Abstract: A method of manufacturing an insulated gate bipolar transistor includes providing trenches extending from a first surface to a layer section in a semiconductor portion, introducing impurities into mesa sections between the trenches, and forming, from the introduced impurities, second portions of doped regions separated from source regions by body regions. The source regions are electrically connected to an emitter electrode. The second portions have a second mean net impurity concentration exceeding at least ten times a first mean net impurity concentration in first portions of the doped layer. The first portions extend from the body regions to the layer section, respectively.

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: A method of manufacturing a semiconductor device includes forming a cavity in a first semiconductor layer formed on a semiconducting base layer, the cavity extending from a process surface of the first semiconductor layer at least down to the base layer, forming a recessed mask liner on a portion of a sidewall of the cavity distant to the process surface or a mask plug in a portion of the cavity distant to the process surface, and growing a second semiconductor layer on the process surface by epitaxy, the second semiconductor layer spanning the cavity.

Abstract: An electric assembly includes a semiconductor switching device with a maximum breakdown voltage rating across two load terminals in an off-state. A clamping diode is electrically connected to the two load terminals and parallel to the switching device. A semiconductor body of the clamping diode is made of silicon carbide. An avalanche voltage of the clamping diode is lower than the maximum breakdown voltage rating of the switching device.

Abstract: A first doped region is formed in a single crystalline semiconductor substrate. Light ions are implanted through a process surface into the semiconductor substrate to generate crystal lattice vacancies between the first doped region and the process surface, wherein a main beam axis of an implant beam used for implanting the light ions deviates by at most 1.5 degree from a main crystal direction along which channeling of the light ions occurs. A second doped region with a conductivity type opposite to the first doped region is formed based on the crystal lattice vacancies and hydrogen atoms.

Abstract: A method for forming a semiconductor device includes implanting doping ions into a semiconductor substrate. A deviation between a main direction of a doping ion beam implanting the doping ions and a main crystal direction of the semiconductor substrate is less than ±0.5° during the implanting of the doping ions into the semiconductor substrate. The method further includes controlling a temperature of the semiconductor substrate during the implantation of the doping ions so that the temperature of the semiconductor substrate is within a target temperature range for more than 70% of an implant process time used for implanting the doping ions. The target temperature range reaches from a lower target temperature limit to an upper target temperature limit. The lower target temperature limit is equal to a target temperature minus 30° C., and the target temperature is higher than 80° C.

Abstract: A semiconductor device is operated by applying a gate voltage with a first value to a gate electrode terminal such that current flows through the IGBT between first and second electrode terminals and current flow through a desaturation channel is substantially blocked. A gate voltage with a second value is applied to the gate electrode terminal the absolute value of which is lower than that of the first value, such that current flows through the IGBT between the first and second electrode terminals and charge carriers flow as a desaturating current through the desaturation channel to the first electrode terminal. A gate voltage with a third value is applied to the gate electrode terminal, the absolute value of which is lower than that of the first and second values, such that current flow through the IGBT between the first and second electrode terminals is substantially blocked.

Abstract: Temperature sensor devices and corresponding methods are provided. A temperature sensor may include a first layer being essentially non-conductive in a temperature range and a second layer having a varying resistance in the temperature range.

Abstract: A transistor is driven by a drive circuit that includes a logic unit and drive signal generator. The drive signal generator outputs a temporally variable drive voltage for driving the transistor, based on setpoint state information. A short-circuit information signal contains information about a possible short circuit of a load connected in series with the transistor load path. In response to this signal, the drive signal generator switches on the transistor at a first point in time by setting the transistor drive voltage to a value or a value range above a switch-on threshold value of the transistor, but limits the drive voltage to a maximum first switch-on voltage limit value. The drive signal generator maintains the drive voltage at maximally the first switch-on voltage limit value or sets the drive voltage to a value or a value range greater than or equal to a second switch-on voltage limit value.

Abstract: A semiconductor device includes a first load terminal electrically coupled to a source zone of a transistor cell. A gate terminal is electrically coupled to a gate electrode which is capacitively coupled to a body zone of the transistor cell. The source and body zones are formed in a semiconductor portion. A thermoresistive element is thermally connected to the semiconductor portion and is electrically coupled between the gate terminal and the first load terminal. Above a maximum operation temperature specified for the semiconductor device, an electric resistance of the thermoresistive element decreases by at least two orders of magnitude within a critical temperature span of at most 50 Kelvin.

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 body with parallel first and second surfaces and containing hydrogen-related donors. A concentration profile of the hydrogen-related donors vertical to the first surface includes a maximum value of at least 1E15 cm?3 at a first distance to the first surface and does not fall below 1E14 cm?3 over at least 60% of an interval between the first surface and the first distance.

Abstract: A semiconductor device includes a semiconductor mesa which is formed between cell trench structures extending from a first surface into a semiconductor body. The semiconductor mesa includes a body zone forming a first pn junction with a drift zone between the body zone and a second surface opposite to the first surface. Source zones are arranged along a longitudinal axis of the semiconductor mesa at a first distance from each other and form second pn junctions with the body zone. A barrier structure, which has the conductivity type of the source zones, forms at least one of a unipolar homojunction with the drift zone and a pn junction with the body zone at least outside a vertical projection of the source zones perpendicular to the first surface. The barrier structure may be absent in the vertical projection of the source zones.

Abstract: A semiconductor device includes at least one IGBT cell region, at least one switchable free-wheeling diode region, and at least one non-switchable free-wheeling diode region integrated in the same semiconductor substrate as the at least one IGBT cell region and the at least one switchable free-wheeling diode region.

Abstract: A semiconductor device includes transistor cells that connect a first load electrode with a drift structure forming first pn junctions with body zones when a gate voltage applied to a gate electrode exceeds a first threshold voltage. First auxiliary cells in a vertical projection of and electrically connected with the first load electrode are configured to inject charge carriers into the drift structure at least in a forward biased mode of the first pn junctions. Second auxiliary cells are configured to inject charge carriers into the drift structure at high emitter efficiency when in the forward biased mode of the first pn junctions the gate voltage is below a second threshold voltage lower than the first threshold voltage and at low emitter efficiency when the gate voltage exceeds the second threshold voltage.

Abstract: A semiconductor device includes a drift zone in a semiconductor body. A charge-carrier transfer region forms a pn junction with the drift zone in the semiconductor body. A control structure electrically connects a recombination region to the drift zone during a desaturation cycle and disconnects the recombination region from the drift zone outside the desaturation cycle. During the desaturation cycle the recombination region reduces a charge carrier plasma in the drift zone and reduces reverse recovery losses without adversely affecting blocking characteristics.

Abstract: A semiconductor switching device includes a first load terminal electrically connected to source zones of transistor cells. The source zones form first pn junctions with body zones. A second load terminal is electrically connected to a drain construction that forms second pn junctions with the body zones. Control structures, which include a control electrode and charge storage structures, directly adjoin the body zones. The control electrode controls a load current through the body zones. The charge storage structures insulate the control electrode from the body zones and contain a control charge adapted to induce inversion channels in the body zones in the absence of a potential difference between the control electrode and the first load electrode.

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 method for forming a semiconductor device includes implanting a predefined dose of protons into a semiconductor substrate. Further, the method comprises controlling a temperature of the semiconductor substrate during the implantation of the predefined dose of protons so that the temperature of the semiconductor substrate is within a target temperature range for more than 70% of an implant process time used for implanting the predefined dose of protons. The target temperature range reaches from a lower target temperature limit to an upper target temperature limit. Further, the lower target temperature limit is equal to a target temperature minus 30° C. and the upper target temperature limit is equal to the target temperature plus 30° C. and the target temperature is higher than 80° C.

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.