An array substrate includes a substrate and data lines and scan lines arranged on the substrate. The data lines and the scan lines define plural pixel regions. A thin film transistor is arranged in each pixel region and includes a gate electrode, a source electrode, a drain electrode, and an active region. The gate electrode is arranged above the active region. The source electrode and the drain electrode are arranged at two opposite sides of the active region respectively. A light shielding metal layer is further arranged in each pixel region. The light shielding metal layer and the data lines are arranged in the same layer on the substrate. The light shielding metal layer is arranged under the active region and at least partially overlaps with the active region. The data line is close to the source electrode and does not overlap with the active region at least partially.

The disclosure provides a manufacturing method and a structure thereof of a TFT backplane. In the manufacturing method of the TFT backplane, after a polysilicon layer (3) is formed by implanting a induced ion solid-phase crystallization into an amorphous silicon layer (3), patterning the polysilicon layer using a half-tone mask to form an island active layer (4), and at the same time, etching a upper layer portion (31) with more implanted induced ions located in the middle portion of the island active layer (4) to form a channel region, retaining the upper layer portion (31) with more implanted induced ions located in two sides of the island active layer (4) to form a source/drain contact region, it not only reduces the number of masks, but also saves a process only for implanting doped ion into the source/drain contact region, thereby simplifying the process and reducing production cost.

When a transistor having bottom gate bottom contact structure is manufactured, for example, a conductive layer constituting a source and a drain has a three-layer structure and two-step etching is performed. In the first etching process, an etching method in which the etching rates for at least the second film and the third film are high is employed, and the first etching process is performed until at least the first film is exposed. In the second etching process, an etching method in which the etching rate for the first film is higher than that in the first etching process and the etching rate for a layer provided below and in contact with the first film is lower than that in the first etching process is employed. The side wall of the second film is slightly etched when a resist mask is removed after the second etching process.

The present invention provides a TFT substrate structure and a manufacturing method thereof. In the manufacturing method of a TFT substrate structure according to present invention, a graphene layer is formed on a semiconductor layer and after the formation of a second metal layer, the second metal layer is used as a shielding mask to conduct injection of fluoride ions into the graphene layer to form a modified area in a portion of the graphene layer that is located on and corresponds to a channel zone of the semiconductor layer, wherein the modified area of the graphene layer shows a property of electrical insulation and a property of blocking moisture/oxygen so as to provide protection to the channel zone; portions of the graphene layer that are located under source and drain electrodes are not doped with ions and preserves the excellent electrical conduction property of graphene and thus electrical connection between the source and drain electrodes and the semiconductor layer can be achieved without formation of a via in the graphene layer, making a TFT device so manufactured showing excellent I-V (current-voltage) output characteristics and stability, saving one mask operation process, shortening the manufacturing time, and lowering down the manufacturing cost.

The present invention provides an array substrate and a manufacturing method thereof. The manufacturing method of the array substrate according to the present invention forms a gate electrode in the same metal layer with source and drain electrodes and divides a common electrode layer that is conventionally in the form of an entire surface into two portions, of which one serves as a common electrode, while the other portion feeds an input of a gate scan signal thereby eliminating an operation of forming an interlayer insulation layer and thus reducing manufacturing cost of the operation. The array substrate of the present invention comprises a gate electrode that is formed in the same metal layer with source and drain electrodes so that no interlayer insulation layer is present between the gate electrode and the source and drain electrodes, thereby simplifying the structure and reducing the manufacturing cost of the array substrate.

A COA substrate manufacturing method including: forming a TFT on a base substrate; forming a second insulation layer on the TFT; forming a color resist layer on the second insulation layer; forming a third insulation layer on the color resist layer; forming a through hole which reveals the drain electrode of the TFT; forming an ITO film layer on the third insulation layer; forming a photoresist layer on the ITO film layer; performing a light-shielding process to the photoresist layer on the vias-region ITO film layer and an exposure process to the photoresist layer on the non vias-region ITO film layer; developing the photoresist layer on the vias-region ITO and the non vias-region ITO film layers to obtain a photoresist layer plug covered on the vias-region ITO film layer. The present invention utilizes the photoresist to fill the through hole which can improve the quality of a display device.

A transistor device comprising: source and drain conductors connected by a semiconductor channel provided by a layer of semiconductor material formed over the source and drain conductors; and a gate conductor capacitively coupled to the semiconductor channel via a gate dielectric; wherein at least one of the source and drain conductors comprises a multilayer structure in at least one region thereof, the multilayer structure comprising a lower layer and an upper layer, the material of the lower layer being better than the material of the upper layer at injecting charge into the semiconductor material; and the material of the upper layer exhibiting better electrical conductivity than the material of the lower layer.

A reduction in contaminating impurities in a TFT, and a TFT which is reliable, is obtained in a semiconductor device which uses the TFT. By removing contaminating impurities residing in a film interface of the TFT using a solution containing fluorine, a reliable TFT can be obtained.

The present disclosure provides an array substrate, a method for manufacturing the same and a display device. The array substrate includes a plurality of signal lines and a connection line electrically connected to the plurality of signal lines. During the formation of each insulation layer on the connection line, a via-hole is formed at a position where the connection line is to be interrupted. In addition, the protection layer is provided to cover the portion of the connection line corresponding to the region where the via-hole is located, so as to protect the connection line. Upon the completion of the insulation layers, the connection line may be interrupted through the via-holes, so as to interrupt electrical connection among the signal lines.

A dual-gate TFT array substrate and manufacturing method thereof and a display device are provided. The manufacturing method includes: forming a common electrode and a top-gate electrode through one patterning process. The manufacturing method reduces the times of patterning process and simplifies the process flow.