A display device may include a light emitting element including a first end having a first surface, and a second end having a second surface parallel to the first surface, an organic pattern that overlaps the light emitting element and exposes the first and second surfaces, a first electrode disposed on a substrate and electrically contacting the first end, and a second electrode disposed on the substrate and spaced apart from the first electrode, and electrically contacting the second end. A surface area of the first surface may be less than that of the second surface. A top surface of the organic pattern may be a curved surface.

Disclosed herein are techniques for bonding LED components. According to certain embodiments, a first component including a semiconductor layer stack is hybrid bonded to a second component including a substrate that has a different thermal expansion coefficient than the semiconductor layer stack. The semiconductor layer stack includes an n-side semiconductor layer, an active light emitting layer, and a p-side semiconductor layer. The first component and the second component further include first contacts and second contacts, respectively. To hybrid bond the two components, the first contacts are aligned with the second contacts. Then dielectric bonding is performed to bond respective dielectric materials of both components. The dielectric bonding is followed by metal bonding of the contacts, using annealing. To compensate run-out between the first contacts and the second contacts, aspects of the present disclosure relate to changing a curvature of the first component and/or the second component during the annealing stage.

Disclosed herein is an apparatus including a first three-dimensional (3-D) structure, a second 3-D structure, and a conductive layer. The first 3D structure includes a first-type doped semiconductor material having a semi-polar facet. The second 3-D structure forms a light-emitting diode (LED) and includes a second-type doped semiconductor material, an active layer, and the first-type doped semiconductor material. The conductive layer at least partially overlays and is in ohmic contact with the semi-polar facet. The conductive layer is configured to carry current that flows between the semi-polar facet and the active layer. In some embodiments, the first-type doped semiconductor material may include an N-type doped semiconductor material, and the second-type doped semiconductor material may include a P-type doped semiconductor material. The first-type doped semiconductor material of both 3-D structures may be etched from a common first-type doped semiconductor epitaxial layer.

A light-emitting chip transfer system and a light-emitting chip transfer method are provided. The light-emitting chip transfer system includes a growth substrate (1) grown with light-emitting chip (2), where the light-emitting chip (2) is magnetic and is bonded to the growth substrate (1) through a laser dissociation layer; a laser device configured to irradiate a laser to the laser dissociation layer to dissociate the laser dissociation layer; and a magnetic field generating device capable of generating a magnetic field in a gap between the light-emitting chip (2) and a chip bonding area corresponding to the light-emitting chip.

A laser light is used to modify the surface of the gallium semiconductor layer of an LED. The parameters of the laser are selected so that the laser interacts with the gallium semiconductor layer in a desired manner to yield the desired surface properties. For example, if a particular surface roughness is desired, the power of the laser light is selected so that the laser light penetrates the gallium semiconductor layer to a depth matching the desired surface roughness. The same principles can also be applied in a process that creates features such as trenches, pits, lenses, and mirrors on the gallium semiconductor layer of an LED. The laser projector is operated to irradiate a region of the gallium semiconductor layer to create a region of metallic gallium. The desired surface roughness and the different features can advantageously improve the beam collimation, light extraction, and other properties of the LED.

A semiconductor light-emitting element comprises, in this order, a substrate, a reflective layer, a first conductivity type cladding layer made of InGaAsP containing at least In and P, a semiconductor light-emitting layer having an emission central wavelength of 1000 nm to 2200 nm and a second conductivity type cladding layer made of InGaAsP containing at least In and P, the second conductivity type cladding layer being configured to be on a light extraction side, a surface of a light extraction face of the second conductivity type cladding layer being a roughened surface which has a surface roughness Ra of 0.03 μm or more and has a random irregularity pattern. The surface of the light extraction face has a skewness Rsk of −1 or more, and a protective film is provided on the light extraction face.

A light emitting device including a substrate having a protruding pattern on an upper surface thereof, a first sub-unit disposed on the substrate, a second sub-unit disposed between the substrate and the first sub-unit, a third sub-unit disposed between the substrate and the second sub-unit, a first insulation layer at least partially in contact with side surfaces of the first, second, and third sub-units, and a second insulation layer at least partially overlapping with the first insulation layer, in which at least one of the first insulation layer and the second insulation layer includes a distributed Bragg reflector.

Compound semiconductor and silicon-based structures are epitaxially formed on semiconductor substrates and transferred to a carrier substrate. The transferred structures can be used to form discrete photovoltaic and light-emitting devices on the carrier substrate. Silicon-containing layers grown on doped donor semiconductor substrates and compound semiconductor layers grown on off-cut semiconductor substrates form elements of the devices. The carrier substrates may be electrically insulating substrates or include electrically insulating layers to which photovoltaic and/or light-emitting structures are bonded.

A display device and a method for fabrication thereof are provided. A display device includes a plurality of pixel electrodes spaced from each other on a substrate, a plurality of light emitting elements respectively located on the plurality of pixel electrodes, a common electrode layer on the plurality of light emitting elements, and an emission defining layer defining emission areas in which the plurality of light emitting elements are located, wherein the emission defining layer is in contact with a side surface of each of the plurality of light emitting elements and surrounds the side surface of each of the plurality of light emitting elements.

A transfer method includes providing a first light emitting diode on a first substrate, performing a partial laser liftoff of the first light emitting diode from the first substrate, laser bonding the first light emitting diode to the backplane after performing the partial laser liftoff, and separating the first substrate from the first light emitting diode after the laser bonding.