A method for preparing a reference transistor test structure having a transistor with multiple terminals is provided. The method may include placing a set of bond pads at a first layer of the reference transistor test structure with each of the bond pads connecting to its corresponding terminal of the transistor, wherein the first layer of the reference transistor test structure is an uppermost metal layer. The method may further include placing a first protection device at a second layer of the reference transistor test structure and connecting the first protection device to at least one of the terminals of the transistor, wherein the second layer is a lowermost metal layer.

A method of manufacturing a semiconductor device includes forming a first gate stack over a substrate. The method further includes etching the substrate to define a cavity. The method further includes growing a first epitaxial (epi) material in the cavity, wherein the first epi material includes a first upper surface having a first crystal plane. The method further includes growing a second epi material on the first epi material, wherein the second epi material includes a second upper surface having the first crystal plane. The method further includes treating the second epi material, wherein treating the second epi material comprises causing the second upper surface to transform to a second crystal plane different from the first crystal plane.

An electrical device that in some embodiments includes a substrate including a lateral device region and a vertical device region. A lateral diffusion metal oxide semiconductor (LDMOS) device may be present in the lateral device region, wherein a drift region of the LDMOS device has a length that is parallel to an upper surface of the substrate in which the LDMOS device is formed. A vertical field effect transistor (VFET) device may be present in the vertical device region, wherein a vertical channel of the VFET has a length that is perpendicular to said upper surface of the substrate, the VFET including a gate structure that is positioned around the vertical channel.

A III-nitride device that includes a silicon body having formed therein an integrated circuit and a III-nitride device formed over a surface of the silicon body.

A manufacturing method for a semiconductor device, and an integrated semiconductor device. The manufacturing method comprises: on a semiconductor substrate, forming an epitaxial layer having a first region, a second region, and a third region; forming at least one groove in the third region, forming at least two second doping deep traps in the first region, and forming at least two second doping deep traps in the second region; forming a first dielectric island between the second doping deep traps and forming a second dielectric island on the second doping deep traps; forming a first doping groove at both sides of the first dielectric island in the first region; forming a gate structure on the first dielectric island; forming an isolated first doping source region using the second dielectric island as a mask.

A power transistor assembly and method of operating the assembly are provided. The power transistor assembly includes integrated transient voltage suppression on a single semiconductor substrate and includes a transistor formed of a wide band gap material, the transistor including a gate terminal, a source terminal, and a drain terminal, the transistor further including a predetermined maximum allowable gate voltage value, and a transient voltage suppression (TVS) device formed of a wide band gap material, the TVS device formed with the transistor as a single semiconductor device, the TVS device electrically coupled to the transistor between at least one of the gate and source terminals and the drain and source terminals, the TVS device including a breakdown voltage limitation selected to be greater than the predetermined maximum allowable gate voltage value.

An apparatus comprises an antifuse cell comprising first and second nodes, an antifuse element, and a transistor. The antifuse element and the transistor are coupled in series between the first and second nodes. The antifuse element comprises an antifuse gate. The transistor comprises a transistor gate comprising a substantially-annular structure substantially surrounding the antifuse gate.

A bidirectional blocking monolithic heterogeneous integrated Cascode-structure field effect transistor, which mainly solves a problem that the existing monolithic heterogeneous integrated Cascode-structure field effect transistor has no reverse blocking characteristic. The field effect transistor includes a substrate, a GaN buffer layer, an AlGaN barrier layer and a SiN isolation layer, wherein an isolation groove is etched in the middle of the SiN isolation layer, a Si active layer is printed on the SiN isolation layer on one side of the isolation groove so as to prepare a Si metal oxide semiconductor field effect transistor, and a GaN high-electron-mobility transistor is prepared on the other side of the isolation groove, and a drain electrode of the GaN high-electron-mobility transistor is in Schottky contact with the AlGaN barrier layer to form a bidirectional blocking monolithic heterogeneous integrated Cascode-structure field effect transistor.

A semiconductor device includes a semiconductor substrate having a main surface; a first coil formed on the main surface; a first insulating film formed over the first coil and having a first main surface; a second insulating film formed on the first main surface of the first insulating film and having a second main surface; and a second coil formed on the second main surface of the second insulating film, wherein the first main surface of the first insulating film has a first area on which the second insulating film is formed, and has a second area without the first area in a plan view, and wherein the second insulating film is surrounded with the second area in the plane view.

In described examples, an integrated circuit containing CMOS transistors and an embedded thermoelectric device may be formed by forming active areas which provide transistor active areas for an NMOS transistor and a PMOS transistor of the CMOS transistors and provide n-type thermoelectric elements and p-type thermoelectric elements of the embedded thermoelectric device. Stretch contacts with lateral aspect ratios greater than 4:1 are formed over the n-type thermoelectric elements and p-type thermoelectric elements to provide electrical and thermal connections through metal interconnects to a thermal node of the embedded thermoelectric device. The stretch contacts are formed by forming contact trenches in a dielectric layer, filling the contact trenches with contact metal and subsequently removing the contact metal from over the dielectric layer. The stretch contacts are formed concurrently with contacts to the NMOS and PMOS transistors.