A display device includes a substrate including a first contact hole disposed on a surface of the substrate, a first connection line disposed on the surface of the substrate and electrically connected to a pad unit disposed on another surface opposite to the surface of the substrate through the first contact hole, a filling part filling a depression of the first connection line formed in the first contact hole to planarize an upper surface of the first connection line, a thin film transistor layer disposed on the substrate and the first connection line, the thin film transistor layer comprising at least one thin film transistor, and a light emitting element layer disposed on the thin film transistor layer, the light emitting element layer including a light emitting element electrically connected to the at least one thin film transistor. The thin film transistor layer comprises a second connection line.

Provided is a light-emitting device wherein short-wavelength light included in emitted white light is attenuated with a small increase in manufacturing cost and a small decrease in luminous flux. The light-emitting device includes a mount board, LED elements mounted on the mount board and emitting first light which is blue light or has a shorter wavelength than blue light, and a sealing resin containing phosphor particles and titanium-dioxide particles and filled on the mount board to integrally seal the LED elements, the phosphor particles being excited by the first light to emit second light. The first light and the second light are mixed and emitted as white light, and transmitting through the sealing resin causes the first light to be attenuated more than the second light by the titanium-dioxide particles.

The present disclosure provides a light emitting device and a method for fabricating the same. The light emitting device comprises: a substrate; a plurality of LED light sources, wherein the LED light source adopts a package form emitting light from four sides and having a reflection layer on a top surface, and the plurality of LED light sources are disposed on the substrate at intervals; and a transparent dielectric layer being disposed at a surface of the substrate and covering the plurality of LED light sources. The invention can be used to improve light-mixing effects.

An optical coupling structure is disposed on a light output surface of a semiconductor LED to facilitate coupling of light emitted by the semiconductor LED through the light output surface. The optical coupling structures comprise light scattering particles and/or air voids embedded in or coated with a thin layer of a material that has an index of refraction close to or matching the index of refraction of the material forming the light output surface of the semiconductor LED.

A display may have a pixel array such as a liquid crystal pixel array. The pixel array may be illuminated with backlight illumination from a backlight unit. The backlight unit may include a printed circuit board, a plurality of light-emitting diodes mounted on the printed circuit board, at least one light spreading layer formed over the printed circuit board that spreads light received from the plurality of light-emitting diodes, a partially reflective layer formed over the at least one light spreading layer, a color conversion layer formed over the partially reflective layer, a collimating layer formed over the color conversion layer, a brightness enhancement film formed over the collimating layer, and a diffuser formed over the brightness enhancement film. The at least one light spreading layer may include two light spreading layers with elongated protrusions that are rotated relative to each other.

Provided is a method of manufacturing a light emitting module, the method including: providing a light guiding plate having a first main surface serving as a lighting surface, and a second main surface opposite to the first main surface, the second main surface defining a recess thereon, preparing a light emitting element unit by attaching a wavelength conversion portion to a light emitting element having electrodes and a light emitting surface; providing a light diffusion portion at a bottom of the recess; depositing the light emitting element unit onto the light diffusion portion in the recess; and forming a terminal having an electrical conductivity on the electrodes of the light emitting element.

A lid for an optical element package, comprising: a window material provided in front of the light emitting direction of an optical element of a housing member, inside of which the optical element is housed; and a metal-based adhesive layer formed on a part at which the window material contacts the housing member, wherein with the lid for an optical element package, the metal-based adhesive layer is formed by an adhesive composition including metal nanoparticles, a solder powder, and a dispersion medium coated by a coating agent. It is possible to address deterioration and cracking due to light of short wavelengths, distortion or decay of the adhesive agent due to heat generation of the light emitting element, and the problem of long-term reliability accompanying these. Specifically, it is possible to provide the lid for an optical element package and the optical element package with excellent heat resistance, ultraviolet resistance, etc.

The disclosure provides a display device including red, green and blue pixel units. In the red pixel unit, a light emitting element emits a blue light that then passes through a light conversion element and a color filter and the blue light is converted into a red light while passing through the light conversion element. In the green pixel unit, a light emitting element emits a blue light that then passes through a light conversion element and a color filter and the blue light is converted into a green light while passing through the light conversion element. In the blue pixel, a light emitting element emits a blue light that then passes through a color filter. The red pixel unit has a lighting area greater than a lighting area of the blue pixel unit and less than a lighting area of the green pixel unit.

A micro-LED device of the present disclosure includes a crystal growth substrate (100) and a frontplane (200) that includes a plurality of micro-LEDs (220), each of which includes a first semiconductor layer (21) of a first conductivity type and a second semiconductor layer (22) of a second conductivity type, and a device isolation region (240). The device isolation region includes a metal plug (24) electrically coupled with the second semiconductor layer. This device includes a middle layer (300) which includes first contact electrodes (31) electrically coupled with the first semiconductor layer and a second contact electrode (32) coupled with the metal plug, a backplane (400) provided on the middle layer, a phosphor layer (600) capable of converting the blue light radiated from each of the plurality of micro-LEDs to white light, and a color filter array (620) supported by the substrate with the phosphor layer interposed therebetween, the color filter array being capable of selectively transmitting respective color components of the white light. The phosphor layer contains a scatterer capable of more strongly scattering the blue light than green light and red light.

A display apparatus includes a substrate, a light-emitting diode (“LED”) provided above the substrate, an insulating layer provided above the LED, and a wire grid polarizer (“WGP”) provided above the insulating layer.