Abstract: A lateral semiconductor device includes an alternating conductivity type layer for providing a first semiconductor current path in the ON-state of the device and for being depleted in the OFF-state of the device, that has an improved structure for realizing a high breakdown voltage in the curved sections of the alternating conductivity type layer.

Abstract: A transistor is formed with a source ballast resistor that regulates channel current. In an LDMOS transistor embodiment, the source ballast resistance may be formed using a high sheet resistance diffusion self aligned to the polysilicon gate, and/or by extending a depletion implant from under the polysilicon gate toward the source region. The teachings herein may be used to form effective ballast resistors for source and/or drain regions, and may be used in many types of transistors, including lateral and vertical transistors operating in a depletion or an enhancement mode, and BJT devices.

Abstract: A high voltage device prevents or minimizes the lowering of a maximum operating voltage range. Bulk resistances of the drift regions are reduced by forming trenches within the drift regions and filling the trenches with conductive polysilicon layers. The polysilicon layers reduce the bulk resistances and prevents or minimizes the operation of parasitic bipolar junction transistors typically formed when the high voltage device is manufactured.

Abstract: A power IC for an automobile engine control unit incorporating at least one semiconductor device comprising an N-channel insulated-gate filed-effect transistor formed on an SOI substrate, having an N-type layer having a concentration higher than a concentration of an N-type layer in contact with a p-body layer contacting a gate oxide film of the transistor. The high concentration N-type layer is formed in a region covering at most 95% of the source-drain distance between the p-body layer and a drain electrode of the transistor in the silicon substrate over an interface of a buried oxide film, the silicon substrate being in contact with both the field oxide film and the high concentration N-type layer contacting the drain electrode.

Abstract: Systems, devices and methods are provided to improve performance of integrated circuits by providing a low-k insulator. One aspect is an integrated circuit insulator structure that includes a vapor-deposited dielectric material. The dielectric material has a predetermined microstructure formed using a glancing angle deposition (GLAD) process. The microstructure includes columnar structures that provide a porous dielectric material. One aspect is a method of forming a low-k insulator structure. In one embodiment, a predetermined vapor flux incidence angle &thgr; is set with respect to a normal vector for a substrate surface so as to promote a dielectric microstructure with individual columnar structures. Vapor deposition and substrate motion are coordinated so as to form columnar structures in a predetermined shape. Other aspects are provided herein.

Abstract: A lateral RF MOS transistor with at least one conductive plug structure comprising: (1) a semiconductor material of a first conductivity type having a first dopant concentration and a top surface; (2) a conductive gate overlying and insulated from the top surface of the semiconductor material; (3) at least two enhanced drain drift regions of the second conductivity type of the RF MOS transistor; the first region laying partially underneath the gate; the second enhanced drain drift region contacting the first enhanced drain drift region, the dopant concentration of the second enhanced drain drift region is higher than the dopant concentration of the first enhanced drain drift region; (4) a drain region of the second conductivity type contacting the second enhanced drain drift region; (5) a body region of said RF MOS transistor of the first conductivity type with the dopant concentration being at least equal to the dopant concentration of the semiconductor epi layer; (6) a source region of the second conductivi

Abstract: A semiconductor device includes an elongated, blade-shaped semiconductor element isolated from a surrounding region of a semiconductor substrate by buried and side oxide layers. A polysilicon post disposed at one end of the element has a bottom portion extending through the buried oxide to contact the substrate, providing for electrical and thermal coupling between the element and the substrate and for gettering impurities during processing. A device fabrication process employs a selective silicon-on-insulator (SOI) technique including forming trenches in the substrate; passivating the upper portion of the element; and performing a long oxidation to create the buried oxide layer. A second oxidation is used to create an insulating oxide layer on the sidewalls of the semiconductor element, and polysilicon material is used to fill the trenches and to create the post.

Abstract: An integrated circuit having structure for isolating circuit sections having at least one differing characteristic. The structure includes a chip guard ring for each circuit section having the at least one differing characteristic. Providing multiple chip guard rings allows for isolation of circuit sections and prevention of ionic contamination, but without increased expense and size. In addition, it is practicable with any IC. The invention also may include an interconnect for electrical connectivity about a chip guard ring.

Abstract: A power MOSFET includes a semiconductor substrate having a drift region therein and first and second transition regions of first conductivity type that extend between the drift region and a first surface of the semiconductor substrate. Each of the first and second transition regions has a vertically retrograded first conductivity type doping profile therein that peaks at a first depth relative to the first surface. First and second shielding regions of second conductivity type are provided in the drift region and define respective P-N junctions with the first transition region. The shielding regions extending laterally towards each other in a manner that constricts a neck of the first transition region to a minimum width at a second depth relative to the first surface. An anode electrode is provided. The anode electrode that extends on the first surface of the semiconductor substrate and defines a Schottky rectifying junction with the second transition region.

Abstract: In a high voltage n-channel MOS structure, inserting p+ diffusion and an n-well into NMOS drain area, along with providing ESD protection by means of forming parasitic SCR, allows using signal of 5V and decreases snapback voltage below 2V.

Abstract: The invention concerns a monolithically integrated semiconductor component, having a first charge carrier region (12) of a first charge carrier doping; at least two second charge carrier regions (14) with opposite charge carrier doping, patterned within the first charge carrier region (12) at a spacing from one another; and third charge carrier regions (16), with the first charge carrier doping, patterned within the second charge carrier regions (14), a PN transition (22) being short-circuited between the second charge carrier regions (14) and the third charge carrier regions (16) via a contacting area (20) (source connection), the first charge carrier region (12) being equipped with a contact (18) (drain connection), and the second charge carrier regions (14) being invertable by means of a contacting area (26) in the region between the first charge carrier region (12) and the third charge carrier region (16); and having at least one Schottky diode (30) connected in parallel with the charge carrier region (12

Abstract: An LDMOS device is made on a semiconductor substrate 112. It has an N+ source and drain regions 120, 132 are formed within a P well region 122. An interlevel dielectric layer 140 encapsulates biased charge control electrodes 142a and they control the electric field within the area of the drift region 14 between P-base 122 and the N drain region 132 to increase the reverse breakdown voltage of the device. This permits the user to more heavily dope the drift region and achieve a lower on resistance.

Abstract: A semiconductor integrated circuit system includes first and second semiconductor devices formed on a substrate and required to have properties the same as each other in operation. The first and second semiconductor devices respectively includes first and second channel regions arranged in a surface of the substrate, and first and second gate electrodes disposed on the first and second channel regions via gate insulating films. A relaxing structure is arranged to reduce fluctuations in the properties of the first and second semiconductor devices, the fluctuations being caused by the electrical effects of plasma when a plasma process is performed. The relaxing structure includes first and second short-circuiting elements respectively connected to the first and second wiring layers and equivalent to each other. The first and second short-circuiting elements are configured to short-circuit the first and second gate electrodes with the first and second channel regions, respectively.

Abstract: A high voltage device and a method for fabricating the same are disclosed, which improves voltage-resistant characteristics to protect against high voltage applied to a gate electrode. The high voltage device includes a semiconductor substrate having first, second and third regions, the first region having sidewalls at both sides, and the second and third regions having a height higher than that of the first region at both sides of the first region. A channel region is formed within a surface of the substrate belonging to the first region including some of the sidewalls. A first insulating film is formed on a surface of the first region including the sidewalls. Buffer conductive films are formed to be adjacent to the sidewalls of the first region and isolated from each other. A second insulating film is formed between the buffer conductive films to have a recess portion. A third insulating film is formed on an entire surface including the buffer conductive films.

Abstract: A power MOSFET is provided that includes a substrate of a first conductivity type. An epitaxial layer also of the first conductivity type is deposited on the substrate. First and second body regions are located in the epitaxial layer and define a drift region between them. The body regions have a second conductivity type. First and second source regions of the first conductivity type are respectively located in the first and second body regions. A plurality of trenches are located below the body regions in the drift region of the epitaxial layer. The trenches, which extend toward the substrate from the first and second body regions, are filled with a material that includes a dopant of the second conductivity type. The dopant is diffused from the trenches into portions of the epitaxial layer adjacent the trenches.

Abstract: A method for fabricating a transistor configuration including at least one trench transistor cell has a gate electrode and a field electrode disposed in a trench below the gate electrode. The trenches are formed in a semiconductor substrate. A drift zone, a channel zone, and a source zone are in each case provided in the semiconductor substrate. According to the invention, the source zone and/or the channel zone are formed at the earliest after the introduction of the trenches into the semiconductor substrate by implantation and diffusion.

Abstract: A stack of integrated circuits in thin small outline packages (TSOP's) is constructed with an air space in between adjacent packages. The TSOP's have a plurality of connection terminals extending therefrom. A lead frame is disposed adjacent to the packages, positioned medially of the air space and having a plurality of connection terminals in registration with and in electric contact with the plurality of TSOP connection terminals. The TSOP's have a chip select terminal and several unused terminals. The lead frame has a strain-relieved conductor extending between the chip select terminal on a TSOP higher in the stack to the adjacent TSOP lower in the stack. Moreover, TSOP locating surfaces are included on the lead frame in the finished stack.

Abstract: A semiconductor device includes: an n+ type drain region; an n type drift region that connects with the n+ type drain region; a p type body region; a n+ type source region that connects with the p type body region; and a gate electrode that is provided, with being covered by a gate insulation film, in a gate trench that penetrates the p type body region. The semiconductor further includes: a p type silicon region that adjoins the n type drift region; and an n type silicon region provided in a region almost including a carrier passage that connects the n type drift region and the p type body region. Here, the p type silicon region and the p type body region directly connect with each other.

Abstract: A MOS trench structure integrated with a semiconductor device for enhancing the breakdown characteristics of the semiconductor device, comprises a semiconductor substrate, a plurality of parallel trenches formed in the semiconductor substrate, a peripheral trench formed in the semiconductor substrate and spaced from and at least partially surrounding the parallel trenches, a dielectric material lining the trenches, and a conductive material substantially filling the dielectric-lined trenches.

Abstract: A lateral high voltage transistor device is disclosed. The transistor includes a gate, a drain, and a source. The drain is located apart from the gate to form an intermediate drift region. The drift region has variable dopant concentration between the drain and the gate. In addition, a spiral resistor is placed over the drift region and is connected to the drain and either the gate or the source of the transistor.

Abstract: A high voltage device and a method for fabricating the same are disclosed, which improves voltage-resistant characteristics to protect against high voltage applied to a gate electrode. The high voltage device includes a semiconductor substrate having first, second and third regions, the first region having sidewalls at both sides, and the second and third regions having a height higher than that of the first region at both sides of the first region. A channel region is formed within a surface of the substrate belonging to the first region including some of the sidewalls. A first insulating film is formed on a surface of the first region including the sidewalls. Buffer conductive films are formed to be adjacent to the sidewalls of the first region and isolated from each other. A second insulating film is formed between the buffer conductive films to have a recess portion. A third insulating film is formed on an entire surface including the buffer conductive films.

Abstract: A power MOSFET is provided that includes a substrate of a first conductivity type. An epitaxial layer also of the first conductivity type is deposited on the substrate. First and second body regions are located in the epitaxial layer and define a drift region between them. The body regions have a second conductivity type. First and second source regions of the first conductivity type are respectively located in the first and second body regions. A plurality of trenches are located below the body regions in the drift region of the epitaxial layer. The trenches, which extend toward the substrate from the first and second body regions, are filled with an epitaxially layered material that includes a dopant of the second conductivity type. The dopant is diffused from the trenches into portions of the epitaxial layer adjacent the trenches.

Abstract: An n+ type emitter region and a p-type base region are formed in contact with one main surface of an n-type collector region, a p-type cathode region is formed in a ring shape in contact with the main surface so as to enclose the emitter region and the base region, the potential at the cathode region is sustained at a level equal to the potential at the emitter region and a p-type guard ring region is formed in a ring shape so as to enclose the cathode region. This structure prevents the base drive circuit from becoming damaged by an avalanche breakdown current.

Abstract: A semiconductor device comprising: a semiconductor substrate, a dielectric film formed on the semiconductor substrate, a first electrode and a second electrode separated from each other on the dielectric film; a spiral thin film layer having both ends connected to the first electrode and the second electrode, respectively, the spiral thin film layer surrounding the first electrode, the thin film layer being formed on the dielectric layer, and a plurality of p-n diodes formed in series in the spiral thin film layer along a longitudinal direction of the spiral thin film layer.

Abstract: In accordance with the invention, a semiconductor device having an electrical input/output contact surface is hermetically sealed and provided with connections via a submount such as a two-level ceramic substrate. The device is provided with a contact surface having a sealable peripheral contact and one or more interior contacts. The submount is provided with a peripheral sealable contact corresponding to the device peripheral contact and one or more feed-through contacts corresponding to the device interior contacts. The sealable peripheral contacts surround the interior contacts providing heremetic sealing.

Abstract: A power component formed in an N-type silicon substrate delimited by a P-type wall, having a lower surface including a first P-type region connected to the wall, and an upper surface including a second P-type region, a conductive track extending above the substrate between the second region and the wall. The component includes a succession of trenches extending in the substrate under the track and perpendicularly to this track, each trench being filled with an insulator.

Abstract: A phase splitter circuit includes a first signal transfer path for recieving an input signal to output a first output signal, a second signal transfer path for receiving the input signal to output a second output signal having an inverted phase of the first output signal, and a duty cycle correction circuit for controlling pull-up and pull-down speeds of the first and second signal transfer paths to the opposite direction in response to the first and second output signals. According to this structure, duty cycles of the first and second output signals approach 50% and a skew or delay time therebetween approaches “0.

Abstract: A field effect transistor semiconductor device (1) comprises a source region (33), a drain region (14) and a drain drift region (11), the device having a field shaping region (20) adjacent the drift region (11) and arranged such that, in use, when a voltage is applied between the source (33) and drain (14) regions and the device is non-conducting, a substantially constant electric field is generated in the field shaping region (20) and accordingly in the adjacent drift region (11). The field shaping region (20), which may be intrinsic semiconductor, is arranged to function as a capacitor dielectric region (20) between a first capacitor electrode region (21) and a second capacitor electrode region (22), the first and second capacitor electrode regions (21, 22) being adjacent respective ends of the dielectric region (20) and having different electron energy barriers.

Abstract: The semiconductor device of the present invention includes: a semiconductor layer of a first conductivity type; source and drain regions of a second conductivity type, which are formed within the semiconductor layer; a channel region provided between the source and drain regions; and a gate electrode formed over the channel region. The device further includes: a buried region of the first conductivity type, at least part of the buried region being included in the drain region; and a heavily doped region of the second conductivity type. The heavily doped region is provided at least between a surface of the semiconductor layer and the buried region. The concentration of a dopant of the second conductivity type in the heavily doped region is higher than that of the dopant of the second conductivity type in the drain region.

Abstract: A high-voltage transistor with a low specific on-state resistance and that supports high voltage in the off-state includes one or more source regions disposed adjacent to a multi-layered extended drain structure which comprises extended drift regions separated from field plate members by one or more dielectric layers. The layered structure may be fabricated in a variety of orientations. A MOSFET structure may be incorporated into the device adjacent to the source region, or, alternatively, the MOSFET structure may be omitted to produce a high-voltage transistor structure having a stand-alone drift region. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: A P channel high voltage metal oxide semiconductor device is described which is integrated in the same chip or wafer as standard P channel and N channel metal oxide semiconductor devices. The high voltage device has a lightly doped p− drift region adjacent to the heavily doped p+ drain region. A high voltage support region is formed directly below the drift region using high energy ion implantation with an implantation energy of between about 2 and 3 Mev. This high energy ion implantation is used to precisely locate the high voltage support region directly below the drift region. This high voltage support region avoids punch-through from the P channel drain through the drift region into the substrate while using a standard depth for the n type well. This allows the high voltage device to be integrated into the same chip or wafer as standard P channel and N channel metal oxide semiconductor devices.

Abstract: A semiconductor component includes a first connection zone of a first conductivity type for providing a contact at a first side of a semiconductor body and a second connection zone of the first conductivity type for providing a contact at the second side of the semiconductor body. A drift zone adjoins the first connection zone and extends in a vertical direction of the semiconductor body as far as the second side of the semiconductor body. A body zone of a second conductivity type is disposed between the second connection zone and the first connection zone or the drift zone. A control electrode is insulated from the semiconductor body and disposed above the body zone such that the control electrode substantially does not overlap with the drift zone and the second connection zone in a lateral direction. A method for manufacturing a semiconductor component is also provided.

Abstract: A light shield film is provided adjacent to an anode of an EL element that consists of the anode, an EL layer, and a cathode. The anode and the cathode are transparent or semitransparent to visible light and hence transmit EL light. With this structure, ambient light is absorbed by the light shield film and does not reach an observer. This prevents an external view from appearing on the observation surface.

Abstract: A semiconductor device includes a semiconductor substrate having a first conductive type impurity, a well having a second conductive type impurity formed in a predetermined region of the semiconductor substrate, a plurality of field oxide layer formed on an upper surface of the semiconductor substrate having the first conductive type impurity and the well having the second conductive type impurity, a gate electrode formed on corresponding portions of the field oxide layer and the well, and a lightly doped first impurity region formed in the well between the gate electrode and the first conductive type impurity region and surrounding the first conductive impurity region from sides and lower portions thereof and relatively lightly doped in comparison to the first conductive type impurity region.

Abstract: A field effect transistor structure is formed with a body semiconductor layer (5) having source (9), body (7), drift region and drain (11). An upper semiconductor layer (21) is separated from the body by an oxide layer (17). The upper semiconductor layer (21) is doped to have a gate region (23) arranged over the body (7), a field plate region (25) arranged over the drift region 13 and at least one p-n junction (26) forming at least one diode between the field plate region (25) and the gate region (23). A source contact (39) is connected to both the source (9) and the field plate region (25).

Abstract: Pch-MOS transistors to which a power supply potential is applied are respectively surrounded by first trenches, and Nch-MOS transistors to which a ground potential is applied are respectively surrounded by second trenches. The first trenches are surrounded by a third trench, and the second trenches are surrounded by a fourth trench. A silicon layer existing inside the third trench is set at the power source potential. The silicon layer existing between the third and fourth trenches are set at a floating state. Accordingly, each thickness of oxide layers filling the trenches can be reduced.

Abstract: An improved n-channel integrated lateral DMOS (10) in which a buried body region (30), beneath and self-aligned to the source (18) and normal body diffusions, provides a low impedance path for holes emitted at the drain region (16). This greatly reduces secondary electron generation, and accordingly reduces the gain of the parasitic PNP bipolar device. The reduced regeneration in turn raises the critical field value, and hence the safe operating area.

Abstract: A semiconductor device includes a first semiconductor region having a first conductivity type, a second semiconductor region formed on the first semiconductor region and having the first conductivity type, a third semiconductor region formed in a surface of the second semiconductor region and having a second conductivity type, a fourth semiconductor region formed in the surface of the second semiconductor region and having the second conductivity type, and a gate structure formed on the second and fourth semiconductor region. The semiconductor device further includes a conductive member arranged in the trench extending from a surface of the fourth semiconductor region to the first semiconductor region, the trench having one sidewall surface flush with a sidewall surface of the gate structure.

Abstract: A high voltage vertical conduction semiconductor device has a plurality of deep trenches or holes in a lightly doped body of one conductivity type. A diffusion of the other conductivity type is formed in the trench walls to a depth and a concentration which matches that of the body so that, under reverse blocking, both regions fully deplete. The elongated trench or hole is filled with a dielectric which may be a composite of nitride and oxide layers having a lateral dimension change matched to that of the silicon. The filler may also be a highly resistive SIPOS which permits leakage current flow from source to drain to ensure a uniform electric field distribution along the length of the trench during blocking.

Abstract: Antenna size of conductive members is calculated with respect to an area of a gate oxide film of a transistor using an expression which approximates an actual relationship of changes therein, not using a simple proportional relationship. As a result, in design of a structure having conductive members connected to a gate oxide film of a transistor, it is possible to properly calculate an antenna size such as wire length of the conductive members with respect to an area of the gate oxide film.

Abstract: In a high breakdown voltage semiconductor device, a buried diffusion region is formed on a semiconductor substrate and an epitaxial layer is formed on the buried diffusion region and the substrate. The epitaxial layer includes a low breakdown voltage element region adjoined by a high breakdown voltage isolation region. A method for forming the high breakdown voltage isolation region complies with a Resurf condition by adjusting a thickness and an impurity concentration of the epitaxial layer. Thus, a high breakdown voltage semiconductor device and a manufacturing process therefor is provided, which includes a low breakdown voltage element region and a high breakdown voltage element region, and a high breakdown isolation region separates a high breakdown voltage region without impairing the characteristics of an element formed on the low breakdown voltage element region.

Abstract: One or more antennas are formed on an integrated circuit (IC) chip and connected to other circuitry on the IC chip. Antenna configurations include loop, multi-turn loop, square spiral, long wire, or dipole. The antenna may be formed to have two or more segments which can selectively be connected to one another to alter an effective length of the antenna. Two antennas may be formed in two different metallization layers separated by an insulating layer. Additionally, an antenna may be incorporated in a heat sink structure that is joined to the IC chip. IC chips having antennas are suitably included in a system or subsystem having electrical functionality, such as general purpose computers, telecommunications devices, and the like.

Abstract: A field effect transistor having a high breakdown withstand capacity is provided. An active region 7a is surrounded by a fixed potential diffusion layer 16, and a channel region 15 is formed in the active region 7a. A gate pad 35 is provided outside the fixed potential diffusion layer 16. Minority carriers injected at a peripheral region of the active region 7a flow into the fixed potential diffusion layer 16, which prevents breakdown attributable to concentration of the carriers. The fixed potential diffusion layer 16 is surrounded by a plurality of guard ring diffusion layers 171 through 174, and a pad diffusion layer 18 formed in a position under the gate pad 35 is connected to the innermost guard ring diffusion layer 171. Since this encourages expansion of a depletion layer under the gate pad 35, an increased breakdown voltage is provided.

Abstract: An integrated circuit (10) includes a P-epi substrate (12) having therein an n-well isolation layer (13) and a p-well (14) within the n-well. The p-well includes adjacent an upper surface thereof a p+ layer (18) having several elongate parallel openings (21-23) therethrough. Each of the openings has therein a respective n− RESURF layer (26-28). Each n− RESURF layer has therethrough a respective further elongate opening (31-33), and has a uniform horizontal thickness all around that opening. Each of the openings in the RESURF layers has therein an n+ finger (36-38). The p+ layer and the n+ fingers each have a vertical thickness which is greater than the vertical thickness of the n− RESURF layers. The p+ layer serves as the anode of a zener diode, and the n+ fingers are interconnected and serve as the cathode.

Abstract: The lateral RF MOS device having two drain drift regions and a conductive plug source connection structure is disclosed. The usage of two drain drift regions results in the increased source-drain breakdown voltage and in increased maximum drain current density. The lateral RF MOS device of the present intention can be used for high power and high frequency applications.

Abstract: A MOS type semiconductor apparatus is provided that includes a first MOS type semiconductor device through which main current flows, and a second MOS type semiconductor device through which current that is smaller than the main current flows. The first and second MOS type semiconductor devices provided on the same semiconductor substrate have substantially the same structure, and have a common drain electrode. A gate electrode of the second MOS type semiconductor device is connected to the common drain electrode. The semiconductor apparatus further includes a plurality of pairs of Zener diodes which are connected in series and provided between the source electrode of the second MOS type semiconductor device and the gate electrode of the first MOS type semiconductor device. Each pair of Zener diodes are reversely connected to each other.

Abstract: A gated semiconductor device comprising a substrate defining an active surface area including source regions, and a series of gates formed adjacent and insulated from the source regions. A source electrode contacts the source regions. A termination extends around the periphery of the active surface area, The termination comprises a gate electrode and a layer of conductive material electrically connected between the gate electrode and the gates. The layer of conductive material extends to the source electrode and incorporates a series of regions which are alternately N and P type so as to define a series of breakdown diode junctions distributed around the active surface area and interposed between tie gate electrode and source electrode, In normal operation gate current flows through portions of the conductive layer which do not incorporate diode junctions. In the event that the gate/source voltage exceeds a predetermined level, the diode junctions break down, shorting the gate to the source.

Abstract: An FET structure for utilization with a silicon-on-insulator semiconductor device structure. The structure includes a silicon-on-insulator substrate structure. Source and drain diffusion regions are provided on the silicon-on-insulator substrate. An FET body region is interconnected with the source and drain diffusion regions. A gate oxide region is arranged over at least a portion of the body region and the source and drain diffusion regions. A gate region is arranged over at least a portion of the gate oxide region. A diode is interconnected with and provides a conductive pathway between the gate region and the FET body region. The diode is electrically isolated from the FET source and drain regions and inversion channel by a high threshold FET region.

Abstract: A MOSFET has a buried shield plate under the gate and over the drain with the gate being formed on the periphery of the buried shield plate as a self-aligned structure with minimal or no overlap of the gate over the shield plate. Methods of fabricating the MOSFET are disclosed.

Abstract: A semiconductor integrated circuit has P-channel active MOSFETs and N-channel active MOSFETs formed in a semiconductor substrate. In order to electrically isolate the active MOSFETs, the semiconductor integrated circuit has P-channel field shield MOS devices and N-channel field shield MOS devices. The P-channel field shield MOS devices have field shield electrodes which are laid on regions between impurity diffusion regions of the P-channel active MOSFETs. The N-channel field shield MOS devices have field shield electrodes which are laid on regions between impurity diffusion regions of N-channel active MOSFETs. A P-channel field shield voltage, which is higher than a power supply voltage of the semiconductor integrated circuit, is supplied to the field shield electrodes of the P-channel field shield MOS device to turn the P-channel field shield MOS devices to an OFF-state to electrically isolate the P-channel active MOSFETs.