A semiconductor device includes a first active pattern having a first lower pattern and a first sheet pattern on the first lower pattern. First gate structures include a first gate electrode. A second active pattern includes a second lower pattern. A second sheet pattern is on the second lower pattern. Second gate structures include a second gate electrode that surrounds the second sheet pattern. A first source/drain recess is between adjacent first gate structures. A second source/drain recess is between adjacent second gate structures. A first source/drain pattern extends along the first source/drain recess. A first silicon germanium filling film is on the first silicon germanium liner. A second source/drain pattern includes a second silicon germanium liner extending along the second source/drain recess. A second silicon germanium filling film is on the second silicon germanium liner.

A tunneling field-effect transistor (TFET) device is disclosed. A frustoconical protrusion structure is disposed over the substrate and protrudes out of the plane of substrate. A drain region is disposed over the substrate adjacent to the frustoconical protrusion structure and extends to a bottom portion of the frustoconical protrusion structure as a raised drain region. A gate stack is disposed over the substrate. The gate stack has a planar portion, which is parallel to the surface of substrate and a gating surface, which wraps around a middle portion of the frustoconical protrusion structure, including overlapping with the raised drain region. An isolation dielectric layer is disposed between the planar portion of the gate stack and the drain region. A source region is disposed as a top portion of the frustoconical protrusion structure, including overlapping with a top portion of the gating surface of the gate stack.

A tunnel field-effect transistor and method fabricating the same are provided. The tunnel field-effect transistor includes a drain region, a source region with opposite conductive type to the drain region, a channel region disposed between the drain region and the source region, a metal gate layer disposed around the channel region, and a high-k dielectric layer disposed between the metal gate layer and the channel region.

A method for manufacturing a semiconductor device includes forming a source and region in a substrate. A core channel region is formed adjacent the source region. A barrier layer is formed adjacent the core channel region. A drain region is formed in the substrate such that the barrier layer is between the core channel region and the drain region. A first portion of a shell is formed along the core channel region. A second portion of the shell is formed along the barrier layer. The second portion of the shell includes a different material than the first portion of the shell.

A method for producing a tunnel field-effect transistor (TFET) having a source region, a channel region, and a drain region includes arranging an epitaxial layer on a silicon substrate; applying a gate arrangement having a gate electrode to the epitaxial layer, a gate dielectric being arranged between the gate electrode and the silicon substrate; forming a doped pocket region below the gate dielectric adjacent to the source region; forming a selectively silicidated region in the source region, the selectively silicidated region extending as far as to below a gate; and forming a counter-doped region doped in an opposite way to the pocket region adjacent to the pocket region in the source region by diffusion of dopants out of the silicidated region, as a result of which a tunnel junction parallel to the electric field lines of the gate electrode is achieved.

A semiconductor device is provided that includes a first of a source region and a drain region comprised of a first semiconductor material, wherein an etch stop layer of a second semiconductor material present within the first of the source region and the drain region. A channel semiconductor material is present atop the first of the source region and the drain region. A second of the source and the drain region is present atop the channel semiconductor material. The semiconductor device may be a vertically orientated fin field effect transistor or a vertically orientated tunnel field effect transistor.

Techniques are disclosed for providing an integrated circuit structure having NMOS transistors including an arsenic-doped interface layer between epitaxially grown source/drain regions and a channel region. The arsenic-doped interface layer may include, for example, arsenic-doped silicon (Si:As) having arsenic concentrations in a range of about 1E20 atoms per cm.sup.3 to about 5E21 atoms per cm.sup.3. The interface layer may have a relatively uniform thickness in a range of about 0.5 nm to full fill where the entire source/drain region is composed of the Si:As. In cases where the arsenic-doped interface layer only partially fills the source/drain regions, another n-type doped semiconductor material can fill remainder (e.g., phosphorus-doped III-V compound or silicon). The use of a layer having a high arsenic concentration can provide improved NMOS performance in the form of abrupt junctions in the source/drain regions and highly conductive source/drain regions with negligible diffusion of arsenic into the channel region.

A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate; forming a fin-shaped structure on the substrate; forming a shallow trench isolation (STI) around the fin-shaped structure; forming a gate structure on the fin-shaped structure and the STI and the fin-shaped structure directly under the gate structure includes a first epitaxial layer; forming a source region having first conductive type adjacent to one side of the gate structure; and forming a first drain region having a second conductive type adjacent to another side of the gate structure.

A method for fabrication a field-effect-transistor includes forming a plurality of fin structures on a substrate, forming a gate structure across each fin structure and covering a portion of top and sidewall surfaces of the fin structure, forming a first doped layer, made of a first semiconductor material and doped with first doping ions, in each fin structure on one side of the corresponding gate structure, and forming a second doped layer, made of a second semiconductor material, doped with second doping ions, and having doping properties different from the first doped layer, in each fin structure on another side of the corresponding gate structure.

A method can be used to make a semiconductor device. A number of projecting regions are formed over a first semiconductor layer that has a first conductivity type. The first semiconductor layer is located on an insulating layer that overlies a semiconductor substrate. The projecting regions are spaced apart from each other. Using the projecting regions as an implantation mask, dopants having a second conductivity type are implanted into the first semiconductor layer, so as to form a sequence of PN junctions forming diodes in the first semiconductor layer. The diodes vertically extend from an upper surface of the first semiconductor layer to the insulating layer.