Abstract: A thin-film transistor, such as a top-gate thin-film transistor, is provided herein. The thin-film transistor has a performance-enhancing layer, such as a performance-enhancing bottom layer, comprising a polymer other than a polyimide. In specific embodiments, the polymer is selected from the group consisting of polysiloxane, polysilsesquioxane, and mixtures thereof. In other embodiments, it is a self-assembling polymeric monolayer of a silane agent and an organophosphonic acid. The performance-enhancing layer directly contacts the substrate. The layer improves the carrier mobility and current on/off ratio of the thin film transistor.

Abstract: A thin film transistor array substrate including an insulating substrate, a first metallic pattern formed on the insulating substrate, and an insulating film provided on the first metallic pattern. A semiconductor pattern is provided on the insulating film, and a second metallic pattern is provided on the semiconductor pattern. The second metallic pattern is surrounded by the semiconductor pattern.

Abstract: According to an embodiment, there is provided a thin film transistor substrate divided into a display area displaying the image and a non-display besides the display area, the thin film transistor substrate comprising: a common voltage line for MPS (mass production system) test and a grounding line for MPS (mass production system) test formed at the edge of the non-display area in parallel; an insulating layer covering the common voltage line for MPS (mass production system) test and the grounding line for MPS (mass production system) test; and an electrode layer formed on the insulating layer corresponded to the common voltage line for MPS (mass production system) test and the grounding line for MPS (mass production system) test. Thus, the present invention provides a thin film transistor substrate and a fabricating method thereof for minimizing defects due to static electricity.

Abstract: The active layer of an n-channel TFT is formed with a channel forming region, a first impurity region, a second impurity region and a third impurity region. In this case, the concentration of the impurities in each of the impurity regions is made higher as the region is remote from the channel forming region. Further, the first impurity region is disposed so as to overlap a side wall, and the side wall is caused to function as an electrode to thereby attain a substantial gate overlap structure. By adopting the structure, a semiconductor device of high reliability can be manufactured.

Abstract: A thin film transistor (TFT) with a self-aligned lightly-doped region and a fabrication method thereof. An active layer has a channel region, a first doped region and a second doped region, in which the first doped region is disposed between the channel region and the second doped region. A gate insulating layer formed overlying the active layer has a central region, a shielding region and an extending region. The shielding region is disposed between the central region and the extending region, the central region covers the channel region, the shielding region covers the first doped region, and the extending region covers the second doped region. The shielding region is thicker than the extending region. A gate layer is formed overlying the gate insulating layer, covers the central region and exposes the shielding region and the extending region.

Abstract: Thin film transistors for a display device each include a semiconductor layer made of polysilicon having a channel region, drain and source regions at both sides of the channel region and doped with impurity of high concentration, and an LDD region arranged either between the drain region and the channel region or between the source region and the channel region and doped with impurity of low concentration. An insulation film is formed over an upper surface of the semiconductor layer and has a film thickness which decreases in a step-like manner as it extends to the channel region, the LDD region, the drain and the source regions; and a gate electrode is formed over the channel region through the insulation film. Such a constitution can enhance the numerical aperture and can suppress the magnitude of stepped portions in a periphery of the thin film transistor.

Abstract: Disclosed herein are a perfluoroalkyleneoxy group-substituted phenylethylsilane compound and a polymer thereof. The perfluoroalkyleneoxy group-substituted phenylethylsilane compound represented by Formula 1 has excellent thermal and chemical stability to be solution-processed in a monomer state, and the polymer prepared by thermally crosslinking the compound has a high resistance to organic solvents. Moreover, since an insulating layer prepared by applying the same shows improved thermal and physical properties, it is possible to manufacture organic thin-film transistors having a high on/off ratio in a simple process such as a photolithography for a large-size substrate: wherein R1, R2, R3, Z1, Z2, Z3, and n are the same as defined in the detailed description of the invention.

Abstract: A thin film transistor with multiple gates is fabricated using a super grain silicon (SGS) crystallization process. The thin film transistor a semiconductor layer formed in a zigzag shape on an insulating substrate, and a gate electrode intersecting with the semiconductor layer. The semiconductor layer has a high-angle grain boundary in a portion of the semiconductor layer that does not cross the gate electrode.

Abstract: An exemplary thin film transistor substrate (30) includes a bas substrate (31) and a gate electrode (32) formed on the bas substrate. The gate electrode includes a bonding layer (321) formed on the bas substrate and an electrically conductive layer (322) formed on the bonding layer. The bonding layer includes one of aluminum oxide and zirconium dioxide.

Abstract: The present invention relates to a multi-domain, specifically 4-domain, liquid crystal display and a method for manufacturing the same. In one aspect, the liquid crystal display includes a pair of opposed substrates and a liquid crystal injected and sealed between the substrates. A first region and a second region on the first substrate have different alignment directions due to a photosensitive alignment film formed on the first substrate. Each pixel on the second substrate exhibits four different liquid crystal alignment directions when an electric field is applied. This occurs because a fringe field is generated by a slit-patterned pixel electrode of the second substrate, and different alignment directions are formed in the first substrate.

Abstract: A thin film transistor includes a substrate, a crystallized semiconductor layer formed over the substrate having a channel region, low-density impurity regions and high-density impurity regions, a gate insulating layer formed on the crystallized semiconductor layer, a first gate electrode formed on the gate insulating layer having a width corresponding to the channel region, a second gate electrode formed on the first gate electrode and on the gate insulating layer such that the second gate electrode overlaps the low-density impurity regions and a source electrode and a drain electrode respectively contacting the high-density impurity regions.

Abstract: A method for fabricating a liquid crystal display includes providing a first substrate having a pixel part and a driving circuit part, forming a gate electrode in the pixel part of the first substrate, forming a first insulation film, a first amorphous silicon thin film and a second amorphous silicon thin film on the first substrate, forming a first conductive film on the first substrate, having the first insulation film, the first amorphous silicon thin film, and the second amorphous silicon thin film, selectively patterning the first conductive film, the second amorphous silicon thin film and the first amorphous silicon thin film to form an active pattern in each of the pixel part and the driving circuit part of the first substrate and source and drain electrodes, crystallizing the first amorphous silicon thin film constituting the active pattern of the driving circuit part, forming a second insulation film on the first substrate, forming a pixel electrode in the pixel part and a gate electrode in the drivi

Abstract: An organic thin film transistor (OTFT) having an adhesive layer and a method of fabricating the same. The OTFT includes a gate electrode formed on a substrate, a gate insulating layer formed on the gate electrode and on remaining exposed portions of the substrate, an adhesive layer formed on the gate insulating layer, source/drain electrodes formed on the adhesive layer, and a semiconductor layer formed on the source/drain electrodes and on the adhesive layer. The gate insulating layer and the semiconductor layer are organic, the adhesive layer providing adhesion between the source/drain electrodes and the gate insulating film while preventing gate leakage current while also improving contact resistance.

Abstract: A TFT, in which source and drain electrodes having concentric circular shapes are formed, reduces an OFF current caused by a leakage current and optimizes an ON current and a stray capacitance between gate and source electrodes. The TFT includes a gate electrode formed on a substrate; and source and drain electrodes obtained by sequentially forming a gate insulating film, an intrinsic amorphous silicon layer, and an n+ amorphous silicon layer on the gate electrode, wherein the source and drain electrodes have circular shapes. One of the source and drain electrodes is disposed at the center, and the other one of the source and drain electrodes having a concentric circular shape surrounds the former. A channel region may be formed between the source and drain electrodes; and an area of an effective stray capacitance may be less than 150 ?m2. A ratio of a width of a channel to a length of the channel may be more than 4.5 and a filling capacity index to the effective stray capacitance may be less than 50.

Abstract: Provided is a thin film transistor that may be manufactured using Metal Induced Crystallization (MIC) and method for fabricating the same. Also provided is an active matrix flat panel display using the thin film transistor, which may be created by forming a crystallization inducing metal layer below a buffer layer and diffusing the crystallization inducing metal layer. The thin film transistor may include a crystallization inducing metal layer formed on an insulating substrate, a buffer layer formed on the crystallization inducing metal layer, and an active layer formed on the buffer layer and including source/drain regions, and including polycrystalline silicon crystallized by the MIC process.

Abstract: A thin film transistor (TFT) array substrate is provided in which a sufficiently large contact area between conductive materials is provided in a contact portion, and a method of fabricating the TFT array substrate. The TFT array substrate includes a gate interconnection line arranged on an insulating substrate, a gate insulating layer covering the gate interconnection line, a semiconductor layer arranged on the gate insulating layer, a data interconnection line including a data line, a source electrode, and a drain electrode arranged on the semiconductor layer, a first passivation film arranged on the data interconnection line and exposing the drain electrode, a second passivation film arranged on the first passivation film, and a pixel electrode electrically connected with the drain electrode. An outer sidewall of the second passivation film is positioned inside an outer sidewall of the first passivation film.

Abstract: A thin-film transistor (TFT) substrate includes a gate electrode, a gate insulation pattern, a channel pattern, a first organic insulation pattern, a source electrode and a drain electrode. The gate electrode is formed on a base substrate. The gate insulation pattern is formed on the gate electrode and is smaller than the gate electrode. The channel pattern is formed on the gate insulation pattern and the channel pattern is smaller than the gate electrode. The first organic insulation pattern is formed on the base substrate to cover the channel pattern, the gate insulation pattern and the gate electrode.

Abstract: A method of producing a thin film transistor array substrate which includes an insulating substrate, a display pixel having a pixel electrode connected to a drain electrode, a gate wiring, and a source wiring perpendicular to the gate wiring, comprising forming a first thin metal multi-layer film an upper layer of which includes aluminum, and spreading a photo-resist, forming the photo-resist to a thickness less in an area connected to a second thin metal film than other area, patterning the first thin metal film, reducing a thickness of the photo-resist layer and removing the photo-resist in the area, removing the upper layer in the area to expose a lower layer, forming an interlayer insulating film and patterning it to expose the lower layer in the area, and patterning the second thin metal film to include the area, to connect the lower layer to the second thin metal film.

Abstract: A semiconductor film serving as an active region of a thin film transistor and an upper oxide film protecting the semiconductor film are dry etched to form the active region. In this case, a fluorine-based gas is used as the etching gas, and the etching gas is switched from the fluorine-based gas to a chlorine-based gas at a point of time when a lower oxide film as an underlying film of the semiconductor film is exposed. As the fluorine-based gas, a mixed gas of CF4 and O2 is used, and suitably, a gas ratio of CF4 and O2 in the mixture gas is set at 1:1, and the dry etching is performed therefor. By this etching, a side face of a two-layer structure of the semiconductor film and upper oxide film is optimally tapered, and a crack or a disconnection is prevented from being occurring in a film crossing over the two-layer structure.

Abstract: A plurality of gate lines are formed on a substrate. After depositing a gate insulating layer, a semiconductor layer and a doped amorphous silicon layer are sequentially formed thereon. A lower insulating layer made of silicon nitride and an upper insulating layer made of a photosensitive organic material are deposited thereon after forming data lines and drain electrodes. The upper insulating layer is patterned to form an unevenness pattern on its surface and contact holes on the drain electrodes. The lower insulating layer is patterned together with the gate insulating layer using a photoresist pattern having apertures located in the contact holes to form other contact holes respectively exposing the drain electrodes, portions of the gate lines, and portions of the data lines.

Abstract: Provided is a structure for conductive members in a TFT display. The structure is aluminum based and is heat treated. When heat treated, no hillocks are formed because of the presence of a titanium layer. Furthermore, TiAl3 is not formed because of the presence of a TiN diffusion layer between the aluminum and the Ti layers. This novel structure has a low resistivity and is therefore suited for large displays that use thin film transistors to drive the pixels.

Abstract: In a fabrication method of a thin film transistor, a gate electrode is patterned with a first mask and an active pattern and a photoresist pattern are formed with a second mask. The photoresist pattern is ashed based on a predetermined width of an etch stopper. An insulating layer underlying the ashed photoresist pattern is patterned to form the etch stopper. In the fabrication method, the etch stopper may function as a passivation layer and is formed on an active layer of a thin film transistor part.

Abstract: A light-emitting device is disclosed capable of reducing the variation of an emission spectrum depending on an angle of viewing a light extraction surface. More particularly, a light-emitting device is disclosed capable of preventing impurities from dispersing from a light-emitting element into a thin film transistor as well as reducing the variation of an emission spectrum depending on an angle of viewing a light extraction surface. The disclosed light-emitting device comprises a substrate; a first insulating layer provided over the substrate; a transistor provided over the first insulating layer; and a second insulating layer having a first opening portion so that the transistor is covered and the substrate is exposed; wherein a light-emitting element is provided inside the first opening portion.

Abstract: A method of manufacturing a bottom gate thin film transistor (“TFT”), in which a polycrystalline channel region having a large grain size is formed relatively simply and easily, includes forming a bottom gate electrode on a substrate, forming a gate insulating layer on the substrate to cover the gate electrode, forming an amorphous semiconductor layer on the gate insulating layer, patterning the amorphous semiconductor layer to form an amorphous channel region on the gate electrode, melting the amorphous channel region using a laser annealing method to form a melted amorphous channel region, and crystallizing the melted amorphous channel region to form a laterally grown polycrystalline channel region.

Abstract: The TFT has a channel-forming region formed of a crystalline semiconductor film obtained by heat-treating and crystallizing an amorphous semiconductor film containing silicon as a main component and germanium in an amount of not smaller than 0.1 atomic % but not larger than 10 atomic % while adding a metal element thereto, wherein not smaller than 20% of the lattice plane {101} has an angle of not larger than 10 degrees with respect to the surface of the semiconductor film, not larger than 3% of the lattice plane {001} has an angle of not larger than 10 degrees with respect to the surface of the semiconductor film, and not larger than 5% of the lattice plane {111} has an angle of not larger than 10 degrees with respect to the surface of the semiconductor film as detected by the electron backscatter diffraction pattern method.

Abstract: A display device includes a pixel region having a plurality of pixels and a peripheral circuit region disposed at a periphery of the pixel region for driving the pixels. The peripheral circuit region includes transistors fabricated from polycrystalline semiconductor and having a semiconductor crystalline grain of a first kind in a channel region thereof, wherein a grain size of the semiconductor crystalline grain of the first kind is at least 3 ?m. The pixel region includes transistors fabricated from polycrystalline semiconductor and having a semiconductor crystalline grain of a second kind in a channel region thereof, wherein a grain size of the semiconductor crystalline grain of the second kind is at least 0.05 ?m.

Abstract: Disclosed herein is a method of manufacturing a gate insulator and a thin film transistor (“TFT”) incorporating the gate insulator, including forming an oxygen-containing, conductive gate on a substrate; forming a gate insulator material layer on the substrate so as to cover the gate; and applying a heat treatment so as to diffuse oxygen from the oxygen-containing gate layer into the gate insulating material layer thereby forming the gate insulator.

Abstract: TFTs arranged in various circuits have structures that are suited for circuit functions, in order to improve operation characteristics and reliability of the semiconductor device, to lower consumption of electric power, to decrease the number of steps, to lower the cost of production and to improve the yield. The gradient of concentration of impurity element for controlling the conduction type in the LDD regions 622 and 623 of the TFT is such that the concentration increases toward the drain region. For this purpose, a tapered gate electrode 607 and a tapered gate-insulating film 605 are formed, and the ionized impurity element for controlling the conduction type is added to the semiconductor layer through the gate-insulating film 605.

Abstract: A TFT LCD array substrate and a manufacturing method thereof. The manufacturing method includes the steps of: forming a thin film transistor on a substrate to form a gate line and a gate electrode connected with the gate line on the substrate; forming a gate insulating layer and a semiconductor layer on the gate electrode; forming an ohmic contact layer on the semiconductor layer; forming a transparent pixel electrode layer and a source/drain electrode metal layer in sequence on the resultant substrate, wherein the transparent pixel electrode layer is electrically insulated from the gate line and the gate electrode, and the transparent pixel electrode layer forms an ohmic contact with two sides of the semiconductor layer via the ohmic contact layer; and performing masking and etching with a gray tone mask with respect to the resultant substrate to form a transparent pixel electrode, a source/drain electrode and a data line simultaneously.

Abstract: A method for fabricating a thin film transistor (“TFT”) device includes providing a substrate, forming a patterned amorphous silicon layer over the substrate including a pair of first regions, a second region disposed between the pair of first regions, and at least one third region, each of which being disposed between and contiguous with the second region and each of the pair of first regions, the second region including a sub-region contiguous with each of the at least one third region, forming a heat retaining layer over the substrate, irradiating the patterned amorphous silicon layer with a laser through the heat retaining layer to form a patterned crystallized silicon layer corresponding to the patterned amorphous silicon layer including a grain boundary extending substantially across a crystallized sub-region corresponding to the sub-region, and forming a patterned conductive layer over a portion of a crystallized second region of the patterned crystallized silicon layer corresponding to the second regi

Abstract: A semiconductor device comprises a fin-type semiconductor region (fin) on a support substrate, having a pair of generally vertical side walls and an upper surface coupling the side walls; an insulated gate electrode structure traversing an intermediate portion of the fin and having side walls in conformity with the side walls of the fin; source/drain regions formed in the fin on both sides of the gate electrode; side wall insulating films including a first portion formed on the side walls of the conductive gate electrode and a second portion formed on the side walls of the fin and having an opening in the source/drain regions extending from an upper edge to a lower edge of each of the side walls; a silicide layer formed on each surface of the source/drain regions exposed in the opening of the second side wall insulating film; and source/drain electrodes contacting the silicide layers.

Abstract: A double-gate thin-film transistor and a method for forming the same, using low-temperature poly-silicon formed by direct deposition on a substrate so as to simplify the manufacturing process and improve the electrical characteristics. The double-gate thin-film transistor comprises: a first patterned electrode formed on a substrate; a first dielectric layer; a poly-silicon film, formed by direct deposition on the first dielectric layer so as to form between the poly-silicon film and the first dielectric layer an incubation layer comprising amorphous silicon; a pair of second patterned electrodes, formed on the poly-silicon film so as to define in the poly-silicon film and the incubation layer between the second patterned electrodes a channel region corresponding to the first patterned electrode; a second dielectric layer; and a third patterned electrode corresponding to the channel region.

Abstract: A first thin film transistor including a gate electrode, a source region, a drain region, a GOLD region, and a channel region is formed at a first region at a TFT array substrate. A second thin film transistor including a gate electrode, a source region, drain region, a GOLD region, and a channel region is formed at a second region. The GOLD length (0.5 ?m) of the GOLD region of the second thin film transistor is set shorter than the GOLD length (1.5 ?m) of the GOLD region of the first thin film transistor. Accordingly, a semiconductor device directed to reducing the area occupied by semiconductor elements is obtained.

Abstract: The present invention is characterized in that a semiconductor film containing a rare gas element is formed on a crystalline semiconductor film obtained by using a catalytic element via a barrier layer, and the catalytic element is moved from the crystalline semiconductor film to the semiconductor film containing a rare gas element by a heat treatment. Furthermore, a first impurity region and a second impurity region formed in a semiconductor layer of a first n-channel TFT are provided outside a gate electrode. A third impurity region formed in a semiconductor layer of a second n-channel TFT is provided so as to be partially overlapped with a gate electrode. A third impurity region is provided outside a gate electrode. A fourth impurity region formed in a semiconductor layer of a p-channel TFT is provided so as to be partially overlapped with a gate electrode. A fifth impurity region is provided outside a gate electrode.

Abstract: A method of forming a gate insulation film of a crystallized thin film transistor, is provided, which can enhance an interfacial feature which exists between a gate oxide film and a silicon thin film substrate and which is fatal to performance of the thin film transistor, in the case that crystallization of amorphous silicon is performed by metal induced lateral crystallization (MILC). The gate insulation film formation method includes the steps of: forming an amorphous silicon film on an insulation substrate, and then patterning the amorphous silicon film, to thereby form a semiconductor layer; processing the semiconductor layer made of the amorphous silicon film by an oxygen plasma method, and oxidizing the silicon surface, to thereby form a first silicon oxide film; and mixing gas with silicon and depositing a second silicon oxide film on the first silicon oxide film by a PECVD (Plasma Enhanced Chemical Vapor Deposition) method.

Abstract: A method of manufacturing a semiconductor device having an organic semiconductor film comprises a step of preparing a transparent substrate at least having an opaque gate electrode and a gate insulator thereover, a step of forming a layer containing metal-nano-particles as a conductive layer for a source electrode and a drain electrode to the thus prepared transparent substrate, a step of applying exposure to the transparent substrate on the side of a surface not mounted with the opaque gate electrode, a step of flushing away a portion other than the source electrode and the drain electrode in the layer containing the metal-nano-particles after the exposure, and a step of forming an organic semiconductor layer forming a channel portion. Lower and upper electrodes are positioned in self-alignment manner and thus no positional displacement occurs even if a printing method is used.

Abstract: A semiconductor device having two thin film transistors where cross-talk is minimized and a flat panel display device having the same.

Abstract: A method for fabricating a device is disclosed. The method includes providing a substrate; forming a thin film on the substrate; forming a photoresistable layer on the thin film; irradiating light onto the photoresistable layer through a photo mask having a transmissive region, a semi-transmissive region, a diffractive region and an interceptive region, and developing the photoresistable layer to form a photoresist pattern having at least three different thicknesses. With the above-described process, a liquid crystal display device (LCD), for example, can be manufactured using three photo masks.

Abstract: There is provided a semiconductor device having TFTs whose thresholds can be controlled. There is provided a semiconductor device including a plurality of TFTs having a back gate electrode, a first gate insulation film, a semiconductor active layer a second gate insulation film and a gate electrode, which are formed on a substrate, wherein an arbitrary voltage is applied to the back gate electrode.

Abstract: An organic light-emitting display including a substrate, at least one thin film transistor, a pixel electrode and at least one pad electrode. The substrate is provided with a display area and a pad area spaced apart from the display area. The thin film transistor is disposed on the display area of the substrate, and includes an active layer, a gate electrode and source/drain electrodes. The pixel electrode is adjacent to the thin film transistor, and is electrically connected to the thin film transistor. The pad electrode is disposed on the pad area of the substrate, is formed of the same layer as the gate electrode or the source/drain electrodes, and is coupled with an external module.

Abstract: A vertically-stacked three-dimensional nanocrystal memory device and a method for manufacturing the same is proposed. Each of the two vertically overlapping memory cells of the vertically-stacked three-dimensional nanocrystal memory device includes a thin-film transistor and nanocrystals embedded in a gate dielectric layer of the thin-film transistor. With the two vertically overlapping memory cells including, sharing and being controlled by a wordline, the bit density of the memory increases.

Abstract: Disclosed herein is a method for fabricating a reverse-staggered polycrystalline silicon thin film transistor, and more specifically a method for fabricating a reverse-staggered polycrystalline silicon thin film transistor wherein a phosphosilicate-spin-on-glass (P-SOG) is used for a gate insulating film. The method comprises the steps of: forming a buffer layer on an insulating substrate; forming a gate metal pattern on the buffer layer; forming a planarized gate insulating film on the gate metal pattern; depositing an amorphous silicon layer on the gate insulating film; crystallizing the amorphous silicon layer into a polycrystalline silicon layer; forming a n+ or p+ layer on the polycrystalline silicon layer; forming a source/drain metal layer on the n+ or p+ layer; and forming a passivation layer on the source/drain metal layer.

Abstract: A circuit adapted to dynamically activate an electro-optical display device is constructed from a thin-film gate-insulated semiconductor device. This device comprises PMOS TFTs producing only a small amount of leakage current. Besides the dynamic circuit, a CMOS circuit comprising both NMOS and PMOS thin-film transistors is constructed to drive the dynamic circuit.

Abstract: A liquid crystal display panel including a thin film transistor array substrate structure including, a substrate, a gate line and a data line disposed on the substrate and insulated from each other by a gate insulating pattern, a thin film transistor provided at intersection of the gate and data lines, a protective film disposed to protect the thin film transistor, and a pad structure connected to a respective one of the gate line and data line, the pad structure including a transparent conductive film and a data metal layer; and a color filter array substrate structure joined with the thin film transistor array substrate structure, wherein the protective film is disposed within an area where the color filter array substrate structure overlaps with the thin film transistor array substrate structure, and exposing either the data metal layer or the transparent conductive film along a side portion of the substrate.

Abstract: A technique for manufacturing TFTs having little dispersion in their electrical characteristics is provided. Contamination of a semiconductor film is reduced by performing oxidation processing having an organic matter removing effect, forming a clean oxide film, after removing a natural oxide film formed on a semiconductor film surface. TFTs having little dispersion in their electrical characteristics can be obtained by using the semiconductor film thus obtained in active layers of the TFTs, and the electrical properties can be improved. In addition, deterioration in productivity and throughput can be reduced to a minimum by using a semiconductor manufacturing apparatus of the present invention.

Abstract: A thin film transistor (TFT) substrate comprises: a plastic insulation substrate; a first silicon nitride layer with a first refractive index, formed one surface of the plastic insulation substrate; and a TFT comprising a second silicon nitride layer formed with a second refractive index smaller than the first refractive index on the first silicon nitride layer. Thus, the present invention provides a TFT substrate wherein there is reduced a problem in that thin films are lifted from a plastic insulation substrate.

Abstract: In a solid state image pickup apparatus with a photodetecting device and one or more thin film transistors connected to the photodetecting device formed in one pixel, a part of the photodetecting device is formed over at least a part of the thin film transistor, and the thin film transistor is constructed by a source electrode, a drain electrode, a first gate electrode, and a second gate electrode arranged on the side opposite to the first gate electrode with respect to the source electrode and the drain electrode, and the first gate electrode is connected to the second gate electrode every pixel, thereby, suppressing an adverse effect of the photodetecting device on the TFT, a leakage at turn-off TFT, variation in a threshold voltage of the TFT due to an external electric field, and accurately transferring photo carrier to a signal processing circuit.

Abstract: A thin film transistor array substrate includes a gate pattern on a substrate. The gate pattern includes a gate electrode, a gate line connected to the gate electrode, and a lower gate pad electrode connected to the gate line. A source/drain pattern includes a source electrode and a drain electrode, a data line connected to the source electrode, and a lower data pad electrode connected to the data line. A semiconductor pattern is formed beneath the source/drain pattern. A transparent electrode pattern includes a pixel electrode connected to the drain electrode, an upper gate pad electrode connected to the lower gate pad electrode, and an upper data pad electrode connected to the lower data pad electrode. The thin film array substrate further includes a gate insulating pattern and a passivation film pattern stacked at remaining areas excluding areas within which the transparent electrode pattern is formed.

Abstract: An object of the present invention is to provide a TFT of new structure in which the gate electrode overlaps with the LDD region and a TFT of such structure in which the gate electrode does not overlap with the LDD region. The TFT is made from crystalline semiconductor film and is highly reliable. The TFT of crystalline semiconductor film has the gate electrode formed from a first gate electrode 113 and a second gate electrode in close contact with said first gate electrode and gate insulating film. The LDD is formed by ion doping using said first gate electrode as a mask, and the source-drain region is formed using said second gate electrode as a mask. After that the second gate electrode in the desired region is selectively removed. In this way it is possible to form LDD region which overlaps with the second gate electrode.

Abstract: A thin film transistor substrate for a display device having a plurality of thin film transistors and pixel electrodes connected to the thin film transistors, said thin film transistor substrate includes: a plurality of pad electrodes in a non-display area of the display device for applying signals to the plurality of thin film transistors in a non-display area of the display device; a protective film covering the pad electrodes in the non-display area; and a slit in the protective film adjacent to at least one of the plurality of pad electrodes.