An object is to provide a semiconductor device of which a manufacturing process is not complicated and by which cost can be suppressed, by forming a thin film transistor using an oxide semiconductor film typified by zinc oxide, and a manufacturing method thereof. For the semiconductor device, a gate electrode is formed over a substrate; a gate insulating film is formed covering the gate electrode; an oxide semiconductor film is formed over the gate insulating film; and a first conductive film and a second conductive film are formed over the oxide semiconductor film. The oxide semiconductor film has at least a crystallized region in a channel region.

Semiconductor device, and manufacturing method thereof

There is provided a light emitting device in which low power consumption can be realized even in the case of a large screen. The surface of a source signal line or a power supply line in a pixel portion is plated to reduce a resistance of a wiring. The source signal line in the pixel portion is manufactured by a step different from a source signal line in a driver circuit portion. The power supply line in the pixel portion is manufactured by a step different from a power supply line led on a substrate. A terminal is similarly plated to made the resistance reduction. It is desirable that a wiring before plating is made of the same material as a gate electrode and the surface of the wiring is plated to form the source signal line or the power supply line.

Light emitting device and method of manufacturing the same

In fabricating a thin film transistor, an active layer comprising a silicon semiconductor is formed on a substrate having an insulating surface Hydrogen is introduced into The active layer A thin film comprising SiO x N y is formed to cover the active layer and then a gate insulating film comprising a silicon oxide film formed on the thin film comprising SiO x N y  Also, a thin film comprising SiO x N y is formed under the active layer The active layer includes a metal element at a concentration of 1×10 15 to 1×10 19 cm −3 and hydrogen at a concentration of 2×10 19 to 5×10 21 cm −3 

Semiconductor device and method for forming the same

LED pixel structures and methods that improve brightness uniformity by reducing current nonuniformities in a light-emitting diode of the pixel structures are disclosed.

Active matrix light emitting diode pixel structure and concomitant method

A transferring method including providing a substrate, forming a transferred layer over the substrate, joining a transfer member to the transferred layer, and removing the transferred layer from the substrate. The transferring method further includes transferring the transferred layer to the transfer member and reusing the substrate for another transfer. The transferring method may also include providing a substrate, forming a separation layer over the substrate, forming a transferred layer over the separation layer, and partly cleaving the separation layer such that a part of the transferred layer is transferred to a transfer member in a given pattern. The transferring method may also include joining a transfer member to the transferred layer, removing the transferred layer from the substrate and transferring the transferred layer to the transfer member, these of which constitute a transfer process, the transfer process being repeatedly performed.

Exfoliating method, transferring method of thin film device, and thin film device, thin film integrated circuit device, and liquid crystal display device produced by the same

A light valve has a composite substrate comprised of an electrically insulating substrate and a semiconductor single crystal thin film formed over the electrically insulating substrate. A pixel array comprising semiconductor switch elements is formed in the semiconductor single crystal thin film. A peripheral circuit having circuit elements is formed in the semiconductor single crystal thin film so that a small-sized, high speed light valve is obtained. X- driver and Y-driver circuits are formed in the semiconductor single crystal thin film and controlled by a control circuit, such as a video signal processing circuit, which receives and processes video signals inputted directly from an external source. The peripheral circuit can be a DRAM sense amplifier for sensing charges stored in each pixel of the pixel array to detect defects in the pixel array. The peripheral circuit can be a photosensor circuit for detecting an intensity of incident light to monitor the performance of a light source of the light valve. The peripheral circuit can be a temperature sensor for detecting the temperature of a liquid crystal layer of the light valve, and may be comprised of Darlington connected NPN transistors formed in the semiconductor single crystal thin film. The peripheral circuit can also be a solar cell for converting incident light into electrical energy to supply power to at least one of the pixel array, X-driver and Y-driver circuits and the peripheral circuit.

Light valve device

PURPOSE:To provide the structure for preventing breakdown of a semiconductor thin film layer in a pressure-connection process of an electro-optical device using a semiconductor thin film element. CONSTITUTION:Elastic bodies 12 are formed on a semiconductor substrate 1, which is formed by providing a semiconductor thin film circuit layer 7 on a glass substrate B5 through an adhesive layer 6, by screen printing or the like, and a sealing material 3 is formed outside of the elastic body 12. Thereafter, a glass substrate A2 formed with a transparent electrode 9 is arranged opposite to the substrate 5 and they are compressed, and it is left as it is for a several seconds to deform the elastic bodies 12, and the sealling material 3 is hardened by the heat to obtain an appropriate gap. Thereafter, liquid crystal 4 is filled by the vacuum filling method to form an electro-optical device. Consequently, since the gap is controlled by pinching the elastic body 12, a gap control material such as a glass fiber is not required in the sealing material 3, and breakdown of the semiconductor thin film circuit layer 7 due to the pressure- connection is prevented.

Electro-optical device

A process for forming a light valve device comprises forming a semiconductor single crystal film to form a composite substrate by polishing a semiconductor single crystal substrate after an electric insulating substrate has been bonded thereto; forming a group of pixel electrodes for defining a pixel region and a group of switch elements for selectively energizing the pixel electrodes by integrating a pixel array portion over the composite substrate; forming a liquid crystal aligning means for the pixel region; superposing an opposed substrate over the composite substrate with a gap therebetween; and filling the gap with liquid crystal material.

Light valve device making

A semiconductor device having a double-side wiring structure, in which a single crystal semiconductor thin film is formed integrally with transistor elements and is laminated on an insulating thin film. The single crystal semiconductor thin film is formed with through-holes and the insulating thin film is formed on its back side with electrodes and a shielding film. A light valve device using the semiconductor device is also disclosed. Over the single crystal semiconductor thin film, there are formed switching elements of transistors, pixel electrodes connected electrically with the switching elements, and drive circuits for scanning and driving the switching elements. Also disclosed is a miniature highly dense light valve device. In this light valve device, an electrooptical substance is arranged between a multi-layer substrate. The multi-layer substrate is formed with electrodes and a shielding film at the opposed side of the insulating film to the side formed with the grouped elements through the insulating film. A transparent opposite substrate is also formed so that the optical transparency of the electrooptical substance is controlled by the switching elements.

Light valve device using semiconductive composite substrate

A semiconductor device has an integrated circuit formed in a monosilicon layer provided on an electrically insulative material. The monosilicon layer has an integrated circuit formed thereon, and a passivation film covers the integrated circuit. A support member is fixed to the electrically insulative material through an adhesive layer to support the monosilicon layer. The integrated circuit comprises an MIS transistor having a source region, drain region, and channel region formed in the monosilicon layer. The semiconductor device is suitable for use in a high speed, high capacity liquid crystal light valve having a structure where a pixel switching element group and a peripheral driver circuit are formed integrally on a common substrate.

Hiroaki Takasu

Papers

Light valve device

Electro-optical device

Light valve device making

Light valve device using semiconductive composite substrate

Semiconductor device with monosilicon layer