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: 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 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 vertical transistor device includes a silicon-carbide substrate, a gate trench formed in the silicon-carbide substrate, a body region adjacent the gate trench, a source region adjacent the gate trench and above the body region, and a dielectric material covering a bottom and a sidewall of the gate trench. A thickness of the dielectric material is greater at the bottom of the gate trench than along the sidewall of the gate trench. Further vertical transistor device embodiments and corresponding methods of manufacture are also described.

Abstract: A trench is formed that extends from a main surface into a crystalline silicon carbide semiconductor layer. A mask is formed that includes a mask opening exposing the trench and a rim section of the main surface around the trench. By irradiation with a particle beam a first portion of the semiconductor layer exposed by the mask opening and a second portion outside of the vertical projection of the mask opening and directly adjoining to the first portion are amorphized. A vertical extension of the amorphized second portion gradually decreases with increasing distance to the first portion. The amorphized first and second portions are removed.

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: A SIC transistor device includes a silicon-carbide semiconductor substrate having a plurality of first doped regions laterally spaced apart from one another and beneath a main surface of the substrate, a second doped region extending from the main surface to a third doped region that is above the first doped regions, and a plurality of fourth doped regions in the substrate extending from the main surface to the first doped regions. The second doped region has a first conductivity type. The first, third and fourth doped regions have a second conductivity type opposite the first conductivity type. A gate trench extends through the second and third doped regions. The gate trench has sidewalls, a bottom and rounded corners between the bottom and the sidewalls.

Abstract: A semiconductor device includes a transistor cell with a stripe-shaped trench gate structure that extends from a first surface into a semiconductor body. A gate connector structure at a distance to the first surface is electrically connected to a gate electrode in the trench gate structure. A gate dielectric separates the gate electrode from the semiconductor body. First sections of the gate dielectric outside a vertical projection of the gate connector structure are thinner than second sections within the vertical projection of the gate connector structure.

Abstract: A trench is formed that extends from a main surface into a crystalline silicon carbide semiconductor layer. A mask is formed that includes a mask opening exposing the trench and a rim section of the main surface around the trench. By irradiation with a particle beam a first portion of the semiconductor layer exposed by the mask opening and a second portion outside of the vertical projection of the mask opening and directly adjoining to the first portion are amorphized. A vertical extension of the amorphized second portion gradually decreases with increasing distance to the first portion. The amorphized first and second portions are removed.

Abstract: A semiconductor device includes a source zone electrically connected to a first load terminal, a contiguous zone isolating the source zone from a drift zone, and a trench extending into a semiconductor body along a vertical direction and including a first electrode electrically connected to a control terminal and an insulator in contact with the contiguous zone and which isolates the first electrode from the semiconductor body. The insulator has, at a trench bottom region, a first thickness along the vertical direction, and, at a trench top region, a second thickness along a lateral direction, the first thickness being greater than the second thickness by a factor of at least 1.5. The contiguous zone is arranged in contact with the insulator and extends further along the vertical direction than the trench, and the trench bottom region and the contiguous zone overlap along the lateral direction.

Abstract: A SIC transistor device includes a silicon-carbide semiconductor substrate having a plurality of first doped regions laterally spaced apart from one another and beneath a main surface of the substrate, a second doped region extending from the main surface to a third doped region that is above the first doped regions, and a plurality of fourth doped regions in the substrate extending from the main surface to the first doped regions. The second doped region has a first conductivity type. The first, third and fourth doped regions have a second conductivity type opposite the first conductivity type. A gate trench extends through the second and third doped regions. The gate trench has sidewalls, a bottom and rounded corners between the bottom and the sidewalls.

Abstract: A semiconductor device includes trench gate structures extending from a first surface into a semiconductor body from a wide-bandgap semiconductor material. The trench gate structures separate mesa portions of the semiconductor body from each other. In the mesa portions, body regions form first pn junctions with a drain structure and directly adjoin first mesa sidewalls. Source regions in the mesa portions form second pn junctions with the body regions, wherein the body regions separate the source regions from the drain structure. The source regions directly adjoin the first mesa sidewalls and second mesa sidewalls opposite to the first mesa sidewalls.

Abstract: A SIC transistor device includes a silicon-carbide semiconductor substrate having a plurality of first doped regions laterally spaced apart from one another and beneath a main surface of the substrate, a second doped region extending from the main surface to a third doped region that is above the first doped regions, and a plurality of fourth doped regions in the substrate extending from the main surface to the first doped regions. The second doped region has a first conductivity type. The first, third and fourth doped regions have a second conductivity type opposite the first conductivity type. A gate trench extends through the second and third doped regions. The gate trench has sidewalls, a bottom and rounded corners between the bottom and the sidewalls.

Abstract: A trench is formed that extends from a main surface into a crystalline silicon carbide semiconductor layer. A mask is formed that includes a mask opening exposing the trench and a rim section of the main surface around the trench. By irradiation with a particle beam a first portion of the semiconductor layer exposed by the mask opening and a second portion outside of the vertical projection of the mask opening and directly adjoining to the first portion are amorphized. A vertical extension of the amorphized second portion gradually decreases with increasing distance to the first portion. The amorphized first and second portions are removed.

Abstract: A semiconductor device includes a transistor cell with a stripe-shaped trench gate structure that extends from a first surface into a semiconductor body. A gate connector structure at a distance to the first surface is electrically connected to a gate electrode in the trench gate structure. A gate dielectric separates the gate electrode from the semiconductor body. First sections of the gate dielectric outside a vertical projection of the gate connector structure are thinner than second sections within the vertical projection of the gate connector structure.

Abstract: A silicon-carbide semiconductor substrate having a plurality of first doped regions being laterally spaced apart from one another and beneath a main surface, and a second doped region extending from the main surface to a third doped region that is above the first doped regions is formed. Fourth doped regions extending from the main surface to the first doped regions are formed. A gate trench having a bottom that is arranged over a portion of one of the first doped regions is formed. A high-temperature step is applied to the substrate so as to realign silicon-carbide atoms along sidewalls of the trench and form rounded corners in the gate trench. A surface layer that forms along the sidewalls of the gate trench during the high-temperature step from the substrate is removed.

Abstract: A semiconductor device includes a source zone electrically connected to a first load terminal, a contiguous zone isolating the source zone from a drift zone, and a trench extending into a semiconductor body along a vertical direction and including a first electrode electrically connected to a control terminal and an insulator in contact with the contiguous zone and which isolates the first electrode from the semiconductor body. The insulator has, at a trench bottom region, a first thickness along the vertical direction, and, at a trench top region, a second thickness along a lateral direction, the first thickness being greater than the second thickness by a factor of at least 1.5. The contiguous zone is arranged in contact with the insulator and extends further along the vertical direction than the trench, and the trench bottom region and the contiguous zone overlap along the lateral direction.

Abstract: A silicon-carbide semiconductor substrate having a plurality of first doped regions being laterally spaced apart from one another and beneath a main surface, and a second doped region extending from the main surface to a third doped region that is above the first doped regions is formed. Fourth doped regions extending from the main surface to the first doped regions are formed. A gate trench having a bottom that is arranged over a portion of one of the first doped regions is formed. A high-temperature step is applied to the substrate so as to realign silicon-carbide atoms along sidewalls of the trench and form rounded corners in the gate trench. A surface layer that forms along the sidewalls of the gate trench during the high-temperature step from the substrate is removed.