Abstract: After formation of gate stacks, a carbon-based template layer is deposited over the gate stacks, and is optionally planarized to provide a planar top surface. A hard mask layer and a photoresist layer are subsequently formed above the carbon-based template layer. A pattern including openings is formed within the photoresist layer. The pattern is subsequently transferred through the hard mask layer and the carbon-based template layer with high selectivity to gate spacers to form self-aligned cavities within the carbon-based template layer. Contact structures are formed within the carbon-based template layer by a damascene method. The hard mask layer and the carbon-based template layer are subsequently removed selective to the contact structures. The contact structures can be formed as contact bar structures or contact via structures. Optionally, a contact-level dielectric layer can be subsequently deposited.

Abstract: A design layout including shapes of target areas for forming semiconductor fins employing directed self-assembly can be decomposed into guiding patterns and cut patterns. The lengthwise edges of the shapes of target areas are adjusted. Widthwise edges of the adjusted shapes are extended outward to generate diffusion shapes. Guiding pattern shapes are then generated employing the diffusion shapes. Taper edges are adjusted based on process bias of a photoresist material to be subsequently employed. Optionally, a portion of a guiding pattern shape between diffusion shapes may be removed as a connection shape. The guiding pattern shapes can define at least one guiding pattern mask for lithographic pattern of guiding pattern shapes, and cut shapes can be derived from the diffusion shapes and the guiding pattern shapes. The guiding pattern shapes and the cut shapes may be adjusted to accommodate effects at device cell edges and at device macro edges.

Abstract: Improved fin field effect transistor (FinFET) devices and methods for the fabrication thereof are provided. In one aspect, a field effect transistor device is provided. The field effect transistor device includes a source region; a drain region; a plurality of fins connecting the source region and the drain region, the fins having a pitch of between about 40 nanometers and about 200 nanometers and each fin having a width of between about ten nanometers and about 40 nanometers; and a gate stack over at least a portion of the fins, wherein the source region and the drain region are self-aligned with the gate stack.

Abstract: In one aspect, a method of forming contacts to source and drain regions in a FET device includes the following steps. A patternable dielectric is deposited onto the device so as to surround each of the source and drain regions. The patternable dielectric is exposed to cross-link portions of the patternable dielectric that surround the source and drain regions. Uncross-linked portions of the patternable dielectric are selectively removed relative to the cross-linked portions of the patternable dielectric, wherein the cross-linked portions of the patternable dielectric form dummy contacts that surround the source and drain regions. A planarizing dielectric is deposited onto the device around the dummy contacts. The dummy contacts are selectively removed to form vias in the planarizing dielectric which are then filled with a metal(s) so as to form replacement contacts that surround the source and drain regions.

Abstract: FinFET devices and methods for the fabrication thereof are provided. In one aspect, a method for fabricating a FET device includes the following steps. A wafer is provided having an active layer on an insulator. A plurality of fin hardmasks are patterned on the active layer. A dummy gate is placed over a central portion of the fin hardmasks. One or more doping agents are implanted into source and drain regions of the device. A dielectric filler layer is deposited around the dummy gate. The dummy gate is removed to form a trench in the dielectric filler layer. The fin hardmasks are used to etch a plurality of fins in the active layer within the trench. The doping agents are activated. A replacement gate is formed in the trench, wherein the step of activating the doping agents is performed before the step of forming the replacement gate.

Abstract: Non-planar Metal Oxide Field Effect Transistors (MOSFETs) and methods for making non-planar MOSFETs with asymmetric, recessed source and drains having improved extrinsic resistance and fringing capacitance. The methods include a fin-last, replacement gate process to form the non-planar MOSFETs and employ a retrograde metal lift-off process to form the asymmetric source/drain recesses. The lift-off process creates one recess which is off-set from a gate structure while a second recess is aligned with the structure. Thus, source/drain asymmetry is achieved by the physical structure of the source/drains, and not merely by ion implantation. The resulting non-planar device has a first channel of a fin contacting a substantially undoped area on the drain side and a doped area on the source side, thus the first channel is asymmetric. A channel on atop surface of a fin is symmetric because it contacts doped areas on both the drain and source sides.

Abstract: In one aspect, a method of forming contacts to source and drain regions in a FET device includes the following steps. A patternable dielectric is deposited onto the device so as to surround each of the source and drain regions. The patternable dielectric is exposed to cross-link portions of the patternable dielectric that surround the source and drain regions. Uncross-linked portions of the patternable dielectric are selectively removed relative to the cross-linked portions of the patternable dielectric, wherein the cross-linked portions of the patternable dielectric form dummy contacts that surround the source and drain regions. A planarizing dielectric is deposited onto the device around the dummy contacts. The dummy contacts are selectively removed to form vias in the planarizing dielectric which are then filled with a metal(s) so as to form replacement contacts that surround the source and drain regions.

Abstract: In one aspect, a FET device is provided. The FET device includes a substrate; a semiconductor material on the substrate; at least one gate on the substrate surrounding a portion of the semiconductor material that serves as a channel region of the device, wherein portions of the semiconductor material extending out from the gate serve as source and drain regions of the device, and wherein the source and drain regions of the device are displaced from the substrate; a planarizing dielectric on the device covering the gate and the semiconductor material; and contacts which extend through the planarizing dielectric and surround the source and drain regions of the device.

Abstract: A structure includes a substrate containing at least first and second adjacent gate structures on a silicon surface of the substrate and a silicided source/drain region formed in a V-shaped groove between the first and second adjacent gate structures. The silicided source/drain region formed in the V-shaped groove extend substantially from an edge of the first gate structure to an opposing edge of the second gate structure.

Abstract: Systems and methods for operating a nanometer-scale cantilever beam with a gate electrode. An example system includes a drive circuit coupled to the gate electrode where a drive signal from the circuit may cause the beam to oscillate at or near the beam's resonance frequency. The drive signal includes an AC component, and may include a DC component as well. An alternative example system includes a nanometer-scale cantilever beam, where the beam oscillates to contact a plurality of drain regions.

Abstract: A method includes providing a substrate containing at least first and second adjacent gate structures on a silicon surface of the substrate; etching a V-shaped groove through the silicon surface between the first and second adjacent gate structures, where the V-shaped groove extends substantially from an edge of the first gate structure to an opposing edge of the second gate structure; implanting a source/drain region into the V-shaped groove; and siliciding the implanted source/drain region. The etching step is preferably performed by using a HCl-based chemical vapor etch (CVE) that stops on a Si(111) plane of the silicon substrate (e.g., a SOI layer). A structure containing FETs that is fabricated in accordance with the method is also disclosed.

Abstract: Fin-defining mask structures are formed over a semiconductor material layer having a first semiconductor material and a disposable gate structure is formed thereupon. A gate spacer is formed around the disposable gate structure and physically exposed portions of the fin-defining mask structures are subsequently removed. The semiconductor material layer is recessed employing the disposable gate structure and the gate spacer as an etch mask to form recessed semiconductor material portions. Embedded planar source/drain stressors are formed on the recessed semiconductor material portions by selective deposition of a second semiconductor material having a different lattice constant than the first semiconductor material. After formation of a planarization dielectric layer, the disposable gate structure is removed. A plurality of semiconductor fins are formed employing the fin-defining mask structures as an etch mask. A replacement gate structure is formed on the plurality of semiconductor fins.

Abstract: Improved fin field effect transistor (FinFET) devices and methods for the fabrication thereof are provided. In one aspect, a method for fabricating a field effect transistor device comprises the following steps. A substrate is provided having a silicon layer thereon. A fin lithography hardmask is patterned on the silicon layer. A dummy gate structure is placed over a central portion of the fin lithography hardmask. A filler layer is deposited around the dummy gate structure. The dummy gate structure is removed to reveal a trench in the filler layer, centered over the central portion of the fin lithography hardmask, that distinguishes a fin region of the device from source and drain regions of the device. The fin lithography hardmask in the fin region is used to etch a plurality of fins in the silicon layer. The trench is filled with a gate material to form a gate stack over the fins.

Abstract: Embodiments of the present invention provide a method of preventing electrical shorting of adjacent semiconductor devices. The method includes forming a plurality of fins of a plurality of field-effect-transistors on a substrate; forming at least one barrier structure between a first and a second fin of the plurality of fins; and growing an epitaxial film from the plurality of fins, the epitaxial film extending horizontally from sidewalls of at least the first and second fins and reaching the barrier structure situating between the first and second fins.

Abstract: Raised isolation structures can be formed at the same level as semiconductor fins over an insulator layer. A template material layer can be conformally deposited to fill the gaps among the semiconductor fins within each cluster of semiconductor fins on an insulator layer, while the space between adjacent clusters is not filled. After an anisotropic etch, discrete template material portions can be formed within each cluster region, while the buried insulator is physically exposed between cluster regions. A raised isolation dielectric layer is deposited and planarized to form raised isolation structures employing the template material portions as stopping structures. After removal of the template material portions, a cluster of semiconductor fins are located within a trench that is self-aligned to outer edges of the cluster of semiconductor fins. The trench can be employed to confine raised source/drain regions to be formed on the cluster of semiconductor fins.

Abstract: Embodiments of the present invention provide a method of preventing electrical shorting of adjacent semiconductor devices. The method includes forming a plurality of fins of a plurality of field-effect-transistors on a substrate; forming at least one barrier structure between a first and a second fin of the plurality of fins; and growing an epitaxial film from the plurality of fins, the epitaxial film extending horizontally from sidewalls of at least the first and second fins and reaching the barrier structure situating between the first and second fins.

Abstract: A method of fabricating a FET device is provided which includes the following steps. Nanowires/pads are formed in a SOI layer over a BOX layer, wherein the nanowires are suspended over the BOX. A HSQ layer is deposited that surrounds the nanowires. A portion(s) of the HSQ layer that surround the nanowires are cross-linked, wherein the cross-linking causes the portion(s) of the HSQ layer to shrink thereby inducing strain in the nanowires. One or more gates are formed that retain the strain induced in the nanowires. A FET device is also provided wherein each of the nanowires has a first region(s) that is deformed such that a lattice constant in the first region(s) is less than a relaxed lattice constant of the nanowires and a second region(s) that is deformed such that a lattice constant in the second region(s) is greater than the relaxed lattice constant of the nanowires.

Abstract: Narrow-body FETs, such as, FinFETs and trigates, exhibit superior short-channel characteristics compared to thick-body devices, such as planar bulk Si FETs and planar partially-depleted SOI (PDSOI) FETs. A common problem, however, with narrow-body devices is high series resistance that often negates the short-channel benefits. The high series resistance is due to either dopant pile-up at the SOI/BOX interface or dopant diffusion into the BOX. This disclosure describes a novel narrow-body device geometry that is expected to overcome the high series resistance problem.

Abstract: Narrow-body FETs, such as, FinFETs and trigates, exhibit superior short-channel characteristics compared to thick-body devices, such as planar bulk Si FETs and planar partially-depleted SOI (PDSOI) FETs. A common problem, however, with narrow-body devices is high series resistance that often negates the short-channel benefits. The high series resistance is due to either dopant pile-up at the SOI/BOX interface or dopant diffusion into the BOX. This disclosure describes a novel narrow-body device geometry that is expected to overcome the high series resistance problem.

Abstract: A disposable material layer is first deposited on a graphene layer or a carbon nanotube (CNT). The disposable material layer includes a material that is less inert than graphene or CNT so that a contiguous dielectric material layer can be deposited at a target dielectric thickness without pinholes therein. A gate stack is formed by patterning the contiguous dielectric material layer and a gate conductor layer deposited thereupon. The disposable material layer shields and protects the graphene layer or the CNT during formation of the gate stack. The disposable material layer is then removed by a selective etch, releasing a free-standing gate structure. The free-standing gate structure is collapsed onto the graphene layer or the CNT below at the end of the selective etch so that the bottom surface of the contiguous dielectric material layer contacts an upper surface of the graphene layer or the CNT.