A display device, including a substrate having a plurality of metal pads; and a plurality of semiconductor light emitting devices electrically connected to the metal pads. A respective semiconductor light emitting device includes an n-type semiconductor layer, an active layer and a p-type semiconductor layer, a conductive electrode on the p-type semiconductor layer; and a passivation layer configured to surround the respective semiconductor light emitting device and including a through hole through which the conductive electrode is exposed. Further, the conductive electrode includes a protruding portion protruding through the through hole of the passivation layer and overlapping outer surfaces of the passivation layer. Also, the protruding portion of the conductive electrode contacts a corresponding metal pad, and a width of the protruding portion of the conductive electrode is greater than a width of the corresponding metal pad.

Luminescent microspheres and a preparation method thereof are disclosed. The preparation method includes: 1) preparing cadmium oxide-doped silica microspheres; 2) adding the silica microspheres to a mixed solution of octadecene/oleic acid or trioctylamine (TOA)/oleic acid, and heating a resulting mixture to a boiling point so that the microspheres swell at high temperature and the oleic acid penetrates into the microspheres to react with CdO to obtain an organic cadmium-adsorbed silica suspension; and 3) adding a selenium precursor to the obtained organic cadmium-adsorbed silica suspension to obtain the luminescent microspheres, where, the selenium precursor reacts with the adsorbed organic cadmium to form CdSe. The luminescent microspheres provided in the present disclosure have high fluorescence efficiency and prominent stability, require no barrier materials such as barrier films for protection, and can be directly used for light conversion materials with high color gamut such as luminescent films, luminescent plates, Mini-LEDs, and Micro-LEDs.

Luminescent microspheres and a preparation method thereof are disclosed. The preparation method includes: 1) preparing cadmium oxide-doped silica microspheres; 2) adding the silica microspheres to a mixed solution of octadecene/oleic acid or trioctylamine (TOA)/oleic acid, and heating a resulting mixture to a boiling point so that the microspheres swell at high temperature and the oleic acid penetrates into the microspheres to react with CdO to obtain an organic cadmium-adsorbed silica suspension; and 3) adding a selenium precursor to the obtained organic cadmium-adsorbed silica suspension to obtain the luminescent microspheres, where, the selenium precursor reacts with the adsorbed organic cadmium to form CdSe. The luminescent microspheres provided in the present disclosure have high fluorescence efficiency and prominent stability, require no barrier materials such as barrier films for protection, and can be directly used for light conversion materials with high color gamut such as luminescent films, luminescent plates, Mini-LEDs, and Micro-LEDs.

Provided are an AC electroluminescence device includes a bottom electrode including a first electrode and a second electrode apart from each other, wherein AC power is applied between the first electrode and the second electrode; an electron injecting layer disposed on the bottom electrode; an emission layer disposed on the electron injecting layer; a dielectric layer disposed on the emission layer; a top electrode, which is disposed on the dielectric layer and includes a first portion opposing the first electrode and a second portion opposing the second electrode; a first emission region defined by a first overlapping region of the emission layer between the first portion of the top electrode and the first electrode of the bottom electrode; and a second emission region defined by a second overlapping region of the emission layer between the second portion of the top electrode and the second electrode of the bottom electrode.

Provided are an AC electroluminescence device includes a bottom electrode including a first electrode and a second electrode apart from each other, wherein AC power is applied between the first electrode and the second electrode; an electron injecting layer disposed on the bottom electrode; an emission layer disposed on the electron injecting layer; a dielectric layer disposed on the emission layer; a top electrode, which is disposed on the dielectric layer and includes a first portion opposing the first electrode and a second portion opposing the second electrode; a first emission region defined by a first overlapping region of the emission layer between the first portion of the top electrode and the first electrode of the bottom electrode; and a second emission region defined by a second overlapping region of the emission layer between the second portion of the top electrode and the second electrode of the bottom electrode.

A display device includes a first electrode, a second electrode, a light emitting layer disposed between the first electrode and the second electrode, and an auxiliary electrode connected to the second electrode. The auxiliary electrode includes a first auxiliary electrode and a second auxiliary electrode disposed between the first auxiliary electrode and the second electrode. The second auxiliary electrode contains at least one of an alkaline earth metal element and a lanthanoid element.

A light emitting element includes: a protrusion (28) surrounding a light emitting region (30); a first electrode (31) including a first portion (31A) formed on a portion of a base (26) constituting the light emitting region (28) and a second portion (31B) extending from the first portion (31A) and formed on the protrusion (28); an organic layer (33) formed on and above the first electrode (31); a second electrode (32) formed on the organic layer (33); a first wavelength conversion layer (41.sub.1, 41.sub.2) that is formed between the second portion (31B) of the first electrode (31) and a portion of the organic layer (33) formed above the protrusion (28) and converts light emitted from the organic layer (33) into light on a long wavelength side; and a second wavelength conversion layer (42.sub.1, 42.sub.2) that is formed on or above the second electrode (32) and converts light emitted from the organic layer (33) into light on a long wavelength side.

A display device includes a plurality of light-emitting layers each capable of emitting light in a reference direction orthogonal to a light-emitting surface, and a light-blocking portion capable of blocking part of light traveling from the light-emitting surface in directions inclined with respect to the reference direction. The plurality of light-emitting layers include a first light-emitting layer capable of emitting light with a first peak wavelength and a second light-emitting layer capable of emitting light with a second peak wavelength that is longer than the first peak wavelength. The first light-emitting layer has, compared with the second light-emitting layer, a large ratio of the part of light that can be blocked by the light-blocking portion to light traveling in at least one certain direction out of the inclined directions.

A light emitting diode (LED) having a uniform optimal luminance pattern includes an outer cylindrical section, an inner cone shape section completely contained inside the outer section, and a top section having a plurality of micro-lenses covering the top surface of the outer cylindrical section.

A light emitting diode (LED) having a uniform optimal luminance pattern includes an outer cylindrical section, an inner cone shape section completely contained inside the outer section, and a top section having a plurality of micro-lenses covering the top surface of the outer cylindrical section.