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-based structure may include fins on a surface of a semiconductor substrate. Each of the fins may include a doped portion proximate to the surface of the semiconductor substrate. The fin-based structure may also include an isolation layer disposed between the fins and on the surface of the semiconductor substrate. The fin-based structure may also include a recessed isolation liner on sidewalls of the doped portion of the fins. An unlined doped portion of the fins may extend from the recessed isolation liner to an active portion of the fins at a surface of the isolation layer. The isolation layer is disposed on the unlined doped portion of the fins.

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: 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 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: 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 method for forming a resistive random access memory (RRAM) device is disclosed. The method comprises forming a first electrode, forming a resistive switching oxide layer comprising a metal oxide by thermal atomic layer deposition (ALD), doping the resistive switching oxide layer with a metal dopant different from metal forming the metal oxide, and forming a second electrode by thermal atomic layer deposition (ALD), where the resistive switching layer is interposed between the first electrode and the second electrode. In some embodiments, forming the resistive switching oxide may be performed without exposing a surface of the switching oxide layer to a surface-modifying plasma treatment after depositing the metal oxide.

Abstract: A fin-based structure may include fins on a surface of a semiconductor substrate. Each of the fins may include a doped portion proximate to the surface of the semiconductor substrate. The fin-based structure may also include an isolation layer disposed between the fins and on the surface of the semiconductor substrate. The fin-based structure may also include a recessed isolation liner on sidewalls of the doped portion of the fins. An unlined doped portion of the fins may extend from the recessed isolation liner to an active potion of the fins at a surface of the isolation layer. The isolation layer is disposed on the unlined doped portion of the fins.

Abstract: A semiconductor device includes a gate stack. The semiconductor device also includes a wrap-around contact arranged around and contacting substantially all surface area of a regrown source/drain region of the semiconductor device proximate to the gate stack.

Abstract: Semiconductor structures, devices, and methods of forming the structures and device are disclosed. Exemplary structures include multi-gate or FinFET structures that can include both n-channel MOS (NMOS) and p-channel MOS (PMOS) devices to form CMOS structures and devices on a substrate. The devices can be formed using selective epitaxy and shallow trench isolation techniques.

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: A device includes a first structure and a second structure. The second structure is separated from the first structure by a cavity. The device further includes a seal material, an etch stop material defining an etched region, and a self-aligned contact (SAC). The seal material is configured to seal the cavity, and the SAC is formed within the etched region. The SAC adjoins the seal material, the etch stop material, or a combination thereof.

Abstract: A method of forming a semiconductor fin of a FinFET device includes conformally depositing an amorphous or polycrystalline thin film of silicon-germanium (SiGe) on the semiconductor fin. The method also includes oxidizing the amorphous or polycrystalline thin film to diffuse germanium from the amorphous or polycrystalline thin film into the semiconductor fin. Such a method further includes removing an oxidized portion of the amorphous or polycrystalline thin film.

Abstract: Semiconductor structures, devices, and methods of forming the structures and device are disclosed. Exemplary structures include multi-gate or FinFET structures that can include both re-channel MOS (NMOS) and p-channel MOS (PMOS) devices to form CMOS structures and devices on a substrate. The devices can be formed using selective epitaxy and shallow trench isolation techniques.

Abstract: Methods of treating metal-containing thin films, such as films comprising titanium carbide, with a silane or a 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: According to some embodiments, an electrode have a high effective work function is formed. The electrode may be the gate electrode of a transistor and may be formed on a high-k gate dielectric by depositing a first layer of conductive material, exposing that first layer to a hydrogen-containing gas, and depositing a second layer of conductive material over the first layer. The first layer may be deposited using a non-plasma process in which the substrate is not exposed to plasma or plasma-generated radicals. The hydrogen-containing gas to which the first layer is exposed may include an excited hydrogen species, which may be part of a hydrogen-containing plasma, and may be hydrogen-containing radicals. The first layer may also be exposed to oxygen before depositing the second layer. The work function of the gate electrode in the gate stack may be about 5 eV or higher in some embodiments.

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: 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.

Abstract: A method of forming a semiconductor fin of a FinFET device includes conformally depositing an amorphous or polycrystalline thin film of silicon-germanium (SiGe) on the semiconductor fin. The method also includes oxidizing the amorphous or polycrystalline thin film to diffuse germanium from the amorphous or polycrystalline thin film into the semiconductor fin. Such a method further includes removing an oxidized portion of the amorphous or polycrystalline thin film.

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.