According to one embodiment, a liquid crystal display device includes a first scanning line, a third scanning line, a second scanning line, a first linear electrode, a second linear electrode and a third linear electrode. The first linear electrode is located between the first scanning line and the second scanning line, and extends in a third direction. The second linear electrode is located between the first scanning line and the second scanning line, and extends in a fourth direction. The third linear electrode is located between the second scanning line and the third scanning line, and comprises a portion extending in the fourth direction. The second linear electrode is electrically connected to the third linear electrode.

A thin film transistor, its manufacturing method, and a display device are provided. The method comprises: forming a gate metal layer (35), forming a step-like gate structure (352) by one patterning process; performing a first ion implantation procedure to forming a first heavily doped area (39a) and a second heavily doped area (39b), the first heavily doped area (39a) being separated apart from the second heavily doped area (39b) by a first length; forming a gate electrode (353) from the step-like gate structure (352); performing a second ion implantation procedure to form a first lightly doped area (38a) and a second lightly doped area (38b), the first lightly doped area (38a) being separated apart from the second lightly doped area (38b) by a second length less than the first length. By the above method, the process for manufacturing the LTPS TFT having the lightly doped source/drain structure can be simplified.

The present invention provides a thin film transistor and a method of fabricating the same, an array substrate and a method of fabricating the same, and a display device. The thin film transistor comprises a gate, a source, a drain, a gate insulation layer, an active layer, a passivation layer, a first electrode connection line and a second electrode connection line. The gate, the source and the drain are provided in the same layer and comprise the same material. The gate insulation layer is provided above the gate, the active layer is provided above the gate insulation layer, and a pattern of the gate insulation layer, a pattern of the gate and a pattern of the active layer coincide with each other. The passivation layer covers the source, the drain and the active layer, and the passivation layer has a first via hole corresponding to a position of the source, a second via hole corresponding to a position of the drain, and a third via hole and a fourth via hole corresponding to a position of the active layer provided therein. The first electrode connection line connects the source with the active layer through the first via hole and the third via hole, and the second electrode connection line connects the drain with the active layer through the second via hole and the fourth via hole.

An electro-optical device includes a translucent substrate, a transistor, a light-shielding body having light-shielding properties, including a metal and disposed between the substrate and the transistor, a first insulating layer having insulating properties and disposed between the light-shielding body and the transistor, the first insulating layer being in contact with the light-shielding body, and a second insulating layer having insulating properties and disposed between the first insulating layer and the transistor, the second insulating layer being in contact with the first insulating layer. A content of a predetermined element that is not an element of a main component in the first insulating layer is higher than a content of the predetermined element in the second insulating layer.

To provide a semiconductor device including element layers that are stacked. A first wiring layer and a second wiring layer are stacked between a first element layer and a second element layer. A third wiring layer and a fourth wiring layer are stacked over the second element layer. Transistors of logic cells are provided in the first element layer. Wirings of the logic cells are provided in the first wiring layer or the second wiring layer. Input ports and output ports of the logic cells are provided in the third wiring layer. The input port of one of the logic cells is connected to the output port of another logic cell through the wiring of the third wiring layer or the fourth wiring layer. Connecting the logic cells through the wiring layers over the second element layer improves the efficiency of steps of arranging and connecting the logic cells.

A laser crystallization device includes a laser oscillator, a stage, and a reflection unit. The stage is configured to support a substrate with a target film disposed on the substrate. The laser oscillator is configured to irradiate an incident laser beam on the target film. The stage is configured to move the substrate such that the incident laser beam scans the target film. The incident laser beam is reflected from the target film to generate a reflected laser beam. The reflection unit includes at least two reflection mirrors positioned at a path of the reflected laser beam. The reflection unit is configured to re-irradiate the reflected laser beam on the target film two or more times through a plurality of paths that are different from a path of the incident laser beam.

A thin film transistor and a manufacturing method thereof, an array substrate and a manufacturing method thereof, and a display device are disclosed. The manufacturing method of the array substrate includes depositing an amorphous silicon thin film layer on a base substrate; performing a patterning process on the amorphous silicon thin film layer, so as to form a pattern with multiple small pores at a surface of the amorphous silicon thin film layer. With this method, when a laser annealing treatment of amorphous silicon is performed, the molten silicon after melting fills the space of small pores at a surface of the amorphous silicon thin film layer firstly, thereby avoiding forming a protruded grain boundary that is produced because the excess volume of polysilicon is squeezed.

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.

A low temperature poly-silicon thin film transistor and a fabrication method thereof, an array substrate and a display device are provided. The method comprises: S1: sequentially forming an active layer (3), a gate insulation layer (4), a gate electrode (5) and an interlayer insulation layer (6) on a base substrate (1); S2: forming a first metal thin film layer (8); S3: performing a hydrogenation treatment on the active layer (3) and the gate insulation layer (6); S4: forming a second metal thin film layer (7), the second metal thin film layer (7) being used for forming a source electrode and a drain electrode.

An object is to provide a semiconductor device having a structure in which parasitic capacitance between wirings can be efficiently reduced. In a bottom gate thin film transistor using an oxide semiconductor layer, an oxide insulating layer used as a channel protection layer is formed above and in contact with part of the oxide semiconductor layer overlapping with a gate electrode layer, and at the same time an oxide insulating layer covering a peripheral portion (including a side surface) of the stacked oxide semiconductor layer is formed. Further, a source electrode layer and a drain electrode layer are formed in a manner such that they do not overlap with the channel protection layer. Thus, a structure in which an insulating layer over the source electrode layer and the drain electrode layer is in contact with the oxide semiconductor layer is provided.