A semiconductor device (100) includes: a substrate (11); a first thin film transistor (10A) supported on the substrate (11), the first thin film transistor (10A) having a first active region (13c) which mainly contains a crystalline silicon; and a second thin film transistor (10B) being supported on the substrate (11), the second thin film transistor (10B) having a second active region (17c) which mainly contains an oxide semiconductor having a crystalline portion.

A semiconductor device may include a base substrate, a first thin-film transistor (TFT) provided on the base substrate, a second TFT provided on the base substrate, and a plurality of insulating layers provided on the base substrate to define at least one dummy hole that is not overlapped with the first and second TFTs. The first TFT may include a first input electrode, a first output electrode, a first control electrode, and a first semiconductor pattern including a crystalline semiconductor material, and the second TFT may include a second input electrode, a second output electrode, a second control electrode, and a second semiconductor pattern including an oxide semiconductor material. A shortest distance between the at least one dummy hole and the second semiconductor pattern may be equal to or shorter than 5 micrometers (?m), in a plan view.

A semiconductor device, comprising a base substrate, a buffer layer and a polysilicon layer film, wherein the base substrate, the buffer layer and the polysilicon layer film being laminated sequentially, and wherein regularly arranged first grooves being provided on a surface of the buffer layer contacting the polysilicon film; the polysilicon film being formed, by applying crystallization treatment, through an optical annealing process, to an amorphous silicon film on the buffer layer having regularly arranged first grooves.

The present disclosure relates to a low temperature poly-silicon thin film transistor and a method of preparing the same. The low temperature poly-silicon thin film transistor includes a substrate, a metal induction layer formed on the substrate, a barrier layer formed on the metal induction layer, and an amorphous silicon film layer formed on the barrier layer, the amorphous silicon film layer being converted into a poly-silicon film layer under the inducing effect of the metal induction layer, and the poly-silicon film layer being an active layer. In the present disclosure, although the active layer is obtained by using the metal induction method, the metal induction layer is provided below the amorphous silicon film layer, and a barrier layer is provided between the metal induction layer and the amorphous silicon film layer.

It is an object of the invention to provide a technique to manufacture a display device with high image quality and high reliability at low cost with high yield. The invention has spacers over a pixel electrode layer in a pixel region and over an insulating layer functioning as a partition which covers the periphery of the pixel electrode layer. When forming a light emitting material over a pixel electrode layer, a mask for selective formation is supported by the spacers, thereby preventing the mask from contacting the pixel electrode layer due to a twist and deflection thereof. Accordingly, such damage as a crack by the mask does not occur in the pixel electrode layer. Thus, the pixel electrode layer does not have a defect in shapes, thereby a display device which performs a high resolution display with high reliability can be manufactured.

Disclosed are a thin film transistor and a method for fabricating the same, where annealing can be performed on a base substrate formed with a metal inductive layer to thereby perform metal induced crystallization so as to fabricate the bottom-gate low-temperature poly-silicon thin film transistor while dispensing with a shielding layer in a top-gate thin film transistor. Furthermore an amorphous-silicon layer can be converted into a poly-silicon layer due to metal induced crystallization, and the patterning process can be further performed on the poly-silicon layer to form a first doped zone corresponding to an active layer, and a second doped zone corresponding to a source and drain area, so that a channel area can be separated from the source and drain area to thereby guarantee the electrical performance of the thin film transistor.

A method for manufacturing a TFT substrate is disclosed. The TFT substrate includes a drive TFT region and a display TFT region. The drive TFT region and the display TFT region are manufactured with different technologies, so that different requirements for TFT can be met. The manufacturing method according to the present disclosure mainly includes: forming a first amorphous silicon layer to obtain a drive TFT region; forming a second amorphous silicon layer to obtain a display TFT region; and then depositing a passivation layer and a flat layer, so that the TFT substrate is manufactured after following treatment steps.

It is an object of the invention to provide a technique to manufacture a display device with high image quality and high reliability at low cost with high yield. The invention has spacers over a pixel electrode layer in a pixel region and over an insulating layer functioning as a partition which covers the periphery of the pixel electrode layer. When forming a light emitting material over a pixel electrode layer, a mask for selective formation is supported by the spacers, thereby preventing the mask from contacting the pixel electrode layer due to a twist and deflection thereof. Accordingly, such damage as a crack by the mask does not occur in the pixel electrode layer. Thus, the pixel electrode layer does not have a defect in shapes, thereby a display device which performs a high resolution display with high reliability can be manufactured.

A laser polycrystallization apparatus including: a light source for emitting a laser beam; a diffraction grating for receiving the laser beam from the light source, changing a path and a magnitude of the received laser beam, and outputting the changed laser beam; a light split portion for splitting the laser beam received from the diffraction grating; and a light superposition portion for superposing the split laser beams received from the light split portion and irradiating the superposed split laser beams to a substrate. An angle between the laser beam irradiated to an incidence surface of the diffraction grating from the light source and a line substantially perpendicular to an emission surface of the diffraction grating is an acute angle.

A semiconductor device (100) includes: a substrate (11); a first thin film transistor (10A) supported on the substrate (11), the first thin film transistor (10A) having a first active region (13c) which mainly contains a crystalline silicon; and a second thin film transistor (10B) being supported on the substrate (11), the second thin film transistor (10B) having a second active region (17c) which mainly contains an oxide semiconductor having a crystalline portion.