Abstract: A resistive mixer includes a LO matching circuit inserted between the gate of an FET and a LO terminal, a bias circuit that is connected to the gate and applies a bias voltage to the gate, an RF matching circuit inserted between the drain of the FET and an RF terminal, and an IF matching circuit inserted between the drain and an IF terminal. The source of the FET is grounded. The impedance of the RF matching circuit seen from the drain of the FET at an IF frequency is open-circuit, and the impedance of the IF matching circuit seen from the drain of the FET at an RF frequency is open-circuit.

Abstract: An electrostatic discharge robust semiconductor transistor (transistor) includes a semiconductor substrate of a first conductivity type, a substrate contact region of the first conductivity type coupled with the semiconductor substrate, a source region of a second conductivity type, a channel region of the second conductivity type, a gate region of the first conductivity type, a drain region having a first drain region of the first conductivity type and a second drain region of the second conductivity type, and an electrical conductor coupled over the second drain region and a portion of the first drain region. A portion of the first drain region not covered by the electrical conductor forms a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses. In implementations the transistor includes a silicon controlled rectifier (SCR) junction field effect transistor (SCR JFET) or a laterally diffused metal-oxide semiconductor (SCR LDMOS).

Abstract: The present invention provides a semiconductor device that prevents destruction due to an avalanche breakdown and that has a high tolerance against breakdown by configuring the device so as to have a punch-through breakdown function therein and such that the breakdown voltage of a punch-through breakdown is lower than an avalanche breakdown voltage so that an avalanche breakdown does not occur.

Abstract: A method of fabricating a replacement metal gate structure for a CMOS device. The method includes forming a dummy gate structure on an nFET portion and a pFET portion of the CMOS device; depositing an interlayer dielectric between the dummy gate structures; removing the dummy gate structures from the nFET portion and the pFET portion, resulting in a recess on the nFET portion and a recess on the pFET portion; depositing a first layer of titanium nitride into the recesses on the nFET portion and pFET portion; removing the first layer of titanium nitride from the nFET portion only; depositing a second layer of titanium nitride into the recesses on the nFET portion and pFET portion; depositing a gate metal onto the second layer of titanium nitride in the recesses on the nFET portion and pFET portion to fill the remainder of the recesses.

Abstract: A fin-type field effect transistor including at least one fin-type semiconductor structure, a gate strip and a gate insulating layer is provided. The fin-type semiconductor structure is doped with a first type dopant and has a block region with a first doping concentration and a channel region with a second doping concentration. The first doping concentration is larger than the second doping concentration. The blocking region has a height. The channel region is configured above the blocking region. The gate strip is substantially perpendicular to the fin-type semiconductor structure and covers above the channel region. The gate insulating layer is disposed between the gate strip and the fin-type semiconductor structure.

Abstract: The present invention relates to fabrication of enhancement mode and depletion mode High Electron Mobility Field Effect Transistors on the same die separated by as little as 10 nm. The fabrication method uses selective decomposition and selective regrowth of the Barrier layer and the Cap layer to engineer the bandgap of a region on a die to form an enhancement mode region. In these regions zero or more devices may be fabricated.

Abstract: According to an aspect of the invention, a method is provided for manufacturing electronic components. A conducting element comprising a first portion, a second portion and a third portion between the first portion and the second portion is provided. Thermally responsive dielectric material is added at least onto the third portion of the conducting element. Electric current is supplied between the first portion and the second portion of the conducting element causing ohmic heating to affix dielectric material located on the third portion to the third portion. Non-thermally-affixed dielectric material is removed.

Abstract: The disclosure relates generally to junction gate field effect transistor (JFET) structures and methods of forming the same. The JFET structure includes a p-type substrate having a p-region therein; an n-channel thereunder; and n-doped enhancement regions within the n-channel, each n-doped enhancement region separated from the p-region.

Abstract: A drift layer has a thickness direction throughout which a current flows and has an impurity concentration N1d for a first conductivity type. A body region is provided on a portion of the drift layer, has a channel to be switched by a gate electrode, has an impurity concentration N1b for the first conductivity type, and has an impurity concentration N2b for the second conductivity type greater than the impurity concentration N1b. A JFET region is disposed adjacent to the body region on the drift layer, has an impurity concentration N1j for the first conductivity type, and has an impurity concentration N2j for the second conductivity type smaller than the impurity concentration N1j. N1j?N2j>N1d and N2j<N2b are satisfied.

Abstract: A semiconductor-on-insulator structure includes a buried dielectric layer interposed between a base semiconductor substrate and a surface semiconductor layer. The buried dielectric layer comprises an oxide material that includes a nitrogen gradient that peaks at the interface of the buried dielectric layer with at least one of the base semiconductor substrate and surface semiconductor layer. The interface of the buried dielectric layer with the at least one of the base semiconductor substrate and surface semiconductor layer is abrupt, providing a transition in less than about 5 atomic layer thickness, and having less than about 10 angstroms RMS interfacial roughness. A second dielectric layer comprising an oxide dielectric material absent nitrogen may be located interposed between the buried dielectric layer and the surface semiconductor layer.

Abstract: A semiconductor device includes a first insulated-gate field-effect transistor which is disposed on a semiconductor substrate having an element formation plane in a (110) plane direction, and which has a channel length direction in a <?110> direction, a second insulated-gate field-effect transistor which is disposed on the semiconductor substrate, has a channel length direction in the <?110> direction, and neighbors the first insulated-gate field-effect transistor in the channel length direction, and a first liner insulation film which is provided in a manner to cover the first and second insulated-gate field-effect transistors, the first liner insulation film including a piezomaterial, having a positive expansion coefficient, and applying a compressive stress by operation heat to the first and second insulated-gate field-effect transistors in the channel length direction.

Abstract: The invention relates to an electroluminescent device (10) comprising a substrate (40) and on top of the substrate (40) a substrate electrode (20), a counter electrode (30) and an electroluminescent layer stack with at least one organic electroluminescent layer (50) arranged between the substrate electrode (20) and the counter electrode (30), and at least one electrical shunt means (122) applied on top of the substrate electrode (20) to improve the current distribution over the substrate electrode (20), wherein the at least one electrical shunt means (122) is at least one element of the group of a wire, a metallic stripe or foil, said electrical shunt means (122) fixed to the substrate electrode (20) by a protective means (70) fully covering the electrical shunt means (122) with a shape suitable to prevent the emergence of a shadowing edge on the substrate electrode (20). The invention further relates to a method to manufacture such a device.

Abstract: According to an aspect of the invention, there is provided a semiconductor device including a plurality of memory cells, comprising a plurality of floating gate electrodes which are formed on a tunnel insulating film formed on a semiconductor substrate and have an upper portion which is narrower in a channel width direction than a lower portion, an interelectrode insulating film formed on the floating gate electrodes, and a control gate electrode which is formed on the interelectrode insulating film formed on the floating gate electrodes and partially buried between the floating gate electrodes opposing each other.

Abstract: A LED lamp with straight tube comprises a tube body, a lamp cover sheathed at two ends of the tube body and a lamp strip which is in inserted connection in the tube body and comprises a circuit board and a heat diffuser; the lamp cover is internally, fixedly provided with a connecting device connected with the lamp strip; the connecting device comprises a connecting piece on which a connecting arm extending along the length direction of the lamp strip is arranged; the connecting arm is provided with a buckle body; the corresponding position on the surface of the lamp strip is provided with a buckle seat matched with the buckle body; and the circuit board is overlapped and adhered with the radiator to be into a whole through an insulating heat conducting layer.

Abstract: A light emitting device, includes: a casing; a window; a semiconductor laser provided in an enclosed space formed by the casing and the window; and a fluorescent material in a form of any one of a crystal and glass, the fluorescent material being provided in the enclosed space, the fluorescent material absorbing laser light emitted from the semiconductor laser and emitting secondary light having a wavelength different from a wavelength of the laser light, and the secondary light being taken out through the window.

Abstract: The invention relates to a nonvolatile semiconductor memory cell and to an associated fabrication method, a source region (7), a drain region (8) and a channel region lying in between being formed in a substrate (1). In order to realize locally delimited memory locations (LB, RB), an electrically non-conductive charge storage layer (3) situated on a first insulation layer (2) is divided by an interruption (U), thereby preventing, in particular, a lateral charge transport between the memory locations (LB, RB) and significantly improving the charge retention properties.

Abstract: According to an aspect of the invention, there is provided a semiconductor device including a plurality of memory cells, comprising a plurality of floating gate electrodes which are formed on a tunnel insulating film formed on a semiconductor substrate and have an upper portion which is narrower in a channel width direction than a lower portion, an interelectrode insulating film formed on the floating gate electrodes, and a control gate electrode which is formed on the interelectrode insulating film formed on the floating gate electrodes and partially buried between the floating gate electrodes opposing each other.

Abstract: Various illustrative embodiments of methods for manufacturing a semiconductor device are described. These methods may include, for example, forming a first polysilicon layer above a substrate, wherein the first polysilicon layer comprises a doped portion, and forming a second polysilicon layer over a surface of the first polysilicon layer. Also, various illustrative embodiments of semiconductor devices are described that may be manufactured such as by the various methods described herein.

Abstract: According to an aspect of the invention, there is provided a semiconductor device including a plurality of memory cells, comprising a plurality of floating gate electrodes which are formed on a tunnel insulating film formed on a semiconductor substrate and have an upper portion which is narrower in a channel width direction than a lower portion, an interelectrode insulating film formed on the floating gate electrodes, and a control gate electrode which is formed on the interelectrode insulating film formed on the floating gate electrodes and partially buried between the floating gate electrodes opposing each other.

Abstract: At least one source/drain zone (140, 142, 160, or 162) of an enhancement-mode insulated-gate field-effect transistor (120 or 122) is provided with graded junction characteristics to reduce junction capacitance, thereby increasing switching speed. Each graded junction source/drain zone contains a main portion (140M, 142M, 160M, or 162M) and a more lightly doped lower portion (140L, 142L, 160L, or 162L) underlying, and vertically continuous with, the main portion. The magnitudes of the threshold voltages of a group of such transistors fabricated under the same post-layout fabrication process conditions so as to be of different channel lengths reach a maximum absolute value VTAM when the channel length is at a value LC, are at least 0.03 volt less than VTAM when the channel length is approximately 0.3 ?m greater than LC, and materially decrease with increasing channel length when the channel length is approximately 1.0 ?m greater than LC.

Abstract: A semiconductor device with structured current spread region and method is disclosed. One embodiment provides a drift portion of a first conductivity type, a current spread portion of the first conductivity type and first portions of the first conductivity type. The current spread portion and the first portions are arranged in a first plane on the drift portion, wherein the current spread portion surrounds at least partially the first portions. The semiconductor body further includes spaced apart body regions of a second conductivity type which are arranged on the current spread portion. Further, the doping concentration of the current spread portion is higher than the doping concentrations of the drift portion and of the first portions.

Abstract: In a calibration method, the relation between dopant concentrations of ?-doping layers in a multilayered semiconductor structure and process parameters is determined S1 based on multiple bulk specimens of the material in which the ?-doping layers are located. A desired dopant concentration is selected S2, and the semiconductor structure with predetermined doping levels can be generated S3 based on the relation between the process parameters and the predetermined doping concentrations.

Abstract: A method for patterning a semiconductor device can include forming a conductive layer over a semiconductor substrate; alternatively forming positive photoresists and negative photoresists over the conductive layer; forming a plurality of first conductive lines by selectively removing a portion of the conductive layer using the positive photoresist and the negative photoresist as masks; forming an oxide film over the semiconductor substrate including the first conductive lines and the conductive layer; performing a planarization process over the oxide film using the uppermost surface of the first conductive line as a target; removing the plurality of first conductive lines using the oxide film as a mask; forming a plurality if trenches in the semiconductor substrate and removing a portion of the oxide film to expose the uppermost surface of the conductive layer; and then forming a plurality of second conductive lines by removing the exposed conductive layer using the oxide film as a mask.

Abstract: An improved way to apply tensile or compressive stress to one or more transistors on a semiconductor device is described. A portion of the tensile or compressive stress liner may be removed or modified such that a reduced amount of stress, or even no stress, is applied above the transistor gate. This may cause edges of the stress liner to be adjacent to and on either side of the channel, thus, increasing the stress effect. To produce this stress liner structure, the stress liner may be applied and then a portion of the stress liner is modified to reduce the stress in that portion, such as through ion implantation. The stress liner portion may be modified to have a reduced stress by, for example, implanting certain ions such as germanium or xenon ions therein.

Abstract: A Junction Field Effect Transistor (JFET) can be fabricated with a well region that include a channel region having an average dopant concentration substantially less the average doping concentration of the remaining portions of the well region. The lower average doping concentration of channel region compared to the remaining portions of the well region reduces the pinch-off voltage of the JFET.

Abstract: In a method of manufacturing a buried channel type transistor, a trench is formed at a surface portion of a substrate. A first and a second threshold voltage control regions are formed at portions of the substrate beneath a bottom face of the trench and adjacent to a sidewall of the trench, respectively. A gate electrode filling the trench is formed. Source/drain regions are formed at portions of the substrate adjacent to the sidewall of the gate electrode. Stopper regions are formed at portions of the substrate beneath the source/drain regions and beneath the first and second threshold voltage control regions, respectively. The buried channel type transistor has a high breakdown voltage between the source/drain regions although a threshold voltage thereof is low.

Abstract: A junction field effect transistor (JFET) is provided that is capable of a high voltage resistance, high current switching operation, that operates with a low loss, and that has little variation. This JFET is provided with a gate region (2) of a second conductivity type provided on a surface of a semiconductor substrate, a source region (1) of a first conductivity type, a channel region (10) of the first conductivity type that adjoins the source region, a confining region (5) of the second conductivity type that adjoins the gate region and confines the channel region, a drain region (3) of the first conductivity type provided on a reverse face, and a drift region (4) of the first conductivity type that continuously lies in a direction of thickness of the substrate from a channel to a drain.

Abstract: CMOS device arrangements have a surface channel, and a method for manufacturing the same by forming a multi-layer that includes a first metal layer, a polysilicon layer and a second metal layer having a work function from 4.8 through 5.0 eV on a cell region NMOS and a gate electrode of a peripheral circuit region PMOS, and by forming a multi-layer that includes a polysilicon layer and a second metal layer on a gate electrode of a peripheral circuit region NMOS. Because of the multi-layered gate electrode, a separate transient ion implantation process is not necessary, which consequently simplified the CMOS manufacturing process, while maintaining the threshold voltage of each peripheral circuit region −0.5V and below, and the threshold voltage of the peripheral circuit region NMOS +0.5V and below.

Abstract: A method of forming an MOS integrated circuit having at least two types of NFET, each type having a different threshold voltage, and at least two types of PFET, each type having a different threshold voltage, includes forming at least four active regions in a substrate, each region having a different doping profile. A conventional two threshold voltage CMOS process is modified to produce four transistor threshold voltages with only one additional masked implant operation. This additional implant raises the threshold voltage of one type of MOSFET while lowering that of the other MOSFET type.

Abstract: Integrated circuits with transistors exhibiting improved junction capacitances and various methods of fabricating the same are provided. In one aspect, a method of manufacturing is provided that includes forming a doped region in an active area of a substrate wherein the doped region has a first conductivity type and a first horizontal junction. A first source/drain region of the first conductivity type is formed in the active area with a second horizontal junction. A second source/drain region of the first conductivity type is formed in the active area with a third horizontal junction and a lateral separation from the first source/drain region that defines a channel region. The second and third horizontal junctions are positioned substantially at the first horizontal junction. The portion of the doped region positioned in the channel region is doped with an impurity of a second conductivity type that is opposite to the first conductivity type.

Abstract: An enhancement mode semiconductor device has a barrier layer disposed between the gate electrode of the device and the semiconductor substrate underlying the gate electrode. The barrier layer increases the Schottky barrier height of the gate electrode-barrier layer-substrate interface so that the portion of the substrate underlying the gate electrode operates in an enhancement mode. The barrier layer is particularly useful ill compound semiconductor field effect transistors, and preferred materials for the barrier layer include aluminum gallium arsenide and indium gallium arsenide.

Abstract: A method is provided for maximizing activation of a gate electrode while preventing source and drain regions from being excessively doped. The gate electrode is partially doped when exposed the source/drain implantation step. Then, the gate electrode is fully doped by the selective implantation step while the source/drain regions are blocked. Separate annealing steps are provided subsequent to the gate doping step and the source and drain implantation step.

Abstract: A lateral silicon carbide junction field effect transistor has p-conductive and n-conductive silicon carbide layers. The layers are provided in pairs in lateral direction in a silicon carbide body. Trenches for a source, a drain and a gate extend from a principal surface of the silicon carbide body and penetrate the layers. The source and drain trenches are filled with silicon carbide of one conductivity type, whereas the trench for the gate is filled with silicon carbide of a conductivity type that is different from the source and the drain.

Abstract: A process for forming an ultra-shallow junction depth, doped region within a silicon substrate. The process includes forming a dielectric film on the substrate, then implanting an ionic dopant species into the structure. The profile of the implanted species includes a population implanted through the dielectric film and into the silicon substrate, and a peak concentration deliberately confined in the dielectric film in close proximity to the interface between the dielectric film and the silicon substrate. A high-energy, low-dosage implant process is used and produces a structure that is substantially free of dislocation loops and other defect clusters. An annealing process is used to drive the peak concentration closer to the interface, and some of the population of the originally implanted species from the dielectric film into the silicon substrate.

Abstract: In field-effect transistors, semiconductor clusters, which can extend from the source region to the drain region and which can be implemented in two ways, are embedded in one or a plurality of layers. In a first embodiment, the semiconductor material of the adjacent channel region can be strained by the clusters and the effective mass can thus be reduced by altering the energy band structure and the charge carrier mobility can be increased. In a second embodiment, the clusters themselves can be used as a canal region. These two embodiments can also appear in mixed forms. The invention can be applied to the Si material system with SiGe clusters or to the GaAs material system with InGaAs clusters or to other material systems.

Abstract: A process for forming an ultra-shallow junction depth, doped region within a silicon substrate. The process includes forming a dielectric film on the substrate, then implanting an ionic dopant species into the structure. The profile of the implanted species includes a population implanted through the dielectric film and into the silicon substrate, and a peak concentration deliberately confined in the dielectric film in close proximity to the interface between the dielectric film and the silicon substrate. A high-energy, low-dosage implant process is used and produces a structure that is substantially free of dislocation loops and other defect clusters. An annealing process is used to drive the peak concentration closer to the interface, and some of the population of the originally implanted species from the dielectric film into the silicon substrate.

Abstract: In a silicon carbide static induction transistor, at a surface part of a semiconductor substrate, a p-type gate region is formed partially overlapping a n-type source region, whereby the high accuracy in alignment between the gate region and the source region is not required, and the gate withstand voltage can be highly increased since the substrate is made of silicon carbide, which improves the yield of static induction transistors.

Abstract: The present invention discloses a semiconductor device having a triple well structure. The semiconductor device includes a N-type impurity doped buried layer, formed in the semiconductor substrate at a predetermined depth from the surface of the first active region; a first P-type well region formed beneath the second active region which is adjacent to the first active region; a second P-type well region formed in the semiconductor substrate to a depth from the surface of the first active region; a first N-type well region formed beneath the third active region; a second N-type well region formed beneath selected portion of the isolation film defining first active region and the second active region; and a first P-type doping region and a second N-type doping region formed respectively right beneath the surface of the first active region and right beneath the surface of the second active region, wherein the dopant concentration of the first doping region is lower than that of the second doping region.

Abstract: An n-semiconductor layer is arranged on a low-resistance n-substrate. A drain electrode is in ohmic contact with the n-substrate. A source electrode forms a Schottky junction with the n-semiconductor layer. A gate electrode is arranged adjacent to the source electrode on the n-semiconductor layer through a gate insulating film. When a voltage is applied to the gate electrode to lower the Schottky barrier height at the interface between the source electrode and the n-semiconductor layer, electrons are injected from the source electrode into the n-semiconductor layer, and a current flows in the semiconductor device. A diffusion layer which prevents a decrease in manufacturing time is not required to form in the n-semiconductor layer, and a channel which causes an increase in ON state voltage is not present.

Abstract: The present invention discloses a semiconductor device having a triple well structure. The semiconductor device includes a N-type impurity doped buried layer, formed in the semiconductor substrate at a predetermined depth from the surface of the first active region; a first P-type well region formed beneath the second active region which is adjacent to the first active region; a second P-type well region formed in the semiconductor substrate to a depth from the surface of the first active region; a first N-type well region formed beneath the third active region; a second N-type well region formed beneath selected portion of the isolation film defining first active region and the second active region; and a first P-type doping region and a second N-type doping region formed respectively right beneath the surface of the first active region and right beneath the surface of the second active region, wherein the dopant concentration of the first doping region is lower than that of the second doping region.

Abstract: An electron emitting semiconductor device is provided with a P-type semiconductor layer arranged on a semiconductor substrate having an impurity concentration. A Schottky barrier electrode is arranged on a surface of the P-type semiconductor layer. Plural P.sup.+ -type area units are positioned under and facing the Schottky barrier electrode. An N.sup.+ -type area is disposed in the vicinity of the P.sup.+ -type units. The impurity concentration is such as to cause an avalanche breakdown in at least a portion of the surfaces.

Abstract: AMOS transistor with enhanced electrical characteristics and a method for manufacturing the same. In the channel region, a first impurity region is provided for adjusting a threshold voltage, a second impurity region is provided which serves as a diffusion barrier, and a third impurity region is provided for preventing a punchthrough. These regions are formed sequentially at subsequently shallower depths in the substrate. The disclosed transistor minimizes short-channel effects and punchthrough without reducing the current driving capability of the device.

Abstract: This invention aims at providing an high output FET having a planar type-gate structure suitable for integration, and a structure that suppresses long gate effect. A heavily doped thin channel layer 13 is formed on a semiconductor substrate 11, and a cap layer including a doped layer 15 is formed on the channel layer 13. A thickness and a dopant concentration of the doped layer 15 are so set that the doped layer 15 per se is depleted by a surface depletion region resulting from an interface level of the semiconductor substrate surface, and the surface depletion region does not widen to the channel layer 13. Consequently no long gate effect takes place on the side where a gate bias is lower.

Abstract: A process for fabricating transistors on a substrate is disclosed. In accordance with the process, stacks of material are formed on the surface of the substrate. Walls of silicon dioxide are created around the stacks in order to insulate the material within the stacks from the material deposited outside of the walls. A first layer of polycrystalline material is deposited over the substrate and selectively removed such that only those portions of the polycrystalline layer that surround the stacks of material remain. A layer of silicon nitride or silicon dioxide is then formed over the substrate surface. A first resist is then spun on the substrate surface. This resist aggregates near the stacks of material. An isolation mask is generated that leaves exposed only those areas of the substrate that correspond to the area of overlap between the first polycrystalline area and the stacks of material, which also contain a layer of polycrystalline material.

Abstract: A self-cascoding transconductance circuit has cascoding and current sink/source FETs, serially connected with their gates tied together to receive an input voltage, wherein the cascoding FET has a threshold voltage having an absolute value at least 0.1 volts less than that of the current sink/source FET to ensure that the current sink/source FET operates in its saturated region. A CMOS structure implementing the self-cascoding transconductance circuit has two doped threshold adjust regions formed beneath a gate electrode such that the two doped threshold adjust regions respectively effectuate the cascode and current sink/source FETs which then share the gate electrode. A method of forming the CMOS structure includes forming two self-cascoding transconductance circuits electrically connected in parallel such that they share a common drain region between their respective gate electrodes, and each has one source region.

Abstract: An FET mixer circuit having a stable input impedance uses two tandem-connected GaAs MESFET's (1) and (2) of pulse doped structure instead of a conventional MESFET or a HEMT, as an active device. A gate biasing point for the FET (1) is set around a pinch-off point of a mutual conductance, and a gate biasing point for the FET (2) is set in a region which assures non-change of a mutual conductance with respect to the increase of a gate voltage. Thus, a mixer circuit having a good isolation characteristic for an RF signal and a local oscillation signal and exhibits substantially no change in the input impedance is attained.

Abstract: A junction field effect transistor, specifically a static induction transistor. The N-type source regions are formed as two zones. First, relatively lightly doped first zones are formed by ion-implanting doping material relatively deeply into the semiconductor material. Then relatively heavily doped second zones are formed by ion-implanting doping material to a relatively shallow depth within the first zones to leave portions of the first zones interposed between the second zones and the remainder of the semiconductor material. The resulting devices exhibit reduced gate-drain junction capacitance at low drain bias voltages thereby improving device capacitance linearity.

Abstract: A JFET configuration is obtained whose pinch-off voltage can be set by means of mask dimensions, without process changes, and which is at the same time suitable for operation at very low and very high voltages by cascoding of a first JFET with a diffused or implanted channel which is pinched off in lateral direction, parallel to the surface of the semiconductor body, with a second JFET with a high breakdown voltage and a higher pinch-off voltage than the first JFET. To increase the breakdown voltage still further, the combination of the first and second JFET may be further cascoded, without process changes, with a third JFET which has a channel of the conductivity type opposite to that of the first and second JFET.