A transistor amplifier package includes a base, one or more transistor dies on the base, first and second leads coupled to the one or more transistor dies and defining respective radio frequency (RF) signal paths, and an isolation structure on the base between the respective RF signal paths. The isolation structure includes first and second wire bonds. The first and second wire bonds may have a crossed configuration defining at least one cross point therebetween. Related wire bond-based isolation structures are also discussed.

A method of forming an integrated circuit forms a first oxygen diffusion barrier layer in a fixed position relative to a semiconductor substrate and forms an aperture through the first oxygen diffusion barrier layer to expose a portion of the semiconductor substrate. The method also forms a first LOCOS region in an area of the aperture and a second oxygen diffusion barrier layer along the first LOCOS region and along at least a sidewall portion of the first oxygen diffusion barrier layer in the area of the aperture. The method also deposits a polysilicon layer, at a temperature of 570° C. or less, over the second oxygen diffusion barrier layer, etches the polysilicon layer and the second oxygen diffusion barrier layer to form a spacer in the area of the aperture, and forms a second LOCOS region in the area of the aperture and aligned to the spacer.

An apparatus includes a first lateral diffusion field effect transistor (LDFET) having a first threshold voltage and that includes a first gate electrode, a first drain contact, a first source contact, and a first electrically conductive shield plate separated from the first gate electrode and the first source contact by a first interlayer dielectric. A second LDFET of the apparatus has a second threshold voltage and includes a second gate electrode, a second drain contact, and a second source contact. The second source contact is electrically connected to the first source contact of the first LDFET. A control circuit of the apparatus is electrically coupled to the first electrically conductive shield plate and is configured to apply to the first electrically conductive shield plate a first gate bias voltage of a first level to set the first threshold voltage of the first LDFET to a first desired threshold voltage.

An integrated circuit includes an N-type laterally diffused metal-oxide semiconductor (NLDMOS) transistor including an active semiconductor substrate region having P-type conductivity. The integrated circuit further includes a buried semiconductor region having N+-type conductivity underneath the active substrate region. The buried semiconductor region is more heavily doped than the active semiconductor substrate region.

A high voltage device includes: a semiconductor layer, a well region, a shallow trench isolation region, a drift oxide region, a body region, a gate, a source, and a drain. The drift oxide region is located on a drift region. The shallow trench isolation region is located below the drift oxide region. A part of the drift oxide region is located vertically above a part of the shallow trench isolation region and is in contact with the shallow trench isolation region. The shallow trench isolation region is formed between the drain and the body region.

In some embodiments, the present disclosure relates to an integrated chip that includes a source region and a drain region arranged over and/or within a substrate. Further, a shallow trench isolation (STI) structure is arranged within the substrate and between the source and drain regions. A gate electrode is arranged over the substrate, over the STI structure, and between the source and drain regions. A portion of the gate electrode extends into the STI structure such that a bottommost surface of the portion of the gate electrode is arranged between a topmost surface of the STI structure and a bottommost surface of the STI structure.

Described examples include an integrated circuit having a semiconductor substrate. The integrated circuit has a transistor that includes a buried layer having within the substrate, the buried layer defining a drift region between the buried layer and the top surface and a body region in the substrate extending from the buried layer to the surface of the substrate. The transistor also having a source formed in the body region, a drain extending from the buried layer to the surface of the substrate, a drift well extending from the buried layer toward the top surface and extending from the body region to the drain, a drift surface layer located between the drift well and the top, and a gate proximate to the surface of the substrate at the body region.

A wide gap semiconductor device has: a first MOSFET region (M0) having a first gate electrode 10 and a first source region 30 provided in a first well region 20 made of a second conductivity type; a second MOSFET region (M1) provided below a gate pad 100 and having a second gate electrode 110 and a second source region 130 provided in a second well region 120 made of the second conductivity type; and a built-in diode region electrically connected to the second gate electrode 110. The second source region 130 of the second MOSFET region (M1) is electrically connected to the gate pad 100.

An integrated circuit includes a drift region in a substrate, a drain in the substrate which includes a doped drain well, the doped drain well including a first zone, having a first concentration of a first dopant, and a second zone, having a second concentration of the first dopant, where the first concentration is smaller than the second concentration, and a gate electrode over the drift region and being separated from the doped drain well in a direction parallel to a top surface of the substrate by a distance greater than 0.

Provided is a monolithic metal-insulator transition device. The monolithic metal-insulator transition device includes a substrate including a driving region and a switching region, first and second source/drain regions on the driving region, a gate electrode between the first and second source/drain regions, an inlet well region formed adjacent to an upper surface of the substrate on the switching region, a control well region having a different conductivity type from the inlet well region between the inlet well region and a lower surface of the substrate, a first wiring electrically connecting the first source/drain region and the control well region, and a second wiring electrically connecting the second source/drain region and the inlet well region.