Abstract: A method is disclosed for fabricating a small area, self aligned guard ring in a Schottky barrier diode. A vertically-walled hole is anisotropically etched completely through a dielectric layer on a silicon substrate. A layer of doped polycrystalline silicon is deposited over the apertured dielectric layer. The polycrystalline silicon is reactively ion etched away to leave only a lining about the perimeter of the hole in the dielectric layer. The structure is heated to diffuse the dopant from the lining into the substrate. Schottky diode metal is deposited on the substrate exposed through the lined aperture in the dielectric layer.

Abstract: A method is disclosed for fabricating a small area, self aligned guard ring in a Schottky barrier diode. A vertically-walled hole is anisotropically etched completely through a dielectric layer on a silicon substrate. A layer of doped polycrystalline silicon is deposited over the apertured dielectric layer. The polycrystalline silicon is reactively ion etched away to leave only a lining about the perimeter of the hole in the dielectric layer. The structure is heated to diffuse the dopant from the lining into the substrate. Schottky diode metal is deposited on the substrate exposed through the lined aperture in the dielectric layer.

Abstract: The lateral transistor is described which has both its base width and the emitter region of the transistor minimized. This minimization of the elements of the lateral transistor gives high performance. The lateral transistor which may be typically PNP transistor is formed in a monocrystalline semiconductor body having a buried N+ region within the body. A P type emitter region is located in the body. An N type base region is located around the side periphery of the emitter region. A P type collector region is located in the body surrounding the periphery of the base region. A first P+ polycrystalline silicon layer acting as an emitter contact for the emitter region is in physical and electrical contact with the emitter region and acts as its electrical contact. A second P+ polycrystalline silicon layer is located on the surface of the body to make physical and electrical contact with the collector region.

Abstract: The lateral transistor is described which has both its base width and the emitter region of the transistor minimized. This minimization of the elements of the lateral transistor gives high performance. The lateral transistor which may be typically PNP transistor is formed in a monocrystalline semiconductor body having a buried N+ region within the body. A P type emitter region is located in the body. An N type base region is located around the side periphery of the emitter region. A P type collector region is located in the body surrounding the periphery of the base region. A first P+ polycrystalline silicon layer acting as an emitter contact for the emitter region is in physical and electrical contact with the emitter region and acts as its electrical contact. A second P+ polycrystalline silicon layer is located on the surface of the body to make physical and electrical contact with the collector region.

Abstract: A method for making a lateral PNP transistor simultaneously with an NPN transistor and the resultant device wherein a first mask defines a base-width by the resistor implant for a P-type resistor and a second mask is overlaid asymmetrically on said first mask to partially cover the collector. At the same time that the NPN extrinsic base contact is made, P-type dopants are introduced in the areas exposed by the first and second masks to provide an emitter and a collector contact for the PNP transistor.

Abstract: A high performance lateral transistor may be fabricated by first providing a monocrystalline semiconductor body having a principal surface and where the desired transistor is a PNP transistor, a buried N+ region with an N+ reach-through connecting the buried region to said principal surface. The collector region of the transistor is formed into the surface by blanket diffusing P type impurities into the desired region. An insulating layer is formed upon the top surface of the semiconductor body. An opening is made in the insulating layer where the groove or channel-emitter contact is desired. An etching of a substantially vertical walled groove into the monocrystalline semiconductor body using the patterned insulating layer as the etching mask. An N base diffusion is carried out to produce as N region around the periphery of the opening in the body. Oxygen is then ion implanted into the bottom of the groove to form a silicon dioxide region at the bottom of the groove.

Abstract: A dynamic memory cell has a P+ injector region surrounded by an N+ region in an N- layer on an N+ layer. The injector region is placed between N+ source and drain regions. Holes injected into the N-layer are trapped by the high-low junctions at the N+, N- interfaces and are detected by sensing the source-drain current. Current levels are used to establish binary one and zero levels in the cell. Four masks in an aligned procedure simplify fabrication.

Abstract: A method for eliminating deposited residues, for example polysilicon residue, on vertical silicon dioxide sidewalls that have been reactive ion etched includes reshaping the sidewalls to have a slope of at least +30.degree. relative to the vertical direction of the sidewall.

Abstract: The present invention provides a method for planarizing a non-uniform thickness of oxide, for example silicon dioxide as is formed over oxide-filled trenches used in deep dielectric isolation in integrated circuits. The oxide is removed by a planarizing resist-etching process so that etching in thicker resist areas proceeds at a rate slower than etching in thinner resist areas. A referred etchant is HF gas and etching is preferably at an elevated temperature.

Abstract: A high sheet resistance structure for high density integrated circuits and the method for manufacturing such structure is given. The structure includes a silicon region separated from other silicon regions by a dielectric barrier surrounding the region. A resistor of a first conductivity, for example, N type, encompasses substantially the surface of the silicon region. Electrical contacts are made to the resistor. A region highly doped of a second conductivity, for example, P-type, is located below a portion of the resistor region. This region of second conductivity is connected to the surface. Electrical contacts are made to this varied region for biasing purposes. A second region within the same isolated silicon region may be used as a resistor. This region is located below the buried region of second conductivity. Alternatively, the described resistor regions can be connected as transistors.

Abstract: A method for making a filamentary pedestal transistor is disclosed in which epitaxial silicon is formed selectively above portions of a subcollector through the use of laser radiation. A single crystal substrate, having a subcollector of higher impurity concentration, is covered by an oxide mask which is apertured at two locations above the subcollector. Polycrystalline silicon is deposited over the apertured oxide mask. The structure is exposed to laser radiation of suitable energy level and wavelength to selectively convert the polycrystalline silicon to epitaxial monocrystalline silicon within and above the oxide apertures. The transistor is completed by conventional techniques to form base, emitter and collector reach-through regions.

Abstract: A method for making lateral PNP or NPN devices in isolated monocrystalline silicon pockets wherein silicon dioxide isolation surrounds the pocket and partially, below the surface, within the isolated monocrystalline region. The P emitter or N emitter diffusion is made over the portion of the silicon dioxide that partially extends into the monocrystalline isolated pocket. This structure reduces the vertical current injection which will give relatively high (beta) gain even at low base to emitter voltages. The lateral PNP or NPN device resulting from the method is in a monocrystalline silicon pocket wherein silicon dioxide isolation surrounds the pocket and partially, below the surface, within the isolated monocrystalline silicon region. The P emitter or N emitter diffusion is located over the portion of the silicon dioxide that partially extends into the monocrystalline isolated pocket.

Abstract: A method for making a bipolar filamentary pedestal transistor having reduced base-collector capacitance attributable to the elimination of the extrinsic base-collector junction. Silicon is deposited upon a coplanar oxide-silicon surface in which only the top silicon surface of the buried collector pedestal is exposed through the oxide. Epitaxial silicon deposits only over the exposed pedestal surface while polycrystalline silicon deposits over the oxide surface. The polycrystalline silicon is etched away except in the base region. An emitter is formed in the base region and contacts are made to the emitter, base and collector regions.

Abstract: A method for making a high performance bipolar transistor characterized by self-aligned emitter and base regions and minimized base and emitter contact spacing. The disclosed method comprises forming a recessed oxide-isolated structure having opposite conductivity epitaxial layer and substrate. Multiple layered mass of alternating silicon nitride and silicon dioxide layers are placed over the base region and over the collector reach-through region. Polycrystalline silicon is deposited between the mesas. The mesas are undercut-etched to expose the extrinsic base region which is ion implanted. Then, the mesas are removed to expose the emitter and intrinsic base regions as well as the collector reach-through regions. The latter exposed regions are ion implanted appropriately. Contacts are made directly to the emitter and collector reach-through regions and indirectly via the polysilicon to the base region.

Abstract: A method for manufacturing a high performance bipolar device and the resulting structure which has a very small emitter-base spacing is described. The small emitter-base spacing, reduces the base resistance compared to earlier device spacing and thereby improves the performance of the bipolar device. The method involves providing a silicon semiconductor body having regions of monocrystalline silicon isolated from one another by isolation regions and a buried subcollector therein. A base region is formed in the isolated monocrystalline silicon. A mask is formed on the surface of the silicon body covering those regions designated to be the emitter and collector reach-through regions. A doped polycrystalline silicon layer is then formed through the mask covering the base region and making ohmic contact thereto. An insulating layer is formed over the polysilicon layer. The mask is removed from those regions designated to be the emitter and collector reach-through regions.

Abstract: A small variable resistor is used as a precision terminating resistor in an integrated circuit interconnection structure. The structure involves the use of a driver circuit connected to and driving a plurality of loads which are connected to a transmission line. The transmission line is terminated by the precision variable terminating resistor. The last load in the series of loads is located in the integrated circuit chip which has the variable terminating resistor. The absolute value of the variable resistor is difficult to control. The absolute value of any conventional integrated resistor is hard to control in manufacturing. However, by making the value of the resistance proportional to a voltage which itself is proportional to a deviation from a reference voltage, it is possible to obtain a much more precise value of resistance.

Abstract: A high sheet resistance structure for high density integrated circuits and the method for manufacturing such structure is given. The structure includes a silicon region separated from other silicon regions by a dielectric barrier surrounding the region. A resistor of a first conductivity, for example, N type, encompasses substantially the surface of the silicon region. Electrical contacts are made to the resistor. A region highly doped of a second conductivity, for example, P-type, is located below a portion of the resistor region. This region of second conductivity is connected to the surface. Electrical contacts are made to this varied region for biasing purposes. A second region within the same isolated silicon region may be used as a resistor. This region is located below the buried region of second conductivity. Alternatively, the described resistor regions can be connected as transistors.

Abstract: A method is given for fabricating vertical NPN and PNP structures on the same semiconductor body. The method involves providing a monocrystalline semiconductor substrate having regions of monocrystalline silicon isolated from one another by isolation regions. Buried regions are formed overlapping the juncture of the substrate and epitaxial layer and are located in at least one of the regions of isolated monocrystalline silicon. The P base region in the NPN designated regions and a P reach-through in the PNP designated regions are formed simultaneously. The emitter region in the NPN regions and base contact region in the PNP regions are then formed simultaneously. The P emitter region in the PNP regions is then implanted by suitable ion implantation techniques. A Schottky Barrier collector contact in the PNP regions are formed. Electrical contacts are then made to the PNP and NPN transistor elements. A PNP device may be fabricated without the formation of an NPN device if it is so desired.

Abstract: Lateral PNP or NPN devices in isolated monocrystalline silicon pockets wherein silicon dioxide isolation surrounds the pocket and partially, below the surface, within the isolated monocrystalline region are described. The P emitter or N emitter diffusion is made over the portion of the silicon dioxide that partially extends into the monocrystalline isolated pocket. This structure reduces the vertical current injection which will give relatively high (beta) gain even at low base to emitter voltages.

Abstract: Excessive leakage after initial forward stress, exhibited by subsequently reverse stressed nitride defined, Schottky barrier diodes is solved by the elimination of the "mouse hole" or undercut cavity in the oxide layer beneath the nitride ring defining the Schottky contact to the underlying silicon. The aforementioned cavity is filled by depositing chemical vapor deposited (CVD) oxide onto the nitride layer, into the nitride ring and the undercut oxide cavity beneath the ring and onto the underlying silicon substrate exposed through the nitride ring. The CVD oxide is then reactively ion etched to remove it except along the vertical walls of the nitride ring and the oxide cavity. The Schottky metal is deposited on the silicon substrate exposed by the reactive ion etching step.