Abstract: A thin film transistor substrate of horizontal electric field type includes: a gate line and a first common line formed on a substrate to be in parallel to each other; a data line crossing the gate line and the first common line with a gate insulating film therebetween to define a pixel area; a second common line crossing the first common line having the gate insulating film therebetween; a thin film transistor connected to the gate line and the data line; a common electrode extending from the second common line in said pixel area; a pixel electrode that is parallel to the common electrode and the second common line; a protective film for covering the thin film transistor; a gate pad having a lower gate pad electrode connected to an upper gate pad electrode through a first contact hole; a common pad having a lower common pad electrode connected to an upper common pad electrode through a second contact hole; and a data pad having a lower data pad electrode connected to an upper data pad electrode provided with

Abstract: A method of manufacturing a thin film transistor array panel is provided, which includes: forming a gate line on a substrate; forming a gate insulating layer on the gate line; forming a semiconductor layer on the gate insulating layer; forming an ohmic contact on the semiconductor layer; forming a data line and a drain electrode on the ohmic contact; depositing a passivation layer on the data line and the drain electrode; forming a first photoresist layer on the passivation layer; etching the passivation layer and the gate insulating layer using the first photoresist layer as a mask to expose a portion of the drain electrode and a portion of the substrate; depositing a conductive film; and removing the photoresist layer; to form a pixel electrode on a portion of the drain electrode exposed by the etching of the passivation layer.

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 method of forming wires of a poly-crystalline TFT by crystallizing an amorphous silicon thin film using a metal film is provided. The wires forming method includes the steps of: removing a MILC metal film; forming etch-stopper layer patterns on at least part of respective source and drain regions formed on a semiconductor layer; forming an interlayer insulation film on the substrate; etching the interlayer insulation film to thereby form contact holes which expose the etch-stopper layer patterns of the source and drain regions; and forming a wires metal film contacting the etch-stopper layer patterns, and patterning the wires metal film to thus form metal wires. Thus, as the etch-stopper layer patterns are additionally installed at the contact positions, a silicon thin film can be protected at etching the interlayer insulation film.

Abstract: A Thin Film Transistor (TFT) reduces interconnection resistance of source/drain electrodes, prevents contamination from an active layer, reduces contact resistance between a pixel electrode and the source/drain electrodes, smoothly supplies hydrogen to the active layer and has high mobility, on-current characteristics, and threshold voltage characteristics The TFT includes an active layer having a channel region and source/drain regions, a gate electrode supplying a signal to the channel region, source/drain electrodes respectively connected to the source/drain regions and including at least one of Ti, a Ti alloy, Ta, and a Ta alloy; and an insulating layer interposed between the source/drain electrodes and the active layer and including silicon nitride.

Abstract: Affords high electron mobility transistors having a high-purity channel layer and a high-resistance buffer layer. A high electron mobility transistor 11 is provided with a supporting substrate 13 composed of gallium nitride, a buffer layer 15 composed of a first gallium nitride semiconductor, a channel layer 17 composed of a second gallium nitride semiconductor, a semiconductor layer 19 composed of a third gallium nitride semiconductor, and electrode structures (a gate electrode 21, a source electrode 23 and a drain electrode 25) for the transistor 11. The band gap of the third gallium nitride semiconductor is broader than that of the second gallium nitride semiconductor. The carbon concentration NC1 of the first gallium nitride semiconductor is 4×1017 cm?3 or more. The carbon concentration NC2 of the second gallium nitride semiconductor is less than 4×1016 cm?3.

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 semiconductor structure fabrication method. The method includes providing a structure which includes (a) first and second semiconductor regions, (b) first and second gate dielectric regions on the first and second semiconductor regions, respectively, (c) a high-K dielectric region on the first gate dielectric region, K being greater than 4, (d) an electrically conductive layer on the high-K dielectric region, (e) a poly-silicon layer on the electrically conductive layer and the second gate dielectric region, and (f) a hard mask layer on the poly-silicon layer. The hard mask layer is patterned resulting in first and second hard mask regions. The poly-silicon layer is etched with the first and second hard mask regions as blocking masks resulting in first and second poly-silicon regions. The first and second poly-silicon regions are exposed to a surrounding ambient.

Abstract: Methods for fabricating CMOS image sensor devices are provided, wherein active pixel sensors are constructed with non-planar transistors having vertical gate electrodes and channels, which minimize the effects of image lag and dark current.

Abstract: Methods of forming transistors and structures thereof are disclosed. A preferred embodiment comprises a semiconductor device including a workpiece, a gate dielectric disposed over the workpiece, and a thin layer of conductive material disposed over the gate dielectric. A layer of semiconductive material is disposed over the thin layer of conductive material. The layer of semiconductive material and the thin layer of conductive material comprise a gate electrode of a transistor. A source region and a drain region are formed in the workpiece proximate the gate dielectric. The thin layer of conductive material comprises a thickness of about 50 Angstroms or less.

Abstract: A method of manufacturing a metal-oxide-semiconductor (MOS) transistor device is disclosed. A gate dielectric layer is formed on an active area of a substrate. A gate electrode is patterned on the gate dielectric layer. The gate electrode has vertical sidewalls and a top surface. A liner is formed on the vertical sidewalls of the gate electrode. A nitride spacer is formed on the liner. An ion implanted is performed to form a source/drain region. After salicide process, an STI region that isolates the active area is recessed, thereby forming a step height at interface between the active area and the STI region. The nitride spacer is removed. A nitride cap layer that borders the liner is deposited. The nitride cap layer has a specific stress status.

Abstract: A method includes forming a lower dielectric layer on a semiconductor substrate, forming a bit line landing pad and a storage landing pad that penetrate the lower dielectric layer, covering the lower dielectric layer, the bit line landing pad, and the storage landing pad with an intermediate dielectric layer, forming an upper dielectric layer on the intermediate dielectric layer, partially removing the upper dielectric layer and the intermediate dielectric layer to form a contact opening that exposes the storage landing pad and a portion of the lower dielectric layer, forming a contact spacer on an inner wall of the contact opening, and filling the contact opening with a contact plug, a top surface of the contact plug larger than a surface of the contact plug that is in contact with the storage landing pad, the top surface of the contact plug eccentric in relation to the storage landing pad.

Abstract: A semiconductor structure is described. The structure includes a trench opening formed in a semiconductor substrate having a semiconductor-on-insulator (SOI) layer and a buried insulating (BOX) layer; and a filling material formed in the trench opening, the filling material forming a “V” shape within the trench memory cell, wherein the “V” shape includes a top portion substantially adjacent to a top surface of the BOX layer. A method of fabricating the semiconductor structure is also described. The method includes forming a trench opening in a semiconductor substrate having an SOI layer and a BOX layer; laterally etching the BOX layer such that a portion of the trench opening associated with the BOX layer is substantially greater than a portion of the trench opening associated with the SOI layer; filling the trench opening with a filling material; and recessing the filling material.

Abstract: A method for manufacturing a nonvolatile semiconductor memory device including: forming a first and a second stacked gate structures, each of which including a first polysilicon layer formed on a silicon substrate via a gate insulator, an inter-gate insulator formed on the first polysilicon layer, a second polysilicon layer formed on the inter-gate insulator, and a cap layer formed on the second polysilicon layer, respectively; forming a interlayer insulator between the first and the second stacked gate structures, the interlayer insulator covering upper surfaces of the cap layer; planarizing the interlayer insulator by using the cap layers as a stopper; removing the cap layers so that the second polysilicon layers are exposed; masking the exposed second polysilicon layer of the first stacked gate structure by a photoresist film; removing the second polysilicon layer and the inter-gate insulator of the second stacked gate structure so that the first polysilicon layer of the second stacked gate structure is ex

Abstract: A first dielectric layer is formed over a substrate. A single layer first conductive layer that acts as a floating gate is formed over the first dielectric layer. A trough is formed in the first conductive layer to increase the capacitive coupling of the floating gate with a control gate. An intergate dielectric layer is formed over the floating gate layer. A second conductive layer is formed over the second dielectric layer to act as a control gate.

Abstract: A super-silicon-rich oxide (SSRO) non-volatile memory cell includes a gate conductive layer on a substrate, a source/drain in the substrate at respective sides of the gate conductive layer, a tunneling dielectric layer between the gate conductive layer and the substrate, a SSRO layer serving as a charge trapping layer between the gate conductive layer and the tunneling dielectric layer, and an upper-dielectric layer between the gate conductive layer and the SSRO layer.

Abstract: A semiconductor device includes a semiconductor layer having a plurality of element regions in its surface area, which are delimited by at least one element isolation trench, a plurality of floating gate electrodes provided on the element regions with a first gate insulation film interposed therebetween and each including a first charge-storage layer having a first width which is equal to that of each of the element regions and a second charge-storage layer stacked on the first charge-storage layer and having a second width which is smaller than the first width, and a plurality of control gate electrodes provided on the floating gate electrodes with a second gate insulation films interposed therebetween. The device further includes an element isolating insulation film buried into the element isolation trench. The top surface of the element isolating insulation film is located higher than that of the first charge-storage layer.

Abstract: A method of forming a buried interconnection includes removing a semiconductor substrate to form a groove in the semiconductor substrate. A metal layer is formed on inner walls of the groove using an electroless deposition technique. A silicidation process is applied to the substrate having the metal layer, thereby forming a metal silicide layer on the inner walls of the groove.

Abstract: A method of fabricating a nonvolatile semiconductor memory device includes the steps of: (a) forming a layered dielectric film on the semiconductor substrate; (b) forming a first conductive film on the layered dielectric film; (c) forming a first dielectric film on the first conductive film; (d) patterning the first dielectric film and the first conductive film to form a layered pattern composed of first dielectric films and first conductive films; and (e) implanting a first impurity along a direction having an inclination angle to a normal direction to a principal plane of the semiconductor substrate by using the layered pattern as a mask to form a first impurity diffusion layer being the same in conductivity type as the semiconductor substrate, wherein, step (d) includes patterning the first dielectric film to form the first dielectric films having a shape with a width narrower in an upper surface than in a lower surface.

Abstract: A method and device providing a strained Si film with reduced defects is provided, where the strained Si film forms a fin vertically oriented on a surface of a non-conductive substrate. The strained Si film or fin may form a semiconductor channel having relatively small dimensions while also having few defects. The strained Si fin is formed by growing Si on the side of a relaxed SiGe block. A dielectric gate, such as, for example, an oxide, a high “k” material, or a combination of the two, may be formed on a surface of the strained Si film. Additionally, without substantially affecting the stress in the strained Si film, the relaxed SiGe block may be removed to allow a second gate oxide to be formed on the surface previously occupied by the relaxed SiGe block.

Abstract: A method for fabricating a semiconductor device with a bulb-shaped recess gate pattern is provided. The method includes forming a plurality of oxide layers over a substrate; forming a silicon layer to cover the oxide layers; forming a mask over the silicon layer; etching the silicon layer using the mask as an etch mask to form a plurality of first recesses to expose the oxide layers; etching the oxide layers to form a plurality of second recesses; and forming a plurality of gate patterns at least partially buried into the first recesses and the second recesses.

Abstract: A semiconductor device includes an active region including a surface region and a first recess formed below the surface region, the active region extending along a first direction; a device isolation structure provided on an edge of the active region; a gate line traversing over the surface region of the active region along a second direction orthogonal to the first direction; a second recess formed in the device isolation structure to receive a given portion of the gate line into the second recess; a first junction region formed in the active region beneath the first recess and on a first side of the gate line; and a second junction region formed on a second side of the gate line and above the first junction region, wherein the first and second junction regions define a vertical-type channel that extends along lateral and vertical directions.

Abstract: A method of manufacturing a semiconductor device having a polycrystalline silicon layer (5) includes; a step of forming a mask layer (7) on the polycrystalline silicon layer (5); a step of forming a side wall (8) that is provided on a side face of the mask layer (7) and covers part of the polycrystalline silicon layer (6); a step of doping an impurity (52) into the polycrystalline silicon layer (5) by using at least one of the mask layer (7) and the side wall (8) as a mask; and a step of etching the polycrystalline silicon layer (5, 6) by using at least one of the mask layer (7) and the side wall (8) as a mask.

Abstract: A method of forming a contact structure includes forming an isolation region defining active regions in a semiconductor substrate. Gate patterns extending to the isolation region while crossing the active regions are formed. A sacrificial layer is formed on the semiconductor substrate having the gate patterns. Sacrificial patterns remaining on the active regions are formed by patterning the sacrificial layer. Molding patterns are formed on the isolation region. Contact holes exposing the active regions at both sides of the gate patterns are formed by etching the sacrificial patterns using the molding patterns and the gate patterns as an etching mask. Contact patterns respectively filling the contact holes are formed. The disclosed method of forming a contact structure may be used in fabricating a semiconductor device.

Abstract: A p-type field effect transistor (PFET) and an n-type field effect transistor (NFET) are formed by patterning of a gate dielectric layer, a thin silicon layer, and a silicon-germanium alloy layer. After formation of the source/drain regions and gate spacers, silicon germanium alloy portions are removed from gate stacks. A dielectric layer is formed and patterned to cover an NFET gate electrode, while exposing a thin silicon portion for a PFET. Germanium is selectively deposited on semiconductor surfaces including the exposed silicon portion. The dielectric layer is removed and a metal layer is deposited and reacted with underlying semiconductor material to form a metal silicide for a gate electrode of the NFET, while forming a metal silicide-germanide alloy for a gate electrode of the PFET.

Abstract: Non-volatile memory devices and arrays are described that facilitate the use of band-gap engineered gate stacks with asymmetric tunnel barriers in floating gate memory cells in NOR or NAND memory architectures that allow for direct tunneling programming and erase with electrons and holes, while maintaining high charge blocking barriers and deep carrier trapping sites for good charge retention. The direct tunneling program and erase capability reduces damage to the gate stack and the crystal lattice from high energy carriers, reducing write fatigue and leakage issues and enhancing device lifespan. Memory cells of the present invention also allow multiple bit storage in a single memory cell, and allow for programming and erase with reduced voltages. A positive voltage erase process via hole tunneling is also provided.

Abstract: Methods for selectively oxidizing a semiconductor structure include generating a gas cluster ion beam comprising an oxidizing source gas, directing the gas cluster ion beam to a region of a substrate adjacent a conductive line and exposing the region to the gas cluster ion beam including an oxidizing matter. Utilizing the gas cluster ion beam enables selective oxidation of a targeted region at temperatures substantially lower than those of typical oxidation processes thus, reducing or eliminating oxidation of the conductive line. Semiconductor devices including transistors formed using such methods are also disclosed.

Abstract: In a semiconductor device having a raised source and drain structure, in forming a raised region by etching, etching of an island-like semiconductor film which is an active layer is inhibited. In a method for manufacturing a semiconductor device, an insulating film is formed by oxidizing or nitriding the surface of an island-like semiconductor film, a semiconductor film is formed on a region which is a part of the insulating film, a gate electrode is formed over the insulating film, an impurity element imparting one conductivity type is added to the island-like semiconductor film and the semiconductor film using the gate electrode as a mask, the impurity element is activated by heating the island-like semiconductor film and the semiconductor film, and the part of the insulating film between the island-like semiconductor film and the semiconductor film disappears by heating the island-like semiconductor film and the semiconductor film.

Abstract: According to the present invention, there is provided a semiconductor device including a first conductive type semiconductor substrate, a gate electrode formed over the semiconductor substrate via a gate insulator, a first conductive impurity region buried in the semiconductor substrate, the first conductive impurity region being both sides of an extend plane, the extend plane being extended from side-walls of the gate electrode into the semiconductor substrate and a second conductive type source/drain region partially overlapping with the first conductive impurity region and extending from an end of the gate electrode at the semiconductor substrate to an outer region in the semiconductor substrate, wherein a first conductive impurity concentration at a prescribed depth in the overlapping portion between the first conductive impurity region and the source/drain region is lower than the first conductive impurity concentration in the first conductive impurity region except the overlapping portion corresponding

Abstract: Methods of forming a dielectric layer of a MIM capacitor can include forming a passivation layer on a dielectric layer of a MIM capacitor to separate the dielectric layer from direct contact with an overlying photo-resist pattern. Related capacitor structures are also disclosed.

Abstract: A memory device, such as a PCRAM, including a chalcogenide glass backbone material with germanium telluride glass and methods of forming such a memory device.

Abstract: A self-converged memory material element is created during the manufacture of a memory cell comprising a base layer, with a bottom electrode, and an upper layer having a third, planarization stop layer over the base layer, a second layer over the third layer, and the first layer over the second layer. A keyhole opening is formed through the upper layer to expose the bottom electrode. The first layer has an overhanging portion extending into the opening. A dielectric material is deposited into the keyhole opening so to create a self-converged void within the keyhole opening. An anisotropic etch forms a sidewall of the dielectric material in the keyhole opening with an electrode hole aligned with the void and exposing the bottom electrode. A memory material is deposited into the electrode hole in contact with the bottom electrode and is planarized down to the third layer to create the memory material element.

Abstract: A method of forming a capacitor for use as a charge pump with flash memory, comprising: (a) concurrently forming polysilicon gates on a semiconductor body in a core region and a polysilicon middle capacitor plate in a peripheral region, (b) forming a first dielectric layer over the polysilicon gates and the middle capacitor plate, (c) planarizing the first dielectric layer to expose a top portion of the polysilicon gates and a top portion of the middle capacitor plate, (d) forming a second dielectric layer over the top portion of the middle capacitor layer, (e) concurrently forming patterning a second polysilicon layer in the core region and a third capacitor plate in the periphery region and (f) connecting the third capacitor plate to the source/drain well.

Abstract: A method of fabricating a storage node with a supported structure is provided. A dielectric stacked comprising an etch stop layer, a first dielectric layer, a support layer and a second dielectric layer is formed on a substrate. An opening is etched into the dielectric stacked. A conductive layer is formed on the second dielectric layer and inside the opening. The conductive layer directly above the second dielectric layer is removed to form columnar node structure. The second dielectric layer is then removed. A spacer layer is deposited on the support layer and the columnar node structure. A tilt-angle implant is performed to implant dopants into the spacer layer. The undoped spacer layer is removed to form a hard mask. The support layer not covered by the hard mask is etched away to expose the first dielectric layer. The first dielectric layer and the hard mask are removed.

Abstract: A silicon substrate (SOI) is placed on a buried oxide layer (BOX). An MOS transistor is produced in an active zone of the substrate which is defined by an isolating region. A gate region and source and drain regions, which between them define a channel, are produced so that the gate region extends above the channel. The isolating region is produced by localized formation of a zone of material that can be selectively etched with respect to silicon. That material is selectively etched, and a dielectric material is deposited in the etched feature. The etching is carried out after the gate region has been produced.

Abstract: Semiconductor devices and methods of manufacture thereof are disclosed. In a preferred embodiment, a semiconductor device includes a workpiece having a buried layer disposed beneath a top portion of the workpiece. An isolation ring structure is disposed within the top portion of the workpiece extending completely through at least a portion of the buried layer, the isolation ring structure comprising a ring having an interior region. A diffusion confining structure is disposed within the interior region of the isolation ring structure. A conductive region is disposed within the top portion of the workpiece within a portion of the interior of the isolation ring structure, the conductive region comprising at least one dopant element implanted and diffused into the top portion of the workpiece. The diffusion confining structure defines at least one edge of the conductive region, and the conductive region is coupled to the buried layer.

Abstract: The present invention relates to a method for forming an isolation trench structure in a semiconductor substrate without causing deleterious topographical depressions in the upper surface thereof which cause current and charge leakage to an adjacent active area. The inventive method forms a pad oxide upon a semiconductor substrate, and then forms a nitride layer on the pad oxide. The nitride layer is patterned with a mask and etched to expose a portion of the pad oxide layer and to protect an active area in the semiconductor substrate that remains covered with the nitride layer. A second dielectric layer is formed substantially conformably over the pad oxide layer and the remaining portions of the first dielectric layer. A spacer etch is then carried out to form a spacer from the second dielectric layer. The spacer is in contact with the remaining portion of the first dielectric layer. An isolation trench etch follows the spacer etch.

Abstract: According to the present invention, there is provided a method for manufacturing an SOI substrate based on a bonding method, comprising at least: forming a silicon oxide film on a surface of at least one of a single-crystal silicon substrate that becomes an SOI layer and a single-crystal silicon substrate that becomes a support substrate; bonding the single-crystal silicon substrate that becomes the SOI layer to the single-crystal silicon substrate that becomes the support substrate through the silicon oxide film; and performing a heat treatment for holding at a temperature falling within the range of at least 950° C. to 1100° C. and then carrying out a heat treatment at a temperature higher than 1100° C. when effecting a bonding heat treatment for increasing bonding strength.

Abstract: A method for minimizing defects when transferring a useful layer from a donor wafer to a receptor wafer is described. The method includes providing a donor wafer having a surface below which a zone of weakness is present to define a useful layer to be transferred, molecularly bonding at a bonding interface the surface of the useful layer of the donor wafer to a surface of the receptor wafer to form a structure, heating the structure at a first temperature that is substantially higher than ambient temperature for a first time period sufficient to liberate water molecules from the bonding interface, with the heating being insufficient to cause detachment of the useful layer at the zone of weakness, and detaching the useful layer from the donor wafer.

Abstract: A method for fabricating a thermal management substrate comprises acts of ion-implanting a substrate material to form a substrate layer, a ion-implanted layer, and an overlay layer; bonding a handle wafer to the overlay layer with a SiO2 bonding layer; splitting the ion-implanted wafer at the ion-implanted layer, resulting in a handle wafer SiO2 bonded with the overlay layer; depositing an insulating layer onto the overlay layer; and removing the handle wafer, whereby the resulting thermal management substrate comprises an overlay layer epitaxially fused with the insulating layer.

Abstract: A semiconductor device with a thinned semiconductor chip and a method for producing the latter is disclosed. In one embodiment, the thinned semiconductor chip has a top side with contact areas and a rear side with a rear side electrode. In this case, the rear side electrode is cohesively connected to a chip pad of a circuit carrier via an electrically conductive layer. In another embodiment, the thinned semiconductor chips of this semiconductor device according to the invention have low-microdefect edge side regions with semiconductor element structures and edge sides patterned by etching technology.

Abstract: A method for producing semiconductor wafers, from a semiconductor ingot, wherein an oxygen concentration distribution in the growth axis direction is measured in the ingot state (F2), a position at which the oxygen concentration is maximum or minimum in a range of a predetermined length is determined as a cut position according to the measurement results (F3), the ingot is cut in a perpendicular direction to the growth axis at the cut position into blocks each having the oxygen concentrations being maximum and minimum at both ends thereof (F4), each of the blocks is sliced, and thereby semiconductor wafers are produced. Thereby, there can be provided a technique by which when semiconductor wafers are produced from a semiconductor ingot, wafers having oxygen concentration being in a predetermined standard range can be certainly produced.

Abstract: A method for sawing a wafer includes the following steps. A wafer which has an active surface, a back surface and a plurality of longitudinal and transverse sawing lines is provided, wherein the sawing lines are located on the active surface so as to define a plurality of dies. A multiple-type tape is attached on the active surface of the wafer, wherein the multiple-type tape includes a first tape and a second tape, the second tape is located between the first tape and the active surface of the wafer, and the second tape is transparent. The back surface of the wafer is grinded. The first tape is removed. Finally, the wafer including the second tape is sawn along the sawing lines so as to separate the dies from one another.

Abstract: A method of cutting an object which can accurately cut the object is provided. An object to be processed 1 such as a silicon wafer is irradiated with laser light L while a light-converging point P is positioned therewithin, so as to form a modified region 7 due to multiphoton absorption within the object 1, and cause the modified region 7 to form a starting point region for cutting 8 shifted from the center line CL of the thickness of the object 1 toward the front face 3 of the object 1 along a line along which the object should be cut. Subsequently, the object 1 is pressed from the rear face 21 side thereof. This can generate a fracture from the starting point region for cutting 8 acting as a start point, thereby accurately cutting the object 1 along the line along which the object should be cut.

Abstract: A semiconductor substrate shaped to have a curved surface profile by anodization. Prior to being anodized, the substrate is finished with an anode pattern on its bottom surface so as to be consolidated into a unitary structure in which the anode pattern is precisely reproduced on the substrate. The anodization utilizes an electrolytic solution which etches out an oxidized portion as soon as it is formed as a result of the anodization, to thereby develop a porous layer in a pattern in match with the anode pattern. The anode pattern brings about an in-plane distribution of varying electric field intensity by which the porous layer develops into a shape complementary to a desired surface profile. Upon completion of the anodization, the curves surface is revealed on the surface of the substrate by etching out the porous layer and the anode pattern from the substrate.

Abstract: A method for improving the minority lifetime of silicon containing wafer having metallic contaminants therein is described incorporating annealing at 1200° C. or greater and providing a gaseous ambient of oxygen, an inert gas and a chlorine containing gas such as HCl.

Abstract: Provided is a method for producing an SOI substrate comprising a transparent insulating substrate and a silicon film formed on a first major surface of the insulating substrate wherein a second major surface of the insulating substrate which is opposite to the major surface is roughened, the method suppressing the generation of metal impurities and particles in a simple and easy way.

Abstract: The present method provides tools for growing conformal metal nitride, metal carbide and metal thin films, and nanolaminate structures incorporating these films, from aggressive chemicals. The amount of corrosive chemical compounds, such as hydrogen halides, is reduced during the deposition of transition metal, transition metal carbide and transition metal nitride thin films on various surfaces, such as metals and oxides. Getter compounds protect surfaces sensitive to hydrogen halides and ammonium halides, such as aluminum, copper, silicon oxide and the layers being deposited, against corrosion. Nanolaminate structures (20) incorporating metal nitrides, such as titanium nitride (30) and tungsten nitride (40), and metal carbides, and methods for forming the same, are also disclosed.

Abstract: Single-crystalline growth is realized using a liquid-phase crystallization approach involving the inhibition of defects typically associated with liquid-phase crystalline growth of lattice mismatched materials. According to one example embodiment, a semiconductor device structure includes a substantially single-crystal region. A liquid-phase material, such as Ge or a semiconductor compound, is crystallized to form the single-crystal region using an approach involving defect inhibition for the promotion of single-crystalline growth. In some instances, this defect inhibition involves the reduction and/or elimination of defects using a relatively small physical opening via which a crystalline growth front propagates. In other instances, this defect inhibition involves causing a change in crystallization front direction relative to a crystallization seed location.

Abstract: A polycrystalline silicon layer, a flat panel display using the polycrystalline silicon layer, and methods of fabricating the same are provided. An amorphous silicon layer is formed on a substrate. A first pattern layer, a second pattern layer, and a metal catalyst layer are formed on the amorphous silicon layer. The first pattern layer and the second pattern layer are formed to define a region of at least 400 ?m2 within which a metal catalyst of the metal catalyst layer is diffused into the amorphous silicon layer. A seed region is crystallized by the diffused metal catalyst. After a crystallization region is grown from the seed region, a semiconductor layer is formed on the crystallization region, so as to fabricate a thin film transistor with excellent characteristics. Using this, a flat panel display is fabricated.