The present disclosure provides a semiconductor device that includes a semiconductor fin disposed over a substrate, an isolation structure at least partially surrounding the fin, an epitaxial source/drain (S/D) feature disposed over the semiconductor fin, where an extended portion of the epitaxial S/D feature extends over the isolation structure, and a silicide layer disposed on the epitaxial S/D feature, where the silicide layer covers top, bottom, sidewall, front, and back surfaces of the extended portion of the S/D feature.

In an embodiment, a device includes: a gate structure on a channel region of a substrate; a gate mask on the gate structure, the gate mask including a first dielectric material and an impurity, a concentration of the impurity in the gate mask decreasing in a direction extending from an upper region of the gate mask to a lower region of the gate mask; a gate spacer on sidewalls of the gate mask and the gate structure, the gate spacer including the first dielectric material and the impurity, a concentration of the impurity in the gate spacer decreasing in a direction extending from an upper region of the gate spacer to a lower region of the gate spacer; and a source/drain region adjoining the gate spacer and the channel region.

Some embodiments include a method of forming an integrated assembly. An arrangement is formed to include a conductive pillar extending through an insulative mass. An upper surface of the conductive pillar is recessed to form a cavity. An insulative collar is formed within the cavity to line an outer lateral periphery of the cavity. A recessed surface of the conductive pillar is exposed at a bottom of the lined cavity. A conductive expanse is formed over the insulative mass. A portion of the conductive expanse extends into the cavity and is configured as an interconnect. The conductive expanse is patterned into multiple conductive structures. One of the conductive structures includes the interconnect.

An exemplary semiconductor device includes a source feature and a drain feature disposed over a substrate. The semiconductor device further includes a source via electrically coupled to the source feature, and a drain via electrically coupled to the drain feature. The source via has a first size; the drain via has a second size; and the first size is greater than the second size. The semiconductor device may further include a first metal line electrically coupled to the source via and a second metal line electrically coupled to the drain via. The source via has a first dimension matching a dimension of the first metal line, and the drain via has a second dimension matching a dimension of the second metal line. The first metal line may be wider than the second metal line.

Embodiments described herein may be related to apparatuses, processes, and techniques related to protecting metal gates within transistor gate structures during SAC patterning. In particular, embodiments include area selective deposition techniques to deposit films on the gate or on a gate cap that have a good selectivity to SAC etch. In embodiments the film may include a combination of zirconium and/or oxygen, or may include zirconium oxide. Other embodiments may be described and/or claimed.

Back-side transistor contacts that wrap around a portion of source and/or drain semiconductor bodies, related transistor structures, integrated circuits, systems, and methods of fabrication are disclosed. Such back-side transistor contacts are coupled to a top and a side of the source and/or drain semiconductor and extend to back-side interconnects. Coupling to top and side surfaces of the source and/or drain semiconductor reduces contact resistance and extending the metallization along the side reduces transistor cell size for improve device density.

A top via interconnect with enlarged via top and a fabrication method therefor. One embodiment may comprise a semiconductor interconnect structure, comprising a first dielectric layer having a top surface, a bottom metal line formed in the dielectric layer, a second dielectric layer deposited above the top surface of the first dielectric layer, a via etched through the second dielectric layer above the bottom metal line, wherein the via exposes at least a portion of the top surface of the first dielectric layer, and a metal stud in the via that extends over the exposed at least a portion of the first dielectric layer. The metal stud in the via may further comprise a shoulder surface and a convex top surface.

A transistor includes a semiconductor substrate including a first active region, a second active region, and a semiconductor channel, a gate stack structure that overlies the semiconductor channel, a proximal dielectric material layer overlying the semiconductor substrate, laterally surrounding the gate stack structure, a distal dielectric material layer overlying the proximal dielectric material layer, and a first contact via structure contacting the first active region having a greater lateral extent at a level of the proximal dielectric material layer than at a level of the distal dielectric material layer.

A semiconductor device is disclosed. The semiconductor device may include a substrate including a first active pattern, the first active pattern vertically protruding from a top surface of the substrate, a first source/drain pattern filling a first recess, which is formed in an upper portion of the first active pattern, a first metal silicide layer on the first source/drain pattern, the first metal silicide layer including a first portion and a second portion, which are located on a first surface of the first source/drain pattern, and a first contact in contact with the second portion of the first metal silicide layer. A thickness of the first portion may be different from a thickness of the second portion.

A method for fabricating a semiconductor device includes: forming a first conductive structure over a substrate; forming a multi-layer spacer including a non-conformal sacrificial spacer on both sidewalls of the first conductive structure; forming a second conductive structure adjacent to the first conductive structure with the multi-layer spacer therebetween; forming an air gap by removing the non-conformal sacrificial spacer; forming a capping layer covering the second conductive structure and the air gap; forming an opening that exposes a top surface of the second conductive structure by etching the capping layer; and forming a conductive pad coupled to the second conductive structure in the opening.