Abstract: A CMOSFET in which a p-type gate electrode and an n-type gate electrode are formed on a silicon substrate. The p-type gate electrode includes, in order, a p-type polycrystalline silicon layer and a tungsten silicide layer. The n-type gate electrode includes, in order, an n-type polycrystaline silicon layer and a tungsten silicide layer. A carbon-containing polycrystalline silicon layer, which is an impurity thermal diffusion prevention layer to suppress the interdiffusion of impurities, is provided between the p-type polycrystalline silicon layer and the tungsten silicide layer.

Abstract: Gate stacks with sidewall spacers having improved profiles to suppress or eliminate void formation between the gate stacks during gap-filling is disclosed, along with a method of forming the gate structures over a semiconductor substrate. A gate dielectric layer is formed on a semiconductor substrate. Then, a gate stack 24 having a sidewall is formed over the gate dielectric layer. The gate stack 24 comprises a conductive layer 28 and a capping nitride layer 30 overlying the conductive layer 28. A liner 32 is selectively deposited over the gate stack 24 such that the liner 32 is deposited on the capping nitride layer 30 at a rate lower than the rate of deposition on the conductive layer 28. Thus, the liner 32 is substantially thinner on the capping nitride layer 30 than on the conductive layer 28. A nitride spacer is formed over 34 the liner 32. A PMD layer is formed over the resultant structure, filling the gaps between adjacent gate stacks and substantially free of voids.

Abstract: The present invention provides a method for manufacturing a semiconductor device comprising steps of: bonding one semiconductor chip to each of multiple mounting portions of a substrate; covering the semiconductor chips bonded to the mounting portions with a common resin layer; bringing the substrate into contact with the resin layer and gluing the substrate to an adhesive sheet; and performing dicing and measurement for the semiconductor chips that are glued to the adhesive sheet.

Abstract: The present invention provides a method for manufacturing a thin film transistor panel. At first, a gate line is formed on an insulating substrate. A gate insulating layer and a semiconductor layer which comprises an impurity-doped layer are deposited over the gate line sequentially. The semiconductor layer is patterned. A conductive pattern layer with a source electrode, a channel region and a drain electrode is formed over the patterned semiconductor layer. The impurity-doped layer is exposed at the channel region. Then, the impurity-doped layer at the channel region is insulated.

Abstract: A method of making a microelectronic assembly comprises providing a first side assembly juxtaposed with a second side assembly and a first resilient element disposed therebetween. Leads extend between the first side assembly and the second side assembly. A compressive force is applied to the juxtaposed assemblies so as to compress the first resilient element and the compressive force is at least partially released so as to allow the first resilient element to expand, thereby moving one or both of the first side assembly and the second side assembly to deform the leads.

Abstract: The specification describes interconnection techniques for interconnecting large arrays of micromechanical devices on a silicon platform. The problem of interconnection congestion is overcome by routing the interconnections through the substrate. The through interconnections are made by etching vias through the substrate by RIE, oxidizing the via sidewalls, and filling the vias with polysilicon.

Abstract: Improved processes for depositing dielectric layers by HDP (High Density Plasma) CVD (Chemical Vapor Deposition) are described. One method controls the RF power applied to the side source RF power to be less than about 2500 Watts during dielectric deposition. A second method controls the thickness of the HDP-CVD deposited dielectric layer to be less than between about 2000 and 3000 Angstroms. These methods of HDP-CVD deposition of dielectric layers result in elimination or suppression of plasma induced damage to MOSFET devices and improved gate oxide integrity of MOSFET devices following deposition of dielectric layers by HDP-CVD.

Abstract: A method of fabricating a semiconductor apparatus includes forming a base member and a conductive layer on a first surface of a semiconductor substrate. The conductive layer has an extended portion that extends onto the base member. A first surface of the semiconductor substrate is placed to face a connection substrate, the extended portion of the conductive layer is then connected to the connection substrate, and a seal member is supplied in a space between the semiconductor substrate and the connection substrate.

Abstract: A microelectronic substrate and method for manufacture. In one embodiment, the microelectronic substrate includes a body having a first surface, a second surface facing a direction opposite from the first surface, and a plurality of voids in the body between the first and second surfaces. The voids can extend from the first surface to a separation region beneath the first surface. At least one operable microelectronic device is formed at and/or proximate to the first surface of the substrate material, and then a first stratum of the microelectronic substrate above the separation region is separated from a second stratum of the microelectronic substrate below the separation region. The first stratum of the microelectronic substrate can be further separated into discrete microelectronic dies before the first stratum is separated from the second stratum. In one aspect of this embodiment, the substrate can support a film and microelectronic devices can be formed in the film and/or in the substrate.

Abstract: A semiconductor manufacturing method and a semiconductor manufacturing apparatus capable of manufacturing semiconductor devices without the need of specifically determining an optimal configuration of a gas mixing chamber (6) with care or elaboration. A ruthenium raw gas feed pipe (4) and an oxygen-containing gas feed pipe (5) are merged with each other at a location upstream of a gas mixing chamber (6), so that the ruthenium raw gas and the gas containing oxygen atoms (e.g., oxygen (O2), ozone (O3), etc.) are mixed with each other prior to entering the gas mixing chamber (6).

Abstract: According to the present invention, a semiconductor device to use a SOI substrate performing insulation by a LOCOS method in which an oxide resistivety film provided on a silicon layer is used, includes steps of: implanting impurity in a LOCOS edge which is a silicon layer under bird's beak of the field oxide film with the oxide resistant film as a mask after a field oxide film is formed and forming a high density impurity area having impurity density higher than impurity density of an impurity diffusion layer formed on the silicon layer, and removing a pad oxide film after a heat treatment is performed for the field oxide film after the high density impurity area is formed. Therefore, a method of manufacturing the semiconductor device at a lower cost to suppress occurrence of hump and to prevent a MOSFET characteristic from deteriorating can be provided.

Abstract: A method of manufacturing a semiconductor device which reduces the number of impurity implantations. A buffer film for reducing a quantity of an impurity implantation is provided adjacent to an MIS gate structure over a surface of a semiconductor substrate, and an impurity implantation is carried out over the semiconductor substrate, through the buffer film in a first predetermined region in which the buffer film is provided and directly in a second predetermined region of the substrate. An impurity concentration is reduced in a the first predetermined region in which the impurity implantation is carried out through the buffer film, while the impurity concentration is increased in the second predetermined region in which the buffer film is not provided. Accordingly, a plurality of regions having different impurity concentrations are formed as a source/drain of an MISFET by a one-time impurity implantation. Consequently, the number of the impurity implantations is reduced.

Abstract: To fabricate contacts on a wafer backside, openings (124) are formed in the face side of the wafer (104). A dielectric layer (140) and some contact material (150), e.g. metal, are deposited into the openings. Then the backside is etched until the contacts (150C) are exposed and protrude out. The protruding portion of each contact has an outer sidewall (150V). At least a portion of the sidewall is vertical or sloped outwards with respect to the opening when the contact is traced down. The contact is soldered to an another structure (410), e.g. a die or a PCB. The solder (420) reaches and at least partially covers the sidewall portion which is vertical or sloped outwards. The strength of the solder bond is improved as a result. The dielectric layer protrudes around each contact. The protruding portion (140P) of the dielectric becomes gradually thinner around each contact in the downward direction.

Abstract: In a method for manufacturing a semiconductor device, a semiconductor substrate is provided. On the substrate, conductors spaced apart from one another are formed. Then, an insulating layer is formed on the conductors and the substrate. The insulating layer is formed by a chemical vapor deposition using tetramethylcyclotetrasiloxane as a source gas and oxygen as an adjunction gas. The chemical vapor deposition is performed while the substrate is irradiated by vacuum ultraviolet light. Finally, a part of the insulating layer is removed in a substantial uniform way to form a contact hole through the insulating film.

Abstract: A process of manufacturing a semiconductor device including a buried channel field effect transistor comprising, for realizing said field effect transistor, steps of forming a stacked arrangement of semiconductor layers on a substrate including an active layer (3), forming a recess in said active layer, referred to as gate recess (A4), for constituting a channel between source and drain electrodes, and forming a submicronic gate electrode (G) which is in contact with the active layer (3) in said gate recess (A4), wherein: the gate recess width (Wri) and the gate length (LGo) are manufactured with predetermined respective values, in order that the access region, defined between the gate (G) and the gate recess edge (31), has an access region width (2&Dgr;o), derived from said predetermined values (Wri, LGo), which is sufficiently small to permit the transistor of functioning according to saturation current characteristics having continuous slopes.

Abstract: The present invention provides a method for fabricating low-resistance, sub-0.1 &mgr;m channel T-gate MOSFETs that do not exhibit any poly depletion problems. The inventive method employs a damascene-gate processing step and a chemical oxide removal etch to fabricate such MOSFETs. The chemical oxide removal may be performed in a vapor containing HF and NH3 or a plasma containing HF and NH3.

Abstract: Method for forming a Schottky contact in a semiconductor device includes a step of preparing an n type GaN group compound semiconductor layer, such as AlxGa1-xN and InxGa1-xN. At least one metal layer including a ruthenium component layer is formed on the n type GaN group compound semiconductor layer as a rectifying junction metal. The rectifying junction metal may be used as a gate of a field effect transistor, or an electrode of a Schottky diode. The ruthenium oxide has a low cost, is stable to heat and chemical, and has excellent electric characteristics. The application of the ruthenium oxide to the rectifying junction metal enhances performances, such as UV ray detection, of electronic devices and optical devices operable at an elevated temperature.

Abstract: An integrated circuit wafer element and an improved method for bonding the same to produce a stacked integrated circuit. Plugs that extend from one surface of the wafer into the wafer are used to provide vertical connections and to bond the wafers together. A stacked integrated circuit is constructed by bonding the front side of a new wafer to a wafer in the stack and then thinning the backside of the new wafer to a thickness that leaves a portion of the plugs extending above the surface of the backside of the thinned wafer. The elevated plug ends can then be used to bond another wafer by bonding to pads on the front side of that wafer. The mating bonding pads can include depressed regions that mate to the elevated plug ends.

Abstract: A GaN-based LED element 1 having a double heterostructure, which includes a GaN layer and the like and is formed on a sapphire substrate, is mounted face-down on a Si diode element 2 formed in a silicon substrate. Electrical connections are provided via Au microbumps 11 and 12 between a p-side electrode 5 of the GaN-based LED element 1 and an n-side electrode 8 of the Si diode element 2 and between an n-side electrode 6 of the GaN-based LED element 1 and a p-side electrode 7 of the Si diode element 2. The Si diode element 2 functions to protect the LED element 1 from an electrostatic destruction. The Si diode element 2 has a backside electrode 9 connected to a leadframe 13a. The p-side electrode 7 of the Si diode element 2 has a bonding pad portion 10 connected to a leadframe 13b via an Au wire 17.

Abstract: Described is a method for fabricating a semiconductor device having an FET of a trench-gate structure obtained by disposing a conductive layer, which will be a gate, in a trench extended in the main surface of a semiconductor substrate, wherein the upper surface of the trench-gate conductive layer is formed equal to or higher than the main surface of the semiconductor substrate. In addition, the conductive layer of the trench gate is formed to have a substantially flat or concave upper surface and the upper surface is formed equal to or higher than the main surface of the semiconductor substrate. Moreover, after etching of the semiconductor substrate to form the upper surface of the conductive layer of the trench gate equal to or higher than the main surface of the semiconductor substrate, a channel region and a source region are formed by ion implantation. The semiconductor device thus fabricated according to the present invention is free from occurrence of a source offset.