A display device including a substrate and a plurality of pixels in a display region of the substrate. Each of the pixels includes first and second sub-pixels, and each of the first and second sub-pixels has a light emitting region for emitting light. The first sub-pixel includes a first light emitting element in the light emitting region and configured to emit visible light. The second sub-pixel includes a second light emitting element in the light emitting region and configured to emit infrared light and a light receiving element configured to receive the infrared light emitted from the second light emitting element to detect a user's touch. The second light emitting element and the light receiving element in the second sub-pixel are electrically insulated from and optically coupled to each other to form a photo-coupler.

A light emitting diode (LED) precursor is provided. The LED precursor comprises a substrate (10), an LED structure (30) comprising a plurality of Group III-nitride layers, and a passivation layer (40). The LED structure comprises a p-type semiconductor layer (36), an n-type semiconductor layer (32), and an active layer (34) between the p-type and n-type semiconductor layers. Each of the plurality of Group III-nitride layers comprises a crystalline Group III-nitride. The LED structure has a sidewall (37) which extends in a plane orthogonal to a (0001) crystal plane of the Group III-nitride layers. The passivation layer is provided on the sidewall of the LED structure such that the passivation layer covers the active layer. The passivation layer comprises a crystalline Group III-nitride with a bandgap higher than a bandgap of the active layer. The LED structure is shaped such that the sidewall of the LED structure is aligned with a non-polar crystal plane of each the Group III-nitride layers of the LED structure.

The present disclosure relates to a patterned substrate, an epitaxial wafer, a manufacturing method, a storage medium and an LED chip. The patterned substrate is applied to a Micro LED, a substrate body of the patterned substrate is provided with at least one receiving groove capable of receiving at least part epitaxial material dropped during an epitaxial process. According to the patterned substrate provided in the present disclosure, at least part excess epitaxial material produced during a high-speed rotational molding process of an epitaxial layer in an MOCVD furnace may drop into the receiving groove and not remain on the epitaxial layer, thereby solving the problem of the thickness of the epitaxial layer being uneven, and thus improving wavelength uniformity, that is, the patterned substrate provided in the present disclosure at least solves the problem of wavelength non-uniformity.

An embodiment of the disclosed technology provides a scalable method of growing nitride-based LED devices on a growth substrate and transferring an individually selected nitride-based LED device to a receiving substrate. The method can include subdividing the growth substrate into delimited areas using a patterned grid. A mechanical release layer can be grown on the growth substrate. A set of nitride-based LED devices can be grown on the mechanical release layer, such that a nitride-based LED device can be grown in each delimited area. An individual nitride-based LED device can be selected and released from the growth substrate. The selected nitride-based LED device can be transferred to the receiving substrate.

A preparation method for a resonant cavity light-emitting diode comprises: forming a first mirror and a first semiconductor layer on a substrate in sequence; forming an active layer on the first semiconductor layer; and forming a second semiconductor layer and a second mirror on the active layer in sequence. The preparation method further comprises: planarizing at least one of a first contact surface between the first semiconductor layer and the first mirror, and a second contact surface between the second semiconductor layer and the second mirror. Since the first contact surface between the first semiconductor layer and the first mirror, and/or the second contact surface between the second semiconductor layer and the second mirror is planarized, the light emission uniformity of the resonant cavity light-emitting diode can be improved.

A light emitting apparatus includes a laminated structure including a plurality of columnar portions. The plurality of columnar portions each includes a first semiconductor layer, a second semiconductor layer different from the first semiconductor layer in terms of conductivity type, and a light emitting layer provided between the first semiconductor layer and the second semiconductor layer. The second semiconductor layer has a first section, and a second section that surrounds the first section in a plan view along a lamination direction in which the first semiconductor layer and the light emitting layer are laminated structured on each other and has a bandgap wider than a bandgap of the first section. The second section forms a side surface of each of the columnar portions.

A method for manufacturing a light-emitting element includes providing the light-emitting element that includes a light-emitting layer with an emission wavelength of not more than 306 nm and a p-type layer including AlGaInN including Mg as an acceptor, and removing hydrogen in the p-type layer from the light-emitting element by irradiating the light-emitting element with ultraviolet light at a wavelength of not more than 306 nm from outside and treating the light-emitting element with heat in a state in which a reverse voltage, or a forward voltage lower than a threshold voltage of the light-emitting element, or no voltage is applied to the light-emitting element. The removing of hydrogen in the p-type layer from the light-emitting element is performed in a N.sub.2 atmosphere at not less than 650° C. or in a N.sub.2+O.sub.2 atmosphere at not less than 500° C.

A method of manufacturing a light-emitting element includes: providing a semiconductor structure including: a first layer containing gallium and nitrogen, a second layer of a first conductive type, the second layer containing gallium, aluminum, and nitrogen and being located on or above the first layer, an active layer located on or above the second layer, and a third layer of a second conductive type, the third layer located on or above the active layer, wherein a thickness of the first layer is larger than a thickness of the second layer; performing chemical-mechanical polishing from a first layer side to reduce the thickness of the first layer; and performing dry etching from the first layer side to remove the first layer and reduce the thickness of the second layer.

LED chips and related fabrication methods are disclosed. A LED chip includes an active layer arranged on or over a light-transmissive substrate having a light extraction surface. The light extraction surface comprises a microtextured etched surface having a non-repeating, irregular textural pattern (e.g., with an average feature depth in a range of from 120 nm to 400 nm, and preferably free of any plurality of equally sized, shaped, and spaced textural features). The microtextured etched surface may be formed by applying a micromask having first and second solid materials of different etching rates over the light extraction surface, and exposing the micromask to an etchant (e.g., via reactive ion etching) to form a microtextured etched surface having a non-repeating, irregular textural pattern. Lumiphoric material may be applied over the microtextured surface.

A substrate for epitaxial growth includes a central region that has a center of the substrate and that serves as a non-modified region, and a peripheral region that surrounds the central region in a manner to be spaced apart from the center of the substrate by a distance and that serves as a modified region having a plurality of modified points. A method for manufacturing a substrate for epitaxial growth includes providing a substrate and forming a plurality of modified points in an interior of the substrate in position corresponding to the modified region. A semiconductor device including the substrate and a method for manufacturing the semiconductor device are also disclosed.