One illustrative device disclosed herein includes a stepped conductive source/drain structure with a cavity defined therein, the cavity being located vertically above an active region, a non-conductive structure positioned in the cavity, a layer of insulating material positioned above the gate structure, the stepped conductive source/drain structure and the non-conductive structure, a gate contact opening defined in the layer of insulating material and a conductive gate contact positioned in the gate contact opening that is conductively coupled to the gate structure, wherein at least a portion of the conductive gate contact is positioned vertically above the non-conductive structure.

A semiconductor device includes a semiconductor-on-insulator wafer having a buried layer. The buried layer includes therein opposing etch barrier regions and a gate region between the etch barrier regions. The semiconductor device further includes at least one nanowire having a channel portion interposed between opposing source/drain portions. The channel portion is suspended in the gate region. A gate electrode is formed in the gate region, and completely surrounds all surfaces of the suspended nanowire. The buried layer comprises a first electrical insulating material, and the etch barrier regions comprising a second electrical insulating material different from the first electrical insulating material.

A device is provided. The device includes a transistor formed on a semiconductor substrate, the transistor having a conduction channel. The device includes at least one edge dislocation formed adjacent to the conduction channel on the semiconductor substrate. The device also includes at least one free surface introduced above the conduction channel and the at least one edge dislocation.

A semiconductor structure is provided including a strained silicon germanium alloy fin that can be employed as a channel material for a FinFET device and having a gate spacer including a lower portion that fills in a undercut region that lies adjacent to the strained silicon germanium alloy fin and beneath raised source/drain (S/D) structures and silicon pedestal structures that can provide improved overlay capacitance.

A method for filling gaps between structures includes forming a plurality of high aspect ratio structures adjacent to one another with gaps, forming a first dielectric layer on tops of the structures and conformally depositing a spacer dielectric layer over the structures. The spacer dielectric layer is removed from horizontal surfaces and a protection layer is conformally deposited over the structures. The gaps are filled with a flowable dielectric, which is recessed to a height along sidewalls of the structures by a selective etch process such that the protection layer protects the spacer dielectric layer on sidewalls of the structures. The first dielectric layer and the spacer dielectric layer are exposed above the height using a higher etch resistance than the protection layer to maintain dimensions of the spacer layer dielectric through the etching processes. The gaps are filled by a high density plasma fill.

A semiconductor device includes a substrate including a plurality of transistor devices formed thereon, at least an epitaxial structure formed in between the transistor devices, and a tri-layered structure formed on the epitaxial structure. The epitaxial structure includes a first semiconductor material and a second semiconductor material, and a lattice constant of the second semiconductor material is larger than a lattice constant of the first semiconductor material. The tri-layered structure includes an undoped epitaxial layer, a metal-semiconductor compound layer, and a doped epitaxial layer sandwiched in between the undoped epitaxial layer and the metal-semiconductor compound layer. The undoped epitaxial layer and the doped epitaxial layer include at least the second semiconductor material.

The present invention relates generally to semiconductor devices and more particularly, to a structure and method of forming a contact silicide on a source-drain (S-D) region of a field effect transistor (FET) having extensions by using an undercut etch and a salicide process. A method of forming a contact silicide extension is disclosed. The method may include: forming an undercut region below a dielectric layer and above a source-drain region, the undercut region located directly below a bottom of a contact trench and extending below the dielectric layer to a gate spacer formed on a sidewall of a gate stack; and forming a contact silicide in the undercut region, the contact silicide in direct contact with the source-drain region.

A semiconductor device includes a semiconductor substrate, a gate structure formed over the semiconductor substrate, and an epitaxial structure formed partially within the semiconductor substrate. A vertically extending portion of the epitaxial structure extends vertically above a top surface of the semiconductor substrate in an area adjacent the gate structure. A laterally extending portion of the epitaxial structure extends laterally at an area below the top surface of the semiconductor substrate in a direction toward an area below the gate structure and beyond an area where the epitaxial structure extends vertically. The device further includes an interlayer dielectric layer between a side surface of the vertically extending portion of the epitaxial structure and a side surface of the gate structure. A top surface of the laterally extending portion of the epitaxial structure directly contacts the interlayer dielectric layer.

A method for fabricating a semiconductor device includes forming a pre-fin extending in a first direction, the pre-fin including first, second, and third regions, forming first and second gates on the pre-fin to extend in a second direction intersecting the first direction, the first and second gates being spaced apart from each other in the first direction and overlapping with the first and second regions, respectively, forming first and second dummy spacers on the first and second regions, respectively to form a first trench in the third region that exposes the third region, forming a second trench by etching the exposed third region using the first and second dummy spacers as masks to separate the pre-fin into first and second active fins corresponding to the first and second regions, respectively, forming a dummy gate by filling the first and second trenches and removing the first and second dummy spacers.

A method for producing a cutting tool, in particular a drill bit, is specified wherein the cutting tool has a front end (F) at the front and a rear end (R) toward the rear, wherein a tool tip is formed on the front end (F), a point thinning is ground at the tool tip with a grinding tool, the point thinning being ground to be narrower toward the front than toward the rear. The point thinning is ground with a constant point thinning angle (AW). Furthermore, a corresponding cutting tool is specified.