Disclosed are a yttrium-doped barium fluoride crystal and a preparation method and the use thereof, wherein the yttrium-doped barium fluoride crystal has a chemical composition of Ba.sub.(1−x)Y.sub.xF.sub.2+x, in which 0.01≤x≤0.50. The yttrium-doped BaF.sub.2 crystal of the present invention has improved scintillation performance. The yttrium doping may greatly suppress the slow luminescence component of the BaF.sub.2 crystal and has an excellent fast/slow scintillation component ratio. The doped crystal is coupled to an optical detector to obtain a scintillation probe which is applicable to the fields of high time resolved measurement radiation such as high-energy physics, nuclear physics, ultrafast imaging and nuclear medicine imaging.

A detector array (112) includes a detector pixel (206). The detector pixel includes a three dimensional cavity (304 and 306; 432 and 404) having walls (308/602 and 316; 434 and 406/502) that include active regions, which detect light photons traversing within the three dimensional cavity and produce respective electrical signals indicative thereof. The detector pixel further includes a first scintillator (320; 410) disposed in the three dimensional cavity adjacent to a bottom (320; 416) of the at least one detector pixel. The detector pixel further includes a second scintillator (326; 444) disposed in the three dimensional cavity on top of the first scintillator, wherein the first and second scintillators emits the light photons in response to absorbing x-ray photons. At least one of the walls is vertically oriented with respect to detector pixel, maximizing contact area between a corresponding active region and one of the first or second scintillators.

Methods and apparatus for calibrating radioactive sources are described. An array of scintillation detectors form a receptacle within which a sample or sample container can be retained by a holder. The scintillation detectors are coupled via light transducers such as photomultiplier tubes (PMTs) to independent electronic counters. Coincidence processing of time-tagged events yields a correlated cent rate. One or more corrections can be applied as needed, for background counts, deadtime, or random coincidences. Voltage tuning of PMTs yields improved reproducibility. Variations are disclosed. 1% accuracy has been demonstrated over a range N of 10 kBq-3 MBq, covering a gap in the capabilities of conventional technology.

The invention relates to a scintillator array for a radiation imaging detector. A method for manufacturing the scintillator array, a radiation imaging detector, and a medical imaging system are also provided. The scintillator array has a radiation receiving face and an opposing scintillation light output face. The scintillator array includes a plurality of scintillator elements and a separator material that is disposed between the scintillator elements. The separator material consists of separator particles that have a predetermined size and with this the separator material provides an optical separation of the scintillator elements by providing a physical spacing between the scintillator elements, the width of which spacing is defined by the separator particle size.

The present invention includes: a radiation detecting unit including a fluorescent body expressed by the formula ATaO.sub.4: B, C (in the formula, A is selected from at least one kind of element from among rare-earth elements involving 4f-4f transitions, B is selected from at least one kind of element, different from A, from among rare-earth elements involving 4f-4f transitions, and C is selected from at least one kind of element from among rare-earth elements involving 5d-4f transitions); an optical fiber that transmits photons generated by the fluorescent body; a light detector that converts the photons transmitted via the optical fiber 3 one by one into electrical pulse signals; a counter that counts the number of electrical pulse signals converted by the light detector; an analysis and display device 6 that obtains a radiation dose rate on the basis of the number of electrical pulse signals counted by the counter.

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.

Disclosed are a ray converter and a ray detection panel device. The ray converter (100, 100′) includes a substrate (110) and a conversion body (120). The substrate (110) includes a medium carrier. The medium carrier has a mesoporous structure distributed in an array. A pore of the mesoporous structure extends from an entrance end of the substrate (110) to an exit end of the substrate (110). The conversion body (120) is filled in the pore. The ray detection panel device includes a ray converter (100, 100′) and a light sensor.

A radiation detection module according to an embodiment includes: an array substrate including multiple photoelectric converters; a scintillator provided on the multiple photoelectric converters; a sealing part that has a frame shape, is provided around the scintillator, is bonded to the array substrate and the scintillator, and includes a thermoplastic resin as a major component; and a moisture-resistant part covering the scintillator from above, in which a peripheral edge vicinity is bonded to an outer surface of the sealing part. The shape of the outer surface of the sealing part is a curved surface protruding outward.

A method and apparatus for testing the response of protective headgear 104 to impact forces. A high-speed cineradiography imaging system 100 is used to obtain full-field, time-resolved internal monitoring and measurement of headgear component (pads 140 and liners 142) deformation and interaction with a head surrogate (headform 102), deformation of headform components, and stress and strain transfer into the headform. Radiopaque contrast materials (144 & 148) and integration techniques are used to highlight specific regions of interest within the headgear and headform components during the impact loading events.

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.