A semiconductor device includes first and second second-conductivity-type region groups containing multiple second-conductivity-type regions that are disposed on a first silicon carbide semiconductor layer of a first conductivity type, arrayed in parallel following one direction with a space between each other, and first and second electrodes disposed on the first silicon carbide semiconductor layer and forming a Schottky junction with the first silicon carbide semiconductor layer. The first electrode covers a position where a distance from adjacent first and second second-conductivity-type regions included in a first second-conductivity-type region group, and a distance from a third second-conductivity-type region included in a second second-conductivity-type region group and adjacent to the first and second second-conductivity-type regions, are equal. A Schottky barrier between the first electrode and the first silicon carbide semiconductor layer is larger than a Schottky barrier between the second electrode and the first silicon carbide semiconductor layer.

A plurality of gate trenches is formed into an epitaxial region of a first conductivity type over a semiconductor substrate. One or more contact trenches are formed into the epitaxial region, each between two adjacent gate trenches. One or more source regions of the first conductivity type are formed in a top portion of the epitaxial region between a contact trench and a gate trench. A barrier metal is formed inside each contact trench.

Each gate trench is substantially filled with a conductive material separated from trench walls by a layer of dielectric material to form a gate . A heavily doped well region of a conductivity opposite the first type is provided in the epitaxial region proximate a bottom portion of each of the contact trenches. A horizontal width of a gap between the well region and the gate trench is about 0.05 nm to 0.2 nm.

A method of forming a transistor device includes providing a drift layer having a first conductivity type, forming a first region in the drift layer, the first region having a second conductivity type that is opposite the first conductivity type, forming a body layer on the drift layer including the first region, forming a source layer on the body layer, forming a trench in the source layer and the body layer above the first region and extending into the first region, forming a gate insulator on the inner sidewall of the trench, and forming a gate contact on the gate insulator.

An integrated transistor structure includes an epitaxial layer on a semiconductor substrate, a power transistor formed in a first region of the epitaxial layer and having a drain region, a source region and a body region shorted to the source region, a bipolar transistor formed in a second region of the epitaxial layer spaced apart from the power transistor. A first trench structure formed in the epitaxial layer adjacent at least two opposing lateral sides of the power transistor includes a gate electrode spaced apart from a channel region of the power transistor by an insulating material. A second trench structure formed in the epitaxial layer adjacent at least two opposing lateral sides of the bipolar transistor includes a trench electrode spaced apart from the epitaxial layer by an insulating material. The gate electrode, base and emitter of the bipolar transistor are connected to different contacts isolated from one another.

Methods, systems, and devices are disclosed for implementing high power circuits and semiconductor devices. In one aspect, a method for fabricating a silicon carbide semiconductor device includes forming a thin epitaxial layer of a nitrogen doped SiC material on a SiC epitaxial layer formed on a SiC substrate, and thermally growing an oxide layer to form an insulator material on the nitrogen doped SiC epitaxial layer, in which the thermally grown oxide layer results in at least partially consuming the nitrogen doped SiC epitaxial layer in the oxide layer to produce an interface including nitrogen between the SiC epitaxial layer and the oxide layer.

A semiconductor device includes a gate pad, a first source pad and a second source pad insulated from each other, a drain pad, a main region, and a sense region for detecting a forward current and a reverse current. The main region and the sense region each include a plurality of unit cells which are in parallel connection, the number of unit cells in the sense region being smaller than the number of unit cells in the main region. A source electrode of any unit cell in the main region is connected to the first source pad, and a source electrode of any unit cell in the sense region is connected to the second source pad.

The present disclosure relates to a manufacturing method for a power semiconductor device (1, 40), comprising: forming multiple growth templates on a carrier substrate (2), comprising at least a first plurality of hollow growth templates (18) and a second plurality of hollow growth templates (28); selectively growing a first sequence of differently doped wide bandgap semiconductor materials in each one of the first hollow growth templates (18), thereby forming a corresponding plurality of first semiconductor structures (5) of a first type, in particular n+/p/n/n+ structures; and selectively growing a second sequence of differently doped wide bandgap semiconductor materials in each one of the second hollow growth templates (28), thereby forming a corresponding plurality of second semiconductor structures (6) of a second type, in particular n+/n/p/n+ structures. The disclosure further relates to a power semiconductor device (1, 40) comprising a carrier substrate (2), at least one dielectric layer (4, 27, 31), a plurality of first semiconductor structures (5) of a first type, and a plurality of second semiconductor structures (6) of a second type formed within the at least one dielectric layer (4, 27, 31).

Provided is a semiconductor device including: at least a semiconductor layer having a corundum structure, the semiconductor layer including a first surface having at least a first side and a second side shorter than the first side, the first surface being a c-plane or an m-plane, a direction of the first side being a direction of a c-axis or a direction of an m-axis.

Embodiments of the present disclosure relate to the field of semiconductors, and provide a semiconductor structure and a manufacturing method thereof. The semiconductor structure includes: an active pillar, where the active pillar includes: a channel region, as well as a first doped region and a second doped region located at two sides of the channel region, the channel region, the first doped region, and the second doped region having a same doping type, where a counter-doped region is arranged in the channel region, the counter-doped region is close to the first doped region, and a doping type of the counter-doped region is different from a doping type of the channel region; and a gate, where the gate surrounds a part of the channel region, and in a plane in which an axis of the active pillar is located, projection of the gate partially overlaps with projection of the counter-doped region.

A vertical field effect transistor. The vertical field effect transistor includes: a drift area; a semiconductor fin on or above the drift area; a connection area on or above the semiconductor fin; and a gate electrode, which is formed adjacent to at least one side wall of the semiconductor fin, the semiconductor fin, in a first section, which is situated laterally adjacent to the gate electrode, having a lesser lateral extension than in a second section, which contacts the drift area, and/or than in a third section, which contacts the connection area.