Abstract: Embodiments of the present invention are directed to a method for forming a complementary field effect transistor (CFET) structure having a wrap-around contact. In a non-limiting embodiment of the invention, a complementary nanosheet stack is formed over a substrate. The complementary nanosheet stack includes a first nanosheet and a second nanosheet separated by a dielectric spacer. A first sacrificial layer is formed over a source or drain (S/D) region of the first nanosheet and a second sacrificial layer is formed over a S/D region of the second nanosheet. A conductive gate is formed over channel regions of the first nanosheet and the second nanosheet. After the conductive gate is formed, the first sacrificial layer is replaced with a first wrap-around contact and the second sacrificial layer is replaced with a second wrap-around contact.

Abstract: A semiconductor device includes one or more fins. Each fin includes a top channel portion formed from a channel material, and a bottom substrate portion formed from a same material as an underlying substrate. An isolation dielectric layer is formed between and around the bottom substrate portion of the one or more fins. A single oxide layer is formed in direct contact with the bottom substrate portion of each fin, between the bottom substrate portion of each fin and the isolation dielectric layer. A gate dielectric is formed over the one or more fins and between a straight sidewall of at least a top portion of the single oxide layer and an adjacent sidewall of the one or more fins, in contact with both the straight sidewall and the bottom substrate portion.

Abstract: A semiconductor structure includes a first field-effect transistor disposed on a substrate. The first field-effect transistor includes a first metal gate, and a first source/drain region. A second field-effect transistor is vertically stacked above the first field-effect transistor. The second field-effect transistor includes a second metal gate, and a second source/drain region. The first metal gate and the second metal gate are vertically aligned and configured with an air gap disposed therebetween. The first source/drain region and the second source/drain region are vertically aligned and configured with another air gap disposed therebetween.

Abstract: A method of fabricating a semiconductor device includes forming a plurality of semiconductor fins upon a substrate, forming a plurality of epitaxially grown source-drain regions upon the fins, forming a plurality of device gates upon the fins, the device gates disposed between the epitaxially grown source-drain regions, forming a trench exposing at least one epitaxially grown source-drain region, masking at least a portion of the exposed epitaxially grown source-drain region, forming a gate trench exposing at least a portion of a device gate and gate spacer, forming a metallization layer between the epitaxially grown source-drain region and the device gate, selectively recessing the metallization layer, forming a conductive layer upon the metallization layer, and forming a dielectric cap above the conductive layer.

Abstract: 6T-SRAM cell designs for larger SRAM arrays and methods of manufacture generally include a single fin device for both nFET (pass-gate (PG) and pull-down (PD)) and pFET (pull-up (PU). The pFET can be configured with a smaller effective channel width (Weff) than the nFET or with a smaller active fin height. An SRAM big cell consumes the (111) 6t-SRAM design area while provide different Weff ratios other than 1:1 for PU/PD or PU/PG as can be desired for different SRAM designs.

Abstract: 6T-SRAM cell designs for larger SRAM arrays and methods of manufacture generally include a single fin device for both nFET (pass-gate (PG) and pull-down (PD)) and pFET (pull-up (PU). The pFET can be configured with a smaller effective channel width (Weff) than the nFET or with a smaller active fin height. An SRAM big cell consumes the (111) 6t-SRAM design area while provide different Weff ratios other than 1:1 for PU/PD or PU/PG as can be desired for different SRAM designs.

Abstract: 6T-SRAM cell designs for larger SRAM arrays and methods of manufacture generally include a single fin device for both nFET (pass-gate (PG) and pull-down (PD)) and pFET (pull-up (PU). The pFET can be configured with a smaller effective channel width (Weff) than the nFET or with a smaller active fin height. An SRAM big cell consumes the (111) 6t-SRAM design area while provide different Weff ratios other than 1:1 for PU/PD or PU/PG as can be desired for different SRAM designs.

Abstract: A semiconductor structure is provided that includes a first FinFET device for low power applications and a second FinFET device for non-low power applications. The first FinFET device has an active fin height, i.e., channel height, which is less that an active fin height of the second FinFET device. The active fin height adjustment is achieved utilizing an isolation structure that has a constant height in the region including the first FinFET device and the region including the second FinFET device.

Abstract: A method of forming a semiconductor structure includes forming an interfacial layer surrounding at least one channel stack, forming a high-k dielectric layer surrounding the interfacial layer, and forming a metal gate layer surrounding the high-k dielectric layer. The method also includes forming a silicon layer over the metal gate layer and forming at least one additional metal layer over the silicon layer. The method further includes performing silicidation to transform at least a portion of the at least one additional metal layer and at least a portion of the silicon layer into a silicide layer. The metal gate layer, the silicon layer and the silicide layer form at least one gate electrode for a vertical transport field-effect transistor (VTFET).

Abstract: Embodiments of the invention are directed to an integrated circuit. A non-limiting example of the integrated circuit includes a transistor formed over a substrate. A dielectric region is formed over the transistor and the substrate. A trench is positioned in the dielectric region and over a S/D region of the transistor. A first liner and a conductive plug are within the trench such that the first liner and the conductive plug are only present within a bottom portion of the trench. A substantially oxygen-free replacement liner and a S/D contact are within the top portion of the trench such that a bottom contact surface of the S/D contact directly couples to a top surface of the conductive plug.

Abstract: Embodiments of the invention are directed to a method of forming an interconnect structure. A non-limiting example of the method includes forming a transistor over a substrate, forming a dielectric region over the transistor and the substrate, and forming a trench positioned in the dielectric region and over a source or drain (S/D) region of the transistor, wherein a sidewall of the trench includes a gate spacer of the transistor. A volume of the trench is increased by removing the gate spacer from the sidewall of the trench. A first liner and a conductive plug are deposited within a bottom portion of the trench.

Abstract: Techniques for interface charge reduction to improve performance of SiGe channel devices are provided. In one aspect, a method for reducing interface charge density (Dit) for a SiGe channel material includes: contacting the SiGe channel material with an Si-containing chemical precursor under conditions sufficient to form a thin continuous Si layer, e.g., less than 5 monolayers thick on a surface of the SiGe channel material which is optionally contacted with an n-dopant precursor; and depositing a gate dielectric on the SiGe channel material over the thin continuous Si layer, wherein the thin continuous Si layer by itself or in conjunction with n-dopant precursor passivates an interface between the SiGe channel material and the gate dielectric thereby reducing the Dit. A FET device and method for formation thereof are also provided.

Abstract: A method of forming a semiconductor structure includes forming an interfacial layer surrounding at least one channel stack, forming a high-k dielectric layer surrounding the interfacial layer, and forming a metal gate layer surrounding the high-k dielectric layer. The method also includes forming a silicon layer over the metal gate layer and forming at least one additional metal layer over the silicon layer. The method further includes performing silicidation to transform at least a portion of the at least one additional metal layer and at least a portion of the silicon layer into a silicide layer. The metal gate layer, the silicon layer and the silicide layer form at least one gate electrode for a vertical transport field-effect transistor (VTFET).

Abstract: A method for fabricating a semiconductor device includes forming a first inner spacer layer along a substrate and a nanosheet stack disposed on the substrate, performing an ultraviolet (UV) condensation process to form a hardened inner spacer from the first inner spacer layer, forming a second inner spacer layer along the hardened inner spacer, and removing material to form inner spacers by performing an inner spacer etch.

Abstract: Improved gate stack designs for Si and SiGe dual channel devices are provided. In one aspect, a method for forming a dual channel device includes: forming fins on a substrate, the fins including Si fins in combination with SiGe fins as dual channels of an analog device and a logic device, with the analog device and the logic device each having a Si fin and a SiGe fin; forming a silicon germanium oxide (SiGeOx) layer on the SiGe fins; annealing the SiGeOx layer to form a Si-rich layer on the SiGe fins via a reaction between SiGeOx and SiGe; and forming metal gates over the Si fins and over the Si-rich layer on the SiGe fins. A dual channel device is also provided.

Abstract: Integrated chips include a semiconductor fin that has a first active region and a second active region that are electrically separated by an oxide region that completely penetrates the semiconductor fin. A first semiconductor device is formed on the first active region. A second semiconductor device formed on the second active region.

Abstract: A technique relates to a semiconductor device. A source or drain (S/D) contact liner is formed on one or more S/D regions. Annealing is performed to form a silicide layer around the one or more S/D regions, the silicide layer being formed at an interface between the S/D contact liner and the S/D regions. A block layer is formed into a pattern over the one or more S/D regions, such that a portion of the S/D contact liner is protected by the block layer. Unprotected portions of the S/D contact liner are removed, such that the S/D contact liner protected by the block layer remains over the one or more S/D regions. The block layer and S/D contacts are formed on the S/D contact liner over the one or more S/D regions.

Abstract: Techniques are provided to fabricate embedded insulating layers within an active semiconductor layer of substrate to reduce leakage between field-effect transistor devices and the semiconductor substrate. For example, an epitaxial semiconductor layer is formed on a surface of a semiconductor substrate. An ion implantation process is performed to form an embedded insulation layer within the semiconductor substrate below the epitaxial semiconductor layer. A nanosheet field-effect transistor device is formed over the embedded insulation layer. The nanosheet field-effect transistor device includes active nanosheet channel layers, source/drain layers, and a high-k dielectric/metal gate structure formed around the active nanosheet channel layers. The process of forming the nanosheet field-effect transistor device includes removing the epitaxial semiconductor layer to release the active nanosheet channel layers.

Abstract: Techniques for fabricating a semiconductor device having a two-part spacer. In one embodiment, a device is provided that comprises a spacer having a first portion and a second portion, where the first portion comprises one or more layers and the second portion comprises a dielectric material. In one or more implementations, the device further comprises an isolation layer coupled to the spacer, where the isolation layer comprises a silicon oxide material. In one or implementation, the device can further comprise a gate structure formed on a substrate, where the gate structure comprises a polysilicon contact portion, a first silicon dioxide portion, a silicon nitride portion and a second silicon dioxide portion.

Abstract: Techniques are provided to fabricate embedded insulating layers within an active semiconductor layer of substrate to reduce leakage between field-effect transistor devices and the semiconductor substrate. For example, an epitaxial semiconductor layer is formed on a surface of a semiconductor substrate. An ion implantation process is performed to form an embedded insulation layer within the semiconductor substrate below the epitaxial semiconductor layer. A nanosheet field-effect transistor device is formed over the embedded insulation layer. The nanosheet field-effect transistor device includes active nanosheet channel layers, source/drain layers, and a high-k dielectric/metal gate structure formed around the active nanosheet channel layers. The process of forming the nanosheet field-effect transistor device includes removing the epitaxial semiconductor layer to release the active nanosheet channel layers.