Abstract: A lateral semiconductor device (20) such as LDMOS, a UIGBT, a lateral diode, a lateral GTO, a lateral JFRT or a lateral BJT, comprising a drift region (12) having a first surface (22) and a first conductivity type, first and second conductive regions (4, 8) extending into the drift region from the first surface. The lateral semiconductor device further comprises an additional region (24) or several additional regions, having a second conductivity type, between the first and second semiconductor regions (4, 8), the additional region extending into the drift region from the first surface (22), wherein the additional region forms a junction dividing the electric field between the first and second semiconductor regions when a current path is established between the first and second semiconductor regions. This allows the doping concentration of the drift region to be increased, thereby lowering the on-resistance of the device.

Abstract: A level shifter is provided that facilitates reducing high-bias-voltage application to a MOSFET and improving the reliability thereof. The level shifter includes an NMOSFET formed of a first isolated region in the surface portion of a P-type substrate, a source, a channel and a drain in the surface portion of a first isolated region, and a gate above the first isolated region; a second isolated region in the surface portion of P-type substrate and space apart from first isolated region; and high-potential portions including pinch resistance with a high breakdown voltage in second isolated region.

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 lateral conduction superjunction semiconductor device has a plurality of spaced vertical trenches in a junction receiving layer of P− silicon. An N− diffusion lines the walls of the trench and the concentration and thickness of the N− diffusion and P− mesas are arranged to deplete fully in reverse blocking operation. A MOSgate structure is connected at one end of the trenches and a drain is connected at its other end. An N− further layer or an insulation oxide layer may be interposed between a P− substrate and the P− junction receiving layer.

Abstract: Power MOSFET devices provide highly linear transfer characteristics (e.g., Id v. Vg) and can be used effectively in linear power amplifiers. These linear transfer characteristics are provided by a device having a channel that operates in a linear mode and a drift region that simultaneously supports large voltages and operates in a current saturation mode. A relatively highly doped transition region is provided between the channel region and the drift region. Upon depletion, this transition region provides a potential barrier that supports simultaneous linear and current saturation modes of operation. Highly doped shielding regions may also be provided that contribute to depletion of the transition region.

Abstract: Merging together the drift regions in a low-power trench MOSFET device via a dopant implant through the bottom of the trench permits use of a very small cell pitch, resulting in a very high channel density and a uniformly doped channel and a consequent significant reduction in the channel resistance. By properly choosing the implant dose and the annealing parameters of the drift region, the channel length of the device can be closely controlled, and the channel doping may be made highly uniform. In comparison with a conventional device, the threshold voltage is reduced, the channel resistance is lowered, and the drift region on-resistance is also lowered. Implementing the merged drift regions requires incorporation of a new edge termination design, so that the PN junction formed by the P epi-layer and the N+ substrate can be terminated at the edge of the die.

Abstract: A power field effect transistor utilizes a retrograded-doped transition region to enhance forward on-state and reverse breakdown voltage characteristics. Highly doped shielding regions may also be provided that extend adjacent the transition region and contribute to depletion of the transition region during both forward on-state conduction and reverse blocking modes of operation. In a vertical embodiment, the transition region has a peak first conductivity type dopant concentration at a first depth relative to a surface on which gate electrodes are formed. A product of the peak dopant concentration and a width of the transition region at the first depth is preferably in a range between 1×1012 cm−2 and 7×1012 cm−2.

Abstract: A bidirectional semiconductor component having two symmetrical MOS transistor structures integrated laterally in a substrate and connected antiserially, their drain terminals being connected to one another. A zone having the same type of conductivity as the drain region yet a higher doping than that of the drain region is situated upstream from a pn junction of one of the MOS transistors in a junction area with the drain region.

Abstract: An integrated semiconductor device containing semiconductor elements that have respective desired on-resistances and breakdown voltages achieves appropriate characteristics as a whole of the integrated semiconductor element. The integrated semiconductor device includes a plurality of semiconductor elements formed in a semiconductor layer and each having a source of an n type semiconductor, a drain of the n type semiconductor and a back gate of a p type semiconductor between the source and the drain. At least a predetermined part of the drain of one semiconductor element and a predetermined part of the drain of another semiconductor element have respective impurity concentrations different from each other.

Abstract: A SJ-LDMOST device offers significantly improved on-state, off-state, and switching characteristics of lateral power devices for power integrated circuits applications. The device is fabricated on an insulator substrate. The proposed structure achieves charge compensation in the drift region by terminating the bottom of the SJ structure by a dielectric hence eliminating the undesirable vertical electric field component and preventing any substrate-assisted-depletion. The device structural arrangement thereby achieve a uniform distribution of the electric field thus maximizing the BV for a given drift region length.

Abstract: An LDMOS transistor includes drift regions from the body to the drain and the source terminals and is capable of handling high voltages at both the source and drain terminals. In one embodiment, a transistor includes a body region formed in a first well, a conductive gate formed over a first dielectric layer where the first dielectric layer overlies the first well, a second dielectric layer encircling the first dielectric layer, a drain region abutting one edge of the second dielectric layer and a source region abutting an opposite edge of the second dielectric layer. A first drift region is formed between the source region and the body region while a second drift region is formed between the drain region and the body region. Accordingly, the drain and source region of the transistor is interchangeable. In one embodiment, the first and second dielectric layers are a contiguous field oxide layer.

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: A RESURF super-junction device (51) is provided which comprises a plurality of electrodes (53) disposed in a layer of a first material (61) having a first conductivity type. Each of the plurality of electrodes contains a second material (57) of a second conductivity type which is encased in a dielectric material (55).

Abstract: A method of forming a semiconductor device includes forming a body region of a semiconductor substrate and forming a drift region adjacent at least a portion of the body region. A dopant is used to form the drift region. The dopant may comprise phosphorous. The method also includes forming a field oxide structure adjacent a portion of the drift region and a portion of a drain region. The field oxide structure is located between a gate electrode region and the drain region and is spaced apart from the gate electrode region. Atoms of the dopant accumulate adjacent a portion of the field oxide structure, forming an intermediate-doped region adjacent a portion of the field oxide structure. The method includes forming a gate oxide adjacent a portion of the body region and forming a gate electrode adjacent a portion of the gate oxide.

Abstract: A semiconductor device has a drift region in which a drift current flows if it is in the ON mode and which is depleted if it is in the OFF mode. The drift region is formed as a structure having a plurality of first conductive type divided drift regions and a plurality of second conductive type compartment regions in which each of the compartment regions is positioned among the adjacent drift regions in parallel to make p-n junctions, respectively.

Abstract: A high withstand voltage insulated gate N-channel field effect transistor has N-type source and drain regions formed on a semiconductor substrate, and a channel forming region disposed between the source and drain regions. A gate insulating film is disposed over the channel forming region. A gate electrode is formed on the channel forming region through the gate insulating film. N-type low concentration regions are formed between respective ones of the drain region and the channel forming region and the source region and the channel forming region. Second insulating films are formed on respective ones of the low concentration regions. A P-type buried layer is formed in a boundary region between the semiconductor substrate and the epitaxial layer and below the source region, the drain region, the channel forming region, the gate insulating film, and the second insulating films. A P-type well layer is formed in a part of a region under the gate insulating film.

Abstract: A metal-oxide-semiconductor (MOS) device is formed comprising a semiconductor layer of a first conductivity type, a first source/drain region of a second conductivity type formed in the semiconductor layer, and a second source/drain region of the second conductivity type formed in the semiconductor layer and spaced apart from the first source/drain region.

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 semiconductor component includes a first semiconductor region (110, 210) having a first conductivity type and a second semiconductor region (120, 220) above the first semiconductor region and having a second conductivity type. The semiconductor component further comprises a third semiconductor region (130, 230) above the second semiconductor region and having the first conductivity type, a fourth semiconductor region (140, 240) above the third semiconductor region and having the second conductivity type, a fifth semiconductor region (150, 250) above the third semiconductor region and having the first conductivity type, a sixth semiconductor region (160, 260) substantially enclosed within the fifth semiconductor region and having the second conductivity type, and a seventh semiconductor region (170, 270) above the first semiconductor region and having the second conductivity type.

Abstract: A lateral semiconductor device has a semiconductor layer on an insulating layer on a semiconductor substrate. The semiconductor layer has a region of a first conduction type and a region of a second conduction type with a drift region therebetween. The drift region is provided by a region of the first conduction type and a region of the second conduction type. The first and second conduction type drift regions are so arranged that when a reverse voltage bias is applied across the first and second conduction type regions of the semiconductor layer, the second conduction type drift region has an excess of charge relative to the first conduction type drift region which varies substantially linearly from the end of the drift region towards the first conduction type region of the semiconductor layer to the end of the drift region towards the second conduction type region of the semiconductor layer.

Abstract: A semiconductor device includes a drain layer, first and second drift layers, a RESURF layer, a drain electrode, a base layer, a source layer, a source electrode, and a gate electrode. The first drift layer is formed on the drain layer. The second drift layers and RESURF layers are formed on the first drift layer and periodically arranged in a direction perpendicular to the direction of depth. The RESURF layer forms a depletion layer in the second drift layer by a p-n junction including the second drift layer and RESURF layer. The impurity concentration in the first drift layer is different from that in the second drift layer. The drain electrode is electrically connected to the drain layer.

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: This invention achieves a high inverse voltage of a super-junction semiconductor device, which has a drift layer composed of a parallel pn layer that conducts electricity in the ON state and is depleted in the OFF state. An n− high resistance region is formed at the periphery of a drift layer composed of a parallel pn layer of n drift regions and p partition regions. The impurity density ND of the n− high resistance region is 5.62×1017×VDSS−1.36(cm−3) or less. VDSS denotes the withstand voltage (V). An n low resistance region is arranged adjacent to the n− high resistance region.

Abstract: A RESURF super-junction device (51) is provided which comprises a plurality of electrodes (53) disposed in a layer of a first material (61) having a first conductivity type. Each of the plurality of electrodes contains a second material (57) of a second conductivity type which is encased in a dielectric material (55).

Abstract: Charge balancing is achieved in a compensation component by creating compensation regions having different thickness. In this manner, the ripple of the electric field can be chosen to have approximately the same magnitude in all of the compensation regions.

Abstract: A power semiconductor device and a method of forming the same is provided. The method begins by providing a substrate of a first conductivity type and then forming a voltage sustaining region on the substrate. The voltage sustaining region is formed by depositing an epitaxial layer of a first conductivity type on the substrate and forming at least one trench in the epitaxial layer. A barrier material is deposited along the walls of the trench. A dopant of a second conductivity type is implanted through the barrier material into a portion of the epitaxial layer adjacent to and beneath the bottom of the trench. The dopant is diffused to form a first doped layer in the epitaxial layer and the barrier material is removed from at least the bottom of the trench. The trench is etched through the first doped layer and a filler material is deposited in the trench to substantially fill the trench, thus completing the voltage sustaining region.

Abstract: The semiconductor component is a charge carrier compensation component formed in a semiconductor body. A semiconductor basic body is disposed in the semiconductor body. The basic body has at least one compensation layer which adjoins a boundary layer and first regions of a first conductivity type and second regions of a second conductivity type are provided along a layout grid. A total quantity of charge of the first regions corresponds approximately to a total quantity of charge of the second regions. At least one semiconductor layer in the semiconductor body adjoins the semiconductor basic body at the boundary layer. A multiplicity of doped regions are embedded in the first surface of the semiconductor layer which form a grid for a cell array of the semiconductor component. The grid in the semiconductor layer is aligned independently of the layout grid in the semiconductor basic body.

Abstract: In an N-MOSFET having a Double RESURF structure, an n-drift layer and a p-base layer are formed to be adjacent to each other in the surface of a p-semiconductor active layer. An n+-drain layer and a p-RESURF layer are formed in the surface of the drift layer. An n+-source layer and a p+-contact layer are formed to be adjacent to each other in the surface of the base layer. A gate electrode is arranged through a gate insulating film on that region of the base layer, which is located between the drift layer and the source layer. The RESURF layer is doped with a p-carrier impurity at a dose that is set to be gradually higher from the drain layer side to the base layer side.

Abstract: The performance of high-voltage devices is often influenced by charge-creep effects in the package. In order to avoid the resultant degradation, a bleeder may be used between the device and the package. However, it has been found in practice that the use of a high-resistive bleeder may lead to a certain instability of the device during operation. According to the invention, the bleeder (8) is provided with a plurality of conductive regions (12, 13) which are distributed in such a way that, when a high voltage is applied across the bleeder, a non-linear potential profile across the bleeder is obtained, which harmonizes with the ideal potential profile without the bleeder, instead of a linear profile which would have been obtained in the absence of said conductive regions due to charge-loading effects, and which would result in the above-mentioned instability effects.

Abstract: A compensation component and a process for production thereof includes a semiconductor body having first and second electrodes, a drift zone disposed therebetween, and areas of a first conductivity type and a second conductivity type opposite the first conductivity type disposed in the drift zone. Higher doped zones of the first type are inlaid in a weaker doped environment of the second type closer to the first electrode and higher doped zones of the second type are inlaid in a weaker doped environment of the first type closer to the second electrode. The drift zone is complementary so that, in a direction between the electrodes, a more highly doped zone of the first type adjoins a more weakly doped environment of the first type, and a more weakly doped environment of the second type adjoins a more highly doped zone of the second type.

Abstract: In the first aspect of the invention, a semiconductor device can effectively suppress the adverse short channel effect and the possible occurrence of junction leak current and has a low resistance diffusion layer to realize a short propagation delay time as a plurality of side wall films 4, 5 are formed at least in a part of the area between the gate electrode 3 and an elevated region 8 by laying a plurality of films in an appropriate order.

Abstract: A QFN semiconductor package and a fabrication method thereof are proposed, wherein a lead frame having a plurality of leads is adopted, and each lead is formed at its inner end with a protruding portion. A wire bonding region and a bump attach region are respectively defined on opposite surfaces of the protruding portion, and staggered in position. This allows a force applied from a wire bonder to the wire bonding regions not to adversely affect solder bumps implanted on the bump attach regions, so that the solder bumps can be structurally assured without cracking. Moreover, the wire bonding regions spaced apart from the bump attach regions can be prevented from being contaminated by an etching solution used in solder bump implantation, so that wire bonding quality can be well maintained.

Abstract: A power MOSFET semiconductor device high in breakdown voltage and low in resistance can be manufactured at a low cost and in a short turnaround time. In a planar-type power MOSFET, a manufacture method comprises forming a trench in a drift region, and forming a body diffusion layer on a trench side wall and bottom portion (forming the trench and subsequently performing diffusion) to obtain a structure. Deep body diffusion formation is effective for obtaining the high breakdown voltage and low resistance, but to attain the structure, usually epitaxial growth and selective formation of a deep body region have to be performed a plurality of times, and with an increase of manufacture steps, souring of manufacture cost and lengthening of manufacture period are caused. However, the present structure can further simply bring about the similar effect. It is possible to supply the power MOSFET semiconductor device at the low cost and in the short manufacture turnaround time.

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 semiconductor wafer including an NMOS device and a PMOS device. The NMOS device is formed to have a high-K gate dielectric and the PMOS device is formed to have a standard-K gate dielectric. A method of forming the NMOS device and the PMOS device is also disclosed.

Abstract: A high withstand voltage insulated gate N-channel field effect transistor has a P-type semiconductor substrate and an N-type epitaxial layer formed on the semiconductor substrate. An N-type source region having a high concentration is formed on the epitaxial layer. An N-type drain region having a high concentration is formed on the epitaxial layer and is spaced-apart from the source region. A channel forming region is disposed between the source region and the drain region. A gate insulating film is disposed over the source and drain regions and the channel forming region. A gate electrode is formed through the channel forming region and the gate insulating film. An N-type low concentration region is formed between the drain region and the channel forming region. A second insulating film is formed on the low concentration region and has a thickness greater than that of the gate insulating film.

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 charge compensation structure wherein locations with a maximum local field strength are positioned in a compensation edge region of the charge compensation structure. Thus, an electrical parameter such as the on resistance of the semiconductor component can be substantially improved without influencing or impairing further parameters such as the breakdown voltage and the robustness with respect to TRAPATT oscillations. Methods of fabricating a semiconductor component with a charge compensation structure are also provided.

Abstract: A two-terminal power diode has improved reverse bias breakdown voltage and on resistance includes a semiconductor body having two opposing surfaces and a superjunction structure therebetween, the superjunction structure including a plurality of alternating P and N doped regions aligned generally perpendicular to the two surfaces. The P and N doped regions can be parallel stripes or a mesh with each region being surrounded by doped material of opposite conductivity type. A diode junction associated with one surface can be an anode region with a gate controlled channel region connecting the anode region to the superjunction structure. Alternatively, the diode junction can comprise a metal forming a Schottky junction with the one surface. The superjunction structure is within the cathode and spaced from the anode. The spacing can be varied during device fabrication.

Abstract: A drift layer is formed on a substrate. A base region is formed on the drift layer. A plurality of source regions are formed in a surficial layer of the base region. A plurality of gate electrodes face to the base region and the source region via a gate insulating film. A source electrode is brought into contact with the base region and the source region. A nitrogen cluster containing layer is embedded in the drift layer so as to extend laterally under the base region so that at least part of the drift region is left under the nitrogen cluster containing layer.

Abstract: Power MOSFET devices provide highly linear transfer characteristics (e.g., Id v. Vg) and can be used effectively in linear power amplifiers. These linear transfer characteristics are provided by a device having a channel that operates in a linear mode and a drift region that simultaneously supports large voltages and operates in a current saturation mode. A relatively highly doped transition region is provided between the channel region and the drift region. Upon depletion, this transition region provides a potential barrier that supports simultaneous linear and current saturation modes of operation. Highly doped shielding regions may also be provided that contribute to depletion of the transition region.

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 semiconductor device has an element region including MOS structure. A p-well region, a connecting impurity diffused region, and an impurity diffused region for guard ring are formed in an n-type semiconductor layer so as to form a well region, The well region has a step defining a higher portion and a lower portion lower than the higher portion so that the impurity diffused region for guard ring is located at the lower portion. The lower portion is located at a periphery of the element region. In this structure, the impurity diffused region for guard ring is completely depleted while the connecting impurity diffused region is partially depleted so that a portion having carriers remains therein while a depletion layer expands in the connecting impurity diffused region before a breakdown due to a reverse bias occurs in the element region.

Abstract: A dual-die packaging technology is proposed to pack two semiconductor chips in one single package module, so that one single package module is capable of offering a doubled level of functionality or data storage capacity. The proposed dual-die packaging technology is characterized in the use of a face-to-face stacked dual-die construction to pack two integrated circuit chips, such as flash memory chips, in one single package module. The first semiconductor die has its non-circuit surface attached to the front side of the die pad of the leadframe, while the second semiconductor die has its circuit surface attached by means of adhesive layer to the circuit surface of the first semiconductor die, thus forming a face-to-face stacked dual-die construction over the die pad of the leadframe, allowing one single package module to offer a doubled level of functionality or data storage capacity.

Abstract: Charge balancing is achieved in a compensation component by creating compensation regions having different thickness. In this manner, the ripple of the electric field can be chosen to have approximately the same magnitude in all of the compensation regions.

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: A silicon-based semiconductor component includes a high-efficiency barrier junction termination. In the semiconductor component, a silicon semiconductor region takes on the depletion region of an active area of the semiconductor component. The junction termination for the active area is formed with silicon with a doping that is opposite to that of the semiconductor region, and the junction termination surrounds the active area on or in a surface of the semiconductor region. The junction termination is doped with a dopant that has a low impurity energy level of at least 0.1 eV in silicon. Preferably Be, Zn, Ni, Co, Mg, Sn or In are used as acceptors and S, Se or Ti are provided as donors.

Abstract: A semiconductor device, such as a pin diode, includes a first drift layer, a second drift layer, an anode layer on the first drift layer, and a buffer layer formed between the first and second drift layers. The shortest distance from the pn-junction between the anode layer and the buffer layer, and the thickness of the buffer layer are set at the respective values at which a high breakdown voltage is obtained, while reducing the tradeoff relation between the soft recovery and the fast and low-loss reverse recovery.