-of-view (FOV) and mounted directly to the detector mounting surface of the rotatable gantry, a data acquisition system (DAS) configured to receive outputs from at least one of the plurality of detector modules, and a computer programmed to acquire projections of imaging data of the object from the DAS, and generate an image of the object using the imaging data.

Abstract: An air ion measuring apparatus (20) is used for measuring the amount of ions in ionized air generated by an ion generating apparatus (10) having a discharge electrode (11) and a nozzle (12) serving as a discharge electrode. The air ion measuring apparatus (20) has a cylindrical electrode (22), and when the length of the cylindrical electrode (22) is denoted by “l”, a flow rate of air which flows through the cylindrical electrode (22) is denoted by “U”, detection current which flows in the electrode 22 is denoted by “Im”, time constant is denoted by “?”, and the detection current “Im” is denoted by a current detector (33), current generated by passage of ion is calculated by I 0 = U ? ? ? + l l ? I m ? [ A ] , it is possible to measure the amount of ions from the calculated carried ion current “I0”, and to measure the amount of ions while splaying the ionized air to an object required to be electrically neutralized.

Abstract: A method for locally resolved measurement of a radiation distribution (24) produced using a lithography mask (16) comprises providing a radiation converter (31, 131) having an at least two-dimensional arrangement of converter elements (32, 132) which can respectively be put in an active and a passive state, and are configured to convert incoming radiation in respect of its wavelength in the active state. The method further includes: manipulating the radiation converter (31, 131) several times such that respectively only a fraction of the converter elements (32, 132) adopts the active state, irradiating the radiation converter (31, 131) with the radiation distribution (24) after every manipulation of the radiation converter (31, 131) so that the active converter elements (32, 132) emit wavelength-converted measuring radiation (34), recording respective places of origin (54) of the measuring radiation at every irradiation with the radiation distribution (24).

Abstract: A flat panel X-ray detector that comprises an X-ray panel and a scintillator layer disposed on a first surface of the X-ray panel, is disclosed herein. The flat panel X-ray detector further comprises a hermetic cover that covers the scintillator layer. The hermetic cover comprises a top surface and at least one sidewall extending away from the top surface. The flat panel X-ray detector further comprises a solder seal disposed between the hermetic cover and the X-ray panel. A rim of the sidewall is substantially embedded within the solder seal such that the rim does not directly contact the X-ray panel. A method for fabricating a flat panel X-ray detector is also disclosed.

Abstract: A fiber optic dosimeter probe for sensing radiation dose including an optical fiber having a free end and a sensitive end, a window having a sensitive side and a rear side; a radiation sensitive layer between the sensitive end of the optical fiber and a sensitive side of the window, the radiation sensitive layer being made of a material having an optical property that changes with absorbed radiation dose, an amount of the material corresponding to a predetermined sensitivity to radiation; wherein the window and the optical fiber have a near water equivalent interaction with radiation and are MR compatible.

Abstract: A photon counting detector and a photon counting and detecting method using the same is provided. The photon counting detector includes readout circuits configured to count photons in multi-energy radiation incident to a sensor, the photons being counted with respect to each of a plurality of energy bands of the multi-energy radiation, the readout circuits respectively corresponding to pixels of a region onto which the multi-energy radiation is irradiated, each of the readout circuits being configured to count photons in a predetermined one of the energy bands, at least one of the readout circuits being configured to count photons in at least one of energy bands other than the predetermined one of the energy bands.

Abstract: (EN) A system (MSY) for measuring an electromagnetic field comprises an antenna device disposed on a plane (AB1). The antenna device is arranged to provide a pa it of signals representative of a pair of orthogonal components of the electromagnetic field. A printed circuit (PT1) for signal transmission is orthogonally disposed with respect to the plane (AB1) on which the antenna device is disposed. The printed circuit (PT1) comprises a transmission line coupled to the antenna device to transmit the pair of signals provided by the antenna device towards a measurement module.

Abstract: A detector device detects the penetration depth of a particle beam applied to a target volume. The detector device includes a first detection device and a second detection device. The second detection device is configured to detect photons that are formed in the target volume and is disposed behind the first detection device with respect to a direction of the particle beam.

Abstract: A smart device “plug-in” radiation module(s) and/or methods are described wherein the bulk of non-sensor radiation circuitry is off-loaded to the smart device. By attaching the radiation module to the smart device via a power/communication port (for example, the smart device's headphone/microphone jack) robust attachment can be achieved as well as uniformity of attachment across different smart devices. A very small radiation module form factor is obtainable, not to mention a very significant cost reduction, allowing widespread adoption of radiation detectors as well as radiation geo-mapping. Power for the radiation module can be obtained from the smart device's headphone plug, utilizing the audio out (speaker) signal's power. Similarly, input to the smart device can be facilitated via the audio in (microphone) signal. Further, output of the radiation module can be visualized on the smart device, as well as control functions.

Abstract: An electromagnetic wave transmission filter may include a substrate and one or more coils. The one or more coils may be at least partly disposed in an opening through the substrate. An electromagnetic camera may include an electromagnetic wave detector array, including a plurality of detector cells for detecting electromagnetic waves, and an electromagnetic wave transmission filter disposed in front of the electromagnetic wave detector array to provide each of the detector cells with an electromagnetic wave of a certain wavelength. The electromagnetic wave transmission filter may includes a substrate and a plurality of coils. At least one of the plurality of coils may be at least partly disposed in each of a plurality of openings through the substrate.

Abstract: A portable x-ray detector is disclosed that includes an x-ray detecting member and a user removable electromagnetic interference (EMI) shielding member. The user removable EMI shielding member is positioned to at least partially magnetically shield the x-ray detecting member of the portable x-ray detector by redirecting an impinging magnetic field around the x-ray detecting member. The user removable EMI shielding member includes a first magnetic shielding layer, a second magnetic shielding layer, and an intervening material, other than the x-ray detecting member, between the first magnetic shielding layer and the second magnetic shielding layer.

Abstract: The present disclosure relates approaches for removing or reducing the effects of motion in parallel and non-parallel data acquisitions using a nuclear medicine imaging system. In certain embodiments, translation vectors are derived based on a registration performed on transaxial slices generated from the acquired projection data. The translation vectors may be employed to update a system matrix such that images generated using the updated system matrix are free or motion artifacts or have reduced motion artifacts.

Abstract: A glass pane (1) has an inner side (6) and an outer side (5) and a detector (10) located on the inner side (6) for electromagnetic radiation which, coming from the outer side (5), passes through the glass pane (1) and can be detected by means of the detector. The glass pane (1) is a composite pane, in particular a glass pane of composite safety glass of a motor vehicle, with an inner pane (3) and an outer pane (2), which are joined to each other with the aid of a film (4) arranged between the inner pane (3) and the outer pane (2). In order also to obtain a sufficient intensity of the electromagnetic radiation passing through the glass pane (1) and detectable by the detector (10) in glass panes with a small transmission coefficient, it is proposed that the beam path of the electromagnetic radiation leading to the detector (10) penetrate only the material of the outer pane (2) and pass through the plane of the inner pane (3) in the region of a continuous hole (7).

Abstract: A mechanical device for supporting and attaching at least one ionizing radiation detection probe. For each detection probe it includes one probe-holder ending in a collimator-holder able to support a collimator intended to delimit a field of observation of the detection probe, and an attachment device intended to be attached to a glove port of a glove box, where the probe-holder, or each probe-holder, cooperates with the said attachment device.

Abstract: A quantum efficiency measurement method includes the steps of: disposing a sample at a predetermined position in an integrator having an integrating space; applying excitation light to the sample and measuring a spectrum in the integrating space as a first spectrum through a second window; configuring an excitation light incident portion so that excitation light after having passed through the sample is not reflected in the integrating space; applying the excitation light to the sample and measuring a spectrum in the integrating space as a second spectrum through the second window; and calculating a quantum efficiency of the sample based on a component constituting a part of the first spectrum and corresponding to a wavelength range of the excitation light, and a component constituting a part of the second spectrum and corresponding to a wavelength range of light generated by the sample from the received excitation light.

Abstract: An apparatus for simultaneous detection of backscattered electrons and photons from a sample. The device includes a direct detection backscattered electron detector and a photon detector. The backscattered electron detector has a reflective surface that reflects photons emitted by the sample onto the photon detector.

Abstract: A novel detector tube structure (such as for a neutron detection tube) and method of manufacture are described. The novel manufacturing process carries out the electron scrubbing of the detection surface/material after the container enclosure has already been sealed. In this manner, much of the complex manufacturing equipment typically associated with such detection tubes can be eliminated and large numbers of detectors may be manufactured at the same time. The present invention therefore involves a novel detector tube structure and a new method of manufacture for the same.

Abstract: A portable radiographic imaging device including: a radiation detection panel including optoelectric conversion elements that convert irradiated radiation into an electrical signal; a signal processing substrate performing predetermined signal processing on the input electrical signal; a holding base provided between the radiation detection panel and the signal processing substrate and holding the signal processing substrate; a flexible substrate including a flexed portion, with one end of the flexible substrate being connected to the radiation detection panel and the other end of the flexible substrate being connected to the signal processing substrate; a casing in which the radiation detection panel, the signal processing substrate, the holding base and the flexible substrate are installed; and a contact avoidance portion formed at at least one of the signal processing substrate, the holding base or the casing such that contact of with the flexible substrate is avoided, is provided.

Abstract: An apparatus for detecting a position by infrared rays is disclosed. The apparatus includes a plurality of IR sources, a plurality of receivers and a processor electrically coupled to the receivers. The IR sources and the receivers are interlacedly configured along a frame. The IR sources emit IR signals in at least two dimensions, and the IR sources in each dimension comprise two sets of IR signals running contrarily in direction. The receivers receive the IR signals from the corresponding IR sources. Even if the IR signals in one direction of one dimension are subject to interference, the IR signals in the other direction of the dimension can still be measured by the corresponding receivers. When at least one object is set in at least one position within the frame, the processor determines the position according to the coordinates of the receivers and strength variations of the received IR signals.

Abstract: According to example embodiments, an image sensor includes a charge sensing amplifier configured to amplify charges sensed by a sensing unit. The charge sensing amplifier includes an input terminal, an amplification terminal, an output terminal, a first capacitor connected between the input terminal and the amplification terminal, a first switch connected between the input terminal and the amplification terminal, a second capacitor connected between the amplification terminal and the output terminal, and a second switch connected between the output terminal and a reference voltage terminal.

Abstract: A detection apparatus includes a conversion element; a transistor which includes a semiconductor layer including a first channel region and a second channel region, a first gate electrode, and a second gate electrode; a first drive wiring which is connected to the first gate electrode; a second drive wiring which is connected to the second gate electrode; a first conduction voltage supply unit which supplies the first conduction voltage to the first driving wiring; a second conduction voltage supply unit which supplies the second conduction voltage to the second driving wiring; and a selection unit which selects any one of a first connection between the second drive wiring and the first conduction voltage supply unit and a second connection between the second drive wiring and the second conduction voltage supply unit.

Abstract: An electrode for an ionization chamber and an ionization chamber including an electrode are provided wherein the electrode comprises a substrate comprising a first material, and a plurality of nanowires extending from the substrate and manufactured by processing the first material of the substrate.

Abstract: A measurement system for use in radiation therapy, for example for measuring radiation sources, in particular for a water phantom. The water phantom has a water container and a measurement system, on which at least one holder for a radiation detector is arranged. The holder can be moved within the water container along at least one movement axis, with a control unit being present, which accepts and executes commands for controlling the movement axis. A virtual coordinate system which is aligned to the water surface is defined so that the movement device does not have to be aligned with great complexity. A conversion unit transfers control commands from the virtual coordinate system into the real coordinate system of the movement device so movements of the holder are always parallel and/or perpendicular to the water surface.

Abstract: An apparatus for monitoring an ion distribution of a wafer comprises a first sensor and a sensor. The first sensor, the second sensor and the wafer are placed in an effective range of a uniform ion implantation current profile. A controller determines the ion dose of each region of the wafer based upon the detected signal from the first sensor and the second sensor. In addition, the controller adjusts the scanning frequency of an ion beam or the movement speed of the wafer to achieve a uniform ion distribution on the wafer.

Abstract: A trigger signal generation device restrains a jitter from being generated in a measurement result of light, such as terahertz light, that has transmitted through a device under test. The device includes a first photoelectric conversion unit that applies photoelectric conversion to a probe light pulse, a second photoelectric conversion unit that applies photoelectric conversion to a pump light pulse, a first amplification unit that amplifies an output from the first photoelectric conversion unit, and a second amplification unit that amplifies an output from the second photoelectric conversion unit. The device also includes a trigger signal output unit that outputs a cross-correlation of outputs of the first amplification unit and the second amplification unit as a trigger signal, and a period difference adjustment unit that adjusts a difference in periods.

Abstract: A system for investigating a plurality of samples having varying positions or orientations moving with respect to the system, the system including an emitter of terahertz radiation for irradiating a sample provided in a sample space; a detector of terahertz radiation configured to detect radiation reflected from said sample space; and determining means to determine if radiation reflected from said sample space is from a sample with a predetermined orientation in the sample space.

Abstract: A first intensity Az expressed as Az=az×E?, a first reference intensity A0 expressed as A0=a0×E?, a second intensity Bz expressed as Bz=bz×E, and a second reference intensity B0=b0×E, are evaluated. The first intensity and the first reference intensity are of radioactive nuclides generated by a neutron capture reaction of a heavy nuclide or a fission product nuclide. The second intensity and the second reference intensity are of radioactive fission product nuclides except nuclides generated by a neutron capture reaction. The reference intensities are measured where the void fraction is known. Also a correlation curve of (az/a0) and a void fraction is evaluated. Finally an axial void fraction distribution is evaluated based on the value of (az/a0) and the correlation curve.

Abstract: An airborne/spaceborne oil spill detection method includes the step of providing a moderate-resolution-imaging-spectroradiometer and sensing the spectral reflections from two optical bands one of which is in the near infrared range. The spectral contrast shift from two adjacent areas of water are calculated and a warning issued when an oil spill or other contaminant is detected. A system for detecting an oil spill or other contaminant on the surface of water is also disclosed.

Abstract: The invention relates to a charged particle detector system comprising a conversion plate (110) to convert incoming radiation to secondary electrons. These secondary electrons are then detected by a secondary electron detector (120), thereby providing information of the incoming radiation. Often this information is limited to, in first approximation, the flux of incoming radiation. In the case of, for example, backscattered electrons this is the current of the incoming backscattered electrons. The invention proposes to form the conversion plate as, for example, an energy dependent detector, for example a photodiode to detect electrons, so that the detector system simultaneously provides information of, for example, current (S1) and mean energy (S2) of the incoming radiation. The detector system is especially suited for use in a SEM or a DualBeam apparatus.

Abstract: An X-ray detecting apparatus for the detection and localisation of ionising X-ray or gamma radiation in radiography, the apparatus comprising: an X-ray detector including: conversion means for converting incident x-ray photons of an incident x-ray photon beam into detectable electrical charges; and amplification means for amplifying the electrical charges in the detector by an non-linear amplification gain factor the non-linear amplification gain being characterised by a decrease in amplification gain at high fluxes of incident x-ray photons; and amplification gain adjustment means configured to vary the amplification gain of the amplification means according to the emission parameters of an x-ray source providing the incident x-ray photon beam for the radio-graphic examination to be performed and/or the transmitted beam received by the detector from the x-ray source via the subject being imaged. A radiographic imaging device and a method of operating the radiographic imaging device are also presented.

Abstract: A tumor treatment apparatus may include an array of collimated CZT detectors configured to intersect a known coordinate and measure gamma radiation activity, for example at 511 keV. A radiation delivery system may be configured to direct radiation through the known coordinate on the basis of the gamma radiation activity. A translatable and rotatable table may be configured to support a tumor host, wherein the tumor is positionable relative to the known coordinate on the basis of the gamma radiation activity emitted by the tumor and measured by the array of collimated CZT detectors. Radiation from the radiation delivery system may be delivered to the tumor at the known coordinate, and may be delivered in an intra-operative surgical environment.

Abstract: A sensor-location system for locating sensors in a tract covered by an earth-based sensor network. The sensor-location system includes at least one sensor-identification device, and at least one sensor locator. The sensor-identification device is affixed to a respective sensor in the earth-based sensor network. The sensor locator is configured for use from on board of an aircraft. In addition, the sensor locator is configured to acquire geographic-location data of said sensor including an identifying signature from the sensor-identification device of the sensor in the tract covered by the earth-based sensor network.

Abstract: Digital images or the charge from pixels in light sensitive semiconductor based imagers may be used to detect gamma rays and energetic particles emitted by radioactive materials. Methods may be used to identify pixel-scale artifacts introduced into digital images and video images by high energy gamma rays. Statistical tests and other comparisons on the artifacts in the images or pixels may be used to prevent false-positive detection of gamma rays. The sensitivity of the system may be used to detect radiological material at distances in excess of 50 meters. Advanced processing techniques allow for gradient searches to more accurately determine the source's location, while other acts may be used to identify the specific isotope. Coordination of different imagers and network alerts permit the system to separate non-radioactive objects from radioactive objects.

Abstract: The invention features a method including: (i) providing spectrally resolved information about light coming from different spatial locations in a sample comprising deep tissue in response to an illumination of the sample, wherein the light includes contributions from different components in the sample; (ii) decomposing the spectrally resolved information for each of at least some of the different spatial locations into contributions from spectral estimates associated with at least some of the components in the sample; and (iii) constructing a deep tissue image of the sample based on the decomposition to preferentially show a selected one of the components.

Abstract: Disclosed is a radiation imaging device configuring a radiation imaging system. Specifically disclosed is a radiation imaging device wherein external force action mechanisms are capable of applying external force to the peripheral sections of a radiation conversion panel, or applying the external force while being laminated on the radiation conversion panel, or pressing the radiation conversion panel against the inner wall of a panel containing unit, which contains the radiation conversion panel, at least in imaging when radiation is applied.

Abstract: A network for power transmission to a receiver that converts the power into current includes a first node for transmitting power wirelessly in a first area. The first area has a minimum electric or magnetic field strength. The network includes a second node for transmitting power wirelessly in a second area. The second area has a minimum electric or magnetic field strength and overlaps the first area to define an overlap area. In another embodiment, the network includes a source in communication with the first and second nodes which provides power to them. Also disclosed are methods for power transmission to a receiver that converts the power into current.

Abstract: A device for a radiation detector includes a main body, which includes a material G and is at least partially provided with a coating. The coating has at least a first layer with a material A1. The material G of the main body can be excited by a primary radiation impinging on the coating, so that an x-ray fluorescence radiation is produced with an x-ray fluorescence spectrum, which has a maximum MG at an energy EG. Furthermore, at an energy E1, the material A1 has an absorption edge. In this case, the material A1 is chosen such that the relationships E1<EG and EG?E1?4 keV apply. Also specified is a radiation detector, which has the device and a detector element, which is suitable for the detection of the primary radiation.

Abstract: A counting detector is disclosed. In at least one embodiment, the counting detector includes sensors for converting radiation quanta into electrical pulses and an evaluation unit with a number of energy thresholds, wherein the evaluation unit generates for each sensor a count value for each energy threshold from the pulses, which count value represents the number of radiation quanta with an energy above the respective energy threshold. In at least one embodiment, one of the energy thresholds is arranged directly above a characteristic energy of radiation quanta causing double counting in order to correct double counting; and a correction unit calculates a corrected count value from the count values of the energy thresholds, which corrected count value has reduced double counting for at least one of the energy thresholds. Images with an improved contrast-to-noise ratio and, at the same time, a reduced X-ray dose can be generated on the basis of the at least one corrected count value.

Abstract: An Aharonov-Bohm (AB) sensor is provided. The AB sensor includes a beam splitter configured to split a first electron beam into a first wave and a second wave. The beam splitter is configured to direct the first wave along a first path through a field-free cage. A phase of the first wave is configured to shift in response to a vector potential of a signal. The vector potential is present within the field-free cage. The AB sensor includes a beam combiner configured to combine the phase shifted first wave with the second wave to generate a second electron beam, which is modulated based on the phase shift of the first wave. The AB sensor includes a detector configured to receive the second electron beam and to detect the signal based on the modulation of the second electron beam.

Abstract: A bolometer comprising an outer surface for the thermal absorption of incident radiation in thermal contact with a radiation measurement element having a variable resistance (R) depending on the temperature, the element being in a heat feedback loop comprising a corrector for applying a heating power to a resistive heating means in order to maintain the temperature of the resistor equal to a setpoint temperature (Tref). According to the invention, the resistive heating means comprises the element, the corrector is designed to generate a frequency component (S1) of the heating power, which is applied to a coupling means provided between the element and the corrector in order to apply a DC-free signal to the element, a coupling means, separate from the means, is provided between the element and a DC bias means in order to maintain the resistor at a prescribed continuous operation point.

Abstract: A method of fabricating a mixed ionic-electronic conductor (e.g. TlBr)-based radiation detector having halide-treated surfaces and associated methods of fabrication, which controls polarization of the mixed ionic-electronic MIEC material to improve stability and operational lifetime.

Abstract: A gamma ray detector includes a gamma ray detecting rod elongated along a longitudinal axis, wherein gamma ray detection is enhanced along the longitudinal axis, and a gamma ray shield encapsulating the rod, the shield having an aperture at an end of the detecting rod along the longitudinal axis to admit gamma rays substantially parallel to the longitudinal axis of the elongated detecting rod, wherein gamma ray detection is enhanced along the longitudinal axis and aperture to substantially collimate the sensitivity of the gamma ray detector along the combined aperture and longitudinal axis of the detecting rod.