Abstract: In a liquid crystal display device having a reflection electrode of a reflection diffuser panel shape formed with surface roughness, a liquid crystal orientation film for realizing a predetermined pre-tilt angle is formed on the reflection electrode by an optical orientation technique.

Abstract: A bottom-gate thin-film transistor includes a gate electrode, a gate insulating film, an active layer, and a protective insulating film deposited in that order on a substrate. The protective insulating film has a thickness of 100 nm or less, and the protective insulating film is formed on any one of the active layer, and LDD region, and a source-drain region. A method for making a bottom-gate thin-film transistor, a liquid crystal display device including a TFT substrate using the bottom-gate thin-film transistor and a method for fabricating the same, and an organic EL device including the bottom-gate thin-film transistor and a method for fabricating the same are also disclosed.

Abstract: A display device includes pixels disposed in a matrix on a transparent base plate. Each pixel includes an opening region, in which an electro-optic element for emitting light through the base plate is formed, and a non-opening region, in which a thin film transistor for driving the electro-optic element is formed. The non-opening region has a first film structure including the thin film transistor. The opening region has a second film structure extending from the first film structure and existing between the electro-optic element and the base plate. The second film structure is different from the first film structure so as to adjust the light passing through the opening region.

Abstract: A thin film semiconductor device formed as integrated circuits on an insulating substrate with bottom gate type thin film transistors stacked with gate electrodes, a gate insulating film and a semiconductor thin film in the order from below upward. The gate electrodes comprise metallic materials with thickness less than 100 nm. The gate insulating film has a thickness thicker than the gate electrodes. The semiconductor thin film comprises polycrystalline silicon crystallized by a laser beam. By reducing thickness of metallic gate electrodes, thermal capacity becomes small and difference in thermal condition on the metallic gate electrodes and on the insulating substrate made of glass or the like becomes small. This invention relates to the task of uiforming and optimizing recrystallization by a laser anneal treatment provided for the semiconductor thin film which works as an active layer of the bottom gate type thin film transistors.

Abstract: A polycrystalline thin film of good quality is obtained by improving a crystallization process of a semiconductor thin film using laser light. After conducting a film forming step of forming a non-single crystal semiconductor thin film on a surface of a substrate, an annealing step is conducted by irradiating with laser light to convert the non-single crystal semiconductor thin film to a polycrystalline material. The annealing step is conducted by changing and adjusting the cross sectional shape of the laser light to a prescribed region. The semiconductor thin film is irradiated once or more with a pulse of laser light having an emission time width from upstand to downfall of 50 ns or more and having a constant cross sectional area, so as to convert the semiconductor thin film contained in an irradiated region corresponding to the cross sectional area to a polycrystalline material at a time. At this time, the energy intensity of laser light from upstand to downfall is controlled to apply a desired change.

Abstract: Method of forming a uniform polycrystalline semiconductor thin film by laser annealing. The method is started with preparing a substrate having an insulating layer which has a relatively low thermal conductivity and a thickness of more than 20 nm. Then, an amorphous silicon thin film having a relatively high thermal conductivity is formed to a thickness of less than 35 nm on the insulating layer. Thereafter, the amorphous silicon thin film is irradiated with laser beam to impart thermal energy to the film. In this way, the amorphous film is converted into a polysilicon thin film. Since the thickness of the amorphous silicon film is less than 35 nm, polysilicons having uniform grain diameters can be grown.