A semiconductor device includes a substrate, a first unit FET including first source, first drain, and first gate electrodes, a second unit FET including second source, second drain, and second gate electrodes, a first source wiring electrically contacting the first source electrode, a gate bus bar electrically connected to the first gate electrode, and interposing the first gate electrode between the gate bus bar and the second gate electrode, and a gate wiring provided above the first source electrode in non-contact with the first source electrode, and electrically connecting the gate bus bar and the second gate electrode, wherein a maximum width in a first direction of a region where the first source wiring contacts the first source electrode is times or more a maximum width in the first direction of a region where the first source wiring overlaps the first source electrode.

A semiconductor device includes a substrate, a first transistor unit having a first drain electrode, a first gate electrode, and a first source electrode, a second transistor unit having a second source electrode, a second gate electrode electrically, and a second drain electrode, a gate wiring provided on the substrate between the first source electrode and the second source electrode and electrically connected to the first gate electrode and the second gate electrode, a first cover metal layer provided above the substrate between the first source electrode and the gate wiring and adjacent to the first source electrode and the gate wiring, and electrically connected to the first source electrode, and a second cover metal layer provided above the substrate between the second source electrode and the gate wiring and adjacent to the second source electrode and the gate wiring, and electrically connected to the second source electrode.

A semiconductor device including a substrate; a first active region disposed in the substrate, the first active region having one or more first type channels and a first plurality of doped regions; a second active region disposed in the substrate, the second active region having one or more second type channels and a second plurality of doped regions, the second active region being physically separated from the first active region by a STI region; an intermediate wiring layer disposed above the substrate, the intermediate wiring layer having a plurality of fingers connected to the first plurality of doped regions and the second plurality of doped regions, respectively; and a metal wiring layer having a source finger and a drain finger, wherein the source finger is connected to a first group of the plurality of fingers, and the drain finger is connected to a second group of the plurality of fingers.

A multi-finger transistor structure is provided in the present invention, including multiple active areas, a gate structure consisting of multiple gate parts and connecting parts, wherein each gate part crosses over one of the active areas and each connecting part alternatively connects one end and the other end of the gate parts so as to form a meander gate structure, and multiple sources and drains, wherein one source and one drain are set between two adjacent gate parts, and each gate parts is accompanied by one source and one drain at two sides respectively, and the distance between the drain and the gate part is larger than the distance between the source and the gate part, so that the source and the drain are asymmetric with respect to the corresponding gate part, and air gaps are formed in the dielectric layer between each drain and the corresponding gate part.

A semiconductor device 1 has an electrode structure that includes source electrodes 3, a gate electrode 4, and drain electrodes 5 disposed on a semiconductor laminated structure 2 and extending in parallel to each other and in a predetermined first direction and a wiring structure that includes source wirings 9, drain wirings 10, and gate wirings 11 disposed on the electrode structure and extending in parallel to each other and in a second direction orthogonal to the first direction. The source wirings 9, the drain wirings 10, and the gate wirings 11 are electrically connected to the source electrodes 3, the drain electrodes 5, and the gate electrode 4, respectively. The semiconductor device 1 includes a conductive film 8 disposed between the gate electrode 4 and the drain wirings 10 and being electrically connected to the source electrodes 3.

A technique for making contact to the cap layers in multifinger III-Nitride transistors with cap layers is described. A contact structure is disposed at an end of the transistor device and connects to the cap layer of individual fingers of the transistor device using a cap contact bus. A transistor is also described that includes a contact structure that is used to move the cap layer contact away from the individual fingers. Transistors may be created using unit cells, wherein each unit cell includes a contact structure and cap contact bus.

A semiconductor device (1A) includes a chip (2) that includes an SiC monocrystal and has a main surface (3), a trench structure (20) that has a first side wall (22A) extending in an a-axis direction of the SiC monocrystal and a second side wall (22B) extending in an m-axis direction of the SiC monocrystal and is formed in the main surface, and a contact region (50) of a first conductivity type that is formed in a region inside the chip along the trench structure at an interval in the a-axis direction from the second side wall.

The present disclosure provides a semiconductor device and a fabrication method thereof. The semiconductor device includes a III-nitride layer, a gate, a connection structure, and a gate bus. The gate is disposed over the III-nitride layer. The connection structure is disposed over the gate. The gate bus extends substantially in parallel to the gate and disposed over the connection structure from a top view perspective. The gate bus is electrically connected to the gate through the connection structure.

Example embodiments relate to a field-effect transistors having improved layouts. One example field-effect transistor includes a semiconductor substrate on which at least one transistor cell array is arranged. Each transistor cell includes a first transistor cell unit. Each first transistor cell unit includes a plurality of gate fingers, a main gate finger segment, a plurality of drain fingers, and a main drain finger segment. Each first transistor cell unit also includes a main gate finger base connected to the main gate finger segment of the first transistor cell unit and extending from that main gate finger segment towards the main drain finger segment of that first transistor cell unit. Further, each first transistor cell unit includes a main drain finger base connected to the main drain finger segment of that first transistor cell and extending from that main drain finger segment towards that main gate finger segment.

Electronic device, comprising: a semiconductor body having a surface, an electrical conductivity P and a first doping value; at least one gate region on the surface; one or more source regions, having a second electrical conductivity N, extending in the semiconductor body at the surface and at a first side of the gate region; and at least one body contact region, of P+ type, extending in the semiconductor body at the surface and at the first side of the gate region 22. The first gate region has the shape of a stripe with main extension along a first direction. The first body contact region has a tapered shape along said first direction. The one or more source regions are adjacent to, and at least partially surround, the first body contact region.