Abstract: A semiconductor processing method forms etch stop layers over semiconductor structures without the need for additional etching, masking, and deposition steps. A refractory metal capable of forming silicides and oxides under standard processing conditions is deposited over the deposition, oxide, and polysilicon layers of a MOS integrated circuit wafer. The coated wafer is first annealed to form refractory metal silicide layers over the unoxidized silicon structures. The coated wafer is then oxidized to convert unreacted refractory metal over the oxidized silicon structures into refractory metal oxide etch stops over these structures.

Abstract: An electrical circuit and method combine junction field effect transistors (JFET) and metal oxide semiconductor (MOS) circuits in series between V.sub.DD and ground, with a feedback of output voltage to control current from V.sub.DD to ground. The electrical circuit comprises a complementary metal oxide semiconductor (CMOS) inverter circuit with an input and an output, and a JFET having a gate coupled to the CMOS inverter for feedback to control the JFET. The JFET and CMOS circuitry is formed on a common substrate with the JFET gate junction being formed by implanting impurity dopants through a layer of gate oxide.

Abstract: A process and resulting product are described for forming an integrated circuit structure with horizontal fuses on an insulation layer formed over other portions of the integrated circuit structure by forming rectangular recesses in the insulation layer which are subsequently filled during a subsequent metal deposition step which also serves to fill with the same metal vias or contact openings which have been etched through the insulation layer. Subsequent planarization of the deposited metal layer down to the vias or contact openings, i.e. to remove the portions of the metal layer over the insulation layer, leaves the metal in the vias or contact openings and also leaves metal stringers on the sidewalls of the rectangular recess which then serve as fusible links (fuses) which are then connected to one or more metal lines thereafter formed on the insulation layer.

Abstract: Automated photolithography of integrated circuit wafers is enabled with a processor connected to a Rayleigh derator, a form factor generator, a logic synthesizer, a layout generator, a lithography module and a wafer process. The Rayleigh derator receives manufacturing information resulting from yield data in the wafer process, and this manufacturing data is then used to derate the theoretical minimum feature size available for etching wafer masks given a known light source and object lens numerical aperture. This minimum feature size is then used by a form factor generator in sizing transistors in a net list to their smallest manufacturable size. A logic synthesizer then converts the net list into a physical design using a layout generator combined with user defined constraints. This physical design is then used by the mask lithography module to generate wafer masks for use in the semiconductor manufacturing.

Abstract: A microelectronic integrated circuit includes a semiconductor substrate, and a plurality of microelectronic devices formed on the substrate. Each device has a periphery defined by a triangle, and includes an active area formed within the periphery, a central terminal formed in a central portion of the active area, and interconnected first to third terminals formed in the active area adjacent to vertices of the triangle respectively. First to third gates are formed between the first to third terminals respectively and the central terminal, and have contacts formed outside the active area adjacent to the sides of the triangle. The power supply connections to the central terminal and the first to third terminals, the conductivity type (NMOS or PMOS), and the addition of a pull-up or a pull-down resistor is selected for each device to provide a desired OR, NOR, AND or NAND function.

Abstract: A microelectronic integrated circuit includes a semiconductor substrate, and a plurality of CMOS microelectronic devices formed on the substrate. Each device includes a triangular ANY element of a first conductivity type (PMOS or NMOS), and a triangular ALL element of a second conductivity type (NMOS or PMOS), the ANY and ALL elements each having a plurality of inputs and an output that are electrically interconnected respectively. The ANY element is basically an OR element, and the ALL element is basically an AND element. However, the power supply connections and the selection of conductivity type (NMOS or PMOS) for the ANY and ALL elements can be varied to provide the device as having a desired NAND, AND, NOR or OR configuration, in which the ANY element acts as a pull-up and the ALL element acts as a pull-down, or vice-versa.

Abstract: A process is disclosed for forming an integrated circuit device, such as an EPROM device, with a floating gate electrode with a discontinuous phase of metal silicide formed on a surface thereof is described. The process for forming such a discontinuous phase of metal silicide on the surface of a polysilicon floating gate electrode for the device comprises the steps of depositing a first polysilicon layer over a substrate, and preferably over a thin oxide layer on the substrate capable of functioning as a gate oxide; then forming a very thin layer of a silicide-forming metal over the polysilicon layer; and heating the structure sufficiently to cause all of the silicide-forming metal to react with the underlying polysilicon layer to form metal silicide and to coalesce the metal silicide into a discontinuous phase on the surface of the polysilicon layer.

Abstract: An integrated circuit structure is described wherein individual integrated circuit devices such as MOS or bipolar transistors are constructed on and in a semiconductor substrate and one or more layers of metal interconnects are constructed on and in a second substrate, preferably of similar thickness, and the two substrates are then aligned and bonded together to thereby provide electrical interconnections of individual integrated circuit devices on the semiconductor substrate with appropriate metal interconnects on the second substrate to provide the desired integrated circuit structure without, however, contributing unduly to the overall size of the integrated circuit structure comprising the die or chip.

Abstract: A transistor circuit is formed on a substrate having source and drain electrodes and multiple current-controlling gates. The two current-controlling gates are separated by spacer oxide material. The first gate is an metal oxide semiconductor (MOS) gate that is insulated from the substrate by a layer of gate oxide. The second gate is a junction field effect transistor (JFET) gate contiguous to the MOS gate that is insulated from the MOS gate by a layer of spacer oxide.

Abstract: A microelectronic integrated circuit includes a semiconductor substrate, and a plurality of microelectronic devices formed on the substrate. Each device has a periphery defined by a triangle, and includes an active area formed within the periphery. First and second terminals are formed in the active area adjacent to two vertices of the triangle respectively, and first to third gates are formed between the first and second terminals. The gates have contacts formed outside the active area adjacent to a side of the triangle between the two vertices. The power supply connections to the first and second terminals, the conductivity type (NMOS or PMOS), and the addition of a pull-up or a pull-down resistor are selected for each device to provide a desired AND, NAND, OR or NOR function. A third terminal can be formed between two of the gates and used as an output terminal to provide an AND/OR logic function. The devices are interconnected using three direction routing based on hexagonal geometry.

Abstract: A process and structure are disclosed for inhibiting the channeling of dopant through the polysilicon gate electrode into a semiconductor substrate during implantation of source and drain regions in the substrate during the formation of MOS devices. After deposition over a semiconductor substrate of a polysilicon layer which will be subsequently patterned to form a gate electrode, an amorphous layer of silicon is formed over the polysilicon layer. This amorphous silicon layer is then treated with a material such as a nitrogen-bearing material capable of inhibiting grain growth and recrystallization of the amorphous silicon during subsequent high temperature processing. The amorphous silicon and polysilicon layers are subsequently conventionally patterned to form the gate electrode. The structure is then implanted without channeling of the dopant ions through the gate electrode into the underlying portion of the substrate where the channel of the MOS device will be formed.

Abstract: A low dielectric insulation layer for an integrated circuit structure material, and a method of making same, are disclosed. The low dielectric constant insulation layer comprises a porous insulation layer, preferably sandwiched between non-porous upper and lower insulation layers. The presence of some gases such as air or an inert gas, or a vacuum, in the porous insulation material reduces the overall dielectric constant of the insulation material, thereby effectively reducing the capacitance of the structure. The porous insulation layer is formed by a chemical vapor deposition of a mixture of the insulation material and a second extractable material; and then subsequently selectively removing the second extractable material, thereby leaving behind a porous matrix of the insulation material, comprising the low dielectric constant insulation layer.

Abstract: A method is provided for forming planar, self aligned wells without a high temperature oxidation step to form an ion barrier. The method comprises preparing a substrate with a silicon dioxide-polysilicon-silicon dioxide barrier layer that can be etched to expose different sublayers of the barrier at selected junctures in the production process. A single masking step defines the location of a first set of wells on the prepared substrate. The outer silicon dioxide layer is etched to expose the polysilicon layer at the selected locations, and the substrate is implanted with boron ions to form the first set of wells. Following ion implantation, the substrate photo-resist is removed, and the substrate is exposed to a germanium-silicon mixture under conditions selected to preferentially deposit a germanium-silicon alloy barrier layer on the exposed polysilicon layer.

Abstract: A transistor circuit is formed on a substrate having source and drain electrodes and multiple current-controlling gates. The two current-controlling gates are separated by spacer oxide material. The first gate is an metal oxide semiconductor (MOS) gate that is insulated from the substrate by a layer of gate oxide. The second gate is a junction field effect transistor (JFET) gate contiguous to the MOS gate that is insulated from the MOS gate by a layer of spacer oxide.

Abstract: A compact MOS type active device is constructed at least partially in an opening in an insulation layer, such as an oxide layer, above a portion of a semiconductor substrate forming a first source/drain region of the MOS type active device. A semiconductor material, on the sidewall of the opening, and in electrical communication with the portion of the substrate forming the first source/drain region of the device, comprises the channel portion of the MOS device. A second source/drain region, in communication with an opposite end of the channel, is formed on the insulation layer adjacent the opening and in electrical communication with the channel material in the opening. A gate oxide layer is formed over the channel portion and at least partially in the opening, and a conductive gate electrode is then formed above the gate oxide.

Abstract: A compact MOS type active device is constructed at least partially in an opening in an insulation layer, such as an oxide layer, above a portion of a semiconductor substrate forming a first source/drain region of the MOS type active device. A semiconductor material, on the sidewall of the opening, and in electrical communication with the portion of the substrate forming the first source/drain region of the device, comprises the channel portion of the MOS device. A second source/drain region, in communication with an opposite end of the channel, is formed on the insulation layer adjacent the opening and in electrical communication with the channel material in the opening. A gate oxide layer is formed over the channel portion and at least partially in the opening, and a conductive gate electrode is then formed above the gate oxide. In this embodiment, the memory transistors are connected to the Vcc bus by resistors.

Abstract: A process is disclosed for forming an integrated circuit device, such as an EPROM device, with a floating gate electrode with a discontinuous phase of metal silicide formed on a surface thereof is described. The process for forming such a discontinuous phase of metal silicide on the surface of a polysilicon floating gate electrode for the device comprises the steps of depositing a first polysilicon layer over a substrate, and preferably over a thin oxide layer on the substrate capable of functioning as a gate oxide; then forming a very thin layer of a silicide-forming metal over the polysilicon layer; and heating the structure sufficiently to cause all of the silicide-forming metal to react with the underlying polysilicon layer to form metal silicide and to coalesce the metal silicide into a discontinuous phase on the surface of the polysilicon layer.

Abstract: A low dielectric constant insulation layer for an integrated circuit structure material, and a method of making same. The low dielectric constant insulation layer comprises a porous insulation layer, preferably sandwiched between non-porous upper and lower insulation layers. The porous insulation layer is formed by depositing a composite layer comprising an insulation material or a material which can be converted to an insulation material, by a converting process and a material which can be converted to a gas upon subjection to the converting process. Release of the gas leaves behind a porous matrix of the insulation material which has a lower dielectric constant than the composite layer.

Abstract: A process and resulting product are described for forming an integrated circuit structure with horizontal fuses on an insulation layer formed over other portions of the integrated circuit structure by forming rectangular recesses in the insulation layer which are subsequently filled during a subsequent metal deposition step which also serves to fill with the same metal vias or contact openings which have been etched through the insulation layer. Subsequent planarization of the deposited metal layer down to the vias or contact openings, i.e. to remove the portions of the metal layer over the insulation layer, leaves the metal in the vias or contact openings and also leaves metal stringers on the sidewalls of the rectangular recess which then serve as fusible links (fuses) which are then connected to one or more metal lines thereafter formed on the insulation layer.

Abstract: A low dielectric insulation layer for an integrated circuit structure material, and a method of making same, are disclosed. The low dielectric constant insulation layer comprises a porous insulation layer, preferably sandwiched between non-porous upper and lower insulation layers. The presence of some gases such as air or an inert gas, or a vacuum, in the porous insulation material reduces the overall dielectric constant of the insulation material, thereby effectively reducing the capacitance of the structure. The porous insulation layer is formed by a chemical vapor deposition of a mixture of the insulation material and a second extractable material; and then subsequently selectively removing the second extractable material, thereby leaving behind a porous matrix of the insulation material, comprising the low dielectric constant insulation layer.