A light emitting element ink and a method of manufacturing a display device are provided. The light emitting element ink includes a light emitting element solvent, a light emitting element dispersed in the light emitting element solvent, the light emitting element including a plurality of semiconductor layers and an insulating film surrounding outer surfaces of the semiconductor layers, a thickener dispersed in the light emitting element solvent, wherein a compound of the thickener includes a functional group capable of forming a hydrogen bond together with a compound of the light emitting element solvent or another compound of the thickener and the compound of the thickener is represented by Chemical Formula 1.

A display device includes a base substrate, a partitioning wall on the base substrate, wherein the partitioning wall includes a first partitioning wall, and a second partitioning wall on the first partitioning wall, and a light emitting element spaced from the partitioning wall and located in a space surrounded by the partitioning wall in a plan view. The first partitioning wall and the light emitting element include a same material. The second partitioning wall includes a transparent conductive oxide.

Structures and methods are disclosed for fabricating optoelectronic solid state array devices. In one case a backplane and array of micro devices is aligned and connected through bumps.

This semiconductor light emitting device includes an emission layer, a passivation layer on the emission layer, and a first adhesive layer on the passivation layer. The passivation layer may include a plurality of grooves, and the first adhesive layer may be disposed in each of the plurality of grooves. Arranging the first adhesive layer in the plurality of grooves may enhance fixability. The display device includes a plurality of semiconductor light emitting devices. The semiconductor light emitting devices may include a horizontal semiconductor light emitting device, a flip chip semiconductor light emitting device, or a vertical semiconductor light emitting device.

A method for manufacturing an LED structure includes forming a first semiconductor layer on a first substrate; performing a first implantation operation to form a first implanted region and a first non-implanted region in a second doping semiconductor layer of the first semiconductor layer; forming a second semiconductor layer on the first semiconductor layer; performing a second implantation operation to form a second implanted region and a second non-implanted region in a fourth doping semiconductor layer of the second semiconductor layer; performing a first etch operation to remove a portion of the second semiconductor layer and expose at least the first non-implanted region; performing a second etch operation to expose a plurality of contacts of a driving circuit formed in the first substrate; and electrically connecting the first non-implanted region and the second non-implanted region with the plurality of contacts.

An emitter includes a light emission region configured to emit light associated with a first optical spectrum, a light emission surface, and an optical element disposed on the light emission surface. A first surface of the optical element, which contacts the light emission surface, is configured to reflect light associated with the first optical spectrum. A second surface of the optical element, opposite the first surface of the optical element, is configured to absorb light associated with a second optical spectrum. At least one aperture is formed in the optical element.

A display device includes a substrate in which a plurality of sub pixels are defined; a pair of low potential power lines are in a sub pixel of the plurality of sub pixels; and a plurality of light emitting diodes that overlap an area between the pair of low potential power lines. Each of the plurality of light emitting diodes includes a first semiconductor layer; an emission layer; a second semiconductor layer; a first insulating film that encloses side surfaces of the first semiconductor layer, the emission layer, and the second semiconductor layer; a side electrode on the first insulating film; and a first electrode that is in contact with a bottom surface of the first semiconductor layer and a lower part of the side electrode.

A display device includes a first electrode and a second electrode which are spaced apart from each other on a substrate. A light emitting element is disposed between the first electrode and the second electrode. A light emitting element core of the light emitting element includes a first semiconductor layer, a second semiconductor layer spaced apart from the first semiconductor layer, and a light emitting layer disposed between the first semiconductor layer and the second semiconductor layer. A first element insulating layer surrounds a side surface of the light emitting element core. The first element insulating layer is an oxide insulating layer having a single crystalline structure.

Solid-state lighting devices including light-emitting diodes (LEDs) and more particularly arrangements of lumiphoric materials within LED chips are disclosed. Lumiphoric materials are incorporated or otherwise embedded within LED chips. Embedded lumiphoric materials are provided so that at least some portions of light generated by active LED structures are subject to wavelength conversion before exiting LED chip surfaces. Lumiphoric materials may form dielectric and/or passivation layers between various chip structures, such as between active LED structures and internal reflective layers and/or electrical contacts. Internally converted light propagating within LED chips may pass back through active LED structures with reduced light absorption.

A method for manufacturing a light-emitting device includes providing a layered body including a wavelength conversion layer, a light-transmissive layer disposed above the wavelength conversion layer, and a semiconductor layer disposed above the light-transmissive layer, separating the semiconductor layer into a plurality of semiconductor portions above the wavelength conversion layer by removing a part of the semiconductor layer; and singulating the layered body into a plurality of light-emitting devices by cleaving the wavelength conversion layer along a portion where the part of the semiconductor layer is removed.