Abstract: A method for manufacturing the pixel structure of a liquid crystal display is provided. In comparison to using seven masks in the conventional lithographic processes for the pixel structure, only four masks are required in the manufacturing method of the present invention. Therefore, the cost of manufacturing is reduced. Furthermore, the unnecessary multilayer structures on the display area can be removed in the manufacturing processes, and thus, enhance the transmittance thereof.

Abstract: To achieve electro-optical devices typified by active matrix liquid crystal display devices with higher productivity and yield and lower manufacturing cost by reducing the number of steps of manufacturing a terminal portion and a pixel portion having an inverted staggered thin film transistor, specifically by reducing the number of photomasks used in a photolithography process. In view of this object, a photomask (multitone photomask) formed in such a manner that a light-transmitting substrate is provided with a transmitting portion, a partially-transmitting portion having a function of reducing light intensity, and a light-blocking portion is employed. Moreover, a lift-off method which does not require an etching step in patterning of a source electrode and a drain electrode of the pixel portion and a source wiring that extends to the terminal portion is employed.

Abstract: A semiconductor device and a method of fabricating the same are provided. First, a first oxide layer and a nitride layer are formed on a base having a first region and a second region. Next, the nitride layer is oxidized. A part of nitride in the nitride layer moves to the first oxide layer and the base. An upper portion of the nitride layer is converted to an upper oxide layer. Then, the upper oxide layer, the nitride layer and the first oxide layer in the second region are removed. Thereon, a second oxide layer is grown on the base in the second region. Nitride in the second region moves to the second oxide layer.

Abstract: A method for forming a semiconductor device includes providing a semiconductor substrate; forming a gate dielectric over the semiconductor substrate; forming a gate electrode over the gate dielectric; forming an insulating layer over a sidewall of the gate electrode; defining source and drain regions in the semiconductor substrate adjacent to the insulating layer; implanting a dopant in the source and drain regions of the semiconductor substrate to form doped source and drain regions; forming a sidewall spacer adjacent to the insulating layer; forming a recess in the semiconductor substrate in the source and drain regions, wherein the recess extends directly underneath the spacer a predetermined distance from a channel regions; and forming a stressor material in the recess. The method allows the stressor material to be formed closer to a channel region, thus improving carrier mobility in the channel while not degrading short channel effects.

Abstract: The present invention is to provide a semiconductor device that achieves high mechanical strength without reducing the circuit scale and that can prevent the data from being forged and altered illegally while suppressing the cost. The present invention discloses a semiconductor device typified by an ID chip that is formed from a semiconductor thin film including a first region with high crystallinity and a second region with the crystallinity inferior to the first region. Specifically, a TFT (thin film transistor) of a circuit requiring high-speed operation is formed by using the first region and a memory element for an identifying ROM is formed by using the second region.

Abstract: A display device with improved reliability and a manufacturing method of the same with improved yield. A display device according to the invention comprises a display area including a first electrode, an insulating layer covering an edge of the first electrode, a layer containing an organic compound, which is formed on the first electrode, and a second electrode. The first electrode and the insulating layer are doped with an impurity element of one conductivity.

Abstract: A semiconductor structure and a method of fabricating the same in which strain enhancement is achieved for both nFET and pFET devices is provided. In particular, the present invention provides at least one spacerless FET for stronger strain enhancement and defect reduction. The at least one spacerless FET can be a pFET, an nFET, or a combination thereof, with spacerless pFETs being particularly preferred since pFETs are generally fabricated to have a greater width than nFETs. The at least one spacerless FET allows to provide a stress inducing liner in closer proximity to the device channel than prior art structures including FETs having spacers. The spacerless FET is achieved without negatively affecting the resistance of the corresponding silicided source/drain diffusion contacts, which do not encroach underneath the spacerless FET.

Abstract: A method for manufacturing an integrated circuit containing fully and partially depleted MOS transistors, including the steps of forming similar MOS transistors on a thin silicon layer formed on a silicon-germanium layer resting on a silicon substrate; attaching the upper surface of the structure to a support wafer; eliminating the substrate; depositing a mask and opening this mask at the locations of the fully-depleted transistors; oxidizing the silicon-germanium at the locations of the fully-depleted transistors in conditions such that a condensation phenomenon occurs; and eliminating the oxidized portion and the silicon-germanium portion, whereby there remain transistors with a thinned silicon layer.

Abstract: A stacked semiconductor device comprises a lower transistor formed on a semiconductor substrate, a lower interlevel insulation film formed on the semiconductor substrate over the lower transistor, an upper transistor formed on the lower interlayer insulation film over the lower transistor, and an upper interlevel insulation film formed on the lower interlevel insulation film over the upper transistor. The stacked semiconductor device further comprises a contact plug connected between a drain or source region of the lower transistor and a source or drain region of the upper transistor, and an extension layer connected to a lateral face of the source or drain region of the upper transistor to enlarge an area of contact between the source or drain region of the upper transistor and a side of the contact plug.

Abstract: In a method for manufacturing a display device having a light emitting element, a first base insulating film, a second base insulating film, a semiconductor layer, and a gate insulating film are formed in this order over a substrate. A gate electrode is formed over the gate insulating film to overlap with at least a part of the semiconductor layer, and a portion to be a pixel portion of the gate insulating film and the second base insulating film is doped with at least one conductive type impurities. An opening portion is formed by selectively etching the gate insulating film and second base insulating film that are each doped with impurities. The first base insulating film is exposed in a bottom face of the opening portion. Subsequently, an insulating film is formed to cover the opening portion, the gate insulating film, and the gate electrode, and a light emitting element is formed over the insulating film to overlap with at least a part of the opening portion.

Abstract: Flash memory device structures and methods of manufacture thereof are disclosed. The flash memory devices are manufactured on silicon-on-insulator (SOI) substrates. Shallow trench isolation (STI) regions and the buried oxide layer of the SOI substrate are used to isolate adjacent devices from one another. The methods of manufacture require fewer lithography masks and may be implemented in stand-alone flash memory devices, embedded flash memory devices, and system on a chip (SoC) flash memory devices.

Abstract: A method that includes forming a pattern of strained material and relaxed material on a substrate; forming a strained device in the strained material; and forming a non-strained device in the relaxed material is disclosed. In one embodiment, the strained material is silicon (Si) in either a tensile or compressive state, and the relaxed material is Si in a normal state. A buffer layer of silicon germanium (SiGe), silicon carbon (SiC), or similar material is formed on the substrate and has a lattice constant/structure mis-match with the substrate. A relaxed layer of SiGe, SiC, or similar material is formed on the buffer layer and places the strained material in the tensile or compressive state. In another embodiment, carbon-doped silicon or germanium-doped silicon is used to form the strained material. The structure includes a multi-layered substrate having strained and non-strained materials patterned thereon.

Abstract: An organic light emitting display provided according to the invention maintains light emission efficiency and elongates its lifetime by radiating heat generated from organic light emitting elements to the outside of an encapsulated area. In the organic light emitting display, a part of a cathode is extended to the outside of the encapsulated area of a main substrate to form a radiation section integrally with the cathode. Heat generated from organic light emitting elements is diffused and radiated from the radiation section so that the heat can be discharged therefrom.

Abstract: A method of fabricating a semiconductor device including a channel layer includes forming a single crystalline semiconductor layer on a semiconductor substrate. The single crystalline semiconductor layer includes a protrusion extending from a surface thereof. A first polishing process is performed on the single crystalline semiconductor layer to remove a portion of the protrusion such that the single crystalline semiconductor layer includes a remaining portion of the protrusion. A second polishing process different from the first polishing process is performed to remove the remaining portion of the protrusion and define a substantially planar single crystalline semiconductor layer having a substantially uniform thickness. A sacrificial layer may be formed on the single crystalline semiconductor layer and used as a polish stop for the first polishing process to define a sacrificial layer pattern, which may be removed prior to the second polishing process.

Abstract: A semiconductor structure including an nFET having a fully silicided gate electrode wherein a new dual stress liner configuration is used to enhance the stress in the channel region that lies beneath the gate electrode is provided. The new dual stress liner configuration includes a first stress liner that has an upper surface that is substantially planar with an upper surface of a fully silicided gate electrode of the nFET. In accordance with the present invention, the first stress liner is not present atop the nFET including the fully silicided gate electrode. Instead, the first stress liner of the present invention partially wraps around, i.e., surrounds the sides of, the nFET with the fully silicided gate electrode. A second stress liner having an opposite polarity as that of the first stress liner (i.e., of an opposite stress type) is located on the upper surface of the first stress liner as well as atop the nFET that contains the fully silicided FET.

Abstract: Integrated circuit devices are provide having a vertical diode therein. The devices include an integrated circuit substrate and an insulating layer on the integrated circuit substrate. A contact hole penetrates the insulating layer. A vertical diode is in lower region of the contact hole and a bottom electrode in the contact hole has a bottom surface on a top surface of the vertical diode. The bottom electrode is self-aligned with the vertical diode. A top surface area of the bottom electrode is less than a horizontal section area of the contact hole. Methods of forming the integrated circuit devices and phase change memory cells are also provided.

Abstract: An improved semiconductor-on-insulator (SOI) substrate is provided, which contains a patterned buried insulator layer at varying depths. Specifically, the SOI substrate has a substantially planar upper surface and comprises: (1) first regions that do not contain any buried insulator, (2) second regions that contain first portions of the patterned buried insulator layer at a first depth (i.e., measured from the planar upper surface of the SOI substrate), and (3) third regions that contain second portions of the patterned buried insulator layer at a second depth, where the first depth is larger than the second depth. One or more field effect transistors (FETs) can be formed in the SOI substrate. For example, the FETs may comprise: channel regions in the first regions of the SOI substrate, source and drain regions in the second regions of the SOI substrate, and source/drain extension regions in the third regions of the SOI substrate.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a substrate, a gate disposed thereon, an insulation layer disposed on the substrate and overlying the gate, a patterned semiconductor layer disposed on the insulation layer, a source and a drain disposed on the patterned semiconductor layer, a protective layer overlying the insulation layer, the source and the boundary of the drain to expose a portion of the drain, and a pixel electrode disposed on the substrate, overlying the protective layer overlying the boundary of the drain, electrically connected to the exposed drain.

Abstract: A method of manufacturing a silicon carbide semiconductor device having a MOS structure includes preparing a substrate made of silicon carbide, and forming a channel region, a first impurity region, a second impurity region, a gate insulation layer, and a gate electrode to form a semiconductor element on the substrate. In addition, a film is formed on the semiconductor element to provide a material of an interlayer insulation layer, and a reflow process is performed at a temperature about 700° C. or over in an wet atmosphere so that the interlayer insulation layer is formed from the film. Furthermore, a dehydration process is performed at about 700° C. or lower in an inert gas atmosphere after the reflow process is performed.

Abstract: A first resist mask and a second resist mask used for forming a gate electrode for a p-channel TFT and a gate electrode for an n-channel TFT are left, and a third resist mask is formed afterwards over a first area where one of the p-channel TFT and the n-channel TFT is to be formed; thus, a source region and a drain region are formed in a semiconductor film of the other one of the p-channel TFT and the n-channel TFT by adding first impurity ions using the second resist mask and the third resist mask. After that, the first resist mask, the second resist mask, and the third resist mask are removed, and a source region and a drain region are formed in a semiconductor film of the one of the p-channel TFT and the n-channel TFT by adding second impurity ions using a fourth resist mask.

Abstract: The present invention includes a technique for making a dual voltage integrated circuit device. A gate dielectric layer is formed on a semiconductor substrate and a gate material layer is formed on the dielectric layer. A first region of the gate material layer is doped to a first nonzero level and a second region of the gate material level is doped to a second nonzero level greater than the first level. A first field effect transistor is defined that has a first gate formed from the first region. Also, a second field effect transistor is defined that has a second gate formed from the second region. The first transistor is operable at a gate threshold voltage greater than the second transistor in accordance with a difference between the first level and the second level.

Abstract: A display device includes a substrate having a display region and a driver region; a gate line and a data line crossing each other to define a pixel region in the display region, the pixel region having a pixel electrode; an insulation layer between the gate line and the data line; a first thin film transistor in the display region; and a second thin film transistor having a first polarity and a third thin film transistor having a second polarity in the driver region, wherein the pixel electrode, the gate line and the gate electrodes of the first to third thin film transistors have a double-layer structure in which a metal layer is formed on a transparent conductive layer, and the transparent conductive layer of the pixel electrode is exposed through a transmission hole passing through the insulation layer and the metal layer in the pixel region.

Abstract: A method is provided for fabricating a field effect transistor (“FET”) having a channel region in a semiconductor-on-insulator (“SOI”) layer of an SOI substrate. Desirably, in such method, a sacrificial stressed layer is formed to overlie a first portion of an active semiconductor region but not overlie second portion of the active semiconductor region which shares a common boundary with the first portion. After forming trenches in the SOI layer, the SOI substrate is heated with the stressed layer thereon sufficiently to cause the stressed layer to relax, thereby causing the stressed layer to apply a first stress to the first portion and to apply a second stress to the second portion. For example, when the first stress is tensile, the second stress is compressive, or the first stress can be compressive when the second stress is tensile. Desirably, the stressed layer is then removed to expose the first and second portions of the active semiconductor region.

Abstract: The present invention provides a semiconducting structure including a substrate having an SOI region and a bulk-Si region, wherein the SOI region and the bulk-Si region have a same or differing crystallographic orientation; an isolation region separating the SOI region from the bulk-Si region; and at least one first device located in the SOI region and at least one second device located in the bulk-Si region. The SOI region has an silicon layer atop an insulating layer. The bulk-Si region further comprises a well region underlying the second device and a contact to the well region, wherein the contact stabilizes floating body effects. The well contact is also used to control the threshold voltages of the FETs in the bulk-Si region to optimized the power and performance of circuits built from the combination of the SOI and bulk-Si region FETs.

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. The method of manufacturing a bottom gate thin film transistor includes forming a bottom gate electrode on a substrate, forming a gate insulating layer on the substrate to cover the bottom gate electrode, forming an amorphous semiconductor layer, an N-type semiconductor layer and an electrode layer on the gate insulating layer sequentially, etching an electrode region and an N-type semiconductor layer region formed on the bottom gate electrode sequentially to expose an amorphous semiconductor layer region, melting the amorphous semiconductor layer region using a laser annealing method, and crystallizing the melted amorphous semiconductor layer region to form a laterally grown polycrystalline channel region.

Abstract: A method of manufacturing a thin film transistor capable of inhibiting the characteristics variation of the thin film transistor without deteriorating the characteristics thereof is provided. A crystalline silicon film is formed by indirect heat treatment through a photothermal conversion layer and a buffer layer. By patterning the buffer layer and an insulating film, a channel protective film is selectively formed in a region corresponding to a channel region on the crystalline silicon film. Further, when an n+ silicon film and a metal layer are selectively removed, the channel protective film functions as an etching stopper. When the crystalline silicon film is formed, heat is uniformly supplied. Further, in etching, the channel region of the crystalline silicon film is protected.

Abstract: Substrate having a first partial substrate with a carrier layer and a second partial substrate, which is bonded to the first partial substrate. The second partial substrate has an insulator layer, which is applied on the carrier layer and has at least two regions each having a different thickness, thereby forming a stepped surface of the insulator layer, and a semiconductor layer, which is applied to the stepped surface of the insulator layer and is formed at least partially epitaxially, wherein the semiconductor layer has a planar surface which is opposite to the stepped surface of the insulator layer. Transistors are formed on the semiconductor layer.

Abstract: A top layer of a predetermined metal is provided on a mirror for use in a lithographic apparatus having source to provide radiation of a desired wavelength. The source generates a stream of undesired metal particles that are deposited to form smaller and larger nuclei on the mirror. The top layer may interdiffuse in a predetermined temperature range with nuclei of the metal deposition. An additional layer of an alloy of the metal particles and the metal of the top layer is formed that has a higher reflectivity than a layer only comprising the metal particles would have.

Abstract: A semiconductor integrated circuit is provided in which a CMOS transistor is formed on a first conductivity type semiconductor film provided on a first conductivity type supporting substrate through an embedded insulating film. Second conductivity type source and drain regions are formed in the semiconductor film. The source region has an ultra-shallow high-density second conductivity type source extension region at a boundary with a channel region, a low-density second conductivity type source extension region under the ultra-shallow high-density second conductivity type source extension region, and a high-density second conductivity type source extension region under the low-density second conductivity type source extension region.

Abstract: There is provided a method of forming a semiconductor device having stacked transistors. When forming a contact hole for connecting the stacked transistors to each other, ohmic layers on the bottom and the sidewall of the common contact hole are separately formed. As a result, the respective ohmic layers are optimally formed to meet requirements or conditions. Accordingly, the contact resistance of the common contact may be minimized so that it is possible to enhance the speed of the semiconductor device.

Abstract: To form a driver circuit to be mounted to a liquid crystal display device or the like on a glass substrate, a quartz substrate, etc., and to provide a display device mounting driver circuits formed from different TFTs suited for their respective operational characteristics. A stick driver circuit on the scanning line side and a stick driver circuit on the data line side are different in structure, and have different TFTs in which the thickness of a gate insulating film, the channel length and other parameters are varied depending on required circuit characteristics. In the stick driver on the scanning line side, which is composed of a shift register circuit, a level shifter circuit, and a buffer circuit, the buffer circuit has a TFT with a thick gate insulating film because it is required to have a withstand voltage of 30 V.

Abstract: A method for fabricating an AMOLED pixel includes forming a transparent semiconductor layer on a substrate and forming a first channel layer of the switch TFT, a lower electrode of a storage capacitor and a second channel layer of a driving TFT. A first dielectric layer is formed over the substrate. A first opaque metal gate of the switch TFT, a second opaque metal gate of the driving TFT and a scan line are formed on the first dielectric layer. A first source and a first drain of the switch TFT are formed in the first channel layer and a second source and a second drain of the switch TFT are formed in the second channel layer. A patterned transparent metal layer is formed on the first dielectric layer. A data line is formed over the substrate. An OLED is formed over the substrate.

Abstract: A process for depositing a thin film material on a substrate is disclosed, comprising simultaneously directing a series of gas flows from the output face of a delivery head of a thin film deposition system toward the surface of a substrate, and wherein the series of gas flows comprises at least a first reactive gaseous material, an inert purge gas, and a second reactive gaseous material, wherein the first reactive gaseous material is capable of reacting with a substrate surface treated with the second reactive gaseous material. A system capable of carrying out such a process is also disclosed.

Abstract: By forming a semiconductor alloy in a silicon-based active semiconductor region prior to the gate patterning, material characteristics of the semiconductor alloy itself may also be exploited in addition to the strain-inducing effect thereof. Consequently, device performance of advanced field effect transistors may be even further enhanced compared to conventional approaches using a strained semiconductor alloy in the drain and source regions.

Abstract: A field effect transistor and a method of fabricating the field effect transistor. The field effect transistor includes: a silicon body, a perimeter of the silicon body abutting a dielectric isolation; a source and a drain formed in the body and on opposite sides of a channel formed in the body; and a gate dielectric layer between the body and an electrically conductive gate electrode, a bottom surface of the gate dielectric layer in direct physical contact with a top surface of the body and a bottom surface the gate electrode in direct physical contact with a top surface of the gate dielectric layer, the gate electrode having a first region having a first thickness and a second region having a second thickness, the first region extending along the top surface of the gate dielectric layer over the channel region, the second thickness greater than the first thickness.

Abstract: A TFT having a dual buffer structure, a method of fabricating the same, and a flat panel display having the TFT, and a method of fabricating the same are provided. The TFT includes a first buffer layer formed of an amorphous silicon layer on a substrate, a second buffer layer formed on the first buffer layer. The TFT also includes a semiconductor layer formed on the second buffer layer and a gate electrode formed on the semiconductor layer. The dual buffer structure provides better barrier to impurities diffusing from the substrate, and also acts as a black matrix to reduce unwanted reflections and is a source of hydrogen to passivate other layers.

Abstract: Flash memory device structures and methods of manufacture thereof are disclosed. The flash memory devices are manufactured on silicon-on-insulator (SOI) substrates. Shallow trench isolation (STI) regions and the buried oxide layer of the SOI substrate are used to isolate adjacent devices from one another. The methods of manufacture require fewer lithography masks and may be implemented in stand-alone flash memory devices, embedded flash memory devices, and system on a chip (SoC) flash memory devices.

Abstract: A substrate having a gate electrode layer, a gate insulating layer, and a silicon layer thereon is provided. These layers are patterned into a gate area, a gate line and a gate line wiring area. A passivation layer is formed on the entire substrate and patterned to form two contact holes in the passivation layer on the silicon layer at the gate area, and partions of the passivation layer at the gate line and at the gate line wiring areas are removed. An ion implanting layer and a metal layer are formed on the substrate and patterned to form a source region, a drain region, a data line, a data line wiring area and a second layer of the gate line wiring area. A pixel electrode is formed on the passivation layer and electrically coupled to the drain region. Therefore, the TFT array can be fabricated by only four masks.

Abstract: The present invention discloses a method for manufacturing a TFT LCD array substrate by utilizing the gray tone mask technology and the photoresist lifting-off technology with only two masks in two photolithography processes, and to a TFT LCD array substrate manufactured by the same. In the resultant array substrate, the gate line and the data line are perpendicular to and intersect with each other to define the pixel area, and one of the gate line and the data line is continuous and the other is discontinuous. The array substrate is covered with a passivation protection film. The disconnected gate line or the data line is connected together through the via holes formed in the passivation protection film and the connecting conductive film formed on the passivation protection film.

Abstract: A method of manufacturing a thin film transistor array panel is provided, which includes: forming a semiconductor layer of polysilicon on an insulating substrate; forming a gate insulating layer on the semiconductor layer; forming a gate electrode on the gate insulating layer; forming a source region and a drain region by doping conductive impurities in the semiconductor layer; forming an interlayer insulating layer covering the gate electrode; forming a source electrode and a drain electrode respectively connected to the source and the drain regions; forming a passivation layer covering the source and the drain electrodes; forming a pixel electrode connected to the drain electrode; and forming a first alignment key when forming one selected from the semiconductor layer, the gate electrode, the source and the drain electrodes, and the pixel electrode, wherein one selected from the semiconductor layer, the gate electrode, the source and the drain electrodes, and the pixel electrode is at least formed by photol

Abstract: A semiconductor process and apparatus includes forming first and second metal gate electrodes (151, 161) over a hybrid substrate (17) by forming the first gate electrode (151) over a first high-k gate dielectric (121) and forming the second gate electrode (161) over at least a second high-k gate dielectric (122) different from the first gate dielectric (121). By forming the first gate electrode (151) over a first SOI substrate (90) formed by depositing (100) silicon and forming the second gate electrode (161) over an epitaxially grown (110) SiGe substrate (70), a high performance CMOS device is obtained which includes high-k metal PMOS gate electrodes (161) having improved hole mobility.

Abstract: Provided is an organic light emitting display, comprising a substrate; a driving unit formed over the substrate; a planarization layer formed over the driving unit, the planarization layer comprising a normal tapered edge portion; and an emission unit formed over the planarization layer to be electrically connected to the driving unit.

Abstract: A method for fabricating an active-matrix organic electroluminescent (OEL) display panel is described. A transparent conductive layer is formed on a substrate as a common anode for all organic light emitting diodes (OLED), and a passivation layer is formed on the transparent conductive layer. Thin film transistors are formed on the passivation layer to serve as an active matrix, and openings are formed in the passivation layer to expose portions of the transparent conductive layer and define pixel regions. An organic function layer is formed in each opening, and a metal electrode layer is formed on each organic function layer, wherein the metal electrode layer is electrically connected with the drain of the corresponding thin film transistor.

Abstract: Methods are disclosed for forming self-aligned dual stressed layers for enhancing the performance of NFETs and PFETs. In one embodiment, a sacrificial layer is used to remove a previously deposited stressed layer. A mask position used to pattern the sacrificial layer is adjusted such that removal of the latter deposited stressed layer, using the sacrificial layer, leaves the dual stress layers in an aligned form. The methods result in dual stressed layers that do not overlap or underlap, thus avoiding processing problems created by those issues. A semiconductor device including the aligned dual stressed layers is also disclosed.

Abstract: The present invention relates to an organic thin film transistor (OTFT), a method of fabricating the OTFT, and an organic electroluminescent display that has the OTFTs. The invention prevents surface damage of an organic semiconductor layer and reduces an off-current. The OTFT includes a substrate, a source electrode and a drain electrode formed on the substrate, and a semiconductor layer formed on the substrate that has a channel layer disposed over and between the source electrode and drain electrode. In addition, the OTFT includes a gate insulating layer formed on the semiconductor layer, a separation pattern formed through the semiconductor layer and the gate insulating layer to separate the channel layer, and a gate electrode formed on the gate insulating layer over the channel layer.

Abstract: A semiconductor device according to example embodiments may have a plurality of stacked transistors. The semiconductor device may have a lower insulating layer formed on a semiconductor substrate and an upper channel body pattern formed on the lower insulating layer. A source region and a drain region may be formed within the upper channel body pattern, and a non-metal transfer gate electrode may be disposed on the upper channel body pattern between the source and drain regions. The non-metal transfer gate electrode, the upper channel body pattern, and the lower insulating layer may be covered by an intermediate insulating layer. A metal word line may be disposed within the intermediate insulating layer to contact at least an upper surface of the non-metal transfer gate electrode. An insulating spacer may be disposed on a sidewall of the metal word line.

Abstract: Semiconductor integrated circuits that include thin film transistors (TFTs) and methods of fabricating such semiconductor integrated circuits are provided. The semiconductor integrated circuits may include a bulk transistor formed at a semiconductor substrate and a first interlayer insulating layer on the bulk transistor. A lower TFT may be on the first interlayer insulating layer, and a second interlayer insulating layer may be on the lower TFT. An upper TFT may be on the second interlayer insulating layer, and a third interlayer insulating layer may be on the upper TFT. A first impurity region of the bulk transistor, a first impurity region of the lower TFT, and a first impurity region of the upper TFT may be electrically connected to one another through a node plug that penetrates the first, second and third interlayer insulating layers.

Abstract: A method of fabricating a liquid crystal display device includes forming first, second, and third active patterns on a substrate having a pixel region and a driving region, wherein the first and second active patterns are in the driving region and the third active pattern is in the pixel region, the first, second, and third active patterns each having an active region, a source region, and a drain region with the source and drain regions on opposing sides of the active region, forming a gate insulator on the first, second, and third active patterns, forming first, second, and third gate electrodes on the gate insulator, wherein the first, second, and third gate electrodes correspond to the active regions of the first, second, and third active patterns, respectively, doping the source and drain regions of the first, second, and third active patterns with n? ions using the first, second, and third gate electrodes as a doping mask, doping the n? doped source and drain regions of the second active pattern with p+

Abstract: A semiconductor process and apparatus provides a planarized hybrid substrate (16) by removing a nitride mask layer (96) and using an oxide polish stop layer (92) when an epitaxial semiconductor layer (99) is being polished for DSO and BOS integrations. To this end, an initial SOI wafer semiconductor stack (11) is formed which includes one or more oxide polish stop layers (91, 92) formed between the SOI semiconductor layer (90) and a nitride mask layer (93). The oxide polish stop layer (92) may be formed by depositing a densified LPCVD layer of TEOS to a thickness of approximately 100-250 Angstroms.

Abstract: A method of forming a semiconductor device may include forming an interlayer insulating layer on a semiconductor substrate, and the interlayer insulating layer may have a contact hole therein exposing a portion of the semiconductor substrate. A single crystal semiconductor plug may be formed in the contact hole and on portions of the interlayer insulating layer adjacent the contact hole opposite the semiconductor substrate, and portions of the interlayer insulating layer opposite the semiconductor substrate may be free of the single crystal semiconductor plug. Portions of the single crystal semiconductor plug in the contact hole may be removed while maintaining portions of the single crystal semiconductor plug on portions of the interlayer insulating layer adjacent the contact hole as a single crystal semiconductor contact pattern.