Abstract: A contact portion of wiring and a method of manufacturing the same are disclosed. A contact portion of wiring according to an embodiment includes: a substrate; a conductive layer disposed on the substrate; an interlayer insulating layer disposed on the conductive layer and having a contact hole; a metal layer disposed on the conductive layer and filling the contact hole; and a transparent electrode disposed on the interlayer insulating layer and connected to the metal layer, wherein the interlayer insulating layer includes a lower insulating layer and an upper insulating layer disposed on the lower insulating layer, the lower insulating layer is undercut at the contact hole, and the metal layer fills in the portion where the lower insulating layer is undercut.

Abstract: A display device including a thin film transistor with high electric characteristics and high reliability, and a method for manufacturing the display device in high yield are proposed. In a display device including a channel stop thin film transistor with an inverted-staggered structure, the channel stop thin film transistor with the inverted-staggered structure includes a microcrystalline semiconductor film including a channel formation region. An impurity region including an impurity element imparting one conductivity type is formed as selected in a region in the channel formation region of the microcrystalline semiconductor film which does not overlap with a source electrode or a drain electrode. In the channel formation region, a non-doped region, to which the impurity element imparting one conductivity type is not added, is formed between the impurity region, which is a doped region to which the impurity element is added, and the source region or the drain region.

Abstract: A thin film transistor includes a gate electrode; an active layer formed of an oxide and insulated from the gate electrode; and a source electrode and a drain electrode formed of an oxide on the active layer such that the source electrode and the drain electrode are insulated from the gate electrode and electrically connected to the active layer, wherein the active layer, the source and the drain electrode are formed using an atomic layer deposition (ALD) and an insitu process, and a root mean square (RMS) value of the surface roughness of the active layer which contacts with the source and drain electrodes is less than 1 nm in order to reduce the contact resistance between the active layer and the source and drain electrodes, a method of manufacturing the same, an organic light emitting display apparatus including the thin film transistor, and a method of manufacturing the same.

Abstract: An active device array substrate and its fabricating method are provided. According to the subject invention, the elements of an array substrate such as the thin film transistors, gate lines, gate pads, data lines, data pads and storage electrodes, are provided by forming a patterned first metal layer, an insulating layer, a patterned semiconductor layer and a patterned metal multilayer. Furthermore, the subject invention uses the means of selectively etching certain layers. Using the aforesaid means, the array substrate of the subject invention has some layers with under-cut structures, and thus, the number of the time-consuming and complicated mask etching process involved in the production of an array substrate can be reduced. The subject invention provides a relatively simple and time-saving method for producing an array substrate.

Abstract: A display device including a thin film transistor with high electric characteristics and high reliability, and a method for manufacturing the display device with high mass-productivity. In a display device including an inverted-staggered channel-stop-type thin film transistor, the inverted-staggered channel-stop-type thin film transistor includes a microcrystalline semiconductor film including a channel formation region, and an impurity region containing an impurity element of one conductivity type is selectively provided in a region which is not overlapped with source and drain electrodes, in the channel formation region of the microcrystalline semiconductor film.

Abstract: A thin film transistor substrate having a semiconductor layer including a low concentration region and a source region/drain region adjacent to the low concentration region at both sides of a channel region made of polysilicon; a gate insulating layer and a conductive layer on the substrate the conductive layer patterned to form a gate electrode.

Abstract: The present invention provides Al—Ni-based wiring material that allows, in a display device including thin film transistors and transparent electrode layers, direct bonding to the transparent electrode layer made of ITO, IZO or the like as well as direct bonding to the semiconductor layer, such as n+-Si.

Abstract: A method for making a thin film transistor, the method comprising the steps of: providing a growing substrate; applying a catalyst layer on the growing substrate; heating the growing substrate with the catalyst layer in a furnace with a protective gas therein, supplying a carbon source gas and a carrier gas at a ratio ranging from 100:1 to 100:10, and growing a carbon nanotube layer on the growing substrate; forming a source electrode, a drain electrode, and a gate electrode; and covering the carbon nanotube layer with an insulating layer, wherein the source electrode and the drain electrode are electrically connected to the single-walled carbon nanotube layer, the gate electrode is opposite to and electrically insulated from the single-walled carbon nanotube layer.

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: An object is to obtain a semiconductor device with improved characteristics by reducing contact resistance of a semiconductor film with electrodes or wirings, and improving coverage of the semiconductor film and the electrodes or wirings. The present invention relates to a semiconductor device including a gate electrode over a substrate, a gate insulating film over the gate electrode, a first source or drain electrode over the gate insulating film, an island-shaped semiconductor film over the first source or drain electrode, and a second source or drain electrode over the island-shaped semiconductor film and the first source or drain electrode. Further, the second source or drain electrode is in contact with the first source or drain electrode, and the island-shaped semiconductor film is sandwiched between the first source or drain electrode and the second source or drain electrode. Moreover, the present invention relates to a manufacturing method of the semiconductor device.

Abstract: A process for fabricating fine features such as small gate electrodes on a transistor. The process involves the jet-printing of a mask and the plating of a metal to fabricate sub-pixel and standard pixel size features in one layer. Printing creates a small sub-pixel size gap mask for plating a fine feature. A second printed mask may be used to protect the newly formed gate and etch standard pixel size lines connecting the small gates.

Abstract: A method of fabricating a high voltage fully depleted silicon-on-insulator (FD SOI) transistor, the FD SOI transistor having a structure including a region within a body on which a gate structure is disposed. The region includes a channel separating the source region and the drain region. Above the source region is disposed a carrier recombination element, which abuts the gate structure and is electrically connected to the region via the channel. The drain region is lightly doped and ballasted to increase breakdown voltage. The FD SOI may be fabricated by forming a body with a thin silicon layer disposed on a buried oxide (BOX). Alternatively, the body may be formed using a partially depleted (PD) SOI where the region formed therein has a reduced thickness in comparison to the overall thickness of the PD SOI.

Abstract: A manufacturing method of an active layer of a thin film transistor is provided. The method includes following steps. First a substrate is provided, and a semiconductor precursor solution is then prepared through a liquid process. Thereafter, the semiconductor precursor solution is provided on the substrate to form a semiconductor precursor thin film. After that, a light source is used to irradiate the semiconductor precursor thin film to remove residual solvent and allow the semiconductor precursor thin film to produce semiconductor property, so as to form a semiconductor active layer.

Abstract: A liquid crystal display panel and a fabricating method thereof comprising an image sensing capability, image scanning, and touch inputting. In the liquid crystal display device, a gate line and a data line are formed to intersect each other on a substrate to define a pixel area in which a pixel electrode is positioned. A first thin film transistor is positioned at an intersection area of the gate line and the data line. A sensor thin film transistor senses light having image information and supplied with a first driving voltage from the data line. A driving voltage supply line is positioned in parallel to the gate line to supply a second driving voltage to the sensor thin film transistor.

Abstract: A TFT substrate includes a base substrate, a gate wiring formed on the base substrate, a gate insulation layer, an activation layer, an oxidation-blocking layer, a data wiring, a protection layer and a pixel electrode. The gate wiring includes a gate line and a gate electrode. The gate insulation layer is formed on the base substrate to cover the gate wiring. The activation layer is formed on the gate insulation layer. The oxidation-blocking layer is formed on the activation layer. The data wiring includes a data line, a source electrode and a drain electrode. The source and drain electrodes are disposed on the oxidation-blocking layer therefore lowering the on-current (“Ion”) for turning on the TFT and increasing the off-current (“Ioff”) for turning off the TFT due to the oxidation-blocking layer.

Abstract: Methods for manufacturing thin film transistor arrays utilizing three steps of lithography and one step of laser ablation while the lithography procedure is used four to five times in conventional processes are disclosed. The use of the disclosed methods assists in improving throughput and saving of manufacturing cost.

Abstract: The transistor comprises a source and a drain separated by a lightly doped intermediate zone. The intermediate zone forms first and second junctions respectively with the source and with the drain. The transistor comprises a first gate to generate an electric field in the intermediate zone, on the same side as the first junction, and a second gate to generate an electric field in the intermediate zone, on the same side as the second junction.

Abstract: A TFT is manufactured using at least five photomasks in a conventional liquid crystal display device, and therefore the manufacturing cost is high. By performing the formation of the pixel electrode 127, the source region 123 and the drain region 124 by using three photomasks in three photolithography steps, a liquid crystal display device prepared with a pixel TFT portion, having a reverse stagger type n-channel TFT, and a storage capacitor can be realized.

Abstract: A pixel structure formed on a substrate and electrically connected with a scan line and a data line, and including a semiconductor pattern and a pixel electrode is provided. The semiconductor pattern includes at least two channel areas, at least one doping area, a source area, and a drain area. The channel areas are located below the scan line and have different aspect ratios. The doping area is connected between the channel areas. The pixel electrode electrically connects the drain area, the source area is connected between one of the channel areas and the data line, and the drain area is connected between the other channel area and the pixel electrode. The scan line has different widths above different channel areas, and a length of each channel area is substantially equal to the width of the scan line.

Abstract: To provide a thin film integrated circuit at low cost and with thin thickness, which is applicable to mass production unlike the conventional glass substrate or the single crystalline silicon substrate, and a structure and a process of a thin film integrated circuit device or an IC chip having the thin film integrated circuit. A manufacturing method of a semiconductor device includes the steps of forming a first insulating film over one surface of a silicon substrate, forming a layer having at least two thin film integrated circuits over the first insulating film, forming a resin layer so as to cover the layer having the thin film integrated circuit, forming a film so as to cover the resin layer, grinding a backside of one surface of the silicon substrate which is formed with the layer having the thin film integrated circuit, and polishing the ground surface of the silicon substrate.

Abstract: There is provided an active matrix type display device in which the display device is formed of a driver circuit with an insulated gate FET capable of operating at high speed, and even if an area of a pixel electrode per unit pixel is made small, sufficient storage capacitance can be obtained. In a semiconductor device comprising an active matrix circuit with an insulated gate field effect transistor having at least an active layer made of single crystalline semiconductor, an organic resin insulating layer is formed over the insulated gate field effect transistor, a storage capacitance is formed of a light shielding layer formed over the organic resin insulating layer, a dielectric layer formed to be in close contact with the light shielding layer, and a light reflecting electrode connected to the insulated gate field effect transistor.

Abstract: Disclosed are a thin film transistor substrate of an LCD device and a method of manufacturing the same. The thin film transistor substrate includes a nickel-silicide layer formed on an insulating layer pattern including silicon and a metal layer formed on the nickel-silicide layer. Nickel is coated on the insulating layer pattern including silicon and a metal material is coated on the nickel-coated layer. After that, a heat treatment is performed at about 200 to about 350° C. to obtain the nickel-silicide layer. Since the thin film transistor substrate of the LCD device is manufactured by applying the nickel-silicide wiring, a device having low resistivity and good ohmic contact property can be obtained.

Abstract: Nickel is selectively held in contact with a particular region of an amorphous silicon film. Crystal growth parallel with a substrate is effected by performing a heat treatment. A thermal oxidation film is formed on the silicon film by performing a heat treatment in an oxidizing atmosphere containing a halogen element. During this step, in the silicon film, impurities included such as oxygen or chlorine, are segregated with extending along the crystal growth, the crystallinity is improved, and the gettering of nickel element proceeds. A thin-film transistor is formed so that the direction connecting source and drain regions coincides with the above crystal growth direction. As a result, a TFT having superior characteristics such as a mobility larger than 200 cm2/Vs and an S value smaller than 100 mV/dec. can be obtained.

Abstract: According to the present invention, which is a display device in which a light-emitting element where an organic substance generating luminescence referred to as electroluminescence or a medium including a mixture of an organic substance and an inorganic substance is sandwiched between electrodes is connected to a TFT, the invention is to manufacture a display panel by forming at least one or more of a conductive layer which forms a wiring or an electrode and a pattern necessary for manufacturing a display panel such as a mask layer for forming a predetermined pattern is formed by a method capable of selectively forming a pattern. A droplet discharge method capable of forming a predetermined pattern by selectively discharging a droplet of a composition in accordance with a particular object and by forming a conductive layer or an insulating layer is used as a method capable of selectively forming a pattern.

Abstract: The present invention relates to an OLED display and a manufacturing method thereof, including a substrate, a control electrode formed on the substrate, a polysilicon semiconductor formed on the control electrode, a data line including an input electrode at least partially overlapping the polysilicon semiconductor and an output electrode facing the input electrode, an insulating layer covering the data line and the output electrode and having a contact hole, a gate line connected to the control electrode through the contact hole, and a pixel electrode connected to the output electrode.

Abstract: A fabricating method of a TFT includes first forming a source on a substrate. Then, a first insulation pattern layer is formed to cover parts of the source and the substrate. The first insulation pattern layer has an opening exposing a part of the source. Thereafter, a gate pattern layer is formed on the first insulation pattern layer. Then, the gate pattern layer and a second insulation pattern layer formed thereon surround the opening. Moreover, a second lateral protection wall is formed on an edge of the gate pattern layer in the opening. Afterwards, a channel layer is formed in the opening and covers the second lateral protection wall and the source. Then, a passivation layer with a contact window is formed on the channel layer and the second insulation pattern layer to expose a portion of the channel layer. Thereafter, a drain is formed on the exposed channel layer.

Abstract: An array substrate includes a substrate, a data line formed on the substrate, a passivation layer formed on the data line, a gate line including a gate electrode and a capacitor line formed on the passivation layer, a gate insulation layer formed on the gate electrode and the capacitor line, a semiconductor layer formed on the gate insulation layer, a contact hole formed through the passivation layer and the gate insulation layer to expose the data line and a source electrode and a drain electrode formed on the semiconductor layer. The capacitor electrode is overlapped with the data line. The source electrode is connected to the data line through the contact hole and the source electrode and the drain electrode include a transparent conductive material.

Abstract: The present invention provides an electronic device having more than two conductive layers that cross but not in contact with each other. At least one of the conductive layers comprises a width change part, a width of which changes in a length direction of at least one of the conductive layer. The width change part is formed away from a region of at least one of the conductive layers that crosses a neighboring conductive layer. The present invention also provides a flat panel display device that includes the electronic device described above and manufactured in accordance with the principles of the present invention. The electronic device of the present invention may comprise a thin film transistor.

Abstract: The formation of contact holes and a capacitor is performed in a semiconductor integrated circuit such as an active matrix circuit. An interlayer insulator having a multilayer (a lower layer is silicon oxide; an upper layer is silicon nitride) each having different dry etching characteristic is formed. Using a first mask, the silicon nitride corresponding to the upper layer in the interlayer insulator is etched by dry etching. This etching is completed by using the silicon oxide corresponding to the lower layer as an etching stopper. A pattern is formed using a second mask to form selectively the silicon oxide corresponding to the lower layer. Thus a first portion that the silicon oxide and the silicon nitride are etched and a second portion that only silicon nitride is etched are obtained. The first portion is used as a contact hole. A capacitor is formed in the second portion.

Abstract: In a thin-film transistor substrate including a substrate, a thin-film transistor semiconductor layer, a source/drain electrode, and a transparent pixel electrode, the source/drain electrode includes a thin film of an aluminum alloy containing 0.1 to 6 atomic percent of nickel as an alloy element, and the aluminum alloy thin film is directly connected to the thin-film transistor semiconductor layer.

Abstract: A TFT array panel and a method for fabricating the same is disclosed, wherein an adhesion force between an elongated wire and a TFT array panel pad is improved by increasing the contact area of a bonding pad. The TFT array panel pad includes a first conductive layer formed in a pad region on an insulating substrate. The first conductive layer includes a plurality of conductive islands and holes. A second conductive layer is formed over and covers the first conductive layer.

Abstract: In a manufacturing process of a semiconductor device, when harmonic of CW laser is irradiated to a semiconductor film with relatively scanning the harmonic, several long crystal grains extending in a scanning direction are formed. In the scanning direction, thus formed semiconductor film is substantially close to a single crystal in characteristic. However, the output of the harmonic of the CW laser is small to cause a low annealing efficiency. In the present invention, aid for the output is performed by irradiating second harmonic of CW laser and a fundamental wave of CW laser at the same time to the same portion. In general, the fundamental wave has a wavelength band around 1 ?m, and is not well absorbed in a semiconductor film.

Abstract: A system performs a method including contact printing one of a wetting agent and a non-wetting agent on a semiconductor and inkjet printing an electrically conductive material proximate said one of the wetting agent and the non-wetting agent.

Abstract: A method of manufacturing a thin-film semiconductor device, including forming a crystallized region on a transparent insulating substrate, implanting an impurity into the crystallized region and an amorphous semiconductor layer to form a source diffusion region and a drain diffusion region in the crystallized region, subjecting the resultant structure to heat treatment, thereby not only activating the impurity implanted in the crystallized region and the amorphous semiconductor layer but also restoring crystallinity of only a portion of the amorphous semiconductor layer which is formed on the crystallized region to thereby turn the portion into a polycrystalline semiconductor layer, and subjecting the resultant surface to selective etching to thereby leave only the polycrystalline semiconductor layer and to remove the amorphous semiconductor layer formed on other regions, thereby forming, in a self-aligned manner, a stacked source diffusion layer and a stacked drain diffusion layer.

Abstract: A thin film transistor array panel is provided, which includes: a gate line, a gate insulating layer, and a semiconductor layer sequentially formed on a substrate; a data line and a drain electrode formed at least on the semiconductor layer; a first passivation layer formed on the data line and the drain electrode and having a first contact hole exposing the drain electrode at least in part; a second passivation layer formed on the first passivation layer and having a second contact hole that is disposed on the first contact hole and has a first bottom edge, placed outside the first contact hole and a second bottom edge placed inside the first contact hole; and a pixel electrode formed on the second passivation layer and connected to the drain electrode through the first and the second contact holes.

Abstract: A thin film transistor (TFT) includes an N-type oxide semiconductor layer on a substrate, a gate electrode spaced apart from the N-type oxide semiconductor layer by a gate dielectric layer, a source electrode contacting a first portion of the N-type oxide semiconductor layer, and a drain electrode contacting a second portion of the N-type oxide semiconductor layer. The first and second portions each have a doped region containing ions of at least one Group 1 element, and the ions of the at least one Group 1 element in the doped region may have a work function that is less than that of an N-type oxide semiconductor material included in the semiconductor layer.

Abstract: A display device having a gate wiring including a first conductive material, an insulating film over the gate wiring, a semiconductor film over the insulating film, a source electrode and a drain electrode including a second conductive material formed over a source region and a drain region, and a pixel electrode including a transparent conductive film. The device includes a first terminal portion electrically connected to the gate wiring and having a first layer including a same material as the first conductive material and a second layer including a same material as the transparent conductive film. The device further includes a second terminal portion electrically connected to the source wiring and having a first layer including a same material as the second conductive material and a second layer including a same material as the transparent conductive film. An IC chip may be electrically connected to at least one of the first and second terminal portions.

Abstract: A method for forming a low temperature polysilicon thin film transistor with a low doped drain structure comprises: a) forming a polysilicon island on a substrate; b) forming a dielectric layer, a metal layer and a cap layer in sequence cover to the polysilicon island; c) forming a photo-resist patterened layer on the cap layer; d) removing the portion of the metal layer and the portion of the cap layer which are uncovered by the photo-resist patterned layer, and the remaining metal layer is uncovered by the remaining cap layer with a predetermined distance at the same side; e) performing a high concentration ion-doping using the metal layer as a mask; f) removing the portion of the metal layer uncovered by the remaining cap layer; and g) performing a low concentration ion-doping using the metal layer as a mask.

Abstract: A method for manufacturing a semiconductor device having steps of forming an amorphous semiconductor on a substrate having an insulating surface; patterning the amorphous semiconductor to form plural first island-like semiconductors; irradiating a linearly condensed laser beam on the plural first island-like semiconductors while relatively scanning the substrate, thus crystallizing the plural first island-like semiconductors; patterning the plural first island-like semiconductors that have been crystallized to form plural second island-like semiconductors; forming plural transistors using the plural second island-like semiconductors; and forming a unit circuit using a predetermined number of the transistors, where the second island-like semiconductors used for the predetermined number of the transistors are formed from the first island-like semiconductors that are different from each other.

Abstract: A method for manufacturing a semiconductor device such as a thin film transistor using a crystal silicon film is provided. The crystal silicon film is obtained by selectively forming films, particles or clusters containing nickel, iron, cobalt, ruthenium, rhodium, paradium, osmium, iridium, platinum, scandium, titanium, vanadium, chrome, manganese, copper, zinc, gold, silver or silicide thereof in a form of island, line, stripe, dot or film on or under an amorphous silicon film and using them as a starting point, by advancing its crystallization by annealing at a temperature lower than a normal crystallization temperature of an amorphous silicon. A transistor whose leak current is low and a transistor in which a mobility is high are obtained in the same time in structuring a dynamic circuit having a thin film transistor by selectively forming a cover film on a semiconductor layer which is to become an active layer of the transistor and by thermally crystallizing it thereafter.

Abstract: An electro-optical device includes an element substrate having a plurality of pixel regions; thin-film transistors, arranged in the pixel regions, including gate electrodes, portions of a gate insulating layer, and semiconductor layers; pixel electrodes electrically connected to drain regions of the thin-film transistors; and storage capacitors including lower electrodes and upper electrodes that are opposed to the lower electrodes with insulating layers disposed therebetween, the insulating layers being made of the same material as that for forming the gate insulating layer. The upper electrodes overlap with some of end portions of the lower electrodes. The gate insulating layer has thin portions located in inner portions of regions overlapping with the lower and upper electrodes and thick portions which are located in regions overlapping with the upper electrodes and the end portions of the lower electrodes and which have a thickness greater than that of the thin portions.

Abstract: The present invention relates to a thin film transistor substrate and a liquid crystal display panel for use in a liquid crystal display apparatus, and aims to provide a thin film transistor substrate and a liquid crystal display panel with good display quality. The thin film transistor substrate has a first sub-pixel electrode 16 and second sub-pixel electrode 17 arranged on the opposite sides of the gate bus line 12, a first thin film transistor 20a that establishes direct electrical connection with the first sub-pixel electrode 16, and a second thin film transistor 20b capacitively coupled to the second sub-pixel electrode 17. Since capacitance is formed where conventionally a source electrode and pixel electrode are connected via a contact hole, excessively opaque wiring is not required, which ensures sufficient effective area and transmittance of a pixel.

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 includes a gate electrode, an active layer, a source electrode, a drain electrode, and a buffer layer. The gate electrode is formed on the substrate; the active layer is formed on the gate electrode. The source and drain electrodes, formed on the active layer, are separated by a predetermined distance. The buffer layer is formed between the active layer and the source and drain electrodes. The buffer layer has a substantially continuously varying content ratio corresponding to a buffer layer thickness. The buffer layer is formed to suppress oxidation of the active layer, and reduce contact resistance.

Abstract: To reduce the adverse affect that characteristics of end portions of a channel forming region of a semiconductor film have on characteristics of a transistor. A gate electrode is formed over a channel forming region of a semiconductor film over a substrate, with a gate insulating film interposed therebetween. The semiconductor film is disposed in a region inside end portions of the gate insulating film. A side surface of the channel forming region is not in contact with at least the gate insulating film, so there is a space enclosed by the substrate, the side surface of the channel forming region, and the gate insulating film. Further, the side surface of the channel forming region is not necessarily in contact with the gate electrode. There may be a space enclosed by the substrate, the side surface of the channel forming region, the gate insulating film, and the gate electrode.

Abstract: A thin film transistor including: an active layer on a substrate, the active layer having at least two unit channels; and source and drain electrodes on the active layer, wherein an interval D between each of the channels is larger than a unit channel width W.

Abstract: A method of fabricating self-aligned metal oxide TFTs on transparent flexible substrates is disclosed and includes the steps of providing a transparent flexible substrate with at least an opaque first metal TFT electrode in a supporting relationship on the front surface of the substrate and a layer of transparent material, including at least one of a metal oxide semiconductor and/or a gate dielectric, on the front surface of the substrate and the first metal TFT electrode. A layer of photoresist is positioned in overlying relationship to the layer of transparent material. Dual photo masks are positioned over the front and rear surfaces of the substrate, respectively, and the layer of photoresist is exposed. The layer of photoresist is developed and used to form a layer of second metal.

Abstract: According to one exemplary embodiment, a p-channel germanium on insulator (GOI) one transistor memory cell comprises a buried oxide (BOX) layer formed over a bulk substrate, and a gate formed over a gate dielectric layer situated over a germanium layer formed over the buried oxide (BOX) layer. A source region is formed in the germanium layer adjacent to a channel region underlying the gate and overlaying the BOX layer, and a drain region is formed in the germanium layer adjacent to the channel region. The source region and the drain region are implanted with a p-type dopant. In one embodiment, a p-channel GOI one transistor memory cell is implemented as a capacitorless dynamic random access memory (DRAM) cell. In one embodiment, a plurality of p-channel GOI one transistor memory cells are included in a memory array.

Abstract: It is an object of the present invention to provide a method for preventing a breaking and poor contact, without increasing the number of steps, thereby forming an integrated circuit with high driving performance and reliability. The present invention applies a photo mask or a reticle each of which is provided with a diffraction grating pattern or with an auxiliary pattern formed of a semi-translucent film having a light intensity reducing function to a photolithography step for forming wires in an overlapping portion of wires. And a conductive film to serve as a lower wire of a two-layer structure is formed, and then, a resist pattern is formed so that a first layer of the lower wire and a second layer narrower than the first layer are formed for relieving a steep step.

Abstract: A thin film transistor and a method of manufacturing the same are disclosed. More specifically, there is provided a thin film transistor having a thin film transistor and a method of manufacturing the same wherein an inorganic layer and an organic planarization layer are sequentially formed on the surface of a substrate on source/drain electrode of a thin film transistor having a semiconductor layer, a gate, source/drain areas and the source/drain electrodes, and a blanket etching process is performed to the organic planarization layer to planarize the inorganic layer. After forming a photoresist pattern on the inorganic layer, an etching process is performed to form a hole coupling a pixel electrode with one of the source/drain electrodes. According to the manufacturing method, the hole may be formed using one mask, thereby simplifying a manufacturing process, and improving an adhesion with the pixel electrode by the inorganic layer formed above.