A nitride semiconductor light emitting element includes: n-side and p-side nitride semiconductor layers; and an active layer. The active layer includes a plurality of well layers and a plurality of barrier layers. The plurality of well layers include first well layers, and second well layers positioned closer to the p-side nitride semiconductor layer than the first well layers. At least one of the plurality of barrier layers positioned between the first well layers and at least one of the plurality of barrier layers positioned between the second well layers respectively include a first barrier layer containing an n-type impurity, and a second barrier layer, wherein a concentration of the n-type impurity in the second barrier layer is lower than a concentration of the n-type impurity in the first barrier layer, and wherein the second barrier layer is positioned closer to the p-side nitride semiconductor layer than the first barrier layer.

Disclosed are a light emitting diode and a method for manufacturing a light emitting diode. The light emitting diode includes a first-type layer, a light emitting layer, a second-type layer and an electrode layer; the first-type layer includes a first-type gallium nitride; the light emitting layer is located on the first-type layer; the light emitting layer includes a quantum point; the second-type layer is located on the light emitting layer; the second-type layer includes a second-type gallium nitride or an indium tin oxide; and the electrode layer is located on the second-type layer.

A composition and method for formation of ohmic contacts on a semiconductor structure are provided. The composition includes a TiAl.sub.xN.sub.y material at least partially contiguous with the semiconductor structure. The TiAl.sub.xN.sub.y material can be TiAl.sub.3. The composition can include an aluminum material, the aluminum material being contiguous to at least part of the TiAl.sub.xN.sub.y material, such that the TiAl.sub.xN.sub.y material is between the aluminum material and the semiconductor structure. The method includes annealing the composition to form an ohmic contact on the semiconductor structure.

A process for manufacturing an electroluminescent device, comprising: (a) using a stack comprising, successively: a substrate having a surface; matrix arrays of pixels formed on the surface of the substrate, of columnar shape; an encapsulating layer arranged to cover the matrix arrays of pixels; a dielectric layer formed on the encapsulating layer; (b) performing a directional etch along the normal to the surface of the substrate, of a portion of the dielectric layer extending between the pixels of the matrix arrays of pixels; the dielectric layer having a portion remaining at the end of step (b); and (c) performing a selective chemical etch of the remaining portion of the dielectric layer with a chemical etchant that permits selective etching of the remaining portion of the dielectric layer with respect to the encapsulating layer.

A semiconductor heterostructure for an optoelectronic device with improved light emission is disclosed. The heterostructure can include a first semiconductor layer having a first index of refraction n1. A second semiconductor layer can be located over the first semiconductor layer. The second semiconductor layer can include a laminate of semiconductor sublayers having an effective index of refraction n2. A third semiconductor layer having a third index of refraction n3 can be located over the second semiconductor layer. The first index of refraction n1 is greater than the second index of refraction n2, which is greater than the third index of refraction n3.

A light emitting diode epitaxial structure (LEDES) based on an aluminum gallium nitride material and a manufacturing method thereof are described. The LEDES includes a first layer of n-type aluminum gallium nitride, an active layer comprising aluminum gallium nitride, a p-type aluminum gallium nitride, and a second layer of n-type aluminum gallium nitride disposed above the p-type aluminum gallium nitride along an epitaxial growth direction. An epitaxial layer comprising a gallium nitride layer is contained between an epitaxial layer of the p-type aluminum gallium nitride and an epitaxial layer of the second layer of n-type aluminum gallium nitride. The epitaxial layer comprising the gallium nitride layer has an energy band width smaller than those of the epitaxial layers of the p-type aluminum gallium nitride and the second layer of n-type aluminum gallium nitride. A coarsened structure exists on a surface of the second layer of n-type aluminum gallium nitride.

Direct-bonded LED arrays and applications are provided. An example process fabricates a LED structure that includes coplanar electrical contacts for p-type and n-type semiconductors of the LED structure on a flat bonding interface surface of the LED structure. The coplanar electrical contacts of the flat bonding interface surface are direct-bonded to electrical contacts of a driver circuit for the LED structure. In a wafer-level process, micro-LED structures are fabricated on a first wafer, including coplanar electrical contacts for p-type and n-type semiconductors of the LED structures on the flat bonding interface surfaces of the wafer. At least the coplanar electrical contacts of the flat bonding interface are direct-bonded to electrical contacts of CMOS driver circuits on a second wafer. The process provides a transparent and flexible micro-LED array display, with each micro-LED structure having an illumination area approximately the size of a pixel or a smallest controllable element of an image represented on a high-resolution video display.

A light-emitting diode manufacturing method including the forming of three-dimensional semiconductor elements, extending along parallel axes, made of a III-V compound, each having a lower portion and a flared upper portion inscribed within a frustum of half apical angle . The method further comprises, for each semiconductor element, the forming of an active area covering the top of the upper portion and the forming of at least one semiconductor layer of the III-V compound covering the active area by vapor deposition at a pressure lower than 10 mPa, by using a flux of the group-III element along a direction inclined by an angle III and a flux of the group-V element along a direction inclined by an angle V with respect to the vertical axis, angles III and V being smaller than angle .

A light emitting diode including a substrate having a first area and a second area defined by an isolation groove line, a semiconductor stack disposed on the substrate and including a lower semiconductor layer, an upper semiconductor layer, an active layer, a first electrode pad electrically connected to the lower semiconductor layer, a second electrode pad electrically connected to the upper semiconductor layer, and a connecting portion electrically connecting the semiconductor stack disposed in the first and second areas to each other, and including a first portion, a second portion, and a third portion extending from a second distal end of the first portion, in which the isolation groove line is disposed between the first and second electrode pads and exposes the substrate, the first portion extends along a first direction substantially parallel to an extending direction of the isolation groove line, and the second and third portions extend in a second direction crossing the first direction.

A light-emitting device including an epitaxial layer, a support layer, an insulating layer, a first electrode pad, and a second electrode pad is provided. The epitaxial layer includes a first type doped semiconductor layer, a light-emitting layer and a second type doped semiconductor layer, wherein the light-emitting layer is disposed on a partial area of the first type doped semiconductor layer and is between the first type doped semiconductor layer and the second type doped semiconductor layer. The support layer covers the second type doped semiconductor layer while the insulating layer covers the epitaxial layer and the support layer. The first and the second electrode pads are disposed over the insulating layer and electrically connected to the first and the second type doped semiconductor layers, respectively. The support layer extends from a first position below the first electrode pad to a second position below the second electrode pad.