A semiconductor light emitting device includes a first conductivity type semiconductor, an active layer on the first conductivity type semiconductor, a second conductivity type semiconductor on the active layer, an electrode layer on the second conductivity type semiconductor, and a passivation layer covering at least side surfaces of the first conductivity type semiconductor, the active layer, the second conductivity type semiconductor, and the electrode layer. The angle between the lower surface and the side surface of the electrode layer is about 45° or more and about 90° or less. The passivation layer includes a first portion disposed on a side surface of the first conductivity type semiconductor and having a first thickness, and a second portion on a side surface of the electrode layer and having a second thickness different from the first thickness.

A method and system for rapid and efficient mass transfer of a quantity of micro LEDs from storage onto a display substrate provides a micro LED which includes an electrode part, a luminous part, and a suspending part. The electrode part includes at least one electrode. The luminous part emits a certain color of light. The matter density of the suspending part is reduced to be less than that of a liquid holding the quantity of micro LEDs in suspension, and also less than the matter density of the other two parts of the micro LED. Even before illumination, the suspending part has the same color as the color of light to be emitted by that micro LED. A mass transfer system and a mass transfer method are disclosed.

A light-emitting element includes a core comprising a first semiconductor layer, a second semiconductor layer disposed on the first semiconductor layer, and an emissive layer disposed between the first semiconductor layer and the second semiconductor layer, an interlayer dielectric film surrounding a side surface of the core, a first element insulating film surrounding an outer surface of the interlayer dielectric film, and a second element insulating film surrounding an outer surface of the first element insulating film. The interlayer dielectric film includes an oxide insulating material having a dielectric constant of about 10 or more, and the interlayer dielectric film has a thickness of less than or equal to about 5 nm.

A method for fabricating a light emitting element includes preparing a substrate, and forming a first semiconductor material layer, a light emitting material layer, a second semiconductor material layer and an electrode material layer on the substrate, forming semiconductor rods spaced apart from each other by etching the first semiconductor material layer, the light emitting material layer, the second semiconductor material layer and the electrode material layer in a direction perpendicular to an upper surface of the substrate, forming an insulating layer surrounding sides of the semiconductor rods through a sol-gel process by immersing the substrate, including the semiconductor rods, in a solution containing a precursor material, and forming light emitting elements by separating the semiconductor rods, including the insulating layer, from the substrate, and the light emitting elements have an external quantum efficiency of 20.2±0.6%.

A micro light-emitting device includes an epitaxial structure and a bridge connection structure. The epitaxial structure includes a first mesa surface and a second mesa surface which are located on the same side of the epitaxial structure with a height difference therebetween, which have the same widths in a first direction, and which respectively have center points in the first direction that are aligned in a second direction perpendicular to the first direction. The bridge connection structure includes a first bridge connection layer that is formed on the first and second mesa surfaces so as to be symmetrically disposed on at least one of the first and second mesa surfaces with a line of symmetry thereof being in the second direction and passing through the center points of the first and second mesa surfaces. A method for making the same, and a light-emitting apparatus including the same are also disclosed.

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.

In an embodiment a method includes providing the first component part with a partially exposed first insulating layer, a plurality of first through-vias and an exposed first contact layer structured in places and planarized in places, wherein the first through-vias are each laterally enclosed by the first insulating layer, and wherein the first contact layer partially covers the first insulating layer and completely covers the first through-vias; providing the second component part with a partially exposed second insulating layer, a plurality of second through-vias and an exposed second contact layer structured in places and planarized in places, wherein the second through-vias are each laterally enclosed by the second insulating layer, and wherein the second contact layer partially covers the second insulating layer and completely covers the second through-vias and joining the component parts such that the contact layers overlap each other thereby mechanically and electrically connecting the component parts to each other by a direct bonding process at the contact layers.

A light emitting diode (LED) includes a n-doped semiconductor material layer, a p-doped semiconductor material layer, an active region disposed between the n-doped semiconductor layer and the p-doped semiconductor layer, and a photonic crystal grating configured to increase the light extraction efficiency of the LED.

A light-emitting device is provided. The light emitting device includes a support substrate having a light-emitting cell region, a pad region and an edge region, the edge region surrounding the light-emitting cell region and the pad region; a plurality of unit light-emitting devices arranged in a matrix in the light-emitting cell region and spaced apart from each other; a plurality of pads formed in the pad region; partition walls arranged on the plurality of unit light-emitting devices, the partition walls defining a plurality of cell spaces respectively corresponding to the plurality of unit light-emitting devices; and a plurality of fluorescent layers arranged on the plurality of unit light-emitting devices in the plurality of cell spaces. The light-emitting device has a cuboid shape, in which a first length in a first direction is greater than a second length in a second direction.

Provided are a transfer method, a display device, and a storage medium. The transfer method includes: performing partial cutting on preset scribe lines (22) on an epitaxial layer to obtain to-be-transferred wafers (24) after cutting (S1); adhering a temporary substrate (26) on the to-be-transferred wafers (24) through adhering a first release adhesive (25) to first side faces of the to-be-transferred wafers (24), and removing a growth substrate (21) (S2); adhering the to-be-transferred wafers (24) to the blue tape (28) through adhering a second release adhesive (27) to second side faces of the to-be-transferred wafers (24), and removing the temporary substrate (26) (S3); jacking up the blue tape (28) with a roller so that remaining scribe lines (23) on the to-be-transferred wafers (24) are separated by breaking under action of stress (S4).