Abstract: By providing a hard mask layer stack including at least three different layers for patterning a gate electrode structure, constraints demanded by sophisticated lithography, as well as cap layer integrity, in a subsequent selective epitaxial growth process may be accomplished, thereby providing the potential for further device scaling of transistor devices requiring raised drain and source regions.

Abstract: Methods of preparing conductive regions such as source/drain regions for silicidation procedures, has been developed. The methods feature removal of native oxide as well as removal of deposited arsenic based defects from conductive surfaces prior to deposition of a metal component of subsequently formed metal silicide regions. Arsenic ions implanted for N type source/drain regions are also implanted into insulator regions such as insulator filled shallow trench isolation regions. A hydrofluoric acid cycle used as a component of the pre-silicidation preparation procedure can release arsenic from the shallow trench isolation regions in the form of arsenic based defects, which in turn can re-deposit on the surface of source/drain region. Therefore pre-silicidation preparation treatments described in this invention feature removal of both native oxide and arsenic based defects from conductive surfaces prior to metal silicide formation.

Abstract: A method for forming silicide includes the steps of: forming a nickel film on a silicon layer (or a silicon substrate); introducing nitrogen into at least one of the nickel film and the interface between the nickel film and the silicon layer (or the silicon substrate); and after the introduction of the nitrogen, applying heat treatment to the nickel film and the silicon layer (or the silicon substrate) under predetermined conditions to form a nickel disilicide layer.

Abstract: In a method for manufacturing a semiconductor device, gate insulation films and gate electrodes are first formed on a substrate. An impurity is implanted into each gate electrode. Next, a first heat treatment is performed to the substrate for diffusing the impurity in the gate electrodes. After the heat treatment, a second heat treatment is performed for releasing stress generated in the substrate in the first heat-treatment. Thereafter, an impurity is implanted into an area to become an implanted region of the substrate, using the gate electrodes as masks, and a third heat treatment is performed for activating the impurity implanted.

Abstract: Raised Si/SiGe source and drain regions include epitaxially grown silicon on SiGe sidewalls. The epi silicon prevents adverse effects of Ge during silicidation, including Ge out diffusion and silicide line breakage. The Si also increases the active area.

Abstract: According to one embodiment of the present invention, a method of forming a semiconductor device includes forming a gate stack on an outer surface of a semiconductor body. First and second sidewall bodies are formed on opposing sides of the gate stack. A first recess is formed in an outer surface of the gate stack, and a first dopant is implanted into the gate stack after the first recess is formed. The first dopant diffuses inwardly from the outer surface of the gate stack that defines the first recess. The first dopant diffuses toward an interface between the gate stack and the semiconductor body. The first recess increases the concentration of the first dopant at the interface.

Abstract: A field-effect transistor has a channel region in a bulk semiconductor substrate, a first source/drain region on a first side of the channel region, a second source/drain region on a second side of the channel region, and an extension of epitaxial monocrystalline material formed on the bulk semiconductor substrate so as to extend away from each side of the channel region.

Abstract: A semiconductor device comprises a device isolation layer disposed in a portion of a substrate of first conductivity type. An outline of the device isolation layer defines an active region of the substrate. An impurity diffused region of second conductivity type may be formed in a portion of the active region; and a silicide layer may be formed to cover the impurity diffused region of second conductivity type. The device isolation layer may include a recess formed therein to expose a portion of the substrate of first conductivity type adjacent to the impurity diffused region of second conductivity type. The silicide layer that is formed to cover the impurity diffused layer of second conductivity type may extend over and against the exposed region of the substrate of first conductivity type that was exposed by the recess of the device isolation layer.

Abstract: Embodiments of the invention provide a transistor with stepped source and drain regions. The stepped regions may provide significant strain in a channel region while minimizing current leakage. The stepped regions may be formed by forming two recesses in a substrate to result in a stepped recess, and forming the source/drain regions in the recesses.