A display device including a color filter is provided. The display device may include at least one color conversion pattern realizing a color same as the color filter. The color conversion pattern may be surrounded by the color filter. Thus, in the display device according to the embodiment of the present disclosure, the color gamut may be improved without increasing the overall thickness of the display device.

A method of manufacturing a flexible display device, includes forming a base layer on a non-flexible substrate, the base layer including a first resin layer, an inorganic film, and a second resin layer, wherein the forming of the base layer includes a first step of forming the first resin layer inward from an end portion region of the non-flexible substrate, a second step of forming the inorganic film on the first resin layer such that the non-flexible substrate and/or the first resin layer is exposed, and a third step of forming the second resin layer in contact with the non-flexible substrate exposed from the inorganic film and/or the first resin layer exposed from the inorganic film, and the method further includes peeling the non-flexible substrate and bonding a flexible substrate to the first resin layer via an adhesive layer.

A package structure includes a substrate and a package plate. A frame is formed of a seal glue arranged between the substrate and the package plate. An underfill is positioned inboard of the frame. The package plate has a spreading surface, and at least one groove is formed in a spreading path of the frame on the spreading surface of the package plate.

An organic EL element includes a pixel electrode, a light emitting function layer that is formed on the pixel electrode, an electron injection layer formed on the light emitting function layer, and a counter electrode that is formed on the electron injection layer and that has semi-transmissive reflectivity, in which the counter electrode contains a reductive material that reduces material of the electron injection layer and Ag with atomic ratio of 75% or more, and an adsorption layer is formed on the counter electrode.

A display panel includes a EL panel part, a CF panel part, and a resin layer. Light is extracted from a luminous part including an organic luminous layer in the EL panel part in a direction of an arrow. The resin layer is formed to cover an upper surface of the EL panel part. Transmittance of the light from the EL panel part is 80% or higher. The resin layer includes a resin part and a plurality of particles dispersed in the resin part. The particles are formed of synthetic zeolite having a refractive-index ratio to the resin part of 1.0 or more and a particle size of 2 μm or more.

The present invention relates to a current-light conversion device (1), such as an OLED or an OPVD, wherein the current-light conversion device comprises a substrate (10), a current-light conversion arrangement (11) comprising a current-light conversion material (111) provided between a first and a second electrode layer (110, 112), and a barrier layer (12) comprising a transparent organic layer (121) provided between a first and a second transparent inorganic barrier layer (120, 122). A getter material is provided in the transparent organic layer (121) in a pattern of getter dots (1210). Since the getter material is provided in a pattern of getter dots (1210), the light scattering effect resulting from dispersed getter particles can be avoided, resulting in improved transparency characteristics of the barrier layer (12) while still providing the desired getter functionality.

A display panel includes an EL panel part, a CP panel part, and a resin layer. Light is extracted from a luminous part including an organic luminous layer in the EL panel part in a direction of an arrow. The CP panel part includes a circular polarizing film. The resin layer is formed to cover an upper surface of the EL panel part, has a layer thickness of 15 μm, and includes a resin part and a plurality of getter particles dispersed in the resin part. The getter particles are dispersed at a density at which the getter particles do not overlap one another in plan view.

A method of fabricating a display panel having a display area and a component installation area substantially surrounded by the display area. The method includes forming one or more organic layers on a base substrate in both the display area and the component installation area; removing the one or more organic layers in at least a first region of the component installation area; forming an encapsulating material layer in at least the first region of the component installation area; and curing the encapsulating material layer.

The present invention provides an organic light emitting diode display panel and a fabricating method thereof. The organic light emitting diode display panel includes a lower substrate, having one side extending to form a signal path; an upper cover plate on the lower substrate, wherein a lower surface of the upper cover plate is connected to an upper surface of the lower substrate; and a barrier film package bag enclosing the upper cover plate and the lower substrate from a side away from the signal channel. The method of fabricating the OLED display panel includes following steps: forming a lower substrate; forming an upper cover plate; bonding the upper cover plate to the lower substrate; and packaging the display panel to be packaged by vacuum thermocompression. The present invention simplifies the packaging of the OLED display panel and can meet the package requirements of various types of OLED display panels.

Provided is a display device including a substrate having a first region and a second region adjacent to the first region. The second region is located in a direction from the first region to an outside of the substrate. The first region possesses a transistor, a leveling film over the transistor, and a light-emitting element over the leveling film and electrically connected to the transistor. The display device further includes a plurality of metal films in the second region and a sealing film. The plurality of metal films includes at least one of Group 1 metal elements and Group 2 elements, and the leveling film is arranged so as to be confined in the first region.