Abstract: The invention relates to a turn-off power semiconductor device comprising a plurality of thyristor cells, each thyristor cell comprising a cathode region; a base layer; a drift layer; an anode layer; a gate electrode which is arranged lateral to the cathode region in contact with the base layer; a cathode electrode; and an anode electrode. Interfaces between the cathode regions and the cathode electrodes as well as interfaces between the base layers and the gate electrodes of the plurality of thyristor cells are flat and coplanar.

Abstract: A bidirectional power semiconductor device with full turn-off control in both current directions and improved electrical and thermal properties is provided, the device comprises a plurality of first gate commutated thyristor (GCT) cells and a plurality of second GCT cells alternating with each other, a first base layer of each first GCT cell is separated from a neighbouring second anode layer of a neighbouring second GCT cell by a first separation region, and a second base layer of each second GCT cell is separated from a neighbouring first anode layer of a neighbouring first GCT cell by a second separation region.

Abstract: A power semiconductor module including at least one power semiconductor chip providing a power electronics switch; and a semiconductor wafer, to which the at least one power semiconductor chip is bonded; wherein the semiconductor wafer is doped, such that it includes a field blocking region and an electrically conducting region on the field blocking region, to which electrically conducting region the at least one power semiconductor chip is bonded.

Abstract: A bidirectional power semiconductor device with full turn-off control in both current directions and improved electrical and thermal properties is provided, the device comprises a plurality of first gate commutated thyristor (GCT) cells and a plurality of second GCT cells alternating with each other, a first base layer of each first GCT cell is separated from a neighbouring second anode layer of a neighbouring second GCT cell by a first separation region, and a second base layer of each second GCT cell is separated from a neighbouring first anode layer of a neighbouring first GCT cell by a second separation region.

Abstract: A RC power semiconductor is provided which comprises a plurality of diode cells and a plurality of GCT cells. Each GCT cell comprises a first cathode layer with at least three cathode layer regions, which are separated from each other by a base layer. In orthogonal projection onto a plane parallel to the first main side each one of the cathode layer regions is strip-shaped and a width (w, w?), wherein the diode cells alternate with the GCT cells in a lateral direction in at least a mixed part, wherein in each GCT cell, the width (w?) of each one of the two outer cathode layer regions next to a diode cell neighboring to that GCT cell is less than the width (w) of any intermediate cathode layer region between the two outer cathode layer regions in that GCT cell.

Abstract: A RC power semiconductor is provided which comprises a plurality of diode cells and a plurality of GCT cells. Each GCT cell comprises a first cathode layer with at least three cathode layer regions, which are separated from each other by a base layer. In orthogonal projection onto a plane parallel to the first main side each one of the cathode layer regions is strip-shaped and a width (w, w?), wherein the diode cells alternate with the GCT cells in a lateral direction in at least a mixed part, wherein in each GCT cell, the width (w?) of each one of the two outer cathode layer regions next to a diode cell neighbouring to that GCT cell is less than the width (w) of any intermediate cathode layer region between the two outer cathode layer regions in that GCT cell.

Abstract: A reverse-conducting power semiconductor device with a wafer has first and second main sides which are arranged opposite and parallel to each other. The device includes a plurality of diode cells and a plurality of gate commutated thyristors (GCT) cells. Each GCT cell includes layers of a first conductivity type (e.g., n-type) and a second conductivity type (e.g., p-type) between the first and second main sides. The device includes at least one mixed part in which diode anode layers of the diode cells alternate with first cathode layers of the GCT cells. In each diode cell, a diode buffer layer of the first conductivity type is arranged between the diode anode layer and a drift layer such that the diode buffer layer covers lateral sides of the diode anode layer from the first main side to a depth of approximately 90% of the thickness of the diode anode layer.

Abstract: A reverse-conducting power semiconductor device with a wafer has first and second main sides which are arranged opposite and parallel to each other. The device includes a plurality of diode cells and a plurality of gate commutated thyristors (GCT) cells. Each GCT cell includes layers of a first conductivity type (e.g., n-type) and a second conductivity type (e.g., p-type) between the first and second main sides. The device includes at least one mixed part in which diode anode layers of the diode cells alternate with first cathode layers of the GCT cells. In each diode cell, a diode buffer layer of the first conductivity type is arranged between the diode anode layer and a drift layer such that the diode buffer layer covers lateral sides of the diode anode layer from the first main side to a depth of approximately 90% of the thickness of the diode anode layer.