Abstract: Disclosed is a wavelength conversion member that is provided with: a light transmissive member including a light input plane into which excitation light is inputted, and a light output plane from which wavelength converted light is outputted; and a semiconductor fine particle phosphor, which is dispersed in the light transmissive member, and which absorbs the excitation light, converts the wavelength, and emits light. The dispersion concentration of the semiconductor fine particle phosphor in the direction parallel to the light traveling direction, i.e., the direction connecting the light input plane and the light output plane, is lower than the dispersion concentration of the semiconductor fine particle phosphor in the direction orthogonal to the light traveling direction.

Abstract: A fluorescent material-sealed sheet includes a plurality of fluorescent sections, an upper sealing section, and a lower sealing section, the plurality of fluorescent sections being sealed by the upper sealing section and the lower sealing section.

Abstract: A fluorescent material-sealed sheet includes a plurality of fluorescent sections, an upper sealing section, and a lower sealing section, the plurality of fluorescent sections being sealed by the upper sealing section and the lower sealing section.

Abstract: A light emitting device is provided that includes a light emitting element emitting primary light, and a wavelength conversion portion provided on the light emitting element, absorbing a part of the primary light and emitting secondary light, in which the wavelength conversion portion is made of a plurality of resin layers including at least a first wavelength conversion portion made of a resin layer containing a rare earth-activated phosphor or a transition metal element-activated phosphor, and a second wavelength conversion portion made of a resin layer containing a nanocrystalline phosphor. The first wavelength conversion portion is disposed closer to the light emitting element than the second wavelength conversion portion is. According to the light emitting device, it becomes possible to prevent a substrate from discoloring due to reaction of a silver part of the light emitting device with a nanocrystalline phosphor, thereby preventing a decrease in light emitting efficiency.

Abstract: Disclosed is a wavelength conversion member that is provided with: a light transmissive member including a light input plane into which excitation light is inputted, and a light output plane from which wavelength converted light is outputted; and a semiconductor fine particle phosphor, which is dispersed in the light transmissive member, and which absorbs the excitation light, converts the wavelength, and emits light. The dispersion concentration of the semiconductor fine particle phosphor in the direction parallel to the light traveling direction, i.e., the direction connecting the light input plane and the light output plane, is lower than the dispersion concentration of the semiconductor fine particle phosphor in the direction orthogonal to the light traveling direction.

Abstract: A method of producing a semiconductor nanoparticle of the present invention includes a core formation step of heating a first solution including group 13 element-containing fatty acid salt, a group 13 element-containing halide, and alkali metal amide to obtain a nanoparticle core made of a group 13 element-containing nitride, and a shell formation step of heating a second solution including the nanoparticle core, group 13 element-containing fatty acid salt, and alkali metal amide to obtain a semiconductor nanoparticle having the nanoparticle core covered with a shell layer made of a group 13 element-containing nitride.

Abstract: A semiconductor phosphor nanoparticle including nanoparticle core made of a group 13-group 15 semiconductor; a shell layer coating the semiconductor nanoparticle core; and a metal-containing modified organic compound and a modified organic compound binding to a surface of the shell layer is disclosed.

Abstract: Provided are a group 13 nitride phosphor having high luminous intensity and excellent reliability obtained by preparing group 13 nitride crystallites homogeneously dispersible in a solid matrix by capping surface defects and homogeneously dispersing the group 13 nitride crystallites in the solid matrix and an efficient method of preparing the same. The present invention relates to a group 13 nitride phosphor consisting of group 13 nitride crystallites having a group 13 element dispersed in a matrix of a silica gel solid layer, with a diamine compound bonded to the surfaces of the group 13 nitride crystallites and the silica gel solid layer, and a method of preparing the same.

Abstract: Disclosed is a semiconductor phosphor nanoparticle including a semiconductor crystalline particle made of a 13th family-15th family semiconductor, a modified organic compound binding to the semiconductor crystalline particle, and a layered compound sandwiching the semiconductor crystalline particle protected with the modified organic compound.

Abstract: Provided is a nanocrystalline phosphor having a core/shell structure formed by a core of a group 13 nitride semiconductor and a shell layer, covering the core, including a shell film of a group 13 nitride mixed crystal semiconductor. This nanocrystalline phosphor has high luminous efficiency, and is excellent in reliability. Also provided is a coated nanocrystalline phosphor prepared by bonding modified organic molecules to the nanocrystalline phosphor and/or coating the nanocrystalline phosphor with the modified organic molecules. This coated nanocrystalline phosphor has high dispersibility. Further provided is a method of preparing a coated nanocrystalline phosphor by heating a mixed solution containing a core of a group 13 nitride semiconductor, a nitrogen-containing compound, a group 13 element-containing compound and modified organic molecules.

Abstract: A semiconductor phosphor nanoparticle including nanoparticle core made of a group 13-group 15 semiconductor; a shell layer coating the semiconductor nanoparticle core; and a metal-containing modified organic compound and a modified organic compound binding to a surface of the shell layer is disclosed.

Abstract: A semiconductor nanoparticle phosphor includes a nanoparticle core composed of a group-XIII and -XV semiconductor, a first shell for coating the nanoparticle core, and a second shell for coating the first shell, a difference in a lattice constant between the nanoparticle core and the second shell being smaller than a difference in the lattice constant between the nanoparticle core and the first shell, or the first shell being smaller in the lattice constant than the nanoparticle core and the second shell being greater in the lattice constant than the nanoparticle core, or the first shell being greater in the lattice constant than the nanoparticle core and the second shell being smaller in the lattice constant than the nanoparticle core.

Abstract: Provided are a group 13 nitride phosphor having high luminous intensity and excellent reliability obtained by preparing group 13 nitride crystallites homogeneously dispersible in a solid matrix by capping surface defects and homogeneously dispersing the group 13 nitride crystallites in the solid matrix and an efficient method of preparing the same. The present invention relates to a group 13 nitride phosphor consisting of group 13 nitride crystallites having a group 13 element dispersed in a matrix of a silica gel solid layer, with a diamine compound bonded to the surfaces of the group 13 nitride crystallites and the silica gel solid layer, and a method of preparing the same.

Abstract: Provided is a nanocrystalline phosphor having a core/shell structure formed by a core of a group 13 nitride semiconductor and a shell layer, covering the core, including a shell film of a group 13 nitride mixed crystal semiconductor. This nanocrystalline phosphor has high luminous efficiency, and is excellent in reliability. Also provided is a coated nanocrystalline phosphor prepared by bonding modified organic molecules to the nanocrystalline phosphor and/or coating the nanocrystalline phosphor with the modified organic molecules. This coated nanocrystalline phosphor has high dispersibility. Further provided is a method of preparing a coated nanocrystalline phosphor by heating a mixed solution containing a core of a group 13 nitride semiconductor, a nitrogen-containing compound, a group 13 element-containing compound and modified organic molecules.

Abstract: To prevent deterioration induced by wire bonding in a laser device incorporating a semiconductor laser element having a nitride semiconductor laid on top of a nitride semiconductor substrate, the position at which a wire (301) is bonded to an electrode (113) formed on the top surface of a semiconductor layered structure is located off the area right above a dislocation (crystal defect)-concentrated region (X) of the substrate. Concentration of dislocations in the substrate spreads to the layered structure, producing a dislocation-concentrated region in the part of the layered structure located right above the dislocation-concentrated region of the substrate. If a wire is bonded above this region, the pressure applied when the wire is bonded causes the metal of which the electrode is made to diffuse along the concentrated dislocations, lowering the quality of the layered structure and thus resulting in deterioration of the element.

Abstract: Disclosed is a light-emitting device comprising a semiconductor excitation light source emitting blue-violet light and a solid material illuminant having an absorbent for the blue-violet light containing samarium (Sm). With such a constitution, the light-emitting device has high efficiency, long life and excellent color rendering properties.

Abstract: To prevent deterioration induced by wire bonding in a laser device incorporating a semiconductor laser element having a nitride semiconductor laid on top of a nitride semiconductor substrate, the position at which a wire (301) is bonded to an electrode (113) formed on the top surface of a semiconductor layered structure is located off the area right above a dislocation (crystal defect)-concentrated region (X) of the substrate. Concentration of dislocations in the substrate spreads to the layered structure, producing a dislocation-concentrated region in the part of the layered structure located right above the dislocation-concentrated region of the substrate. If a wire is bonded above this region, the pressure applied when the wire is bonded causes the metal of which the electrode is made to diffuse along the concentrated dislocations, lowering the quality of the layered structure and thus resulting in deterioration of the element.