Abstract: A transistor arrangement includes: a layer stack with first and second semiconductor layers of complementary first and second doping types; a first source region of a first transistor device adjoining the first semiconductor layers; a first drain region of the first transistor device adjoining the second semiconductor layers and spaced apart from the first source region; gate regions of the first transistor device, each gate region adjoining at least one second semiconductor layer, being arranged between the first source region and the first drain region, and being spaced apart from the first source region and the first drain region; a third semiconductor layer adjoining the layer stack and each of the first source region, first drain region, and each gate region; and active regions of a second transistor device integrated in the third semiconductor layer in a second region spaced apart from a first region of the third semiconductor layer.

Abstract: An electronic circuit is disclosed. The electronic circuit includes: a first transistor device integrated in an inner region of a first semiconductor body; a level shifter integrated in a level shifter region of the first semiconductor body, the level shifter region located in an edge region surrounding the inner region of the semiconductor body; and a drive circuit integrated in a drive circuit region in the edge region of the first semiconductor body, the drive circuit configured to receive a first input signal from a first input and drive the first transistor device based on the first input signal, the drive circuit region arranged closer to the inner region than the level shifter region.

Abstract: A method of manufacturing a semiconductor device is described. The method includes forming a hard mask over a semiconductor substrate. The hard mask is patterned to generate openings in the hard mask. Deep trenches are formed in the semiconductor substrate by etching through the openings in the hard mask. The openings in the hard mask are widened. A pre-filler side wall layer is formed over the widened openings of the hard mask and the side walls of the deep trenches. The pre-filler side wall layer is recessed down to at least a first depth in the semiconductor substrate. The deep trenches are filled with a filler material. A corresponding semiconductor device is also described.

Abstract: A semiconductor device includes a layer stack with first and second semiconductor layers of complementary doping types are arranged alternatingly between first and second surfaces of the layer stack. A first semiconductor region adjoins the first semiconductor layers and has a first end arranged in a first device region and extends from the first end into a second device region. Second semiconductor regions adjoin at least one of the second semiconductor layers. A third semiconductor region adjoins the first semiconductor layers. The first semiconductor region extends from the first device region into the second device region and is spaced apart from the third semiconductor region. The second semiconductor regions are arranged between, and spaced apart from, the third and first semiconductor regions.

Abstract: A semiconductor device includes a layer stack with first semiconductor layers and second semiconductor layers of opposite doping types arranged alternatingly. A first semiconductor region of a first semiconductor device adjoins the first semiconductor layers, and has a first end arranged in a first region of the first semiconductor device and extends from the first end into a second region of the first semiconductor device. Second semiconductor regions of the first semiconductor device adjoin at least one of the second semiconductor layers. A third semiconductor region of the first semiconductor device adjoins the first semiconductor layers. The first semiconductor region extends from the first region into the second region and is spaced apart from the third semiconductor region. The second semiconductor regions are arranged between, and spaced apart from, the third and first semiconductor regions.

Abstract: An electronic circuit is disclosed. The electronic circuit includes: a first transistor device integrated in an inner region of a first semiconductor body; and a first drive circuit integrated in a first drive circuit region of the semiconductor body. The first drive circuit is configured to be connected to a level shifter and to drive a second transistor device. The first drive circuit region is located in an edge region surrounding the inner region of the semiconductor body.

Abstract: A transistor arrangement and a method are disclosed. The transistor arrangement includes: a plurality of first semiconductor regions of a first doping type and a plurality of second semiconductor regions of a second doping type, the first semiconductor regions and the second semiconductor regions being arranged alternatingly in a vertical direction of a semiconductor body; a source region adjoining the plurality of first semiconductor regions; a drain region adjoining the plurality of second semiconductor regions and arranged spaced apart from the source region in a first lateral direction; and a plurality of gate regions each of which adjoins at least one of the plurality of second semiconductor regions and is arranged between the source region and the drain region. At least one of the first and semiconductor regions, but less than each of the first and second semiconductor regions has a doping dose that varies in the first lateral direction.

Abstract: A method includes: forming first and second trenches in a semiconductor body; forming a first material layer on the semiconductor body in the first and second trenches such that a first residual trench remains in the first trench and a second residual trench remains in the second trench; removing the first material from the second trench; and forming a second material layer on the first material layer in the first residual trench and on the semiconductor body in the second trench. The first material layer includes dopants of a first doping type and the second material layer includes dopants of a second doping type. The method further includes diffusing dopants from the first material layer in the first trench into the semiconductor body to form a first doped region, and from the second material layer in the second trench into the semiconductor body to form a second doped region.

Abstract: A semiconductor device includes a layer stack with a plurality of first semiconductor layers of a first doping type and a plurality of second semiconductor layers of a second doping type complementary to the first doping type. The first and second semiconductor layers are arranged alternatingly between first and second surfaces of the layer stack. A first semiconductor region of a first semiconductor device adjoins the first semiconductor layers. Each of at least one second semiconductor region of the first semiconductor device adjoins at least one of the plurality of second semiconductor layers, and is spaced apart from the first semiconductor region. Each of at least one barrier layer configured to form a diffusion barrier is arranged in parallel to the first surface and to the second surface and adjacent to one of the first semiconductor layers, or adjacent to one of the second semiconductor layers, or both.

Abstract: A semiconductor device includes a layer stack with a plurality of first semiconductor layers of a first doping type and a plurality of second semiconductor layers of a second doping type complementary to the first doping type. A first semiconductor region of a first semiconductor device adjoins the first semiconductor layers. Each second semiconductor region of the first semiconductor device adjoins at least one of the second semiconductor layers, and is spaced apart from the first semiconductor region. A third semiconductor layer adjoins the layer stack and each first semiconductor region and each second semiconductor region. The third semiconductor layer includes a first region arranged between the first semiconductor region and the second semiconductor region in a first direction. A third semiconductor region of the first or the second doping type extends from a first surface of the third semiconductor layer into the first region.

Abstract: A method for forming a battery element includes etching trenches into a substrate and crystal orientation dependent etching of the trenches. Further, the method includes forming solid state battery structures within the trenches.

Abstract: A method includes forming a layer stack with a plurality of first layers of a first doping type and a plurality of second layers of a second doping type complementary to the first doping type on top of a carrier. Forming the layer stack includes forming a plurality of epitaxial layers on the carrier. Forming each of the plurality of epitaxial layers includes depositing a layer of semiconductor material, forming at least two first implantation regions of one of a first type or a second type at different vertical positions of the respective layer of semiconductor material, and forming at least one second implantation region of a type that is complementary to the type of the first implantation regions, the first implantation regions and the second implantation regions being arranged alternatingly.

Abstract: A transistor arrangement and a method are disclosed. The transistor arrangement includes: a plurality of first semiconductor regions of a first doping type and a plurality of second semiconductor regions of a second doping type, the first semiconductor regions and the second semiconductor regions being arranged alternatingly in a vertical direction of a semiconductor body; a source region adjoining the plurality of first semiconductor regions; a drain region adjoining the plurality of second semiconductor regions and arranged spaced apart from the source region in a first lateral direction; and a plurality of gate regions each of which adjoins at least one of the plurality of second semiconductor regions and is arranged between the source region and the drain region. At least one of the first and semiconductor regions, but less than each of the first and second semiconductor regions has a doping dose that varies in the first lateral direction.

Abstract: A circuit has first and second semiconductor switches, each of which has a load path and control terminal connected in series. Each switch includes a first semiconductor device having a load path and a control terminal coupled to the control terminal of its switch, and a second semiconductor device having a load path between first and second load terminals, and a control terminal. Each second semiconductor device has its load path connected in series to the load path of the corresponding first semiconductor device. The semiconductor devices are coupled such that the second semiconductor devices are controlled by a load path voltage of the first semiconductor devices. The switches are integrated in a common semiconductor body. The first switch is implemented in a first area of the semiconductor body, and the second switch is implemented in a second area. In a horizontal plane, the first area surrounds the second area.

Abstract: An electronic circuit includes: a drive circuit having an output coupled to a control node of a first electronic switch; a switch circuit with second electronic switches, load paths of the second electronic switches being connected in series, and the switch circuit being connected between a first load node of the first electronic switch and a reference node; and a level shifter coupled between a first signal input and an input of the drive circuit and including cascaded level shifter cells. Each level shifter cell includes a signal input and output, and first and second supply nodes. Each level shifter cell is associated with a respective second electronic switch. The first supply node of each level shifter cell is coupled to a first load node of the associated second electronic switch, and the second supply node is coupled to a second load node of the associated second electronic switch.

Abstract: An electronic circuit is disclosed. The electronic circuit includes: a first transistor device integrated in an inner region of a first semiconductor body; and a first drive circuit integrated in a first drive circuit region of the semiconductor body. The first drive circuit is configured to be connected to a level shifter and to drive a second transistor device. The first drive circuit region is located in an edge region surrounding the inner region of the semiconductor body.

Abstract: A semiconductor device includes a semiconductor substrate having a first side, and a trench structure having a bottom and a sidewall. The bottom has at least first and second bottom portions laterally adjacent to one another. Each bottom portion has a concave shape with a ridge formed between the first and second bottom portions. An insulating material covers the sidewall and first bottom portion of the trench structure while leaving the second bottom portion uncovered. A mesa region extends to the first side of the substrate and forms the sidewall of the trench structure. The device also includes a first silicide layer on a top region of the mesa region, a second silicide layer on the second bottom portion of the trench structure, a first metal layer on and in contact with the first silicide layer, and a second metal layer on and in contact with the second silicide layer.

Abstract: A semiconductor device includes a transistor in a semiconductor body having a first main surface. The transistor includes: a source contact electrically connected to a source region; a drain contact electrically connected to a drain region; a gate electrode at the channel region, the channel region and a drift zone disposed along a first direction between the source and drain regions, the first direction being parallel to the first main surface, the channel region patterned into a ridge by adjacent gate trenches formed in the first main surface, the adjacent gate trenches spaced apart in a second direction perpendicular to the first direction, a longitudinal axis of the ridge extending in the first direction and a longitudinal axis of the gate trenches extending in the first direction; and at least one of the source and drain contacts being adjacent to a second main surface opposite the first main surface.

Abstract: A method includes: forming first and second trenches in a semiconductor body; forming a first material layer on the semiconductor body in the first and second trenches such that a first residual trench remains in the first trench and a second residual trench remains in the second trench; removing the first material from the second trench; and forming a second material layer on the first material layer in the first residual trench and on the semiconductor body in the second trench. The first material layer includes dopants of a first doping type and the second material layer includes dopants of a second doping type. The method further includes diffusing dopants from the first material layer in the first trench into the semiconductor body to form a first doped region, and from the second material layer in the second trench into the semiconductor body to form a second doped region.

Abstract: A transistor arrangement includes: a layer stack with first and second semiconductor layers of complementary first and second doping types; a first source region of a first transistor device adjoining the first semiconductor layers; a first drain region of the first transistor device adjoining the second semiconductor layers and spaced apart from the first source region; gate regions of the first transistor device, each gate region adjoining at least one second semiconductor layer, being arranged between the first source region and the first drain region, and being spaced apart from the first source region and the first drain region; a third semiconductor layer adjoining the layer stack and each of the first source region, first drain region, and each gate region; and active regions of a second transistor device integrated in the third semiconductor layer in a second region spaced apart from a first region of the third semiconductor layer.