A field effect transistor having a higher breakdown voltage can be provided by forming a contiguous dielectric material layer over gate stacks, forming via cavities laterally spaced from the gate stacks, selectively depositing a single crystalline semiconductor material, and converting upper portions of the deposited single crystalline semiconductor material into elevated source/drain regions. Lower portions of the selectively deposited single crystalline semiconductor material in the via cavities can have a doping of a lesser concentration, thereby effectively increasing the distance between two steep junctions at edges of a source region and a drain region. Optionally, embedded active regions for additional devices can be formed prior to formation of the contiguous dielectric material layer. Raised active regions contacting a top surface of a substrate can be formed simultaneously with formation of the elevated active regions that are vertically spaced from the top surface.

In a method for fabricating a field-effect transistor (FET) structure, forming a shallow trench isolation (STI) structure on a semiconductor substrate, wherein the STI structure includes dielectric structures that form one or more dielectric walled aspect ratio trapping (ART) trenches. The method further includes epitaxially growing a first semiconductor material on the semiconductor substrate and substantially filling at least one of the one or more ART trenches, and recessing the first semiconductor material down into the ART trenches selective to the dielectric structures, such that the upper surface of the first semiconductor material is below the upper surface of the dielectric structures. The method further includes epitaxially growing a second semiconductor material on top of the first semiconductor material and substantially filling the ART trenches to form a semiconductor fin that comprises an upper portion comprising the second semiconductor material and a lower portion comprising the first semiconductor material.

A method of fabricating a semiconductor device including a diffused metal-oxide-semiconductor (DMOS) transistor, an n-type metal-oxide-semiconductor (NMOS) transistor, and a p-type metal-oxide-semiconductor (PMOS) transistor includes forming separation regions in a semiconductor substrate, forming a gate insulating film, forming a DMOS gate electrode on the gate insulating film, forming a first mask pattern on the semiconductor substrate, performing a first ion implantation process, forming a second mask pattern on the semiconductor substrate, performing a second ion implantation process, forming a third mask pattern on the semiconductor substrate and performing a third ion implantation process into the semiconductor substrate, and forming a fourth mask pattern on the semiconductor substrate and performing a fourth ion implantation process.

Semiconductor devices having vertical FET (field effect transistor) devices with metallic source/drain regions are provided, as well as methods for fabricating such vertical FET devices. For example, a semiconductor device includes a first source/drain region formed on a semiconductor substrate, a vertical semiconductor fin formed on the first source/drain region, a second source/drain region formed on an upper surface of the vertical semiconductor fin, a gate structure formed on a sidewall surface of the vertical semiconductor fin, and an insulating material that encapsulates the vertical semiconductor fin and the gate structure. The first source/drain region comprises a metallic layer and at least a first epitaxial semiconductor layer. For example, the metallic layer of the first source/drain region comprises a metal-semiconductor alloy such as silicide.

The present disclosure describes a fin-like field-effect transistor (FinFET). The device includes one or more fin structures over a substrate, each with source/drain (S/D) features and a high-k/metal gate (HK/MG). A first HK/MG in a first gate region wraps over an upper portion of a first fin structure, the first fin structure including an epitaxial silicon (Si) layer as its upper portion and an epitaxial growth silicon germanium (SiGe), with a silicon germanium oxide (SiGeO) feature at its outer layer, as its middle portion, and the substrate as its bottom portion. A second HK/MG in a second gate region, wraps over an upper portion of a second fin structure, the second fin structure including an epitaxial SiGe layer as its upper portion, an epitaxial Si layer as it upper middle portion, an epitaxial SiGe layer as its lower middle portion, and the substrate as its bottom portion.

An electrical device including a first semiconductor device having a silicon and germanium containing source and drain region, and a second semiconductor device having a silicon containing source and drain region. A first device contact to at least one of said silicon and germanium containing source and drain region of the first semiconductor device including a metal liner of an aluminum titanium and silicon alloy and a first tungsten fill. A second device contact is in contact with at least one of the silicon containing source and drain region of the second semiconductor device including a material stack of a titanium oxide layer and a titanium layer. The second device contact may further include a second tungsten fill.

A method of forming a gate structure for a semiconductor device that includes forming first spacers on the sidewalls of replacement gate structures that are present on a fin structure, wherein an upper surface of the first spacers is offset from an upper surface of the replacement gate structure, and forming at least second spacers on the first spacers and the exposed surfaces of the replacement gate structure. The method may further include substituting the replacement gate structure with a functional gate structure having a first width portion in a first space between adjacent first spacers, and a second width portion having a second width in a second space between adjacent second spacers, wherein the second width is greater than the first width.

A gate insulating film and a gate electrode of non-single crystalline silicon for forming an nMOS transistor are provided on a silicon substrate. Using the gate electrode as a mask, n-type dopants having a relatively large mass number (70 or more) such as As ions or Sb ions are implanted, to form a source/drain region of the nMOS transistor, whereby the gate electrode is amorphized. Subsequently, a silicon oxide film is provided to cover the gate electrode, at a temperature which is less than the one at which recrystallization of the gate electrode occurs. Thereafter, thermal processing is performed at a temperature of about 1000 C., whereby high compressive residual stress is exerted on the gate electrode, and high tensile stress is applied to a channel region under the gate electrode. As a result, carrier mobility of the nMOS transistor is enhanced.

A method of fabricating a vertical field effect transistor including forming a first recess in a substrate; epitaxially growing a first drain from the first bottom surface of the first recess; epitaxially growing a second drain from the second bottom surface of a second recess formed in the substrate; growing a channel material epitaxially on the first drain and the second drain; forming troughs in the channel material to form one or more fin channels on the first drain and one or more fin channels on the second drain, wherein the troughs over the first drain extend to the surface of the first drain, and the troughs over the second drain extend to the surface of the second drain; forming a gate structure on each of the one or more fin channels; and growing sources on each of the fin channels associated with the first and second drains.

A semiconductor device includes one nanowire structure disposed on semiconductor substrate and extending in first direction on semiconductor substrate. Each nanowire structure includes plurality of nanowires extending along first direction and arranged in second direction, the second direction being substantially perpendicular to first direction. Each nanowire is spaced-apart from immediately adjacent nanowire. A gate structure extends in third direction over first region of nanowire structure, the third direction being substantially perpendicular to both first direction and second direction. The gate structure includes a gate electrode. Source/drain regions are disposed over second region of nanowire structure, the second region being located on opposing sides of gate structure. The gate electrode wraps around each nanowire. When viewed in cross section taken along third direction, each nanowire in nanowire structure is differently shaped from other nanowires, and each nanowire has substantially same cross-sectional area as other nanowires in nanowire structure.