Abstract: Techniques are disclosed for forming group III-V material transistors employing nitride-based dopant diffusion barrier layers. The techniques can include growing the dilute nitride-based barrier layer as a relatively thin layer of III-V material in the sub-channel (or sub-fin) region of a transistor, near the substrate/III-V material interface, for example. Such a nitride-based barrier layer can be used to trap atoms from the substrate at vacancy sites within the III-V material. Therefore, the barrier layer can arrest substrate atoms from diffusing in an undesired manner by protecting the sub-channel layer from being unintentionally doped due to subsequent processing in the transistor fabrication. In addition, by forming the barrier layer pseudomorphically, the lattice mismatch of the barrier layer with the sub-channel layer in the heterojunction stack becomes insignificant. In some embodiments, the group III-V alloyed with nitrogen (N) material may include an N concentration of less than 5, 2, or 1.

Abstract: Semiconductor devices, computing devices, and related methods are disclosed herein. A semiconductor device includes a seed material, an epitaxial material in contact with the seed material, and at least one quantum region including an elastic stiffness that is greater than an elastic stiffness of the epitaxial material. The epitaxial material has lattice parameters that are different from lattice parameters of the seed material by at least a threshold amount. Lattice parameters of the quantum region are within the threshold amount of the lattice parameters of the epitaxial material. A method includes disposing an epitaxial material on a seed material, disposing a quantum region on the epitaxial material, and disposing the epitaxial material on the quantum region.

Abstract: An integrated circuit apparatus including a body; a transistor formed on a first portion of the body, the transistor including a gate stack and a channel defined in the body between a source and a drain; and a plug formed in a second portion of the body, the plug including a material operable to impart a stress on the first portion of the body. A method of forming an integrated circuit device including forming a transistor body on a substrate; forming a transistor device in a first portion of the transistor body on a first side of the substrate; and dividing the transistor body into at least the first portion and a second portion with a plug in the transistor body, the plug including a material operable to impart a stress on the first portion of the body, wherein the material is introduced through a second side of the substrate.

Abstract: Embodiments are generally directed to a semiconductor device with released source and drain. An embodiment of a method includes etching a buffer layer of a semiconductor device to form a gate trench under a gate channel portion of a channel layer of the device; filling the gate trench with an oxide material to form an oxide isolation layer; etching one or more source/drain contact trenches in an interlayer dielectric (ILD) layer for source and drain regions of the device; etching the oxide isolation layer within the one or more source/drain contact trenches to form one or more cavities under a source/drain channel in the source and drain regions, wherein the etching of each contact trench is to expose all sides of the source/drain channel; and depositing contact metal in the one or more contact trenches, including depositing the contact metal in the cavities under the source/drain channel.

Abstract: An apparatus including a transistor device including a body including a channel region between a source region and a drain region; and a gate stack on the body in the channel region, wherein at least one of the source region and the drain region of the body include a contact surface between opposing sidewalls and the contact surface includes a profile such that a height dimension of the contact surface is greater at the sidewalls than at a point between the sidewalls. A method including forming a transistor device body on a circuit substrate, the transistor device body dimension defining a channel region between a source region and a drain region; forming a groove in the body in at least one of the source region and the drain region; and forming a gate stack on the body in the channel region.

Abstract: An apparatus is described. The apparatus includes a FINFET device having a channel. The channel is composed of a first semiconductor material that is epitaxially grown on a subfin structure beneath the channel. The subfin structure is composed of a second semiconductor material that is different than the first semiconductor material. The subfm structure is epitaxially grown on a substrate composed of a third semiconductor material that is different than the first and second semiconductor materials. The subfin structure has a doped region to substantially impede leakage currents between the channel and the substrate.

Abstract: An apparatus including a transistor device on a substrate including an intrinsic layer including a channel; a source and a drain on opposite sides of the channel; and a diffusion barrier between the intrinsic layer and each of the source and the drain, the diffusion barrier including a conduction band energy that is less than a conduction band energy of the channel and greater than a material of the source and drain. A method including defining an area of an intrinsic layer on a substrate for a channel of a transistor device; forming a diffusion barrier layer in an area defined for a source and a drain; and forming a source on the diffusion barrier layer in the area defined for the source and forming a drain in the area defined for the drain.

Abstract: Monolithic FETs including a channel region in a first semiconductor material disposed over a substrate. While a mask, such as a gate stack or sacrificial gate stack, is covering a channel region, a semiconductor spacer of a semiconductor material with a band offset relative to the channel material is grown, for example on at least a drain end of the channel region to introduce at least one charge carrier-blocking band offset between the channel semiconductor and a drain region of a third III-V semiconductor material. In some N-type transistor embodiments, the carrier-blocking band offset is a conduction band offset of at least 0.1 eV. A wider band gap and/or a blocking conduction band offset may contribute to reduced gate induced drain leakage (GIDL). Source/drain regions couple electrically to the channel region through the semiconductor spacer, which may be substantially undoped (i.e. intrinsic) or doped.

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.