An organic light-emitting diode (OLED) structure includes a stack of OLED layers; a light extraction layer (LEL) comprising a UV-cured ink; and a UV blocking layer between the LEL and the stack of OLED layers.

An organic light-emitting diode (OLED) structure includes a stack of OLED layers that includes a light emission zone having a planar portion, and a light extraction layer formed of a UV-cured ink disposed over the light emission zone of the stack of OLED layers. The light extraction layer has a gradient in index of refraction along an axis normal to the planar portion.

A display panel includes a first pixel area and a second pixel area. A division partition wall includes an opening corresponding to at least the first pixel area. A light conversion pattern for changing the color of source light is disposed inside the opening. An optical pattern is arranged to correspond to the second pixel area. The optical pattern transmits the source light therethrough. The optical pattern may have a shape integrally formed with or different from the division partition wall.

Embodiments of the disclosed subject matter provide a device that may include an organic light emitting device (OLED) having a substrate, a first electrode disposed over the substrate, a second electrode disposed over the first electrode, and an organic emissive layer having a first surface positioned over a second surface is disposed between the first electrode and the second electrode. A nanoparticle layer may be disposed over the organic emissive layer and has a first surface that is positioned over a second surface. The nanoparticle layer may include a first plurality of nanoparticles comprising a dielectric material, and a surrounding medium. A distance from the second surface of the nanoparticle layer to the first surface of the organic emissive layer may be not more than 50 nm, and there may be a difference of at least 1.0 between a refractive index of the dielectric material and the surrounding medium.

The present disclosure provides a display device that include: a display panel that includes a display area and a peripheral area that is provided at the periphery of an edge of the display area; a window that is provided on one side of the display panel to protect the display panel; and an adhesive film that is provided between the display panel and the window to bond the display panel and the window to each other, wherein the adhesive film in an area that corresponds to the peripheral area and the adhesive film in an area that corresponds to the display area have different properties.

A display screen includes: a flexible display panel, and a flexible protective layer covering a light-emitting surface of the flexible display panel, wherein a side surface of the flexible protective layer facing away from the flexible display panel is a light-emitting side surface, and an anti-reflection structure is disposed on the light-emitting side surface. An unevenness feel on a surface of the display screen can be reduced, thereby improving performance of a foldable product such as a foldable terminal.

A display screen includes: a flexible display panel, and a flexible protective layer covering a light-emitting surface of the flexible display panel, wherein a side surface of the flexible protective layer facing away from the flexible display panel is a light-emitting side surface, and an anti-reflection structure is disposed on the light-emitting side surface. An unevenness feel on a surface of the display screen can be reduced, thereby improving performance of a foldable product such as a foldable terminal.

A quantum dot organic light emitting diode (OLED) display panel is disclosed. A red-and-blue mixture light source is used as an OLED light source corresponding to a red sub-color-resist of a color filter, and/or a green-and-blue mixture light source is used as the OLED light source corresponding to a green sub-color-resist of the color filter. A blue light source in a color-mixture light source can trigger a red/green quantum dot material of a quantum dot photo-transfer film, and the triggered light passes through the color filter. A red/green light source in the color-mixture light source can directly pass through the color filter, thereby effectively improving the brightness of the quantum dot OLED display panel and the efficiency of a display panel and prolonging the lifetime of the display panel.

A quantum dot organic light emitting diode (OLED) display panel is disclosed. A red-and-blue mixture light source is used as an OLED light source corresponding to a red sub-color-resist of a color filter, and/or a green-and-blue mixture light source is used as the OLED light source corresponding to a green sub-color-resist of the color filter. A blue light source in a color-mixture light source can trigger a red/green quantum dot material of a quantum dot photo-transfer film, and the triggered light passes through the color filter. A red/green light source in the color-mixture light source can directly pass through the color filter, thereby effectively improving the brightness of the quantum dot OLED display panel and the efficiency of a display panel and prolonging the lifetime of the display panel.

A display device includes a scan driver which includes a first stage including a first output terminal connected to a first carry line, a second output terminal connected to a first scan line, and a third output terminal connected to a first sensing line, and a second stage including a first input terminal connected to the first carry line, a fourth output terminal connected to a second scan line, and a fifth output terminal connected to a second sensing line. In a sensing period, signals having a turn-on level are respectively output from the first output terminal, the second output terminal, and the third output terminal during a predetermined delay period before signals having a turn-on level are respectively output from the fourth output terminal and the fifth output terminal.