A method according to embodiments of the invention includes providing a wafer of semiconductor devices grown on a growth substrate. The wafer of semiconductor devices has a first surface and a second surface opposite the first surface. The second surface is a surface of the growth substrate. The method further includes bonding the first surface to a first wafer and bonding the second surface to a second wafer. In some embodiments, the first and second wafer each have a different coefficient of thermal expansion than the growth substrate. In some embodiments, the second wafer may compensate for stress introduced to the wafer of semiconductor devices by the first wafer.

A method for manufacturing an image display device includes: providing a second substrate that comprises a first substrate, and a semiconductor layer on the first substrate, the semiconductor layer comprising a light-emitting layer; providing a third substrate comprising a circuit, the circuit comprising a circuit element; bonding the semiconductor layer to the third substrate; forming a light-emitting element by etching the semiconductor layer; covering the light-emitting element with a light-transmissive insulating member; and forming a wiring layer electrically connecting the light-emitting element to the circuit element; wherein: the light-emitting element has a light-emitting surface opposite to a surface of the light-emitting element that is bonded to the third substrate; and the insulating member is configured to cause light radiated from the light-emitting element to have a light distribution in a normal direction of the light-emitting surface toward a light-emitting surface side.

A light-emitting diode (LED) device includes a substrate, an epitaxial layered structure disposed on the substrate, a current-spreading layer disposed on the epitaxial layered structure, a current-blocking unit disposed on the current-spreading layer, and a distributed Bragg reflector. The epitaxial layered structure, the current-spreading layer and the current-blocking unit are covered by the distributed Bragg reflector. One of the current-spreading layer, the current-blocking unit, and a combination thereof has a patterned rough structure. A method for manufacturing the LED device is also disclosed.

As the pixel density of optoelectronic devices becomes higher, and the size of the optoelectronic devices becomes smaller, the problem of isolating the individual micro devices becomes more difficult. A method of fabricating an optoelectronic device, which includes an array of micro devices, comprises: forming a device layer structure including a monolithic active layer on a substrate; forming an array of first contacts on the device layer structure defining the array of micro devices; mounting the array of first contacts to a backplane comprising a driving circuit which controls the current flowing into the array of micro devices; removing the substrate; and forming an array of second contacts corresponding to the array of first contacts with a barrier between each second contact.

A nitride semiconductor light-emitting element includes an n-type semiconductor layer, a p-type semiconductor layer, an active layer, and an electron blocking layer comprising at least one layer. The at least one layer of the electron blocking layer includes a peak-containing layer having an n-type impurity concentration peak in an n-type impurity concentration distribution along a stacking direction. The n-type impurity concentration peak appears as a local maximum in the n-type impurity concentration distribution along the stacking direction in the peak-containing layer and has an n-type impurity concentration of not less than 10 times a smallest value of the n-type impurity concentration in a region along the stacking direction between positions that are separated from a position of the peak in the stacking direction on both sides in the stacking direction by 10% of a thickness of the peak-containing layer.

Described are light emitting diode (LED) devices having patterned substrates and methods for effectively growing epitaxial III-nitride layers on them. A nucleation layer, comprising a III-nitride material, is grown on a substrate before any patterning takes place. The nucleation layer results in growth of smooth coalesced III-nitride layers over the patterns.

A Micro-LED array device based on III-nitride semiconductors and a method for fabricating the same are provided. The Micro-LED array device includes arrayed sector mesa structures that are formed by etching to penetrate through a p-type GaN layer and a quantum-well active layer and deep into an n-type GaN layer, a p-type electrode array deposited by evaporation on the p-type GaN layer of sector arrays, and an n-type electrode array deposited by evaporation on the n-type GaN layer. The n-type electrode array forms blocking walls to isolate the sector mesas from one another. The blocking walls, and each of the blocking walls and the annular structure surrounding the sector mesa are connected to each other.

A micro device structure comprising at least part of an edge of a micro device is covered with a metal-insulator-semiconductor (MIS) structure, wherein the MIS structure comprises a MIS dielectric layer and a MIS gate conductive layer, at least one gate pad provided to the MIS gate conductive layer, and at least one micro device contact extended upwardly on a top surface of the micro device.

The present invention provides a micro-LED chip, a manufacturing method of the micro-LED chip, and a display panel. The micro-LED chip includes a plurality of sub-chips connected in series. The first sub-chip and the last sub-chip are connected to a first electrode and a second electrode, respectively. Accordingly, a voltage across the micro-LED chip is increased, power consumption of a driving thin film transistor (TFT) is reduced, and a high power consumption problem of driving TFTs in conventional micro-LED displays is improved.

Various embodiments of light emitting devices, assemblies, and methods of manufacturing are described herein. In one embodiment, a method for manufacturing a lighting emitting device includes forming a light emitting structure, and depositing a barrier material, a mirror material, and a bonding material on the light emitting structure in series. The bonding material contains nickel (Ni). The method also includes placing the light emitting structure onto a silicon substrate with the bonding material in contact with the silicon substrate and annealing the light emitting structure and the silicon substrate. As a result, a nickel silicide (NiSi) material is formed at an interface between the silicon substrate and the bonding material to mechanically couple the light emitting structure to the silicon substrate.