Abstract: Gate-all-around integrated circuit structures having confined epitaxial source or drain structures, are described. For example, an integrated circuit structure includes a plurality of nanowires above a sub-fin. A gate stack is over the plurality of nanowires and the sub-fin. Epitaxial source or drain structures are on opposite ends of the plurality of nanowires. The epitaxial source or drain structures comprise i) a first PMOS epitaxial (pEPI) region of germanium and boron, ii) a second pEPI region of silicon, germanium and boron on the first pEPI region at a contact location, iii) titanium silicide conductive contact material on the second pEPI region.

Abstract: Gate-all-around integrated circuit structures having raised wall structures for epitaxial source or drain region confinement are described. For example, an integrated circuit structure includes a first vertical arrangement of nanowires and a second vertical arrangement of nanowires. A gate stack is over the first and second vertical arrangements of nanowires. First epitaxial source or drain structures are at ends of the first vertical arrangement of nanowires. Second epitaxial source or drain structures are at ends of the second vertical arrangement of nanowires. An intervening dielectric structure is between neighboring ones of the first epitaxial source or drain structures and the second epitaxial source or drain structures. The intervening dielectric structure has a top surface above a top surface of the first and second vertical arrangements of nanowires.

Abstract: Fin smoothing, and integrated circuit structures resulting therefrom, are described. For example, an integrated circuit structure includes a semiconductor fin having a protruding fin portion above an isolation structure, the protruding fin portion having substantially vertical sidewalls. The semiconductor fin further includes a sub-fin portion within an opening in the isolation structure, the sub-fin portion having a different semiconductor material than the protruding fin portion. The sub-fin portion has a width greater than or less than a width of the protruding portion where the sub-fin portion meets the protruding portion. A gate stack is over and conformal with the protruding fin portion of the semiconductor fin. A first source or drain region at a first side of the gate stack, and a second source or drain region at a second side of the gate stack opposite the first side of the gate stack.

Abstract: Fabrication techniques for NMOS and PMOS nanowires leveraging an isolated process flow for NMOS and PMOS nanowires facilitates independent (decoupled) tuning/variation of the respective geometries (i.e., sizing) and chemical composition of NMOS and PMOS nanowires existing in the same process. These independently tunable degrees of freedom are achieved due to fabrication techniques disclosed herein, which enable the ability to individually adjust the width of NMOS and PMOS nanowires as well as the general composition of the material forming these nanowires independently of one another.

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 subfin 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: Techniques and methods related to strained NMOS and PMOS devices without relaxed substrates, systems incorporating such semiconductor devices, and methods therefor may include a semiconductor device that may have both n-type and p-type semiconductor bodies. Both types of semiconductor bodies may be formed from an initially strained semiconductor material such as silicon germanium. A silicon cladding layer may then be provided at least over or on the n-type semiconductor body. In one example, a lower portion of the semiconductor bodies is formed by a Si extension of the wafer or substrate. By one approach, an upper portion of the semiconductor bodies, formed of the strained SiGe, may be formed by blanket depositing the strained SiGe layer on the Si wafer, and then etching through the SiGe layer and into the Si wafer to form the semiconductor bodies or fins with the lower and upper portions.

Abstract: Techniques are disclosed for achieving multiple fin dimensions on a single die or semiconductor substrate. In some cases, multiple fin dimensions are achieved by lithographically defining (e.g., hardmasking and patterning) areas to be trimmed using a trim etch process, leaving the remainder of the die unaffected. In some such cases, the trim etch is performed on only the channel regions of the fins, when such channel regions are re-exposed during a replacement gate process. The trim etch may narrow the width of the fins being trimmed (or just the channel region of such fins) by 2-6 nm, for example. Alternatively, or in addition, the trim may reduce the height of the fins. The techniques can include any number of patterning and trimming processes to enable a variety of fin dimensions and/or fin channel dimensions on a given die, which may be useful for integrated circuit and system-on-chip (SOC) applications.

Abstract: Embodiments of the invention include nanowire and nanoribbon transistors and methods of forming such transistors. According to an embodiment, a method for forming a microelectronic device may include forming a multi-layer stack within a trench formed in a shallow trench isolation (STI) layer. The multi-layer stack may comprise at least a channel layer, a release layer formed below the channel layer, and a buffer layer formed below the channel layer. The STI layer may be recessed so that a top surface of the STI layer is below a top surface of the release layer. The exposed release layer from below the channel layer by selectively etching away the release layer relative to the channel layer.

Abstract: Techniques and mechanisms to impose stress on a transistor which includes a channel region and a source or drain region each in a fin structure. In an embodiment, a gate structure of the transistor extends over the fin structure, wherein a first spacer portion is at a sidewall of the gate structure and a second spacer portion adjoins the first spacer portion. Either or both of two features are present at or under respective bottom edges of the spacer portions. One of the features includes a line of discontinuity on the fin structure. The other feature includes a concentration of a dopant in the second spacer portion being greater than a concentration of the dopant in the source or drain region. In another embodiment, the fin structure is disposed on a buffer layer, wherein stress on the channel region is imposed at least in part with the buffer layer.

Abstract: Gate-all-around integrated circuit structures having confined epitaxial source or drain structures, are described. For example, an integrated circuit structure includes a plurality of nanowires above a sub-fin. A gate stack is over the plurality of nanowires and the sub-fin. Epitaxial source or drain structures are on opposite ends of the plurality of nanowires. The epitaxial source or drain structures comprise germanium and boron, and a protective layer comprises silicon, and germanium that at least partially covers the epitaxial source or drain structures. A conductive contact comprising titanium silicide is on the epitaxial source or drain structures.

Abstract: Gate-all-around integrated circuit structures having confined epitaxial source or drain structures, are described. For example, an integrated circuit structure includes a plurality of nanowires above a sub-fin. A gate stack is over the plurality of nanowires and the sub-fin. Epitaxial source or drain structures are on opposite ends of the plurality of nanowires. The epitaxial source or drain structures comprise i) a first PMOS epitaxial (pEPI) region of germanium and boron, ii) a second pEPI region of silicon, germanium and boron on the first pEPI region at a contact location, iii) a capping layer comprising silicon over the second pEPI region. A conductive contact material comprising titanium is on the capping layer.

Abstract: Gate-all-around integrated circuit structures having a doped subfin, and methods of fabricating gate-all-around integrated circuit structures having a doped subfin, are described. For example, an integrated circuit structure includes a subfin structure having well dopants. A vertical arrangement of horizontal semiconductor nanowires is over the subfin structure. A gate stack is surrounding a channel region of the vertical arrangement of horizontal semiconductor nanowires, the gate stack overlying the subfin structure. A pair of epitaxial source or drain structures is at first and second ends of the vertical arrangement of horizontal semiconductor nanowires.

Abstract: Integrated circuit structures having a dielectric gate wall and a dielectric gate plug, and methods of fabricating integrated circuit structures having a dielectric gate wall and a dielectric gate plug, are described. For example, an integrated circuit structure includes a sub-fin having a portion protruding above a shallow trench isolation (STI) structure. A plurality of horizontally stacked nanowires is over the sub-fin. A gate dielectric material layer is over the protruding portion of the sub-fin, over the STI structure, and surrounding the horizontally stacked nanowires. A conductive gate layer is over the gate dielectric material layer. A conductive gate fill material is over the conductive gate layer. A dielectric gate wall is laterally spaced apart from the sub-fin and the plurality of horizontally stacked nanowires, the dielectric gate wall on the STI structure. A dielectric gate plug is on the dielectric gate wall.

Abstract: Apparatus, system and method to provide switchable coils in a computing device, comprising: a plurality of electrically conductive coils to transfer electromagnetic energy; a sensor coupled to a processor, to select a coil from among the plurality of electrically conductive coils; a switch to energize the selected coil; and a switch controller coupled to the switch and to the processor. In some embodiments, the plurality of coils may comprise an inductive charging interface. Some embodiments may further include a communication interface between the processor to the plurality of electrically conductive coils, the plurality of coils comprising an interface for near-field communications (NFC). The antenna coils may be arranged to provide improved NFC coverage when the computing device is in a respective predetermined physical configuration. Sensors may be used to detect the configuration and switch NFC communications to use a preferred antenna coil for the detected configuration.

Abstract: Techniques are provided herein to form semiconductor devices having self-aligned gate cut structures. In an example, neighboring semiconductor devices each include a semiconductor region extending between a source region and a drain region, and a gate layer extending over the semiconductor regions of the neighboring semiconductor devices. A gate cut structure that includes a dielectric material interrupts the gate layer between the neighboring semiconductor devices. Due to the process of forming the gate cut structure, the distance between the gate cut structure and the semiconductor region of one of the neighboring semiconductor devices is substantially the same as (e.g., within 1.5 nm of) the distance between the gate cut structure and the semiconductor region of the other one of the neighboring semiconductor devices.

Abstract: Particular embodiments described herein provide for an electronic device that can include a nanowire channel. The nanowire channel can include nanowires and the nanowires can be about fifteen (15) or less angstroms apart. The nanowire channel can include more than ten (10) nanowires and can be created from a MXene material.

Abstract: Techniques and methods related to strained NMOS and PMOS devices without relaxed substrates, systems incorporating such semiconductor devices, and methods therefor may include a semiconductor device that may have both n-type and p-type semiconductor bodies. Both types of semiconductor bodies may be formed from an initially strained semiconductor material such as silicon germanium. A silicon cladding layer may then be provided at least over or on the n-type semiconductor body. In one example, a lower portion of the semiconductor bodies is formed by a Si extension of the wafer or substrate. By one approach, an upper portion of the semiconductor bodies, formed of the strained SiGe, may be formed by blanket depositing the strained SiGe layer on the Si wafer, and then etching through the SiGe layer and into the Si wafer to form the semiconductor bodies or fins with the lower and upper portions.

Abstract: An integrated circuit structure includes: a semiconductor nanowire extending in a length direction and including a body portion; a gate dielectric surrounding the body portion; a gate electrode insulated from the body portion by the gate dielectric; a semiconductor source portion adjacent to a first side of the body portion; and a semiconductor drain portion adjacent to a second side of the body portion opposite the first side, the narrowest dimension of the second side of the body portion being smaller than the narrowest dimension of the first side. In an embodiment, the nanowire has a conical tapering. In an embodiment, the gate electrode extends along the body portion in the length direction to the source portion, but not to the drain portion. In an embodiment, the drain portion at the second side of the body portion has a lower dopant concentration than the source portion at the first side.

Abstract: Transistors having a plurality of channel semiconductor structures, such as fins, over a dielectric material. A source and drain are coupled to opposite ends of the structures and a gate stack intersects the plurality of structures between the source and drain. Lateral epitaxial overgrowth (LEO) may be employed to form a super-lattice of a desired periodicity from a sidewall of a fin template structure that is within a trench and extends from the dielectric material. Following LEO, the super-lattice structure may be planarized with surrounding dielectric material to expose a top of the super-lattice layers. Alternating ones of the super-lattice layers may then be selectively etched away, with the retained layers of the super-lattice then laterally separated from each other by a distance that is a function of the super-lattice periodicity. A gate dielectric and a gate electrode may be formed over the retained super-lattice layers for a channel of a transistor.

Abstract: Techniques and mechanisms to impose stress on a transistor which includes a channel region and a source or drain region each in a fin structure. In an embodiment, a gate structure of the transistor extends over the fin structure, wherein a first spacer portion is at a sidewall of the gate structure and a second spacer portion adjoins the first spacer portion. Either or both of two features are present at or under respective bottom edges of the spacer portions. One of the features includes a line of discontinuity on the fin structure. The other feature includes a concentration of a dopant in the second spacer portion being greater than a concentration of the dopant in the source or drain region. In another embodiment, the fin structure is disposed on a buffer layer, wherein stress on the channel region is imposed at least in part with the buffer layer.