A light-emitting device includes light-emitting elements each having a light-extracting surface, light-transmissive members and a covering member, The light-transmissive members each has an upper surface and a lower surface facing the light-extracting surface of at least one of the light-emitting elements. The covering member integrally covers lateral surfaces of the light-emitting elements and lateral surfaces of the light-transmissive members such that a pair of electrodes of the light-emitting elements are exposed from the covering member at a lower surface of the covering member. At a lower surface of the light-emitting device, the light-emitting elements are arranged in a plurality of columns and a plurality of rows, an alignment direction of the electrodes in one of the light-emitting elements is rotated by 90° in a prescribed. direction from an alignment direction of the electrodes in an adjacent one of the light-emitting elements in one of a column direction and a row direction.

An electronic device is provided in this disclosure. In some embodiments, the electronic device includes a first substrate and a second substrate adjacent to the first substrate. In some embodiments, the electronic device includes a plurality of organic light emitting diodes, a filter layer, and a third substrate. At least a part of the plurality of organic light emitting diodes are disposed on the first substrate. The filter layer is disposed at least on the second substrate. The third substrate is disposed corresponding to the first substrate and the second substrate. The plurality of organic light emitting diodes and the filter layer are disposed under the third substrate.

A light emitting device including a substrate, a first light emitter to emit light having a first color temperature, and a second light emitter to emit light having a second color temperature, in which the first light emitter has a first converter including first phosphors and a first resin, each first phosphor having different half-value widths, the second light emitter has a second converter including second phosphors and a second resin, each second phosphor having different peak wavelengths, at least one phosphor of the first converter has a half-value width of 33 nm to 110 nm, a distance between peak wavelengths of at least two phosphors of the second converter is 150 nm or less, at least one phosphor of the first converter has a particle size of 5 um to 50 um, and a thickness of the second converter is in 0.07 mm to 1.5 mm.

Example implementations include a method of mass transfer of display elements, by depositing one or more resist layers between one or more display elements disposed on a photoemitting layer, depositing at least one stress buffer layer between the resist layers, removing the resist layer and at least a portion of the photoemitting layer disposed in contact with the resist layers to form resist layer gaps on a wafer substrate, dicing the wafer substrate at the resist layer gaps to form at least one wafer die, separating the wafer substrate from the display elements by irradiation at corresponding first surfaces of the display elements, removing the stress buffer layers from the wafer die, and bonding the portion of the display elements to a first handler substrate at one or more electrode pads of the portion of the display elements.

A plant cultivation light source includes a plurality of light sources configured to be turned on or turned off depending on a selected plant and a growth stage of the selected plant, and a controller. The controller is operable to turn on the light sources during a light period such that the light sources are operable to emit a light having a spectrum with a plurality of peaks to the selected plant. The light period including a first period and a second period and the first period preceding or following the second period. The controller is operable to adjust the spectrum of the light to alternate the first period and the second period during the light period.

Discussed is a display device including a base part; a plurality of assembly electrodes disposed on the base part and having a first electrode and a second electrode that generate an electric field when power is applied; a dielectric layer disposed to cover the plurality of assembly electrodes; and a plurality of semiconductor light emitting devices disposed on a surface of the dielectric layer, wherein one surface of the plurality of semiconductor light emitting devices facing the dielectric layer and one surface of the dielectric layer facing the plurality of semiconductor light emitting devices respectively comprise a concave-convex structure.

Discussed is a display device including a base portion; assembly electrodes that extend in one direction and are disposed on the base portion at predetermined intervals; a dielectric layer deposited on the base portion to cover the assembly electrodes; a first wiring electrode that extends in the same direction as the assembly electrodes and is disposed on the dielectric layer so as not to overlap the assembly electrodes; a partition wall portion deposited on the dielectric layer while arranging cells at predetermined intervals to overlap the assembly electrodes and the first wiring electrode along an extension direction of the assembly electrodes; and semiconductor light-emitting elements seated in the cells, respectively, wherein a solder layer electrically connecting a semiconductor light-emitting element seated in a cell and the first wiring electrode overlapping the cell is filled in the cell from among the plurality semiconductor light emitting elements and the cells.

A semiconductor light-emitting element supply device according to an embodiment of the present invention supplies semiconductor light-emitting elements in a fluid chamber in which self-assembly occurs, the semdconductor light-emitting element supply device comprising: a tray disposed in the fluid chamber; a transfer unit which includes a magnet and a magnet accommodating part for accommodating the magnet and which transfers the semiconductor light-emitting elements by using magnetic force; a supply unit disposed above the tray to supply the transferred semiconductor light-emitting elements to the tray; and a control unit for controlling operations of the tray, the transfer unit and the supply unit, wherein the control unit controls the position of the magnet accommodated in the magnet accommodating part so that the semiconductor light-emitting elements are adhered on one surface of the magnet accommodating part or the adhered semiconductor light-emittng elements are separated from the one surface of the magnet accommodating part.

A method of fabricating and transferring high quality and manufacturable light-emitting devices, such as micro-sized light-emitting diodes (μLEDs), edge-emitting lasers and vertical-cavity surface-emitting lasers (VCSELs), using epitaxial later over-growth (ELO) and isolation methods. III-nitride semiconductor layers are grown on a host substrate using a growth restrict mask, and the III-nitride semiconductor layers on wings of the ELO are then made into the light-emitting devices. The devices are isolated from the host substrate to a thickness equivalent to the growth restrict mask and then transferred or lifted from of the host substrate. Back-end processing of the devices is then performed, such as attaching distributed Bragg reflector (DBR) mirrors, forming cladding layers, and/or adding heatsinks.

A display apparatus having a noncontact input function is provided. The display apparatus has a first function of detecting, with a light-receiving device, light irradiated from a light source outside a display portion and blocked by a pointing object to recognize the position pointed by the pointing object, and a second function of detecting, with the light-receiving device, light irradiated from a light source inside or outside the display portion and reflected by the pointing object to recognize the position pointed by the pointing object. The display apparatus can operate by switching the first function and the second function in accordance with the intensity of the light irradiated from the light source outside the display portion.