Abstract: A semiconductor device includes transistor cells with source zones of a first conductivity type and body zones of a second conductivity type. The source and body zones are formed in a semiconductor mesa formed from a portion of a semiconductor body. Control structures include first portions extending into the semiconductor body on at least two opposing sides of the semiconductor mesa, second portions in a distance to the first surface between the first portions, and third portions in a distance to the first surface and connecting the first and the second portions, wherein constricted sections of the semiconductor mesa are formed between neighboring third portions.

Abstract: A semiconductor device includes an insulated gate bipolar transistor (IGBT) arrangement. The IGBT arrangement includes a carrier confinement reduction region laterally arranged between a cell region and a sensitive region. The IGBT arrangement is configured or formed so that the cell region has a first average density of free charge carriers in an on-state of the IGBT arrangement, the carrier confinement reduction region has a second average density of free charge carriers in the on-state of the IGBT arrangement and the sensitive region has a third average density of free charge carriers in the on-state of the IGBT arrangement. The first average density of free charge carriers is larger than the second average density of free charge carriers and the second average density of free charge carriers is larger than the third average density of free charge carriers.

Abstract: A method for controlling a first switch and a second switch is suggested, wherein each switch is an RC-IGBT and wherein both switches are arranged as a half-bridge circuit. The method includes: controlling the first switch in an IGBT-mode; controlling the second switch such that it becomes desaturated when being in a DIODE-mode; wherein controlling the second switch starts before and lasts at least as long as the first switch changes its IGBT-mode from blocking state to conducting state.

Abstract: Disclosed is a bipolar semiconductor device, comprising a semiconductor body having a first surface; and a base region of a first doping type and a first emitter region in the semiconductor body, wherein the first emitter region adjoins the first surface and comprises a plurality of first type emitter regions of a second doping type complementary to the first doping type, a plurality of second type emitter regions of the second doping type, a plurality of third type emitter regions of the first doping type, and a recombination region comprising recombination centers, wherein the first type emitter regions and the second type emitter regions extend from the first surface into the semiconductor body, wherein the first type emitter regions have a higher doping concentration and extend deeper into the semiconductor body from the first surface than the second type emitter regions, wherein the third type emitter regions adjoin the first type emitter regions and the second type emitter regions, and wherein the recom

Abstract: A semiconductor device includes a pn junction between a drift zone and a charge-carrier transfer region in a semiconductor body. An access channel provides a permanent charge carrier path connecting the drift zone with a recombination region through a separation region between the drift zone and the recombination region. The access channel adjusts a plasma density in the drift zone and the recombination region.

Abstract: A semiconductor device includes a semiconductor region having charge carriers of a first conductivity type, a transistor cell in the semiconductor region, and a semiconductor channel region in the transistor cell and having a first doping concentration of charge carriers of a second conductivity type. A semiconductor auxiliary region in the semiconductor region has a second doping concentration of charge carriers of the second conductivity type, which is at least 30% higher than the first doping concentration. A pn-junction between the semiconductor auxiliary region and the semiconductor region is positioned as deep or deeper in the semiconductor region as a pn-junction between the semiconductor channel region and the semiconductor region. The semiconductor auxiliary region is positioned closer to the semiconductor channel region than any other semiconductor region having charge carriers of the second conductivity type and that forms a further pn-junction with the semiconductor region.

Abstract: A semiconductor device includes transistor cells and enhancement cells. Each transistor cell includes a body zone that forms a first pn junction with a drift structure. The transistor cells may form, in the body zones, inversion channels when a first control signal exceeds a first threshold. The inversion channels form part of a connection between the drift structure and a first load electrode. A delay unit generates a second control signal which trailing edge is delayed with respect to a trailing edge of the first control signal. The enhancement cells form inversion layers in the drift structure when the second control signal falls below a second threshold lower than the first threshold. The inversion layers are effective as minority charge carrier emitters.

Abstract: A semiconductor component is described herein. In accordance with one example of the invention, the semiconductor component includes a semiconductor body, which has a top surface and a bottom surface. A body region, which is doped with dopants of a second doping type, is arranged at the top surface of the semiconductor body. A drift region is arranged under the body region and doped with dopants of a first doping type, which is complementary to the second doping type. Thus a first pn-junction is formed at the transition between the body region and the drift region. A field stop region is arranged under the drift region and adjoins the drift region. The field stop region is doped with dopants of the same doping type as the drift region. However, the concentration of dopants in the field stop region is higher than the concentration of dopants in the drift region. At least one pair of semiconductor layers composed of a first and a second semiconductor layer are arranged in the drift region.

Abstract: A reverse blocking semiconductor device is manufactured by introducing impurities of a first conductivity type into a semiconductor substrate of the first conductivity type through a process surface to obtain a process layer extending into the semiconductor substrate up to a first depth, and introducing impurities of a second, complementary conductivity type into the semiconductor substrate through openings of an impurity mask provided on the process surface to obtain emitter zones of the second conductivity type extending up to a second depth deeper than the first depth and channels of the first conductivity type between the emitter zones. Exposed portions of the process layer are removed above the emitter zones.

Abstract: A semiconductor device includes transistor cells formed along a first surface at a front side of a semiconductor body in a transistor cell area. A drift zone structure forms first pn junctions with body zones of the transistor cells. An auxiliary structure between the drift zone structure and a second surface at a rear side of the semiconductor body includes a first portion that contains deep level dopants requiring at least 150 meV to ionize. A collector structure directly adjoins the auxiliary structure. An injection efficiency of minority carriers from the collector structure into the drift zone structure varies along a direction parallel to the first surface at least in the transistor cell area.

Abstract: A semiconductor device includes a semiconductor mesa having source zones separated from each other along a longitudinal axis of the semiconductor mesa and at least one body zone forming first pn junctions with the source zones and a second pn junction with a drift zone. Electrode structures are on opposite sides of the semiconductor mesa, at least one of which includes a gate electrode configured to control a charge carrier flow through the at least one body zone. First portions of the at least one body zone are formed between the source zones and separation regions. In the separation regions, at least one of (i) a capacitive coupling between the gate electrode and the semiconductor mesa and (ii) a conductivity of majority charge carriers of the drift zone is lower than outside of the separation region.

Abstract: A semiconductor device includes transistor cells with source zones of a first conductivity type and body zones of a second conductivity type. The source and body zones are formed in a semiconductor mesa formed from a portion of a semiconductor body. Control structures include first portions extending into the semiconductor body on at least two opposing sides of the semiconductor mesa, second portions in a distance to the first surface between the first portions, and third portions in a distance to the first surface and connecting the first and the second portions, wherein constricted sections of the semiconductor mesa are formed between neighboring third portions.

Abstract: A reverse blocking semiconductor device includes a base region of a first conductivity type and a body region of a second, complementary conductivity type, wherein the base and body regions form a pn junction. Between the base region and a collector electrode an emitter layer is arranged that includes emitter zones of the second conductivity type and at least one channel of the first conductivity type. The channels extend through the emitter layer between the base region and the collector electrode and reduce the leakage current in a forward blocking state.

Abstract: A semiconductor device includes a semiconductor mesa with at least one body zone forming first pn junctions with source zones and a second pn junction with a drift zone. A pedestal layer at a side of the drift zone opposite to the at least one body zone includes first zones of a conductivity type of the at least one body zone and second zones of the conductivity type of the drift zone. Electrode structures are on opposite sides of the semiconductor mesa. At least one of the electrode structures includes a gate electrode controlling a charge carrier flow through the at least one body zone. In a separation region between two of the source zones (i) a capacitive coupling between the gate electrode and the semiconductor mesa or (ii) a conductivity of majority charge carriers of the drift zone is lower than outside of the separation region.

Abstract: A semiconductor device includes an insulated gate bipolar transistor (IGBT) arrangement having a first configuration region of emitter-side insulated gate bipolar transistor structures, a second configuration region of emitter-side insulated gate bipolar transistor structures, a collector layer and a drift layer. The drift layer is arranged between the collector layer and the emitter-side insulated gate bipolar transistor structures of the first configuration region and the second configuration region. The collector layer includes at least a first doping region laterally adjacent to a second doping region, the doping regions having different charge carrier life times, different conductivity types or different doping concentrations. The first configuration region is located with at least a partial lateral overlap to the first doping region, and the second configuration region is located with at least a partial lateral overlap to the second doping region.

Abstract: A semiconductor component is described herein. In accordance with one example of the invention, the semiconductor component includes a semiconductor body, which has a top surface and a bottom surface. A body region, which is doped with dopants of a second doping type, is arranged at the top surface of the semiconductor body. A drift region is arranged under the body region and doped with dopants of a first doping type, which is complementary to the second doping type. Thus a first pn-junction is formed at the transition between the body region and the drift region. A field stop region is arranged under the drift region and adjoins the drift region. The field stop region is doped with dopants of the same doping type as the drift region. However, the concentration of dopants in the field stop region is higher than the concentration of dopants in the drift region. At least one pair of semiconductor layers composed of a first and a second semiconductor layer are arranged in the drift region.

Abstract: A semiconductor device includes a semiconductor mesa that includes at least one body zone forming first pn junctions with source zones and a second pn junction with a drift zone. Electrode structures are on opposite sides of the semiconductor mesa. At least one of the electrode structures includes a gate electrode configured to control a charge carrier flow through the at least one body zone. In a separation region between the source zones, which are arranged along an extension direction of the semiconductor mesa, the semiconductor mesa includes at least one partial or complete constriction.

Abstract: A semiconductor device includes a semiconductor mesa with at least one body zone forming first pn junctions with source zones and a second pn junction with a drift zone. A pedestal layer at a side of the drift zone opposite to the at least one body zone includes first zones of a conductivity type of the at least one body zone and second zones of the conductivity type of the drift zone. Electrode structures are on opposite sides of the semiconductor mesa. At least one of the electrode structures includes a gate electrode controlling a charge carrier flow through the at least one body zone. In a separation region between two of the source zones (i) a capacitive coupling between the gate electrode and the semiconductor mesa or (ii) a conductivity of majority charge carriers of the drift zone is lower than outside of the separation region.

Abstract: A semiconductor device includes an insulated gate bipolar transistor (IGBT) arrangement. The IGBT arrangement includes a carrier confinement reduction region laterally arranged between a cell region and a sensitive region. The IGBT arrangement is configured or formed so that the cell region has a first average density of free charge carriers in an on-state of the IGBT arrangement, the carrier confinement reduction region has a second average density of free charge carriers in the on-state of the IGBT arrangement and the sensitive region has a third average density of free charge carriers in the on-state of the IGBT arrangement. The first average density of free charge carriers is larger than the second average density of free charge carriers and the second average density of free charge carriers is larger than the third average density of free charge carriers.

Abstract: A semiconductor device includes a body zone in a semiconductor mesa, which is formed between neighboring control structures that extend from a first surface into a semiconductor body. A drift zone forms a first pn junction with the body zone. In the semiconductor mesa, the drift zone includes a first drift zone section that includes a constricted section of the semiconductor mesa. A minimum horizontal width of the constricted section parallel to the first surface is smaller than a maximum horizontal width of the body zone. An emitter layer between the drift zone and the second surface parallel to the first surface includes at least one first zone of a conductivity type of the drift zone.