Abstract: An apparatus including a non-planar body on a substrate, the body including a channel on a blocking material, and a gate stack on the body, the gate stack including a first gate electrode material including a first work function disposed on the channel material and a second gate electrode material including a second work function different from the first work function disposed on the channel material and on the blocking material. A method including forming a non-planar body on a substrate, the non-planar body including a channel on a blocking material, and forming a gate stack on the body, the gate stack including a first gate electrode material including a first work function disposed on the channel and a second gate electrode material including a second work function different from the first work function disposed on the channel and on the blocking material.

Abstract: Monolithic FETs including a channel region of a first semiconductor material disposed over a substrate. While a mask, such as a gate stack or sacrificial gate stack, is covering the channel region, an impurity-doped compositionally graded semiconductor is grown, for example on at least a drain end of the channel region to introduce a carrier-blocking conduction band offset and/or a wider band gap within the drain region of the transistor. In some embodiments, the compositional grade induces a carrier-blocking band offset of at least 0.25 eV. The wider band gap and/or band offset contributes to a reduced gate induced drain leakage (GIDL). The impurity-doped semiconductor may be compositionally graded back down from the retrograded composition to a suitably narrow band gap material providing good ohmic contact. In some embodiments, the impurity-doped compositionally graded semiconductor growth is integrated into a gate-last, source/drain regrowth finFET fabrication process.

Abstract: Techniques are disclosed for resistance reduction in p-MOS transistors having epitaxially grown boron-doped silicon germanium (SiGe:B) S/D regions. The techniques can include growing one or more interface layers between a silicon (Si) channel region of the transistor and the SiGe:B replacement S/D regions. The one or more interface layers may include: a single layer of boron-doped Si (Si:B); a single layer of SiGe:B, where the Ge content in the interface layer is less than that in the resulting SiGe:B S/D regions; a graded layer of SiGe:B, where the Ge content in the alloy starts at a low percentage (or 0%) and is increased to a higher percentage; or multiple stepped layers of SiGe:B, where the Ge content in the alloy starts at a low percentage (or 0%) and is increased to a higher percentage at each step. Inclusion of the interface layer(s) reduces resistance for on-state current flow.