Abstract: A method for annealing semiconductor samples, especially following ion-implantation of semiconductor samples is disclosed. A furnace on a set of rails is passed over the semiconductor sample which is supported on a stationary wire basket made of low thermal mass, fine tungsten wire. The furnace temperature may be about 5.degree. above the desired anneal temperature of the semiconductor sample such that the sample temperature rises to within a few degrees of the furnace temperature within seconds. Utilizing the moveable furnace insures uniform heating without elaborate temperature control or expensive beam generating equipment.The apparatus and process of the present invention are utilized for rapid annealing of ion-implanted indium phosphide semiconductors within 10 to 30 seconds and at temperatures of approximately 700.degree. C., thereby eliminating undesired and damaging movement of impurities within the ion-implanted InP.

Abstract: A monocrystalline layer of one semiconductor material is grown onto a surface of a monocrystalline semiconductor body by means of molecular beam epitaxy. During such growth, the semiconductor body is kept at such a low temperature that a non-monocrystalline layer is obtained. The non-monocrystalline layer is then converted by a heat treatment into a monocrystalline form. Accordingly, an abrupt junction between the two semiconductor materials is obtained.

Abstract: A method is disclosed for growing an epitaxial layer composed of semiconductor material belonging to the cubic crystal system on a substrate, where the lattice constant of the epitaxial layer is graded from an initial lattice constant adjacent to the substrate to a final lattice constant on the surface of the epitaxial layer. Growth surfaces are formed on the substrate, and the epitaxial layer is grown as its lattice constant changes from the initial lattice constant to the final lattice constant.

Abstract: An integrated circuit wherein the base and surface collector regions of the I.sup.2 L vertical transistor are formed by the same steps used to form the collector and base, respectively, of complementary bipolar transistors. Thus, a high voltage bipolar transistor of the same type as the vertical I.sup.2 L transistor may be formed using separate process steps, thereby optimizing the design of both devices.

Abstract: In a semiconductor device comprising at least one bipolar transistor and a VIP isolating layer which are formed in both an epitaxial layer and a semiconductor substrate, an impurity-introduced region having the same conductivity type as that of the semiconductor substrate is formed so as to surround the V-groove. A buried layer of the bipolar transistor comes into contact with the VIP isolating layer to divide the impurity-introduced region into two parts, one of which is combined with a base region and the other one of which serves as a channel stopper.

Abstract: A method of making semiconductor integrated circuit devices with narrow and deep isolation regions of polycrystalline silicon and wide and thick isolation regions of thermally grown silicon oxide. A multi-layer of a first silicon nitride layer, a polycrystalline silicon layer, a second silicon nitride layer and a silicon oxide layer are formed on a semiconductor body. A photoresist layer is applied on the surface of the silicon oxide layer. An opening is formed in the photoresist layer and the multi-layer. The silicon oxide layer under the photoresist layer is side-etched through the opening. The exposed polycrystalline layer is converted into another silicon oxide layer. Another opening surrounding the silicon oxide layer is formed to expose surfaces of the semiconductor body. Deep grooves are formed in the semiconductor body.

Abstract: Semiconductor layers are selectively epitaxially grown in portions having an insulating film removed which is formed on a substrate by selective epitaxial growth under reduced pressure. With respect to a circumferential region outwardly of the removed portions in which the semiconductor elements are to be provided, there are formed one or more removed portions (dummy portions) in which no semiconductor element is provided, thereby making arrangement of the removed portions as even as possible with respect to the entire surface of the insulating film, to overcome position dependency in flatness of the semiconductor layers to be obtained. The semiconductor layers grown in the dummy portions may be left not to have semiconductor elements formed therein.

Abstract: A method of producing a high frequency III-V FET and the resultant structure is described wherein a doped layer is formed on a wafer of undoped, semi-insulating III-V material. The structure is then etched to form a mesa after which, a channel region is regrown from an exposed portion of the III-V substrate. The formation of the channel region defines the source and drain regions. Ohmic contacts are then made to the source and drain regions after which a Schottky contact is made to the channel region.

Abstract: A method and apparatus is described for activating implants in gallium arsenide incorporating crushed gallium arsenide and hydrogen to form a gas mixture to provide an atmosphere for the gallium arsenide to be activated and a furnace for heating the crushed gallium arsenide to a first temperature and the gallium arsenide to be activated to a second temperature. The invention overcomes the problem of wafer loss at the surface by evaporation during anneal and activation of gallium arsenide.

Abstract: In the fabrication of integrated circuits, a method is provided for forming dielectrically isolated regions in a semiconductor substrate comprising forming over the semiconductor substrate surface an electrically insulating layer of dielectric material having a plurality of openings therethrough and etching to form recesses in the semiconductor substrate exposed in the openings. Then, aluminum is deposited over the substrate so that an aluminum layer is formed on said layer of dielectric material as well as in said recesses. Next, the aluminum in the recesses is selectively anodized to form aluminum oxide, and the remaining aluminum on said layer of dielectric material is removed either by selectively etching away the aluminum layer or by a "lift-off" technique wherein the insulating layer of dielectric material under the aluminum is etched away thereby "lifting-off" and removing the aluminum.

Abstract: The invention provides a process comprising a step for depositing at least one intrinsic or doped monocrystalline silicon layer on a substrate, also monocrystalline, followed by a step for forming a thin silica layer at the level of the original substrate-silicon interface. The silica layer is obtained by oxidation through the substrate, followed by a heat treatment step during which the monocrystalline silicon is oxidized by the implanted oxygen ions. The first approach may take place according to two variants: thermal or plasma oxidation of the silicon-substrate interface. Oxidation takes place during the return to ambient temperature of the stack of layers after the deposit has been made.

Abstract: A sidewall-nitride isolation technology avoids stress-induced defects, while permitting a heavy channel stop implant to avoid turn-on of the field oxide transistor, by performing a two-step silicon etch. The first channel stop implant is performed after the first silicon etch, before the sidewall nitride is deposited. A further silicon etch is performed after the sidewall nitride is in place, and a second channel stop implant follows. The first implant can be a light dose, to avoid excess subthreshold leakage in the active devices due to field-assisted turn on at the corners of the moat regions, and the second implant can be a very heavy dose to provide complete isolation without any danger of the channel stop species encroaching on the active device regions.

Abstract: A CMOS process is described which is particularly suited for forming dynamic memory cells. The cells are formed in an n-well and a single plate member formed from a first layer of polysilicon is used for the entire array. Unique etching of the first polysilicon layer prevents stringers from occurring when the second layer of polysilicon is deposited. A tri-layer dielectric is used for the capacitors in the array. Novel "rear-end" processing is disclosed using a phosphorus doped glass.

Abstract: A method is provided for manufacturing semiconductor structures having dielectrically isolated silicon regions on one side of a silicon body. This is accomplished by forming in the silicon body a set of buried regions and a set of surface regions having characteristics which make them anodically etch slower than the remaining portion of the silicon body. These two sets of regions define portions in the silicon body which are anodically etched to form porous silicon regions which are oxidized to form an isolation structure that isolates the silicon surface regions from each other and the remaining portion of the silicon body. Typically in a P-type silicon body the buried and surface regions are N-type regions formed through ion implantation.

Abstract: A layer of a compound semiconductor having good quality is formed by disposing a substrate in an epitaxial growth layer, feeding a second reactant gas through a guide member extending from the downstream side to the upstream side of the flow of a first reactant gas, mixing the first reactant gas and second reactant gas, and supplying the resultant gaseous mixture of the first and second reactant gases onto the substrate.

Abstract: A molecular beam epitaxy method of growing Ge.sub.x Si.sub.1-x films on silicon substrate is described.

Abstract: A method for the formation of buried gates in a semiconductor device using epitaxial growing method combined with diffusion method or diffusion by an additional heat treatment. The buried gate has smaller gate resistance by providing relatively high impurity concentration and also having good reverse characteristic by providing relatively low impurity concentration at the top of the buried gates.

Abstract: A void-free isolated semiconductor substrate is described which contains a pattern of substantially vertically sided trenches within a semiconductor body. The pattern of isolation trenches isolate regions of monocrystalline semiconductor material which may contain active and passive semiconductor devices. A first insulating layer is located upon the sidewalls of the trenches. The base or bottom of the trenches is open to the monocrystalline semiconductor body. An epitaxial layer extending from the base of the trenches fills the pattern of trenches up to a level from the upper surface of the trenches as specified approximately by the equation:y=0.34xwhere y is the distance between the epitaxial layer and the top surface and x is the trench width. The preferred range for the trench width x is about 10 micrometers or less. A polycrystalline silicon layer fills the additional portion of the pattern of trenches above the upper surfaces of the epitaxial layer.

Abstract: The void-free pattern of isolation in a semiconductor substrate is described. There is contained within a semiconductor body a pattern of substantially vertically sided trenches. The pattern of isolation trenches isolate regions of monocrystalline semiconductor material which may contain active and passive semiconductor devices. The depth of the pattern of trenches is greater than about 3 micrometers. A first insulating layer is located upon the sidewalls of the trenches. The base or bottom of the trenches is open to the monocrystalline semiconductor body. An epitaxial layer extending from the base of the trenches fills the pattern of trenches up to between about 500 to 1500 nanometers from the upper surface of the trenches. A capping second insulating layer fills the additional portion of the pattern of trenches above the upper surfaces of the epitaxial layer for isolation of the pattern of trenches from the ambient.

Abstract: The invention relates to a process for producing silicon diaphragm pressure transducers, and to pressure transducers so produced, which will operate in high temperature applications above 150.degree. C. by properly insulating the strain gauges from the diaphragm. This is achieved by utilizing two properly oriented silicon wafers which are joined together by a two-step diffusion technique, which includes the diffusion bonding of one boron doped wafer surface into the other wafer surface previously oxide coated, at greatly reduced pressures and temperatures than heretofore used. This simultaneous diffusion takes place because of prior contouring or the forming of relief channels into one of the bonded surfaces, and because only one joined surface is oxide coated, thus reducing process times substantially. That is, there is a continuous diffusion of boron into the boron oxide coated surface resulting in a boron rich layer of great uniformity.