A light-emitting device includes an epitaxial structure, and first and second electrodes. The epitaxial structure has a first surface and a second surface opposite to each other, first dislocation density regions and second dislocation density regions. The first dislocation density regions and the second dislocation density regions are alternately disposed between the first surface and the second surface. A dislocation density of each first dislocation density region is lower than a dislocation density of each second dislocation density region and a quantity of the first dislocation density regions is at least ten. The epitaxial structure further includes a light-emitting layer, a first-type semiconductor layer and a second-type semiconductor layer disposed on two opposite sides of the light-emitting layer. The first electrode and the second electrode are electrically connected to the first-type semiconductor layer and the second-type semiconductor layer, respectively. A light-emitting device structure adopting the light-emitting device is provided.

A display device includes a first electrode and a second electrode disposed on a substrate and spaced apart from each other, a light emitting element on the substrate and having a first end and a second end, a third electrode disposed on the light emitting element, and electrically connecting the first electrode with the first end of the light emitting element, an insulating pattern disposed on the third electrode and exposing the second end of the light emitting element, and a fourth electrode on the substrate, and electrically connecting the second electrode with the second end of the light emitting element. A void may be formed between the light emitting element and the insulating pattern.

The present application provides a light emitting device, a method for making the same and a display apparatus. The light emitting device includes: a driving backplane; at least one set of driving electrodes disposed on the driving backplane, each set of driving electrodes including a first driving electrode and a second driving electrode; an epitaxial layer located on a side of the at least one set of driving electrodes away from the driving backplane; and at least one set of metal electrodes located on a side of the epitaxial layer close to the driving backplane, each set of metal electrodes including a first metal electrode and a second metal electrode, the first metal electrode and the second metal electrode being respectively connected to a first driving electrode and a second driving electrode, and a filling material being disposed between the first metal electrode and the second metal electrode.

The present application provides a light emitting device, a method for making the same and a display apparatus. The light emitting device includes: a driving backplane; at least one set of driving electrodes disposed on the driving backplane, each set of driving electrodes including a first driving electrode and a second driving electrode; an epitaxial layer located on a side of the at least one set of driving electrodes away from the driving backplane; and at least one set of metal electrodes located on a side of the epitaxial layer close to the driving backplane, each set of metal electrodes including a first metal electrode and a second metal electrode, the first metal electrode and the second metal electrode being respectively connected to a first driving electrode and a second driving electrode, and a filling material being disposed between the first metal electrode and the second metal electrode.

Disclosed is a color emissive LED array having a substantially flat backplane which has circuitry. The color emissive LED array includes a plurality of multi thickness color emissive LED units disposed in an array on the substantially flat backplane; The plurality of multi thickness color emissive LED units have a thickness of the first color emissive LED unit is less than a thickness of the second color emissive LED unit and less than a thickness of the third color emissive LED unit. Meanwhile, the substantially flat backplane having circuitry has one or more anode and one or more cathode. Further, the array is attached to the substantially flat backplane having circuitry by using a jointing layer.

Disclosed is a color emissive LED array having a substantially flat backplane which has circuitry. The color emissive LED array includes a plurality of multi thickness color emissive LED units disposed in an array on the substantially flat backplane; The plurality of multi thickness color emissive LED units have a thickness of the first color emissive LED unit is less than a thickness of the second color emissive LED unit and less than a thickness of the third color emissive LED unit. Meanwhile, the substantially flat backplane having circuitry has one or more anode and one or more cathode. Further, the array is attached to the substantially flat backplane having circuitry by using a jointing layer.

A semiconductor device is provided, which includes a first semiconductor structure, a second semiconductor structure and a light-emitting structure. The light-emitting structure is located between the first semiconductor structure and the second semiconductor structure. The light-emitting structure includes a first multiple quantum well structure containing aluminum and a plurality of semiconductor stacks. Each of the semiconductor stacks is stacked by a well layer and a barrier layer. The light-emitting structure emits an incoherent light. The well layer and the barrier layer in each of the semiconductor stacks include the same quaternary semiconductor material which includes indium (In). The well layer has a first In content percentage larger than 0.53, and the barrier layer has a second In content percentage less than 0.53.

A semiconductor device is provided, which includes a first semiconductor structure, a second semiconductor structure and a light-emitting structure. The light-emitting structure is located between the first semiconductor structure and the second semiconductor structure. The light-emitting structure includes a first multiple quantum well structure containing aluminum and a plurality of semiconductor stacks. Each of the semiconductor stacks is stacked by a well layer and a barrier layer. The light-emitting structure emits an incoherent light. The well layer and the barrier layer in each of the semiconductor stacks include the same quaternary semiconductor material which includes indium (In). The well layer has a first In content percentage larger than 0.53, and the barrier layer has a second In content percentage less than 0.53.

The present invention discloses a bidirectional ultraviolet light emitting diode (UV LED) based on N—ZnO/N—GaN/N—ZnO heterojunction as well as its preparation method. The LED includes: N—ZnO microwires, a N—GaN film, a PMMA protective layer and alloy electrodes; and its preparation method includes the following steps: lay two N—ZnO microwires on the N—GaN film, then spin-coat a PMMA protective layer on the film to fix the N—ZnO microwires until the PMMA protective layer spreads over the N—ZnO microwires, and then place the film on a drying table to solidify the PMMA protective layer; then etch the PMMA protective layer with O.sub.2 to expose the N—ZnO microwires, and prepare alloy electrodes on different N—ZnO microwires to construct a N—ZnO/N—GaN/N—ZnO heterojunction to constitute a complete device. The present invention constructs an N/N/N symmetrical structure; the device is composed of N—ZnO and N—GaN, emits light in the ultraviolet region and has a small turn-on voltage.

A light-emitting device is provided, including a light-emitting unit and an optical layer. The light-emitting unit includes a light-emitting chip and an encapsulation disposed thereon. The optical layer is disposed on the light-emitting unit, the optical layer having a first region overlapping the light-emitting chip in a top view direction of the light-emitting device and a second region not overlapping the light-emitting chip in the top view direction of the light-emitting device, wherein the transmittance of the first region is less than the transmittance of the second region.