Abstract: The present invention relates to a semiconductor device including a substrate layer, a metal-oxide-semiconductor field-effect transistor (MOSFET), a backgate region, an isolation layer and a diode. The MOSFET includes a gate region, a source region and a drain region. The source and drain regions are embedded in the backgate region, which includes a voltage input terminal. The isolation layer is located between the backgate region and the substrate layer and has a doping type opposite that of the backgate region. The diode includes a first terminal connected to the isolation layer and a second terminal coupled to an isolation voltage source.

Abstract: A semiconductor device is provided. An isolation structure is formed in a substrate to define a first and a second active region, and a channel active region therebetween. A field implant region is formed below a portion of the isolation structure around the first, second, and channel active regions. A channel active region includes two first sides defining a channel width. The distance from each first side to a second side of a neighboring field implant region is d1. The shortest distance from a third side of each first or second active region to an extension line of each second side of the field implant region is d2. R=d1/d2, where 0.15?R?0.85. A gate structure covers the channel active region and extends over a portion of the isolation structure. Source/drain doped regions are formed in the first and the second active regions.

Abstract: An object of the present invention is to provide a semiconductor device capable of radiating electron-beams only to a desired region without forming a layer for restricting the radiating rays. A source electrode 22 made of aluminum prevents the generation of bremsstrahlung even when the electron-beams are radiated to the source electrode in a exposed condition. Also, the source electrode having an opening 25 at above of a crystal defect region 11 is used as a mask when the electron-beams are radiated thereto. That is the source electrode made of aluminum can be used both as a wiring and a mask for the radiating rays.

Abstract: The invention relates to FETs with stripe cells (6). Some of the cells have alternating low and high threshold regions (10, 8) along their length. In a linear operations regime, the low threshold regions conduct preferentially and increase the current density, thereby reducing the risk of thermal runaway. By distributing the low threshold regions (10) along the length of the cells (6), the risk of current crowding is reduced.

Abstract: The high voltage integrated circuit comprises a P substrate. An N well barrier is disposed in the substrate. Separated P diffusion regions forming P wells are disposed in the substrate for serving as the isolation structures. The low voltage control circuit is located outside the N well barrier. A floating circuit is located inside the N well barrier. In order to develop a high voltage junction barrier in between the floating circuit and the substrate, the maximum space of devices of the floating circuit is restricted.

Abstract: A method for smoothing variations in threshold voltage in an integrated circuit layout. The method begins by identifying recombination surfaces associated with transistors in the layout. Such recombination surfaces are treated to affect the recombination of interstitial atoms adjacent such surfaces, thus minimizing variations in threshold voltage of transistors within the layout.

Abstract: A method for smoothing variations in threshold voltage in an integrated circuit layout. The method begins by identifying recombination surfaces associated with transistors in the layout. Such recombination surfaces are treated to affect the recombination of interstitial atoms adjacent such surfaces, thus minimizing variations in threshold voltage of transistors within the layout.

Abstract: Deep trench isolation structures and methods of formation thereof are disclosed. Several methods of and structures for increasing the threshold voltage of a parasitic transistor formed proximate deep trench isolation structures are described, including implanting a channel stop region into the bottom surface of the deep trench isolation structures, partially filling a bottom portion of the deep trench isolation structures with an insulating material, and/or filling at least a portion of the deep trench isolation structures with a doped polysilicon material.

Abstract: A metal oxide semiconductor field effect transistor includes a semiconductor substrate; a well region containing an impurity of a first conductivity type disposed on the semiconductor substrate, the well region including a source region and a drain region formed by adding an impurity of a second conductivity type, the source region and the drain region being separated from each other by a predetermined gap; an insulating film disposed on the surface of the well region in the gap between the source region and the drain region; and a gate electrode disposed on the insulating film. The well region is composed of an epitaxial layer, and the epitaxial layer includes an impurity layer of the first conductivity type having a different impurity concentration.

Abstract: A new method to form CMOS image sensors in the manufacture of an integrated circuit device is achieved. The method comprises providing a semiconductor substrate. Sensor diodes are formed in the semiconductor substrate each comprising a first terminal and a second terminal. Gates are formed for transistors in the CMOS image sensors. The gates comprise a conductor layer overlying the semiconductor substrate with an insulating layer therebetween. The transistors include reset transistors. Ions are implanted into the semiconductor substrate to form source/drain regions for the transistors. The source regions of the reset transistors are formed in the first terminals of the sensor diodes. Ions are implanted into the reset transistor sources to form double diffused sources. The implanting is blocked from other source/drain regions.

Abstract: An n-type drift region includes an active element region and a peripheral region. A p-type base region is formed at least in the active element region. A trench-type gate electrode is formed in each of the active element region and the peripheral region. An n-type source region formed in the base region. A plurality of p-type column regions is selectively formed separately from one another in each of the active element region and the peripheral region. In a peripheral region, a p-type guard region is formed below the gate electrode. In the active element region, the p-type guard region is not formed below the gate electrode. As a result, it is possible to hold the breakdown voltage in the peripheral region at a higher level than in the active element region while maintaining the low ON resistance due to a superjunction structure and to raise the breakdown voltage performance of the semiconductor device.

Abstract: Semiconductor devices can be fabricated using conventional designs and process but including specialized structures to reduce or eliminate detrimental effects caused by various forms of radiation. Such semiconductor devices can include the one or more parasitic isolation devices and/or buried guard ring structures disclosed in the present application. The introduction of design and/or process steps to accommodate these novel structures is compatible with conventional CMOS fabrication processes, and can therefore be accomplished at relatively low cost and with relative simplicity.

Abstract: A switching transistor includes a substrate having a substrate dopant concentration and a barrier region bordering on the substrate, having a first conductivity type and having a barrier region dopant concentration that is higher than the substrate dopant concentration. A source region is embedded in the barrier region, and has a second conductivity type and has a dopant concentration that is higher than the barrier region dopant concentration. A drain region is embedded in the barrier region and is offset from the source region. The draining region has the second conductivity type and a dopant concentration that is higher than the barrier region dopant concentration. A channel region extends between the source region and the drain region, wherein the channel region comprises a subregion of the barrier region. An insulation region covers the channel region and is disposed between the channel region and a gate electrode.

Abstract: Low voltage, middle voltage and high voltage CMOS devices have upper buffer layers of the same conductivity type as the sources and drains that extend under the sources and drains and the gates but not past the middle of the gates, and lower bulk buffer layers of the opposite conductivity type to the upper buffer layers extend from under the upper buffer layers to past the middle of the gates forming an overlap of the two bulk buffer layers under the gates. The upper buffer layers and the lower bulk buffer layers can be implanted for both the NMOS and PMOS FETs using two masking layers. For middle voltage and high voltage devices the upper buffer layers together with the lower bulk buffer layers provide a resurf region.

Abstract: Systems and methods for voltage distribution via multiple epitaxial layers. In accordance with a first embodiment of the present invention, an integrated circuit comprises a wafer substrate of a connectivity type. A first epitaxial layer of a connectivity type is disposed upon a second epitaxial layer of an opposite connectivity type, which is disposed upon the wafer substrate.

Abstract: The invention relates to layers in substrate wafers. The aim of the invention is to provide layers in substrate wafers with which the drawbacks of conventional assemblies are overcome in order to achieve, on the one hand, an adequate resistance to latch-up in highly scaled, digital CMOS circuits with comparatively low costs and, on the other hand, to ensure low substrate losses/couplings for analog high-frequency circuits and, in addition, to influence the component behavior in a non-destructive manner.

Abstract: A high-frequency switching transistor comprises a substrate having a substrate dopant concentration and a barrier region bordering on the substrate, which has a first conductivity type, wherein a barrier region dopant concentration is higher than the substrate dopant concentration. Further, the high-frequency switching transistor comprises a source region embedded in the barrier region, which comprises a second conductivity type different to the first conductivity type, and has a source region dopant concentration, which is higher than the barrier region dopant concentration. Additionally, the high-frequency switching transistor comprises a drain region embedded in the barrier region and disposed offset from the source region, which comprises the second conductivity type and has a drain region dopant concentration, which is higher than the barrier region dopant concentration.

Abstract: A semiconductor device has a channel termination region for using a trench (30) filled with field oxide (32) and a channel stopper ring (18) which extends from the first major surface (8) through p-well (6) along the outer edge (36) of the trench (30), under the trench and extends passed the inner edge (34) of the trench. This asymmetric channel stopper ring provides an effective termination to the channel (10) which can extend as far as the trench (30).

Abstract: Semiconductor devices and memory cells are formed using silicon rich barrier layers to prevent diffusion of dopants from differently doped polysilicon films to overlying conductive layers or to substrates. A polycilicide gate electrode structure may be formed using the silicon rich barrier layers. Methods of forming the semiconductor devices and memory cells are also provided.

Abstract: A semiconductor integrated circuit device has a plurality of CMOS-type base cells arranged on a semiconductor substrate and m wiring layers, and gate array type logic cells are composed of the base cells and the wiring layers. Wiring within and between the logic cells is constituted by using only upper n (n<m) wiring layers. It becomes possible to shorten a development period and reduce a development cost when a gate array type semiconductor integrated circuit device becomes large in scale.

Abstract: An electrostatic discharge (ESD) device with a parasitic silicon controlled rectifier (SCR) structure and controllable holding current is provided. A first distance is kept between a first N+ doped region and a first P+ doped region, and a second distance is kept between a second P+ doped region and a third N+ doped region. In addition, the holding current of the ESD device can be set to a specific value by modulating the first distance and the second distance. The holding current is in inverse proportion to the first distance and the second distance.

Abstract: An FET (field effect transistor) having source, drain and channel regions of a conductivity type in a semiconductor body of opposite conductivity type. The channel region is located at the lower extremity of the source and drain regions so as to be spaced from the surface of the semiconductor body by a distance d.

Abstract: Semiconductor devices can be fabricated using conventional designs and process but including specialized structures to reduce or eliminate detrimental effects caused by various forms of radiation. Such semiconductor devices can include the one or more parasitic isolation devices and/or buried guard ring structures disclosed in the present application. The introduction of design and/or process steps to accommodate these novel structures is compatible with conventional CMOS fabrication processes, and can therefore be accomplished at relatively low cost and with relative simplicity.

Abstract: An object of the present invention is to provide a semiconductor device capable of radiating electron-beams only to a desired region without forming a layer for restricting the radiating rays. A source electrode 22 made of aluminum prevents the generation of bremsstrahlung even when the electron-beams are radiated to the source electrode in a exposed condition. Also, the source electrode having an opening 25 at above of a crystal defect region 11 is used as a mask when the electron-beams are radiated thereto. That is the source electrode made of aluminum can be used both as a wiring and a mask for the radiating rays.

Abstract: A high-voltage device structure includes a high-voltage device disposed on a semiconductor substrate. The semiconductor includes an active region and an isolation region, and the high-voltage device is disposed in the active region. The high-voltage device structure includes a source diffusion region of a first conductive type, a drain region of the first conductive type, and a gate longer than the source diffusion region and the drain diffusion region so as to form spare regions on both sides of the gate. The isolation region is outside the active region and surrounds the active region. In the isolation region, an isolation ion implantation region of a second conductive type and an extended ion implantation region are disposed to prevent parasitic current from being generating between the source diffusion region and the drain diffusion region.

Abstract: Semiconductor devices and memory cells are formed using silicon rich barrier layers to prevent diffusion of dopants from differently doped polysilicon films to overlying conductive layers or to substrates. A polycilicide gate electrode structure may be formed using the silicon rich barrier layers. Methods of forming the semiconductor devices and memory cells are also provided.

Abstract: A technology of restraining junction leakage in a semiconductor device is to be provided. There is provided a semiconductor device provided with a semiconductor substrate, a gate electrode 9 formed on the semiconductor substrate, and a source/drain region formed beside the gate electrode, wherein the source/drain region 4 comprises a first impurity diffusion region including a first P-type impurity and located in the proximity of a surface of the semiconductor substrate, and a second P-type impurity diffusion region located below the first impurity diffusion region and including a second P-type impurity having a smaller diffusion coefficient in the semiconductor substrate than the first P-type impurity.

Abstract: A method of fabricating an integrated circuit utilizes symmetric source/drain junctions. The process can be utilized for P-channel or N-channel metal oxide field semiconductor effect transistors (MOSFETS). The drain extension is deeper than the source extension. The source extension is more conductive than the drain extension. The transistor has reduced short channel effects and strong drive current and yet is reliable.

Abstract: The invention relates to an integrated CMOS circuit comprising, in a semiconductor substrate (1) with a first type of conductivity, a casing (2) of a second type of retrograde-doped conductivity, the end of said casing being covered by an inter-casing insulating region (4). The components contained in said casing are separated from each other by means of intra-casing insulating regions (6,7). The first insulating elements (15) of the second type of high-level doping conductivity extend under each intra-casing insulating region. A second region (21) of the second type of high-level doping conductivity partially extends under the inter-casing insulator beyond the periphery of each casing.

Abstract: A MIS type semiconductor device and a method for fabricating the same characterized in that impurity regions are selectively formed on a semiconductor substrate or semiconductor thin film and are activated by radiating laser beams or a strong light equivalent thereto from above so that the laser beams or the equivalent strong light are radiated onto the impurity regions and on an boundary between the impurity region and an active region adjoining the impurity region.

Abstract: A ring-shaped P+ type diffusion region is formed on the top surface of a P type substrate in such a way as to surround a single internal circuit region. A shunt wiring is formed in an area including directly above the P+ type diffusion region on the P type substrate. The shunt wiring is connected to the P+ type diffusion region by a plurality of contacts. The shunt wiring is provided with an annular ring portion surrounding the internal circuit region. A meander inductor led out from the ring portion and the one end of the meander inductor is connected to a ground potential wiring. A resonance circuit is formed by a parasitic capacitor and the inductance of the shunt wiring. The parasitic capacitor is formed between the shunt wiring and the P+ type diffusion region on the P type substrate.

Abstract: The invention encompasses a method of forming a semiconductor-on-insulator construction. A substrate is provided. The substrate includes a semiconductor-containing layer over an insulative mass. The insulative mass comprises silicon dioxide. A band of material is formed within the insulative mass. The material comprises one or more of nitrogen argon, fluorine, bromine, chlorine, iodine and germanium.

Abstract: Complementary metal-oxide-semiconductor (CMOS) integrated circuits with bipolar transistors and methods for fabrication are provided. A bipolar transistor may have a lightly-doped base region. To reduce the resistance associated with making electrical contact to the lightly-doped base region, a low-resistance current path into the base region may be provided. The low-resistance current path may be provided by a base conductor formed from heavily-doped epitaxial crystalline semiconductor. Metal-oxide-semiconductor (MOS) transistors with narrow gates may be formed on the same substrate as bipolar transistors. The MOS gates may be formed using a self-aligned process in which a patterned gate conductor layer serves as both an implantation mask and as a gate conductor. A base masking layer that is separate from the patterned gate conductor layer may be used as an implantation mask for defining the lightly-doped base region.

Abstract: In a semiconductor device such as MOSFET, a single crystal semiconductor substrate is provided. An epitaxitial layer is formed on the single crystal semiconductor substrate. A p-well regions are formed on the epitaxitial layer, respectively, and n+ source regions are formed on the p-well regions, respectively. A gate electrode is formed through a gate insulation film on a part of each p-well region and that of each n+ source region. The gate electrode is covered with an insulation film. On the insulation film, a source electrode is formed so that the n-channel MOSFET includes body diodes BD imbedded therein. A drain electrode is formed on the single crystal semiconductor substrate. A cluster-containing layer is implanted in the single crystal semiconductor substrate as a gettering layer so that the cluster-containing layer contains a cluster of nitrogen.

Abstract: A semiconductor arrangement including: a substrate having a substrate layer (13) with an upper and lower surface, the substrate layer (13) being of a first conductivity type; a first buried layer (12) in the substrate, extending along said lower surface below a first portion of said upper surface of said substrate layer (13), and a second buried layer (12) in the substrate, extending along said lower surface below a second portion of said upper surface of said substrate layer (13); a first diffusion (26) in said first portion of said substrate layer (13), being of a second conductivity type opposite to said first conductivity type and having a first distance to said first buried layer (12) for defining a first breakdown voltage between said first diffusion (26) and said first buried layer (12); a second diffusion (45) in said second portion of said substrate layer (13), being of said second conductivity type and having a second distance to said second buried layer (12) for defining a second breakdown volta

Abstract: Semiconductor devices and memory cells are formed using silicon rich barrier layers to prevent diffusion of dopants from differently doped polysilicon films to overlying conductive layers or to substrates. A polycilicide gate electrode structure may be formed using the silicon rich barrier layers. Methods of forming the semiconductor devices and memory cells are also provided. It is emphasized that this abstract is provided to comply with the rules requiring an abstract which will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that is will not be used to interpret or limit the scope or meaning of the claims. 37 CFR 1.72(b).

Abstract: The present invention relates to a technique that can be used to reduce the sensitivity of integrated circuits to a failure mechanism to which some integrated circuits (ICs) are susceptible, known as latchup. The present invention relates to a scheme for suppressing latchup sensitivity by a step to be performed after the IC has been manufactured, rather than being a step in the normal production process. The process involves exposing silicon, either in wafer or die form, to energetic ions, such as protons (hydrogen nuclei) or heavier nuclei (e.g. argon, copper, gold, etc.), having energy sufficient to penetrate the silicon from the back of the wafer or die to within a well-defined distance from the surface of the silicon on which the integrated circuit has been formed (the front surface).

Abstract: A method for fabricating a CMOS transistor is disclosed. The present invention provides a method for producing a CMOS transistor having enhanced performance since a short channel characteristic and operation power can be controlled by the duplicate punch stop layer of the pMOS region and the operation power of the nMOS is also controlled by dopant concentration of the duplicated LDD region combined by the first LDD region and the second LDD region.

Abstract: An asymmetrical channel implant from source to drain improves short channel characteristics. The implant provides a relatively high VT net dopant adjacent to the source region and a relatively low VT net dopant in the remainder of the channel region. One way to achieve this arrangement with disposable gate processing is to add disposable sidewalls inside the gate opening (after removing the disposable gate), patterning to selectively remove the source or gate side sidewalls, implant the source and drain regions and remove the remaining sidewall and the proceed. According to a second embodiment, wherein the channel implant can be symmetrical, a relatively low net VT implant is provided in the central region of the channel and a relatively high net VT implant is provided in the channel regions adjacent to the source and drain regions.

Abstract: A semiconductor device for a charge pump device suitable for providing large current capacity and preventing a latch up from occurring is offered. A first and a second N-type epitaxial silicon layers are stacked on a P-type single crystalline silicon substrate, and a P-type well region is formed in the second epitaxial silicon layer. A P+-type buried layer is formed abutting on a bottom of the P-type well region, and an MOS transistor is formed in the P-type well region. The MOS transistor has a first source layer N+S of high impurity concentration, a first drain layer N+D of high impurity concentration and a second source layer N?S and/or a second drain layer N?D of low impurity concentration, which is diffused deeper than the first source layer N+S of high impurity concentration and the first drain layer N+D of high impurity concentration.

Abstract: The present invention provides a semiconductor device, a method of manufacture therefor, and an integrated circuit including the same. The semiconductor device may include a doped buried layer located over a doped substrate and a doped epitaxial layer located over the doped buried layer. The semiconductor device may further include a first doped lattice matching layer located between the substrate and the buried layer and a second doped lattice matching layer located between the doped buried layer and the doped epitaxial layer.

Abstract: A CMOS device includes a p-channel MOS transistor and an n-channel MOS transistor having a structure formed on a (100) surface of a silicon substrate and having a different crystal surface, a high-quality gate insulation film formed on such a structure by a microwave plasma process, and a gate electrode formed thereon, wherein the size and the shape of the foregoing structure is set such that the carrier mobility is balanced between the p-channel MOS transistor and the n-channel MOS transistor.

Abstract: Junction field effect transistors (JFETs) can be fabricated with an epitaxial layer that forms a sufficiently thick channel region to enable the JFET for use in high voltage applications (e.g., having a breakdown voltage greater than about 20V). Additionally or alternatively, threshold voltage (VT) implants can be introduced at one or more of the gate, source and drain regions to improve noise performance of the JFET. Additionally, fabrication of such a JFET can be facilitated forming the entire JFET structure concurrently with a CMOS fabrication process and/or with a BiCMOS fabrication process.

Abstract: An electronic device architecture is described comprising a field effect device in an active region 22 of a substrate 10. Channel stop implant regions 28a and 28b are used as isolation structures and are spaced apart from the active region 22 by extension zones 27a and 27b. The spacing is established by using an inner mask layer 20 and an outer mask layer 26 to define the isolation structures.

Abstract: The semiconductor device comprises insulation films 30a-30f formed on a semiconductor substrate 10, and a thermal conductor 42 buried in the insulation films. The thermal conductor is formed on a tube structure of carbon atoms. The thermal conductor is formed on a tube structure of carbon atoms, which is a material of very high thermal conductivity, can effectively radiate heat of a very high generated in semiconductor elements, etc., such as transistors 24a, 24b, etc. Accordingly, the semiconductor device can have good heat radiation characteristics.

Abstract: A structure protects CMOS logic from substrate minority carrier injection caused by the inductive switching of a power device. A single Integrated Circuit (IC) supports one or more power MOSFETs and one or more arrays of CMOS logic. A highly doped ring is formed between the drain of the power MOSFET and the CMOS logic array to provide a low resistance path to ground for the injected minority carriers. Under the CMOS logic is a highly doped buried layer to form a region of high recombination for the injected minority carriers. One or more CMOS devices are formed above the buried layer. The substrate is a resistive and the injected current is attenuated. The well in which the CMOS devices rest forms a low resistance ground plane for the injected minority carriers.

Abstract: The invention concerns a semi-conductor device comprising on a substrate: a first dynamic threshold voltage MOS transistor (10), with a gate (116), and a channel (111) of a first conductivity type, and a current limiter means (20) connected between the gate and the channel of said first transistor. In accordance with the invention, this first transistor is fitted with a first doped zone (160) of the first conductivity type, connected to the channel, and the current limiter means comprises a second doped zone (124) of a second conductivity type, placed against the first doped zone and electrically connected to the first zone by an ohmic connection. Application to the manufacture of CMOS circuits.

Abstract: A MOSFET fabrication methodology and device structure, exhibiting improved gate activation characteristics. The gate doping that may be introduced while the source drain regions are protected by a damascene mandrel to allow for a very high doping in the gate conductors, without excessively forming deep source/drain diffusions. The high gate conductor doping minimizes the effects of electrical depletion of carriers in the gate conductor. The MOSFET fabrication methodology and device structure further results in a device having a lower gate conductor width less than the minimum lithographic minimum image, and a wider upper gate conductor portion width which may be greater than the minimum lithographic image. Since the effective channel length of the MOSFET is defined by the length of the lower gate portion, and the line resistance is determined by the width of the upper gate portion, both short channel performance and low gate resistance are satisfied simultaneously.

Abstract: High performance (surface channel) CMOS devices with a mid-gap work function metal gate are disclosed wherein an epitaxial layer is used for a threshold voltage Vt adjust/decrease for the PFET area, for large Vt reductions (˜500 mV), as are required by CMOS devices with a mid-gap metal gate. The present invention provides counter doping using an in situ B doped epitaxial layer or a B and C co-doped epitaxial layer, wherein the C co-doping provides an additional degree of freedom to reduce the diffusion of B (also during subsequent activation thermal cycles) to maintain a shallow B profile, which is critical to provide a surface channel CMOS device with a mid-gap metal gate while maintaining good short channel effects. The B diffusion profiles are satisfactorily shallow, sharp and have a high B concentration for devices with mid-gap metal gates, to provide and maintain a thin, highly doped B layer under the gate oxide.

Abstract: An SOI chip having an isolation barrier. The SOI chip includes a substrate, an oxide layer deposited on the substrate, and a silicon layer deposited on the oxide layer. A gate is deposited above the silicon layer. A first metal contact is deposited above the gate to form an electrical contact with the gate. Second and third metal contacts are deposited to form electrical contacts with the silicon layer. The isolation barrier extends through the silicon layer and the oxide layer, and partially into the substrate, to block impurities in the oxide layer outside the isolation barrier from diffusing into the oxide layer inside the isolation barrier. The isolation barrier surrounds the gate, the first metal contact, the second metal contact, and the third metal contact—which define an active chip area inside the isolation barrier. A method of manufacturing the SOI chip is also disclosed.