Abstract: A method for fabricating a MOS transistor having an offset resistance in a channel region controlled by a gate voltage and structure thereof is disclosed. A gate electrode is divided into three adjacent regions of respectively a second conductivity type, first conductivity type and second conductivity type connected laterally to one another on a channel region. A gate control voltage is applied to a central region of the first conductivity type, and a predetermined voltage between maximum and minimum values of the gate control voltage is applied to left and right adjacent regions of the second conductivity type. If a gate turn-on voltage is applied to the central region the gate turn-on voltage is forward biased to the adjacent left and right regions and is therefore also applied to the forwardly biased left and right regions. The effective length of the gate electrode then becomes the total length of the central region and the left and right adjacent regions.

Abstract: The present invention relates to a MOS transistor having floating source regions and floating drain regions.An epitaxial layer is grown on the channel regions of a semiconductor substrate in such a manner that the surface of the epitaxial layer makes a plane together with the upper surface of field oxide films, thereby enabling steps to be reduced.A polysilicon film is filled in recess regions formed by the growth of epitaxial layer and impurity-ions are implanted into the polysilicon film to form floating source regions and a floating drain regions.A buried oxide film is formed such a manner that it encloses the polysilicon film filled in the recess regions to prevent the junction leakage and to improve the characteristic of insulation.

Abstract: A method of manufacturing a semiconductor device includes the following steps. A silicon oxide film having a predetermined film thickness is formed on a smooth major surface of a first silicon substrate of a first conductivity type having a first region wherein a power transistor is to be formed. The major surface of the first silicon substrate is bonded to a smooth major surface of a second silicon substrate having one of the first conductivity type and a second conductivity type. The other surface of the second silicon substrate bonded to the first silicon substrate is polished to form a silicon layer having a predetermined film thickness and a second region wherein a transistor constituting a control circuit for driving the power transistor is to be formed. The silicon layer and the silicon oxide film are removed from a predetermined portion in the first region.

Abstract: A metal structure, such as an apparatus used in plasma processing of substrates, is rendered resistant to corrosion by coating components exposed to the plasma with a coating of rhodium. The rhodium coating can be made by electroplating, and preferably has a thickness of at least about 10 microinches, and preferably from about 10 to about 100 microinches. A coating of nickel can be applied between the rhodium coating and the metal component.

Abstract: A resonant tunneling transistor (400) with lateral carrier transport through tunneling barriers (404, 408) grown as a refilling of trenches etched partially into a transverse quantum well (410) and defining a quantum wire or quantum dot (406). The fabrication methods include use of angled deposition to create overhangs at the top of openings which define sublithographic separations for tunneling barrier locations.

Abstract: The invention increases withstand voltage and current capacity of a DMOS portion simultaneously built in by the BiCMOS process. The manufacturing method for the DMOS portion is comprised of steps of forming an ion-implanted layer in a surface of a P-type well; forming a gate electrode; self-aligning a P-type base region by employing the P-type base formation process of the bipolar transistor and by using the gate electrode as a mask; forming a side wall on a side face of the gate electrode by employing the process for forming the LDD structure of the CMOS; and self-aligning an N+type source region by employing the process for forming the N+type source and the drain of the CMOS and by using the side wall as a mask. The effective channel length becomes longer by the side wall length and the rate of heavily doped channel portion to the total channel length becomes high.

Abstract: This invention pertains to a lateral bipolar transistor comprising an emitter, a base and a collector. The transistor exhibits improved function and overall size reduction, due to the base and emitter structure. An island forms both the base and emitter regions in the transistor structure with the base region being above the collector region, below the emitter region, and surrounded by a dielectric region. The emitter is surrounded by emitter isolation walls, which are formed approximately 0.2 microns above the plane of the dielectric region, such that any manufacturing variances will not cause the emitter isolation walls to contact the dielectric region and pinch-off the base region from the base junction region. This structure also allows the size of the base-emitter junction to be decreased without increasing the parasitic characteristics of the transistor.

Abstract: A new method of forming a silicon-on-insulator device having a body node contact is dscribed. Active areas are isolated from one another within a silicon-on-insulator layer. Adjacent active areas are doped with dopants of opposite polarities to form at least one n-channel active area and at least one p-channel active area. Gate electrodes are formed over each active area. The area directly underlying the gate electrode and extending downward to the insulator layer comprises the body node. Lightly doped areas are formed beneath the spacers on the sidewalls of the gate electrodes. First ions are implanted into the active areas not covered by a mask whereby source and drain regions are formed in the at least one n-channel active area and whereby a p-channel body contact region is formed within the at least one p-channel active area wherein the p-channel body contact region contacts the p-channel body node.

Abstract: A solid state imaging device manufacturing process by which a solid state imaging device for a regular image and a solid state imaging device for a mirror image can be manufactured alternatively by a simple operation and a solid state imaging device which allows employment of an existing driving system as a driving system which includes a timing generator are disclosed. In manufacture, a solid state imaging device as an intermediate product is prepared first. The solid state imaging device includes an image section, a horizontal charge transfer section formed from a plurality of transfer electrodes having a fixed number of phases, and a pair of charge detection sections provided at the opposite ends of the horizontal charge transfer section.

Abstract: A process for the fabrication of a non-silicided region in an integrated circuit includes the fabrication of a silicide blocking layer (24, 46, 54, 92, 112). In one embodiment, a field transistor (80) is formed by depositing a silicide blocking layer (84) overlying a field gate electrode (70) and source and drain regions (76, 78). A carbonaceous mask (86) is formed on the silicide blocking layer (84) overlying the field transistor (80). A partial etching process is performed to remove a portion of the silicide blocking layer (84) exposed by the carbonaceous mask (86). Then, the carbonaceous mask (86) is removed and the etching process is continued to completely remove portions of the silicide blocking layer (84) not originally protected by the carbonaceous mask (86). The etching process forms a silicide blocking layer (92) overlying the field transistor (80) and sidewall (94) adjacent to an MOS gate electrode (68).

Abstract: An apparatus for forming a film by the CVD method allows reaction products to be easily removed from a gas discharge surface without decreasing the uptime/downtime ratio, and includes a gas distributor having a gas discharge surface for discharge of a reaction gas for forming a film on a substrate. A wafer holder has a wafer mounting surface facing the gas discharge surface. A cleaner has a suction head and a brush formed at the entrance of the suction head. A rotary shaft supports the cleaner for movement between the gas discharge surface and a stand-by position and brings the brush of the cleaner onto the gas discharge surface. A vertical positioner moves the wafer holder or gas distributor upward or downward, whereby the wafer holder approaches the gas discharge surface for forming a film and is spaced from the gas discharge surface when cleaning the gas discharge surface by movement of the cleaner on the gas discharge surface.

Abstract: A process for fabricating high-voltage MOSFET devices on a semiconductor substrate is disclosed. The substrate has heavily-doped impurities of a first conductivity type, and constitutes the drain region for the MOSFET. The process of fabrication comprises the steps of subsequently forming on the substrate a first doped layer, a second doped layer, a third doped layer and a shielding layer. All of these doped layers are of the first conductivity type. The second doped layer has an impurity concentration and a thickness smaller and larger than the impurity concentration and thickness respectively of the first doped layer, and larger and smaller than the impurity concentration and thickness respectively of the third doped layer. The impurity concentration of the first doped layer is smaller than the impurity concentration of the substrate. An opening in the shielding layer is formed, and then the source region of the MOSFET is formed in the area exposed by the opening.

Abstract: A structure and its fabrication method of an integrated semiconductor device including circuit elements such as MOSFETs. A well is formed in the semiconductor substrate within windows of a field oxide layer. A lightly-doped semiconductor layer is selectively formed on the exposed surface of the well. A channel region and a pair of source and drain regions of a MOSFET are formed in the lightly-doped semiconductor layer. The highly-doped buried semiconductor layer of the same conductivity type as that of the lightly-doped semiconductor layer is formed under the channel region in the lightly-doped semiconductor layer. The structural features and fabrication method provides a great degree of freedom in designing a MOSFET having a further shorter-channel length without deteriorating its drivability and punch-through breakdown voltage.

Abstract: A chemical vapor deposition apparatus comprises a reaction chamber for annealing a silicon wafer, a transportation mechanism for transporting the silicon wafer to the reaction chamber, a detecting device for detecting temperature of the reaction chamber, and an operation control device for receiving signals corresponding to the temperature of the reaction chamber, and supplying to the transportation mechanism, other signals for preventing the silicon wafer from being transported when the temperature is 100.degree. C. or more.

Abstract: A process for the fabrication of an improved LDMOS transistor, and such an improved LDMOS transistor are provided. The improved LDMOS transistor is in a semiconductor layer of a first conductivity type. The transistor has a source and drain of a second conductivity type (opposite the first conductivity type) and a channel of the first conductivity type with a conductive gate insulatively disposed over the channel. A low-voltage tank of the second conductivity type is used to contain the drain drift region and because of its lower sheet resistance provides a lower R.sub.DS (on). This tank of the second conductivity type extends from the field oxide at the exterior perimeter of the drain region, joins with the channel region and extends below the gate oxide and field oxide associated therewith.

Abstract: A self aligned, lateral-overflow drain antiblooming structure that is insensitive to drain bias voltages and therefore has improved insensitivity to process variations. The length of the antiblooming barrier regions are easily adjusted and determined by photolithography. The self aligned, lateral-overflow drain (LOD) antiblooming structure results in a design that saves space, and hence, improves overall sensor performance. In this structure, an antiblooming potential barrier is provided that is smaller (in volts) than the barriers that separate the pixels from one another so that excess charge will flow preferentially into the LOD as opposed to the adjacent pixels.

Abstract: A recess is formed (dug) into the surface of a substrate to form a gate channel in the recess, so that a monocrystalline source/drain region can be formed at a level higher than that of the channel. The process includes the steps of: (a) forming an insulating layer and an oxidation preventing layer on a semiconductor substrate, and removing the oxidation preventing layer of a channel region of the transistor by an etching process; (b) forming an oxide layer on the channel region of the transistor by thermally oxidizing the semiconductor substrate, removing the oxidation preventing layer, and carrying out a first ion implantation on the whole surface; (c) removing the oxide layer, and forming the channel of the transistor in the form of a recess so as for the recess to be positioned lower than the surface of the substrate; (d) forming a gate electrode in the recess; and (e) carrying out a second ion implantation on the whole surface, and carrying out a heat treatment to form a source/drain region.

Abstract: The new CCD output region provides a method of reducing the width of a wide CCD at its output to maintain a high sensitivity output node without sacrificing charge-transfer efficiency. A barrier region is shaped so the "channel width" of the CCD increases towards the input edge of the output gate. The barrier region, therefore, decreases in width towards the output end of the final CCD phase of a multi-phase device. Also, the channel width under the output gate decreases towards its output end in the direction of charge transfer towards the floating diffusion, or detection node. Since the "shaped" portion of the barrier region under the last CCD phase can be formed by the same process steps as the regular-shaped barrier regions, it is possible to form this structure without the requirement for additional masking and implant steps. The advantages of this structure over the prior art are improved charge-transfer characteristics without requiring additional process steps.

Abstract: A photoconductive isotype heterojunction impedance-matched infrared detector has blocking contacts which are positioned on the bottom side of the detector. The blocking contacts prevent transfer of minority carriers from the active region of the detector, thereby extending the lifetime of these carriers. The detector is formed by first fabricating an active layer followed by an isotype blocking layer on a growth substrate. These layers are etched and appropriate passivation layers and contacts are applied. A mechanical supporting substrate is applied to the detector and the growth substrate is removed. Etch stop holes are formed which extend into the active layer of the detector. A precision thickness of the active layer required in an impedance-matched detector design is produced by thinning the active layer in an etching process until the surface of the active layer reaches the etch stop hole.

Abstract: A lateral bipolar transistor capable of forming a narrow-sized diffusion region, such as a base width, is disclosed. The transistor exhibits no scattering in the direction of the depth of the width of the diffusion region. Emitter resistance is reduced by varying an impurity diffusion source at substantially a uniform concentration in a semiconductor portion and forming a diffusion region by diffusion from the impurity diffusion source. The bipolar transistor has an SOI structure. A method of making such device is also disclosed.