Abstract: A method of forming an isolation region is provided that in one embodiment substantially reduces divot formation. In one embodiment, the method includes providing a semiconductor substrate, forming a first pad dielectric layer on an upper surface of the semiconductor substrate and forming a trench through the first pad dielectric layer into the semiconductor substrate. In a following process sequence, the first pad dielectric layer is laterally etched to expose an upper surface of the semiconductor substrate that is adjacent the trench, and the trench is filled with a trench dielectric material, wherein the trench dielectric material extends atop the upper surface of the semiconductor substrate adjacent the trench and abuts the pad dielectric layer.

Abstract: A semiconductor body includes a substrate, a buried zone having a first conductivity type that is formed in the substrate, a first zone having the first conductivity type that is above the buried zone, a second zone having a second conductivity type that is different from the first conductivity type and above the first zone, and a third zone having the first conductivity type that is above the second zone. The buried zone includes first and second implantation regions that are formed via first and second implantations that are performed using a mask. The buried zone, the first zone, the second zone and the third zone are parts of a first transistor structure.

Abstract: A MOSFET comprising a substrate of a semiconductor material; source/drain regions, which are arranged at a distance from each other at a surface of the substrate; a gate electrode arranged above an area of the surface of the substrate between the source/drain regions, the gate electrode being electrically insulated from the semiconductor material; at least one recess in the gate electrode, a through-contact arranged in the recess of the gate electrode, the through-contact being electrically insulated from the gate electrode; a terminal contact on the semiconductor material; and a terminal conductor arranged on the side of the gate electrode that faces away from the substrate, wherein the through-contact electrically connects the terminal contact to the terminal conductor.

Abstract: A semiconductor body (1) comprises a connecting lead (21) for contacting a semiconductor area (2). The conductivity S per unit length of the connecting lead (21) changes from a first value SW to a second value S0. The semiconductor area (2) is electrically conductively connected to the connecting lead (21).

Abstract: A high voltage NMOS transistor is disclosed where the p-doped body is isolated against the p-doped substrate by a DN well having a pinch-off region where the depth of the DN-well is at minimum. By the forming space charge region at raising drain potentials a shielding of the drain potential results because the space charge region touches the field oxide between source and drain at the pinch-off region. An operation at the high side at enhanced voltage levels is possible.

Abstract: In a high-voltage NMOS transistor with low threshold voltage, it is proposed to realize the body doping that defines the channel region in the form of a deep p-well, and to arrange an additional shallow p-doping as a channel stopper on the transistor head, wherein this additional shallow p-doping is produced in the semiconductor substrate at the end of the deep p-well that faces away from the channel region, and extends up to a location underneath a field oxide region that encloses the active window. The leakage current of the parasitic transistor at the transistor head is suppressed with the channel stopper.

Abstract: A transistor includes an emitter, a collector, and a base layer having a base contact. The base layer includes an intrinsic region between the emitter and the collector, an extrinsic region between the intrinsic region and the base contact, and a first doping layer that is doped with a trivalent substance, that extends into the extrinsic region, and that is counter-doped with a pentavalent substance in a region adjacent to the emitter.

Abstract: A method for producing a transistor structure with a lightly doped drain (LDD) includes structuring a gate electrode on a gate dielectric. The method also includes etching the semiconductor body or substrate to form sloping sidewails on regions adjacent to the gate electrode, and anisotropically back-etching the spacer layer to form spacers. The gate electrode is used as a mask to implant dopant to form a source region, a drain region, and regions of lower dopant concentration. Implanting dopant is performed at a first angle relative to the upper surface of the semiconductor body or substrate to form the source and drain regions, and at a second angle relative to the upper surface of the semiconductor body or substrate, and through the spacers, to form the regions of lower dopant concentration. The first angle is greater than the second angle.

Abstract: A bipolar transistor formed in a substrate includes a collector, a base layer above the collector, where the base layer includes a base that is monocrystalline, and an emitter layer that is monocrystalline and above the base, where the emitter layer includes silicon or silicon-germanium. An intermediate layer is above the base layer and below the emitter layer. The intermediate layer includes silicon carbide. The intermediate layer is grown epitaxially and is etchable in a dry plasma relative to the emitter layer.

Abstract: A bipolar transistor formed in a substrate includes a collector, a base layer above the collector, where the base layer includes a base that is monocrystalline, and an emitter layer that is monocrystalline and above the base, where the emitter layer includes silicon or silicon-germanium. An intermediate layer is above the base layer and below the emitter layer. The intermediate layer includes silicon carbide. The intermediate layer is grown epitaxially and is etchable in a dry plasma relative to the emitter layer.