The present disclosure relates to an integrated chip. The integrated chip includes a substrate having a first semiconductor material. A second semiconductor material fills an indentation formed by interior sidewalls and a recessed surface of the substrate. The second semiconductor material is a group IV semiconductor or a group III-V compound semiconductor. A third semiconductor material is disposed on an upper surface of the second semiconductor material. A first doped region and a second doped region respectively have a first part within the third semiconductor material and a second part within the second semiconductor material.

An apparatus includes a first drain/source region and a second drain/source region surrounded by an isolation ring formed over a substrate, the isolation ring formed being configured to be floating, and a first diode connected between the substrate and the isolation ring, wherein the first diode is a Schottky diode.

A semiconductor structure is provided. The semiconductor structure includes a substrate, a deep trench isolation (DTI), an interconnect structure, and a conductive pillar. The DTI is disposed in the substrate and the interconnect structure is disposed over the substrate. The conductive pillar extends from the interconnect structure toward the substrate and penetrates the DTI. A method of manufacturing the semiconductor structure is also provided.

According to the embodiment of the present invention, a semiconductor device includes a first source/drain and a second source/drain. A first source/drain contact includes a first portion and a second portion. The first portion of the first source/drain contact is located directly atop the first source/drain. The second portion of the first source/drain contact extends vertically past the first source/drain. The first source/drain is in direct contact with three different sides of a first section of the second portion of the first source/drain contact.

A semiconductor device includes a semiconductor layer of a first conductivity type. A well region that is a second conductivity type well region is formed on a surface layer portion of the semiconductor layer and has a channel region defined therein. A source region that is a first conductivity type source region is formed on a surface layer portion of the well region. A gate insulating film is formed on the semiconductor layer and has a multilayer structure. A gate electrode is opposed to the channel region of the well region where a channel is formed through the gate insulating film.

A semiconductor device includes: a substrate; a first nitride semiconductor layer above the substrate; a second nitride semiconductor layer above the first nitride semiconductor layer and being greater than the first nitride semiconductor layer in band gap; and a first field-effect transistor including a first source electrode, a first drain electrode, and a first gate electrode that are above the second nitride semiconductor layer, the first source electrode and the first drain electrode being separated from each other, the first gate electrode being disposed between the first source electrode and the first drain electrode. The first field-effect transistor includes a third semiconductor layer that is above the second nitride semiconductor layer in part of a region between lower part of the first source electrode and the first gate electrode, and is separated from the first gate electrode. The third semiconductor layer and the first source electrode are electrically connected.

Disclosed is a structure including a field effect transistor (FET). The FET includes, on an insulator layer above a substrate, source/drain regions and a section of a semiconductor layer extending laterally between the source/drain regions. A primary gate structure is made of the insulator layer and a well region in the substrate opposite at least the section of the semiconductor layer extending laterally between the source/drain regions. One or two secondary gate structures are on the semiconductor layer between and near one or both of the source/drain regions, respectively. The FET can further include a patterned conformal dielectric layer, which is on the center of the semiconductor layer between the source/drain regions, and which extends onto the secondary gate structure(s). Also disclosed are methods of operating the structure by biasing the secondary gate structure(s) to adjust the effective gate length of the FET and methods of forming the structure.

A semiconductor structure is provided. The semiconductor structure includes a substrate, a deep trench isolation (DTI), an interconnect structure, and a conductive pillar. The DTI is disposed in the substrate and the interconnect structure is disposed over the substrate. The conductive pillar extends from the interconnect structure toward the substrate and penetrates the DTI.

The present application relates to a semiconductor die, comprising a silicon carbide (SiC) semiconductor body comprising a first doping type region; a metallization on a first side of the SiC semiconductor body; an inorganic passivation layer system; a lateral edge of the inorganic passivation layer system arranged on the SiC semiconductor body, wherein the lateral edge of the inorganic passivation layer system is laterally offset inwards from a lateral edge of the SiC semiconductor body, the SiC semiconductor body being uncovered by the inorganic passivation layer system in an edge area, wherein a second doping type well is formed at the first side of the SiC semiconductor body in the first doping type region, the second doping type well extending from below the inorganic passivation layer system into the edge area.

The fabrication of field-effect transistor (FET) devices is described herein where the FET devices include one or more body contacts implemented between source, gate, drain (S/G/D) assemblies to improve the influence of a voltage applied at the body contact on the S/G/D assemblies. The FET devices can include source fingers and drain fingers interleaved with gate fingers. The source and drain fingers of a first S/G/D assembly can be electrically connected to the source and drain fingers of a second S/G/D assembly. The source fingers and the drain fingers can be arranged in alternating rows.