A luminescent component includes a first element comprising a first solid polymer composition, wherein the first solid polymer composition includes first luminescent crystals, wherein the first luminescent crystals are of the perovskite structure, and are selected from compounds of formula (I): M.sup.1.sub.aM.sup.2.sub.bX.sub.c, wherein M.sup.1 represents Cs, optionally doped with up to 30 mol % of one or more other metals having coordination number 12, M.sup.2 represents Pb, optionally doped with up to 30 mol % of one or more other metals having coordination number 6, X independently represents anions selected from the group consisting of Cl, Br, I, cyanide, and thiocyanate. The first luminescent crystals are of size between 3 nm and 3000 nm, and emit light of a first wavelength in response to excitation by light with a wavelength shorter than the first wavelength. An encapsulation including a polymer or an inorganic matrix encloses the first element.

The present invention discloses a nitrogen-containing luminescent particle, characterized in that a structure of the nitrogen-containing luminescent particle is divided into an oxygen poor zone, a transition zone, and an oxygen rich zone from a core to an outer surface of the particle depending on an increasing oxygen content, the oxygen poor zone being predominantly a nitride luminescent crystal or oxygen-containing solid solution thereof, the transition zone being predominantly a nitroxide material, the oxygen rich zone being predominantly an oxide material or oxynitride material; the nitride luminescent crystal or oxygen-containing solid solution thereof has a chemical formula of M.sub.m-m1A.sub.a1B.sub.b1O.sub.o1N.sub.n1:R.sub.m1, the nitroxide material has a chemical formula of M.sub.m-m2A.sub.a2B.sub.b2O.sub.o2N.sub.n2:R.sub.m2, the oxide material or oxynitride material has a chemical formula of M.sub.m-m3A.sub.a3B.sub.b3O.sub.o3N.sub.n3:R.sub.m3. The nitrogen-containing luminescent particle and the nitrogen-containing illuminant of the present invention have good chemical stability, good aging and light decay resistance, and high luminescent efficiency, and are useful for various luminescent devices. The manufacturing method of the present invention is easy and reliable, and useful for industrial mass production.

This application relates to a light conversion device and a display device.

Embodiments of the present invention relate to a phosphor plate and a lighting device including the phosphor plate, the phosphor plate according to an embodiment of the present invention has a light incident region on which light generated from a light source is incident and a light emitting region which converts a wavelength of the incident light and then outputs the light, wherein a ratio of a diameter of the light incident region and a diameter of the light emitting region ranges from 1:3 to 1:9.

A wavelength conversion device includes a wavelength conversion element configured to convert at least a part of incident excitation light into converted light having a wavelength different from a wavelength of the excitation light and emit the converted light and a substrate connected to the wavelength conversion element in a crossing direction crossing an incident direction of the excitation light on the wavelength conversion element and configured to radiate heat transferred from the wavelength conversion element. A dimension of the substrate along the incident direction is larger than a dimension of the wavelength conversion element along the incident direction.

Lighting system including mounting body, lever-locking bracket, and lighting module. Mounting body has first end spaced apart along longitudinal axis from second end. Lever-locking bracket includes bracket body and lever actuator. Lever-locking bracket is pivotally connected with first end of mounting body by flange retained in alignment with aperture of mounting body communicating with cavity inside mounting body. Lighting module has semiconductor light-emitting device in housing, and has mounting arm pivotally connected with lever-locking bracket by first pivot joint for rotation of lighting module to plurality of primary positions around first pivot axis. Flange of the lever-locking bracket forms part of second pivot joint for rotation of lighting module to plurality of secondary positions around second pivot axis. Lever-locking bracket is configured for simultaneously locking lighting module at primary position and secondary position by movement of lever actuator from an unlocked position to locked position.

Disclosed are an optical member and a display device having the same. The optical member includes a first substrate, a plurality of wavelength conversion parts provided on the first substrate while being spaced apart from each other, and a sealing layer on a top surface of the wavelength conversion parts and at a lateral side of the wavelength conversion parts. Each of the wavelength conversion parts includes a host on the first substrate, and a plurality of wavelength conversion particles in the host.

The invention relates to an arrangement (100) comprising a lighting system (110) and a target object (120), wherein the lighting system (110) is arranged to illuminate a target surface of the target object (120) with a primary light output (111) and with a secondary light output (112). Each of these light outputs has an illumination spectrum representing a color. The two illumination spectra are different, but the two colors are substantially the same. The target surface has a first target surface area and a second target surface area. When the first and second target surface areas are illuminated with the primary light output (111), they have a contrast that is lower than when they are illuminated with the secondary light output (112). The arrangement of the invention can be used for atmosphere creation or for attracting attention to the target object (120).

In order to suppress the chromaticity shift and corrosion associated with the deterioration of a sulfide phosphor particle, this phosphor sheet is produced using a phosphor particle-containing resin composition which comprises: covered phosphor particles; polymerizable compound; and a polymerization initiator. The covered phosphor particles are obtained by covering phosphor particles with silicon dioxide films, wherein among the phosphor particles, at least sulfide phosphor particles are covered with silicon dioxide films that contain a metal oxide powder. Thus, the phosphor sheet can be inhibited from emitting a sulfur-based gas, and exhibits a minimized chromaticity shift, even when the phosphor sheet is present in such a manner that the edge of the phosphor layer of the sheet is in an exposed state.

A vehicle tailgate includes a substrate operable between open and closed positions and defining an inboard surface, an outboard surface and a top surface. A light assembly is positioned on the substrate. A first lens is positioned over the inboard surface and the top surface. A second lens is positioned over the top surface and the outboard surface. A plurality of light sources is positioned between the substrate and the first and second lenses.