A method is presented for forming a diffusion barrier in a field effect transistor with a source. A raised source is formed at least partially on the source with the raised source comprising III-V material. An interfacial layer is formed at least partially on the raised source with the interfacial layer comprising silicon or germanium. A metal layer is formed at least partially on the interfacial layer with the metal layer comprising transition metal. The diffusion barrier is formed at least partially on the raised source with the diffusion barrier layer comprising transition metal from the metal layer bonded to silicon or germanium from the interfacial layer. Similar processing forms a corresponding diffusion barrier on a raised drain.

A semiconductor device and a fabrication method thereof are provided. The semiconductor device includes a semiconductor structure, a dielectric layer, a metal-semiconductor compound film and a cover layer. The semiconductor structure has an upper surface and a lateral surface. The dielectric layer encloses the lateral surface of the semiconductor structure and exposes the upper surface of the semiconductor structure. The metal-semiconductor compound film is on the semiconductor structure, wherein the dielectric layer exposes a portion of a surface of the metal-semiconductor compound film. The cover layer encloses the portion of the surface of the metal-semiconductor compound film exposed by the dielectric layer, and exposes the dielectric layer.

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.

In one aspect, methods of silicidation and germanidation are provided. In some embodiments, methods for forming metal silicide can include forming a non-oxide interface, such as germanium or solid antimony, over exposed silicon regions of a substrate. Metal oxide is formed over the interface layer. Annealing and reducing causes metal from the metal oxide to react with the underlying silicon and form metal silicide. Additionally, metal germanide can be formed by reduction of metal oxide over germanium, whether or not any underlying silicon is also silicided. In other embodiments, nickel is deposited directly and an interface layer is not used. In another aspect, methods of depositing nickel thin films by vapor phase deposition processes are provided. In some embodiments, nickel thin films are deposited by ALD.

A method includes forming a gate, a first dielectric layer, a first contact structure, and a second contact structure over a substrate. The first contact structure and the second contact structure are over a source region and a drain region respectively. The first dielectric layer surrounds the gate, the first contact structure, and the second contact structure. The method includes forming a second dielectric layer over the first dielectric layer. The second dielectric layer has an opening exposing the gate, the first contact structure, and the second contact structure. A conductive layer is formed in the opening to electrically connect the gate to the first contact structure and the second contact structure.

A semiconductor device including a first fin active area substantially parallel to a second fin active area, a first source/drain in the first fin active area, a second source/drain in the second fin active area, a first contact plug on the first source/drain, and a second contact plug on the second source/drain. The center of the second contact plug is offset from the center of the second source/drain.

A method of making a semiconductor device includes forming a recessed fin in a substrate, the recessed fin being substantially flush with a surface of the substrate; performing an epitaxial growth process over the recessed fin to form a source/drain over the recessed fin; and disposing a conductive metal around the source/drain.

Reliability of a semiconductor device is improved, and use efficiency of a sputtering apparatus is increased. When depositing thin films over a main surface of a semiconductor wafer using a magnetron sputtering apparatus in which a collimator is installed in a space between the semiconductor wafer and a target installed in a chamber, a region inner than a peripheral part of the collimator is made thinner than the peripheral part. Thus, it becomes possible to suppress deterioration in uniformity of the thin film in a wafer plane, which may occur as the integrated usage of the target increases.

A method of fabricating a semiconductor device is disclosed. The method includes the steps of forming recesses in a semiconductor substrate; epitaxial growing a first SiGe seed layer with constant Ge content in the recesses; epitaxial growing a second SiGe layer with a constant Ge content higher than the Ge content of first SiGe seed layer on the first SiGe seed layer; epitaxial growing a third SiGe layer with a constant Ge content lower than the Ge content of the second SiGe layer; and forming a cap layer on the third SiGe layer.

A semiconductor structure is disclosed. The semiconductor structure includes: a substrate of a first conductivity; a first region of the first conductivity formed in the substrate; a second region of the first conductivity formed in the first region, wherein the second region has a higher doping density than the first region; a source region of a second conductivity formed in the second region; a drain region of the second conductivity formed in the substrate; a pickup region of the first conductivity formed in the second region and adjacent to the source region; and a resist protective oxide (RPO) layer formed on a top surface of the second region. An associated fabricating method is also disclosed.