A semiconductor device includes a buried metal line disposed in a semiconductor substrate, a first dielectric material on a first sidewall of the buried metal line and a second dielectric material on a second sidewall of the buried metal line, a first multiple fins disposed proximate the first sidewall of the buried metal line, a second multiple fins disposed proximate the second sidewall of the buried metal line, a first metal gate structure over the first multiple fins and over the buried metal line, wherein the first metal gate structure extends through the first dielectric material to contact the buried metal line, and a second metal gate structure over the second multiple fins and over the buried metal line.

A semiconductor device is provided. The semiconductor device includes a fin protruding from a semiconductor substrate and a gate structure formed across the fin. The semiconductor device also includes a gate spacer formed over a sidewall of the gate structure. The gate spacer includes a sidewall spacer and a sealing spacer formed above the sidewall spacer. In addition, an air gap is vertically sandwiched between the sidewall spacer and the sealing spacer. The semiconductor device further includes a hard mask formed over the gate structure and covering a sidewall of the sealing spacer.

A semiconductor device including first fin-shaped patterns in a first region of a substrate and spaced apart from each other in a first direction, second fin-shaped patterns in a second region of the substrate and spaced apart from each other in a second direction, a first field insulating film on the substrate and covering sidewalls of the first fin-shaped patterns, a second field insulating film on the substrate and covering sidewalls of the second fin-shaped patterns, a first source/drain pattern on the first field insulating film, connected to the first fin-shaped patterns, and including a first silicon-germanium pattern, and a second source/drain pattern on the second field insulating film, connected to the second fin-shaped patterns, and including a second silicon-germanium pattern, the second source/drain pattern and the second field insulating film defining one or more first air gaps therebetween may be provided.

Techniques are provided herein to form semiconductor devices having self-aligned gate cut structures. In an example, neighboring semiconductor devices each include a semiconductor region extending between a source region and a drain region, and a gate layer extending over the semiconductor regions of the neighboring semiconductor devices. A gate cut structure that includes a dielectric material interrupts the gate layer between the neighboring semiconductor devices. Due to the process of forming the gate cut structure, the distance between the gate cut structure and the semiconductor region of one of the neighboring semiconductor devices is substantially the same as (e.g., within 1.5 nm of) the distance between the gate cut structure and the semiconductor region of the other one of the neighboring semiconductor devices.

An integrated circuit (IC) layout design is received that includes a first circuit cell and a second circuit cell abutted to one another. The first circuit cell contains a first IC component, and the second circuit cell contains a second IC component. A determination is made that a distance between the first IC component and the second IC component is less than a predefined threshold when the first circuit cell and the second circuit cell are abutted together. The IC layout design is revised such that the distance between the first IC component and the second IC component is eliminated in the revised IC layout design.

A fuse structure includes first and second transistors where each of the first and the second transistors has a source terminal, a drain terminal, and a gate terminal; a first source/drain contact disposed on the source terminal of the first transistor; a second source/drain contact disposed on the drain terminal of the second transistor; an insulator disposed laterally between the first and the second source/drain contacts; a source/drain contact via disposed on the first source/drain contact; and a program line connected to the source/drain contact via, wherein a width of the insulator is configured such that a programming potential applied across the source/drain contact via and the drain terminal of the second transistor causes the insulator to break down.

A dummy gate is formed over a substrate. A sacrificial layer is formed over the dummy gate. An interlayer dielectric (ILD) is formed over the dummy gate and over the sacrificial layer. The dummy gate is replaced with a metal-containing gate. The sacrificial layer is removed. A removal of the sacrificial layer leaves air gaps around the metal-containing gate. The air gaps are then sealed.

A method includes providing a semiconductor structure having a metal gate structure (MG), gate spacers disposed on sidewalls of the MG, and a source/drain (S/D) feature disposed adjacent to the gate spacers; forming a first metal layer over the S/D feature and between the gate spacers; recessing the first metal layer to form a trench; forming a dielectric layer on sidewalls of the trench; forming a second metal layer over the first metal layer in the trench, wherein sidewalls of the second metal layer are defined by the dielectric layer; and forming a contact feature over the MG to contact the MG.

The embodiments described herein are directed to a method for mitigating the fringing capacitances generated by patterned gate structures. The method includes forming a gate structure on fin structures disposed on a substrate; forming an opening in the gate structure to divide the gate structure into a first section and a second section, where the first and second sections are spaced apart by the opening. The method also includes forming a fill structure in the opening, where forming the fill structure includes depositing a silicon nitride liner in the opening to cover sidewall surfaces of the opening and depositing silicon oxide on the silicon nitride liner.

Various embodiments of the present disclosure are directed towards a semiconductor device including a gate electrode over a semiconductor substrate. An epitaxial source/drain layer is disposed on the semiconductor substrate and is laterally adjacent to the gate electrode. The epitaxial source/drain layer comprises a first dopant. A diffusion barrier layer is between the epitaxial source/drain layer and the semiconductor substrate. The diffusion barrier layer comprises a barrier dopant that is different from the first dopant.