A 3D display apparatus in which a display panel has a curvature is provided. A lower barrier layer, an upper barrier layer and lenticular lenses may be sequentially stacked on the display panel. The lower barrier layer and the upper barrier layer may include openings corresponding pixel areas of the display panel, respectively. Each opening of the lower barrier layer and each opening of the upper barrier layer may be disposed on an imaginary line passing through the corresponding pixel area of the display panel and a setting region. Thus, in the 3D display apparatus, the quality of the realized 3D image may be improved.

A 3D display apparatus in which a display panel has a curvature is provided. A lower barrier layer, an upper barrier layer and lenticular lenses may be sequentially stacked on the display panel. The lower barrier layer and the upper barrier layer may include openings corresponding pixel areas of the display panel, respectively. Each opening of the lower barrier layer and each opening of the upper barrier layer may be disposed on an imaginary line passing through the corresponding pixel area of the display panel and a setting region. Thus, in the 3D display apparatus, the quality of the realized 3D image may be improved.

A display panel and a method of manufacturing thereof are provided. A hole injection layer, a hole transport layer, a light emitting layer, and a planarization layer are formed by an inkjet-printing method. Specifically, solvents including hole injecting layer material, hole transporting layer material, light emitting layer material, and planarization layer material are evaporated by vacuum drying so as to uniformize the surface of the entire layer, thereby improving light uniformity. Moreover, a notch of the light emitting layer can be effectively filled by disposing a planarization layer on the light emitting layer, so a uniform layer can be formed, which can reduce the current accumulated at the notch. Therefore, the light uniformity of the display panel is improved, and the risk of leakage current at the notch is also reduced.

An encapsulation structure, an encapsulation method, an electroluminescent device, and display equipment, which relate to the technical field of displays. The encapsulation structure comprises: a first inorganic dielectric layer (1), wherein the first inorganic dielectric layer (1) has a surface attached to a surface of a cathode layer (4) of an electroluminescent device; a chromatic dispersion relationship between the first inorganic dielectric layer (1), the cathode layer (4) and an electron injection layer (5) of the electroluminescent device meets a preset condition; the preset condition is used for defining an optical parameter of a first interface, the optical parameter is related to chromatic dispersion, and the optical parameter is used for coupling surface plasmon polaritons on interfaces on both sides of the cathode layer (4); and the first interface is an interface between the first inorganic dielectric layer (1) and the cathode layer (4).

A flexible display panel and a display device are disclosed. An opening hole is defined in a corner splicing section of the flexible display panel and is filled with a splicing element formed by filling a light guide material, and a light guide layer is disposed on one side of a display surface of the flexible display panel at a same time. Therefore, the flexible display panel and the display device of the present disclosure can prevent wrinkle phenomena and realize normal light emission in the corner splicing section.

The present application provides a display panel and a manufacturing method thereof. The display panel includes a pixel defining layer, a light-emitting layer, an encapsulation layer, and a color filter functional layer. The pixel defining layer is provided with a first surface and a second surface opposite to each other, and a groove. The light-emitting layer is disposed in the groove. The encapsulation layer is disposed on the first surface of the pixel defining layer and extends to cover the light-emitting layer. The color filter functional layer is disposed in the encapsulation layer and corresponds to the groove.

Provided are a liquid crystal composition that is capable of forming a light absorption anisotropic film having a low reflectance, and a light absorption anisotropic film, a laminate, and an image display device, each of which is obtained using the liquid crystal composition. The liquid crystal composition contains a side-chain type high-molecular-weight liquid crystalline compound and a dichroic substance, in which the side-chain type high-molecular-weight liquid crystalline compound is a copolymer having a repeating unit M including a mesogenic group and a repeating unit F including a fluorine atom.

A light-emitting device includes a metal reflection layer having a phase modulation surface, a color conversion layer provided on the phase modulation surface of the metal reflection layer, a first electrode provided on the color conversion layer, a hole injection and transport layer provided on the first electrode, a blue organic light-emitting layer provided on the hole injection and transport layer, an electron injection and transport layer provided on the blue organic light-emitting layer, and a second electrode provided on the electron injection and transport layer. The phase modulation surface of the metal reflection layer generates magnetic resonance with respect to incident light. The color conversion layer includes a photoluminescent material.

A display apparatus capable of performing image capturing with high sensitivity is provided. The display apparatus includes a light-emitting element including a light-emitting layer, and a light-receiving element including a photoelectric conversion layer. A transflective electrode is provided over the light-emitting layer, and a transparent electrode is provided over the photoelectric conversion layer. With a structure where the transflective electrode does not overlap the photoelectric conversion layer, a reduction in light-receiving sensitivity of the light-receiving element can be prevented while a microcavity structure is used for the light-emitting element. Thus, the display apparatus can emit light with high color purity and perform image capturing with high sensitivity.

The present invention provides a display panel and a manufacturing method thereof. The display panel includes a glass substrate and a one-dimensional photonic crystal layer disposed on the glass substrate. The one-dimensional photonic crystal layer includes a plurality of crystal unit layers stacked upon each other. Each of the plurality of crystal unit layers includes a low-refractive-index sublayer disposed on a side of each of the plurality of crystal unit layers near the glass substrate and a high-refractive-index sublayer disposed on a side of each of the plurality of crystal unit layers away from the glass substrate.