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.

Mixed halide scintillation materials of the general formula AB.sub.(1−y)M.sub.yX′.sub.wX″.sub.(3−w), where 0≤y≤1, 0.05≤w≤1, A may be an alkali metal, B may be an alkali earth metal, and X′ and X″ may be two different halogen atoms, and of the general formula A.sub.(1−y)BM.sub.yX′.sub.wX″.sub.(3−w), where 0≤y≤1, 0.05≤w≤1, A maybe an alkali metal, B may be an alkali earth metal, and X′ and X″ are two different halogen atoms. The scintillation materials of formula (1) include a divalent external activator, M, such as Eu.sup.2+ or Yb.sup.2+. The scintillation materials of formula (2) include a monovalent external activator, M, such as Tl.sup.+, Na.sup.+ and In.sup.+.

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 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.

Compositions of matter, downconversion layers including the compositions of matter, and devices including the compositions of matter are described. In an embodiment, the compositions of matter are downconversion materials configured to absorb a quantum of energy of a first energy and, in response, emit two or more quanta of energy of a second energy less than the first energy. Methods of making and depositing downconversion materials are also described. Downconversion precursor mixtures suitable for making downconversion materials and methods of making the same are also described.

A wireless optogenetic device in proximity to a neural cell of a subject includes a body configured to hold light transducing materials arranged to up-convert electromagnetic radiation in infrared or near-infrared spectrum into light in the visible spectrum to affect activity of the neural cell. The body allows electromagnetic radiation in infrared or near-infrared to reach the light transducing materials. A radiation system includes a radiation probe for irradiating a wireless optogenetic device with electromagnetic radiation in infrared or near-infrared spectrum from a radiation source. The system further includes a movement mechanism for moving the radiation probe, a detector for detecting a location of the wireless optogenetic device, and a controller for controlling the movement mechanism based on the detected location of the wireless optogenetic device such that the radiation probe is arranged to irradiate the wireless optogenetic device at the detected location with the electromagnetic radiation.

The present disclosure features a luminescent solar concentrator, including a layer including a quantum-cutting material; and a layer including a broadly light-absorbing material (that is also photoluminescent) optically coupled to and beneath the layer including the quantum-cutting material, relative to a light source.

The present invention relates to the field of luminescent crystals (LCs), and more specifically to Quantum Dots (QDs) of formula A.sup.1.sub.aM.sup.2.sub.bX.sub.c, wherein the substituents are as defined in the specification. The invention provides methods of manufacturing such luminescent crystals, particularly by dispersing suitable starting materials in the presence of a liquid and by the aid of milling balls; to compositions comprising luminescent crystals and to electronic devices, decorative coatings; and to components comprising luminescent crystals.

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.

Described herein are phosphor-containing ink compositions for disinfecting surfaces and improving the photostability of synthetic polymers. Methods for preparing the ink compositions are additionally described.