A touch panel, a method for fabricating the same, and a display device are provided. The touch panel includes: a base substrate, a plurality of touch electrode lines, a plurality of cathodes arranged in a matrix, and a plurality of spacers, where each cathode corresponds to at least one of the touch electrode lines, and each spacer includes a first photo spacer and a second photo spacer stacked successively; each touch electrode line includes a first lead part and a second lead part, wherein the first lead part is electrically connected with corresponding one of the cathodes, and the second lead part is configured to electrically connect the first lead part with a corresponding pin on a touch integrated circuit; and the first lead part at least covers the surface of the first photo spacer.

Disclosed are a double-face display panel and a double-face display device. The double-face display panel comprises a plurality of pixel units arranged in an array, each of the pixel units including a thin film transistor, a front display pixel and a rear display pixel; the front display pixel comprises a first anode, a first light emitting layer and a first cathode; the rear display pixel comprises a second anode, a second light emitting layer and a second cathode; and the first anode and the second anode are electrically connected to a drain of the thin film transistor, respectively. Thereby, the present application can effectively reduce the number of wirings in the manufacturing process of the panel, and thus can reduce the impact on the pixel density due to the excessive number of wirings.

An organic EL device includes a substrate, a reflection electrode, an organic compound layer and a light extraction electrode in this order. The organic compound layer includes a first light-emitting layer which is electron trapping type light-emitting layer and a second light-emitting layer disposed between the reflection electrode and the first light-emitting layer. An optical distance between the reflection electrode and the first light-emitting layer is a distance of constructive interference for the light of the first light-emitting layer.

A light emitting display device includes: a substrate; an organic film on the substrate; a green light emitting diode on the organic film and including a first anode; a red light emitting diode on the organic film and including a second anode; a black pixel defining film having an opening exposing the first anode and an opening exposing the second anode; a cathode on the black pixel defining film, the first anode, and the second anode; an encapsulation layer covering the cathode; a light blocking member on the encapsulation layer and having an opening; and a color filter filling the opening in the light blocking member. A portion of the organic film overlapping the first anode in a plan view has a halftone exposure area, and a step of the halftone exposure area is 30 nm or less.

A display panel includes a pixel defining film which is disposed on a base layer and in which a light-emitting opening is defined, a partitioning wall which is disposed on the pixel defining film and in which a partitioning wall opening corresponding to the light-emitting opening is defined, and a light-emitting element including an anode, a middle layer, and a cathode which contacts the partitioning wall. The light-emitting element is disposed in the partitioning wall opening. The partitioning wall includes a first partitioning wall layer disposed on the pixel defining film and defining a portion of a first area of the partitioning wall opening, a second partitioning wall layer disposed on the first partitioning wall layer and defining a portion of a second area of the partitioning wall opening. A width of the first area is different from a width of the second area.

A method for manufacturing a display panel including a substrate and a light emitting functional layer on the substrate comprises the following steps: forming a conductive wire on the substrate; forming a semiconductor layer on the conductive wire; forming a conductive channel in the semiconductor layer, the conductive channel connects to the conductive wire; and forming a first electrode layer on the semiconductor layer and the light emitting functional layer, wherein the first electrode layer connects with the conductive channel. The present disclosure can reduce a length of a wiring trace between the electrode layer and the conductive wire, and avoid a touch blind region on the display panel caused by the excessively large wiring trace region.

The present disclosure relates to a OLED display panel and the manufacturing method thereof. The OLED display panel includes a carrier substrate, a flexible substrate formed on the carrier substrate, a TFT layer formed on the flexible substrate, an organic emission layer formed on the TFT layer, and a cathode formed on the TFT layer and the organic emission layer. The flexible substrate is configured with at least one first groove exterior to a border of the cathode, and the TFT layer is configured with at least one second groove corresponding to the first groove. The second groove is configured to collect particles generated when the cathode is applied with an evaporation process. In this way, the packaging reliability may be enhanced.

A pixel structure of an organic light emitting diode (OLED) display panel and a manufacturing method thereof are disclosed. The pixel structure comprises a pixel region, anode conductive layers, pixel units, and a cathode conductive layer. The pixel region comprises sub-pixel regions arranged in sequence, at least two adjacent sub-pixel regions defined as a sub-pixel region group are disposed integrally. The anode conductive layers are disposed in the sub-pixel regions respectively, and separated from each other. The cathode conductive layer is electrically connected with the anode conductive layers to control the pixel units. Each of the pixel units comprises sub-pixels and is disposed in the pixel region. Each of the sub-pixels is disposed in one of the sub-pixel regions. The sub-pixels are formed integrally and have a same color in the sub-pixel region group. The pixel unit comprises a hole injection layer, a luminous layer and an electron injection layer.

A light-emitting device includes an emissive layer that emits light by recombination of first charges and second charges; a first electrode from which the first charges are supplied; a second electrode from which the second charges are supplied; a first charge transport layer that injects the first charges from the first electrode into the emissive layer; and a second charge transport layer that injects the second charges from the second electrode into the emissive layer. At least one of the charge transport layers is an absorbing charge transport layer that includes a light absorbing material that absorbs light within a portion of the emission spectrum of the light emitted by the emissive layer. The absorbing charge transport layer may be an ETL or an HTL, and may be located only between the first electrode and the emissive layer, only between the opposing second electrode and the emissive layer, or between both electrodes and the emissive layer.

The disclosure provides an all-solution OLED device and a manufacturing method thereof. The manufacturing method fabricate a hole injection layer, a hole transport layer, a light emitting layer, an electron transport layer, and a cathode by solution film-forming. Compared with the manufacturing method of the existing OLED device, an all-solution fabrication of the electron transport layer and the cathode is achieved, the use of high vacuum evaporation process and equipment can be avoided, thereby saving materials and reducing manufacturing costs; and the adjacent layers will not appear mutual solubility, so the film quality is high and the device performance can be improved. The hole injection layer, the hole transport layer, the light emitting layer, the electron transport layer, and the cathode are all fabricated by solution film-forming; and compared with the existing OLED device, the manufacturing cost is low, the film-forming quality is high, and the display quality is excellent.