Abstract: Embodiments include a first nanowire transistor having a first source and a first drain with a first channel in between, where the first channel includes a first III-V alloy. A first gate stack is around the first channel, where a portion of the first gate stack is between the first channel and a substrate. The first gate stack includes a gate electrode metal in contact with a gate dielectric. A second nanowire transistor is on the substrate, having a second source and a second drain with a second channel therebetween, the second channel including a second III-V alloy. A second gate stack is around the second channel, where an intervening material is between the second gate stack and the substrate, the intervening material including a third III-V alloy. The second gate stack includes the gate electrode metal in contact with the gate dielectric.

Abstract: A transistor includes a body of semiconductor material with a gate structure in contact with a portion of the body. A source region contacts the body adjacent the gate structure and a drain region contacts the body adjacent the gate structure such that the portion of the body is between the source region and the drain region. A first isolation region is under the source region and has a top surface in contact with a bottom surface of the source region. A second isolation region is under the drain region and has a top surface in contact with a bottom surface of the drain region. Depending on the transistor configuration, a major portion of the inner-facing sidewalls of the first and second isolation regions contact respective sidewalls of either a subfin structure (e.g., FinFET transistor configurations) or a lower portion of a gate structure (e.g., gate-all-around transistor configuration).

Abstract: Techniques are disclosed for customization of fin-based transistor devices to provide a diverse range of channel configurations and/or material systems, and within the same integrated circuit die. Sacrificial fins are removed via wet and/or dry etch chemistries configured to provide trench bottoms that are non-faceted and have no or otherwise low-ion damage. The trench is then filled with desired semiconductor material. A trench bottom having low-ion damage and non-faceted morphology encourages a defect-free or low defect interface between the substrate and the replacement material. In an embodiment, each of a first set of the sacrificial silicon fins is recessed and replaced with a p-type material, and each of a second set of the sacrificial fins is recessed and replaced with an n-type material. Another embodiment may include a combination of native fins (e.g., Si) and replacement fins (e.g., SiGe). Another embodiment may include replacement fins all of the same configuration.

Abstract: Integrated circuit transistor structures are disclosed that reduce band-to-band tunneling between the channel region and the source/drain region of the transistor, without adversely increasing the extrinsic resistance of the device. In an example embodiment, the structure includes one or more spacer configured to separate the source and/or drain from the channel region. The spacer(s) regions comprise a semiconductor material that provides a relatively high conduction band offset (CBO) and a relatively low valence band offset (VBO) for PMOS devices, and a relatively high VBO and a relatively low CBO for NMOS devices. In some cases, the spacer includes silicon, germanium, and carbon (e.g., for devices having germanium channel). The proportions may be at least 10% silicon by atomic percentage, at least 85% germanium by atomic percentage, and at least 1% carbon by atomic percentage. Other embodiments are implemented with III-V materials.

Abstract: Techniques are disclosed for forming transistors including one or more group III-V semiconductor material nanowires using sacrificial group IV semiconductor material layers. In some cases, the transistors may include a gate-all-around (GAA) configuration. In some cases, the techniques may include forming a replacement fin stack that includes group III-V material layer (such as indium gallium arsenide, indium arsenide, or indium antimonide) formed on a group IV material buffer layer (such as silicon, germanium, or silicon germanium), such that the group IV buffer layer can be later removed using a selective etch process to leave the group III-V material for use as a nanowire in a transistor channel. In some such cases, the group III-V material layer may be grown pseudomorphically to the underlying group IV material, so as to not form misfit dislocations. The techniques may be used to form transistors including any number of nanowires.

Abstract: Embodiments of the invention include a semiconductor structure and a method of making such a structure. In one embodiment, the semiconductor structure comprises a first fin and a second fin formed over a substrate. The first fin may comprise a first semiconductor material and the second fin may comprise a second semiconductor material. In an embodiment, a first cage structure is formed adjacent to the first fin, and a second cage structure is formed adjacent to the second fin. Additionally, embodiments may include a first gate electrode formed over the first fin, where the first cage structure directly contacts the first gate electrode, and a second gate electrode formed over the second fin, where the second cage structure directly contacts the second gate electrode.

Abstract: Integrated circuit transistor structures and processes are disclosed that reduce n-type dopant diffusion, such as phosphorous or arsenic, from the source region and the drain region of a germanium n-MOS device into adjacent channel regions during fabrication. The n-MOS transistor device may include at least 70% germanium (Ge) by atomic percentage. In an example embodiment, source and drain regions of the transistor are formed using a low temperature, non-selective deposition process of n-type doped material. In some embodiments, the low temperature deposition process is performed in the range of 450 to 600 degrees C. The resulting structure includes a layer of doped mono-crystyalline silicon (Si), or silicon germanium (SiGe), on the source/drain regions. The structure also includes a layer of doped amorphous Si:P (or SiGe:P) on the surfaces of a shallow trench isolation (STI) region and the surfaces of contact trench sidewalls.

Abstract: The present disclosure provides systems and methods for a layered substrate. A layered substrate may include a core comprising graphite. The layered substrate may also include a coating layer comprising a coating material that surrounds the core, wherein the coating material has a melting point that is greater than a melting point of silicon.

Abstract: Techniques are disclosed for backside contact resistance reduction for semiconductor devices with metallization on both sides (MOBS). In some embodiments, the techniques described herein provide methods to recover low contact resistance that would otherwise be present with making backside contacts, thereby reducing or eliminating parasitic external resistance that degrades transistor performance. In some embodiments, the techniques include adding an epitaxial deposition of very highly doped crystalline semiconductor material in backside contact trenches to provide enhanced ohmic contact properties. In some cases, a backside source/drain (S/D) etch-stop layer may be formed below the replacement S/D regions of the one or more transistors formed on the transfer wafer (during frontside processing), such that when backside contact trenches are being formed, the backside S/D etch-stop layer may help stop the backside contact etch process before consuming a portion or all of the S/D material.

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: Techniques are described for forming strained fins for co-integrated n-MOS and p-MOS devices that include one or more defect trapping layers that prevent defects from migrating into channel regions of the various co-integrated n-MOS and p-MOS devices. A defect trapping layer can include one or more patterned dielectric layers that define aspect ratio trapping trenches. An alternative defect trapping layer can include a superlattice structure of alternating, epitaxially mismatched materials that provides an energetic barrier to the migration of defect. Regardless, the defect trapping layer can prevent dislocations, stacking faults, and other crystallographic defects present in a relaxed silicon germanium layer from migrating into strained n-MOS and p-MOS channel regions grown thereon.

Abstract: Epitaxial oxide plugs are described for imposing strain on a channel region of a proximate channel region of a transistor. The oxide plugs form epitaxial and coherent contact with one or more source and drain regions adjacent to the strained channel region. The epitaxial oxide plugs can be used to either impart strain to an otherwise unstrained channel region (e.g., for a semiconductor body that is unstrained relative to an underlying buffer layer), or to restore, maintain, or increase strain within a channel region of a previously strained semiconductor body. The epitaxial crystalline oxide plugs have a perovskite crystal structure in some embodiments.

Abstract: Techniques are disclosed for forming transistor devices having reduced parasitic contact resistance relative to conventional devices. The techniques can be implemented, for example, using a standard contact stack such as a series of metals on, for example, silicon or silicon germanium (SiGe) source/drain regions. In accordance with one example such embodiment, an intermediate boron doped germanium layer is provided between the source/drain and contact metals to significantly reduce contact resistance. Numerous transistor configurations and suitable fabrication processes will be apparent in light of this disclosure, including both planar and non-planar transistor structures (e.g., FinFETs), as well as strained and unstrained channel structures. Graded buffering can be used to reduce misfit dislocation. The techniques are particularly well-suited for implementing p-type devices, but can be used for n-type devices if so desired.

Abstract: Techniques are disclosed for forming germanium (Ge)-rich channel transistors including one or more dopant diffusion barrier elements. The introduction of one or more dopant diffusion elements into at least a portion of a given source/drain (S/D) region helps inhibit the undesired diffusion of dopant (e.g., B, P, or As) into the adjacent Ge-rich channel region. In some embodiments, the elements that may be included in a given S/D region to help prevent the undesired dopant diffusion include at least one of tin and relatively high silicon. Further, in some such embodiments, carbon may also be included to help prevent the undesired dopant diffusion. In some embodiments, the one or more dopant diffusion barrier elements may be included in an interfacial layer between a given S/D region and the Ge-rich channel region and/or throughout at least a majority of a given S/D region. Numerous embodiments, configurations, and variations will be apparent.

Abstract: Techniques are disclosed for deuterium-based passivation of non-planar transistor interfaces. In some cases, the techniques can include annealing an integrated circuit structure including the transistor in a range of temperatures, pressures, and times in an atmosphere that includes deuterium. In some instances, the anneal process may be performed at pressures of up to 50 atmospheres to increase the amount of deuterium that penetrates the integrated circuit structure and reaches the interfaces to be passivated. Interfaces to be passivated may include, for example, an interface between the transistor conductive channel and bordering transistor gate dielectric and/or an interface between sub-channel semiconductor and bordering shallow trench isolation oxides.

Abstract: Disclosed herein are tri-gate and all-around-gate transistor arrangements, and related methods and devices. For example, in some embodiments, a transistor arrangement may include a channel material disposed over a substrate; a gate electrode of a first tri-gate or all-around-gate transistor, disposed over a first part of the channel material; and a gate electrode of a second tri-gate or all-around-gate transistor, disposed over a second part of the channel material. The transistor arrangement may further include a device isolation structure made of a fixed charge dielectric material disposed over a third part of the channel material, the third part being between the first part and the second part of the channel material.

Abstract: An apparatus is provided which comprises: a semiconductor region on a substrate, a gate stack on the semiconductor region, a source region comprising doped semiconductor material on the substrate adjacent a first side of the semiconductor region, a drain region comprising doped semiconductor material on the substrate adjacent a second side of the semiconductor region, a substantially conformal semiconductor layer over a surface of a recess in the source region, and a metal over the conformal layer substantially filling the recess in the source region. Other embodiments are also disclosed and claimed.

Abstract: Disclosed herein are integrated circuit (IC) contact structures, and related devices and methods. For example, in some embodiments, an IC contact structure may include an electrical element, a metal on the electrical element, and a semiconductor material on the metal. The metal may conductively couple the semiconductor material and the electrical element.

Abstract: A non-planar gate all-around device and method of fabrication thereby are described. In one embodiment, a multi-layer stack is formed by selectively depositing the entire epi-stack in an STI trench. The channel layer is grown pseudomorphically over a buffer layer. A cap layer is grown on top of the channel layer. In an embodiment, the height of the STI layer remains higher than the channel layer until the formation of the gate. A gate dielectric layer is formed on and all-around each channel nanowire. A gate electrode is formed on the gate dielectric layer and surrounding the channel nanowire.

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.