A semiconductor device includes a semiconductor substrate including, between a bottom side and a top side, a first trench and a second trench extending in a vertical direction, and a contact groove arranged between the first trench and the second trench. The contact groove has a longitudinal extension in a plane perpendicular to the vertical direction. The longitudinal extension of the contact groove at least partially has a wave-shape.

A semiconductor device comprises a first semiconductor wafer including a cavity formed in the first semiconductor die. A second semiconductor die is bonded to the first semiconductor die over the cavity. A first transistor includes a portion of the first transistor formed over the cavity.

A method of manufacturing a semiconductor device includes forming electrode trenches in a semiconductor substrate between semiconductor mesas that separate the electrode trenches, the semiconductor mesas including portions of a drift layer of a first conductivity type and a body layer of a second, complementary conductivity type between a first surface of the semiconductor substrate and the drift layer, respectively. The method further includes forming isolated source zones of the first conductivity type in the semiconductor mesas, the source zones extending from the first surface into the body layer. The method also includes forming separation structures in the semiconductor mesas between neighboring source zones arranged along an extension direction of the semiconductor mesas, the separation structures forming partial or complete constrictions of the semiconductor mesa, respectively.

A semiconductor device which solves the following problem of a super junction structure: due to a relatively high concentration in the body cell region (active region), in peripheral areas (peripheral regions or junction end regions), it is difficult to achieve a breakdown voltage equivalent to or higher than in the cell region through a conventional junction edge terminal structure or resurf structure. The semiconductor device includes a power MOSFET having a super junction structure formed in the cell region by a trench fill technique. Also, super junction structures having orientations parallel to the sides of the cell region are provided in a drift region around the cell region.

The present invention provides a switching device (100) for power conversion in which a first gate electrode (6), a p-type channel layer (2) having an n-type emitter region (3), a second gate electrode (13), and a p-type floating layer (15) are repeatedly arranged in order on the surface side of an n.sup.type semiconductor substrate (1). An interval a between the two gates (6, 13) that sandwich the p-type channel layer (2) is configured to be smaller than an interval b between the two gates (13, 6) that sandwich the p-type floating layer (15). The first gate electrode (6) and the second gate electrode (13) are both supplied with drive signals having a time difference in drive timing.

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.

A method of manufacturing a semiconductor device includes: forming field electrode structures extending in a direction vertical to a first surface in a semiconductor body; forming cell mesas from portions of the semiconductor body between the field electrode structures, including body zones forming first pn junctions with a drift zone; forming gate structures between the field electrode structures and configured to control a current flow through the body zones; and forming auxiliary diode structures with a forward voltage lower than the first pn junctions and electrically connected in parallel with the first pn junctions, wherein semiconducting portions of the auxiliary diode structures are formed in the cell mesas.

Disclosed is a method for producing a transistor device and a transistor device. The method includes: forming a source region of a first doping type in a body region of a second doping type in a semiconductor body; and forming a low-resistance region of the second doping type adjoining the source region in the body region. Forming the source region includes implanting dopant particles of the first doping type using an implantation mask via a first surface of the semiconductor body into the body region. Implanting the doping particles of the first doping type includes a tilted implantation.

A semiconductor device and a method for producing thereof is provided. The semiconductor device includes a plurality of device cells, each comprising a body region, a source region, and a gate electrode adjacent to the body region and dielectrically insulated from the body region by a gate dielectric; and an electrically conductive gate layer comprising the gate electrodes or electrically connected to the gate electrodes of the plurality of device cells. The gate layer is electrically connected to a gate conductor and includes at least one of an increased resistance region and a decreased resistance region.

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.