Abstract: A semiconductor device and method of manufacturing the same are provided. A trench is formed in a semiconductor substrate. A thin oxide liner is preferably formed on surfaces of the trench. After formation of the oxide liner, first regions of the semiconductor substrate are masked, leaving second regions thereof exposed. N-type devices are to be formed in the first regions and p-type devices are to be formed in the second regions. N-type ions may then be implanted into sidewalls of the trenches in the second regions. The mask is stripped and formation of the semiconductor device may be carried out in a conventional manner. The n-type ions are preferably only implanted into sidewalls where PMOSFETs are formed.

Abstract: A semiconductor device improved to suppress a leakage current of a transistor is provided. A gate electrode is disposed on a semiconductor substrate. A pair of p type source/drain layers are provided on the surface of the semiconductor substrate, on both sides of the gate electrode in the gate length direction Y. An n type gate width determining layer is provided on the surface of the semiconductor substrate to sandwich the source/drain layers in the width direction X of the gate electrode, which determines a gate width of the gate electrode. The source/drain layers and the gate width determining layer are isolated by PN junction.

Abstract: A fabrication method for fabricating a dual-gate CMOSFET on a semiconductor substrate according to the present invention includes: implanting ions of N-type impurity for forming a deep junction source and drain in a first region on the semiconductor substrate where an NMOSFET is to be formed; performing a first annealing process for activating the N-type impurity; implanting ions of P-type impurity for forming a deep junction source and drain in a second region on the semiconductor substrate where a PMOSFET is to be formed; and performing a, second annealing process for activating the P-type impurity. By performing the above processes in that order, the N-type impurity ions in the N+ polysilicon gate electrode of the NMOSFET are sufficiently activated, thus preventing the problem of depletion. Also, fluctuation of a threshold voltage because of penetration of the P-type impurity ions in the gate electrode of the PMOSFET can be prevented in the PMOSFET.

Abstract: The n-channel VDMOS transistor is formed in an n-type active region of an integrated circuit with junction isolation. To prevent over-voltages between source and gate which could damage or destroy the gate dielectric, a p-channel MOS transistor is formed in the same active region and has its gate electrode connected to the gate electrode of the VDMOS transistor, its source region in common with the source region of the VDMOS transistor, and its drain region connected to the p-type junction-isolation region. The p-channel MOS transistor has a threshold voltage below the breakdown voltage of the gate dielectric of the VDMOS transistor so that it acts as a voltage limiter.

Abstract: A semiconductor device capable of suppressing increase in the junction leakage current and preventing deterioration in the electric characteristics even when the device is miniaturized, and a method of manufacturing thereof are attained. The semiconductor device includes a semiconductor substrate, an isolation insulator, a gate electrode, a coating film, an interlayer insulation film, and a sidewall coating film. The semiconductor substrate has a main surface. The isolation insulator is formed at the main surface of the semiconductor substrate and isolates a conductive region. The gate electrode is formed in the conductive region. The coating film is formed on the isolation insulator, and it has a sidewall and a film thickness of at most that of the gate electrode. The interlayer insulation film is formed on the coating film. The sidewall coating film is formed on the sidewall of the coating film, and it includes a material having an etching rate different from that of the interlayer insulation film.

Abstract: An electronic amplifier circuit according to the principle of current detection is coupled to a memory cell field and has an input transistor for each respective row or column of the matrix array. The input transistor is connected to the respective row or column and can be driven and switched by a control signal of a multiplexer circuit. The amplifier circuit may be constructed as a gate circuit or as a transistor diode circuit. A matrix array of memory cells and a matrix array of photodetectors are also provided.

Abstract: A microlens of which surface is a conductive surface, or a solid state imaging device equipped with the microlens, in which the conductive surface can be given by a metal oxide film, a film containing carbon as a main component, a surface-modified film or the like.

Abstract: A twin-well CMOS integrated circuit device includes an n-well region and a p-well region. Each of the n-well and p-well region includes spaced-apart regions which serve as drain and source regions, a channel region between the spaced-apart regions, a shallow trench isolation structure contiguous with one of the spaced-apart regions, and a doped diffused region extending from the surface of the well region, around and underneath the trench isolation structure, to a region beneath the contiguous spaced-apart region.

Abstract: The present invention relates to electro optical devices with a reduced filter thinning on the edge pixels and a method for reducing the thinning of filter layers on the pixels closest to the edge of an electro optical device such as a photosensitive chip, as would be used, for example, in a full-color digital copier or scanner. A semiconductor wafer includes a main surface defining a plurality of chip areas and tab regions separated by grooves, wherein the chip areas include inner photosites, outer photosites and bonding pads. A plurality of dams are deposited over the main surface in the tab regions, and a clear layer is deposited over the main surface exclusive of the bonding pads. Alternatively, a clear layer is deposited over the main surface exclusive of the bonding pads, and a plurality of tabs is then deposited in the tab regions on the main surface.

Abstract: An integrated circuit with a passive component and an ESD device in accordance with the present invention has: a P substrate; an N+ buried layer implanted in the P substrate; a cathode coupled to the N+ buried layer with an N area formed between the cathode and the N+ buried layer; an anode coupled to the N+ buried layer with a P area formed between the anode and the N+ buried layer; and a first P+ buried layer implanted in the N+ buried layer and below the P area to form a Zener diode. In an alternative embodiment, the ESD device may be incorporated in an integrated circuit with an active component.

Abstract: The present invention provide a method for forming a triple well. The triple well includes an n-well, a first p-well surrounded with the n-well and a second p-well apart from the first p-well and adjacent to the n-well. According to the present invention, only one conductivity type of impurities are implanted in each well. Therefore, it is possible to prevent the decrease of the carrier mobility and increase of the leakage current.

Abstract: Integrated circuits suitable for high-performance applications, especially mixed signal products that have analog and digital sections, are fabricated from a semiconductor structure in which lower buried regions of opposite conductivity types are situated along a lower semiconductor interface between a semiconductive substrate and an overlying lower semiconductive layer. An upper buried region of a selected conductivity type is situated along an upper semiconductor interface between the lower semiconductive layer and an overlying upper semiconductive layer. Another upper buried region of opposite conductivity type to the first-mentioned upper buried region is preferably situated along the upper semiconductor interface. The upper semiconductive layer contains P-type and N-type device regions in which transistor zones are situated. The semiconductor structure is configured so that at least one of each of the P-type and N-type device regions is electrically isolated from the substrate.

Abstract: A vertical PNP transistor (11) and method for making it includes forming an N- region (19) in a P substrate (12), and forming an N+ region (26) in the substrate (12) laterally surrounding and partially extending into the N- region (19). A P region (30) is formed above the N- region (19), bounded laterally by the N+ region (26) to be horizontally and vertically isolated from the substrate (12) by the N- and N+ regions (19 and 26). A layer of semiconductor material (32) is formed overall, and an N well (35) and a surrounding P well (36) are formed, each extending to the P region (30). An isolating N+ well (38) is formed surrounding the P well (36), extending to the buried N+ region (26). A P emitter region (40) and an N base contact region (41) are formed at a surface of the N well (35), and a P collector contact region (44) is formed at a surface of the P well (36).

Abstract: In an NPN bipolar transistor having a special structure in which each impurity region is formed by ion implantation, a width of a base region is significantly reduced, and therefore, current amplification factor hfe is increased, resulting in improvement in performance thereof. Furthermore, a Bi-CMOS transistor can be manufactured using a CMOS process. The use of the bipolar transistor having a special structure for a driving circuit allows implementation of a driving circuit having large driving force with slight increase in cost.

Abstract: To accomplish the above objectives, the present invention provides a method of fabricating a collector well in a semiconductor BiCMOS device. The method begins by providing a substrate having c-well areas, N-well areas, and P-well areas. The substrate has n-plug doped regions in said c-well areas. A stress release oxide layer is grown over the substrate surface. A first nitride layer 27 is formed over the stress release oxide layer 26. A C-well mask 29having C-well mask openings 28A is formed over C-well areas 28 and openings are formed in the first nitride layer. Impurities are implanted through the opening forming collector-well regions. The c-well mask is then removed. A n-well photoresist mask having n-well mask openings 42A is formed over the first nitride layer and openings are etched in the first nitride layer over N-well areas 40. Ions impurities are implanted through the n-well nitride opening 42A forming n-well regions 44 in the n-well area in the substrate 10. The n-well mask 42 is then removed.