Abstract: A method and apparatus for providing a meshed power and signal bus system on an array type integrated circuit that minimizes the size of the circuit. In a departure from the art, through-holes for the mesh system are placed in the cell array, as well as the peripheral circuits. The power and signal buses of the mesh system run in both vertical and horizontal directions across the array such that all the vertical buses lie in one metal layer, and all the horizontal buses lie in another metal layer. The buses of one layer are connected to the appropriate bus(es) of the other layer using through-holes located in the array. Once connected, the buses extend to the appropriate sense amplifier drivers. The method and apparatus are facilitated by an improved subdecoder circuit implementing a hierarchical word line structure.

Abstract: The present invention discloses a novel integrated circuit capacitor and a method of forming such a capacitor. The capacitor formation begins with a base electrode 18 adjacent an insulating region 26. This base electrode 18 can comprise either polysilicon or a metal. A layer 28 of a first material, such as a siliciding metal, is formed over the base electrode 18 as well as the adjacent insulating region. A self-aligned capacitor electrode 12 can then be formed by reacting the first material 28 with the base electrode 18 and removing unreacted portions of the first material 28 from the insulating region 26. The capacitor is then completed by forming a dielectric layer 16 over the self-aligned capacitor electrode 12 and a second capacitor electrode 14 over the dielectric layer 16.

Abstract: A method and apparatus for providing a meshed power and signal bus system on an array type integrated circuit that minimizes the size of the circuit. In a departure from the art, through-holes for the mesh system are placed in the cell array, as well as the peripheral circuits. The power and signal buses of the mesh system run in both vertical and horizontal directions across the array such that all the vertical buses lie in one metal layer, and all the horizontal buses lie in another metal layer. The buses of one layer are connected to the appropriate bus(es) of the other layer using through-holes located in the array. Once connected, the buses extend to the appropriate sense amplifier drivers. The method and apparatus are facilitated by an improved subdecoder circuit implementing a hierarchical word line structure.

Abstract: A single polysilicon memory cell (10) provides a positive low programming and erase voltage together with a small cell size and includes P substrate (12) and P-well (14) formed within P substrate (12). NMOS transistor (16) is formed within P-well (14). N+ control gate (26) is formed in P-well (14) and includes punch-through implant region (26). NMOS transistor (16) and N+ control gate (26) have in common electrically isolated polysilicon gate (22, 32) for operating as a floating gate in common with NMOS transistor (16) and N+ control gate (26). N+ control gate (26) includes P-channel punch-through implant (34) for increasing the capacitive coupling ratio. This improves programming and erasing efficiency within single polysilicon memory cell (10).

Abstract: An integrated circuit. The circuit includes a memory cell array including wordlines 201 formed on a substrate and bitlines 200 and capacitors 203 formed over the wordlines. The bitlines have a first thickness and pitch. The circuit also includes circuits peripheral to the array including transistors formed in the substrate and conductors 202 over the transistors. The conductors have a second thickness and pitch. The circuit is further characterized in that the bitlines and conductors are formed in a common conductive layer. In further embodiments, the first thickness and pitch are smaller than the second thickness and pitch.

Abstract: A thermal neutron shield (520) for integrated circuits (511-515) deters absorption of thermal neutrons by circuit constituents to form unstable isotopes with subsequent decay which generates bursts of charge which may upset of stored charge and create soft errors. The shielding may be either at the integrated circuit level (such as a layer on insulation or in the filler of plastic packaging material) or at the board level (such as a filler or film on a container wall).

Abstract: Post-etch treatment of an etch-damaged semiconductor device includes forming a protective cover (48, 148) over an oxidizable section (18, 118) of the semiconductor device. The protective cover (48, 148) is operable to at least inhibit oxidation of the oxidizable section (18, 118). While the oxidizable section (18, 118) is covered, an oxide structure (52, 152) is formed. The oxide structure (52, 152) is operable to at least ameliorate etch damage to the semiconductor device.

Abstract: A method and apparatus for providing a meshed power and signal bus system on an array type integrated circuit that minimizes the size of the circuit. In a departure from the art, through-holes for the mesh system are placed in the cell array, as well as the peripheral circuits. The power and signal buses of the mesh system run in both vertical and horizontal directions across the array such that all the vertical buses lie in one metal layer, and all the horizontal buses lie in another metal layer. The buses of one layer are connected to the appropriate bus(es) of the other layer using through-holes located in the array. Once connected, the buses extend to the appropriate sense amplifier drivers. The method and apparatus are facilitated by an improved subdecoder circuit implementing a hierarchical word line structure.

Abstract: In one embodiment, the present invention provides a method of treating a dielectric layer 24. First, the dielectric layer is heated while being subjected to an O.sub.2 plasma. After that, the dielectric layer is heated while being subject to an ozone environment. This method can be useful in forming a capacitor 12 dielectric 24. In turn, the capacitor could be used in a DRAM memory device.

Abstract: A method and apparatus for providing a meshed power and signal bus system on an array type integrated circuit that minimizes the size of the circuit. In a departure from the art, through-holes for the mesh system are placed in the cell array, as well as the peripheral circuits. The power and signal buses of the mesh system run in both vertical and horizontal directions across the array such that all the vertical buses lie in one metal layer, and all the horizontal buses lie in another metal layer. The buses of one layer are connected to the appropriate bus(es) of the other layer using through-holes located in the array. Once connected, the buses extend to the appropriate sense amplifier drivers. The method and apparatus are facilitated by an improved subdecoder circuit implementing a hierarchical word line structure.

Abstract: A method for forming a semiconductor memory device storage cell structure having an increased surface area. The storage cell structure has one or more rough polysilicon surfaces formed by depositing the polysilicon under conditions that result in gas phase dominant nucleation.

Abstract: A single polysilicon memory cell (10) provides a positive low programming and erase voltage together with a small cell size and includes P substrate (12) and P-well (14) formed within P substrate (12). NMOS transistor (16) is formed within P-well (14). N.sup.+ control gate (26) is formed in P-well (14) and includes punch-through implant region (26). NMOS transistor (16) and N.sup.+ control gate (26) have in common electrically isolated polysilicon gate (22, 32) for operating as a floating gate in common with NMOS transistor (16) and N.sup.+ control gate (26). N.sup.+ control gate (26) includes P-channel punch-through implant (34) for increasing the capacitive coupling ratio. This improves programming and erasing efficiency within single polysilicon memory cell (10).

Abstract: A method and apparatus for providing a meshed power and signal bus system on an array type integrated circuit that minimizes the size of the circuit. In a departure from the art, through-holes for the mesh system are placed in the cell array, as well as the peripheral circuits. The power and signal buses of the mesh system run in both vertical and horizontal directions across the array such that all the vertical buses lie in one metal layer, and all the horizontal buses lie in another metal layer. The buses of one layer are connected to the appropriate bus(es) of the other layer using through-holes located in the array. Once connected, the buses extend to the appropriate sense amplifier drivers. The method and apparatus are facilitated by an improved subdecoder circuit implementing a hierarchical word line structure.

Abstract: In a semiconductor device having two N type regions separated by a P type region, a channel stop is needed to prevent shorting between the two N type regions. The channel stop of the invention has oxide isolators over the two N type regions and a P+ type diffusion lying between the oxide isolators in the P type region. When the N type regions are phosphorus doped deep N- regions biased at different potentials and the P type region is a boron doped P- region, a shallow P+ boron region within the P- region acts as a blocking mechanism to prevent phosphorus from piling up at the semiconductor surface and shorting the two N- regions. The channel stop may be manufactured without adding additional steps to a CMOS process flow. The oxide isolators may be formed when the oxide isolator over the inverse moat separating the P tank and the N tank is created. The P+ region within the channel maybe formed when the sources and drains for transistors within the N tank are formed.

Abstract: A method of reducing gated diode leakage in trench capacitor type field plate isolated dynamic random access memory devices is disclosed. Trenches are etched into a face of a body of semiconductor material. Storage nodes surrounding the trenches are created. A polysilicon layer is formed on the trench walls. A storage dielectric layer is formed on the trench walls, adjacent to the layer of polysilicon on the trench walls, so that the layer of polysilicon on the trench walls lies between the storage dielectric layer and the storage node. The layer of polysilicon on the trench walls reduces leakage current from the storage node. A trench type field plate isolated random access memory cell structure is also disclosed.

Abstract: A method is disclosed for preventing formation of undesirable polysilicon word line gate filaments in integrated circuit devices such as VLSI dynamic random access memories employing field plate isolation. Before the word lines are processed, an oxide layer is formed in the field plate openings beneath sidewalls of nitride along the edges of the field plate openings. The oxide layer partially fills an undercut area beneath a dip out of the sidewall of nitride. The dip out of the sidewall of nitride is removed. The removal of the dip out and the partial filling of the undercut area reduces the possibility of polysilicon word line filaments from forming around the edge of the field plate openings in the undercut area when the word lines are later added. A field plate isolated memory device is also disclosed wherein along the edges of the field plate openings, the partially filling oxide layer and the sidewall nitride layer are approximately coincident.

Abstract: By placing boundary cells within areas of discontinuity of a memory array, such as in word line strap areas, stress on edge cells of the memory array is reduced; the reduction of stress improves leakage characteristics and pause-refresh capabilities of edge cells. The boundary cells may further be laid out in the areas of discontinuity with the same pattern as the memory array. Some of the boundary cells may be electrically biased to act as minority carrier sinks. By collecting minority carriers that otherwise may be attracted to edge cells of the memory array, the leakage characteristics of the edge cells and their pause-refresh capabilities are further enhanced. The boundary cells are particularly useful in improving leakage characteristics of dynamic random access memory devices of the trench capacitor type.

Abstract: An improved data recording system incorporates a detection circuit directly into the data read channel circuitry of the recording system to provide the capability of automatic self-testing and mapping of media flaws. The flaw detection circuit outputs an error signal in response to distortions in the readback signal caused by a defect on the medium. Firmware code is utilized for controlling the scanning of the medium by the flaw detection circuit and for recording the locations of the defects on the medium in response to the error signal. The detection circuit itself comprises a phase-splitter for splitting the readback signal into in-phase and quadrature-phase components. These components are then squared and summed to generate a phase independent flaw signal having an amplitude modulated in relation to the locations of the defects.

Abstract: A method of reducing gated diode leakage in trench capacitor type field plate isolated dynamic random access memory devices is disclosed. The storage node of the capacitor is formed by placing a storage node material, such as implanted arsenic, into the trench walls of the device at a first tilt and a second tilt. The angle of the second tilt is preferably larger, higher, than the angle of the first tilt. This higher angle provides the storage node with a larger concentration of doping around the upper portion the trench walls. This larger concentration of doping reduces the charge leaking from the upper portion of the storage node into the substrate of semiconductor material. A trench type storage capacitor for a dynamic random access memory device is also disclosed.

Abstract: A method of reducing gated diode leakage in trench capacitor type field plate isolated dynamic random access memory devices is disclosed. Trenches are etched into a face of a body of semiconductor material. Storage nodes surrounding the trenches are created. A polysilicon layer is formed on the trench walls. A storage dielectric layer is formed on the trench walls, adjacent to the layer of polysilicon on the trench walls, so that the layer of polysilicon on the trench walls lies between the storage dielectric layer and the storage node. The layer of polysilicon on the trench walls reduces leakage current from the storage node. A trench type field plate isolated random access memory cell structure is also disclosed.