Abstract: A method of manufacturing an insulated gate field effect transistor is described. The method comprises providing a gate layer (6) on an insulating layer (12) on one surface (4) of a semiconductor body (1) and source regions (2) of one conductivity type within a respective body region (14), a portion of each body region (14) underlying a portion of the gate layer to provide a channel area extending between the source region (2) and a drain region (3) meeting another surface (5) of the semiconductor body opposite the one surface (4).

Abstract: A first semiconductor layer is formed on a semiconductor anode layer containing a high concentration of impurity of a first conductivity type. This first semiconductor layer contains an impurity in a lower concentration than the impurity concentration of the anode layer on which it is formed. A second semiconductor layer containing a high concentration of impurity of a second conductive type is formed on the first semiconductor layer, and a third semiconductor layer containing a low concentration of impurity of the second conductive type is formed on the second semiconductor layer. Impurity regions of at least the first conductivity type are formed by thermal diffusion in the surface region of this third semiconductor layer. During the thermal diffusion, the impurity contained in the anode layer diffuses into the first semiconductor layer.

Abstract: A two-terminal, bidirectional semiconductor trigger switch is provided. The trigger switch is a relatively sensitive multilayer semiconductor breakover device that switches on fully when its breakover voltage is reached. The design of the trigger switch allows its breakover voltage point to be readily adjustable during fabrication of the device.The semiconductor trigger switch is particularly suited to provide a low voltage trigger for a TRIAC. The trigger switch is connected in series with the gate of the TRIAC and mounted on the gate lead to provide a unitary, three-terminal device incorporating the TRIAC/trigger switch combination.

Abstract: A silicon integrated circuit includes a vertical power DMOS transistor and a vertical NPN transistor in separate epitaxial pockets by a method including simultaneously forming a plurality of D-well regions in the DMOS transistor and the base region in the NPN transistor, and including simultaneously forming the elemental source regions and the emitter region. N-type buried layers are provided simultaneously in the DMOS and the NPN transistors, respectively. Also formed simultaneously are two N+ plugs connecting the two buried layers, respectively, to the epitaxial surface of the integrated circuit die. None of these economically attractive simultaneous steps requires deviation in either device from optimum geometries. Also disclosed are compatible and integrated steps for forming small signal CMOS transistors. This method also includes a full self-alignment of gate, source and channel regions in the DMOS transistor as well as in the CMOS transistors.

Abstract: Disclosed is a process for making a DMOS, including lining a groove with a dielectric material to form an inner groove having sidewalls extending through the bottom of the first groove, and lining the inner groove with a dielectric material to obtain increased thickness of the gate dielectric on the sidewalls of the inner groove.

Abstract: The present invention relates to a method of producing a vertical insulated gate field effect transistor. In the present invention a window portion is formed on a polysilicon layer which serves as a gate, by selectively etching the layer so as to leave the central portion intact. Ions of impurities are implanted while using the polysilicon layer having the window portion as a mask. Thereby a phase layer is formed and the ions of impurities are again implanted from the window portion, forming the N.sup.+ source region. Since this method is different from a conventional method in that positioning using a special resist mask is unnecessary, the N.sup.+ source region is formed by self alignment with a high efficiency and a high accuracy without any positional deviation caused by inaccurate positioning of a mask.

Abstract: A symmetrical blocking high breakdown voltage semiconductor device in which the lower junction termination is brought to the upper surface is fabricated by diffusing first and second regions of a first conductivity type into an upper surface of an epitaxial layer of a second conductivity type disposed on a substrate, and forming a groove having sloped sidewalls in the upper surface such that the groove extends through the second diffused region, the epitaxial layer and into the substrate. A thin layer of impurities of the first conductivity type is implanted into the sidewalls, and the impurities are electrically activated to form a low resistivity path that connects the substrate to the second diffused region. Subsequently, the semiconductor device may be separated from the wafer by cutting the wafer at the groove. The manufacturing process enables substantially complete fabrication of a plurality of devices while still in wafer form, thereby avoiding the inconvenience of processing individual dice.

Abstract: A method for manufacturing double-diffused metal-oxide-semiconductor field effect transistor (DMOSFET) device is to form an insulating layer having an opening in top surface on a semiconductor wafer, channel regions and well regions and source regions through two stage diffusions of impurity materials respectively of a different conductivity type from and the same conductivity type as the wafer and carried out through the opening, and further gate, source and drain electrodes are formed after masks provided on a surface area where the drain regions and the source electrode regions that are to be connected to the well regions and source regions and a further ion-implantation of an impurity material of the same conductivity type as the wafer into the channel regions, with the threshold voltage controlled to achieve a depletion type.

Abstract: A method for manufacturing a DMOS which comprises forming a first conductive type layer on a substrate, forming a gate oxide layer thereon, forming a gate electrode layer and a second insulating layer successively on the gate oxide layer, forming a second conductive type body region and a first conductive type source region having a narrower width by implanting impurities utilizing the second insulating layer as a mask, forming a side wall spacer of an insulating material on at least a side portion of the gate electrode, forming a conductive passage penetrating the source region and extending into the body region while utilizing the second insulating layer and the side wall spacer as mask, optionally implanting the exposed body region, further excessively etching the sidewall spacer, the masking layer overlying the gate, and the gate oxide prior to providing an electrode connecting the source and body regions.

Abstract: A wafer with a <100> orientation comprises a strongly doped N layer (substrate), a lightly doped N layer (middle layer) and a lightly doped P layer (top layer). A strongly doped N layer (source layer) is diffused into most of the top layer. An oxide layer is grown. A V groove with a flat bottom is anisotropically etched through openings in the oxide layer. The V groove is etched through the source layer and most of the P layer. The bottom of the groove initially is at a level above the junction between the top layer and the middle layer. Exposure to beam of phosphorous ions forms a shallow implanted channel region proximate the walls of the groove. An unwanted implanted region along the bottom of the groove is also formed. A second anisotropic etch, through the same oxide mask, deepens the groove bottom to a point below the junction, removing the unwanted portion of the implanted region along the groove bottom. The implanted concentration of the channel is later reduced as the gate oxide is formed.

Abstract: A process of fabricating high performance EPROMs in which memory cell devices and high voltage circuit devices are formed in p-type tub regions of high threshold voltage. The tub regions are formed by implanting boron ions in photolithographically defined memory cell and high voltage device areas of a p-type wafer substrate, then subjecting the substrate to a high temperature drive-in. The N-channel isolation field is formed separately and has a lower threshold voltage than the tub regions. The isolation field is formed by implanting boron ions around all device areas, including low voltage device areas, using a nitride mask and a low implantation energy. The wafer is then subjected to an anneal step followed by a field oxidation step. The memory cell and other MOS devices are finally formed in the appropriate defined regions.

Abstract: A vertical MOSFET in a silicon wafer having opposing major surfaces includes a source electrode on one surface, a drain electrode on the second surface, and an internally disposed insulated gate. The silicon between the insulated gate and each of the major surfaces is of first conductivity type and the silicon that is laterally adjacent to the insulated gate is of second conductivity type, such that a predetermined voltage on the insulated gate creates an inversion channel extending a predetermined distance into the laterally adjacent silicon. That portion of the laterally adjacent silicon where the inversion channel is formed is of relatively lightly doped material, whereas other areas of the laterally adjacent silicon is relatively heavily doped.

Abstract: Grounding of source contacts (S) of flat devices and integrated circuits (of the FET type) is carried out according to the following process steps: a GaAs wafer is applied on a support and is covered on its free or rear face with photoresist; the latter is then etched along the border lines of the single FETs; the GaAs layer between contiguous FETs is removed also to make accessible the contacts S; a layer of noble metal is then deposited on the FET rear faces, so that it bridges the contacts S; the single metallized devices are disconnected from the initial support and finally are soldered to a package base.

Abstract: An insulated-gate semiconductor device, such as an IGFET or IGT, with improved source-to-base shorts includes, in a semiconductor wafer, a drain region, a voltage-supporting region, a base region, and a source region. Generally parallel gate fingers of refractory material are insulatingly spaced above the wafer. Elongated base portions are provided between, and preferably registered to, a respective pair of adjacent gate fingers. Elongated source portions are each situated within a respective base portion and each is preferably registered to a respective pair of adjacent gate fingers. Generally parallel shorting portions are included in the wafer and are oriented transverse to the gate fingers, whereby the shorting portions can be formed without a critical alignment step. The shorting portions adjoin the base portions and also a source electrode so as to complete source-to-base electrical shorts.

Abstract: A vertical IGFET comprising a substantially planar silicon wafer with a source electrode on one major surface and a drain electrode on the opposite major surface is disclosed. An insulated gate electrode, which includes a conductive finger portion surrounded by an insulating layer, is internally disposed in the silicon wafer such that a predetermined voltage applied to the gate electrode will regulate a current flow between the source and drain electrodes. The device is fabricated utilizing an epitaxial lateral overgrowth technique for depositing monocrystalline silicon over the insulated gate which is disposed on a silicon substrate.