Abstract: A method for forming a semiconductor device having recess channel includes forming a hard mask film pattern for exposing first regions for forming the trenches on a semiconductor substrate; forming first trenches by a first etching process using the hard mask film pattern as a mask, and removing the hard mask film pattern; forming a barrier film on the semiconductor substrate including the first trenches; forming an ion implantation mask film for exposing the first trenches on the barrier film; forming an ion implantation region in the semiconductor substrate below the first trenches using the ion implantation mask film and the barrier film; forming bulb-shaped second trenches by a second etching process using the ion implantation mask film and the barrier film as a mask, so that bulb-type trenches for recess channels, each including the first trench and the second trench, are formed; and removing the ion implantation mask film and the barrier film.

Abstract: A method of forming a transistor structure on a substrate (SOI) is disclosed, wherein the substrate comprises a supporting Si layer, a buried insulating layer, and a top Si layer. The method comprises forming a gate region of the transistor structure on the top Si layer, wherein the gate region is separated from the top Si layer by a dielectric layer, and wherein the top Si layer comprises a high dopant level. The method further comprises forming an open area on the top Si layer demarcated by a demarcating oxide and/or resist layer region, forming high level impurity or heavily-damaged regions by ion implantation, and exposing the open area to an ion beam, wherein the ion beam comprises a combination of beam energy and dose, and wherein the demarcating layer region and the gate region act as an implantation mask.

Abstract: A silicone-doped carbon interlayer dielectric (ILD) and its method of formation are disclosed. The ILD's dielectric constant and/or its mechanical strength can be tailored by varying the ratio of carbon-to-silicon in the silicon-doped carbon matrix.

Abstract: A low k stress liner, which replaces conventional stress liners in CMOS devices, is provided. In one embodiment, a compressive, low k stress liner is provided which can improve the hole mobility in pFET devices. UV exposure of this compressive, low k material results in changing the polarity of the low k stress liner from compressive to tensile. The use of such a tensile, low k stress liner improves electron mobility in nFET devices.

Abstract: A III-V group nitride system semiconductor self-standing substrate has: a first III-V group nitride system semiconductor crystal layer that has a region with dislocation lines gathered densely, the dislocation lines being gathered substantially perpendicular to a surface of the substrate, and a region with dislocation lines gathered thinly; and a second III-V group nitride system semiconductor crystal layer that is formed up to 10 ?m from the surface of the substrate on the first III-V group nitride system semiconductor crystal layer and that has a dislocation density distribution that is substantially uniform.

Abstract: Dual storage node memory devices and methods for fabricating dual storage node memory devices have been provided. In accordance with an exemplary embodiment, a method includes the steps of etching a plurality of trenches in a semiconductor substrate and forming a layered structure within the trenches. The layered structure includes a tunnel dielectric layer and a charge storage layer. Bit lines are formed within the semiconductor substrate and a layer of conductive material is deposited overlying the layered structure.

Abstract: A mask for forming polysilicon has a first slit region where a plurality of horizontal slit patterns are arranged in the vertical direction while bearing the same width, a second slit region where a plurality of horizontal slit patterns are arranged in the vertical direction while baring the same width, a third slit region where a plurality of horizontal slit patterns are arranged in the vertical direction while bearing the same width, and a fourth slit region where a plurality of horizontal slit patterns are arranged in the vertical direction while bearing the same width. The slit patterns arranged at the first to fourth slit regions are sequentially enlarged in width in the horizontal direction in multiple proportion to the width d of the slit pattern at the first slit region. The centers of the slit patterns arranged at the first to fourth slit regions in the horizontal direction are placed at the same line.

Abstract: An interlayer insulating film made of insulating material is formed on a semiconductor substrate. A hydrogen diffusion barrier film is formed on the interlayer insulating film, the hydrogen diffusion barrier film being made of material having a higher hydrogen diffusion barrier function than a hydrogen diffusion barrier function of material of the interlayer insulating film. The semiconductor substrate formed with the interlayer insulating film and hydrogen diffusion barrier film is thermally treated. In the process of forming the interlayer insulating film, the interlayer insulating film is formed under the condition that a moisture content becomes 5×10?3 g/cm3 or lower. Even if annealing is performed after the hydrogen diffusion barrier film is formed, a crack is hard to be formed in the underlying interlayer insulating film.

Abstract: This disclosure is concerned a method of manufacturing a semiconductor device which includes providing an dielectric film on a substrate; providing a mask material on the dielectric film; etching the dielectric film using the mask material; performing a first treatment of removing a metal residue generated by etching the dielectric film; performing a second treatment of making a sidewall of the dielectric film formed by etching the dielectric film hydrophobic; and performing a third treatment of removing a silicon residue generated by etching the dielectric film.

Abstract: Disclosed are methods and systems for improving cell-to-cell repeatability of electrical performance in memory cells. The methods involve forming an electrically non-conducting material having ordered porosity over a passive layer. The ordered porosity can facilitate formation of conductive channels through which charge carriers can migrate across the otherwise non-conductive layer to facilitate changing a state of a memory cell. A barrier layer can optionally be formed over the non-conductive layer, and can have ordered porosity oriented in a manner substantially perpendicular to the conductive channels such that charge carries migrating across the non-conductive layer cannot permeate the barrier layer. The methods provide for the manufacture of microelectronic devices with cost-effective and electrically reliable memory cells.

Abstract: A method for manufacturing a liquid crystal display includes simultaneously forming a gate electrode and a gate bus line on a transparent dielectric substrate, simultaneously forming a channel layer, an ohmic contact layer, and source/drain electrodes by forming a gate insulation film, an amorphous silicon film, a doped amorphous silicon film, and a metal film on the transparent dielectric substrate on which the gate electrode and the gate bus line are formed and etching the metal film, the amorphous silicon film, and the doped amorphous silicon film, and forming a pixel electrode by forming a protective film and a transparent metal film on the transparent dielectric substrate upon which the source/drain electrodes are formed and finely etching the transparent metal film through a lift-off process using a stripper solution.

Abstract: A memory cell device of the type that includes a memory material switchable between electrical property states by application of energy, situated between first and second (“bottom” and “top”) electrodes has a top electrode including a larger body portion and a stem portion. The memory material is disposed as a layer over a bottom electrode layer, and a base of the stem portion of the top electrode is in electrical contact with a small area of the surface of the memory material. Methods for making the memory cell are described.

Abstract: A method for forming through-wafer interconnects (TWI) in a substrate of a thickness in excess of that of a semiconductor die such as a semiconductor wafer. Blind holes are formed from the active surface, sidewalls thereof are passivated and coated with a solder-wetting material. A vent hole is then formed from the opposite surface (e.g., wafer back side) to intersect the blind hole. The blind hole is solder filled, followed by back thinning of the vent hole portion of the wafer to a final substrate thickness to expose the solder and solder-wetting material at both the active surface and the thinned back side. A metal layer such as nickel, having a glass transition temperature greater than that of the solder, may be plated to form a dam structure covering one or both ends of the TWI including the solder and solder-wetting material to prevent leakage of molten solder from the TWI during high temperature excursions.

Abstract: An adhesive sheet for laser dicing is used for dicing a workpiece into individual chips by light absorption ablation of laser beam and has at least an adhesive layer on one side of a base material which has a surface opposite to the adhesive layer having no convex parts of width (W) of 20 mm or less and height (h) of 1 ?m or more, or no concave parts of width (W) of 20 mm or less and depth (d) of 1 ?m or more.

Abstract: A dual damascene process is disclosed. A substrate having a base dielectric layer, a lower wiring layer inlaid in the base dielectric layer, and a cap layer capping the lower wiring layer is provided. A dielectric layer is deposited on the cap layer. A silicon oxide layer is deposited on the dielectric layer. A metal hard mask is formed on the silicon oxide layer. A trench opening is etched into the metal hard mask. A partial via feature is etched into the dielectric layer within the trench opening. The trench opening and the partial via feature are etch transferred into the dielectric layer, thereby forming a dual damascene opening, which exposes a portion of the cap layer. A liner removal step is performed to selectively remove the exposed cap layer from the dual damascene opening by employing CF4/NF3 plasma.

Abstract: The method of manufacturing a semiconductor device has the steps of: etching a semiconductor substrate to form an isolation trench by using as a mask a pattern including a first silicon nitride film and having a window; depositing a second silicon nitride film covering an inner surface of the isolation trench; forming a first silicon oxide film burying the isolation trench; etching and removing the first silicon oxide film in an upper region of the isolation trench; etching and removing the exposed second silicon nitride film; chemical-mechanical-polishing the second silicon oxide film; and etching and removing the exposed first silicon nitride film.

Abstract: A semiconductor device comprises a substrate, a patterned metal conductor layer over the substrate, and a passivation layer. The passivation layer may comprise a UV blocking, protection layer, over at least a portion of the substrate and patterned metal conductor layers, and a separation layer between the patterned metal conductor layer and the UV protection layer. The passivation layer may also comprise a gap-filling, hydrogen-blocking layer over the substrate, the patterned metal conductor layer and any UV protection layer.

Abstract: A method of forming a metal silicate film on a silicon substrate in a processing container is disclosed that includes the steps of (a) forming a base oxide film on the silicon substrate by feeding an oxidation gas into the processing container; and (b) forming the metal silicate film on the base oxide film by continuing to feed the oxidation gas and by feeding a first gaseous phase material formed of an amidic organic hafnium compound and a second gaseous phase material formed of a silicon-containing material into the processing container.

Abstract: A power electronic device is integrated on a semiconductor substrate of a first type of conductivity. The device includes a plurality of elemental units, and each elemental unit includes a body region of a second type of conductivity which is realized on a semiconductor layer of the first type of conductivity formed on the semiconductor substrate, and a column region of the first type of conductivity which is realized in said semiconductor layer below the body region. The semiconductor layer includes multiple semiconductor layers which overlap each other. The resistivity of each layer is different from that of the other layers. The column region includes a plurality of doped sub-regions, each realized in one of the semiconductor layers. The amount of charge of each doped sub-region balances the amount of charge of the corresponding semiconductor layer in which each doped sub-region is realized.

Abstract: A manufacturing method for a thin film transistor (TFT) is provided. In the manufactured TFT, after a source structure, a drain structure and a channel structure are formed, a first photoresist layer is not removed and a second photoresist is formed on the first photoresist layer through which a semiconductor structure is formed. Further, n-type amorphous silicon, poly silicon or an organic metallic compound is used in replace of the conventional metal to form the source and drain structures so as to reduce step number of manufacturing for the TFT.