A transistor device and a method for manufacturing a transistor device are disclosed. The transistor device includes a semiconductor body and a plurality of transistor cells. Each transistor cell includes: a drift region, a body region, and a source region; a gate electrode connected to a gate node; and a field electrode connected to a source node. The gate electrode is dielectrically insulated from the body region by a gate dielectric, and is arranged in a first trench extending from a first surface into the semiconductor body. The field electrode is dielectrically insulated from the drift region by a high-k dielectric, and is arranged in a second trench. The second trench extends from the first surface into the semiconductor body and is spaced apart from the first trench, and the field electrode extends at least as deep as the first trench into the semiconductor body.

A power semiconductor device comprises a semiconductor body, a gate electrode, and an extraction electrode, wherein the semiconductor body comprises a source region of a first conductivity type, well region of a second conductivity type different from the first conductivity type at the gate electrode, a drift region which is of the first conductivity type, and a barrier region which is of the first conductivity type, the barrier region is located between the drift region and the extraction electrode.

A semiconductor device includes: a transistor provided in a first region of a semiconductor layer in a plan view; a transistor provided in a second region adjacent to the first region of the semiconductor layer in the plan view; and a drain pad provided in a third region not overlapping the first region and the second region in the plan view. In the plan view, the first region and the second region are one region and an other region that divide an area of the semiconductor layer excluding the third region in half. In the plan view, the transistors are arranged in a first direction. The center of the third region is located on a straight center line that divides the semiconductor layer in half in the first direction and is orthogonal to the first direction. In the plan view, the drain pad is contained in the third region.

A power semiconductor device having a barrier region is provided. A power unit cell of the power semiconductor device has at least two trenches that may both extend into the barrier region. The at least two trenches may both have a respective trench electrode coupled to a control terminal of the power semiconductor device. For example, the trench electrodes are structured to reduce the total gate charge of the power semiconductor device. The barrier region may be p-doped and vertically confined, i.e., in and against the extension direction, by the drift region. The barrier region can be electrically floating.

A semiconductor device includes: a semiconductor substrate; an epitaxial layer or layer stack on the semiconductor substrate; a plurality of transistor cells of a first type formed in a first region of the epitaxial layer or layer stack and electrically coupled in parallel to form a vertical power transistor; a plurality of transistor cells of a second type different than the first type and formed in a second region of the epitaxial layer or layer stack; and an isolation structure that laterally and vertically delimits the second region of the epitaxial layer or layer stack. Sidewalls and a bottom of the isolation structure include a dielectric material that electrically isolates the plurality of transistor cells of the second type from the plurality of transistor cells of the first type in the epitaxial layer or layer stack. Methods of producing the semiconductor device are also described.

A semiconductor device includes a semiconductor layer made of SiC. A transistor element having an impurity region is formed in a front surface portion of the semiconductor layer. A first contact wiring is formed on a back surface portion of the semiconductor layer, and defines one electrode electrically connected to the transistor element. The first contact wiring has a first wiring layer forming an ohmic contact with the semiconductor layer without a silicide contact and a second wiring layer formed on the first wiring layer and having a resistivity lower than that of the first wiring layer.

Neighboring gate-all-around integrated circuit structures having a conductive contact stressor between epitaxial source or drain regions are described. In an example, a first vertical arrangement of nanowires and a second vertical arrangement of nanowires above a substrate. A first gate stack is over the first vertical arrangement of nanowires. A second gate stack is over the second vertical arrangement of nanowires. First epitaxial source or drain structures are at ends of the first vertical arrangement of nanowires. Second epitaxial source or drain structures are at ends of the second vertical arrangement of nanowires. An intervening conductive contact structure is between neighboring ones of the first epitaxial source or drain structures and of the second epitaxial source or drain structures. The intervening conductive contact structure imparts a stress to the neighboring ones of the first epitaxial source or drain structures and of the second epitaxial source or drain structures.

This disclosure provides a semiconductor structure and a method of forming buried field plate structures. The semiconductor structure includes a substrate, buried field plate structures, and a gate. The substrate incudes a first surface and a second surface opposite the first surface. Each of the buried field plate structures include a conductive structure and an insulation structure surrounding the conductive structure. The gate is embedded in the substrate and extend into the substrate from the first surface of the substrate, wherein the gate is configured between the two neighboring buried field plate structures. The conductive structure includes portions arranging along a direction perpendicular to the first surface of the substrate and having different widths in a direction parallel to the first surface of the substrate.

An embodiment relates to a n-type planar gate DMOSFET comprising a Silicon Carbide (SiC) substrate. The SiC substrate includes a N+ substrate, a N drift layer, a P-well region and a first N+ source region within each P-well region. A second N+ source region is formed between the P-well region and a source metal via a silicide layer. During third quadrant operation of the DMOSFET, the second N+ source region starts depleting when a source terminal is positively biased with respect to a drain terminal. The second N+ source region impacts turn-on voltage of body diode regions of the DMOSFET by establishing short-circuitry between the P-well region and the source metal when the second N+ source region is completely depleted.

An embodiment semiconductor device includes a conductive region extending in a first direction and a second direction intersecting the first direction and stacked in a third direction intersecting the first direction and the second direction and a termination region at an end of the conductive region in the first direction, wherein the termination region includes an n+ type substrate, an n type layer disposed on an upper surface of the n+ type substrate and having a plurality of first trenches opening upward in the third direction, and a lower gate runner covering the plurality of first trenches and disposed on an upper surface of the n type layer.