An apparatus includes a first drain/source region and a second drain/source region over a substrate, a first gate adjacent to the first drain/source region, the first gate comprising a plurality of first fingers forming a first comb structure, and a second gate adjacent to the second drain/source region, the second gate comprising a plurality of second fingers forming a second comb structure, wherein the plurality of first fingers and the plurality of second fingers are placed in an alternating manner, and wherein the first drain/source region, the second drain/source region, the first gate and the second gate form two back-to-back connected transistors.

An apparatus includes a first drain/source region and a second drain/source region over a substrate, a first gate adjacent to the first drain/source region, the first gate comprising a plurality of first fingers forming a first comb structure, and a second gate adjacent to the second drain/source region, the second gate comprising a plurality of second fingers forming a second comb structure, wherein the plurality of first fingers and the plurality of second fingers are placed in an alternating manner, and wherein the first drain/source region, the second drain/source region, the first gate and the second gate form two back-to-back connected transistors.

A method for manufacturing a semiconductor device and an integrated semiconductor device, said method comprising: providing an epitaxial layer having a first region and a second region, forming, in the first region, at least two second doping-type deep wells, and forming, in the second region, at least two second doping-type deep wells; forming a first dielectric island between the second doping-type deep wells and forming a second dielectric island on the second doping-type deep wells; forming a first doping-type trench on two sides of the first dielectric island in the first region; forming a gate structure on the first dielectric island; and forming a separated first doping-type source region by using the second dielectric island as a mask, the first doping-type trench extending, in the first region, transversally to the first doping-type source region.

Embodiments include a transistor and methods of forming such transistors. In an embodiment, the transistor comprises a semiconductor substrate, a barrier layer over the semiconductor substrate; a polarization layer over the barrier layer, an insulating layer over the polarization layer, a gate electrode through the insulating layer and the polarization layer, a spacer along sidewalls of the gate electrode, and a gate dielectric between the gate electrode and the barrier layer.

Embodiments include a transistor and methods of forming such transistors. In an embodiment, the transistor comprises a semiconductor substrate, a barrier layer over the semiconductor substrate; a polarization layer over the barrier layer, an insulating layer over the polarization layer, a gate electrode through the insulating layer and the polarization layer, a spacer along sidewalls of the gate electrode, and a gate dielectric between the gate electrode and the barrier layer.

The power device is formed by a D-mode HEMT and by a MOSFET in cascade to each other and integrated in a chip having a base body and a heterostructure layer on the base body. The D-mode HEMT includes a channel area formed in the heterostructure layer; the MOSFET includes a first and a second conduction region formed in the base body, and an insulated-gate region formed in the heterostructure layer, laterally and electrically insulated from the D-mode HEMT. A first metal region extends through the heterostructure layer, laterally to the channel area and in electrical contact with the channel area and the first conduction region.

The power device is formed by a D-mode HEMT and by a MOSFET in cascade to each other and integrated in a chip having a base body and a heterostructure layer on the base body. The D-mode HEMT includes a channel area formed in the heterostructure layer; the MOSFET includes a first and a second conduction region formed in the base body, and an insulated-gate region formed in the heterostructure layer, laterally and electrically insulated from the D-mode HEMT. A first metal region extends through the heterostructure layer, laterally to the channel area and in electrical contact with the channel area and the first conduction region.

A semiconductor structure and a method for forming a semiconductor structure are provided. The semiconductor structure includes a well region extending in a first direction; a gate electrode disposed within the substrate and overlapping the well region; a gate dielectric layer disposed within the substrate and laterally surrounding the gate electrode; a plurality of first protection structures disposed over the gate electrode; a second protection structure extending in a second direction different from the first direction over the gate dielectric layer; and an insulating layer extending in the second direction between the second protection structure and the gate dielectric layer.

A semiconductor structure and a method for forming a semiconductor structure are provided. The semiconductor structure includes a well region extending in a first direction; a gate electrode disposed within the substrate and overlapping the well region; a gate dielectric layer disposed within the substrate and laterally surrounding the gate electrode; a plurality of first protection structures disposed over the gate electrode; a second protection structure extending in a second direction different from the first direction over the gate dielectric layer; and an insulating layer extending in the second direction between the second protection structure and the gate dielectric layer.

The present application provides an integrated semiconductor device and an electronic apparatus, comprising a semiconductor substrate and a first doped epitaxial layer having a first region, a second region, and a third region; a partition structure is arranged in the third region; the first region is formed having at least two second doped deep wells, and the second region is formed having at least two second doped deep wells; a dielectric island partially covers a region between two adjacent doped deep wells in the first region and second region; a gate structure covers the dielectric island; a first doped source region is located on the two sides of the gate structure, and a first doped source region located in the same second doped deep well is separated; a first doped trench is located on the two sides of the dielectric island in the first region, and extends laterally to the first doped source region.