Abstract: The invention relates to a vertical field-effect transistor in source-down structure, in which the active zones (10, 7, 11) are introduced from trenches (5, 8, 9) into a semiconductor body (1), a source electrode (18) being connected via the filling (6) of a body trench (5) to a highly doped substrate (2) via a conductive connection (15).

Abstract: The invention relates to a field effect controllable semiconductor component, comprising a semiconductor body with a first terminal zone and a second terminal zone, a channel zone formed between the two terminal zones, a control electrode, and also a plurality of compensation zones. The semiconductor component furthermore has additional doping zones which are arranged in spatial proximity to the compensation zones or in a manner merged therewith. The additional doping zones are connected to the first terminal zone, if appropriate via a series diode.

Abstract: A field effect semiconductor component has a bipolar transistor structure in a semiconductor body consisting of a lightly doped upper area of a first conductivity type as base region and of a lower heavily doped area as emitter region with a complementary conductivity type. Between the base region and the emitter region, a horizontal pn junction forms. The emitter region is in resistive contact with a large-area emitter electrode on the rear of the semiconductor component. On the top of the semiconductor component, a first insulated gate electrode and a second insulated gate electrode are arranged adjacently in the area close to the surface. A vertical pn junction region insulated from the upper area is arranged in such a manner that a collector region and the base region of the bipolar transistor structure can be controlled via the insulated gate electrodes (G1 and G2) arranged electrically separately.

Abstract: The invention relates to a semiconductor arrangement having a MOSFET structure and an active zener function. A n+-doped zone and a p+-doped zone are provided at the bottom of a trench for the purpose of forming zener diodes, the n+-doped zone being directly connected to the gate electrode.

Abstract: The invention relates to a semiconductor component, in which regions of the conduction type opposite to the conduction type of the drift zone are incorporated in the drift zone and also in the region of the active zones.

Abstract: The invention relates to a field effect controllable semiconductor component, comprising a semiconductor body with a first terminal zone and a second terminal zone, a channel zone formed between the two terminal zones, a control electrode, and also a plurality of compensation zones. The semiconductor component furthermore has additional doping zones which are arranged in spatial proximity to the compensation zones or in a manner merged therewith. The additional doping zones are connected to the first terminal zone, if appropriate via a series diode.

Abstract: In a method for forming a channel zone in field-effect transistors, a polysilicon layer is patterned above the channel zone to be formed. The polysilicon layer serves as a mask substrate for the subsequent doping of the channel zone. The expedient patterning of the polysilicon layer with holes in a gate region and pillars in a source region enables the channel zone to be doped more lightly. In another embodiment, the novel method is used for a channel width shading of a PMOS transistor cell.

Abstract: The invention relates to a vertical field-effect transistor in source-down structure, in which the active zones (10, 7, 11) are introduced from trenches (5, 8, 9) into a semiconductor body (1), a source electrode (18) being connected via the filling (6) of a body trench (5) to a highly doped substrate (2) via a conductive connection (15).

Abstract: A memory cell stores data permanently in a memory material that can assume a first, high-resistance state and a second, low-resistance state, that is in a phase-changeable or ovonic material. A heating device is disposed to heat the memory material at different rates to a programming temperature. The memory material either has a high resistance or a low resistance after cooling, depending on the heating rate. The heating device has a switching device and a heating element in immediate vicinity to the memory material. The switching device has a field-effect transistor and a drain region of the field-effect transistor forms the heating element. Alternatively, the heating element includes a diode or a diode chain.

Abstract: The invention relates to a semiconductor arrangement having a MOSFET structure and an active zener function. A n+-doped zone and a p+-doped zone are provided at the bottom of a trench for the purpose of forming zener diodes, the n+-doped zone being directly connected to the gate electrode.

Abstract: A vertical semiconductor component having a semiconductor body of a first conductivity type is described. In a surface region of the semiconductor body, at least one zone of a second conductivity type, opposite to the first conductivity type, is embedded. Regions of the second conductivity type are provided in the semiconductor body in a plane running substantially parallel to the surface of the surface region. The regions are in this case sufficiently highly doped that they cannot be depleted of charge carriers when a voltage is applied.

Abstract: The invention relates to a semiconductor component, in which regions of the conduction type opposite to the conduction type of the drift zone are incorporated in the drift zone and also in the region of the active zones.

Abstract: A memory cell stores data permanently in a memory material that can assume a first, high-resistance state and a second, low-resistance state, that is in a phase-changeable or ovonic material. A heating device is disposed to heat the memory material at different rates to a programming temperature. The memory material either has a high resistance or a low resistance after cooling, depending on the heating rate. The heating device has a switching device and a heating element in immediate vicinity to the memory material. The switching device has a field-effect transistor and a drain region of the field-effect transistor forms the heating element. Alternatively, the heating element includes a diode or a diode chain.

Abstract: A semiconductor component includes a semiconductor body of a first conductivity type which accommodates a space charge region. Semiconductor regions of a second conductivity type are disposed in at least one plane extending essentially perpendicularly to a connecting line extending between two electrodes. A cell array is disposed under one of the electrodes in the semiconductor body. At least some of the semiconductor regions of the second conductivity type are connected to the cell array via filiform semiconductor zones of the second conductivity type in order to expedite switching processes. A method for fabricating such a semiconductor component is also provided.

Abstract: In a method for forming a channel zone in field-effect transistors, a polysilicon layer is patterned above the channel zone to be formed. The polysilicon layer serves as a mask substrate for the subsequent doping of the channel zone. The expedient patterning of the polysilicon layer with holes in a gate region and pillars in a source region enables the channel zone to be doped more lightly. In another embodiment, the novel method is used for a channel width shading of a PMOS transistor cell.

Abstract: A universal semiconductor wafer for high-voltage semiconductor components includes at least one layer of a first conductivity type which is provided on a semiconductor substrate of the first conductivity type. A plurality of floating semiconductor zones of a second, opposite conductivity type are embedded in the interface region between the semiconductor substrate and the at least one layer. The floating semiconductor zones are dimensioned such that the dimension of a semiconductor zone is do small compared to the layer thickness of the at least one semiconductor layer and is essentially equal to or less than a distance between the floating semiconductor zones in the interface region.

Abstract: A lateral high-voltage sidewall transistor configuration includes a low-doped semiconductor substrate of a first conductivity type and a low-doped epitaxial layer of a second conductivity type disposed on the semiconductor substrate. First semiconductor layers of the first conductivity type and second semiconductor layers of the second conductivity type are disposed in an alternating configuration in the epitaxial layer. A source region and a drain region of the second conductivity type extend through the first and second semiconductor layers as far as the semiconductor substrate. A gate electrode includes a gate insulating layer lining a gate trench and includes a conductive material which fills the gate trench. The gate electrode extends through the first and second semiconductor layers as far as the semiconductor substrate and is disposed adjacent to the source region toward the drain region.

Abstract: A semiconductor component includes a semiconductor body of a first conductivity type which accommodates a space charge region. Semiconductor regions of a second conductivity type are disposed in at least one plane extending essentially perpendicularly to a connecting line extending between two electrodes. A cell array is disposed under one of the electrodes in the semiconductor body. At least some of the semiconductor regions of the second conductivity type are connected to the cell array via filiform semiconductor zones of the second conductivity type in order to expedite switching processes. A method for fabricating such a semiconductor component is also provided.

Abstract: A vertical semiconductor component having a semiconductor body of a first conductivity type is described. In a surface region of the semiconductor body, at least one zone of a second conductivity type, opposite to the first conductivity type, is embedded. Regions of the second conductivity type are provided in the semiconductor body in a plane running substantially parallel to the surface of the surface region. The regions are in this case sufficiently highly doped that they cannot be depleted of charge carriers when a voltage is applied.

Abstract: The invention relates to a field effect-controllable semiconductor component of vertical or lateral design i.e. MOSFETs and IGBTs. In this case, depletion zones and complementary depletion zones of opposite conduction types are introduced in the source-drain load path, in the semiconductor body, i.e. in the inner zone in the case of vertical components and in the drift zone in the case of lateral components, the concentration of the regions doped by the first conduction type corresponding approximately to the concentration of the regions doped by the second conduction type.