A nitride semiconductor multilayer structure includes a first nitride semiconductor layer; a second nitride semiconductor layer; and a third nitride semiconductor layer formed between the first nitride semiconductor layer and the second nitride semiconductor layer. The third nitride semiconductor layer includes a first region and a second region that surrounds the first region in a same plane, and an indium content of the second region is lower than an indium content of the first region.

The present invention discloses a semiconductor structure with an epitaxial layer, including a substrate, a blocking layer on said substrate, wherein said blocking layer is provided with predetermined recess patterns, multiple recesses formed in said substrate, wherein each of said multiple recesses is in 3D diamond shape with a centerline perpendicular to a surface of said substrate, a buffer layer on a surface of each of said multiple recesses, and an epitaxial layer comprising a buried portion formed on said buffer layer in each of said multiple recesses and only one above-surface portion formed directly above said blocking layer and directly above said recess patterns of said blocking layer, and said above-surface portion directly connects said buried portion in each of said multiple recesses, and a first void is formed inside each of said buried portions of said epitaxial layer in said recess.

Provided are: a near infrared light-emitting semiconductor element that does not contain any harmful elements and that makes it possible to obtain near infrared light of a stable wavelength in a narrow band regardless of the operating environment; and a method for producing the near infrared light-emitting semiconductor element. GaN is used in the method for producing a near infrared light-emitting semiconductor element, and an active layer added in order to substitute Tm with Ga is formed on GaN in a reaction container at a growth rate of 0.1-30 μm/h without removal from said reaction container using an organometallic vapor phase growth method under temperature conditions of 600-1400° C. in a series of formation steps including formation of a p-type layer and an n-type layer. GaN is used in the near infrared light-emitting semiconductor element, and said near infrared light-emitting semiconductor element includes an active layer sandwiched between an n-type layer and a p-type layer on a substrate. An organometallic vapor phase growth method is used to add the active layer to the GaN in order to substitute Tm with Ga.

A display device includes: a substrate including a pixel; a scan line for supplying a scan signal to the pixel; a data line for supplying a data signal to the pixel; a first power line for supplying a first driving power source to the pixel; a second power line for supplying a second driving power source to the pixel; and a third power line for supplying a ground voltage to the pixel. The pixel includes: first and second electrodes spaced apart from each other on the substrate; a plurality of light emitting elements, each of the light emitting elements having first and second end portions in a length direction thereof and being arranged between the first electrode and the second electrode; and a first switch electrically connected between the third power line and the first electrode. The first switch is configured to be turned on by a control signal.

A method of producing microelectronic components includes forming a functional layer system; applying a laminar carrier to the functional layer system; attaching a workpiece to a workpiece carrier; utilizing incident radiation of a laser beam is focused in a boundary region between a growth substrate and the functional layer system, and a bond between the growth substrate and the functional layer system in the boundary region is weakened or destroyed; separating a functional layer stack from the growth substrate, wherein a vacuum gripper having a sealing zone that circumferentially encloses an inner region is applied to the reverse side of the growth substrate, a negative pressure is generated in the inner region such that separation of the functional layer stack from the growth substrate is initiated in the inner region; and the growth substrate held on the vacuum gripper is removed from the functional layer stack.

An optoelectronic device including one or a plurality of light-emitting diodes, each light-emitting diode including a three-dimensional semiconductor element, an active area resting on the three-dimensional semiconductor element and a stack of semiconductor layers covering the active area, the active area including a plurality of quantum wells, said stack being in mechanical contact with a plurality of quantum wells.

A semiconductor device having a planar III-N semiconductor layer, comprising a substrate comprising a wafer (101) and a buffer layer (102), of a buffer material different from a material of the wafer, the buffer layer having a growth surface (1021); an array of nano structures (1010) epitaxially grown from the growth surface; a continuous planar layer (1020) formed by coalescence of upper parts of the nano structures at an elevated temperature T, wherein the number of lattice cells spanning a center distance between adjacent nano structures are different at the growth surface and at the coalesced planar layer; a growth layer (1030), epitaxially grown on the planar layer (1020).

Provided in the present specification is a novel structured semiconductor light-emitting element capable of preventing an electrode forming failure due to an arrangement error occurring during assembly or transfer of semiconductor light-emitting elements on a substrate, when a display device is implemented using the semiconductor light-emitting elements, wherein at least one of a plurality of semiconductor light-emitting elements according to one embodiment of the present disclosure comprises: a first conductive type semiconductor layer; a second conductive type semiconductor layer located on the first conductive type semiconductor layer; an active layer arranged between the first conductive type semiconductor layer and the second conductive type semiconductor layer; a second conductive type electrode located on the second conductive type semiconductor layer; and a first conductive type electrode located on at least a one-side stepped portion of the first conductive type semiconductor layer exposed by etching a portion of the second conductive type semiconductor layer and the active layer.

The present invention discloses a two-dimensional AlN material and its preparation method and application, wherein the preparation method comprises the following steps: (1) selecting a substrate and its crystal orientation; (2) cleaning the surface of the substrate; (3) transferring a graphene layer to the substrate layer; (4) annealing the substrate; (5) using the MOCVD process to introduce H.sub.2 to open the graphene layer and passivate the surface of the substrate; and (6) using the MOCVD process to grow a two-dimensional AlN layer. The preparation method of the present invention has the advantages that the process is simple, time saving and efficient. Besides, the two-dimensional AlN material prepared by the present invention can be widely used in HEMT devices, deep ultraviolet detectors or deep ultraviolet LEDs, and other fields.

A light-emitting diode (LED) device includes a substrate, an epitaxial layered structure disposed on the substrate, a current-spreading layer disposed on the epitaxial layered structure, a current-blocking unit disposed on the current-spreading layer, and a distributed Bragg reflector. The epitaxial layered structure, the current-spreading layer and the current-blocking unit are covered by the distributed Bragg reflector. One of the current-spreading layer, the current-blocking unit, and a combination thereof has a patterned rough structure. A method for manufacturing the LED device is also disclosed.