Abstract: A method for manufacturing a semiconductor device of the invention comprises the steps of(a) forming a gate insulating film on a surface of a silicon substrate, and a gate electrode on said gate insulating film;(b) forming a self-aligned insulating film at least on a side wall of said gate electrode;(c) forming a self-aligned metal or metal silicide film on a region on which an insulating film is not formed, said region including a source region, a drain region and a diffusion interconnection region which is an extended part of at least one of said source region and said drain region, or prospective regions for said source, drain and diffusion interconnection regions; and(d) forming said source region, said drain region and said diffusion interconnected region which is the extended part of at least one of said source region and said drain region, by doping at least one time said substrate with an impurity which has a conductivity type opposite to a conductivity type of said silicon substrate any time after st

Abstract: A molecular beam epitaxial growth process, for growth of III-V compounds, wherein a substrate is heated approximately to growth temperature before the group III cell is fully heated. That is, for example, to grow gallium arsenide, the arsenic cell would be heated, the arsenic cell's shutter opened, and the substrate heated up to growth temperature (e.g. 600 C), before the gallium cell is heated up. After the gallium cell is heated up, its shutter is opened, and epitaxial growth proceeds.

Abstract: A method of manufacturing a semiconductor device which comprises a step of forming a first groove in a semiconductor layer, a step of filling the first groove with a first insulating film, a step of selectively etching the first insulating film in the first groove to form at least one second groove having a small width, and a step of filling the second groove with a second insulating film to form an isolation layer having a large width and substantially flush with the semiconductor layer.

Abstract: A method of manufacturing a semiconductor device which comprises a step of forming a first groove in a semiconductor layer, a step of filling the first groove with a first insulating film, a step of selectively etching the first insulating film in the first groove to form at least one second groove having a small width, and a step of filling the second groove with a second insulating film to form an isolation layer having a large width and substantially flush with the semiconductor layer.

Abstract: The purity and perfection of a semiconductor is improved by depositing a patterned mask (12) of a material impervious to impurities of the semiconductor on a surface (14) of a blank (10). When a layer (40) of semiconductor is grown on the mask, the semiconductor will first grow from the surface portions exposed by the openings (16) in the mask (12) and will bridge the connecting portions of the mask to form a continuous layer (40) having improved purity, since only the portions (42) overlying the openings (16) are exposed to defects and impurities. The process can be reiterated and the mask translated to further improve the quality of grown layers.

Abstract: A heterojunction bipolar transistor having an n- type epitaxial indium phosphide collector layer grown on a semi-insulating indium phosphide substrate with an n+ buried layer, a p- type indium phosphide base and an epitaxial, n- type boron phosphide wide gap emitter. The p- type base region is formed by ion implantation of magnesium ions into the collector layer. The transistor is applicable to millimeter wave applications due to the high electron mobility in the indium phosphide base. The wide gaps of both the boron phosphide (2.2 eV) and indium phosphide (1.34 eV) permit operation up to 350.degree. C. The transistor is easily processed using metal organic-chemical vapor deposition (MO-CVD) and standard microelectronic techniques.

Abstract: An improved means and method is provided for forming isolated device regions suitable for the construction of control circuits and devices, in the presence of and isolated from other device regions suitable for the construction of bottom-contact power devices. In a preferred embodiment the desired structure is obtained by growing a first epitaxial layer on a semiconductor substrate, providing a patterned mask in which areas of the epitaxial layer are exposed to be etched, etching recesses in the exposed areas to a first depth to leave pedestals beneath the masked areas, and forming a second and third epitaxial layer on the substrate to fill the recesses. The second epitaxial layer is U-shaped and conformally coats the bottom and sides of the recesses. The U-shaped layer acts as the isolation layer separating the first epitaxial layer portions in the pedestals wherein the power devices will be built, from the third epitaxial layer regions which fill in the U, where the control devices will be built.

Abstract: The fabrication of high performance and reliable Buried Channel Field Effect Transistor (BCFET) using Schottky gate junction and heavily doped N layers for the source and drain electrode is described. The BCFET is composed of a semi-insulating substrate in which two N layers for the drain electrodes and one N layer for the source electrode are formed in one of the semi-insulating surface. The N source electrode is centrally located between the two N drain electrodes and all three lie in the same plane. The source and drain electrodes are separated by a thin semi-insulating layer, the length of which can range from 0.5 micron to several micron range, depending on the desired voltage breakdown. A Schottky gate is defined in an active N layer directly above the source N layer. The ohmic contacts for the source and drain N layers are defined several mcirons away from the Schottky junction, resulting in a considerable improvement in device reliability.

Abstract: A method of producing a semiconductor device, including the steps of introducing an impurity of one conductivity type into a semiconductor substrate of an opposite conductivity type having an insulating film pattern formed on a surface thereof, using the insulating film pattern as a mask to form a diffusion layer; and forming a metal film on the diffusion layer by selective vapor growth with a mixture of a metal source gas and a carrier gas used as a feed gas. The vapor growth is carried out such that the distance of entry of the metal film from the edge of the insulating film pattern to the interface between the insulating film pattern and the diffusion layer is smaller than the depth of the pn junction of the diffusion layer. The particular method makes it possible to achieve a selective vapor growth of a metal film on the diffusion layer without deteriorating the pn junction characteristics.

Abstract: The invention concerns an integrated circuit the monocrystalline or polycrystalline silicon zones of which the source, gate and drain are covered with tantalum silicide TaSi.sub.2 while the remainder of the slice is covered with portions of a layer of tantalum oxide Ta.sub.2 O.sub.5, especially on the sides of the grids of polycrystalline silicon and on the thick oxide and an aluminum alloy layer comes into contact with the tantalum silicide to form connections with the portions of tantalum silicide.

Abstract: The specification describes a high capacity nonvolatile CCD read only memory system that includes a plurality of memory cells. Selected ones of the memory cells include a double-diffused region having a first and second implant or diffusion under a clocked electrode whereby the first implant or diffusion provides a fixed charge required for ROM operation and the charge and polarity of said second implant or diffusion provides a neutralizing effect on the surface potential under the clocked electrode and above the double implanted or double diffused region.

Abstract: Monocrystalline silicon is deposited on first and second portions of a substrate, the first and second portions having substantially unequal dimensions. The method comprises subjecting the substrate to a silicon-source gas and a predetermined concentration of chloride at a predetermined temperature. The chloride concentration is selected so as to create a substantially equally thick monocrystalline silicon deposit on each of the substrate portions.

Abstract: The present invention is to provide a method for manufacturing a semiconductor device of high efficiency and high integration density. The method for manufacturing a semiconductor device comprises the steps of forming semiconductive layers (30), (31) and (31') having on the surface thereof a concave portion, forming a nitride layer (35) within the concave portions forming with the nitride layer (35) as a mask an oxide layer (39) on the surface of the semiconductive layer (30), removing said nitride layer (35) and introducing an impurity into the semiconductive layers (31) and (31') with the oxide layer (39) as a mask. In accordance therewith, the elements can be made finer and hence the method of this invention is suitable for manufacturing an IC device high in efficiency and high in integration density.

Abstract: Expitaxial composite comprising thin films of a Group III-V compound semiconductor such as gallium arsenide (GaAs) or gallium aluminum arsenide (GaAlAs) on single crystal silicon substrates are disclosed. Also disclosed is a process for manufacturing, by chemical deposition from the vapor phase, epitaxial composites as above described, and to semiconductor devices based on such epitaxial composites. The composites have particular utility for use in making light sensitive solid state solar cells.

Abstract: The present invention deals with a semiconductor memory circuit device, in which a memory array portion of a rectangular shape consisting of semiconductor non-volatile memory elements is formed on a main surface of the semiconductor substrate, a low voltage driver circuit (decoder) is formed along a side of the memory array portion, and a high voltage driver circuit is formed along an opposite side of the memory array portion. This permits a reduction in word line length and avoids crossing of the word lines to permit increased operation speed and, particularly, increased reading speed.

Abstract: Apart from the base fingers (10), this transistor includes a titanium silicide coating, from which the base diffusions have been formed, and a silicon nitride coating (4). The edges of sandwiches made up of bands (3) and (4) are bordered by a silica bank (7) formed automatically by deposit and anisotropic attack, without additional masking. The emitter fingers (9) are overhung by a polycrystalline silicon layer (8) from which doping of these fingers has been obtained.The possibility is also obtained, automatically and without masks alignment, of having the emitter and base fingers brought firmly together with minimum protection distances.

Abstract: The efficacy of dielectrically isolated device formation on a substrate is substantially enhanced through a specific set of processing steps. In particular, before silicon oxide regions, e.g., gate oxide regions, are produced, bulk polycrystalline areas are heat treated to substantially increase their polycrystalline silicon grain size.

Abstract: A method and apparatus for low temperature deposition of epitaxial films using low pressure chemical vapor deposition (CVD) with and without plasma enhancement. More specifically, the process enables CVD of epitaxial silicon at temperatures below 800.degree. C. by use of an in situ argon plasma sputter cleaning treatment of the silicon substrate prior to deposition.

Abstract: A retrograde dopant distribution is provided in a semiconductor substrate by the combined use of indiffusion and surface outdiffusion and without the use of high energy implants or buried epitaxial layers. The retrograde dopant distribution is provided both in the n-well and the p-well regions to a depth sufficient to accommodate deep trench isolation structures.

Abstract: Single GaAs quantum well or single GaAs active layer or single reverse interface structures with Al.sub.x Ga.sub.1-x As barrier layers have improved qualities when one or more narrow bandgap GaAs getter-smoothing layers, which are thin, are grown and are incorporated in the barrier layer before and in close proximity to the active layer.