A method for manufacturing a semiconductor device includes providing a substrate, performing an N-type dopant implantation into a first region of the substrate to form an N-well, removing a portion of the substrate to form a first set of fins on the N-well and a second set of fins on a second region of the substrate adjacent the N-well, filling gap spaces between the fins to form an isolation region, and performing a P-type dopant implantation into the second region to form a P-well adjacent the N-well. The N-well and the P-well are formed separately at different times. The loss of the P-type dopant ions due to the diffusion of P-type dopant ions in the P-well into the isolation region can be eliminated, and the damage to the fins caused by N-type dopant ions can be avoided.

In a method of fabricating at least one IC, doped regions are formed on a semiconductor wafer using a first photolithography mask, including at least one doped region of a test structure. Active regions are formed on the semiconductor wafer using a second photolithography mask, including active regions of the test structure. Electrical contacts are formed on the active regions of the test structure. Electrical resistances are measured between pairs of active regions of the test structure using the electrical contacts. At least one metric is determined indicating whether the doped regions are spatially aligned with the active regions based on the measured electrical resistances. In response to the at least one metric indicating the doped regions are spatially aligned with the active regions, completing fabrication of the at least one integrated circuit.

The present disclosure provides a method of manufacturing a semiconductor device includes forming a first gate insulating film on a substrate for a first device, forming a first gate electrode on the first gate insulating film; forming a mask pattern on the first gate electrode to expose opposing end portions of the first gate electrode, wherein a length of the mask pattern is smaller than a length of the first gate electrode; performing ion implantation through the exposed opposing end portions of the first gate electrode using the mask pattern to simultaneously form first and second drift regions in the substrate; forming spacers on sidewalls of the first gate electrode, respectively; and forming a first source region and a first drain region in the first and second drift regions, respectively.

A semiconductor arrangement includes a well region and a first region disposed within the well region. The first region includes a first conductivity type. The semiconductor arrangement includes a first gate disposed above the well region on a first side of the first region. The first gate includes a first top surface facing away from the well region. The first top surface has a first top surface area. The semiconductor arrangement includes a first gate contact disposed above the first gate. The first gate contact includes a first bottom surface facing towards the well region. The first bottom surface has a first bottom surface area. The first bottom surface area covers at least about two thirds of the first top surface area.

Provided is a method for forming a two-dimensional array of semiconductor quantum confined structures. The method includes providing a layer that has first atoms and second atoms, the first atoms having a different size than the second atoms; providing an indenter template that includes at least one indenter structure extending from a surface of the indenter template; contacting the layer and the at least one indenter structure together with a pressure sufficient to generate an elastic deformation in the layer but without generating plastic deformation of the layer; annealing the layer. The contacting of the layer and the at least one indenter structure includes forming at least one quantum confined structure in the layer.

A semiconductor structure includes first, second, and third transistor elements each having a first screening region concurrently formed therein. A second screening region is formed in the second and third transistor elements such that there is at least one characteristic of the screening region in the second transistor element that is different than the second screening region in the third transistor element. Different characteristics include doping concentration and depth of implant. In addition, a different characteristic may be achieved by concurrently implanting the second screening region in the second and third transistor element followed by implanting an additional dopant into the second screening region of the third transistor element

An integrated circuit is formed on a substrate containing a semiconductor material having a first conductivity type. A deep well having a second, opposite, conductivity type is formed in the semiconductor material of the first conductivity type. A deep isolation trench is formed in the substrate through the deep well so as separate an unused portion of the deep well from a functional portion of the deep well. The functional portion of the deep well contains an active circuit element of the integrated circuit. The separated portion of the deep well does not contain an active circuit element. A contact region having the second conductivity type and a higher average doping density than the deep well is formed in the separated portion of the deep well. The contact region is connected to a voltage terminal of the integrated circuit.

An integrated semiconductor transistor chip for use in a buck converter includes a high side transistor formed on the chip and comprising a laterally diffused metal oxide semiconductor (LDMOS) transistor and a low side transistor formed on the chip and comprising a source down metal oxide semiconductor field effect transistor (MOSFET). The chip also includes a substrate of the chip for use as a source for the low side transistor and an n-doped well for isolation of the high side transistor from the source of the low side transistor.

A gate-all around fin double diffused metal oxide semiconductor (DMOS) devices and methods of manufacture are disclosed. The method includes forming a plurality of fin structures from a substrate. The method further includes forming a well of a first conductivity type and a second conductivity type within the substrate and corresponding fin structures of the plurality of fin structures. The method further includes forming a source contact on an exposed portion of a first fin structure. The method further comprises forming drain contacts on exposed portions of adjacent fin structures to the first fin structure. The method further includes forming a gate structure in a dielectric fill material about the first fin structure and extending over the well of the first conductivity type.

A semiconductor device of a circuit is provided. The circuit is configured to be operated under a power supply. The semiconductor device of the circuit includes a first transistor and a second transistor. The first transistor includes a first source region in a first bulk region; a first drain region defined by a well and a doped region, wherein the first source region and the doped region are separate by a distance, which is a factor which determines a breakdown voltage of the first transistor, the breakdown voltage being associated with the power supply; and a first gate. The second transistor includes a second source region in a second bulk region, the second source region electrically connected with the first source region and the first gate.