Abstract: Integrated circuit structures having source or drain structures with vertical trenches are described. In an example, an integrated circuit structure includes a fin having a lower fin portion and an upper fin portion. A gate stack is over the upper fin portion of the fin, the gate stack having a first side opposite a second side. A first source or drain structure includes an epitaxial structure embedded in the fin at the first side of the gate stack. A second source or drain structure includes an epitaxial structure embedded in the fin at the second side of the gate stack. The epitaxial structures of the first and second source or drain structures have a vertical trench centered therein. The first and second source or drain structures include silicon and a Group V dopant impurity.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device having a channel area including a channel III-V material, and a source area including a first portion and a second portion of the source area. The first portion of the source area includes a first III-V material, and the second portion of the source area includes a second III-V material. The channel III-V material, the first III-V material and the second III-V material may have a same lattice constant. Moreover, the first III-V material has a first bandgap, and the second III-V material has a second bandgap, the channel III-V material has a channel III-V material bandgap, where the channel material bandgap, the second bandgap, and the first bandgap form a monotonic sequence of bandgaps. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. A semiconductor device may include isolation areas above a substrate to form a trench between the isolation areas. A first buffer layer is over the substrate, in contact with the substrate, and within the trench. A second buffer layer is within the trench over the first buffer layer, and in contact with the first buffer layer. A channel area is above the first buffer layer, above a portion of the second buffer layer that are below a source area or a drain area, and without being vertically above a portion of the second buffer layer. In addition, the source area or the drain area is above the second buffer layer, in contact with the second buffer layer, and adjacent to the channel area. Other embodiments may be described and/or claimed.

Abstract: An integrated circuit (IC) structure, an IC device, an IC device assembly, and a method of forming the same. The IC structure includes a transistor device on a substrate comprising: a gate structure including a metal, the gate structure on a channel structure; a source structure in a first trench at a first side of the gate structure; a drain structure in a second trench at a second side of the gate structure; a capping layer on individual ones of the source structure and of the drain structure. The capping layer comprising a semiconductor material of a same group as a semiconductor material of a corresponding one of the source structure or of the drain structure, wherein an isotope of a p-type dopant in the capping layer represents an atomic percentage of at least about 95% of a p-type isotope content of the capping layer; and metal contact structures coupled to respective ones of the source structure and of the drain structure.

Abstract: In one embodiment, a transistor includes a substrate, a buffer layer on the substrate a channel layer on the buffer layer, and one or more polarization layers on the channel layer. The one or more polarization layers include a group III-N material comprising a first group III constituent and a second group III constituent. The transistor further includes a plurality of p-type doped layers on the one or more polarization layers. Each of the plurality of p-type doped layers includes a first p-type dopant and the III-N material, wherein each successive layer of the first p-type doped layers has a lower proportion of the first group III constituent to the second group III constituent relative to a layer below it. The transistor also includes a p-type doped layer on the plurality of p-type doped layers comprising a second p-type dopant and a group III-N material.

Abstract: In one embodiment, a transistor is formed by a process comprising forming a buffer layer on a substrate, the buffer layer comprising a first group III-nitride (III-N) material (e.g., AlGaN), forming a channel layer on the buffer layer, the channel layer comprising a second III-N material (e.g., GaN), forming a polarization layer on the channel layer, the polarization layer comprising a third III-N material (e.g., AlGaN), flowing a p-type dopant precursor compound (e.g., Cp2Mg) after forming the polarization layer, forming a p-type doped layer (e.g., p-GaN) on the polarization layer, the p-type doped layer comprising a p-type dopant (e.g., Mg) and a fourth III-N material (e.g., GaN), forming a source region adjacent one end of the channel layer, and forming a drain region adjacent another end of the channel layer.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device including a substrate and an insulator layer above the substrate. A channel area may include an III-V material relaxed grown on the insulator layer. A source area may be above the insulator layer, in contact with the insulator layer, and adjacent to a first end of the channel area. A drain area may be above the insulator layer, in contact with the insulator layer, and adjacent to a second end of the channel area that is opposite to the first end of the channel area. The source area or the drain area may include one or more seed components including a seed material with free surface. Other embodiments may be described and/or claimed.

Abstract: III-N e-mode high electron mobility transistors (HEMTs) including a dopant diffusion spacer between an impurity-doped III-N material layer and a III-N polarization layer of the HEMT material stack. The spacer may be a substantially undoped III-N material, such as GaN. With the diffusion spacer, P-type impurities within the pGaN are setback from the polarization layer sufficiently to avoid significant levels of P-type impurities from entering the III-N material interface where the 2DEG resides. With the diffusion spacer, clustering of impurities near the 2DEG may be avoided and a III-N e-mode HEMT may achieve higher drive currents.

Abstract: Techniques and mechanisms for providing functionality of a non-planar device which includes a semiconductor body disposed on a dielectric layer and over an underlying subfin region. In an embodiment, the dielectric layer is disposed between, and adjoins each of, a first semiconductor material of the subfin region and a second semiconductor material of semiconductor body. The dielectric layer is an artefact of fabrication processing wherein an epitaxy of the semiconductor body is grown horizontally along a length of the subfin region. During such epitaxial growth, the dielectric layer prevents vertical growth of the second semiconductor material from the subfin region. Moreover, at least a portion of a dummy gate determines a shape of the semiconductor body. In another embodiment, formation of the semiconductor body is preceded by an etching to remove a section of a fin portion which is disposed over the subfin region.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device having a channel area including a channel III-V material, and a source area including a first portion and a second portion of the source area. The first portion of the source area includes a first III-V material, and the second portion of the source area includes a second III-V material. The channel III-V material, the first III-V material and the second III-V material may have a same lattice constant. Moreover, the first III-V material has a first bandgap, and the second III-V material has a second bandgap, the channel III-V material has a channel III-V material bandgap, where the channel material bandgap, the second bandgap, and the first bandgap form a monotonic sequence of bandgaps. Other embodiments may be described and/or claimed.

Abstract: An integrated circuit with at least one transistor is formed using a buffer structure on the substrate. The buffer structure includes one or more layers of buffer material and comprises indium, gallium, and phosphorous. A ratio of indium to gallium in the buffer structure increases from a lower value to a higher value such that the buffer structure has small changes in lattice constant to control relaxation and defects. A source and a drain are on top of the buffer structure and a body of Group III-V semiconductor material extends between and connects the source and the drain. A gate structure wrapped around the body, the gate structure including a gate electrode and a gate dielectric, wherein the gate dielectric is between the body and the gate electrode.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device having a channel area including a channel III-V material, and a source area including a first portion and a second portion of the source area. The first portion of the source area includes a first III-V material, and the second portion of the source area includes a second III-V material. The channel III-V material, the first III-V material and the second III-V material may have a same lattice constant. Moreover, the first III-V material has a first bandgap, and the second III-V material has a second bandgap, the channel III-V material has a channel III-V material bandgap, where the channel material bandgap, the second bandgap, and the first bandgap form a monotonic sequence of bandgaps. Other embodiments may be described and/or claimed.

Abstract: Integrated circuit structures having source or drain structures with vertical trenches are described. In an example, an integrated circuit structure includes a fin having a lower fin portion and an upper fin portion. A gate stack is over the upper fin portion of the fin, the gate stack having a first side opposite a second side. A first source or drain structure includes an epitaxial structure embedded in the fin at the first side of the gate stack. A second source or drain structure includes an epitaxial structure embedded in the fin at the second side of the gate stack. The epitaxial structures of the first and second source or drain structures have a vertical trench centered therein. The first and second source or drain structures include silicon and a Group V dopant impurity.

Abstract: Techniques and mechanisms for providing functionality of a non-planar device which includes a semiconductor body disposed on a dielectric layer and over an underlying subfin region. In an embodiment, the dielectric layer is disposed between, and adjoins each of, a first semiconductor material of the subfin region and a second semiconductor material of semiconductor body. The dielectric layer is an artefact of fabrication processing wherein an epitaxy of the semiconductor body is grown horizontally along a length of the subfin region. During such epitaxial growth, the dielectric layer prevents vertical growth of the second semiconductor material from the subfin region. Moreover, at least a portion of a dummy gate determines a shape of the semiconductor body. In another embodiment, formation of the semiconductor body is preceded by an etching to remove a section of a fin portion which is disposed over the subfin region.

Abstract: An integrated circuit with at least one transistor is formed using a buffer structure on the substrate. The buffer structure includes one or more layers of buffer material and comprises indium, gallium, and phosphorous. A ratio of indium to gallium in the buffer structure increases from a lower value to a higher value such that the buffer structure has small changes in lattice constant to control relaxation and defects. A source and a drain are on top of the buffer structure and a body of Group III-V semiconductor material extends between and connects the source and the drain. A gate structure wrapped around the body, the gate structure including a gate electrode and a gate dielectric, wherein the gate dielectric is between the body and the gate electrode.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device including a substrate with a surface that is substantially flat. A channel area including an III-V compound may be above the substrate, where the channel area is an epitaxial layer directly in contact with the surface of the substrate. A gate dielectric layer is adjacent to the channel area and in direct contact with the channel area, while a gate electrode is adjacent to the gate dielectric layer. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device including a substrate and an insulator layer above the substrate. A channel area may include an III-V material relaxed grown on the insulator layer. A source area may be above the insulator layer, in contact with the insulator layer, and adjacent to a first end of the channel area. A drain area may be above the insulator layer, in contact with the insulator layer, and adjacent to a second end of the channel area that is opposite to the first end of the channel area. The source area or the drain area may include one or more seed components including a seed material with free surface. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. A semiconductor device may include isolation areas above a substrate to form a trench between the isolation areas. A first buffer layer is over the substrate, in contact with the substrate, and within the trench. A second buffer layer is within the trench over the first buffer layer, and in contact with the first buffer layer. A channel area is above the first buffer layer, above a portion of the second buffer layer that are below a source area or a drain area, and without being vertically above a portion of the second buffer layer. In addition, the source area or the drain area is above the second buffer layer, in contact with the second buffer layer, and adjacent to the channel area. Other embodiments may be described and/or claimed.

Abstract: Embodiments herein describe techniques, systems, and method for a semiconductor device. Embodiments herein may present a semiconductor device having a channel area including a channel III-V material, and a source area including a first portion and a second portion of the source area. The first portion of the source area includes a first III-V material, and the second portion of the source area includes a second III-V material. The channel III-V material, the first III-V material and the second III-V material may have a same lattice constant. Moreover, the first III-V material has a first bandgap, and the second III-V material has a second bandgap, the channel III-V material has a channel III-V material bandgap, where the channel material bandgap, the second bandgap, and the first bandgap form a monotonic sequence of bandgaps. Other embodiments may be described and/or claimed.