Abstract: Disclosed is a method for producing a semiconductor device, the method including forming a plurality of semiconductor arrangements one above the other, wherein forming each of the plurality of semiconductor arrangements includes forming a semiconductor layer, forming a plurality of trenches in a first surface of the semiconductor layer, and implanting dopant atoms of at least one of a first type and a second type into at least one of a first sidewall and a second sidewall of each of the plurality of trenches. Forming of at least one of the plurality of semiconductor arrangements further includes forming a protective layer covering mesa regions between the plurality of trenches of the respective semiconductor layer, and covering a bottom, the first sidewall and the second sidewall of each of the plurality of trenches that are formed in the respective semiconductor layer.

Abstract: A method and a transistor device are disclosed. The transistor device includes: a semiconductor body; first regions of a first doping type and second regions of a second doping type in an inner region and an edge region of the semiconductor body; transistor cells in the inner region of the semiconductor body, each transistor cell including a body region and a source region, the transistor cells including a common drain region; and a buffer region arranged between the drain region and the first and second regions. A dopant dose in the first and second regions decreases towards an edge surface of the semiconductor body. A dopant dose in the buffer region decreases towards the edge surface.

Abstract: Disclosed is a method for producing a semiconductor device, the method including forming a plurality of semiconductor arrangements one above the other, wherein forming each of the plurality of semiconductor arrangements includes forming a semiconductor layer, forming a plurality of trenches in a first surface of the semiconductor layer, and implanting dopant atoms of at least one of a first type and a second type into at least one of a first sidewall and a second sidewall of each of the plurality of trenches. Forming of at least one of the plurality of semiconductor arrangements further includes forming a protective layer covering mesa regions between the plurality of trenches of the respective semiconductor layer, and covering a bottom, the first sidewall and the second sidewall of each of the plurality of trenches that are formed in the respective semiconductor layer.

Abstract: A method for producing a semiconductor device includes forming transistor cells in a semiconductor body, each cell including a drift region separated from a source region by a body region, a gate electrode dielectrically insulated from the body region, and a compensation region of a doping type complementary to the doping type of the drift region and extending from a respective body region into the drift region in a vertical direction. Forming the drift and compensation regions includes performing a first implantation step, thereby implanting first and second type dopant atoms into the semiconductor body, wherein an implantation dose of at least one of the first type dopant atoms and the second type dopant atoms for each of at least two sections of the semiconductor body differs from the implantation dose of the corresponding type of dopant atoms of at least one other section of the at least two sections.

Abstract: A transistor device and a method for forming a transistor device are disclosed. The transistor device includes: first regions of a first doping type and second regions of a second doping type in an inner region and an edge region of a semiconductor body; and transistor cells each having a body region and a source region in the inner region of the semiconductor body. An effective lateral doping dose of the first regions in the edge region is lower than an effective lateral doping dose of the first regions in the inner region. An effective lateral doping dose of the second regions in the edge region is lower than an effective lateral doping dose of the second regions in the inner region.

Abstract: A transistor device and a method for forming a transistor device are disclosed. The method includes: forming first regions of a first doping type and second regions of a second doping type in inner and edge regions of a semiconductor body; and forming body and source regions of transistor cells in the inner region. Forming the first and second regions includes: forming first and second implanted regions in the inner and edge regions, each first implanted region including at least dopant atoms of a first doping type and each second implanted region including at least dopant atoms of a second doping type; and diffusing the dopant atoms of both doping types in a thermal process such that dopant atoms of at least one of the first and second doping types have at least one of different diffusion rates and diffusion lengths in the inner and edge regions.

Abstract: Forming a semiconductor arrangement includes providing a first semiconductor layer having a first surface, forming a first plurality of trenches in the first surface of the first semiconductor layer, each of the trenches in the first plurality having first and second sidewalls that extend from the first surface to a bottom of the respective trench, implanting first type dopant atoms into the first and second sidewalls of each of the trenches in the first plurality, implanting second type dopant atoms into the first and second sidewalls of each of the trenches in the first plurality, and annealing the semiconductor arrangement to simultaneously activate the first type dopant atoms and the second type dopant atoms.

Abstract: A method and a transistor device are disclosed. The transistor device includes: a semiconductor body; first regions of a first doping type and second regions of a second doping type in an inner region and an edge region of the semiconductor body; transistor cells in the inner region of the semiconductor body, each transistor cell including a body region and a source region, the transistor cells including a common drain region; and a buffer region arranged between the drain region and the first and second regions. A dopant dose in the first and second regions decreases towards an edge surface of the semiconductor body. A dopant dose in the buffer region decreases towards the edge surface.

Abstract: Disclosed is a method for producing a semiconductor device, the method including forming a plurality of semiconductor arrangements one above the other, wherein forming each of the plurality of semiconductor arrangements includes forming a semiconductor layer, forming a plurality of trenches in a first surface of the semiconductor layer, and implanting dopant atoms of at least one of a first type and a second type into at least one of a first sidewall and a second sidewall of each of the plurality of trenches. Forming of at least one of the plurality of semiconductor arrangements further includes forming a protective layer covering mesa regions between the plurality of trenches of the respective semiconductor layer, and covering a bottom, the first sidewall and the second sidewall of each of the plurality of trenches that are formed in the respective semiconductor layer.

Abstract: A method for forming a drift region of a superjunction transistor and a superjunction transistor device are disclosed. The method includes forming first regions of a first doping type and second regions of a second type in a semiconductor body such that the first and second regions are arranged alternatingly in the body. The first and second regions are formed by: forming trenches in at least one semiconductor layer; implanting first type dopant atoms and second type dopant atoms into opposing sidewalls of the trenches; filling the trenches with a semiconductor material; and diffusing the dopant atoms in a thermal process so that the first type dopant atoms form the first regions and the second type dopant atoms form the second regions. Each trench has a first width, the trenches are separated by mesa regions each having a second width, and the first width is greater than the second width.

Abstract: A method for producing a semiconductor device includes forming transistor cells in a semiconductor body, each cell including a drift region separated from a source region by a body region, a gate electrode dielectrically insulated from the body region, and a compensation region of a doping type complementary to the doping type of the drift region and extending from a respective body region into the drift region in a vertical direction. Forming the drift and compensation regions includes performing a first implantation step, thereby implanting first and second type dopant atoms into the semiconductor body, wherein an implantation dose of at least one of the first type dopant atoms and the second type dopant atoms for each of at least two sections of the semiconductor body differs from the implantation dose of the corresponding type of dopant atoms of at least one other section of the at least two sections.

Abstract: A method and a transistor device are disclosed. The method includes: forming first regions of a first doping type and second regions of a second doping type in an inner region and an edge region of a semiconductor body; and forming body regions and source regions of transistor cells in the inner region of the semiconductor body. Forming the first regions and second regions includes: forming semiconductor layers one on top of the other; and in each of the semiconductor layers and before forming a respective next one of the semiconductor layers, forming trenches in the inner region and the edge region and implanting dopant atoms into a first sidewall and a second sidewall of each trench. Implanting the dopant atoms into at least one of the semiconductor layers includes partly covering the trenches in the edge region during an implantation process.

Abstract: Disclosed is a method. The method includes forming a trench structure with at least one first trench in a first section of a semiconductor body; forming a second trench that is wider than the first trench in a second section of the semiconductor body; and forming a semiconductor layer on a surface of the semiconductor body in the first section and the second section and in the at least one first trench and the second trench such that the semiconductor layer has a substantially planar surface above the first section and a residual trench remains above the second section. Forming the semiconductor layer includes forming a first epitaxial layer in a first epitaxial growth process and a second epitaxial layer on top of the first epitaxial layer in a second epitaxial growth process.

Abstract: A transistor device and a method for forming a transistor device are disclosed. The method includes: forming first regions of a first doping type and second regions of a second doping type in inner and edge regions of a semiconductor body; and forming body and source regions of transistor cells in the inner region. Forming the first and second regions includes: forming first and second implanted regions in the inner and edge regions, each first implanted region including at least dopant atoms of a first doping type and each second implanted region including at least dopant atoms of a second doping type; and diffusing the dopant atoms of both doping types in a thermal process such that dopant atoms of at least one of the first and second doping types have at least one of different diffusion rates and diffusion lengths in the inner and edge regions.

Abstract: Forming a semiconductor arrangement includes providing a first semiconductor layer having a first surface, forming a first plurality of trenches in the first surface of the first semiconductor layer, each of the trenches in the first plurality having first and second sidewalls that extend from the first surface to a bottom of the respective trench, implanting first type dopant atoms into the first and second sidewalls of each of the trenches in the first plurality, implanting second type dopant atoms into the first and second sidewalls of each of the trenches in the first plurality, and annealing the semiconductor arrangement to simultaneously activate the first type dopant atoms and the second type dopant atoms.

Abstract: A method and a transistor device are disclosed. The method includes: forming first regions of a first doping type and second regions of a second doping type in an inner region and an edge region of a semiconductor body; and forming body regions and source regions of transistor cells in the inner region of the semiconductor body. Forming the first regions and second regions includes: forming semiconductor layers one on top of the other; and in each of the semiconductor layers and before forming a respective next one of the semiconductor layers, forming trenches in the inner region and the edge region and implanting dopant atoms into a first sidewall and a second sidewall of each trench. Implanting the dopant atoms into at least one of the semiconductor layers includes partly covering the trenches in the edge region during an implantation process.

Abstract: Disclosed is a method that includes forming a plurality of semiconductor arrangements one above the other. In this method, forming each of the plurality of semiconductor arrangements includes: forming a semiconductor layer; forming a plurality of trenches in a first surface of the semiconductor layer; and implanting dopant atoms of at least one of a first type and a second type into at least one of a first sidewall and a second sidewall of each of the plurality of trenches of the semiconductor layer.

Abstract: A method for forming a field-effect semiconductor device includes providing a wafer having a substantially compensated semiconductor layer extending to an upper side and including a semiconductor material which is co-doped with n-type dopants and p-type dopants. A peripheral area laterally surrounding an active area are defined in the wafer. Trenches in the active area are filled with a substantially intrinsic semiconductor material. More p-type dopants than n-type dopants are diffused from the compensated semiconductor layer into the intrinsic semiconductor material to form a plurality of p-type compensation regions in the trenches which are separated from each other by respective n-type drift portions. P-type dopants are introduced at least into a semiconductor zone of the peripheral area, so that the semiconductor zone and a dielectric layer on the upper side form an interface. A horizontal extension of the interface is larger than a vertical extension of the trenches.

Abstract: A semiconductor wafer having a main surface is provided. A first etch resistant mask is provided on the main surface. A first reactive ion etching step that forms a first group of trenches using the first etch resistant mask is performed. Each of the trenches in the first group is covered with a second etch resistant mask after performing the first reactive ion etching step. A second reactive ion etching step that forms a second group of trenches using one or both of the first etch resistant mask and the second etch resistant mask is performed. The trenches in the second group are laterally offset from the trenches in the first group. The first and second reactive ion etching processes are performed such that a depth of the trenches of the first group is substantially equal to a depth of the trenches in the second group.

Abstract: A method includes forming first regions of a first doping type and second regions of a second doping type in first and second semiconductor layers such that the first and second regions are arranged alternately in at least one horizontal direction of the first and second semiconductor layers, and forming a control structure with transistor cells each including at least one body region, at least one source region and at least one gate electrode in the second semiconductor layer. Forming the first and second regions includes: forming trenches in the first semiconductor layer and implanting at least one of first and second type dopant atoms into sidewalls of the trenches; forming the second semiconductor layer on the first semiconductor layer such that the second layer fills the trenches; implanting at least one of first and second type dopant atoms into the second semiconductor layer; and at least one temperature process.