Abstract: An integrated circuit includes a transistor in a semiconductor substrate having a main surface. The transistor includes a source region, a drain region, a channel region, a drift zone, a gate electrode, and a gate dielectric adjacent to the gate electrode. The gate electrode is disposed adjacent to at least two sides of the channel region. The channel region and the drift zone are disposed along a first direction parallel to the main surface between the source region and the drain region. The gate dielectric has a thickness that varies at different positions of the gate electrode.

Abstract: A semiconductor device is manufactured at least partially in a semiconductor substrate. The substrate has first and second opposing main surfaces. The method includes forming a cell field portion and a contact area, the contact area being electrically coupled to the cell field portion, and forming the cell field portion by at least forming a transistor. The method further includes insulating a part of the semiconductor substrate from other substrate portions to form a connection substrate portion, forming an electrode adjacent to the second main surface so as to be in contact with the connection substrate portion, forming an insulating layer over the first main surface, forming a metal layer over the insulating layer, forming a trench in the first main surface, and filling the trench with a conductive material, and electrically coupling the connection substrate portion to the metal layer via the trench.

Abstract: A method of manufacturing a semiconductor device includes providing dielectric stripe structures extending from a first surface into a semiconductor substrate between semiconductor fins. A first mask is provided that covers a first area including first stripe sections of the dielectric stripe structures and first fin sections of the semiconductor fins. The first mask exposes a second area including second stripe and second fin sections. A channel/body zone is formed in the second fin sections by introducing impurities, wherein the first mask is used as an implant mask. Using an etch mask that is based on the first mask, recess grooves are formed at least in the second stripe sections.

Abstract: A semiconductor device includes field electrode structures regularly arranged in lines in a cell area and forming a first portion of a regular pattern. Termination structures are formed in an inner edge area surrounding the cell area, wherein at least portions of the termination structures form a second portion of the regular pattern. Cell mesas separate neighboring ones of the field electrode structures from each other in the cell area and include first portions of a drift zone, wherein a voltage applied to a gate electrode controls a current flow through the cell mesas. At least one doped region forms a homojunction with the drift zone in the inner edge area.

Abstract: Embodiments relate to bootstrap circuits integrated with at least one other device, such as a power transistor or other semiconductor device. In embodiments, the bootstrap circuit can comprise a bootstrap capacitor and a bootstrap diode, or the bootstrap circuit can comprise a bootstrap capacitor and a bootstrap transistor. The bootstrap capacitor comprises a semiconductor-based capacitor, as opposed to an electrolytic, ceramic or other capacitor, in embodiments. The integration of the bootstrap circuit with another circuit or device, such as a power transistor device in one embodiment, is at a silicon-level in embodiments, rather than as a module-like system-in-package of conventional approaches. In other words, the combination of the bootstrap circuit elements and power transistor or other device forms a system-on-silicon, or an integrated circuit, in embodiments, and additionally can be arranged in a single package.

Abstract: A method for forming a semiconductor device. One embodiment provides a semiconductor substrate having a trench with a sidewall isolation. The sidewall isolation is removed in a portion of the trench. A gate dielectric is formed on the laid open sidewall. A gate electrode is formed adjacent to the date dielectric. The upper surface of the gate electrode is located at a depth d1 below the surface of the semiconductor substrate. The gate oxide is removed above the gate electrode. An isolation is formed simultaneously on the gate electrode and the semiconductor substrate such that the absolute value of height difference d2 between the isolation over the gate electrode and the isolation over the semiconductor substrate is smaller than the depth d1.

Abstract: A semiconductor device includes a field electrode structure that includes a field electrode and a field dielectric surrounding the field electrode. The field dielectric includes a first dielectric layer and a second dielectric layer having a smaller band gap and/or a lower conduction band edge than the first dielectric layer. A semiconductor body includes a transistor section that surrounds the field electrode structure and directly adjoins the first dielectric layer. The transistor section includes a source zone, a first drift zone section and a body zone separating the source zone and the first drift zone section. The body zone forms a first pn junction with the source zone and a second pn junction with the first drift zone section.

Abstract: A semiconductor device is at least partially formed in a semiconductor substrate, the substrate including first and second opposing main surfaces. The semiconductor device includes a cell field portion and a contact area, the contact area being electrically coupled to the cell field portion, the cell field portion including at least a transistor. The contact area includes a connection substrate portion insulated from other substrate portions and including a part of the semiconductor substrate, an electrode adjacent to the second main surface and in contact with the connection substrate portion, and a metal layer disposed over the first main surface, the connection substrate portion being electrically coupled to the metal layer to form an ohmic contact between the electrode and metal layer. The connection substrate portion is not electrically coupled to a component of the cell field portion by a conductive material disposed between the first and second main surfaces.

Abstract: A method for manufacturing a semiconductor device comprises includes providing a substrate with a surface, forming an isolating layer on part of the surface, and forming a first semiconductor portion and spaced therefrom a second semiconductor portion on the surface of the substrate. The isolating layer is interposed between a side surface of the first semiconductor portion and a side surface of the second semiconductor portion which face each other. The method further includes forming a first side isolation layer on the side surface of the first semiconductor portion.

Abstract: Embodiments relate to bootstrap circuits integrated with at least one other device, such as a power transistor or other semiconductor device. In embodiments, the bootstrap circuit can comprise a bootstrap capacitor and a bootstrap diode, or the bootstrap circuit can comprise a bootstrap capacitor and a bootstrap transistor. The bootstrap capacitor comprises a semiconductor-based capacitor, as opposed to an electrolytic, ceramic or other capacitor, in embodiments. The integration of the bootstrap circuit with another circuit or device, such as a power transistor device in one embodiment, is at a silicon-level in embodiments, rather than as a module-like system-in-package of conventional approaches. In other words, the combination of the bootstrap circuit elements and power transistor or other device forms a system-on-silicon, or an integrated circuit, in embodiments, and additionally can be arranged in a single package.

Abstract: A method for producing a semiconductor component includes providing a semiconductor body having a first semiconductor material extending to a first surface and at least one trench, the at least one trench extending from the first surface into the semiconductor body, a first insulation layer being arranged in the at least one trench. The method further includes forming a second insulation layer on the first surface having a recess that overlaps in a projection onto the first surface with the at least one trench, forming a mask region in the recess, etching the second insulation layer selectively to the mask region, depositing a third insulation layer over the first surface, and etching the third insulation layer so that a semiconductor mesa of the semiconductor body arranged next to the at least one trench is exposed at the first surface.

Abstract: A semiconductor workpiece includes a semiconductor substrate, at least two chip areas, components of semiconductor devices being formed in the semiconductor substrate in the at least two chip areas, and a separation trench disposed between adjacent chip areas. The separation trench is formed in a first main surface of the semiconductor substrate and extends from the first main surface to a second main surface of the semiconductor substrate. The second main surface is disposed opposite to the first main surface. The separation trench is filled with at least one sacrificial material.

Abstract: In one aspect, a method of forming a trench in a semiconductor material includes forming a first dielectric layer on a semiconductor substrate. The first dielectric layer includes first openings. An epitaxial layer is grown on the semiconductor substrate by an epitaxial lateral overgrowth process. The first openings are filled by the epitaxial layer and the epitaxial layer is grown onto adjacent portions of the first dielectric layer so that part of the first dielectric layer is uncovered by the epitaxial layer and a gap forms between opposing sidewalls of the epitaxial layer over the part of the first dielectric layer that is uncovered by the epitaxial layer. The gap defines a first trench in the epitaxial layer that extends to the first dielectric layer.

Abstract: A semiconductor device includes subsurface structures extending from a main surface into a semiconductor portion, each subsurface structure including a gate electrode dielectrically insulated from the semiconductor portion. The semiconductor device further includes alignment plugs in a vertical projection of the subsurface structures, contact spacers extending along sidewalls of the alignment plugs tilted to the main surface, and contact plugs directly adjoining semiconductor mesas between the subsurface structures. The contact plugs are provided between opposing ones of the contact spacers.

Abstract: A semiconductor body component has a first surface and is comprised of a first semiconductor material extending to the first surface. At least one trench extends from the first surface into the semiconductor body and includes a gate electrode insulated from the semiconductor body and arranged below the first surface. A second insulation layer is formed on the first surface with a recess that overlaps in projection onto the first surface with the conductive region. A mask region is formed in the recess, and the second insulation layer is etched selectively to the mask region and the semiconductor body to expose the semiconductor body at the first surface. A third insulation layer is deposited on the first surface, and the third insulation layer is etched so that a semiconductor mesa of the semiconductor body arranged next to the at least one trench is exposed at the first surface.

Abstract: A semiconductor device is manufactured in a semiconductor substrate comprising a first main surface, the semiconductor substrate including chip areas. The method of manufacturing the semiconductor substrate comprises forming components of the semiconductor device in the first main surface in the chip areas, removing substrate material from a second main surface of the semiconductor substrate, the second main surface being opposite to the first main surface, forming a separation trench into a first main surface of the semiconductor substrate, the separation trench being disposed between adjacent chip areas. The method further comprises forming at least one sacrificial material in the separation trench, and removing the at least one sacrificial material from the trench.

Abstract: Semiconductor oxide pillars are selectively grown on semiconductor mesas between precursor structures that extend from a main surface into a semiconductor substrate. Spaces between the semiconductor oxide pillars are filled with one or more auxiliary materials to form alignment plugs in a vertical projection of the precursor structures. The semiconductor oxide pillars are removed selectively against the alignment plugs. Contact spacers are provided along sidewalls of the alignment plugs. Between opposing ones of the contact spacers contact plugs are provided directly adjoining the semiconductor mesas. The contact plugs are self-aligned to the semiconductor mesas and allow a further reduction of the lateral dimensions of the semiconductor mesas without recessing the semiconductor mesas.

Abstract: A method of manufacturing a semiconductor device includes providing dielectric stripe structures extending from a first surface into a semiconductor substrate between semiconductor fins. A first mask is provided that covers a first area including first stripe sections of the dielectric stripe structures and first fin sections of the semiconductor fins. The first mask exposes a second area including second stripe and second fin sections. A channel/body zone is formed in the second fin sections by introducing impurities, wherein the first mask is used as an implant mask. Using an etch mask that is based on the first mask, recess grooves are formed at least in the second stripe sections.

Abstract: An integrated circuit includes a transistor in a semiconductor substrate having a main surface. The transistor includes a source region, a drain region, a channel region, a drift zone, a gate electrode, and a gate dielectric adjacent to the gate electrode. The gate electrode is disposed adjacent to at least two sides of the channel region. The channel region and the drift zone are disposed along a first direction parallel to the main surface between the source region and the drain region. The gate dielectric has a thickness that varies at different positions of the gate electrode.

Abstract: A semiconductor chip has a semiconductor body with a bottom side and a top side arranged distant from the bottom side in a vertical direction, an active and a non-active transistor region, a drift region formed in the semiconductor body, a contact terminal for externally contacting the semiconductor chip, and a plurality of transistor cells formed in the semiconductor body. Each of the transistor cells has a first electrode. Each of a plurality of connection lines electrically connects another one of the first electrodes to the contact terminal pad at a connecting location of the respective connection line. Each of the connection lines has a resistance section that is formed of at least one of: a locally reduced cross-sectional area of the connection line section; and a locally increased specific resistance. Each of the connecting locations and each of the resistance sections is arranged in the non-active transistor region.