A vertical field effect transistor (VFET) cell implementing a VFET circuit over a plurality of gate grids includes: a 1.sup.st circuit including at least one VFET and provided over at least one gate grid; and a 2.sup.nd circuit including at least one VFET and provided over at least one gate grid formed on a left or right side of the 1.sup.st circuit, wherein a gate of the VFET of the 1.sup.st circuit is configured to share a gate signal or a source/drain signal of the VFET of the 2.sup.nd circuit, and the 1.sup.st circuit is an (X−1)-contacted poly pitch (CPP) circuit, which is (X−1) CPP wide, converted from an X-CPP circuit which is X CPP wide and performs a same logic function as the (X−1)-CPP circuit, X being an integer greater than 1.

An integrated circuit structure having a stacked transistor architecture includes a first semiconductor body (e.g., set of one or more nanoribbons) and a second semiconductor body (e.g., set of one or more nanoribbons) above the first semiconductor body. The first and second semiconductor bodies are part of the same fin structure. The distance between an upper surface of the first semiconductor body and a lower surface of the second semiconductor body is 60 nm or less. A first gate structure is on the first semiconductor body, and a second gate structure is on the second semiconductor body. An isolation structure that includes a dielectric material is between the first and second gate structures, and on the first gate structure. In addition, at least a portion of the second gate structure is on a central portion of the isolation structure and between first and second end portions of the isolation structure.

An integrated circuit structure having a stacked transistor architecture includes a first semiconductor body (e.g., set of one or more nanoribbons) and a second semiconductor body (e.g., set of one or more nanoribbons) above the first semiconductor body. The first and second semiconductor bodies are part of the same fin structure. The distance between an upper surface of the first semiconductor body and a lower surface of the second semiconductor body is 60 nm or less. A first gate structure is on the first semiconductor body, and a second gate structure is on the second semiconductor body. An isolation structure that includes a dielectric material is between the first and second gate structures, and on the first gate structure. In addition, at least a portion of the second gate structure is on a central portion of the isolation structure and between first and second end portions of the isolation structure.

A semiconductor device includes a substrate; and a cell region having opposite first and second sides, the cell region including active regions formed in the substrate; relative to an imaginary first reference line, a first majority of the active regions having first ends which align with the first reference line, the first side being parallel and proximal to the first reference line; relative to an imaginary second reference line in the second direction, a second majority of the active regions having second ends which align with the second reference line, the second side being parallel and proximal to the second reference line; and gate structures correspondingly on first and second ones of the active regions; and relative to the second direction, a first end of a selected one of the gate structures abuts an intervening region between the first and second active regions.

A method for making a semiconductor structure includes forming a first fin and a second fin over a substrate. The method includes forming one or more work function layers over the first and second fins. The method includes forming a nitride-based metal film over the one or more work function layers. The method includes covering the first fin with a patternable layer. The method includes removing a second portion of the nitride-based metal film from the second fin, while leaving a first portion of the nitride-based metal film over the first fin substantially intact.

A semiconductor device with different configurations of gate structures and a method of fabricating the same are disclosed. The semiconductor device includes a first gate structure and a second gate structure. The first gate structure includes a first interfacial oxide (IO) layer, a first high-K (HK) dielectric layer disposed on the first interfacial oxide layer, and a first dipole layer disposed at an interface between the first IL layer and the first HK dielectric layer. The HK dielectric layer includes a rare-earth metal dopant or an alkali metal dopant. The second gate structure includes a second IL layer, a second HK dielectric layer disposed on the second IL layer, and a second dipole layer disposed at an interface between the second IL layer and the second HK dielectric layer. The second HK dielectric layer includes a transition metal dopant and the rare-earth metal dopant or the alkali metal dopant.

In a method of manufacturing a semiconductor device, first and second fin structures are formed over a substrate, an isolation insulating layer is formed over the substrate, a gate structure is formed over channel regions of the first and second fin structures, source/drain regions of the first and second fin structure are recessed, and an epitaxial source/drain structure is formed over the recessed first and second fin structures. The epitaxial source/drain structure is a merged structure having a merger point, and a height of a bottom of the merger point from an upper surface of the isolation insulating layer is 50% or more of a height of the channel regions of the first and second fin structures from the upper surface of the isolation insulating layer.

A semiconductor device with different configurations of contact structures and a method of fabricating the same are disclosed. The method includes forming first and second fin structures on a substrate, forming n- and p-type source/drain (S/D) regions on the first and second fin structures, respectively, forming first and second oxidation stop layers on the n- and p-type S/D regions, respectively, epitaxially growing first and second semiconductor layers on the first and second oxidation stop layers, respectively, converting the first and second semiconductor layers into first and second semiconductor oxide layers, respectively, forming a first silicide-germanide layer on the p-type S/D region, and forming a second silicide-germanide layer on the first silicide-germanide layer and on the n-type S/D region.

A method of forming a semiconductor device includes: forming a fin structure protruding above a substrate, where the fin structure includes a fin and a layer stack over the fin, the layer stack comprising alternating layers of a first semiconductor material and a second semiconductor material; forming a first dummy gate structure and a second dummy gate structure over the fin structure; forming an opening in the fin structure between the first dummy gate structure and the second dummy gate structure; converting an upper layer of the fin exposed at a bottom of the opening into a seed layer by performing an implantation process; selectively depositing a dielectric layer over the seed layer at the bottom of the opening; and selectively growing a source/drain material on opposing sidewalls of the second semiconductor material exposed by the opening.

A method of forming a semiconductor device includes: forming a fin structure protruding above a substrate, where the fin structure includes a fin and a layer stack over the fin, the layer stack comprising alternating layers of a first semiconductor material and a second semiconductor material; forming a first dummy gate structure and a second dummy gate structure over the fin structure; forming an opening in the fin structure between the first dummy gate structure and the second dummy gate structure; converting an upper layer of the fin exposed at a bottom of the opening into a seed layer by performing an implantation process; selectively depositing a dielectric layer over the seed layer at the bottom of the opening; and selectively growing a source/drain material on opposing sidewalls of the second semiconductor material exposed by the opening.