Disclosed relates to a transparent display panel and manufacturing method of thereof, and the transparent display panel including a patterned cathode with improved transparency as a whole.

A method for fabricating an array substrate, comprising: providing a base substrate; forming a driving-circuit layer, which comprises first driving circuits and second driving circuits; forming a first electrode layer, which comprises transferring electrodes electrically connected to the first driving circuits, and pixel electrodes electrically connected to the second driving-circuits; forming a pixel-defining layer, which is provided with pixel openings and connecting via holes; forming a first pattern-defining layer, which covers the connecting via holes and exposes the pixel openings; forming an organic light-emitting-material layer, which covers the pixel openings and the first pattern-defining layer; removing the first pattern-defining layer, such that the organic light-emitting-material layer forms an organic light-emitting layer; forming a second pattern-defining layer surrounding the connecting via holes; and forming a second electrode layer, which comprises a common electrode and fingerprint-recognition electrodes isolated by the second pattern-defining layer.

An organic device may include a substrate, first electrodes located on top of the substrate, organic layers located on top of the first electrodes, and a second electrode located on top of the organic layers. When seen along a direction normal to the substrate, the organic device may include a display area including a first display area and a second display area. The first display area may include the organic layers distributed at a first density. The second display area may include the organic layers distributed at a second density that is lower than the first density. The second electrode may include a wide-area electrode spreading in a gapless manner in the first display area and two or more electrode lines overlapping the organic layers in the second display area. Each of the electrode lines includes an end connected to the wide-area electrode.

A method of manufacturing a display panel includes providing a base substrate and forming a plurality of anodes above the base substrate; forming a photoresist layer above a side of the base substrate above which the plurality of anodes are formed, the photoresist layer including a plurality of openings and each opening corresponding to at least one anode; and forming a plurality of light emitting layers and a cathode layer sequentially above a side of the base substrate above which the plurality of anodes and the photoresist layer are formed, the cathode layer including a plurality of cathode films and each cathode film corresponding to a single opening.

A mask group may include two or more masks. When a section in a normal direction is viewed, a region-defining straight line may be defined as a straight line that forms an angle θ together with a first surface. The region-defining straight line may intersect the first surface at a first intersection point. An effective region may be defined as a region inside the first intersection point in the through-hole, and a peripheral region may be defined as a region outside the first intersection point in the through-hole. The angle θ may be 35° or more and 70° or less. The penetration region in the second mask region may include a hole overlapping region in which the through-holes of two masks overlap. The hole overlapping region may include a first hole overlapping region in which the peripheral regions of the through-holes of the two masks overlap.

An ultra-thin shadow mask comprises a plastic foil including a plurality of apertures, wherein the ultra-thin shadow mask is less than 25 μm thick, and wherein the ultra-thin shadow mask has a feature size of at least 1 μm to about 100 μm. An organic photovoltaic (OPV) device comprises a first electrode including a first grid structure, the first grid structure having a feature size of at least 1 μm to about 100 μm, a heterojunction under the first electrode, a second electrode under the heterojunction including a second grid structure, and a plurality of outcoupling layers over the first electrode. Related methods are also disclosed.

A display device including a substrate having a display area and a peripheral area defined outside the display area, a circuit layer disposed on the substrate, a device layer disposed on the display area, an encapsulation layer covering the device layer, a touch sensing unit including at least one touch insulating layer disposed on the encapsulation layer, touch electrodes disposed on the encapsulation layer, and touch signal lines connected to the touch electrodes, a first section disposed in the peripheral area and including a first part having a first thickness, a second part having a second thickness less than the first thickness and overlapping the touch signal lines, and an intermediate part connecting the first part and the second part and being inclined, and a first thickening pattern overlapping at least the intermediate part.

The present invention discloses an auxiliary electrode transfer structure and a manufacturing method for a display panel. The auxiliary electrode transfer structure includes a transparent base layer; a light-to-heat transformation layer disposed above the transparent base layer; and an auxiliary electrode disposed above the light-to-heat transformation layer; a laser mechanism configured to form laser, wherein the laser penetrates the transparent base layer to the light-to-heat transformation layer.

Provided are a display panel, a preparation method thereof and a display device. The display panel includes a light-emitting substrate and a color filter substrate; the color filter substrate includes: a substrate, a baffle wall layer and a reflective metal layer. The baffle wall layer is located on one side of the substrate and includes multiple baffle wall structures; the reflective metal layer includes a first reflective subsection covering a surface on a side, close to the light-emitting substrate, of the multiple baffle wall structures; the first reflective subsection includes multiple first metal subsections and multiple second metal subsections; and the multiple first metal subsections are independently disposed, and adjacent ones of the multiple second metal subsections along the first direction are connected to each other.

A method for manufacturing a transistor being a bottom-gate transistor is provided. The method for manufacturing a transistor includes a step of forming a first metal layer 32 on an insulator layer 20 provided on a substrate 10 including a gate electrode, a step of applying a resist onto the first metal layer 32, and patterning the first metal layer 32 by a photolithographic method, an oxide film removal step of removing an oxide film 26 formed on the patterned first metal layer 32, and a step of forming a source electrode and a drain electrode by forming a second metal layer 42 on the first metal layer 32.