Abstract: A first semiconductor body including type IV semiconductor material is provided. A second semiconductor body including type III-V semiconductor material is provided. A first adhesion layer is formed on the first semiconductor body. A second adhesion layer is formed on the second semiconductor body. The first and the second semiconductor bodies are bonded together by adhering the first and the second adhesion layers to one another.

Abstract: A semiconductor component includes gate structures extending into a silicon carbide body from a first surface. A width of the gate structures along a first horizontal direction parallel to the first surface is less than a vertical extent of the gate structures perpendicular to the first surface. Contact structures extend into the silicon carbide body from the first surface. The gate structures and the contact structures alternate along the first horizontal direction. Shielding regions in the silicon carbide body adjoin a bottom of the contact structures and are spaced apart from the gate structures along the first horizontal direction. Corresponding methods for producing the semiconductor component are also described.

Abstract: A semiconductor component includes a SiC semiconductor body having an active region and an edge termination structure at least partly surrounding the active region. A drift zone of a first conductivity type is formed in the SiC semiconductor body. The edge termination structure includes: a first doped region of a second conductivity type between a first surface of the SiC semiconductor body and the drift zone, the first doped region at least partly surrounding the active region and being spaced apart from the first surface; a plurality of second doped regions of the second conductivity type between the first surface and the first doped region; and third doped regions of the first conductivity type separating adjacent second doped regions of the plurality of second doped regions from one another in a lateral direction.

Abstract: A semiconductor device includes stripe-shaped trench gate structures that extend in a semiconductor body along a first horizontal direction. Transistor mesas between neighboring trench gate structures include body regions and source zones, wherein the body regions form first pn junctions with a drift structure and second pn junctions with the source zones. The source zones directly adjoin two neighboring trench gate structures, respectively. Diode mesas that include at least portions of diode regions form third pn junctions with the drift structure. The diode mesas directly adjoin two neighboring trench gate structures, respectively. The transistor mesas and the diode mesas alternate at least along the first horizontal direction.

Abstract: A semiconductor device includes a semiconductor body and at least one device cell integrated in the semiconductor body. Each device cell includes a drift region, a source region, and a body region arranged between the source region and the drift region. A gate trench extends from a first surface of the semiconductor body, through the source and body regions and into the drift region. A diode region extends under the gate trench. A pn junction is formed between the diode and drift regions below the gate trench. A gate electrode arranged in the gate trench is dielectrically insulated from the source, body, diode and drift regions by a gate dielectric. A contact trench spaced apart from the gate trench extends from the first surface into the source region. A source electrode arranged in the contact trench adjoins the source region at a sidewall of the contact trench.

Abstract: A semiconductor device includes an array of needle-shaped trenches extending into a semiconductor substrate. The semiconductor device further includes a gate trench grid extending into the semiconductor substrate. A gate electrode of a transistor structure is located within the gate trench grid. A gate wiring structure of the transistor structure is connected to the gate electrode of the transistor structure. A field electrode located within at least one needle-shaped trench of the array of needle-shaped trenches is connected to the gate wiring structure of the transistor structure.

Abstract: In an embodiment, a semiconductor device is provided that includes a semiconductor body having a first conductivity type, a first major surface and a second major surface opposite the first major surface, a gate arranged on the first major surface, a body region having a second conductivity type opposite the first conductivity type, the body region extending into the semiconductor body from the first major surface, a source region having the first conductivity type, the source region being arranged in the body region, a buried channel shielding region having the second conductivity type, a contact region having the second conductivity type, and a field plate arranged in a trench extending into the semiconductor body from the first major surface.

Abstract: A semiconductor device comprises a semiconductor substrate structure comprising a cell region and an edge termination region surrounding the cell region. Further it comprises a plurality of needle-shaped cell trenches within the cell region reaching from a surface of the semiconductor substrate structure into the substrate structure and an edge termination trench within the edge termination region surrounding the cell region at the surface of the semiconductor substrate structure.

Abstract: A first semiconductor body including type IV semiconductor material is provided. A second semiconductor body including type III-V semiconductor material is provided. A first adhesion layer is formed on the first semiconductor body. A second adhesion layer is formed on the second semiconductor body. The first and the second semiconductor bodies are bonded together by adhering the first and the second adhesion layers to one another.

Abstract: A semiconductor device includes a semiconductor body formed from a semiconductor material with a band-gap of at least 2.0 eV, the semiconductor body having a diode region and a source region. The semiconductor device further includes a trench gate structure having a first sidewall and a second sidewall opposite the first sidewall, the first sidewall and the second sidewall extending along a common longitudinal direction. A doping concentration of a first doping type is higher in the diode region than in the source region. The trench gate structure projects from a first surface of the semiconductor body into the semiconductor body. A first portion of the second sidewall at the first surface is directly adjoined by the source region. A second portion of the second sidewall is in direct contact with the diode region. Additional semiconductor device embodiments are provided.

Abstract: Disclosed is a transistor device. The transistor device includes: in a semiconductor body, a drift region, a body region adjoining the drift region, and a source region separated from the drift region by the body region; a gate electrode dielectrically insulated from the body region by a gate dielectric; a source electrode electrically connected to the source region; at least one field electrode dielectrically insulated from the drift region by a field electrode dielectric; and a rectifier element coupled between the source electrode and the field electrode. The field electrode and the field electrode dielectric are arranged in a first trench that extends from a first surface of the semiconductor body into the semiconductor body. The rectifier element is integrated in the first trench in a rectifier region that is adjacent at least one of the source region and the body region.

Abstract: A method of manufacturing a semiconductor device includes: forming a trench extending into a semiconductor substrate and a polysilicon gate electrode in the trench; forming a body region of a first conductivity type in the substrate adjacent the trench and a source region of a second conductivity type adjacent the body region and the trench; forming a dielectric layer on the substrate; forming a gate metallization on the dielectric layer which covers part of the substrate and a source metallization on the dielectric layer which is electrically connected to the source region, spaced apart from the gate metallization and covering a different part of the substrate than the gate metallization; and forming a metal-filled groove in the polysilicon gate electrode which is electrically connected to the gate metallization. The metal-filled groove extends along a length of the trench underneath at least part of the source metallization.

Abstract: A semiconductor device includes a semiconductor substrate having drift and body regions. The drift region includes upper and lower drift regions. An active area includes a plurality of spicular trenches extending through the body region and into the drift region. Each spicular trench in the active area has a lower end which together define a lower end of the upper drift region extending towards a first side and a lower drift region extending from the lower end of the upper drift region towards a second side. The edge termination area includes spicular termination trenches extending at least into the upper drift region. A surface doping region arranged in the upper drift region in the edge termination area extends to the first side, is spaced apart from the lower end of the upper drift region, and has a net doping concentration lower than that of the upper drift region.

Abstract: A semiconductor device comprises a semiconductor substrate structure comprising a cell region and an edge termination region surrounding the cell region. Further it comprises a plurality of needle-shaped cell trenches within the cell region reaching from a surface of the semiconductor substrate structure into the substrate structure and an edge termination trench within the edge termination region surrounding the cell region at the surface of the semiconductor substrate structure.

Abstract: A semiconductor device includes trench structures that extend from a first surface into a semiconductor body. The trench structures include a gate structure and a contact structure that extends through the gate structure, respectively. Transistor mesas are between the trench structures. Each transistor mesa includes a body zone forming a first pn junction with a drift structure and a second pn junction with a source zone. Diode regions directly adjoin one of the contact structures form a third pn junction with the drift structure, respectively.

Abstract: By using at least one of a processor device and model transistor cells, a set of design parameters for at least one of a transistor cell and a drift structure of a wide band-gap semiconductor device is determined, wherein an on state failure-in-time rate and an off state failure-in-time rate of a gate dielectric of the transistor cell are within a same order of magnitude for a predefined on-state gate-to-source voltage, a predefined off-state gate-to-source voltage, and a predefined off-state drain-to-source voltage.

Abstract: A semiconductor device includes a gate trench formed in a semiconductor body and having a first sidewall, a second sidewall opposite the first sidewall, and a bottom, a source region and a drift region of a first conductivity type formed in the semiconductor body, a body region of a second conductivity type arranged between the source region and the drift region and adjoining the first sidewall of the gate trench, and a diode region of the second conductivity type adjoining the second sidewall of the gate trench. A pn junction is formed between the diode region and the drift region and adjoins the bottom of the gate trench. The drift region has a locally increased doping concentration in a region between a pn junction at the border between the body region and the drift region and a lower end of the diode region.

Abstract: A semiconductor device includes a trench extending from a first surface into a SiC semiconductor body. The trench has a first sidewall, a second sidewall opposite to the first sidewall, and a trench bottom. A gate electrode is arranged in the trench and is electrically insulated from the SiC semiconductor body by a trench dielectric. A body region of a first conductivity type adjoins the first sidewall. A shielding structure of the first conductivity type adjoins at least a portion of the second sidewall and the trench bottom. A first section of the trench bottom and a second section of the trench bottom are offset to one another by a vertical offset along a vertical direction extending from the first surface to a second surface of the SiC semiconductor body opposite to the first surface.

Abstract: A semiconductor device includes trench structures that extend from a first surface into a semiconductor body. The trench structures include a gate structure and a contact structure that extends through the gate structure, respectively. Transistor mesas are between the trench structures. Each transistor mesa includes a body zone forming a first pn junction with a drift structure and a second pn junction with a source zone. Diode regions directly adjoin one of the contact structures form a third pn junction with the drift structure, respectively.

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 includes a resistance section formed of a locally increased specific resistance relative to a specific resistance of adjacent semiconductor material or metal of the respective connection line. Each of the connecting locations and each of the resistance sections is arranged in the non-active transistor region.