Disclosed is a silicon nano crystal light emitting diode, including: a photoelectric conversion layer formed of a silicon nitride layer including a silicon nano crystal; an electron injection layer formed on the photoelectric conversion layer; and a hole injection layer, which faces the electron injection layer with the photoelectric conversion layer interposed therebetween, has an energy band gap higher than that of the photoelectric conversion layer, and has a refractive index lower than that of a silicon thin film.

The present invention provides a surface mounted light emitting apparatus which has long service life and favorable property for mass production, and a molding used in the surface mounted light emitting apparatus. The surface mounted light emitting apparatus comprises the light emitting device 10 based on GaN which emits blue light, the first resin molding 40 which integrally molds the first lead 20 whereon the light emitting device 10 is mounted and the second lead 30 which is electrically connected to the light emitting device 10, and the second resin molding 50 which contains YAG fluorescent material and covers the light emitting device 10. The first resin molding 40 has the recess 40c comprising the bottom surface 40a and the side surface 40b formed therein, and the second resin molding 50 is placed in the recess 40c. The first resin molding 40 is formed from a thermosetting resin such as epoxy resin by the transfer molding process, and the second resin molding 50 is formed from a thermosetting resin such as silicone resin.

Disclosed are a photoelectronic device using a hybrid structure of silica nanoparticles and graphene quantum dots and a method of manufacturing the same. The photoelectronic device according to the present disclosure has a hybrid structure including graphene quantum dots (GODs) bonded to surfaces of silica nanoparticles (SNPs), thereby increasing energy transfer efficiency.

A semiconductor nanocrystal that emits green light having a peak emission with a full width at half maximum of about 30 nm or less at 100 C. and a method of making coated semiconductor nanocrystals are provided. Materials and other products including semiconductor nanocrystals described herein and materials and other products including semiconductor nanocrystals prepared by a method described herein are also disclosed.

LED devices having high-quality single crystal ZnO structures for spreading currents and extracting light out of the LEDs are disclosed. In one aspect, a LED device is provided to include a substrate; a first semiconductor layer exhibiting a first conductivity type and formed over the substrate; an active light-emitting structure formed over the first semiconductor layer, the active light-emitting structure operable to emit light under electrical excitation; a second semiconductor layer exhibiting a second conductivity type and formed over the active light-emitting structure; and a single crystal ZnO structure formed over the second semiconductor layer and including a bottom single crystal ZnO portion over the second semiconductor layer and a top single crystal ZnO portion extending from the bottom single crystal ZnO portion, wherein the bottom single crystal ZnO portion is a contiguous single crystal ZnO portion without having voids.

A light emitting element includes a semiconductor layer; an upper electrode disposed on an upper surface of the semiconductor layer; and a lower electrode disposed on a lower surface of the semiconductor later. In a plan view, the upper electrode includes a first extending portion extending in an approximately rectangular shape along an outer periphery of the semiconductor layer, a first pad portion connected to a first side among four sides of the first extending portion, a second pad portion connected to a second side that is opposite to the first side, among the four sides of the first extending portion, and a second extending portion and a third extending portion, each disposed in a region surrounded by the first extending portion, the second extending portion and the third extending portion each connecting the first pad portion and the second pad portion.

The invention pertains to formation of a semiconducting portion (60) by epitaxial growth on a strained germination portion (40), comprising the steps in which a cavity (21) is produced under a structured part (11) by rendering free a support layer (30) situated facing the structured part (11), a central portion (40), termed the strained germination portion, then being strained; and a semiconducting portion (60) is formed by epitaxial growth on the strained germination portion (40), wherein the structured part (11) is furthermore placed in contact with the support layer (30) in such a way as to bind the structured part (11) of the support layer.

A method of production of a semiconducting structure including a strained portion tied to a support layer by molecular bonding, including the steps in which a cavity is produced situated under a structured part so as to strain a central portion by lateral portions, and the structured part is placed in contact and molecularly bonded with a support layer, wherein a consolidation annealing is performed, and a distal part of the lateral portions in relation to the strained portion is etched.

A method for manufacturing a functional material including a porous metal complex with nanoparticles included therein, the method including a configuration of adding more than one particle constituent raw material constituting the nanoparticles and a porous metal complex to a solvent, and then synthesizing nanoparticles included in the porous metal complex by heating to a desired temperature. In addition, provided is an electronic component including an electronic component element using a functional material including a porous metal complex with nanoparticles included therein.

An optoelectronic semiconductor device and a method for manufacturing an optoelectronic semiconductor device are disclosed. In an embodiment an optoelectronic semiconductor device includes a semiconductor body having a first region of a first conductive type, an active region configured to generate electromagnetic radiation, a second region of a second conductive type and a coupling-out surface configured to couple-out the electromagnetic radiation, wherein the first region, the active region and the second region are arranged along a stacking direction, wherein the active region extends from a rear surface opposite the coupling-out surface to the coupling-out surface along a longitudinal direction transverse to or perpendicular to the stacking direction, and wherein the coupling-out surface is arranged plane-parallel to the rear surface.