Abstract: A power semiconductor device comprises a semiconductor body, a gate electrode, and an extraction electrode, wherein the semiconductor body comprises a source region of a first conductivity type, well region of a second conductivity type different from the first conductivity type at the gate electrode, a drift region which is of the first conductivity type, and a barrier region which is of the first conductivity type, the barrier region is located between the drift region and the extraction electrode.

Abstract: A power semiconductor device comprises a semiconductor body, a gate electrode, and an extraction electrode, wherein the semiconductor body comprises a source region of a first conductivity type, a well region of a second conductivity type different from the first conductivity type at the gate electrode, a drift region which is of the first conductivity type, and a barrier region which is of the first conductivity type, the barrier region is located between the drift region and the extraction electrode.

Abstract: A reverse conducting insulated gate power semiconductor device is provided which comprises a plurality of active unit cells (40) and a pilot diode unit cell (50) comprising a second conductivity type anode region (51) in direct contact with a first main electrode (21) and extending from a first main side (11) to a first depth (d1). Each active unit cell (40) comprises a first conductivity type first source layer (41a) in direct contact with the first main electrode (21), a second conductivity type base layer (42) and a first gate electrode (47a), which is separated from the first source layer (41a) and the second conductivity type base layer (42) by a first gate insulating layer (46a) to form a first field effect transistor structure. A lateral size (w) of the anode region (51) in an orthogonal projection onto a vertical plane perpendicular to the first main side (11) is equal to or less than 1 ?m.

Abstract: A power semiconductor device (1) comprises a gate-commutated thyristor cell (20) including a cathode electrode (2), a cathode region (9) of a first conductivity type, a base layer (8) of a second conductivity type, a drift layer (7) of the first conductivity type, an anode layer (5) of the second conductivity type, an anode electrode (3) and a gate electrode (4). The base layer (8) comprises a cathode base region (81) located between the cathode region (9) and the drift layer (7) and having a first depth (D1), a gate base region (82) located between the gate electrode (4) and the drift layer (7) and having a second depth (D2), and an intermediate base region (83) located between the cathode base region (81) and the gate base region (82) and having two different values of a third depth (D3) being between the first depth (D1) and the second depth (D2).

Abstract: A power semiconductor device and method of manufacture thereof involving drift layer of a first conductivity type; base layer of a second conductivity type different than the first conductivity type; source region with first conductivity type arranged on a side of the base layer facing away from the drift layer; a first trench extending from the emitter side into the drift layer; an insulated trench gate electrode extending into the first trench; a second trench being arranged on a side of a first trench facing away from the source region; an electrically conductive layer extending into the second trench and electrically insulated from the base layer and the drift layer. A portion of the base layer extends from the emitter side at least as deep in the vertical direction towards the collector side as the at least one second trench.

Abstract: An insulated gate bipolar transistor includes a source electrode, a collector electrode, a source layer, a base layer, a drift layer and a collector layer. Trench gate electrodes extend through the base layer into the drift layer. A channel is located between the source layer, the base layer and the drift layer. A trench Schottky electrode is adjacent to one of the trench gate electrodes and includes an electrically conductive Schottky layer arranged lateral to the base layer and extends through the base layer into the drift layer. The Schottky layer is electrically connected to the source electrode. Collection areas are located in the drift layer at a respective trench gate electrode bottom of the trench gate electrodes or of the trench Schottky electrode. The Schottky layer forms a Schottky contact to the collection area at a contact area.

Abstract: A reverse conducting insulated gate power semiconductor device is provided which comprises a plurality of active unit cells (40) and a pilot diode unit cell (50) comprising a second conductivity type anode region (51) in direct contact with a first main electrode (21) and extending from a first main side (11) to a first depth (d1). Each active unit cell (40) comprises a first conductivity type first source layer (41a) in direct contact with the first main electrode (21), a second conductivity type base layer (42) and a first gate electrode (47a), which is separated from the first source layer (41a) and the second conductivity type base layer (42) by a first gate insulating layer (46a) to form a first field effect transistor structure. A lateral size (w) of the anode region (51) in an orthogonal projection onto a vertical plane perpendicular to the first main side (11) is equal to or less than 1 ?m.

Abstract: A power semiconductor device comprises a wafer (2) having an active region (AR) and a termination region (TR) laterally surrounding the active region; floating field rings in the termination region; a lifetime control region comprising defects reducing a carrier lifetime; and a protecting layer (6) on the wafer. The protecting layer covers the termination region and comprises a thin portion (61) and a thick portion (62) laterally surrounding the thin portion. The thick portion covers the floating field rings. The lifetime control region (5) extends in a lateral direction throughout the active region and in the termination region throughout a portion which is covered by the thin portion and not in a portion which is covered by the thick portion. According to a fabrication method the lifetime control region is formed by irradiating the wafer (2) with ions using the protecting layer (6) as an irradiation mask.

Abstract: An insulated gate power semiconductor device (1a), comprises in an order from a first main side (20) towards a second main side (27) opposite to the first main side (20) a first conductivity type source layer (3), a second conductivity type base layer (4), a first conductivity type enhancement layer (6) and a first conductivity type drift layer (5). The insulated gate power semiconductor device (1a) further comprises two neighbouring trench gate electrodes (7) to form a vertical MOS cell sandwiched between the two neighbouring trench gate electrodes (7). At least a portion of a second conductivity type protection layer (8a) is arranged in an area between the two neighbouring trench gate electrodes (7), wherein the protection layer (8a) is separated from the gate insulating layer (72) by a first conductivity type channel layer (60a; 60b) extending along the gate insulating layer (72).

Abstract: An insulated gate power semiconductor device (1a), comprises in an order from a first main side (20) towards a second main side (27) opposite to the first main side (20) a first conductivity type source layer (3), a second conductivity type base layer (4), a first conductivity type enhancement layer (6) and a first conductivity type drift layer (5). The insulated gate power semiconductor device (1a) further comprises two neighbouring trench gate electrodes (7) to form a vertical MOS cell sandwiched between the two neighbouring trench gate electrodes (7). At least a portion of a second conductivity type protection layer (8a) is arranged in an area between the two neighbouring trench gate electrodes (7), wherein the protection layer (8a) is separated from the gate insulating layer (72) by a first conductivity type channel layer (60a; 60b) extending along the gate insulating layer (72).

Abstract: An insulated gate power semiconductor device includes an (n-) doped drift layer between an emitter side and a collector side. A p doped protection pillow covers a trench bottom of a trench gate electrode. An n doped enhancement layer having a maximum enhancement layer doping concentration in an enhancement layer depth separates the base layer from the drift layer. An n doped plasma enhancement layer having a maximum plasma enhancement layer doping concentration covers an edge region between the protection pillow and the trench gate electrode. The N doping concentration decreases from the maximum enhancement layer doping concentration towards the plasma enhancement layer and the N doping concentration decreases from the maximum plasma enhancement layer doping concentration towards the enhancement layer such that the N doping concentration has a local doping concentration minimum between the enhancement layer and the plasma enhancement layer.

Abstract: An IGBT is provided with at least two first cells, each of which have an n doped source layer, a p doped base layer, an n doped enhancement layer. The base layer separates the source layer from the enhancement layer, an n-doped drift layer and a p doped collector layer. Two trench gate electrodes are arranged on the lateral sides of the first cell. The transistor includes at least one second cell between the trench gate electrodes of two neighboring first cells, which has on the emitter side a p+ doped well and a further n doped enhancement layer which separates the well from the neighboring trench gate electrodes. An insulator layer stack is arranged on top of the second cell on the emitter side to insulate the second cell and the neighboring trench gate electrodes from the metal emitter electrode.

Abstract: An insulated gate power semiconductor device includes an (n?) doped drift layer between an emitter side and a collector side. A p doped protection pillow covers a trench bottom of a trench gate electrode. An n doped enhancement layer having a maximum enhancement layer doping concentration in an enhancement layer depth separates the base layer from the drift layer. An n doped plasma enhancement layer having a maximum plasma enhancement layer doping concentration covers an edge region between the protection pillow and the trench gate electrode. The n doping concentration decreases from the maximum enhancement layer doping concentration towards the plasma enhancement layer and the n doping concentration decreases from the maximum plasma enhancement layer doping concentration towards the enhancement layer such that the n doping concentration has a local doping concentration minimum between the enhancement layer and the plasma enhancement layer.

Abstract: An IGBT is provided comprising at least two first cells (1, 1?), each of which having an n doped source layer (2), a p doped base layer (3), an n doped enhancement layer (4), wherein the base layer (3) separates the source layer (2) from the enhancement layer (4), an n? doped drift layer (5) and a p doped collector layer (6). Two trench gate electrodes (7, 7?) are arranged on the lateral sides of the first cell (1, 1?). The transistor comprises at least one second cell (15) between the trench gate electrodes (7, 7?) of two neighboured first cells (1, 1?), which has on the emitter side (90) a p+ doped well (8) and a further n doped enhancement layer (40, 40?) which separates the well (8) from the neighboured trench gate electrodes (7, 7?).

Abstract: The present application contemplates a method for manufacturing a power semiconductor device.

Abstract: An insulated gate power semiconductor device has an (n?) doped drift layer between an emitter side and a collector side. A trench gate electrode has a trench bottom and trench lateral sides and extends to a trench depth. A p doped first protection pillow covers the trench bottom. An n doped second protection pillow encircles the trench gate electrode at its trench lateral sides. The second protection pillow has a maximum doping concentration in a first depth, which is at least half the trench depth, wherein a doping concentration of the second protection pillow decreases towards the emitter side from the maximum doping concentration to a value of not more than half the maximum doping concentration. An n doped enhancement layer has a maximum doping concentration in a second depth, which is lower than the first depth, wherein the doping concentration has a local doping concentration minimum between the second depth and the first depth.

Abstract: A reverse-conducting MOS device is provided having an active cell region and a termination region. Between a first and second main side. The active cell region comprises a plurality of MOS cells with a base layer of a second conductivity type. On the first main side a bar of the second conductivity type, which has a higher maximum doping concentration than the base layer, is arranged between the active cell region and the termination region, wherein the bar is electrically connected to the first main electrode. On the first main side in the termination region a variable-lateral-doping layer of the second conductivity type is arranged. A protection layer of the second conductivity type is arranged in the variable-lateral-doping layer, which protection layer has a higher maximum doping concentration than the maximum doping concentration of the variable-lateral-doping layer in a region attached to the protection layer.

Abstract: The present application contemplates a method for manufacturing a power semiconductor device.

Abstract: A termination region of an IGBT is described, in which surface p-rings are combined with oxide/polysilicon-filled trenches, buried p-rings and surface field plates, so as to obtain an improved distribution of potential field lines in the termination region. The combination of surface ring termination and deep ring termination offers a significant reduction in the amount silicon area which is required for the termination region.

Abstract: An IGBT is provided having a first gate unit having first trench gates with first conductive layers and planar gates with second conductive layers. A second gate unit having a second trench gates may be connected to the emitter electrode, with the first and second conductive layers forming a first shape closed in itself and enclosing the second gate unit. Third trench gates are arranged between a planar gate and the second gate unit such that first and third trench gates are connected and form a second shape closed in itself by which the second gate unit is enclosed. P+ doped bars below the planar gale contact the emitter electrode with each third trench gate separating a bar and a planar gate electrode from the second gate unit, with a p doped base layer separating the second gate unit from the enclosing second shape.