Abstract: A method of manufacturing a display panel having a plurality of lightly doped drain thin film transistors arranged as a matrix includes forming a semiconductor pattern with a predetermined shape on a substrate; forming a dielectric layer covering the semiconductor pattern on the substrate; forming a metal layer on the dielectric layer; forming a photoresist patterns smaller than the semiconductor pattern on the metal layer above the semiconductor pattern; etching the metal layer to form a gate electrode smaller than the photoresist pattern; doping high concentration ions by using the photoresist pattern as a mask to form a pair of highly doped regions on the semiconductor pattern not covered by the photoresist pattern; removing the photoresist pattern; and doping low concentration ions by using the gate electrode as a mask to form a pair of lightly doped regions between the highly doped regions and a part of the semiconductor pattern.

Abstract: There has been a problem that difference in refractive index between an opposite substrate or a moisture barrier layer provided thereover, and air is maintained large, and light extraction efficiency is low. Further, there has been a problem that peeling or cracking due to the moisture barrier layer is easily generated, which leads to deteriorate the reliability and lifetime of a light-emitting element. A light-emitting element comprises a pixel electrode, an electroluminescent layer, a transparent electrode, a passivation film, a stress relieving layer, and a low refractive index layer, all of which are stacked sequentially. The stress relieving layer serves to prevent peeling of the passivation film. The low refractive index layer serves to reduce reflectivity of light generated in the electroluminescent layer in emitting to air. Therefore, a light-emitting element with high reliability and long lifetime and a display device using the light-emitting element can be provided.

Abstract: A method for producing a semiconductor device includes a first step of forming a first insulating film around the fin-shaped semiconductor layer; a second step of forming a pillar-shaped semiconductor layer and a first dummy gate formed of a first polysilicon; a third step of forming a second dummy gate on sidewalls of the first dummy gate and the pillar-shaped semiconductor layer; a fourth step of forming a fifth insulating film left as a sidewall around the second dummy gate, forming a second diffusion layer in an upper portion of the fin-shaped semiconductor layer and a lower portion of the pillar-shaped semiconductor layer, and forming a metal-semiconductor compound on the second diffusion layer; a fifth step of forming a gate electrode and a gate line; and a sixth step of depositing a second gate insulating film around the pillar-shaped semiconductor layer and on the gate electrode and the gate line, removing a portion of the second gate insulating film on the gate line, depositing a second metal, etchin

Abstract: The present invention relates to a method of defining poly-silicon growth direction. The method of defining poly-silicon growth direction comprises Step 1, forming a buffer layer on a substrate; Step 2, forming an amorphous silicon thin film on the buffer layer; Step 3, forming regular amorphous silicon convex portions on the amorphous silicon thin film; and Step 4, transferring the amorphous silicon thin film into poly-silicon with an excimer laser anneal process. The growth direction of the poly-silicon as being formed can be controlled according to the present method of defining poly-silicon growth direction. Accordingly, the grain size of the poly-silicon can be raised.

Abstract: Silicon and silicon germanium fins are formed on a semiconductor wafer or other substrate in a manner that facilitates production of closely spaced nFET and pFET devices. A patterned mandrel layer is employed for forming one or more recesses in the wafer prior to the epitaxial growth of a silicon germanium layer that fills the recess. Spacers are formed on the side walls of the patterned mandrel layer followed by removal of the mandrel layer. The exposed areas of the wafer and silicon germanium layer between the spacers are etched to form fins usable for nFET devices from the wafer and fins usable for pFET devices from the silicon germanium layer.

Abstract: A thin film deposition device and a method of depositing thin film materials are disclosed. In one aspect, the thin film deposition device includes a deposition chamber configured to accommodate a substrate and a first chamber plate placed in the deposition chamber and configured to mount the substrate on a first surface thereof. The thin film deposition device also includes a second chamber plate placed in the deposition chamber on the opposite side of the first chamber plate with reference to the substrate. A plurality of recesses are formed on a surface of the second chamber plate facing the first surface of the first chamber plate such that gas flow is formed through the respective recesses.

Abstract: A TFT substrate and the manufacturing method thereof are disclosed. The method includes: providing a substrate; forming a gate electrode on the substrate; forming a first insulation layer and an active layer on the gate electrode in turn; forming a first black matrix on the active layer; forming a source electrode and a drain electrode on the first black matrix; forming a second insulation layer on the source electrode and the drain electrode; and forming a pixel electrode on the second insulation layer. The pixel electrode is electrically connected to the source electrode or the drain electrode via the second insulation layer. In this way, the masking effect of the display panel assembled by the TFT substrate can be ensured. In addition, the coupling capacitance between the data line and the scanning line may be reduced.

Abstract: A method of cleaning thin glass substrates comprises applying a sequence of chemical washing steps as the thin glass substrate is being conveyed in a conveyance direction. In addition, surfaces of the glass substrate may be treated to enhance electrostatic discharge properties of the glass substrates.

Abstract: A method for producing a semiconductor device includes forming a fin-shaped semiconductor layer on a semiconductor substrate and a first pillar-shaped semiconductor layer, a first dummy gate layer and a second pillar-shaped semiconductor layer, and a second dummy gate layer. Third and fourth dummy gate layers are formed on sidewalls of the first dummy layer gate, the first pillar-shaped semiconductor layer, the second dummy gate layer and the second pillar-shaped semiconductor layer. An interlayer insulating film is deposited, the dummy gate layers are removed, and a gate insulator is formed film around the first and second pillar-shaped semiconductor layers. A first metal is deposited and a gate electrode and a gate line are formed around the first pillar-shaped semiconductor layer. Second and third metals are deposited and a first contact and a pillar-shaped resistance-changing layer, a lower electrode, and a reset gate are formed.

Abstract: A thin film transistor 100 according to the invention includes a gate electrode 20, a channel 44, and a gate insulating layer 34 provided between the gate electrode 20 and the channel 44 and made of oxide (possibly containing inevitable impurities; this applies to oxide hereinafter) containing lanthanum and zirconium. The channel 44 is made of channel oxide including first oxide containing indium, zinc, and zirconium (Zr) having an atomic ratio of 0.015 or more and 0.075 or less relative to indium assumed to be 1 in atomic ratio, second oxide containing indium and zirconium (Zr) having an atomic ratio of 0.055 or more and 0.16 or less relative to the indium (In) assumed to be 1 in atomic ratio, or third oxide containing indium and lanthanum having an atomic ratio of 0.055 or more and 0.16 or less relative to the indium (In) assumed to be 1 in atomic ratio.

Abstract: In one aspect, organic thin film transistors are described herein. In some embodiments, an organic thin film transistor comprises a source terminal, a drain terminal and a gate terminal; a dielectric layer positioned between the gate terminal and the source and drain terminals; and a vibrationally-assisted drop-cast organic film comprising small molecule semiconductor in electrical communication with the source terminal and drain terminal, wherein the transistor has a carrier mobility (?eff) of at least about 1 cm2/V·s.

Abstract: 3D integrated circuit packages with through-mold first level interconnects and methods to form such packages are described. For example, a semiconductor package includes a substrate. A bottom semiconductor die has an active side with a surface area. The bottom semiconductor die is coupled to the substrate with the active side distal from the substrate. A top semiconductor die has an active side with a surface area larger than the surface area of the bottom semiconductor die. The top semiconductor die is coupled to the substrate with the active side proximate to the substrate. The active side of the bottom semiconductor die is facing and conductively coupled to the active side of the top semiconductor die. The top semiconductor die is conductively coupled to the substrate by first level interconnects that bypass the bottom semiconductor die.

Abstract: A method of forming a field effect transistor (FET) device includes forming a diffusion facilitation layer on top of a semiconductor substrate; forming a doped, raised source/drain (RSD) layer on the diffusion facilitation layer; removing a portion of the diffusion facilitation layer, corresponding to a region directly above a channel region of the FET device; and performing an anneal so as to define abrupt source and drain junctions in the semiconductor substrate, wherein dopant atoms from the doped RSD layer diffuse within the diffusion facilitation layer at a faster rate than with respect to the semiconductor substrate.

Abstract: A method for forming a semiconductor device includes forming a semiconductor substrate having at least one fin structure on an insulator on a substrate. The fin structure includes a semiconductor layer overlying a sacrificial layer. The method also includes forming a patterned dummy gate on the substrate, forming a first spacer on both sides of the dummy gate, and using the dummy gate and the first spacer as a mask to remove a portion of the semiconductor layer and the sacrificial layer. Then the sacrificial layer is etched to form recessed regions on both sides of the sacrificial layer, and a second spacer is formed to cover both sides of the sacrificial layer and expose both sides of the semiconductor layer. The method also includes performing epitaxial growth on both sides of the semiconductor layer to form source and drain regions.

Abstract: According to example embodiments, a transistor includes a gate, a channel layer that is separate from the gate, a gate insulating layer between the gate and the channel layer, and a source electrode and a drain electrode respectively contacting a first region and a second region of the channel layer. The gate insulating layer includes an impurity metal containing region that includes an impurity metal and contacts the channel layer. The gate insulating layer includes an impurity metal non-containing region contacting the gate that is not doped with the impurity metal.

Abstract: A method of manufacturing a photoelectric conversion element including a step of forming a layer containing an organic material and particles dispersed in the organic material on a member including a photoelectric conversion portion and a step of roughening a surface of the layer by dry etching.

Abstract: An ink jet process is used to deposit a material layer to a desired thickness. Layout data is converted to per-cell grayscale values, each representing ink volume to be locally delivered. The grayscale values are used to generate a halftone pattern to deliver variable ink volume (and thickness) to the substrate. The halftoning provides for a relatively continuous layer (e.g., without unintended gaps or holes) while providing for variable volume and, thus, contributes to variable ink/material buildup to achieve desired thickness. The ink is jetted as liquid or aerosol that suspends material used to form the material layer, for example, an organic material used to form an encapsulation layer for a flat panel device. The deposited layer is then cured or otherwise finished to complete the process.

Abstract: Embodiments of the present invention relate to the display field and provide an array substrate, a method for producing the same and a display apparatus, for reducing a via hole space without adding a step for patterning the gate insulation layer and thereby reducing product costs. The array substrate includes a gate metal layer, a gate insulation layer, a source and drain metal layer and a passivation layer, wherein the array substrate is provided with a via hole, which passes through the passivation layer, the source and drain metal layer and the gate insulation layer and at which a transparent conductive material is deposited for connecting the source and drain metal layer with the gate metal layer.

Abstract: A method of growing high quality crystalline films on lattice-mismatched or amorphous layers is presented allowing semiconductor materials that would normally be subject to high stress and cracking to be employed allowing cost reductions and/or performance improvements in devices to be obtained. Catalysis of the growth of these films is based upon utilizing particular combinations of metals, materials, and structures to establish growth of the crystalline film from a predetermined location. The subsequent film growth occurring in one or two dimensions to cover a predetermined area of the amorphous or lattice-mismatched substrate. Accordingly the technique can be used to either cover a large area or provide tiles of crystalline material with or without crystalline film interconnections.

Abstract: A flexible device substrate includes a flexible substrate, a device layer, and a waterproof layer. The flexible substrate has a top surface and a bottom surface disposed opposite to each other. The device layer is disposed on the top surface of the flexible substrate. The waterproof layer is disposed on the bottom surface of the flexible substrate.

Abstract: A nanowire device having a plurality of internal spacers and a method for forming said internal spacers are disclosed. In an embodiment, a semiconductor device comprises a nanowire stack disposed above a substrate, the nanowire stack having a plurality of vertically-stacked nanowires, a gate structure wrapped around each of the plurality of nanowires, defining a channel region of the device, the gate structure having gate sidewalls, a pair of source/drain regions on opposite sides of the channel region; and an internal spacer on a portion of the gate sidewall between two adjacent nanowires, internal to the nanowire stack. In an embodiment, the internal spacers are formed by depositing spacer material in dimples etched adjacent to the channel region. In an embodiment, the dimples are etched through the channel region. In another embodiment, the dimples are etched through the source/drain region.

Abstract: A method is provided for controlling printed ink horizontal. cross-sectional areas using fluoropolymer templates. The method initially forms a fluoropolymer template overlying a substrate. The fluoropolymer template has a horizontal first cross-sectional dimension. Then, a primary ink is printed overlying the fluoropolymer template having a horizontal second cross-sectional dimension less than the first cross-sectional dimension. In the case of a fluoropolymer line having a template length greater than a template width, where the template width is the first cross-sectional dimension, printing the primary ink entails printing a primary ink line having an ink length greater than an ink width, where the ink width is the second cross-sectional dimension. In one aspect, the method prints a plurality of primary ink layers, each primary ink layer having an ink width less than the template width. Each overlying primary ink layer can be printed prior to solvents in underlying primary ink layers evaporating.

Abstract: There is provided an actinic ray-sensitive or radiation-sensitive resin composition comprising: (A) a resin having a repeating unit represented by the specific formula and a group capable of decomposing by an action of an acid to produce a polar group; and an ionic compound represented by the specific formula, and a resist film comprising the actinic ray-sensitive or radiation-sensitive resin composition.

Abstract: A flat panel detector comprises a photoelectric conversion layer and a pixel detecting element disposed under the photoelectric conversion layer. The pixel detecting element comprises: a pixel electrode for receiving charges, a storage capacitor for storing the received charges, and a thin film transistor for controlling outputting of the stored charges. The storage capacitor comprises a first electrode and a second electrode. The first electrode comprises an upper electrode and a bottom electrode that are disposed opposite to each other and electrically connected. A second electrode is sandwiched between the upper electrode and the bottom electrode. It is insulated between the upper electrode and the second electrode and between the second electrode and the bottom electrode.

Abstract: An electronic component includes a first transistor on a substrate. The first transistor includes a first source, a first drain, a first gate dielectric, a first gate, and a first semiconductor channel having a first length. At least a portion of the first semiconductor channel extends in a direction parallel to the substrate. A vertical-support-element on the substrate has a first reentrant profile. A second transistor includes a second source, a second drain, a second gate dielectric, and a second gate having a second semiconductor channel. At least a portion of the second semiconductor channel extends in a direction orthogonal to the substrate in the first reentrant profile of the vertical-support-element.

Abstract: One portion of a first insulator film, which is positioned on a second semiconductor region, and another portion of the first insulator film, which is positioned on a third semiconductor region, are removed, while a first portion of the first insulator film, which is positioned on a first semiconductor region is remained, one portion of a second insulator film, which is positioned on the first semiconductor region, and another portion of the second insulator film, which is positioned on the second semiconductor region, are removed, while a second portion of the second insulator film, which is positioned on the third semiconductor region is remained, and a metal film that covers the first portion, the second semiconductor region, and the second portion, and the second semiconductor region are caused to react with each other and a metal compound layer is formed.

Abstract: A method for processing a substrate, the substrate comprising an organic film pattern, the method comprising: a fusion/deformation step of fusing said organic film pattern to deform the fused organic film pattern and a third removal step of removing at least a part of the fused and deformed organic film pattern.

Abstract: A method for fabricating floating body memory cells (FBCs), and the resultant FBCs where gates favoring different conductivity type regions are used is described. In one embodiment, a p type back gate with a thicker insulation is used with a thinner insulated n type front gate. Processing, which compensates for misalignment, which allows the different oxide and gate materials to he fabricated is described.

Abstract: A system and method for manufacturing a memory device is provided. A preferred embodiment comprises manufacturing a flash memory device with a tunneling layer. The tunneling layer is formed by introducing a bonding agent into the dielectric material to bond with and reduce the number of dangling bonds that would otherwise be present. Further embodiments include initiating the formation of the tunneling layer without the bonding agent and then introducing a bonding agent containing precursor and also include a reduced concentration region formed in the tunneling layer adjacent to a substrate.

Abstract: An electronic component manufacturing method according to an aspect of the present disclosure includes providing a support substrate, forming a release layer including a metal or a metal oxide on a first surface of the support substrate, forming a resin substrate on the release layer, forming a functional element on the resin substrate, and separating the resin substrate from the support substrate by applying laser light to the support substrate through a second surface of the support substrate. The laser light that reaches an interface between the resin substrate and the release layer after being transmitted through the support substrate and the release layer has an energy density lower than a threshold for the resin substrate to be processed by the laser light.

Abstract: One method disclosed herein includes, among other things, forming a first spacer proximate gate structures of first and second transistors that are opposite type transistors, forming an initial second spacer proximate the first spacer of the first transistor and a layer of second spacer material above the second transistor, performing a timed, wet etching process on both of the transistors so as to completely remove the layer of second spacer material from the second transistor while leaving a reduced thickness second spacer positioned adjacent the first spacer of the first transistor, wherein the reduced thickness second spacer has a thickness that is less than an initial thickness of the initial second spacer, and forming a third spacer on and in contact with the first spacer of the second transistor.

Abstract: A process for producing a thin film field-effect transistor includes providing a gate electrode, a gate insulating film, and source and drain electrodes, treating entire surfaces of the source and drain electrodes with a mixture of sulfuric acid and hydrogen peroxide, and providing an organic electronic material layer containing an organic electronic material on the gate insulating film to be in electrical contact with the source and drain electrodes. A reaction product of the organic electronic material, sulfuric acid and hydrogen peroxide containing a sulfonated product of the organic electronic material is present only at an interface between the source electrode and the organic electronic material layer and an interface between the drain electrode and the organic electronic material layer to thereby increase the electroconductivity of the organic electronic material and reduce a charge injection barrier from the source electrode to the organic electronic material.

Abstract: Disclosed are an array substrate and a method of fabricating the same. The array substrate includes an active area including a plurality of pixels defined at an intersection area of a gate line and a data line, a gate driving circuit formed at one side of a non-active area and a signal line extending in parallel with the data line in the non-active area to transfer a signal to the gate driving circuit. The signal line includes a first line with a plurality of segmental lines, and at least one additional line formed of a different material and formed at a different layer than the first line. The at least one additional line electrically connects two segmental lines of the first line adjacent to each other.

Abstract: In a coating-type electron injection layer or electron transport layer using a metal oxide, the present invention aims at improving uniformity or stability of composition distribution and adhesion with another adjoining constituent layer, and improving film forming property, to thereby provide an organic electronic device and manufacture of the device whose efficiency is improved. In the organic electronic device having one pair of electrodes on a substrate, and having at least one organic layer between the electrodes, the electron injection layer or the electron transport layer is formed by application of a liquid material in which an alkaline metal salt and zinc-oxide nano particles are dissolved in alcohol.

Abstract: The present invention relates to a semiconductor structure comprising at least a first and a second three-dimensional transistor, wherein the first transistor and the second transistor are electrically connected in parallel to each other, and wherein each transistor comprises a source and a drain, wherein the source and/or drain of the first transistor is at least partially separated from, respectively, the source and/or drain of the second transistor. The invention further relates to a process for realizing such a semiconductor structure.

Abstract: A SOI substrate layer formed of a silicon semiconductor material includes adjacent first and second regions. A portion of the silicon substrate layer in the second region is removed such that the second region retains a bottom portion made of the silicon semiconductor material. An epitaxial growth of a silicon-germanium semiconductor material is made on the bottom portion to produce a silicon-germanium region. The silicon region is patterned to define a first fin structure of a FinFET of a first (for example, n-channel) conductivity type. The silicon-germanium region is also patterned to define a second fin structure of a FinFET of a second (for example, p-channel) conductivity type.

Abstract: A liquid crystal panel and a liquid crystal display device are provided, and the liquid crystal panel comprises a color filter substrate and an array substrate which are bonded by a sealant doped with gold balls, wherein a gate shift register is provided on a side of the array substrate facing the color filter substrate, a conductive electrode connecting a gate electrode and source/drain electrodes is provided in a region of the gate shift register, and a common electrode is provided on a side of the color filter substrate facing the array substrate, and wherein the liquid crystal panel further includes an insulating layer located between the conductive electrode and the common electrode, a projection of the insulating layer on the side of the array substrate facing the color filter substrate covering a projection of the conductive electrode on the side of the array substrate facing the color filter substrate.

Abstract: An active diode with fast turn-on time, low capacitance, and low turn-on resistance may be manufactured without a gate and without a shallow trench isolation region between doped regions of the diode. A short conduction path in the active diode allows a fast turn-on time, and a lack of gate oxide reduces susceptibility of the active diode to extreme voltages. The active diode may be implemented in integrated circuits to prevent and reduce damage from electrostatic discharge (ESD) events. Manufacturing the active diode is accomplished by depositing a salicide block between doped regions of the diode before salicidation. After the salicide layers are formed on the doped regions, the salicide block is removed.

Abstract: Provided is a method of manufacturing an organic light emitting display device. The method includes: providing a first substrate including: a display portion, and a non-display portion, forming a thin film transistor (TFT) and an organic light emitting diode (OLED) in the display portion of the first substrate, providing a pad portion including: at least one pad contact portion at the non-display portion and electrically connected to the TFT, and a pad insulating portion between adjacent pad contact portions, providing an anti-moisture insulation layer entirely covering the first substrate, adhering an encapsulating substrate onto the anti-moisture insulation portion in correspondence with the display portion, and removing the anti-moisture insulation layer, at the pad contact portion, using a laser.

Abstract: A transistor includes a substrate, an electrically conductive material layer, and an electrically insulating material layer. At least a portion of one or more of the substrate, the electrically conductive material layer, and the electrically insulating material layer define a reentrant profile.

Abstract: A fabrication method of a pixel structure includes the following steps. A first metal layer is patterned to form a source electrode and a drain electrode. A semiconductor material layer is patterned to form a channel layer and a pixel pattern. A first insulation layer is formed to cover the channel layer, the source electrode, the drain electrode and the pixel pattern. A gate electrode is formed on the first insulation layer located above the channel layer. A second insulation layer is formed to cover the gate electrode and the first insulation layer. A pixel opening is formed in the first insulation layer and the second insulation layer to expose a partial region of the pixel pattern. The partial region of the pixel pattern exposed by the pixel opening is modified so as to form a pixel electrode electrically connected to the drain electrode.

Abstract: A fabrication method of a pixel structure includes the following steps. A first metal layer is patterned to form a source electrode and a drain electrode. A semiconductor material layer is patterned to form a channel layer and a pixel pattern. A first insulation layer is formed to cover the channel layer, the source electrode, the drain electrode and the pixel pattern. A gate electrode is formed on the first insulation layer located above the channel layer. A second insulation layer is formed to cover the gate electrode and the first insulation layer. A pixel opening is formed in the first insulation layer and the second insulation layer to expose a partial region of the pixel pattern. The partial region of the pixel pattern exposed by the pixel opening is modified so as to form a pixel electrode electrically connected to the drain electrode.

Abstract: A memory cell array includes a semiconductor substrate, a first word line formed on the semiconductor substrate, a second word line formed on the semiconductor substrate and extending substantially parallel to the first word line, a first inter-pattern insulating layer interposed between the first and second word lines, first active pillars formed within the first word line and arranged along the first word line at a first interval, and second active pillars formed within the second word lines, and arranged along the second word line to face the first active pillars, respectively, with the first inter-pattern insulating layer interposed therebetween.

Abstract: Disclosed herein is a photoelectric conversion element including: a first semiconductor layer of a first conductivity type provided above a substrate; a second semiconductor layer of a second conductivity type provided in a higher layer than the first semiconductor layer; a third semiconductor layer of a third conductivity type provided between the first and second semiconductor layers and lower in electrical conductivity than the first and second semiconductor layers; and a light-shielding layer provided between the substrate and first semiconductor layer.

Abstract: A semiconductor device includes a substrate having a first conductivity type, a high-voltage well having a second conductivity type and disposed in the substrate, a source well having the first conductivity type and disposed in the high-voltage well, a drift region disposed in the high-voltage well and spaced apart from the source well, and a deep implantation region having the first conductivity type and disposed in the high-voltage well between the source well and the drift region.

Abstract: A miniaturized semiconductor device in which an increase in power consumption is suppressed and a method for manufacturing the semiconductor device are provided. A highly reliable semiconductor device having stable electric characteristics and a method for manufacturing the semiconductor device are provided. An oxide semiconductor film is irradiated with ions accelerated by an electric field in order to reduce the average surface roughness of a surface of the oxide semiconductor film. Consequently, an increase in the leakage current and power consumption of a transistor can be suppressed. Moreover, by performing heat treatment so that the oxide semiconductor film includes a crystal having a c-axis substantially perpendicular to the surface of the oxide semiconductor film, a change in electric characteristics of the oxide semiconductor film due to irradiation with visible light or ultraviolet light can be suppressed.

Abstract: A thin film transistor display panel includes a gate electrode on a substrate; a gate insulating layer on the substrate and the gate electrode; a planarization layer on the gate insulating layer and at opposing sides of the gate electrode, where the planarization layer exposes the gate insulating layer; a semiconductor layer on the gate insulating layer; and a source electrode and a drain electrode on the semiconductor layer and spaced apart from each other.

Abstract: A semiconductor device having favorable electric characteristics and a manufacturing method thereof are provided. A transistor includes an oxide semiconductor layer formed over an insulating layer, a source electrode layer and a drain electrode layer which overlap with part of the oxide semiconductor layer, a gate insulating layer in contact with part of the oxide semiconductor layer, and a gate electrode layer over the gate insulating layer. In the transistor, a buffer layer having n-type conductivity is formed between the source electrode layer and the oxide semiconductor layer and between the drain electrode layer and the oxide semiconductor layer. Thus, parasitic resistance is reduced, resulting in improvement of on-state characteristics of the transistor.

Abstract: A method for fabricating floating body memory cells (FBCs), and the resultant FBCs where gates favoring different conductivity type regions are used is described. In one embodiment, a p type back gate with a thicker insulation is used with a thinner insulated n type front gate. Processing, which compensates for misalignment, which allows the different oxide and gate materials to be fabricated is described.

Abstract: Apparatus for atomic layer deposition on a surface of a sheeted substrate, comprising: an injector head comprising a deposition space provided with a precursor supply and a precursor drain; said supply and drain arranged for providing a precursor gas flow from the precursor supply via the deposition space to the precursor drain; the deposition space in use being bounded by the injector head and the substrate surface; a gas bearing comprising a bearing gas injector, arranged for injecting a bearing gas between the injector head and the substrate surface, the bearing gas thus forming a gas-bearing; a conveying system providing relative movement of the substrate and the injector head along a plane of the substrate to form a conveying plane along which the substrate is conveyed.