Methods for low-temperature formation of one or more thin-film semiconductor structures on a substrate that include the steps of, forming a (poly)silane layer over a substrate, transforming one or more parts of the (poly)silane layer in one or more thin-film solid-state semiconductor structures, by exposing the one or more parts with light from an

An object of the present invention is to prevent the deterioration of a TFT (thin film transistor). The deterioration of the TFT by a BT test is prevented by forming a silicon oxide nitride film between the semiconductor layer of the TFT and a substrate, wherein the silicon oxide nitride film ranges from 0.3 to 1.6 in a ratio of the concentration of N to the concentration of Si.

In one aspect, the present invention provides a silicon photodetector having a surface layer that is doped with sulfur inclusions with an average concentration in a range of about 0.5 atom percent to about 1.5 atom percent. The surface layer forms a diode junction with an underlying portion of the substrate. A plurality of electrical contacts allow application of a reverse bias voltage to the junction in order to facilitate generation of an electrical signal, e.g., a photocurrent, in response to irradiation of the surface layer. The photodetector exhibits a responsivity greater than about 1 A/W for incident wavelengths in a range of about 250 nm to about 1050 nm, and a responsivity greater than about 0.1 A/W for longer wavelengths, e.g., up to about 3.5 microns.

To provide a crystalline oxide semiconductor film. By collision of ions with a target including a crystalline In—Ga—Zn oxide, a flat-plate-like In—Ga—Zn oxide is separated. In the flat-plate-like In—Ga—Zn oxide, a first layer including a gallium atom, a zinc atom, and an oxygen atom, a second layer including a zinc atom and an oxygen atom, a third layer including an indium atom and an oxygen atom, and a fourth layer including a gallium atom, a zinc atom, and an oxygen atom are stacked in this order. After the flat-plate-like In—Ga—Zn oxide is deposited over a substrate while maintaining the crystallinity, the second layer is gasified and exhausted.

An active matrix display device having a pixel structure in which pixel electrodes, gate wirings and source wirings are suitably arranged in the pixel portions to realize a high numerical aperture without increasing the number of masks or the number of steps. The device comprises a gate electrode and a source wiring on an insulating surface, a first insulating layer on the gate electrode and on the source wiring, a semiconductor layer on the first insulating film, a second insulating layer on the semiconductor film, a gate wiring connected to the gate electrode on the second insulating layer, a connection electrode for connecting the source wiring and the semiconductor layer together, and a pixel electrode connected to the semiconductor layer.

Process for fabricating a thin single-crystalline layer n, including steps of: a) providing a support substrate n, b) placing a seed sample n, c) depositing a thin layer n so as to form an initial interface region n including a proportion of seed sample n and a proportion of thin layer n, the proportion of seed sample n decreasing from the first peripheral part n towards the second peripheral part n, e) providing an energy input to the initial interface region n contiguous to the first peripheral part n so as to liquefy a portion n of the thin layer and form a solid/liquid interface region n, and f) gradually moving the energy input away from the seed sample n so as to solidify the portion n so as to gradually move the solid/liquid interface region n.

A laser irradiation device may include: a laser device configured to emit a pulse laser beam; beam scan optics configured to allocate the pulse laser beam emitted from the laser device to optical paths; beam homogenizers provided in the respective optical paths, each of the beam homogenizers being configured to homogenize distribution of light intensity of the pulse laser beam allocated to a corresponding optical path of the optical paths; and a controller configured to control the beam scan optics to allocate, for each pulse, the pulse laser beam emitted from the laser device to the corresponding optical path of the optical paths.

The embodiments described herein generally relate to methods for forming an amorphous silicon structure that may be used in thin film transistor devices. In embodiments disclosed herein, the amorphous silicon layer is deposited using a silicon-based gas with an activation gas comprising a high concentration of inert gas and a low concentration of hydrogen-based gas. The activation gas combination allows for a good deposition profile of the amorphous silicon layer from the edge of the shadow frame which is translated to the polycrystalline silicon layer post-annealing.

An array substrate is disclosed. The array substrate includes a substrate, a first film layer on a side surface of the substrate, an insulation layer on the side surface of the substrate, an electrostatic charge dispersion layer on the side surface of the substrate, and a second film layer arranged on the side surface of the substrate. The first film layer, the insulation layer, the electrostatic charge dispersion layer, and the second film layer are sequentially arranged on the substrate. In addition, the insulation layer and the electrostatic charge dispersion layer include via holes, the second film layer is electrically connected with the first film layer through the via holes, and the electrostatic charge dispersion layer is in a same profile as the second film layer.

The present invention discloses a manufacturing method to reduce the surface roughness of the low temperature poly-silicon, including: a surface pretreatment is performed to a substrate with a a-Si layer on it, to form an oxidation layer on the a-Si layer. A first excimer laser annealing is performed on the substrate to make the a-Si layer into a poly-silicon layer; an acid liquid clean is used on the poly-silicon layer to remove the protrusions on the poly-silicon layer; a second excimer laser annealing is performed to the poly-silicon layer to obtain a low temperature poly-silicon layer with lower surface roughness. The manufacturing method is easy to operation and reduce the surface roughness of the low temperature poly-silicon layer with efficiency to obtain a low temperature poly-silicon layer with low roughness, uniform surface and well crystallization. A low temperature poly-silicon layer formed according to the present invention is also provided.