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: 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: Techniques are disclosed for forming a transistor with one or more additional gate spacers. The additional spacers may be formed between the gate and original gate spacers to reduce the parasitic coupling between the gate and the source/drain, for example. In some cases, the additional spacers may include air gaps and/or dielectric material (e.g., low-k dielectric material). In some cases, the gate may include a lower portion and an upper portion. In some such cases, the lower portion of the gate may be narrower in width between the original gate spacers than the upper portion of the gate, which may be as a result of the additional spacers being located between the lower portion of the gate and the original gate spacers. In some such cases, the gate may approximate a “T” shape or various derivatives of that shape such as -shape or -shape, for example.

Abstract: Techniques are disclosed for forming a transistor with one or more additional spacers, or inner-gate spacers, as referred to herein. The additional spacers may be formed between the gate and original spacers to reduce the parasitic coupling between the gate and the source/drain, for example. In some cases, the additional spacers may include air gaps and/or dielectric material (e.g., low-k dielectric material). In some cases, the gate may include a lower portion, a middle portion, and an upper portion. In some such cases, the lower and upper portions of the gate may be wider between the original spacers than the middle portion of the gate, which may be as a result of the additional spacers being located between the middle portion of the gate and the original spacers. In some such cases, the gate may approximate an I-shape, C-shape, -shape, ?-shape, L-shape, or ?-shape, for example.

Abstract: Embodiments of the invention include an electromagnetic waveguide and methods of forming the electromagnetic waveguide. In an embodiment the electromagnetic waveguide includes a first spacer and a second spacer. In an embodiment, the first and second spacer each have a reentrant profile. The electromagnetic waveguide may also include a conductive body formed between in the first and second spacer, and a void formed within the conductive body. In an additional embodiment, the electromagnetic waveguide may include a first spacer and a second spacer. Additionally, the electromagnetic waveguide may include a first portion of a conductive body formed along sidewalls of the first and second spacer and a second portion of the conductive body formed between an upper portion of the first portion of the conductive body. In an embodiment, the first portion of the conductive body and the second portion of the conductive body define a void through the electromagnetic waveguide.

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.

Abstract: Techniques are disclosed for forming a transistor with one or more additional spacers, or inner-gate spacers, as referred to herein. The additional spacers may be formed between the gate and original spacers to reduce the parasitic coupling between the gate and the source/drain, for example. In some cases, the additional spacers may include air gaps and/or dielectric material (e.g., low-k dielectric material). In some cases, the gate may include a lower portion, a middle portion, and an upper portion. In some such cases, the lower and upper portions of the gate may be wider between the original spacers than the middle portion of the gate, which may be as a result of the additional spacers being located between the middle portion of the gate and the original spacers. In some such cases, the gate may approximate an I-shape, -shape, -shape, ?-shape, L-shape, or ?-shape, for example.

Abstract: Embodiments of the invention include an electromagnetic waveguide and methods of forming electromagnetic waveguides. In an embodiment, the electromagnetic waveguide may include a first semiconductor fin extending up from a substrate and a second semiconductor fin extending up from the substrate. The fins may be bent towards each other so that a centerline of the first semiconductor fin and a centerline of the second semiconductor fin extend from the substrate at a non-orthogonal angle. Accordingly, a cavity may be defined by the first semiconductor fin, the second semiconductor fin, and a top surface of the substrate. Embodiments of the invention may include a metallic layer and a cladding layer lining the surfaces of the cavity. Additional embodiments may include a core formed in the cavity.

Abstract: A transistor including a channel disposed between a source and a drain, a gate electrode disposed on the channel and surrounding the channel, wherein the source and the drain are formed in a body on a substrate and the channel is separated from the body. A method of forming an integrated circuit device including forming a trench in a dielectric layer on a substrate, the trench including dimensions for a transistor body including a width; forming a channel material in the trench; recessing the dielectric layer to expose a first portion of the channel material; increasing a width dimension of the exposed channel material; recessing the dielectric layer to expose a second portion of the channel material; removing the second portion of the channel material; and forming a gate stack on the first portion of the channel material, the gate stack including a gate dielectric and a gate electrode.

Abstract: A transistor including a source and a drain each formed in a substrate; a channel disposed in the substrate between the source and drain, wherein the channel includes opposing sidewalls with a distance between the opposing sidewalls defining a width dimension of the channel and wherein the opposing sidewalls extend a distance below a surface of the substrate; and a gate electrode on the channel. A method of forming a transistor including forming a source and a drain in an area of a substrate; forming a source contact on the source and a drain contact on the drain; after forming the source contact and the drain contact, forming a channel in the substrate in an area between the source and drain, the channel including a body having opposing sidewalls separated by a length dimension; and forming a gate contact on the channel.

Abstract: Fin-based thin film resistors, and methods of fabricating fin-based thin film resistors, are described. In an example, an integrated circuit structure includes a fin protruding through a trench isolation region above a substrate. The fin includes a semiconductor material and has a top surface, a first end, a second end, and a pair of sidewalls between the first end and the second end. An isolation layer is conformal with the top surface, the first end, the second end, and the pair of sidewalls of the fin. A resistor layer is conformal with the isolation layer conformal with the top surface, the first end, the second end, and the pair of sidewalls of the fin. A first anode cathode electrode is electrically connected to the resistor layer. A second anode or cathode electrode is electrically connected to the resistor layer.

Abstract: IC device structures including a lateral compound resistor disposed over a surface of a substrate, and fabrication techniques to form such a resistor in conjunction with fabrication of a transistor. Rather than being stacked vertically, a compound resistive trace may include a plurality of resistive materials arranged laterally over a substrate. Along a resistive trace length, a first resistive material is in contact with a sidewall of a second resistive material. A portion of a first resistive material along a centerline of the resistive trace may be replaced with a second resistive material so that the second resistive material is embedded within the first resistive material.

Abstract: Dual height glass is described for doping a fin of a field effect transistor structure in an integrated circuit. In one example, a method includes applying a glass layer over a fin of a FinFET structure, the fin having a source/drain region and a gate region, applying a polysilicon layer over the gate region, removing a portion of the glass layer from the source/drain region after applying the polysilicon, and thermally annealing the glass to drive dopants into the fin, and applying an epitaxial layer over the source/drain region.

Abstract: An embodiment includes an apparatus comprising: a transistor including a source, a drain, and a gate that has first and second sidewalls; a first spacer on the first sidewall between the drain and the gate; a second spacer on the second sidewall between the source and the gate; and a third spacer on the first spacer. Other embodiments are described herein.

Abstract: A microelectronic transistor may be fabricated having an airgap spacer formed as a gate sidewall spacer, such that the airgap spacer is positioned between a gate electrode and a source contact and/or a drain contact of the microelectronic transistor. As the dielectric constant of gaseous substances is significantly lower than that of a solid or a semi-solid dielectric material, the airgap spacer may result in minimal capacitive coupling between the gate electrode and the source contact and/or the drain contact, which may reduce circuit delay of the microelectronic transistor.

Abstract: Integrated circuit structures including a pillar resistor disposed over a surface of a substrate, and fabrication techniques to form such a resistor in conjunction with fabrication of a transistor over the substrate. Following embodiments herein, a small resistor footprint may be achieved by orienting the resistive length orthogonally to the substrate surface. In embodiments, the vertical resistor pillar is disposed over a first end of a conductive trace, a first resistor contact is further disposed on the pillar, and a second resistor contact is disposed over a second end of a conductive trace to render the resistor footprint substantially independent of the resistance value. Formation of a resistor pillar may be integrated with a replacement gate transistor process by concurrently forming the resistor pillar and sacrificial gate out of a same material, such as polysilicon. Pillar resistor contacts may also be concurrently formed with one or more transistor contacts.

Abstract: A microelectronic transistor may be fabricated having an airgap spacer formed as a gate sidewall spacer, such that the airgap spacer is positioned between a gate electrode and a source contact and/or a drain contact of the microelectronic transistor. As the dielectric constant of gaseous substances is significantly lower than that of a solid or a semi-solid dielectric material, the airgap spacer may result in minimal capacitive coupling between the gate electrode and the source contact and/or the drain contact, which may reduce circuit delay of the microelectronic transistor.

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: IC device structures including a lateral compound resistor disposed over a surface of a substrate, and fabrication techniques to form such a resistor in conjunction with fabrication of a transistor. Rather than being stacked vertically, a compound resistive trace may include a plurality of resistive materials arranged laterally over a substrate. Along a resistive trace length, a first resistive material is in contact with a sidewall of a second resistive material. A portion of a first resistive material along a centerline of the resistive trace may be replaced with a second resistive material so that the second resistive material is embedded within the first resistive material.