Abstract: A method for forming a semiconductor device comprising forming a semiconductor fin on a substrate, forming a first sacrificial gate stack over a first channel region of the fin and forming a second sacrificial gate stack over a second channel region of the fin, forming spacers adjacent to the first sacrificial gate stack and the second sacrificial gate stack, depositing a first liner layer on the spacers, the first sacrificial gate stack and the second sacrificial gate stack, depositing a first sacrificial layer on the first liner layer, removing a portion of the first sacrificial layer over the first gate stack to expose a portion of the first liner layer on the first sacrificial gate stack, and growing a first semiconductor material on exposed portions of the fin to form a first source/drain region adjacent to the first gate sacrificial gate stack.

Abstract: A gate tie-down structure includes a gate structure including a gate conductor and gate spacers and inner spacers formed on the gate spacers. Trench contacts are formed on sides of the gate structure. An interlevel dielectric (ILD) has a thickness formed over the gate structure. A horizontal connection is formed within the thickness of the ILD over an active area connecting the gate conductor and one of the trench contacts over one of the inner spacers.

Abstract: After forming a gate stack straddling a portion of each semiconductor fin of a plurality of semiconductor fins located over a substrate, a gate liner is formed on sidewalls of a lower portion of the gate stack that contacts the plurality of semiconductor fins and a gate spacer having a width greater than a width of the gate liner is formed on sidewalls of an upper portion of the gate stack that is located above the plurality of semiconductor fins. The width of the gate spacer thus is not limited by the fin pitch, and can be optimized to improve the device performance.

Abstract: A method of filling trenches between gates includes forming a first and a second dummy gate over a substrate, the first and second dummy gates including a sacrificial gate material and a hard mask layer; forming a first gate spacer along a sidewall of the first dummy gate and a second gate spacer along a sidewall of the second dummy gate; performing an epitaxial growth process to form a source/drain on the substrate between the first and second dummy gates; disposing a conformal liner over the first and second dummy gates and the source/drain; disposing an oxide on the conformal liner between the first and second dummy gates; recessing the oxide to a level below the hard mask layers of the first and second dummy gates to form a recessed oxide; and depositing a spacer material over the recessed oxide between the first dummy gate and the second dummy gate.

Abstract: A method of fabricating a semiconductor device includes forming at least one semiconductor fin on a semiconductor substrate. A plurality of gate formation layers is formed on an etch stop layer disposed on the fin. The plurality of gate formation layers include a dummy gate layer formed from a dielectric material. The plurality of gate formation layers is patterned to form a plurality of dummy gate elements on the etch stop layer. Each dummy gate element is formed from the dielectric material. A spacer layer formed on the dummy gate elements is etched to form a spacer on each sidewall of dummy gate elements. A portion of the etch stop layer located between each dummy gate element is etched to expose a portion the semiconductor fin. A semiconductor material is epitaxially grown from the exposed portion of the semiconductor fin to form source/drain regions.

Abstract: A bonding material stack for wafer-to-wafer bonding is provided. The bonding material stack may include a plurality of layers each including boron and nitrogen. In one embodiment, the plurality of layers may include: a first boron oxynitride layer for adhering to a wafer; a boron nitride layer over the first boron oxynitride layer; a second boron oxynitride layer over the boron nitride layer; and a silicon-containing boron oxynitride layer over the second boron oxynitride layer.

Abstract: A method of filling trenches between gates includes forming a first and a second dummy gate over a substrate, the first and second dummy gates including a sacrificial gate material and a hard mask layer; forming a first gate spacer along a sidewall of the first dummy gate and a second gate spacer along a sidewall of the second dummy gate; performing an epitaxial growth process to form a source/drain on the substrate between the first and second dummy gates; disposing a conformal liner over the first and second dummy gates and the source/drain; disposing an oxide on the conformal liner between the first and second dummy gates; recessing the oxide to a level below the hard mask layers of the first and second dummy gates to form a recessed oxide; and depositing a spacer material over the recessed oxide between the first dummy gate and the second dummy gate.

Abstract: A method for forming a gate tie-down includes opening up a cap layer and recessing gate spacers on a gate structure to expose a gate conductor; forming inner spacers on the gate spacers; etching contact openings adjacent to sides of the gate structure down to a substrate below the gate structures; and forming trench contacts on sides of the gate structure. An interlevel dielectric (ILD) is deposited on the gate conductor and the trench contacts and over the gate structure. The ILD is opened up to expose the trench contact on one side of the gate structure and the gate conductor. A second conductive material provides a self-aligned contact down to the trench contact on the one side and to form a gate contact down to the gate conductor and a horizontal connection within the ILD over an active area between the gate conductor and the self-aligned contact.

Abstract: A method for fabricating a field effect transistor device comprises forming a fin on a substrate, forming a first dummy gate stack and a second dummy gate stack over the fin, forming spacers adjacent to the fin, the first dummy gate stack, and the second dummy gate stack, etching to remove portions of the fin and form a first cavity partially defined by the spacers, depositing an insulator material in the first cavity, patterning a mask over the first dummy gate stack and portions of the fin, etching to remove exposed portions of the insulator material, and epitaxially growing a first semiconductor material on exposed portions of the fin.

Abstract: Embodiments of the present invention provide hydrogen-free dielectric films and methods of fabrication. A hydrogen-free precursor, such as tetraisocyanatosilane, and hydrogen-free reactants, such as nitrogen, oxygen (O2/O3) and nitrous oxide are used with chemical vapor deposition processes (PECVD, thermal CVD, SACVD, HDP CVD, and PE and Thermal ALD) to create hydrogen-free dielectric films. In some embodiments, there are multilayer dielectric films with sublayers of various materials such as silicon oxide, silicon nitride, and silicon oxynitride. In embodiments, the hydrogen-free reactants may include Tetra Isocyanato Silane, along with a hydrogen-free gas including, but not limited to, N2, O2, O3, N2O, CO2, CO and a combination thereof of these H-Free gases. Plasma may be used to enhance the reaction between the TICS and the other H-free gasses. The plasma may be controlled during film deposition to achieve variable density within each sublayer of the films.

Abstract: A method of filling trenches between gates includes forming a first and a second dummy gate over a substrate, the first and second dummy gates including a sacrificial gate material and a hard mask layer; forming a first gate spacer along a sidewall of the first dummy gate and a second gate spacer along a sidewall of the second dummy gate; performing an epitaxial growth process to form a source/drain on the substrate between the first and second dummy gates; disposing a conformal liner over the first and second dummy gates and the source/drain; disposing an oxide on the conformal liner between the first and second dummy gates; recessing the oxide to a level below the hard mask layers of the first and second dummy gates to form a recessed oxide; and depositing a spacer material over the recessed oxide between the first dummy gate and the second dummy gate.

Abstract: A method of forming a punch through stop region in a fin structure is disclosed. The method may include forming a doped glass layer on a fin structure and forming a masking layer on the doped glass layer. The method may further include removing a portion of the masking layer from an active portion of the fin structure, and removing an exposed portion the doped glass layer that is present on the active portion of the fin structure. A remaining portion of the doped glass layer is present on the isolation portion of the fin structure. Dopant from the doped glass layer may then be diffused into the isolation portion of the fin structure to form the punch through stop region between the active portion of the fin structure and a supporting substrate.

Abstract: A method of forming a punch through stop region in a fin structure is disclosed. The method may include forming a doped glass layer on a fin structure and forming a masking layer on the doped glass layer. The method may further include removing a portion of the masking layer from an active portion of the fin structure, and removing an exposed portion the doped glass layer that is present on the active portion of the fin structure. A remaining portion of the doped glass layer is present on the isolation portion of the fin structure. Dopant from the doped glass layer may then be diffused into the isolation portion of the fin structure to form the punch through stop region between the active portion of the fin structure and a supporting substrate.

Abstract: A method of forming a semiconductor device comprises forming a first fin on a substrate, depositing an insulator layer on the substrate adjacent to the first fin, removing a first portion of the insulator layer to expose a first portion of a sidewall of the first fin, depositing a layer of spacer material over the first portion of the sidewall of the first fin, removing a second portion of the insulator layer to expose a second portion of the sidewall of the first fin, depositing a first glass layer including a first doping agent over the exposed second portion of the sidewall of the first fin, and performing a first annealing process to drive the first doping agent into the first fin.

Abstract: A method of filling trenches between gates includes forming a first and a second dummy gate over a substrate, the first and second dummy gates including a sacrificial gate material and a hard mask layer; forming a first gate spacer along a sidewall of the first dummy gate and a second gate spacer along a sidewall of the second dummy gate; performing an epitaxial growth process to form a source/drain on the substrate between the first and second dummy gates; disposing a conformal liner over the first and second dummy gates and the source/drain; disposing an oxide on the conformal liner between the first and second dummy gates; recessing the oxide to a level below the hard mask layers of the first and second dummy gates to form a recessed oxide; and depositing a spacer material over the recessed oxide between the first dummy gate and the second dummy gate.

Abstract: A method for forming a gate tie-down includes opening up a cap layer and recessing gate spacers on a gate structure to expose a gate conductor; forming inner spacers on the gate spacers; etching contact openings adjacent to sides of the gate structure down to a substrate below the gate structures; and forming trench contacts on sides of the gate structure. An interlevel dielectric (ILD) is deposited on the gate conductor and the trench contacts and over the gate structure. The ILD is opened up to expose the trench contact on one side of the gate structure and the gate conductor. A second conductive material provides a self-aligned contact down to the trench contact on the one side and to form a gate contact down to the gate conductor and a horizontal connection within the ILD over an active area between the gate conductor and the self-aligned contact.

Abstract: A method for forming a gate tie-down includes opening up a cap layer and recessing gate spacers on a gate structure to expose a gate conductor; forming inner spacers on the gate spacers; etching contact openings adjacent to sides of the gate structure down to a substrate below the gate structures; and forming trench contacts on sides of the gate structure. An interlevel dielectric (ILD) is deposited on the gate conductor and the trench contacts and over the gate structure. The ILD is opened up to expose the trench contact on one side of the gate structure and the gate conductor. A second conductive material provides a self-aligned contact down to the trench contact on the one side and to form a gate contact down to the gate conductor and a horizontal connection within the ILD over an active area between the gate conductor and the self-aligned contact.

Abstract: A semiconductor structure includes a plurality of semiconductor material fins located on a surface of a substrate. At least one gate structure straddles over a portion of each semiconductor material fin. Unmerged source-side epitaxial semiconductor material portions are located on an exposed surfaces of each semiconductor material fin and on one side of each gate structure and unmerged drain-side epitaxial semiconductor portions are located on other exposed surfaces of each semiconductor material fin and on another side of each gate structure. An etch stop structure is located between each unmerged source-side and drain-side epitaxial semiconductor material portions. Each etch stop structure includes a bottom material portion that has a higher etch resistance in a specific etchant as compared to an upper material portion of the etch stop structure.

Abstract: After forming a gate stack straddling a portion of each semiconductor fin of a plurality of semiconductor fins located over a substrate, a gate liner is formed on sidewalls of a lower portion of the gate stack that contacts the plurality of semiconductor fins and a gate spacer having a width greater than a width of the gate liner is formed on sidewalls of an upper portion of the gate stack that is located above the plurality of semiconductor fins. The width of the gate spacer thus is not limited by the fin pitch, and can be optimized to improve the device performance.

Abstract: A semiconductor device includes a gate disposed over a substrate; a source region and a drain region on opposing sides of the gate; and a pair of trench contacts over and abutting an interfacial layer portion of at least one of the source region and the drain region; wherein the interfacial layer includes boron in an amount in a range from about 5×1021 to about 5×1022 atoms/cm2.