Abstract: Stereolithographically fabricated conductive elements and semiconductor device components and assemblies including these conductive elements. The conductive elements may have multiple superimposed, contiguous, mutually adhered layers of conductive material. In semiconductor device assemblies, the stereolithographically fabricated conductive elements may be used to electrically connect different components to one another. The conductive elements may also be used as the conductive traces and vias on circuit boards. The stereolithographically fabricated conductive elements are also useful for rerouting the bond pad locations of a semiconductor die, such as in chip-scale packages.

Abstract: A semiconductor package assembly 10 has an intervening package (12) that may be connected to a first package (14) from a first substrate (20) on a first side of the package (12) and to a second package (13) from a second substrate (53) on a second, opposing side of the package (12). Electrical contact to a semiconductor die (32) is made from the first side by wire bonding to wire bond posts (26) and by balls (46, 48) from the second side. Electrical contact from one side of the intervening package (12) to the other may be made by bypassing the die. Electrical contact on either side of the intervening package may be made both within and outside the footprint of the semiconductor die (32).

Abstract: A semiconductor device includes a first semiconductor chip provided with a first electrode on a first main surface and a second semiconductor chip provided with a second electrode on a second main surface. The first and the second semiconductor chips are integrated so that the first and second main surfaces are opposed to one another and the first and second electrodes are electrically connected. The second semiconductor chip is polished from the opposite side of the second main surface so that the second semiconductor chip has a thickness smaller than the thickness of the first semiconductor chip.

Abstract: An improved silicon building block is disclosed. In an embodiment, the silicon building block has at least two vias through it. The silicon building block is doped and the vias filled with a first material, and, optionally, selected ones of the vias filled instead with a second material. In an alternative embodiment, regions of the silicon building block have metal deposited on them.

Abstract: Disclosed are a chip scale package and a method of fabricating the chip scale package. The chip scale package comprises an insulating layer formed on the upper surface of a chip provided with a plurality of terminals on its one surface, a plurality of conductive layers formed on the insulating layer and spaced from each other by a designated distance so as to be connected to each of a plurality of the terminals, and a plurality of electrode surfaces formed on each of the upper surfaces of a plurality of the conductive layers. The chip scale package is miniaturized in the whole package size. Further, the method of fabricating the chip scale package does not require a wire-bonding step or a via hole forming step, thereby simplifying the fabrication process of the chip scale package and improving the reliability of the chip scale package.

Abstract: A method and structure for solderably coupling a semiconductor chip to a substrate, with an underfill between the chip and the substrate. In forming the structure, underfill material is dispensed upon a conductive pad on the substrate. The underfill material comprises a resin and a filler. The filler density is less than the resin density. The chip is moved toward the substrate and into the underfill until a solder member coupled to the chip is proximate the conductive pad. The structure is heated, resulting in soldering the solder member to the conductive pad and in curing the underfill. Filler particles move through the resin and toward the chip, resulting in an increased filler concentration near the solder member, and a reduced underfill coefficient of thermal expansion (CTE) near the solder member that is close to the CTE of the solder member.

Abstract: A frame-shaped holding frame which has a small thermal expansion coefficient is used. When a complex member in which a metal material is impregnated in a ceramic material, which has a smaller thermal expansion coefficient than 10 ppm/° C., is used, a warp and a wrinkle are greatly decreased. In particular, in the case of a material with a thermal expansion coefficient of 6.5 ppm/° C. or smaller, the warp and the wrinkle are not caused. When the flexible substrate is adhered to the holding frame by an adhesive, an adhesion area may be obtained so that a sufficient strength is kept. Also, since the flexible substrate is adhered onto the upper surface of the holding frame, the thickness of the holding frame is independent on fixing of the substrate. The thickness may be set so that a mechanical strength is kept and the substrate is smoothly transferred.

Abstract: A method of making a semiconductor device comprises the steps of coating a first face of an insulative board (1) with a thermally plastic resin (2), bonding at least one semiconductor element (3) onto the thermally plastic resin (2), piercing the thermally plastic resin (2) and the insulative board (1) with at least one capillary that holds a metal wire (4), forming a metal ball (4b) and pulling out the capillary from the insulative board (1) and the thermally plastic resin (2), pressing the capillary onto an electrode (3a) of the semiconductor element (3) and cutting off an extra wire, and attaching at least one metal bump (6) to the second face of the insulative board (1) so as to be connected to the metal ball (4a).

Abstract: A molding machine for encapsulating electronic devices mounted on one side of a substrate, and having a ball-grid array, pin-grid array, or land-grid array on the opposite side, has a two member biased floating plate apparatus to compensate for variations in substrate thickness, and a gas collection/venting apparatus for relieving gases emitted from the non-encapsulated underside of the substrate.

Abstract: A method of fabricating an integrated circuit sensor package. The method comprises the steps of: 1) mounting a substrate on a first mold block, the substrate comprising a substantially planar material having a first substrate surface and a second substrate surface that contacts a mounting surface of the first mold block; 2) placing an adhesive on the first substrate surface; 3) placing an integrated circuit sensor on the adhesive; and 4) pressing a second mold block against the first substrate surface. The second mold block comprising a cavity portion for receiving the integrated circuit sensor, a contact surface surrounding the cavity portion, and a compliant layer mounted with the cavity portion. Pressing the second mold block against the first substrate surface causes the contact surface to form with the first substrate surface a seal surrounding the integrated circuit sensor.

Abstract: In a component assembly and method for producing the same, the component assembly includes at least one component arranged on a support subframe, e.g., a printed circuit board. An insulator enclosing the component and including two isolating superimposed layers is also arranged on the support substrate. A sealing mass covering the component is arranged inside the insulator. The two or more isolating layers are made from the same isolating material and connected at the contact area.

Abstract: A method of producing an antifuse, comprises the steps of: depositing a layer of undoped or lightly doped polysilicon on a layer of silicon dioxide on a semiconductor wafer; doping one region of the polysilicon P+; doping another region of the polysilicon N+, leaving an undoped or lightly doped region between the P+ and N+ regions; and forming electrical connections to the P+ and N+ regions.

Abstract: An uppermost interlayer isolation film is provided on a semiconductor substrate. An uppermost wire is provided on the uppermost interlayer isolation film. A silicon oxide film is provided to cover the upper surface and the side wall of the uppermost wire. A nitride film is provided on the uppermost interlayer isolation film to cover the uppermost wire through the silicon oxide film. A polyimide film is provided on the nitride film. A portion of the uppermost interlayer isolation film other than a portion located under the uppermost wire is downwardly scooped. The nitride film covers the scooped portion of the uppermost interlayer isolation film. According to the present invention, a semiconductor device improved to be capable of improving coverage of a silicon nitride passivation film is obtained.

Abstract: A method for manufacturing sidewall contacts for a chalcogenide memory device is disclosed. A first conductive layer is initially deposited on top of a first oxide layer. The first conductive layer is then patterned and etched using well-known processes. Next, a second oxide layer is deposited on top of the first conductive layer and the first oxide layer. An opening is then etched into at least the first oxide layer such that a portion of the first conductive layer is exposed within the opening. The exposed portion of the first conductive layer is then removed from the opening such that the first conductive layer is flush with an inner surface or sidewall of the opening. After depositing a chalcogenide layer on top of the second oxide layer, filling the opening with chalcogenide, a second conductive layer is deposited on top of the chalcogenide layer.

Abstract: A thin film transistor with multiple gates using an MILC process which is capable of materializing multiple gates without increasing dimensions and a method thereof. The thin film transistor has a semiconductor layer which is formed on a insulating substrate in a zigzag shape; and a gate electrode which is equipped with one or more slots intersecting with the semiconductor layer, the semiconductor layer includes two or more body parts intersecting with the gate electrode; and one or more connection parts connecting each neighboring body part, wherein a part overlapping the semiconductor layer in the gate electrode acts as a multiple gate, and MILC surfaces are formed at a part which does not intersect with the gate electrode in the semiconductor layer.

Abstract: A method of forming a gate in a FinFET device includes forming a fin on an insulating layer, forming source/drain regions and forming a gate oxide on the fin. The method also includes depositing a gate material over the insulating layer and the fin, depositing a barrier layer over the gate material and depositing a bottom anti-reflective coating (BARC) layer over the barrier layer. The method further includes forming a gate mask over the BARC layer, etching the BARC layer, where the etching terminates on the barrier layer, and etching the gate material to form the gate.

Abstract: A thin-film transistor is formed by a polycrystalline silicon film having a thin-film part and a thick-film part, the thin-film part minimally being used as a channel part. The polycrystalline silicon film is formed by laser annealing with an energy density that completely melts the thin-film part but does not completely melt the thick-film part. Because large coarse crystal grains growing from the boundary between the thin-film part and the thick-film part form the channel part, it is possible to use a conventional laser annealing apparatus to easily achieve high carrier mobility and low leakage current and the like.

Abstract: The present invention discloses a thin film transistor and a process for forming thereof by a high anisotropy etching process. A thin film transistor according to the present invention comprises a transistor element including a gate electrode, a gate insulating layer, a semiconductor layer, and source and drain electrodes; a passivation layer being deposited on the layers and having first openings for contact holes; and an interlayer insulator extending along with the passivation layer and having second openings for the contact holes, the first openings and the second openings being aligned each other over the substrate, wherein an electrical conductive layer is deposited on an inner wall of the contact hole and the inner wall is formed by the first and second openings tapered smoothly and continuously through an anisotropic etching process.

Abstract: A semiconductor device having CMOS circuits formed on a glass substrate. The CMOS circuits are composed of TFTs. Lightly doped regions are formed only in the N-channel TFTs. When P-channel TFTs are formed, the conductivity type of the lightly doped regions is converted by a boron ion implant. Each CMOS circuit consists of an N-channel TFT having the lightly doped regions and a P-channel TFT having no lightly doped regions.

Abstract: In a bottom gate-type thin-film transistor manufacturing method, after ion doping, an ion stopper is removed. The ion stopper does not remain in the interlayer insulating film lying immediately above the gate electrode. The thin-film transistor has such a structure that no ion stopper, and the interlayer insulating layer is in direct contact with at least the channel region of the semiconductor layer. The impurity concentration in the vicinity of the interface between the interlayer insulating film and the semiconductor layer 4 is 1018 atoms/cc or less. This structure can prevent the back channel phenomenon and reduce variations in characteristic resulting from variations in manufacturing.

Abstract: Subjected to obtain a crystalline TFT which simultaneously prevents increase of OFF current and deterioration of ON current. A gate electrode of a crystalline TFT is comprised of a first gate electrode and a second gate electrode formed in contact with the first gate electrode and a gate insulating film. LDD region is formed by using the first gate electrode as a mask, and a source region and a drain region are formed by using the second gate electrode as a mask. By removing a portion of the second gate electrode, a structure in which a region where LDD region and the second gate electrode overlap with a gate insulating film interposed therebetween, and a region where LDD region and the second gate electrode do not overlap, is obtained.

Abstract: In accordance with the objectives of the invention a new method is provided for the creation of a layer of a Resistance Protective Oxide (RPO) layer. A layer of ONO is deposited that is to function as the layer of RPO. The deposited layer of ONO is patterned and wet etched, removing the upper or first layer of silicon dioxide. The patterned and etch upper of first layer of silicon dioxide is used as a hardmask to remove the central layer of silicon nitride applying a wet etch. A wet etch is then applied to remove the remaining lower of second layer of silicon dioxide, completing the patterning of the layer of RPO.

Abstract: A method of fabricating an integrated circuit device comprises forming a refractory metal layer on a silicon-containing substrate, processing the refractory metal layer to form an amorphous metal silicide layer, and depositing an insulating material on the amorphous metal silicide layer. The insulating material is deposited at a temperature that maintains at least a portion of the amorphous metal silicide layer in an amorphous state, to form a capping structure that contains the amorphous metal silicide layer. The method further includes crystallizing the contained amorphous metal silicide layer, and forming an etching stop layer on the capping structure.

Abstract: Segmented power transistors and fabrication methods are disclosed in which transistor segments are spaced from one another to facilitate thermal diffusion, and in which other electrical devices can be formed in the spaces between transistor segments.

Abstract: The present invention provides FinFETs on the same substrate utilizing various crystal planes for FET current channels in order to optimize mobility and/or to reduce mobility. An embodiment of the present invention provides a substrate having a surface oriented on a first crystal plane that enables subsequent crystal planes for channels to be utilized. A first transistor is also provided having a first fin body. The first fin body has a sidewall forming a first channel, the sidewall oriented on a second crystal plane to provide a first carrier mobility. A second transistor is also provided having a second fin body. The second fin body has a sidewall forming a second channel, the sidewall oriented on a third crystal plane to provide a second carrier mobility that is different from the first carrier mobility.

Abstract: The invention provides integrated semiconductor devices that are formed upon an SOI substrate having different crystal orientations that provide optimal performance for a specific device. Specifically, an integrated semiconductor structure including at least an SOI substrate having a top semiconductor layer of a first crystallographic orientation and a semiconductor material of a second crystallographic orientation, wherein the semiconductor material is substantially coplanar and of substantially the same thickness as that of the top semiconductor layer and the first crystallographic orientation is different from the second crystallographic orientation is provided. The SOI substrate is formed by forming an opening into a structure that includes at least a first semiconductor layer and a second semiconductor layer that have different crystal orientations. The opening extends to the first semiconductor layer.

Abstract: A semiconductor device in which an NMOSFET and a PMOSFET are formed in a silicon substrate, wherein the gate electrodes of NMOSFET and PMOSFET are made of metallic materials, an Si—Ge layer is formed in at least part of the surface regions including the respective channel layers of the NMOSFET and PMOSFET, and the concentration of Ge in the channel layer of the NMOSFET is lower than the concentration of Ge in the channel layer of the PMOSFET.

Abstract: A semiconductor device, comprises a first MOS transistor including a gate electrode having a gate width Le and a first gate post oxide film formed on the circumferential side wall of the gate electrode, and a second MOS transistor including a gate electrode having a gate width Li smaller than the gate width Le of the gate electrode of the first MOS transistor and a second gate post oxide film formed on a circumferential side wall of the gate electrode and having a portion differing in thickness from the first gate post oxide film.

Abstract: In a DRAM-incorporated semiconductor device (SOC) which has a DRAM section and a logic section being formed on one and the same substrate, with the object of providing, with low cost, a SOC having necessary and sufficient characteristics in the DRAM section, while attaining higher-speed performance of the whole elements, silicide is formed at least on all the surfaces of the source-drain regions (10) and the gate surfaces (6) of transistors in the DRAM section and the logic section, concurrently in one and the same step.

Abstract: Silicon on insulator (SOI) field effect transistors (FET) with a shared body contact, a SRAM cell and array including the SOI FETs and the method of forming the SOI FETs. The SRAM cell has a hybrid SOI/bulk structure wherein the source/drain diffusions do not penetrate to the underlying insulator layer, resulting in a FET in the surface of an SOI layer with a body or substrate contact formed at a shared contact. FETs are formed on SOI silicon islands located on a BOX layer and isolated by shallow trench isolation (STI). NFET islands in the SRAM cells include a body contact to a P-type diffusion in the NFET island. Each NFET in the SRAM cells include at least one shallow source/drain diffusion that is shallower than the island thickness. A path remains under the shallow diffusions between NFET channels and the body contact. The P-type body contact diffusion is a deep diffusion, the full thickness of the island. Bit line diffusions shared by SRAM cells on adjacent wordlines may be deep diffusions.

Abstract: The present invention relates to a method of manufacturing a semiconductor device. The present invention sequentially forms a DCS HTO film and a nitride film on the entire structure after a self align source etch process so that so that they can serve as a spacer for compensating for the sidewall of a gate structure damaged upon the self align source etch process. Therefore, the present invention can increase the integrity capability of data by preventing movement of charges and holes between a floating gate electrode and peripheral circuits and can mitigate a stress due to the nitride film in a subsequent process. Further, the present invention can prevent increase of the thickness of the dielectric film between a first polysilicon silicon layer and a second polysilicon layer in a subsequent annealing process and can secure the uniformity of a screen oxide film to make uniform the depth of the junction upon a high concentration ion implantation process.

Abstract: A manufacturing method of this invention has an ion-implantation process for threshold voltage adjustment of an MOS transistor, including a process to form a first well of an opposite conductivity type in a substrate of one conductivity type, to form a second well of the opposite conductivity type having higher impurity concentration than that in the first well, under a region where a thin gate insulation film is formed, to form gate insulation films on the first well and the second well, each having a different thickness, to ion-implant first impurities of the one conductivity type into the wells of the opposite conductivity type under the condition that the impurities penetrate the gate insulation films of different thicknesses and to ion-implant second impurities of the one conductivity type into the second well of the opposite conductivity type under the condition that the second impurities penetrate the thin gate insulation film but do not penetrate the thick gate insulation film.

Abstract: A method for forming a dual gate includes providing a semiconductor substrate that has a first region of a first conductivity type and a second region of a second conductivity type. A gate insulating layer is formed on the semiconductor substrate. An initial metal nitride layer is formed on the gate insulating layer, opposite to the semiconductor substrate. Nitrogen ions are implanted into the initial metal nitride layer in the second transistor region to form a nitrogen-rich metal nitride layer. The initial metal nitride layer is patterned to form a first gate electrode in the first region. The nitrogen-rich metal nitride layer is patterned to form a second gate electrode in the second region. The work function of the nitrogen-rich metal nitride layer is higher than that of the initial metal nitride layer.

Abstract: A method of forming and operating a memory storage and retrieval device containing (a) an electrically conductive first electrode; (b) an electrically conductive second electrode; (c) a layer stack intermediate the first and second electrodes containing (d) at least one active layer with variable electrical conductivity; and (e) at least one passive layer containing a source material for varying the electrical conductivity of the at least one active layer upon application of an electrical potential difference between the first and second electrodes.

Abstract: A DRAM device having improved charge storage capabilities and methods for providing the same. The device includes an array portion having a plurality of memory cells extending from a semiconductor substrate. Each cell includes a storage element for storing a quantity of charge indicative of the state of the memory cell and a valve element that inhibits the quantity of charge from changing during quiescent periods. The storage elements are disposed adjacent a plurality of storage regions of the substrate and the valve elements are disposed adjacent a plurality of valve regions of the substrate. A plurality of dopant atoms are selectively implanted into the array portion so as to increase a threshold voltage which is required to develop a conducting channel through the valve region. The dopant atoms are disposed mainly throughout the valve regions of the substrate and are substantially absent from the storage regions.

Abstract: A memory merged logic (MML) semiconductor device of NMOS and PMOS dual gate structure including embedded memory of a self-aligned structure and a method of manufacturing the same, wherein in the MML semiconductor device, the memory area including n-type metal oxide semiconductor (NMOS) and p-type metal oxide semiconductor (PMOS) are integrated together, wherein the memory area includes a polycide gate electrode, a hard mask pattern comprised of nitride materials which is formed on the polycide gate electrode, a spacer comprised of nitride materials formed along the sidewall of the polycide gate electrode, and a self-aligned contact which is formed between the adjacent spacers and electrically connected with an impurity implantation region formed on a semiconductor substrate. The logic area includes salicided NMOS and PMOS gate electrodes and salicided source/drain regions, and the height of the polycide gate electrode is smaller than the height of the NMOS and PMOS gate electrodes.

Abstract: Provided is a method of manufacturing a semiconductor device capable of effectively removing impurity product attached to a semiconductor film while suppressing coming off of, for example, hemispherical grains formed on a semiconductor film containing an impurity. Spherical or hemispherical grains are formed on the surface of an amorphous silicon film containing phosphorus which forms a bottom electrode of a capacitor. In order to suppress depletion of the bottom electrode, annealing is performed in PH3 atmosphere so as to diffuse phosphorus to the grains. Cleaning is performed using hot water (deionized water) in order to remove the impurity product attached onto the surface of the bottom electrode by annealing. A native oxide film formed on the surface of the bottom electrode is removed by cleaning using a mixed solution of hydrofluoric acid and water. A dielectric film and a top electrode are formed in order so as to cover the surface of the bottom electrode. Thereby, a cylindrical capacitor is fabricated.

Abstract: A stacked gate flash memory device and method of fabricating the same. A cell of the stacked gate flash memory device in accordance with the invention is disposed in a cell trench within a substrate and source and drain regions are formed in the same substrate side of the adjacent isolation trenches. Thus, the stacked gate flash memory device of the invention can achieve high integration of memory cells.

Abstract: The manufacturing method of the invention is applied to production of a semiconductor device including a memory area and a logic circuit area. The method first provides a semiconductor substrate, which has a conductive layer to make a word gate of the non-volatile memory device, a stopper layer formed above the conductive layer, and control gates formed as side walls on both side faces of the conductive layer via an ONO membrane, which are all located above a semiconductor layer in the memory area, as well as a gate electrode of an insulated gate field effect transistor formed above a semiconductor layer in the logic circuit area. The method subsequently forms an insulating layer over whole surface of the memory area and the logic circuit area on the semiconductor substrate, and carries out anisotropic etching of an upper portion in a part of the insulating layer.

Abstract: A flash memory array having improved core field isolation in select gate regions via shallow trench isolation and field isolation implant after liner oxidation is disclosed. The flash memory array includes a core area and a periphery area, wherein the core area further includes a select gate region. The method of fabricating the flash memory array begins by patterning a layer of nitride over a substrate in active device locations. After the nitride is patterned, a silicon trench etch is performed to form trenches. After forming the trenches, a layer of liner oxide is grown in the trenches. Then, a field implant is performed in both the core area and periphery area to provide field isolation regions for the flash memory array with. Thereafter, poly1 is patterned in the core area to form floating gate and select word-lines.

Abstract: A high-voltage transistor with a low specific on-state resistance and that supports high voltage in the off-state includes one or more source regions disposed adjacent to a multi-layered extended drain structure which comprises extended drift regions separated from field plate members by one or more dielectric layers. The layered structure may be fabricated in a variety of orientations. A MOSFET structure may be incorporated into the device adjacent to the source region, or, alternatively, the MOSFET structure may be omitted to produce a high-voltage transistor structure having a stand-alone drift region. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: The present invention provide a vertical nano-sized transistor using carbon nanotubes capable of achieving high-density integration, that is, tera-bit scale integration, and a manufacturing method thereof, wherein in the vertical nano-sized transistor using carbon nanotubes, holes having diameters of several nanometers are formed in an insulating layer and are spaced at intervals of several nanometers. Carbon nanotubes are vertically aligned in the nano-sized holes by chemical vapor deposition, electrophoresis or mechanical compression to be used as channels. A gate is formed in the vicinity of the carbon nanotubes using an ordinary semiconductor manufacturing method, and then a source and a drain are formed at lower and upper parts of each of the carbon nanotubes thereby fabricating the vertical nano-sized transistor having an electrically switching characteristic.

Abstract: In a semiconductor device and a method of manufacturing the same according to the present invention, a trade-off relationship between threshold values and a diffusion layer leakage is eliminated and it is not necessary to form gate oxide films at more than one stages. Since doses of nitrogen are different from each other between gate electrodes (4A to 4C) of N-channel type MOS transistors (T41 to T43), concentrations of nitrogen in the nitrogen-introduced regions (N1 to N3) are accordingly different from each other. Concentrations of nitrogen in the gate electrodes are progressively lower in the order of expected higher threshold values.

Abstract: A method of forming a silicon-on-insulator (SOI) metal oxide semiconductor field effect transistor (MOSFET) device is provided. The SOI MOSFET device includes a polysilicon back-gate which controls the threshold voltage of a polysilicon-containing front-gate. The back-gate functions as a dynamic threshold voltage control system in the SOI MOSFET device because it is suitable for use during circuit/system active periods and during circuit/system idle periods.

Abstract: A fully depleted SOI FET and methods of formation are disclosed. The FET includes a layer of semiconductor material disposed over an insulating layer, the insulating layer disposed over a semiconductor substrate. A source, a drain and a body disposed between the source and the drain are formed from the layer of semiconductor material. The layer of semiconductor material is etched such that a thickness of the body is less than a thickness of the source and the drain and such that a recess is formed in the layer of semiconductor material over the body. A gate is formed at least in part in the recess. The gate defines a channel in the body and includes a gate electrode spaced apart from the body by a high-K gate dielectric.

Abstract: A semiconductor device has a SALICIDE structure with low leakage currents, while maintaining shallow source and drain regions. A method of manufacturing the semiconductor device includes forming source and drain regions in a first semiconductor layer, the source region and the drain region being separated from each other forming a gate insulating film between the source region and the drain region on the first semiconductor layer and a gate electrode on the gate insulating film, forming a metal silicide layer having a first compound phase on the source region, the drain region and the gate electrode, forming a second semiconductor layer on the metal silicide layer having the first compound phase where the second semiconductor layer is adapted to react with the metal silicide layer, and forming a metal silicide layer having a second compound phase by causing the second semiconductor layer and the metal silicide layer having the first compound phase to selectively react with each other.

Abstract: A method for manufacturing a SiC device embraces (a) depositing a polysilicon film above a SiC substrate; (b) delineating the polysilicon film into required pattern; and (c) annealing the SiC substrate in a water rich ambient to selectively grow a thick localized thermal oxide film above the SiC substrate. At the surface of SiC substrate, source/drain regions and substrate contact region are formed. In the water rich ambient, the H2O partial pressure is so maintained that it is more than 0.95.

Abstract: In one embodiment, a plurality of gate structures including gate electrodes and insulating layers covering the gate electrodes are formed on a semiconductor substrate. Impurity ions at a low dose for forming a source/drain region are implanted into the semiconductor substrate, using the gate structures as a mask. First insulating spacers are formed on the sidewalls of the gate structures and second insulating spacers are formed on the first insulating spacers. Thereafter, impurity ions at a high dose are implanted into the semiconductor substrate, using the first and second insulating spacers as a mask. Then, the second insulating spacers are removed. Therefore, contact resistance and characteristics of the transistors can be improved by adjusting an effective channel length and contact areas.

Abstract: A method for fabricating a bipolar transistor includes: a first step of implanting, along the normal direction of the principle surface of a first-conductive-type semiconductor single crystalline substrates ions of a second-conductive-type first impurity into the semiconductor single crystalline substrate to form a second-conductive-type collector layer; a second step of implanting, along the direction tilted from the normal direction, ions of a second-conductive-type second impurity into the semiconductor single crystalline substrate at a higher injection energy than that in the ion implantation of the first step to form a buried collector layer in a lower portion of the collector layer; and a third step of forming each of a first-conductive-type base layer and a second-conductive-type emitter layer in a predetermined region of a surface portion of the collector layer.

Abstract: The present invention provides a method of manufacturing a bipolar transistor. The method may comprise forming a collector in a semiconductor wafer substrate, forming a base in the collector, implanting an oxide region within said collector and over the base, and forming an emitter over the substrate such that the oxide region is located between the emitter and the base.