An image display device according to an embodiment includes a substrate, a first wiring line formed on the substrate along a first direction, a first light-emitting element located on the first wiring line and including a first light-emitting surface, a light-transmitting electrode formed along a second direction intersecting the first direction and located on the first light-emitting surface, a first anisotropic conductive member located on the first wiring line, a first terminal electrically connected to the first wiring line via the first anisotropic conductive member, a second anisotropic conductive member located on the light-transmitting electrode, and a second terminal electrically connected to the light-transmitting electrode via the second anisotropic conductive member. The first light-emitting element includes a first bottom surface in contact with the first wiring line, and the first light-emitting surface is located on a side of the first light-emitting element opposite to the first bottom surface.

Disclosed are a light emitting structure and a preparation method therefor. The method includes: forming a mask layer on a n-type substrate, disposing a plurality of openings in the mask layer; and forming a light emitting unit in each of the plurality of openings, including: forming a metal atomic layer in the opening; forming an n-type semiconductor layer on the metal atomic layer, and forming a light extraction structure on the n-type semiconductor layer; and sequentially forming an active layer and a p-type semiconductor layer on the n-type semiconductor layer and the light extraction structure. In this way, step of peeling off the substrate may be avoided. In addition, with a plurality of discrete light emitting structures formed on the same substrate, a step of cutting a device is avoided, and damage to the device can be prevented.

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.

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.

There is provided an aluminum nitride laminate member including: a sapphire substrate having a base surface on which bumps are distributed periodically, each bump having a height of smaller than or equal to 500 nm; and an aluminum nitride layer provided on the base surface and having a surface on which protrusions are formed above the apices of the bumps.

There is provided an aluminum nitride laminate member including: a sapphire substrate having a base surface on which bumps are distributed periodically, each bump having a height of smaller than or equal to 500 nm; and an aluminum nitride layer grown on the base surface and having a flat surface, there being substantially no voids in the aluminum nitride layer.

A light emitting apparatus includes an electrode and a laminated structure. The laminated structure includes an n-type first semiconductor layer, a light emitting layer, a p-type second semiconductor layer, a tunnel junction layer, and an n-type third semiconductor layer. The electrode is electrically connected to the first semiconductor layer. The first semiconductor layer, the light emitting layer, the second semiconductor layer, the tunnel junction layer, and the third semiconductor layer are arranged in a presented order. The light emitting layer and the first semiconductor layer form a columnar section.

A lift-off method includes a relocation substrate joining step of joining a relocation substrate to a surface of an optical device layer of an optical device wafer with a joining member interposed therebetween, thereby forming a composite substrate, a buffer layer breaking step of applying a pulsed laser beam having a wavelength transmittable through an epitaxy substrate and absorbable by a buffer layer to the buffer layer from a reverse side of the epitaxy substrate of the optical device wafer of the composite substrate, thereby breaking the buffer layer, and an optical device layer relocating step of peeling off the epitaxy substrate from the optical device layer, thereby relocating the optical device layer to the relocation substrate. In the buffer layer breaking step, irradiating conditions of the pulsed la-ser beam are changed for respective ring-shaped areas of the buffer layer, and the pulsed laser beam is applied to the optical device wafer under the changed irradiating conditions.

A dislocation-free GaN/InGaN-based nanowires-LED epitaxially grown on a transparent, electrically conductive template substrate. The simultaneous transparency and conductivity are provided by a thin, translucent metal contact integrated with a quartz substrate. The light transmission properties of the translucent metal contact are tunable during epitaxial growth of the nanowires LED. Transparent light emitting diodes (LED) devices, optical circuits, solar cells, touch screen displays, and integrated photonic circuits can be implemented using the current platform.

The present invention relates to a method for manufacturing a display device, and more particularly, to a method for manufacturing a display device using a semiconductor light emitting device having a size of several μm to several tens of μm, and to an assembly substrate used for manufacturing the display device. The present invention provides a display device, characterized in that including a substrate having a wiring electrode, a plurality of semiconductor light emitting devices electrically connected to the wiring electrode, and a passivation layer formed to cover the semiconductor light emitting device, and the passivation layer is formed to cover only a portion of a side surface of the semiconductor light emitting device.