A method of producing a plurality of optoelectronic semiconductor chips includes a) providing a layer composite assembly having a principal plane which delimits the layer composite assembly in a vertical direction, and includes a semiconductor layer sequence having an active region that generates and/or detects radiation, wherein a plurality of recesses extending from the principal plane in a direction of the active region are formed in the layer composite assembly; b) forming a planarization layer on the principal plane such that the recesses are at least partly filled with material of the planarization layer; c) at least regionally removing material of the planarization layer to level the planarization layer; and d) completing the semiconductor chips, wherein for each semiconductor chip at least one semiconductor body emerges from the semiconductor layer sequence.

A method of producing a plurality of optoelectronic semiconductor chips includes a) providing a layer composite assembly having a principal plane which delimits the layer composite assembly in a vertical direction, and includes a semiconductor layer sequence having an active region that generates and/or detects radiation, wherein a plurality of recesses extending from the principal plane in a direction of the active region are formed in the layer composite assembly; b) forming a planarization layer on the principal plane such that the recesses are at least partly filled with material of the planarization layer; c) at least regionally removing material of the planarization layer to level the planarization layer; and d) completing the semiconductor chips, wherein for each semiconductor chip at least one semiconductor body emerges from the semiconductor layer sequence.

A light emitting device, such as an LED, is formed by forming a plurality of semiconductor nanostructures having a doping of a first conductivity type through, and over, a growth mask layer overlying a doped compound semiconductor layer. Each of the plurality of semiconductor nanostructures includes a nanofrustum including a bottom surface, a top surface, tapered planar sidewalls, and a height that is less than a maximum lateral dimension of the top surface, and a pillar portion contacting the bottom surface of the nanofrustum and located within a respective one of the openings through the growth mask layer. A plurality of active regions on the nanofrustums. A second conductivity type semiconductor material layer is formed on each of the plurality of active regions.

A light emitting device, such as an LED, is formed by forming a plurality of semiconductor nanostructures having a doping of a first conductivity type through, and over, a growth mask layer overlying a doped compound semiconductor layer. Each of the plurality of semiconductor nanostructures includes a nanofrustum including a bottom surface, a top surface, tapered planar sidewalls, and a height that is less than a maximum lateral dimension of the top surface, and a pillar portion contacting the bottom surface of the nanofrustum and located within a respective one of the openings through the growth mask layer. A plurality of active regions on the nanofrustums. A second conductivity type semiconductor material layer is formed on each of the plurality of active regions.

This disclosure discloses a display including a first carrier, a second carrier, a light-emitting unit, a frame, and a protective layer. The first carrier includes a first electrode and a second electrode. The second carrier is arranged below the first carrier and includes a first connection pad and a second connection pad arranged on a side of the second carrier close to the first carrier. The light-emitting unit is arranged on the first carrier. The frame surrounds the light-emitting unit, and the protective layer covers the light-emitting unit. A distance between the first electrode and the second electrode is smaller than that between the first connection pad and the second connection pad.

This disclosure discloses a display including a first carrier, a second carrier, a light-emitting unit, a frame, and a protective layer. The first carrier includes a first electrode and a second electrode. The second carrier is arranged below the first carrier and includes a first connection pad and a second connection pad arranged on a side of the second carrier close to the first carrier. The light-emitting unit is arranged on the first carrier. The frame surrounds the light-emitting unit, and the protective layer covers the light-emitting unit. A distance between the first electrode and the second electrode is smaller than that between the first connection pad and the second connection pad.

The ultraviolet light emitting device includes a substrate; a light emitting structure on the substrate, and including a plurality of compound semiconductors, each including at least a first conductive semiconductor layer, an active layer, and a second conductive semiconductor layer; a first electrode layer on the first conductive semiconductor layer; and a second electrode layer on the second conductive semiconductor layer. The first electrode layer is spaced apart from a side surface of the active layer, and is provided along a peripheral portion of the active layer. At least one of the first and second electrode layers is a reflective layer.

The ultraviolet light emitting device includes a substrate; a light emitting structure on the substrate, and including a plurality of compound semiconductors, each including at least a first conductive semiconductor layer, an active layer, and a second conductive semiconductor layer; a first electrode layer on the first conductive semiconductor layer; and a second electrode layer on the second conductive semiconductor layer. The first electrode layer is spaced apart from a side surface of the active layer, and is provided along a peripheral portion of the active layer. At least one of the first and second electrode layers is a reflective layer.

Micro pick-and-bond heads, assembly methods, and device assemblies. In, embodiments, micro pick-and-bond heads transfer micro device elements, such as (micro) LEDs, en masse from a source substrate to a target substrate, such as a LED display substrate. Anchor and release structures on the source substrate enable device elements to be separated from a source substrate, while pressure sensitive adhesive (PSA) enables device elements to be temporarily affixed to pedestals of a micro pick-and-bond head. Once the device elements are permanently affixed to a target substrate, the PSA interface may be defeated through peeling and/or thermal decomposition of an interface layer.

Micro pick-and-bond heads, assembly methods, and device assemblies. In, embodiments, micro pick-and-bond heads transfer micro device elements, such as (micro) LEDs, en masse from a source substrate to a target substrate, such as a LED display substrate. Anchor and release structures on the source substrate enable device elements to be separated from a source substrate, while pressure sensitive adhesive (PSA) enables device elements to be temporarily affixed to pedestals of a micro pick-and-bond head. Once the device elements are permanently affixed to a target substrate, the PSA interface may be defeated through peeling and/or thermal decomposition of an interface layer.