A semiconductor device including a substrate including a division region extending in a first direction, first and second active patterns on the substrate with the division region interposed therebetween, the first and the second active patterns being spaced apart from each other in a second direction perpendicular to the first direction, gate electrodes extending in the first direction and crossing the first and second active patterns, a first channel pattern on the first active pattern, and a second channel pattern on the second active pattern may be provided. The smallest width of the first active pattern may be smaller than the smallest width of the second active pattern, in the first direction. An end portion of the first channel pattern adjacent to the division region may include a protruding portion extending in the first direction, and the protruding portion may have a triangle shape in a plan view.

A method includes forming a contact spacer on a sidewall of an inter-layer dielectric, wherein the contact spacer encircles a contact opening, forming a silicide region in the opening and on a source/drain region, depositing an adhesion layer extending into the contact opening, and performing a treatment process, so that the contact spacer is treated. The treatment process is selected from the group consisting of an oxidation process, a carbonation process, and combinations thereof. The method further includes depositing a metal barrier over the adhesion layer, depositing a metallic material to fill the contact opening, and performing a planarization process to remove excess portions of the metallic material over the inter-layer dielectric.

A nano-FET and a method of forming is provided. In some embodiments, a nano-FET includes an epitaxial source/drain region contacting ends of a first nanostructure and a second nanostructure. The epitaxial source/drain region may include a first semiconductor material layer of a first semiconductor material, such that the first semiconductor material layer includes a first segment contacting the first nanostructure and a second segment contacting the second nanostructure, wherein the first segment is separated from the second segment. A second semiconductor material layer is formed over the first segment and the second segment. The second semiconductor material layer may include a second semiconductor material having a higher concentration of dopants of a first conductivity type than the first semiconductor material layer. The second semiconductor material layer may have a lower concentration percentage of silicon than the first semiconductor material layer.

A semiconductor device is provided. The semiconductor device includes a plurality of first semiconductor nanostructures formed over a substrate, and a first S/D structure formed on sidewall surfaces of the first semiconductor nanostructures. The semiconductor device includes a plurality of second semiconductor nanostructures formed over the substrate, and a second S/D structure formed on sidewall surfaces of the second semiconductor nanostructures. The semiconductor device includes an isolation structure formed between the first S/D structure and the second S/D structure, and the isolation structure has a first sidewall surface in direct contact with the first S/D structure and a second sidewall surface in direct contact with the second S/D structure.

A semiconductor device includes a first transistor in a first region of a substrate and a second transistor in a second region of the substrate. The first transistor includes multiple first semiconductor patterns; a first gate electrode; a first gate dielectric layer; a first source/drain region; and an inner-insulating spacer. The second transistor includes multiple second semiconductor patterns; a second gate electrode; a second gate dielectric layer; and a second source/drain region. The second gate dielectric layer extends between the second gate electrode and the second source/drain region and is in contact with the second source/drain region. The first source/drain region is not in contact with the first gate dielectric layer.

A memory device includes a substrate, first semiconductor fin, second semiconductor fin, first gate structure, second gate structure, first gate spacer, and a second gate spacer. The first gate structure crosses the first semiconductor fin. The second gate structure crosses the second semiconductor fin, the first gate structure extending continuously from the second gate structure, in which in a top view of the memory device, a width of the first gate structure is greater than a width of the second gate structure. The first gate spacer is on a sidewall of the first gate structure. The second gate spacer extends continuously from the first gate spacer and on a sidewall of the second gate structure, in which in the top view of the memory device, a width of the first gate spacer is less than a width of the second gate spacer.

A semiconductor structure includes a fin disposed on a substrate, the fin including a channel region comprising a plurality of channels vertically stacked over one another, the channels comprising germanium distributed therein. The semiconductor structure further includes a gate stack engaging the channel region of the fin and gate spacers disposed between the gate stack and the source and drain regions of the fin, wherein each channel of the channels includes a middle section wrapped around by the gate stack and two end sections engaged by the gate spacers, wherein a concentration of germanium in the middle section of the channel is higher than a concentration of germanium in the two end sections of the channel, and wherein the middle section of the channel further includes a core portion and an outer portion surrounding the core portion with a germanium concentration profile from the core portion to the outer portion.

A transistor includes a gate structure with reduced gate region or eliminated gate region located between a top MDI region and a bottom MDI region. The reduced gate region has a reduction of conductive material therewithin and may be formed due to the presence of prefabricated wide inner spacers between the top MDI region and the bottom MDI region. The no gate region has an absence of conductive material therewithin and may be formed due to the presence of a prefabricated inner spacer that is between, and has a coplanar perimeter with, the top MDI region and the bottom MDI region. By reducing or eliminating the conductive material of the gate structure between the dual MDI structure, parasitic capacitance otherwise associated therewith is reduced.

An integrated circuit includes a substrate, at least one n-type semiconductor device, and at least one p-type semiconductor device. The n-type semiconductor device is present on the substrate. The n-type semiconductor device includes a gate structure having a bottom surface and at least one sidewall. The bottom surface of the gate structure of the n-type semiconductor device and the sidewall of the gate structure of the n-type semiconductor device intersect to form an interior angle. The p-type semiconductor device is present on the substrate. The p-type semiconductor device includes a gate structure having a bottom surface and at least one sidewall. The bottom surface of the gate structure of the p-type semiconductor device and the sidewall of the gate structure of the p-type semiconductor device intersect to form an interior angle smaller than the interior angle of the gate structure of the n-type semiconductor device.

A method includes providing a workpiece. The workpiece includes a substrate, a fin protruding from the substrate, and a dummy gate structure over the fin. The method further includes performing an oxidizing process to exposed surfaces of the fin and the dummy gate structure to form an oxide layer thereon, removing the oxide layer to expose an unoxidized top surface and sidewalls of the fin and unoxidized sidewalls of the dummy gate structure, epitaxially growing a cap layer on the unoxidized top surface and sidewalls of the fin and the unoxidized sidewalls of the dummy gate structure, forming a source/drain feature on the fin, and replacing the dummy gate structure with a metal gate structure.