Abstract: Obtaining a semiconductor device which can reduce the occupied area of a capacitor in a logic circuit area while ensuring a constant capacitance without increasing the number of steps of fabricating the semiconductor device, and a method of fabricating the same. A first electrode of a capacitor is formed in the logic circuit area. A dielectric film consisting of a first interlayer isolation film is formed on the first electrode. A second electrode is formed on the first interlayer isolation film. A second dielectric film consisting of a second interlayer isolation film is formed on the second electrode. A third electrode is formed on the second interlayer isolation film. A connecting wire connects the first electrode and the third electrode with each other through openings in the first and third connecting regions.

Abstract: A system and method for providing a memory cell on a semiconductor is disclosed. The memory cell has a source and a drain. The method and system include providing a source implant in the semiconductor, providing a pocket implant in the semiconductor, and providing a drain implant in the semiconductor after the pocket implant is provided. Thus, short channel effects are reduced.

Abstract: A bipolar transistor designed to support a substantially uniform current density in base and collector regions to prevent the characteristic early fall-off of bipolar transistor current gain, and to improve the forward safe operating area performance. The advantages of the present invention are achieved by optimally spacing the neighboring emitters in relation to base thickness and further by maintaining a symmetrical topology by the self-aligned formation of emitters and base contacts. The spacing distance between the neighboring emitters does not exceed the base thickness. As a result, the current density below each emitter island is substantially uniform and the transistor as a whole can conduct a higher total current. Moreover, the transistor inhibits formation of current filaments and hot spots because the electric field in the collector region is uniform.

Abstract: A semiconductor package provided with a reinforcing plate on the side of the lead joined face of which a chip housing concave portion is formed, a semiconductor chip housed and fixed in the chip housing concave portion of this reinforcing plate, a plurality of leads joined and held on the lead joined face of the reinforcing plate, the inner lead section of which is joined to the semiconductor chip via a bump and in the outer lead section of which a protruded electrode is formed, a solder resist film formed on the lead except the bump formed area and the electrode formed area of this lead and a polyimide film formed on the side of the inner lead section of the lead on the solder resist film and the manufacturing method are disclosed and hereby, the quality of the semiconductor package with ultra-multipin structure is stabilized.

Abstract: Various processes are provided for producing a p-channel and/or n-channel transistor. The present processes are thereby applicable to NMOS, PMOS or CMOS integrated circuits, any of which derive a benefit from having an asymmetrical LDD structure. The asymmetrical structure can be produced on a p-channel or n-channel transistor in various ways. According, the present process employs various techniques to form an asymmetrical transistor. The various techniques employ processing steps which vary depending upon the LDD result desired. First, the LDD implant can be performed only in the drain-side of the channel, or in the drain-side as well as the source-side. Second, the gate conductor sidewall surface adjacent the drain can be made thicker than the sidewall surface adjacent the source.

Abstract: A design for a picker nest which protects any fragile component, such as a bare IC die, mounted on an IC package when the picker nest is holding the IC package for testing. The picker nest of the present invention includes a picker nest head having a picker nest opening with a vacuum suction. The fragile component fits within the picker nest opening as the picker nest is holding the IC package such that no contact force is exerted on the fragile component. The picker nest of the present invention also includes a conductive seal surrounding the perimeter of the picker nest opening for sealing in the vacuum suction within the picker nest opening. The conductive seal is a silicon-based sponge for effectively sealing in the vacuum suction at various temperatures. At least one supporting bar disposed on the picker nest head exerts a force against the IC package substrate toward test contacts of the testing system during testing of the IC package to ensure proper contact of the IC package pins to the test contacts.

Abstract: A method of forming a dielectric gate insulator in a transistor is disclosed herein. The method includes depositing a layer of material over a semiconductor structure; depositing a covering layer over the layer of material; selectively creating an aperture in the covering layer, wherein an area of the layer of material is exposed; providing thermal oxidation to the exposed area of the layer of material to produce an oxidized area; providing a gate over the oxidized area; and removing the covering layer.

Abstract: A nonvolatile cell comprising a first device comprising a first transistor type and a second device comprising a second transistor type. The first device may have a gate, a source, a drain and a gate oxide layer over the gate. The second device may have a gate, a source, a drain and a floating gate formed between the gate of said first device and the gate of the second device. The floating gate may be configured to store a charge in response to (i) a first voltage applied to the source and drain of said first device and (ii) a second voltage applied to the source and drain of the second device.

Abstract: The invention relates to a method of manufacturing a discrete or integrated bipolar transistor comprising a base (1A), an emitter (2) and a collector (3). The base (1A) and a connecting region (1B) of the base (1A) are formed by providing a semiconductor body (10) with a doped semiconducting layer (1) which locally borders on a monocrystalline part (3) of the semiconductor body which forms the collector (3). Outside said base, the layer (1) borders on a non-monocrystalline part (4) of the semiconductor body (10) and forms a non-monocrystalline connecting region (1B) of the base (1A). By means of a mask (5), the doping concentration of the layer (1) outside the mask (5) is selectively increased, resulting in a highly conducting connection region (1B) and a very fast transistor. In the known method, an ion implantation is used for this purpose.

Abstract: A method of forming a capacitor. A substrate comprises a cell array area and a peripheral area. A dielectric layer is formed on the substrate. The covering layer is formed on the dielectric layer. The contact electrode is formed through the dielectric layer and the covering layer. The first oxide layer is formed over the substrate. A portion of the first oxide layer is removed to form an opening, which exposes the contact electrode. A conformal preserve layer is formed over the substrate. A second oxide layer is formed over the substrate. A portion of the second oxide layer in the cell array area is removed to form an opening, which exposes the contact electrode. A conformal first conductive layer is formed over the substrate to cover the second oxide layer and the opening. A third oxide layer is formed over the substrate to cover the first conductive layer and fill the opening.

Abstract: A method is provided for forming a triple well of a semiconductor memory device, where a second well of a second conductive type encloses a second well of a first conductive type. A single mask is used for ion implanting the base of the enclosing well and also the entire enclosed well, which inherently avoids misalignment. Additional doping is provided to the location where the sidewalls of the enclosing well join its base. This is accomplished either by a second, deeper ion implant of the sidewalls, or by ion implanting the base at an angle and rotating it, or both. Alternately, the single mask pattern is processed between the ion implantation steps to alter its width.

Abstract: In a process for manufacturing a thin film transistor having a semiconductor layer constituting source and drain regions and a channel forming region, by the semiconductor layer being made thinner in the source and drain regions than in the channel forming region a structure is realized wherein, at the boundary between the source region and the channel forming region and the boundary between the drain region and the channel forming region, portions where electric field concentrations occur are displaced from the portion where a channel is formed. By reducing the OFF current (the leak current) without also reducing the ON current, a high mutual conductance is realized.

Abstract: A method of fabricating a transistor. A first dielectric layer with a high dielectric constant is formed on a substrate. An oxide layer is formed on the first dielectric layer. A silicon nitride layer is formed on the oxide layer. The silicon nitride layer, the oxide layer, and the first dielectric layer are patterned to form a dummy gate structure. A spacer is formed on a sidewall of the dummy gate structure. The spacer and the dummy gate structure together form a dummy gate. An ion implantation step with the dummy gate serving as a mask and a thermal annealing step are performed to form a source region and a drain region on opposite sides of the dummy gate in the substrate. A second dielectric layer is formed next to the spacer. A top surface of the second dielectric layer is approximately level with a top surface of the dummy gate structure. The silicon nitride layer is removed. A nitridation process is performed to convert the oxide layer into a nitride layer.

Abstract: A pair of memory cells for use in a DRAM are formed in a monocrystalline bulk portion of a silicon wafer by first forming a pair of vertical trenches spaced apart by a bulk portion of the wafer. After a dielectric layer is formed over the walls of each trench, the trenches are each filled with polycrystalline silicon. By a pair of recess forming and recess filling steps there is formed at the top of each trench a silicon region that was grown epitaxially with the intermediate bulk portion. Each epitaxial region is made to serve as the body of a separate transistor having its drain in the lower polysilicon fill of a trench, and its source in the monocrystalline bulk intermediate between the two epitaxial regions. The lower polysilicon fill of each trench is also made to serve as the storage node of the capacitor of each cell, with the bulk serving as the other plate of the capacitor.

Abstract: A method of fabricating semiconductor memory devices which has sufficient cell isolation to achieve miniaturization at the 0.3 to 0.4 .mu.m level. In the semiconductor memory devices of the present application miniaturization is achieved by removing overlap allowances between each gate and each LOCOS and those between each diffusion layer and each LOCOS used to separate the above-described semiconductor memory elements.

Abstract: A semiconductor processing method of forming an electrically conductive interconnect line having an electrical conductive covering predominately coextensive therewith, includes, a) providing an conductive interconnect line over a first electrically insulating material, the line having a top and sidewalls; b) selectively depositing a second electrically insulating material layer over the interconnect line and the first insulating material in a manner which deposits a greater thickness of the second insulating material atop the interconnect line than a thickness of the second insulating material over the first insulating material; c) anisotropically etching the second insulating material layer inwardly to at least the first insulating material yet leaving second insulating material over the top and the sidewalls of the interconnect line; and d) providing an electrically conductive layer over the anisotropically etched second insulating layer to form a conductive layer which is predominately coextensive with the

Abstract: A semiconductor device includes a first transistor (52) and gated diode (50) formed at a face of a semiconductor layer (56). The first transistor (52) includes a source region (60a), a drain region (60b), a gate oxide layer (62), and a conductive gate (64). The gated diode (54) includes a first moat region (66a), a second moat region (66b), a gate oxide layer (68), and a conductive gate (70). A first conductor (77) connects the conductive gate (70) of the gated diode (54) to the semiconductor layer (56) and a second conductor (76) connects the moat regions (66a, 66b) of the gated diode (54) to the conductive gate (64) of the first transistor (52). Gated diode (54) has a reduced breakdown voltage relative to the gate oxide layer (62) of first transistor (52) and thus establishes a leakage path to semiconductor layer (56) to direct leakage current to semiconductor layer (56), thereby inhibiting charge from accumulating on the gate oxide layer (62) of first transistor (52).

Abstract: A field effect transistor is manufactured by forming an isolating structure on a semiconductor substrate to define an active area. A gate structure is formed which is insulated from a surface of the active area of the semiconductor substrate. An amorphous silicon film is formed on the gate structure, on the surface of the semiconductor substrate, and on the isolating structure. A first portion of the amorphous silicon film is converted to an epitaxial film and a second portion of the amorphous silicon film is converted to a polysilicon film. Impurities are diffused throughout the polysilicon film and into an upper surface portion of said epitaxial film. The impurity doped polysilicon film and the upper surface portion of the epitaxial film are oxidized to form oxide films and the oxide films are removed so that the epitaxial film remains at least on the active area of the semiconductor substrate. Source and drain regions of the transistor are formed in the active area of the semiconductor substrate.

Abstract: An integrated circuit field effect transistor includes a multilayer gate electrode having a first conductive layer and a second conductive layer on the first conductive layer, wherein the second conductive layer is wider than the first conductive layer. The first conductive layer may be formed of titanium nitride and the second conductive layer may be formed of tungsten, copper and/or titanium silicide. The first conductive layer may be recessed relative to the second conductive layer by wet etching using a solution of hydrogen peroxide or hydrogen peroxide and sulfuric acid.

Abstract: An SOI semiconductor substrate and a fabrication method therefor which are capable of preventing a depletion region due to a fixed electric charge occurring at a junction surface from being formed in a silicon wafer within which an integrated circuit is to be formed. The SOI semiconductor substrate includes a first silicon wafer, a first oxide layer formed on an upper surface of the first silicon wafer, an undoped polysilicon layer formed on an upper surface of the first oxide layer, and a second silicon wafer formed on an upper surface of the polysilicon layer.