Abstract: A method of forming a nanowire device includes forming semiconductor material layers above a semiconductor substrate, forming a gate structure above the semiconductor material layers, forming a first sidewall spacer adjacent to the gate structure and forming a second sidewall spacer adjacent to the first sidewall spacer. The method further includes patterning the semiconductor material layers such that each layer has first and second exposed end surfaces. The gate structure, the first sidewall spacer, and the second sidewall spacer are used in combination as an etch mask during the patterning process. The method further includes removing the first and second sidewall spacers, thereby exposing at least a portion of the patterned semiconductor material layers. The method further includes forming doped extension regions in at least the exposed portions of the patterned semiconductor material layers after removing the first and second sidewall spacers.

Abstract: A method includes forming at least one fin in a semiconductor substrate, forming a fin spacer on at least a first portion of the fin, the fin spacer having an upper surface, recessing the at least one fin to thereby define a recessed fin with a recessed upper surface that it is at a level below the upper surface of the fin spacer, and forming a first epitaxial material on the recessed fin, wherein a lateral extension of the epitaxial material is constrained by the fin spacer.

Abstract: A device includes a gate structure and a nanowire channel structure positioned under the gate structure. The nanowire channel structure includes first and second end surfaces. The device further includes a first insulating liner positioned on the first end surface and a second insulating liner positioned on the second end surface. The device further includes a metal-containing source contact positioned on the first insulating liner and a metal-containing drain contact positioned on the second insulating liner.

Abstract: Integrated circuits having metal-insulator-semiconductor (MIS) contact structures and methods for fabricating integrated circuits having metal-insulator-semiconductor (MIS) contact structures are provided. In an embodiment, a method for fabricating an integrated circuit includes providing a fin structure formed from semiconductor material overlying a semiconductor substrate. The method includes depositing a layer of high-k dielectric material over the fin structure. Further, the method includes forming a metal layer or layers over the layer of high-k dielectric material to provide the fin structure with a metal-insulator-semiconductor (MIS) contact structure.

Abstract: One method disclosed herein includes forming a sacrificial gate structure comprised of upper and lower sacrificial gate electrodes, performing at least one etching process to define a patterned upper sacrificial gate electrode comprised of a plurality of trenches that expose a portion of a surface of the lower sacrificial gate electrode and performing another etching process through the patterned upper sacrificial gate electrode to remove the lower sacrificial gate electrode and a sacrificial gate insulation layer and thereby define a first portion of a replacement gate cavity that is at least partially positioned under the patterned upper sacrificial gate electrode.

Abstract: One method includes forming a plurality of first trenches in a semiconductor substrate to thereby define a plurality of initial fins in the substrate, removing at least one, but less than all, of the plurality of initial fins, forming a fin protection layer on at least the sidewalls of the remaining initial fins, with the fin protection layer in position, performing an etching process to extend a depth of the first trenches to thereby define a plurality of final trenches with a final trench depth, wherein the final trenches define a plurality of final fin structures that each comprise an initial fin, removing the fin protection layer, and forming a recessed layer of insulating material in the final trenches, wherein the recessed layer of insulating material has a recessed surface that exposes a portion of the final fin structures.

Abstract: One method disclosed includes, forming a sacrificial gate structure trench in a stack of sacrificial material layers, forming a sacrificial gate structure within the trench, performing at least one process operation to remove at least portions of the stack of sacrificial material layers and thereby expose sidewalls of the sacrificial gate structure, forming a sidewall spacer adjacent the exposed sidewalls of the sacrificial gate structure, removing the sacrificial gate structure so as to define a replacement gate cavity between the spacers, forming a replacement gate structure in the replacement gate cavity, and forming a gate cap above the replacement gate structure within the replacement gate cavity.

Abstract: One method disclosed includes, forming a sacrificial gate structure trench in a stack of sacrificial material layers, forming a sacrificial gate structure within the trench, performing at least one process operation to remove at least portions of the stack of sacrificial material layers and thereby expose sidewalls of the sacrificial gate structure, forming a sidewall spacer adjacent the exposed sidewalls of the sacrificial gate structure, removing the sacrificial gate structure so as to define a replacement gate cavity between the spacers, forming a replacement gate structure in the replacement gate cavity, and forming a gate cap above the replacement gate structure within the replacement gate cavity.

Abstract: In one example, the method disclosed herein includes forming at least one fin for a FinFET device in a semiconducting substrate, performing at least one process operation to form a region in the at least one fin that contains a metal diffusion inhibiting material, depositing a layer of metal on the region in the at least one fin and forming a metal silicide region on the at least one fin.

Abstract: A FinFET device includes a plurality of fin structures positioned in and above a semiconducting substrate, wherein each of the fin structures includes a first portion of the semiconducting substrate, an undoped layer of semiconducting material positioned above the first portion of the semiconducting substrate, and a dopant-containing layer of semiconducting material positioned between the first portion of the semiconducting substrate and the undoped semiconducting material, wherein the dopant material is adapted to retard diffusion of one of boron and phosphorous. A gate electrode is positioned around at least the undoped layer of semiconducting material of each of the plurality of fin structures, wherein a height level of a bottom surface of the gate electrode is positioned approximately level with or lower than a height level of a bottom of the undoped layer of semiconducting material of each of the plurality of fin structures.

Abstract: Integrated circuits having metal-insulator-semiconductor (MIS) contact structures and methods for fabricating integrated circuits having metal-insulator-semiconductor (MIS) contact structures are provided. In an embodiment, a method for fabricating an integrated circuit includes providing a fin structure formed from semiconductor material overlying a semiconductor substrate. The method includes depositing a layer of high-k dielectric material over the fin structure. Further, the method includes forming a metal layer or layers over the layer of high-k dielectric material to provide the fin structure with a metal-insulator-semiconductor (MIS) contact structure.

Abstract: Integrated circuits having silicide contacts with reduced contact resistance and methods for fabricating integrated circuits having silicide contacts with reduced contact resistance are provided. In an embodiment, a method for fabricating an integrated circuit includes providing a semiconductor substrate having selected source/drain regions and non-selected source/drain regions. The method forms a contact resistance modulation material over the selected source/drain regions. Further, the method forms a metal layer over the selected and non-selected source/drain regions. The method includes annealing the metal layer to form silicide contacts on the selected and non-selected source/drain regions.

Abstract: One method disclosed includes, forming a sacrificial gate structure trench in a stack of sacrificial material layers, forming a sacrificial gate structure within the trench, performing at least one process operation to remove at least portions of the stack of sacrificial material layers and thereby expose sidewalls of the sacrificial gate structure, forming a sidewall spacer adjacent the exposed sidewalls of the sacrificial gate structure, removing the sacrificial gate structure so as to define a replacement gate cavity between the spacers, forming a replacement gate structure in the replacement gate cavity, and forming a gate cap above the replacement gate structure within the replacement gate cavity.

Abstract: A FinFET device includes a plurality of fin structures positioned in and above a semiconducting substrate, wherein each of the fin structures includes a first portion of the semiconducting substrate, an undoped layer of semiconducting material positioned above the first portion of the semiconducting substrate, and a dopant-containing layer of semiconducting material positioned between the first portion of the semiconducting substrate and the undoped semiconducting material, wherein the dopant material is adapted to retard diffusion of one of boron and phosphorous. A gate electrode is positioned around at least the undoped layer of semiconducting material of each of the plurality of fin structures, wherein a height level of a bottom surface of the gate electrode is positioned approximately level with or lower than a height level of a bottom of the undoped layer of semiconducting material of each of the plurality of fin structures.

Abstract: A method for fabricating a dual-workfunction FinFET structure includes depositing a first workfunction material in a layer in a plurality of trenches of the FinFET structure, depositing a low-resistance material layer over the first workfunction material layer, and etching the low-resistance material layer and the first workfunction material layer from a portion of the FinFET structure. The method further includes depositing a second workfunction material in a layer in a plurality of trenches of the portion and depositing a stress material layer over the second workfunction material layer.

Abstract: One method disclosed herein includes, prior to forming an isolation region in a semiconducting substrate for the device, forming a doped well region and a doped punch-stop region in the substrate, introducing a dopant material that is adapted to retard diffusion of boron or phosphorous into the substrate to form a dopant-containing layer proximate an upper surface of the substrate, performing an epitaxial deposition process to form an undoped semiconducting material above the dopant-containing layer, forming a plurality of spaced-apart trenches that extend at least partially into the substrate, wherein the trenches define a fin for the device comprised of at least the undoped semiconducting material, forming at least a local isolation insulating material in the trenches, and forming a gate structure around at least the undoped semiconducting material, wherein a bottom of a gate electrode is positioned approximately level with or below a bottom of the undoped semiconducting material.

Abstract: In one example, the method disclosed herein includes forming a shared sacrificial gate structure above at least one first fin for a first type of FinFET device and at least one second fin for a second type of FinFET device, wherein the second type is opposite to the first type, and forming a first sidewall spacer around an entire perimeter of the sacrificial gate structure in a single process operation.

Abstract: Semiconductor devices and methods for fabricating semiconductor devices are provided. In an embodiment, a method for fabricating a semiconductor device includes forming on a semiconductor surface a temporary gate structure including a polysilicon gate and a cap. A spacer is formed around the temporary gate structure. The cap and a portion of the spacer are removed. A uniform liner is deposited overlying the polysilicon gate. The method removes a portion of the uniform liner overlying the polysilicon gate and the polysilicon gate to form a gate trench. Then, a replacement metal gate is formed in the gate trench.

Abstract: Various methods of forming conductive contacts to the source/drain regions of FinFET devices that involves forming a region comprised of a Schottkky barrier lowering material are disclosed. The method disclosed herein includes forming at least one fin for an N-type FinFET device (or a P-type FinFET device) in a semiconducting substrate, performing at least one process operation to form a region in the at least one fin that contains a Schottky barrier lowering material, depositing a layer of a valence band metal (for an N-type device) or a conduction band metal (for a P-type device) on the region and forming a metal silicide region on the fin, wherein the metal silicide is comprised of the valance band metal (for the N-type device) or a conduction band metal (for the P-type device).

Abstract: In one example, the method disclosed herein includes forming at least one fin for a FinFET device in a semiconducting substrate, performing at least one process operation to form a region in the at least one fin that contains a metal diffusion inhibiting material, depositing a layer of metal on the region in the at least one fin and forming a metal silicide region on the at least one fin.