A deep ultraviolet LED with a design wavelength , including a reflecting electrode layer (Au), a metal layer (Ni), a p-GaN contact layer, a p-block layer made of a p-AlGaN layer, an i-guide layer made of an AlN layer, a multi-quantum well layer, an n-AlGaN contact layer, a u-AlGaN layer, an AlN template, and a sapphire substrate that are arranged in this order from a side opposite to the sapphire substrate, in which the thickness of the p-block layer is 52 to 56 nm, a two-dimensional reflecting photonic crystal periodic structure having a plurality of voids is provided in a region from the interface between the metal layer and the p-GaN contact layer to a position not beyond the interface between the p-GaN contact layer and the p-block layer in the thickness direction of the p-GaN contact layer, the distance from an end face of each of the voids in the direction of the sapphire substrate to the interface between the multi-quantum well layer and the i-guide layer satisfies /2n.sub.1Deff (where is the design wavelength and n1Deff is the effective average refractive index of each film of the stacked structure from the end face of each void to the i-guide layer) in the perpendicular direction, the distance being in the range of 53 to 57 nm, the two-dimensional reflecting photonic crystal periodic structure has a photonic band gap that opens for TE polarized components, and provided that the period a of the two-dimensional reflecting photonic crystal periodic structure satisfies a Bragg condition with respect to light with the design wavelength , the order m of a formula of the Bragg condition: m/n.sub.2Deff=2a (where m is the order, is the design wavelength, n.sub.2Deff is the effective refractive index of two-dimensional photonic crystals, and a is the period of the two-dimensional photonic crystals) satisfies 2m4, and the radius of each void is R, R/a satisfies 0.30R/a0.40.

The invention relates to an optoelectronic semiconductor element (100) comprising a semiconductor layer sequence (1) with a first layer (10) of a first conductivity type, a second layer (12) of a second conductivity type, and an active layer (11) which is arranged between the first layer (10) and the second layer (12) and which absorbs or emits electromagnetic radiation when operated as intended. The semiconductor element (100) is equipped with a plurality of injection regions (2) which are arranged adjacently to one another in a lateral direction, wherein the semiconductor layer sequence (1) is doped within each injection region (2) such that the semiconductor layer sequence (1) has the same conductivity type as the first layer (10) within the entire injection region (2). Each injection region (2) passes at least partly through the active layer (11) starting from the first layer (10). Furthermore, each injection region (2) is laterally surrounded by a continuous path of the active layer (11), the active layer (11) being doped less in the path than in the injection region (2) or oppositely thereto. During the operation of the semiconductor element (100), charge carriers reach the injection regions (2) at least partly from the first layer (10) and are directly injected into the active layer (11) from there.

An LED mounted method includes: providing a circuit substrate having a plurality of conductive pads; through a pick and place module, disposing a plurality of conductors on the conductive pads; disposing a plurality of LED chips on the circuit substrate, with each LED chip being disposed on at least two conductors; projecting a laser source generated by a laser generation module to each LED chip so that the laser source passes through the LED chip and is projected onto at least two conductors; and curing the conductor disposed between the LED chip and the circuit substrate by irradiation of the laser source so that the LED chip is mounted on the circuit substrate.

There is provided a manufacturing method of a III-V compound crystal including a seed-crystal-formed substrate provision step of providing a seed-crystal-formed substrate in which a III-V compound seed crystal has been formed on a substrate, a seed crystal partial separation step of separating part of a portion in contact with the substrate in the III-V compound seed crystal from the substrate, and a crystal growth step of generating and growing the III-V compound crystal by reacting a group III element and a group V element with use of the III-V compound seed crystal as a nucleus after the seed crystal partial separation step.

This disclosure relates to methods of growing crystalline layers on amorphous substrates by way of an ultra-thin seed layer, methods for preparing the seed layer, and compositions comprising both. In an aspect of the invention, the crystalline layers can be thin films. In a preferred embodiment, these thin films can be free-standing.

A nitride-based semiconductor light-emitting element includes: a substrate that is an example of a n-type nitride-based semiconductor including a group IV n-type impurity; and an n-side electrode in contact with the substrate. The substrate includes: a surface layer region in contact with the n-side electrode and including a halogen element; and an internal region located across the surface layer region from the n-side electrode. A peak concentration of the group IV n-type impurity in the surface layer region is at least 1.010.sup.21 cm.sup.3. A peak concentration of the halogen element in the surface layer region is at least 10% of the peak concentration of the group IV n-type impurity in the surface layer region. A concentration of the group IV n-type impurity in the internal region is lower than a concentration of the group IV n-type impurity in the surface layer region.

A group III-nitride laminated substrate includes a sapphire substrate, a first layer that is formed on the sapphire substrate and is made of aluminum nitride, a second layer that is formed on the first layer and serves as an n-type layer made of gallium nitride and doped with an n-type dopant, a third layer that is formed on the second layer and serves as a light-emitting layer made of a group III-nitride, and a fourth layer that is formed on the third layer and serves as a p-type layer made of a group III-nitride and doped with a p-type dopant. The second layer has a thickness of 7 m or less. A half-value width of (0002) diffraction determined through X-ray rocking curve analysis is 100 seconds or less, and a half-value width of (10-12) diffraction determined through X-ray rocking curve analysis is 200 seconds or less.

A method is provided for producing a device with light emitting/light receiving diodes, including: producing, on a substrate, a stack including first and second doped semiconductor layers; first etching of the stack, forming first openings through the entire thickness of the second layer; producing dielectric portions covering, in the first openings, the side walls of the second layer; second etching of the stack, extending the first openings until reaching the substrate, delimiting the p-n junctions of the diodes; etching extending the first openings into a part of the substrate; producing first electrically conductive portions in the first openings, forming first electrodes of the diodes, and producing second electrodes electrically connected to the second layer; and eliminating the substrate, forming a collimation grid.

A method for manufacturing a light-emitting element comprises: forming a mask comprising a first film and a second film such that the mask covers a first active layer and a second nitride semiconductor layer, which comprises: forming the first film covering at least an upper surface of the second nitride semiconductor layer, and forming the second film covering the first film; while the first active layer and the second nitride semiconductor layer are covered with the mask, forming a third nitride semiconductor layer at an exposed portion of a first nitride semiconductor layer, wherein a temperature at which the third nitride semiconductor layer is formed is less than a melting point of the second film; and after the forming of the third nitride semiconductor layer, removing the mask, during which lift-off of the mask is performed by removing the first film, which also removes the second film.

A light emitting diode with a zinc oxide layer and a method of fabricating the same are disclosed. The light emitting diode includes: a light emitting structure including a gallium nitride based first conductivity type semiconductor layer, a gallium nitride based second conductivity type semiconductor layer, and an active layer interposed therebetween; and a ZnO transparent electrode layer disposed on the second conductivity type semiconductor layer, wherein the ZnO transparent electrode layer comprises a ZnO seed layer and a ZnO bulk layer formed on the ZnO seed layer, wherein the ZnO bulk layer is porous compared to the ZnO seed layer, wherein an interface between the ZnO seed layer and the second conductivity type semiconductor layer is flatter than an interface between the ZnO seed layer and the ZnO bulk layer, and wherein the interface between the ZnO seed layer and the ZnO bulk layer has an irregular concavo-convex shape.