Abstract: A high-voltage transistor structure is provided that includes a self-aligned isolation feature between the gate and drain. Normally, the isolation feature is not self-aligned. The self-aligned isolation process can be integrated into standard CMOS process technology. In one example embodiment, the drain of the transistor structure is positioned one pitch away from the active gate, with an intervening dummy gate structure formed between the drain and active gate structure. The dummy gate structure is sacrificial in nature and can be utilized to create a self-aligned isolation recess, wherein the gate spacer effectively provides a template for etching the isolation recess. This self-aligned isolation forming process eliminates a number of the variation and dimensional constraints attendant non-aligned isolation forming techniques, which in turn allows for smaller footprint and tighter alignment so as to reduce device variation.

Abstract: A transistor is disclosed. The transistor includes a substrate, a superlattice structure that includes a plurality of heterojunction channels, and a gate that extends to one of the plurality of heterojunction channels. The transistor also includes a source adjacent a first side of the superlattice structure and a drain adjacent a second side of the superlattice structure.

Abstract: High voltage three-dimensional devices having dielectric liners and methods of forming high voltage three-dimensional devices having dielectric liners are described. For example, a semiconductor structure includes a first fin active region and a second fin active region disposed above a substrate. A first gate structure is disposed above a top surface of, and along sidewalls of, the first fin active region. The first gate structure includes a first gate dielectric, a first gate electrode, and first spacers. The first gate dielectric is composed of a first dielectric layer disposed on the first fin active region and along sidewalls of the first spacers, and a second, different, dielectric layer disposed on the first dielectric layer and along sidewalls of the first spacers. The semiconductor structure also includes a second gate structure disposed above a top surface of, and along sidewalls of, the second fin active region.

Abstract: Non-planar I/O and logic semiconductor devices having different workfunctions on common substrates and methods of fabricating non-planar I/O and logic semiconductor devices having different workfunctions on common substrates are described. For example, a semiconductor structure includes a first semiconductor device disposed above a substrate. The first semiconductor device has a conductivity type and includes a gate electrode having a first workfunction. The semiconductor structure also includes a second semiconductor device disposed above the substrate. The second semiconductor device has the conductivity type and includes a gate electrode having a second, different, workfunction.

Abstract: Embodiments include a transistor and methods of forming such transistors. In an embodiment, the transistor comprises a semiconductor substrate, a barrier layer over the semiconductor substrate; a polarization layer over the barrier layer, an insulating layer over the polarization layer, a gate electrode through the insulating layer and the polarization layer, a spacer along sidewalls of the gate electrode, and a gate dielectric between the gate electrode and the barrier layer.

Abstract: Embodiments include a transistor and methods of forming a transistor. In an embodiment, the transistor comprises a semiconductor channel, a source electrode on a first side of the semiconductor channel, a drain electrode on a second side of the semiconductor channel, a polarization layer over the semiconductor channel, an insulator stack over the polarization layer, and a gate electrode over the semiconductor channel. In an embodiment, the gate electrode comprises a main body that passes through the insulator stack and the polarization layer, and a first field plate extending out laterally from the main body.

Abstract: Two or more types of fin-based transistors having different gate structures and formed on a single integrated circuit are described. The gate structures for each type of transistor are distinguished at least by the thickness or composition of the gate dielectric layer(s) or the composition of the work function metal layer(s) in the gate electrode. Methods are also provided for fabricating an integrated circuit having at least two different types of fin-based transistors, where the transistor types are distinguished by the thickness and composition of the gate dielectric layer(s) and/or the thickness and composition of the work function metal in the gate electrode.

Abstract: An impurity source film is formed along a portion of a non-planar semiconductor fin structure. The impurity source film may serve as source of an impurity that becomes electrically active subsequent to diffusing from the source film into the semiconductor fin. In one embodiment, an impurity source film is disposed adjacent to a sidewall surface of a portion of a sub-fin region disposed between an active region of the fin and the substrate and is more proximate to the substrate than to the active area.

Abstract: A semiconductor device is proposed. The semiconductor device includes a group III-N semiconductor layer, an electrically insulating material layer located on the group III-N semiconductor layer, and a metal contact structure located on the electrically insulating material layer. An electrical resistance between the metal contact structure and the group III-N semiconductor layer through the electrically insulating material layer is smaller than 1*10?7? for an area of 1 mm2. Further, semiconductor devices including a low resistance contact structure, radio frequency devices, and methods for forming semiconductor devices are proposed.

Abstract: Group-III nitride (III-N) tunnel devices with a device structure including multiple quantum wells. A bias voltage applied across first device terminals may align the band structure to permit carrier tunneling between a first carrier gas residing in a first of the wells to a second carrier gas residing in a second of the wells. A III-N tunnel device may be operable as a diode, or further include a gate electrode. The III-N tunnel device may display a non-linear current-voltage response with negative differential resistance, and be employed as a frequency mixer operable in the GHz and THz bands. In some examples, a GHz-THz input RF signal and local oscillator signal are coupled into a gate electrode of a III-N tunnel device biased within a non-linear regime to generate an output RF signal indicative of a frequency difference between the RF signal and a local oscillator signal.

Abstract: A transistor device including a transistor including a body disposed on a substrate, a gate stack contacting at least two adjacent sides of the body and a source and a drain on opposing sides of the gate stack and a channel defined in the body between the source and the drain, wherein a conductivity of the channel is similar to a conductivity of the source and the drain. An input/output (IO) circuit including a driver circuit coupled to the logic circuit, the driver circuit including at least one transistor device is described. A method including forming a channel of a transistor device on a substrate including an electrical conductivity; forming a source and a drain on opposite sides of the channel, wherein the source and the drain include the same electrical conductivity as the channel; and forming a gate stack on the channel.

Abstract: Ultra-scaled fin pitch processes having dual gate dielectrics are described. For example, a semiconductor structure includes first and second semiconductor fins above a substrate. A first gate structure includes a first gate electrode over a top surface and laterally adjacent to sidewalls of the first semiconductor fin, a first gate dielectric layer between the first gate electrode and the first semiconductor fin and along sidewalls of the first gate structure, and a second gate dielectric layer between the first gate electrode and the first gate dielectric layer and along the first gate dielectric layer along the sidewalls of the first gate electrode. A second gate structure includes a second gate electrode over a top surface and laterally adjacent to sidewalls of the second semiconductor fin, and the second gate dielectric layer between the second gate electrode and the second semiconductor fin and along sidewalls of the second gate electrode.

Abstract: Metal resistors and self-aligned gate edge (SAGE) architectures having metal resistors are described. In an example, a semiconductor structure includes a plurality of semiconductor fins protruding through a trench isolation region above a substrate. A first gate structure is over a first of the plurality of semiconductor fins. A second gate structure is over a second of the plurality of semiconductor fins. A gate edge isolation structure is laterally between and in contact with the first gate structure and the second gate structure. The gate edge isolation structure is on the trench isolation region and extends above an uppermost surface of the first gate structure and the second gate structure. A metal layer is on the gate edge isolation structure and is electrically isolated from the first gate structure and the second gate structure.

Abstract: Techniques are disclosed for forming a transistor with enhanced thermal performance. The enhanced thermal performance can be derived from the inclusion of thermal boost material adjacent to the transistor, where the material can be selected based on the transistor type being formed. In the case of PMOS devices, the adjacent thermal boost material may have a high positive linear coefficient of thermal expansion (CTE) (e.g., greater than 5 ppm/° C. at around 20° C.) and thus expand as operating temperatures increase, thereby inducing compressive strain on the channel region of an adjacent transistor and increasing carrier (e.g., hole) mobility. In the case of NMOS devices, the adjacent thermal boost material may have a negative linear CTE (e.g., less than 0 ppm/° C. at around 20° C.) and thus contract as operating temperatures increase, thereby inducing tensile strain on the channel region of an adjacent transistor and increasing carrier (e.g., electron) mobility.

Abstract: Techniques are disclosed for forming semiconductor structures including resistors between gates on self-aligned gate edge architecture. A semiconductor structure includes a first semiconductor fin extending in a first direction, and a second semiconductor fin adjacent to the first semiconductor fin, extending in the first direction. A first gate structure is disposed proximal to a first end of the first semiconductor fin and over the first semiconductor fin in a second direction, orthogonal to the first direction, and a second gate structure is disposed proximal to a second end of the first semiconductor fin and over the first semiconductor fin in the second direction. A first structure comprising isolation material is centered between the first and second semiconductor fins. A second structure comprising resistive material is disposed in the first structure, the second structure extending at least between the first gate structure and the second gate structure.

Abstract: A vertical transistor is described that uses a through silicon via as a gate. In one example, the structure includes a substrate, a via in the substrate, the via being filled with a conductive material and having a dielectric liner, a deep well coupled to the via, a drain area coupled to the deep well having a drain contact, a source area between the drain area and the via having a source contact, and a gate contact over the via.

Abstract: Disclosed herein are transistor arrangements with one or more FinFETs, where threshold voltage tuning of a given FinFET may be implemented by controlling the height of a work function (WF) material provided as a layer at least partially surrounding sidewalls of the upper-most portion of the fin of that FinFET. In some embodiments, such a control may be achieved as a part of forming a gate stack of a FinFET. In particular, a layer of a desired WF material may be deposited within an opening formed around a channel region of a fin as a part of forming the gate stack, and subsequently recessed to a desired height, where, for a given geometry and materials selection, the amount of WF material recess controls threshold voltage of the resulting FinFET. In this manner, different FinFETs in a single transistor arrangement may have different heights of their WF material layer.

Abstract: Integrated circuit structures including device terminal interconnect pillar structures, and fabrication techniques to form such structures. Following embodiments herein, a small transistor terminal interconnect footprint may be achieved by patterning recesses in a gate interconnect material and/or a source or drain interconnect material. A dielectric deposited over the gate interconnect material and/or source or drain interconnect material may be planarized to expose portions of the gate interconnect material and/or drain interconnect material that were protected from the recess patterning. An upper level interconnect structure, such as a conductive line or via, may contact the exposed portion of the gate and/or source or drain interconnect material.

Abstract: Embodiments herein may describe techniques for an integrated circuit including a metal interconnect above a substrate and coupled to a first contact and a second contact. The first contact and the second contact may be above the metal interconnect and in contact with the metal interconnect. A first resistance may exist between the first contact and the second contact through the metal interconnect. After a programming voltage is applied to the second contact while the first contact is coupled to a ground terminal to generate a current between the first contact and the second contact, a non-conducting barrier may be formed as an interface between the second contact and the metal interconnect. A second resistance may exist between the first contact, the metal interconnect, the second contact, and the non-conducting barrier. Other embodiments may be described and/or claimed.

Abstract: An apparatus comprising at least one transistor in a first area of a substrate and at least one transistor in a second area, a work function material on a channel region of each of the at least one transistor, wherein an amount of work function material in the first area is different than an amount of work function material in the second area. A method comprising depositing a work function material and a masking material on at least one transistor body in a first area and at least one in a second area; removing less than an entire portion of the masking material so that the portion of the work function material that is exposed in the first area is different than that exposed in the second area; removing the exposed work function material; and forming a gate electrode on each of the at least one transistor bodies.