Provided are a light emitting device and a method of fabricating the same. The light emitting device includes: a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer and including a first surface and a second surface; first and second contact electrodes each ohmic-contacting the first and second conductivity type semiconductor layers; and first and second electrodes disposed on the first surface of the light emitting structure, in which the first and second electrodes each include sintered metal particles and the first and second electrodes each include inclined sides of which the tangential gradients with respect to sides of vertical cross sections thereof are changing.

The method comprises: forming an Al layer or Al droplets on a surface of a substrate by flowing an organic metal gas containing Al without flowing an ammonia gas; forming an AlN buffer layer on the Al layer or Al droplets by flowing the organic metal gas containing Al and the ammonia gas, the Al layer or Al droplets remaining as a metal under the AlN buffer layer; forming the Group III nitride semiconductor on the AlN buffer layer; and peeling the Group III nitride semiconductor in a place of the Al layer or Al droplets from the substrate.

Described herein are methods for using remote plasma chemical vapor deposition (RP-CVD) and sputtering deposition to grow layers for light emitting devices. A method includes growing a light emitting device structure on a growth substrate, and growing a tunnel junction on the light emitting device structure using at least one of RP-CVD and sputtering deposition. The tunnel junction includes a p++ layer in direct contact with a p-type region, where the p++ layer is grown by using at least one of RP-CVD and sputtering deposition. Another method for growing a device includes growing a p-type region over a growth substrate using at least one of RP-CVD and sputtering deposition, and growing further layers over the p-type region. Another method for growing a device includes growing a light emitting region and an n-type region using at least one of RP-CVD and sputtering deposition over a p-type region.

A LED including an epitaxial stacked layer, a first electrode and a second electrode is provided. The epitaxial stacked layer includes a first type doped semiconductor layer, a light emitting layer and a second type doped semiconductor layer. The epitaxial stacked layer has a first mesa portion and a second mesa portion to form a first type conductive region and a second type conductive region respectively. The first electrode is disposed on the first mesa portion. The second electrode is disposed on the second mesa portion. The second electrode contacts the first type doped semiconductor layer, the light emitting layer and the second type doped semiconductor layer located at the second mesa portion. Moreover, a manufacturing method of the LED is also provided.

A method for manufacturing a semiconductor element includes providing a semiconductor layer on a carbide substrate, the carbide substrate having a semiconductor layer contact surface connected to the semiconductor layer and a reflective layer contact surface opposite to the semiconductor layer contact surface. A reflective layer is provided on the reflective layer contact surface of the carbide substrate. The reflective layer contains silver and at least one of oxide particles and nitride particles.

A light emitting diode including a side reflection layer. The light emitting diode includes: a semiconductor stack and a light exit surface having a roughened surface through which light generated from an active layer is emitted; side surfaces defining the light exit surface; and a side reflection layer covering at least part of the side surfaces. The light exit surface is disposed over a first conductivity type semiconductor layer opposite to the ohmic reflection layer, all layers from the active layer to the light exit surface are formed of gallium nitride-based semiconductors, and a distance from the active layer to the light exit surface is 50 m or more.

Pixelated-LED chips and related methods are disclosed. A pixelated-LED chip includes an active layer with independently electrically accessible active layer portions arranged on or over a light-transmissive substrate. The active layer portions are configured to illuminate different light-transmissive substrate portions to form pixels. Various enhancements may beneficially provide increased contrast (i.e., reduced cross-talk between pixels) and/or promote inter-pixel illumination homogeneity, without unduly restricting light utilization efficiency. In some aspects, an underfill material with improved surface coverage is provided between adjacent pixels of a pixelated-LED chip. The underfill material may be arranged to cover all lateral surfaces between the adjacent pixels. In some aspects, discontinuous substrate portions are formed before application of underfill materials. In some aspects, a wetting layer is provided to improve wicking or flow of underfill materials during various fabrication steps. Other technical benefits may additionally or alternatively be achieved.

A method of manufacturing an optoelectronic device, including the steps of: a) providing an active diode stack comprising a first doped semiconductor layer of a first conductivity type and a second doped semiconductor layer of the first conductivity type, coating the upper surface of the first layer; b) arranging a third semiconductor layer on the upper surface of the active stack; c) after step b), forming at least one MOS transistor inside and on top of the third semiconductor layer; and d) after step b), before or after step c), forming trenches vertically extending from the upper surface of the third layer and emerging into or onto the upper surface of the first layer and delimiting a plurality of pixels, each including a diode and an elementary diode control cell.

The invention relates to a method of manufacturing at least one optoelectronic structure on a support substrate.

In particular, this invention relates to manufacturing of an optoelectronic structure that has a plurality of coplanar light emitting diodes, and formed from a succession of light emitting stacks.

Therefore this invention uses a cavity, the bottom of which has a staged profile, such that the formation of the succession of light emitting stacks reproduces the staged profile of the bottom of the cavity, on its exposed face.

Performance of a step to level the succession of light emitting stacks relative to a reference level defined by the exposed surface portion vertically in line with the deepest step, then makes it possible to reveal a set of coplanar light emitting diodes.

The invention relates to a process for fabricating an optoelectronic device (1) comprising a plurality of diodes (40), comprising the following steps: providing a readout substrate (10) containing a readout circuit (12) and having a growth face defined by a plurality of conductive segments (20) that are separate from one another and connected to the readout circuit (12); producing, on the growth face, a plurality of nucleation segments (30) made of a two-dimensional crystalline material, which segments are separate from one another, said segments resting in contact with the conductive segments (20); producing, by epitaxy from the nucleation segments (30), the plurality of diodes.