A method of processing a power semiconductor device includes: providing a semiconductor body with a drift region of a first conductivity type; forming a plurality of trenches extending into the semiconductor body along a vertical direction and arranged adjacent to each other along a first lateral direction; providing a mask arrangement at the semiconductor body, the mask arrangement having a lateral structure according to which some of the trenches are exposed and at least one of the trenches is covered by the mask arrangement along the first lateral direction; forming, below bottoms of the exposed trenches, a plurality of doping regions of a second conductivity type complementary to the first conductivity type; removing the mask arrangement; and extending the plurality of doping regions in parallel to the first lateral direction such that the plurality of doping regions overlap and form a barrier region of the second conductivity type adjacent to the bottoms of the exposed trenches.

An integrated circuit has a P-type substrate and an N-type LDMOS transistor. The LDMOS transistor includes a boron-doped diffused well (DWELL-B) and an arsenic-doped diffused well (DWELL-As) located within the DWELL-B. A first polysilicon gate having first sidewall spacers and a second polysilicon gate having second sidewall spacers are located over opposite edges of the DWELL-B. A source/IBG region includes a first source region adjacent the first polysilicon gate, a second source region adjacent the second polysilicon gate, and an integrated back-gate (IBG) region located between the first and second source regions. The first source region and the second source region each include a lighter-doped source sub-region, the IBG region including an IBG sub-region having P-type dopants, and the source/IBG region includes a heavier-doped source sub-region.

A representative fin field effect transistor (FinFET) includes a substrate having a major surface; a fin structure protruding from the major surface having a lower portion comprising a first semiconductor material having a first lattice constant; an upper portion comprising the first semiconductor material. A bottom portion of the upper portion comprises a dopant with a first peak concentration. A middle portion is disposed between the lower portion and upper portion, where the middle portion comprises a second semiconductor material having a second lattice constant different from the first lattice constant. An isolation structure surrounds the fin structure, where a portion of the isolation structure adjacent to the bottom portion of the upper portion comprises the dopant with a second peak concentration equal to or greater than the first peak concentration.

A semiconductor device includes an anode doping region of a diode structure arranged in a semiconductor substrate. The anode doping region has a first conductivity type. The semiconductor device further includes a second conductivity type contact doping region having a second conductivity type. The second conductivity type contact doping region is arranged at a surface of the semiconductor substrate and surrounded in the semiconductor substrate by the anode doping region. The anode doping region includes a buried non-depletable portion. At least part of the buried non-depletable portion is located below the second conductivity type contact doping region in the semiconductor substrate.

In the semiconductor device, a high-concentration diffusion layer and a low-concentration diffusion layer are disposed around a drain diffusion layer of an ESD protection element. The high-concentration diffusion layer is separated from a gate electrode, and a medium concentration LDD diffusion layer is disposed in a separation gap. Variations in characteristics are suppressed by reducing thermal treatment on the high-concentration diffusion layer and a medium concentration diffusion layer.

A gate-turn-off thyristor is provided. The gate-turn-off thyristor includes a plurality of strips formed by repeatedly arranging a plurality of N-type emitter regions with high doping concentration of an upper transistor on an upper surface of an N-type silicon substrate with high resistivity, wherein a periphery of each strip of the plurality of strips is surrounded with a P-type dense base region bus bar of the upper transistor, a cathode metal layer is disposed on an N-type emitter region of the plurality of N-type emitter regions of the upper transistor, and a P-type base region of the upper transistor is disposed below the N-type emitter region of the upper transistor; a side of the P-type base region of the upper transistor is connected to a P-type dense base region of the upper transistor or a P-type dense base region bus bar of the upper transistor.

The present disclosure provides a method for forming a semiconductor device containing MOS transistors both with and without source/drain extension regions in a semiconductor substrate having a semiconductor material on either side of a gate structure including a gate electrode on a gate dielectric formed in a semiconductor material. In devices with source/drain extensions, a diffusion suppression species of one or more of indium, carbon and a halogen are used. The diffusion suppression implant can be selectively provided only to the semiconductor devices with drain extensions while devices without drain extensions remain diffusion suppression implant free.

A number of monolithic diode limiter semiconductor structures are described. The diode limiters can include a hybrid arrangement of diodes with different intrinsic regions, all formed over the same semiconductor substrate. In one example, a method of manufacture of a monolithic diode limiter includes providing an N-type semiconductor substrate, providing an intrinsic layer on the N-type semiconductor substrate, implanting a first P-type region to a first depth into the intrinsic layer, implanting a second P-type region to a second depth into the intrinsic layer, and forming at least one passive circuit element over the intrinsic layer. The method can also include forming an insulating layer on the intrinsic layer, forming a first opening in the insulating layer, and forming a second opening in the insulating layer. The method can also include implanting the first P-type region through the first opening and implanting the second P-type region through the second opening.

A display device and method of fabricating the same are provided. The display device includes a substrate and a thin-film transistor formed on the substrate. The thin-film transistor includes a lower gate conductive layer disposed on the substrate, and a lower gate insulating film disposed on the lower gate conductive layer The lower gate insulating film includes an upper surface and sidewalls. The thin-film transistor includes an active layer disposed on the upper surface of the lower gate insulating film, the active layer including sidewalls. At least one of the sidewalls of the lower gate insulating film and at least one of the sidewalls of the active layer are aligned with each other.

A method for manufacturing a semiconductor structure and the semiconductor structure are provided. In the method, a first wafer is provided, in which the first wafer has a first side and a second side opposite to each other, and a first conductive structure is provided in the first wafer, and an end of the first conductive structure is located in the first wafer. The first wafer is thinned from the second side along a direction perpendicular to the first side, until a thickness of the remaining first wafer reaches a preset thickness to expose the end of the first conductive structure. The thinning includes performing film peeling at least once. In the film peeling, hydrogen ion implantation is performed on the second side to form a hydrogen ion-containing layer in the first wafer; and the first wafer is heated to cause the hydrogen ion-containing layer to fall off.