Embodiments of the present disclosure provide methods for forming merged source/drain features from two or more fin structures. The merged source/drain features according to the present disclosure have a merged portion with an increased height percentage over the overall height of the source/drain feature. The increase height percentage provides an increased landing range for source/drain contact features, therefore, reducing the connection resistance between the source/drain feature and the source/drain contact features. In some embodiments, the emerged source/drain features include one or more voids formed within the merged portion.

In a method of manufacturing a semiconductor device, underlying structures comprising gate electrodes and source/drain epitaxial layers are formed, one or more layers are formed over the underlying structures, a hard mask layer is formed over the one or more layers, a groove pattern is formed in the hard mask layer, one or more first resist layers are formed over the hard mask layer having the groove pattern, a first photo resist pattern is formed over the one or more first resist layers, the one or more first resist layers are patterned by using the first photo resist pattern as an etching mask, thereby forming a first hard mask pattern, and the hard mask layer with the groove pattern are patterned by using the first hard mask pattern, thereby forming a second hard mask pattern.

Recesses may be formed in portions of an ILD layer of a semiconductor device in a highly uniform manner. Uniformity in depths of the recesses may be increased by configuring flows of gases in an etch tool to promote uniformity of etch rates (and thus, etch depth) across the semiconductor device, from semiconductor device to semiconductor device, and/or from wafer to wafer. In particular, the flow rates of gases at various inlets of the etch tool may be optimized to provide recess depth tuning, which increases the process window for forming the recesses in the portions of the ILD layer. In this way, the increased uniformity of the recesses in the portions of the ILD layer enables highly uniform capping layers to be formed in the recesses.

A semiconductor device includes a silicon substrate and a fin formed above the substrate. The fin provides active regions for two devices, such as gate-all-around transistors. The semiconductor device also includes a fin-insulating structure positioned to electrically isolate the active regions for the two devices. The fin-insulating structure is formed in a trench, with a first portion adjacent the fin and a second portion below the fin and extending into the substrate. The fin-insulating structure includes an oxide liner in the second portion of the trench, but not the first portion. The fin-insulating structure is further filled with an insulating material such as silicon nitride.

Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes an isolation structure formed over a semiconductor substrate. A first fin structure and a second fin structure extend from the semiconductor substrate and protrude above the isolation structure. A first gate structure is formed across the first fin structure and a second gate structure is formed across the second fin structure. A gate isolation structure is formed between the first fin structure and the second fin structure and separates the first gate structure from the second gate structure. The gate isolation structure includes a bowl-shaped insulating layer that has a first convex sidewall surface adjacent to the first gate structure and a second convex sidewall surface adjacent to the second gate structure.

Confined epitaxial regions for semiconductor devices and methods of fabricating semiconductor devices having confined epitaxial regions are described. For example, a semiconductor structure includes a plurality of parallel semiconductor fins disposed above and continuous with a semiconductor substrate. An isolation structure is disposed above the semiconductor substrate and adjacent to lower portions of each of the plurality of parallel semiconductor fins. An upper portion of each of the plurality of parallel semiconductor fins protrudes above an uppermost surface of the isolation structure. Epitaxial source and drain regions are disposed in each of the plurality of parallel semiconductor fins adjacent to a channel region in the upper portion of the semiconductor fin. The epitaxial source and drain regions do not extend laterally over the isolation structure. The semiconductor structure also includes one or more gate electrodes, each gate electrode disposed over the channel region of one or more of the plurality of parallel semiconductor fins.

A method includes forming a semiconductor fin, forming a gate stack on the semiconductor fin, and a gate spacer on a sidewall of the gate stack. The method further includes recessing the semiconductor fin to form a recess, performing a first epitaxy process to grow a first epitaxy semiconductor layer in the recess, wherein the first epitaxy semiconductor layer, and performing a second epitaxy process to grow an embedded stressor extending into the recess. The embedded stressor has a top portion higher than a top surface of the semiconductor fin, with the top portion having a first sidewall contacting a second sidewall of the gate spacer, and with the sidewall having a bottom end level with the top surface of the semiconductor fin. The embedded spacer has a bottom portion lower than the top surface of the semiconductor fin.

An integrated circuit includes a device region and an overlay mark region. The device region includes a plurality of stacked channels of a transistor, a source/drain region of the transistor, a source/drain contact of a first material on the source/drain region, and a conductive via of a second material in contact with the source/drain contact. The overlay mark region includes a first diffraction grating of first metal structures of the first material and a second first diffraction grating of second metal structures above of the second material above and offset from the first metal structures.

A semiconductor device includes a sensing element including a sensing electrode and a filter covering the sensing electrode. The filter includes a first work function layer and a second work function layer. The first work function layer is over the sensing electrode. The second work function layer is over the first work function layer. A work function value of the second work function layer is greater than a work function value of the first work function layer, and an atomic percentage of metal in the second work function layer is greater than an atomic percentage of metal in the first work function layer.

A semiconductor device includes a substrate having a fin element extending therefrom. In some embodiments, a gate structure is formed over the fin element, where the gate structure includes a dielectric layer on the fin element, a metal capping layer disposed over the dielectric layer, and a metal electrode formed over the metal capping layer. In some cases, first sidewall spacers are formed on opposing sidewalls of the metal capping layer and the metal electrode. In various embodiments, the dielectric layer extends laterally underneath the first sidewall spacers to form a dielectric footing region.