Abstract: The present disclosure relates to methods and structures that involve the use of directed self-assembly to selectively remove at least one fin or fin section from a pattern of parallel fins in a semiconductor structure.

Abstract: In a particular embodiment, a method includes forming a first spacer structure on a dummy gate of a semiconductor device and forming a sacrificial spacer on the first spacer structure. The method also includes etching a structure of the semiconductor device to create an opening, removing the sacrificial spacer via the opening, and depositing a material to close to define a gap.

Abstract: An integrated circuit (IC) device may include a first active transistor of a first-type in a first-type region. The first active transistor may have a first-type work function material and a low channel dopant concentration in an active portion of the first active transistor. The IC device may also include a first isolation transistor of the first-type in the first-type region. The second active transistor may have a second-type work function material and the low channel dopant concentration in an active portion of the first isolation transistor. The first isolation transistor may be arranged adjacent to the first active transistor.

Abstract: A fin-type semiconductor device includes a gate structure and a source/drain structure. The fin-type semiconductor device also includes a gate hardmask structure coupled to the gate structure. The gate hardmask structure comprises a first material. The fin-type semiconductor device further includes a source/drain hardmask structure coupled to the source/drain structure. The source/drain hardmask structure comprises a second material.

Abstract: Self-aligned metal cut and via for Back-End-Of-Line (BEOL) processes for semiconductor integrated circuit (IC) fabrication, and related processes and devices, is disclosed. In this manner, mask placement overlay requirements can be relaxed. This relaxation can be multiples of that allowed by conventional BEOL techniques. This is enabled through application of different fill materials for alternating lines in which a conductor will later be placed. With these different fill materials in place, a print cut and via mask is used, with the mask allowed to overlap other adjacent fill lines to that of the desired line. Etching is then applied that is selective to the desired line but not adjacent lines.

Abstract: A device includes a substrate, a fin, and an isolation layer. The device also includes an epitaxial cladding layer on a sidewall of the fin. The epitaxial cladding layer has a substantially uniform thickness and has a continuous lattice structure at an interface with the sidewall. The epitaxial cladding layer is positioned above the isolation layer.

Abstract: A semiconductor device includes a first magnetic tunnel junction (MTJ) device, a second MTJ device, and a top electrode. The first MTJ device includes a barrier layer. The second MTJ device includes the barrier layer. The top electrode is coupled to the first MTJ device and the second MTJ device.

Abstract: A device includes a substrate, a first nanowire field effect transistor (FET), and a second nanowire FET positioned between the substrate and the first nanowire FET. The device also includes a first nanowire electrically coupled to the first nanowire FET and to the second nanowire FET.

Abstract: A nanowire transistor is provided that includes a well implant having a local isolation region for insulating a replacement metal gate from a parasitic channel. In addition, the nanowire transistor includes oxidized caps in the extension regions that inhibit parasitic gate-to-source and gate-to-drain capacitances.

Abstract: Methods of treating metal-containing thin films, such as films comprising titanium carbide, with a silane/borane agent are provided. In some embodiments a film comprising titanium carbide is deposited on a substrate by an atomic layer deposition (ALD) process. The process may include a plurality of deposition cycles involving alternating and sequential pulses of a first source chemical that comprises titanium and at least one halide ligand, a second source chemical comprising metal and carbon, wherein the metal and the carbon from the second source chemical are incorporated into the thin film, and a third source chemical, wherein the third source chemical is a silane or borane that at least partially reduces oxidized portions of the titanium carbide layer formed by the first and second source chemicals. In some embodiments treatment forms a capping layer on the metal carbide film.

Abstract: Self-aligned metal cut and via for Back-End-Of-Line (BEOL) processes for semiconductor integrated circuit (IC) fabrication, and related processes and devices, is disclosed. In this manner, mask placement overlay requirements can be relaxed. This relaxation can be multiples of that allowed by conventional BEOL techniques. This is enabled through application of different fill materials for alternating lines in which a conductor will later be placed. With these different fill materials in place, a print cut and via mask is used, with the mask allowed to overlap other adjacent fill lines to that of the desired line. Etching is then applied that is selective to the desired line but not adjacent lines.

Abstract: Aspects disclosed in the detailed description include nanowire channel structures of continuously stacked heterogeneous nanowires for complementary metal oxide semiconductor (CMOS) devices. Each of the nanowires has a top end portion and a bottom end portion that are narrower than a central portion. Furthermore, vertically adjacent nanowires are interconnected at the narrower top end portions and bottom end portions. This allows for connectivity between stacked nanowires and for having separation areas between vertically adjacent heterogeneous nanowires. Having the separation areas allows for gate material to be disposed over a large area of the heterogeneous nanowires and, therefore, provides strong gate control, a shorter nanowire channel structure, low parallel plate parasitic capacitance, and low parasitic channel capacitance. Having the nanowires be heterogeneous, i.e.

Abstract: Nanowire channel structures of continuously stacked nanowires for complementary metal oxide semiconductor (CMOS) devices are disclosed. In one aspect, an exemplary CMOS device includes a nanowire channel structure that includes a plurality of continuously stacked nanowires. Vertically adjacent nanowires are connected at narrow top and bottom end portions of each nanowire. Thus, the nanowire channel structure comprises a plurality of narrow portions that are narrower than a corresponding plurality of central portions. A wrap-around gate material is disposed around the nanowire channel structure, including the plurality of narrow portions, without entirely wrapping around any nanowire therein. The exemplary CMOS device provides, for example, a larger effective channel width and better gate control than a conventional fin field-effect transistor (FET) (FinFET) of a similar footprint. The exemplary CMOS device further provides, for example, a shorter nanowire channel structure than a conventional nanowire FET.

Abstract: A semiconductor device includes a first magnetic tunnel junction (MTJ) device, a second MTJ device, and a top electrode. The first MTJ device includes a barrier layer. The second MTJ device includes the barrier layer. The top electrode is coupled to the first MTJ device and the second MTJ device.

Abstract: A portion of a bulk silicon (Si) is formed into a fin, having a fin base and, on the fin base, an in-process fin. The fin base is doped Si and the in-process fin is silicon germanium (SiGe). The in-process SiGe fin has a source region and a drain region. Boron is in-situ doped into the drain region and into the source region. Optionally, boron is in-situ doped by forming an epi-layer, having boron, on the drain region and on the source region, and drive-in annealing to diffuse boron in the source region and the drain region.

Abstract: Methods of treating metal-containing thin films, such as films comprising titanium carbide, with a silane/borane agent are provided. In some embodiments a film comprising titanium carbide is deposited on a substrate by an atomic layer deposition (ALD) process. The process may include a plurality of deposition cycles involving alternating and sequential pulses of a first source chemical that comprises titanium and at least one halide ligand, a second source chemical comprising metal and carbon, wherein the metal and the carbon from the second source chemical are incorporated into the thin film, and a third source chemical, wherein the third source chemical is a silane or borane that at least partially reduces oxidized portions of the titanium carbide layer formed by the first and second source chemicals. In some embodiments treatment forms a capping layer on the metal carbide film.

Abstract: A semiconductor device includes a first magnetic tunnel junction (MTJ) device, a second MTJ device, and a top electrode. The first MTJ device includes a barrier layer. The second MTJ device includes the barrier layer. The top electrode is coupled to the first MTJ device and the second MTJ device.

Abstract: A portion of a bulk silicon (Si) is formed into a fin, having a fin base and, on the fin base, an in-process fin. The fin base is doped Si and the in-process fin is silicon germanium (SiGe). The in-process SiGe fin has a source region and a drain region. Boron is in-situ doped into the drain region and into the source region. Optionally, boron is in-situ doped by forming an epi-layer, having boron, on the drain region and on the source region, and drive-in annealing to diffuse boron in the source region and the drain region.

Abstract: An integrated circuit (IC) device may include a first active transistor of a first-type in a first-type region. The first active transistor may have a first-type work function material and a low channel dopant concentration in an active portion of the first active transistor. The IC device may also include a first isolation transistor of the first-type in the first-type region. The second active transistor may have a second-type work function material and the low channel dopant concentration in an active portion of the first isolation transistor. The first isolation transistor may be arranged adjacent to the first active transistor.

Abstract: In some embodiments, a method for manufacturing forms a semiconductor device, such as a transistor. A dielectric stack is formed on a semiconductor substrate. The stack comprises a plurality of dielectric layers separated by one of a plurality of spacer layers. Each of the plurality of spacer layers is formed of a different material than immediately neighboring layers of the plurality of dielectric layers. A vertically-extending hole is formed through the plurality of dielectric layers and the plurality of spacer layers. The hole is filled by performing an epitaxial deposition, with the material filling the hole forming a wire. The wire is doped and three of the dielectric layers are sequentially removed and replaced with conductive material, thereby forming upper and lower contacts to the wire and a gate between the upper and lower contacts. The wire may function as a channel region for a transistor.