A semiconductor device comprises a substrate, a semiconductor layer formed on the substrate; and a high-voltage termination. The high-voltage termination includes a plurality of floating field rings, a deep trench and a dielectric material is disposed within the deep trench. The plurality of floating field rings are formed in the semiconductor layer and respectively disposed around a region of the semiconductor layer. The deep trench is formed in the semiconductor layer and concentrically disposed around an outermost floating field ring of the plurality of floating field rings. The high-voltage termination may also include a field plate disposed over the floating field rings, the deep trench, or both.

A semiconductor device is formed having a deep trench, a conductive material disposed in the deep trench, and a dielectric disposed within the deep trench and separating the conductive material from surfaces of the deep trench. The conductive material may be carbon, and may be formed by pyrolysis of an organic material such as a photoresist. The deep trench and the conductive material may be parts of a high-voltage termination of an active device of the semiconductor device. The conductive material may be floating or may be connected to an electrode of the active device.

An SiC semiconductor device includes an SiC semiconductor layer including an SiC monocrystal that is constituted of a hexagonal crystal and having a first main surface as a device surface facing a c-plane of the SiC monocrystal and has an off angle inclined with respect to the c-plane, a second main surface at a side opposite to the first main surface, and a side surface facing an a-plane of the SiC monocrystal and has an angle less than the off angle with respect to a normal to the first main surface when the normal is 0°.

A semiconductor device includes a region of semiconductor material of a first conductivity type. A body region of a second conductivity type is in the region of semiconductor material. The body region includes a first segment with a first peak dopant concentration, and a second segment laterally adjacent to the first segment with a second peak dopant concentration. A source region of the first conductivity type is in the first segment but not in at least part of the second segment. An insulated gate electrode adjoins the first segment and is configured to provide a first channel region in the first segment, adjoins the second segment and is configured to provide a second channel region in the second segment, and adjoins the source region. During a linear mode of operation, current flows first in the second segment but not in the first segment to reduce the likelihood of thermal runaway.

A multi-transistor device includes first and second lateral double-diffused metal-oxide-semiconductor field effect (LDMOS) transistors sharing a first p-type reduced surface field (RESURF) layer and a first drain n+ region. In certain embodiments, the first LDMOS transistor includes a first drift region, the second LDMOS transistor includes a second drift region, and the first and second drift regions are at least partially separated by the first p-type RESURF layer in a thickness direction.

A silicon chip package structure, in particular a metal-oxide-semiconductor field-effect transistor (MOSFET) and method of manufacture is provided. The disclosure provides improvements to a Chip Silicon Package (CSP) structure by reducing the active area needed to be sacrificed to create a drain area.

A lateral double-diffused metal-oxide-semiconductor transistor includes a silicon semiconductor structure and a vertical gate. The vertical gate include a (a) gate conductor extending from a first outer surface of the silicon semiconductor structure into the silicon semiconductor structure and (b) a gate dielectric layer including a least three dielectric sections. Each of the at least three dielectric sections separates the gate conductor from the silicon semiconductor structure by a respective separation distance, where each of the respective separation distances is different from each other of the respective separation distances.

A vertical field-effect transistor (VFET) includes: a fin structure on a substrate; a gate structure including a gate dielectric layer on an upper portion of a sidewall of the fin structure, and a conductor layer on a lower portion of the gate dielectric layer; a top source/drain (S/D) region above the fin structure and the gate structure; a bottom S/D region below the fin structure and the gate structure; a top spacer on an upper portion of the gate dielectric layer, and between the top S/D region and a top surface of the conductor layer; and a bottom spacer between the gate structure and the bottom S/D region. A top surface of the gate dielectric layer is positioned at the same or substantially same height as or positioned lower than a top surface of the top spacer, and higher than the top surface of the conductor layer.

A multiple gate dielectrics and dual work-functions field effect transistor (MGO-DWF-FET) is provided on an active region of a semiconductor substrate. The MGO-DWF-FET includes a first functional gate structure including a U-shaped first high-k gate dielectric material layer and a first work-function metal-containing structure, and a laterally adjacent, and contacting, second functional gate structure that includes a U-shaped second high-k gate dielectric material layer and a second work-function metal-containing structure. The first functional gate structure has a gate length that differs from a gate length of the second functional gate structure.

A semiconductor device includes: a semiconductor layer of a first conductivity-type; a well region of a second conductivity-type provided at an upper part of the semiconductor layer; a base region of the second conductivity-type provided at an upper part of the well region; a carrier supply region of the first conductivity-type provided at an upper part of the base region; a drift region of the first conductivity-type provided separately from the base region; a carrier reception region of the first conductivity-type provided at an upper part of the drift region; a gate electrode provided on a top surface of the well region interposed between the base region and the drift region via a gate insulating film; and a punch-through prevention region of the second conductivity-type provided at the upper part of the well region and having an impurity concentration different from the impurity concentration of the base region.