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: The invention relates to a bipolar non-punch-through power semiconductor device and a corresponding manufacturing method. The device comprises a semiconductor wafer and a first electrode formed on a first main side of the wafer and a second electrode formed on a second main side of the wafer opposite the first main side. The wafer comprises a pair of layers of different conductivity types, such as a drift layer of a first conductivity type, and a first layer of a second conductivity type arranged on the drift layer towards the first main side and contacting the first electrode. The wafer comprises an inner region wand an outer region surrounding the inner region. The drift layer has a thickness in the inner region greater or equal than a thickness in the outer region. A thickness of the first layer increases in a transition region between the inner region and the outer region from a thickness in the inner region to a maximum thickness in the outer region.

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.

Abstract: A method for manufacturing a power semiconductor device is disclosed which can include: providing a wafer of a first conductivity type; and applying on a second main side of the wafer at least one of a dopant of the first conductivity type for forming a layer of the first conductivity type and a dopant of a second conductivity type for forming a layer of the second conductivity type. A Titanium layer with a metal having a melting point above 1300° C. is then deposited on the second main side. The Titanium deposition layer is annealed so that simultaneously an intermetal compound layer is formed at the interface between the Titanium deposition layer and the wafer and the dopant is diffused into the wafer. A first metal electrode layer is created on the second main side.

Abstract: A fast recovery diode includes a base layer of a first conductivity type. The base layer has a cathode side and an anode side opposite the cathode side. An anode buffer layer of a second conductivity type having a first depth and a first maximum doping concentration is arranged on the anode side. An anode contact layer of the second conductivity type having a second depth, which is lower than the first depth, and a second maximum doping concentration, which is higher than the first maximum doping concentration, is also arranged on the anode side. A space charge region of the anode junction at a breakdown voltage is located in a third depth between the first and second depths. A defect layer with a defect peak is arranged between the second and third depths.

Abstract: A maximum-punch-through semiconductor device such as an insulated gate bipolar transistor (IGBT) or a diode, and a method for producing same are disclosed. The MPT semiconductor device can include at least a two-layer structure having an emitter metallization, a channel region, a base layer with a predetermined doping concentration ND, a buffer layer and a collector metallization. A thickness W of the base layer can be determined by: W = V bd + V pt 4010 ? ? kV ? ? cm - 5 / 8 * ( N D ) 1 / 8 wherein a punch-through voltage Vpt of the semiconductor device is between 70% and 99% of a break down voltage Vbd of the semiconductor device, and wherein the thickness W is a minimum thickness of the base layer between a junction to the channel region and the buffer layer.

Abstract: An exemplary bipolar non-punch-through power semiconductor device includes a semiconductor wafer and a first electrical contact on a first main side and a second electrical contact on a second main side. The wafer has an inner region with a wafer thickness and a termination region that surrounds the inner region, such that the wafer thickness is reduced at least on the first main side with a negative bevel. The semiconductor wafer has at least a two-layer structure with layers of different conductivity types, which can include a drift layer of a first conductivity type, a first layer of a second conductivity type at a first layer depth and directly connected to the drift layer on the first main side and contacting the first electrical contact, and a second layer of the second conductivity type arranged in the termination region on the first main side up to a second layer depth.

Abstract: A method for producing a semiconductor device such as a RC-IGBT or a BIGT having a patterned surface wherein partial regions doped with dopants of a first conductivity type and regions doped with dopants of a second conductivity type are on a same side of a semiconductor substrate is proposed. An exemplary method includes: (a) implanting dopants of the first conductivity type and implanting dopants of the second conductivity type into the surface to be patterned; (b) locally activating dopants of the first conductivity type by locally heating the partial region of the surface to be patterned to a first temperature (e.g., between 900 and 1000° C.) using a laser beam similar to those used in laser annealing; and (c) activating the dopants of the second conductivity type by heating the substrate to a second temperature lower than the first temperature (e.g., to a temperature below 600° C.).

Abstract: A reverse-conducting insulated gate bipolar transistor includes a wafer of first conductivity type with a second layer of a second conductivity type and a third layer of the first conductivity type. A fifth electrically insulating layer partially covers these layers. An electrically conductive fourth layer is electrically insulated from the wafer by the fifth layer. The third through the fifth layers form a first opening above the second layer. A sixth layer of the second conductivity type and a seventh layer of the first conductivity type are arranged alternately in a plane on a second side of the wafer. A ninth layer is formed by implantation of ions through the first opening using the fourth and fifth layers as a first mask.

Abstract: A controlled-punch-through semiconductor device with a four-layer structure is disclosed which includes layers of different conductivity types, a collector on a collector side, and an emitter on an emitter side which lies opposite the collector side. The semiconductor device can be produced by a method performed in the following order: producing layers on the emitter side of wafer of a first conductivity type; thinning the wafer on a second side; applying particles of the first conductivity type to the wafer on the collector side for forming a first buffer layer having a first peak doping concentration in a first depth, which is higher than doping of the wafer; applying particles of a second conductivity type to the wafer on the second side for forming a collector layer on the collector side; and forming a collector metallization on the second side.

Abstract: An exemplary method is disclosed for manufacturing a power semiconductor device which has a first electrical contact on a first main side and a second electrical contact on a second main side opposite the first main side and at least a two-layer structure with layers of different conductivity types, and includes providing an n-doped wafer and creating a surface layer of palladium particles on the first main side. The wafer is irradiated on the first main side with ions. Afterwards, the palladium particles are diffused into the wafer at a temperature of not more than 750° C., by which diffusion a first p-doped layer is created. Then, the first and second electrical contacts are created. At least the irradiation with ions is performed through a mask.

Abstract: A fast recovery diode includes an n-doped base layer having a cathode side and an anode side opposite the cathode side. A p-doped anode layer is arranged on the anode side. The anode layer has a doping profile and includes at least two sublayers. A first one of the sublayers has a first maximum doping concentration, which is between 2*1016 cm?3 and 2*1017 cm?3 and which is higher than the maximum doping concentration of any other sublayer. A last one of the sublayers has a last sublayer depth, which is larger than any other sublayer depth. The last sublayer depth is between 90 to 120 ?m. The doping profile of the anode layer declines such that a doping concentration in a range of 5*1014 cm?3 and 1*1015 cm?3 is reached between a first depth, which is at least 20 ?m, and a second depth, which is at maximum 50 ?m. Such a profile of the doping concentration is achieved by using aluminum diffused layers as the at least two sublayers.

Abstract: A maximum-punch-through semiconductor device such as an insulated gate bipolar transistor (IGBT) or a diode, and a method for producing same are disclosed. The MPT semiconductor device can include at least a two-layer structure having an emitter metallization, a channel region, a base layer with a predetermined doping concentration ND, a buffer layer and a collector metallization. A thickness W of the base layer can be determined by: W = V bd + V pt 4010 ? ? kV ? ? cm - 5 / 8 * ( N D ) 1 / 8 wherein a punch-through voltage Vpt of the semiconductor device is between 70% and 99% of a break down voltage Vbd of the semiconductor device, and wherein the thickness W is a minimum thickness of the base layer between a junction to the channel region and the buffer layer.

Abstract: A method for producing a semiconductor device such as a RC-IGBT or a BIGT having a patterned surface wherein partial regions doped with dopants of a first conductivity type and regions doped with dopants of a second conductivity type are on a same side of a semiconductor substrate is proposed. An exemplary method includes: (a) implanting dopants of the first conductivity type and implanting dopants of the second conductivity type into the surface to be patterned; (b) locally activating dopants of the first conductivity type by locally heating the partial region of the surface to be patterned to a first temperature (e.g., between 900 and 1000° C.) using a laser beam similar to those used in laser annealing; and (c) activating the dopants of the second conductivity type by heating the substrate to a second temperature lower than the first temperature (e.g., to a temperature below 600° C.).

Abstract: A fast recovery diode includes an n-doped base layer having a cathode side and an anode side opposite the cathode side. A p-doped anode layer is arranged on the anode side. The anode layer has a doping profile and includes at least two sublayers. A first one of the sublayers has a first maximum doping concentration, which is between 2*1016 cm?3 and 2*1017 cm?3 and which is higher than the maximum doping concentration of any other sublayer. A last one of the sublayers has a last sublayer depth, which is larger than any other sublayer depth. The last sublayer depth is between 90 to 120 ?m. The doping profile of the anode layer declines such that a doping concentration in a range of 5*1014 cm?3 and 1*1015 cm?3 is reached between a first depth, which is at least 20 ?m, and a second depth, which is at maximum 50 ?m. Such a profile of the doping concentration is achieved by using aluminium diffused layers as the at least two sublayers.

Abstract: A fast recovery diode includes a base layer of a first conductivity type. The base layer has a cathode side and an anode side opposite the cathode side. An anode buffer layer of a second conductivity type having a first depth and a first maximum doping concentration is arranged on the anode side. An anode contact layer of the second conductivity type having a second depth, which is lower than the first depth, and a second maximum doping concentration, which is higher than the first maximum doping concentration, is also arranged on the anode side. A space charge region of the anode junction at a breakdown voltage is located in a third depth between the first and second depths. A defect layer with a defect peak is arranged between the second and third depths.

Abstract: A reverse-conducting insulated gate bipolar transistor includes a wafer of first conductivity type with a second layer of a second conductivity type and a third layer of the first conductivity type. A fifth electrically insulating layer partially covers these layers. An electrically conductive fourth layer is electrically insulated from the wafer by the fifth layer. The third through the fifth layers form a first opening above the second layer. A sixth layer of the second conductivity type and a seventh layer of the first conductivity type are arranged alternately in a plane on a second side of the wafer. A ninth layer is formed by implantation of ions through the first opening using the fourth and fifth layers as a first mask.

Abstract: An exemplary method is disclosed for manufacturing a power semiconductor device which has a first electrical contact on a first main side and a second electrical contact on a second main side opposite the first main side and at least a two-layer structure with layers of different conductivity types, and includes providing an n-doped wafer and creating a surface layer of palladium particles on the first main side. The wafer is irradiated on the first main side with ions. Afterwards, the palladium particles are diffused into the wafer at a temperature of not more than 750° C., by which diffusion a first p-doped layer is created. Then, the first and second electrical contacts are created. At least the irradiation with ions is performed through a mask.

Abstract: A controlled-punch-through semiconductor device with a four-layer structure is disclosed which includes layers of different conductivity types, a collector on a collector side, and an emitter on an emitter side which lies opposite the collector side. The semiconductor device can be produced by a method performed in the following order: producing layers on the emitter side of wafer of a first conductivity type; thinning the wafer on a second side; applying particles of the first conductivity type to the wafer on the collector side for forming a first buffer layer having a first peak doping concentration in a first depth, which is higher than doping of the wafer; applying particles of a second conductivity type to the wafer on the second side for forming a collector layer on the collector side; and forming a collector metallization on the second side.