A method of manufacturing an integrated circuit device including a self-aligned air spacer including the operations of forming a dummy gate, forming a sidewall on the dummy gate, forming a dummy layer on the sidewall, constructing a gate structure within an opening defined by the sidewall, removing at least a portion of the first dummy layer to form a first recess between the sidewall layer and the dummy gate, and capping the first recess to form a first air spacer.

A method includes depositing a multi-layer stack over a semiconductor substrate, the multi-layer stack including a plurality of sacrificial layers that alternate with a plurality of channel layers; forming a first recess in the multi-layer stack; forming first spacers on sidewalls of the sacrificial layers in the first recess; depositing a first semiconductor material in the first recess, where the first semiconductor material is undoped, where the first semiconductor material is in physical contact with a sidewall and a bottom surface of at least one of the first spacers; implanting dopants in the first semiconductor material, where after implanting dopants the first semiconductor material has a gradient-doped profile; and forming an epitaxial source/drain region in the first recess over the first semiconductor material, where a material of the epitaxial source/drain region is different from the first semiconductor material.

A device includes a substrate including an active region, a gate stack over the active region, and a hard mask over the gate stack. The hard mask includes a capping layer, a buttress layer extending along sidewalls and a bottom of the capping layer, and a liner layer extending along sidewalls and a bottom of the buttress layer. The buttress layer includes a metal oxide material or a metal nitride material.

A method can include ion implanting with the gate mask to form first halo regions and ion implanting with the gate mask and first spacers as a mask to form second halo regions. The gate mask and first spacers can be removed, and an epitaxial layer formed. A dummy gate mask can be formed. Ion implanting with the dummy gate mask can from source-drain extensions. Second spacers can be formed on sides of the dummy gate mask. Ion implanting with the dummy gate mask and second spacers as a mask can form source and drain regions. A surface dielectric layer can be formed and planarized to expose a top of the dummy gate. The dummy gate can be removed to form gate openings between the second spacers. A hi-K dielectric layer and at least two gate metal layers within the gate opening. Related devices are also disclosed.

A method of forming a semiconductor device includes forming a source/drain region on a substrate, depositing a metal-rich metal silicide layer on the source/drain region, depositing a silicon-rich metal silicide layer on the metal-rich metal silicide layer, and forming a contact plug on the silicon-rich metal silicide layer. This disclosure also describes a semiconductor device including a fin structure on a substrate, a source/drain region on the fin structure, a metal-rich metal silicide layer on the source/drain region, a silicon-rich metal silicide layer on the metal-rich metal silicide layer, and a contact plug on the silicon-rich metal silicide layer.

An integrated circuit (IC) with a semiconductor device and an interconnect structure with carbon layers and methods of fabricating the same are disclosed. The method includes forming a fin structure on a substrate, forming a source/drain region on the fin structure, forming a contact structure on the S/D region, forming an oxide layer on the contact structure, forming a conductive carbon line within a first insulating carbon layer on the oxide layer, forming a second insulating carbon layer on the first insulating carbon layer, and forming a via within the second insulating carbon layer.

A tunneling field effect transistor device disclosed herein includes a substrate, a body comprised of a first semiconductor material being doped with a first type of dopant material positioned above the substrate, and a second semiconductor material positioned above at least a portion of the gate region and above the source region. The first semiconductor material is part of the drain region, and the second semiconductor material defines the channel region. The device also includes a third semiconductor material positioned above the second semiconductor material and above at least a portion of the gate region and above the source region. The third semiconductor material is part of the source region, and is doped with a second type of dopant material that is opposite to the first type of dopant material. A gate structure is positioned above the first, second and third semiconductor materials in the gate region.

A method of concurrently forming source/drain contacts (CAs) and gate contacts (CBs) and device are provided. Embodiments include forming metal gates (PC) and source/drain (S/D) regions over a substrate; forming an ILD over the PCs and S/D regions; forming a mask over the ILD; concurrently patterning the mask for formation of CAs adjacent a first portion of each PC and CBs over a second portion of the PCs; etching through the mask, forming trenches extending through the ILD down to a nitride capping layer formed over each PC and a trench silicide (TS) contact formed over each S/D region; selectively growing a metal capping layer over the TS contacts formed over the S/D regions; removing the nitride capping layer from the second portion of each PC; and metal filling the trenches, forming the CAs and CBs.

An integrated circuit structure includes a gate stack over a semiconductor substrate, and a silicon germanium region extending into the semiconductor substrate and adjacent to the gate stack. The silicon germanium region has a top surface, with a center portion of the top surface recessed from edge portions of the top surface to form a recess. The edge portions are on opposite sides of the center portion.

A semiconductor device includes a first active structure on a substrate including a first epitaxial pattern, a second epitaxial pattern and a first channel pattern between the first epitaxial pattern and the second epitaxial pattern, the first channel pattern including at least one channel pattern stacked on the substrate. A first gate structure is disposed on top and bottom surfaces of the first channel pattern. A second active structure on the substrate and includes the second epitaxial pattern, a third epitaxial pattern and a second channel pattern between the second epitaxial pattern and the third epitaxial pattern in the first direction. The second channel pattern includes at least one channel pattern stacked on the substrate. The number of stacked second channel patterns is greater than the number of stacked first channel patterns. A second gate structure is disposed on top and bottom surfaces of the second channel pattern.