Hybrid material for plastic scintillation measurement comprising: a polymeric matrix; and a fluorescent mixture incorporated in the polymeric matrix and comprising, with respect to the total number of moles of primary fluorophore in the incorporated fluorescent mixture, i) from 95.6 molar % to 99.6 molar % of a main primary fluorophore consisting of naphthalene and ii) from 0.4 molar % to 20 molar % of an additional primary fluorophore. The decay constant of the fluorescence of the hybrid material is intermediate between that of a fast plastic scintillator material and of a slow plastic scintillator material. Further, they can be chosen over a wide range. The invention also relates to an associated part, device and item of equipment, to their processes of manufacture or their methods of measurement.

Embodiments of composite scintillators which may include a scintillator material encapsulated in a plastic matrix material and their methods of use are described.

A scintillator system is disclosed for detecting incoming radiation. The system makes use of a scintillator structure having first and second dissimilar materials. The first dissimilar material emits a first color of light and the second dissimilar material emits a second color of light different from the first color of light. Either one, or both, of the first or second colors of light are emitted in response to receipt of the incoming radiation. A plurality of light detectors is disposed in proximity to the scintillator structure for detecting the first and second different colors of light and generating output signals in response thereto. A detector electronics subsystem is responsive to the output signals and provides an indication of colors emitted by the scintillator structure to infer at least one property of the incoming radiation.

A scintillator array includes: a structure having scintillator segments and a first reflective layer, the first reflective layer being provided between the scintillator segments and being configured to reflect light, and the scintillator segments having a sintered compact containing a rare earth oxysulfide phosphor; and a layer having a second reflective layer provided above the structure, the second reflective layer being configured to reflect light. The first reflective layer has a portion extending into the layer.

The present invention is a passive sensor to detect ionizing radiation over time. It employs a SAW sensor that incorporates a polymer film that deforms based on the chain-scission reaction as described upon irradiation. The polymer film coats the piezoelectric substrate and reflectors on the SAW sensor and, as it reacts to radiation, the film deforms due to the fracturing of the polymer molecules resulting in a loss of overall mass. As the SAW sensor is interrogated by an electrical signal, the wavelength of the response will change as the overall rigidity of the polymer film changes allowing for the detection of the level of radiation.

An ink for forming a scintillator product includes a phenylated siloxane polymer having at least one functional group per molecule for crosslinking, a filler having a refractive index about matching a refractive index of the phenylated siloxane polymer, where the refractive indices are within about 5% of one another, a rheology modifier, and at least one fluorescent dye.

A scintillator material includes a polymer matrix, a primary dye in the polymer matrix, the primary dye being a fluorescent dye; a secondary dye, and a Li-containing compound in the polymer matrix, where the Li-containing compound is a Li salt of a short-chain aliphatic acid. In addition, the scintillator material exhibits an optical response signature for thermal neutrons that is different than an optical response signature for fast neutrons.

A luminescent material can include an element or an interstitial site that provides a hole trap in the luminescent material; a first dopant that provides a first electron trap in the luminescent material; and a second dopant that provides a second electron trap in the luminescent material, wherein the second dopant is a relatively shallower electron trap as compared to the first dopant. In an embodiment, a ratio of the first dopant to the second dopant is in a range of 10:1 to 100:1 on an atomic basis. In another embodiment, a ratio of the first dopant to the second dopant is selected so that luminescent material has a lower average value for a departure from perfect linearity in a range of 5 keV to 20 keV that is less to other luminescent materials of the same base compound. The luminescent material may not be a rare earth halide.

A storage phosphor panel can include an extruded inorganic storage phosphor layer including a thermoplastic polymer and an inorganic storage phosphor material, where the extruded inorganic storage phosphor panel has an image quality comparable to that of a traditional solvent coated inorganic storage phosphor screen. Further disclosed are certain exemplary method and/or apparatus embodiments that can provide inorganic storage phosphor panels including reduced noise. Further disclosed are certain exemplary method and/or apparatus embodiments that can include inorganic storage phosphor layer including at least one polymer, an inorganic storage phosphor material, and a copper phthalocyanine based blue dye.

Provided are a scintillator panel and an X-ray detector which have high sensitivity and sharpness. The scintillator panel includes a substrate and a scintillator layer containing a binder resin and a phosphor, wherein the scintillator panel further contains an organic compound having the maximum peak wavelength of light emission in the wavelength region of from 450 to 600 nm.