A semiconductor device comprises: a substrate including first and second buried source/drain layers; a first nano sheet stack including first nano sheets stacked in a direction vertical to the substrate; a second nano sheet stack including second nano sheets stacked in a direction vertical to the substrate; an isolation wall disposed between the first nano sheet stack and the second nano sheet stack; first gate covering portions of the first nano sheet stack and extending in a direction vertical to the substrate; second gate covering portions of the second nano sheet stack and extending in a direction vertical to the substrate; first common source/drain layers connected to end portions of the first nano sheets and to the first buried source/drain layers; and second common source/drain layers connected to end portions of the second nano sheets and to the second buried source/drain layers.

An integrated circuit (IC) with a semiconductor device and an interconnect structure with carbon layers and methods of fabricating the same are disclosed. The method includes forming a fin structure on a substrate, forming a source/drain region on the fin structure, forming a contact structure on the S/D region, forming an oxide layer on the contact structure, forming a conductive carbon line within a first insulating carbon layer on the oxide layer, forming a second insulating carbon layer on the first insulating carbon layer, and forming a via within the second insulating carbon layer.

A complementary field effect transistor (CFET) structure including a first transistor disposed above a second transistor, a first source/drain region of the first transistor disposed above a second source/drain region of the second transistor, wherein the first source/drain region comprises a smaller cross-section than the second source/drain region, a first dielectric material disposed in contact with a bottom surface and vertical surfaces of the first source/drain region and further in contact with a vertical surface and top surface of the second source/drain region, and a second dielectric material disposed as an interlayer dielectric material encapsulating the first and second transistors.

A semiconductor device may include a substrate, an n-channel field-effect transistor positioned on the substrate, and a p-channel field-effect transistor positioned on the substrate. The n-channel field-effect transistor may include an n-type silicide source portion, an n-type silicide drain portion, and a first n-type channel region. The first n-type channel region may be positioned between the n-type silicide source portion and the n-type silicide drain portion and may directly contact each of the n-type silicide source portion and the n-type silicide drain portion.

A semiconductor device includes a substrate, a first semiconductor fin, a second semiconductor fin, an n-type epitaxy structure, a p-type epitaxy structure, and a plurality of dielectric fin sidewall structures. The first semiconductor fin is disposed on the substrate. The second semiconductor fin is disposed on the substrate and adjacent to the first semiconductor fin. The n-type epitaxy structure is disposed on the first semiconductor fin. The p-type epitaxy structure is disposed on the second semiconductor fin and separated from the n-type epitaxy structure. The dielectric fin sidewall structures are disposed on opposite sides of at least one of the n-type epitaxy structure and the p-type epitaxy structure.

Fin Field Effect Transistor (FET) (FinFET) complementary metal oxide semiconductor (CMOS) circuits with single and double diffusion breaks for increased performance are disclosed. In one aspect, a FinFET CMOS circuit employing single and double diffusion breaks includes a P-type FinFET that includes a first Fin formed from a semiconductor substrate and corresponding to a P-type diffusion region. The FinFET CMOS circuit includes an N-type FinFET that includes a second Fin formed from the semiconductor substrate and corresponding to an N-type diffusion region. To electrically isolate the P-type FinFET, first and second single diffusion break (SDB) isolation structures are formed in the first Fin on either side of a gate of the P-type FinFET. To electrically isolate the N-type FinFET, first and second double diffusion break (DDB) isolation structures are formed in the second Fin on either side of a gate of the N-type FinFET.

Semiconductor structures having a source contact and a drain contact that exhibit reduced contact resistance and methods of forming the same are disclosed. In one embodiment of the present application, the reduced contact resistance is provided by forming a layer of a dipole metal or metal-insulator-semiconductor (MIS) oxide between an epitaxial semiconductor material (providing the source region and the drain region of the device) and an overlying metal semiconductor alloy. In yet other embodiment, the reduced contact resistance is provided by increasing the area of the source region and drain region by patterning the epitaxial semiconductor material that constitutes at least an upper portion of the source region and drain region of the device.

A manufacturing method of a semiconductor device, comprising the following steps: providing a semiconductor substrate comprising a low-voltage device region and a high-voltage device region; forming first gate oxide layers in a non-gate region of the high-voltage device region and the low-voltage device region and a second gate oxide layer in a gate region of the high-voltage device region; the thickness of the second gate oxide layer is greater than the thickness of the first gate oxide layer; forming a first polysilicon gate and a first sidewall structure on the surface of the first gate oxide layer of the low-voltage device region and a second polysilicon gate and a second sidewall structure on the surface of the second gate oxide layer; the width of the second gate oxide layer is greater than the width of the second polysilicon gate; performing source drain ions injection to form a source drain extraction region; after depositing a metal silicide area block (SAB), performing a photolithographic etching on the metal SAB and forming metal silicide. The above manufacturing method of a semiconductor device simplifies process steps and reduces process cost. The present invention also relates to a semiconductor device.

Semiconductor devices are provided. The semiconductor devices may include a first wire pattern extending in a first direction on a substrate and a second wire pattern on the first wire pattern. The second wire pattern may be spaced apart from the first wire pattern and extends in the first direction. The semiconductor devices may also include a first gate structure at least partially surrounding the first wire pattern and the second wire pattern, a second gate structure spaced apart from the first gate structure in the first direction, a first source/drain region between the first gate structure and the second gate structure, a first spacer between a bottom surface of the first source/drain region and the substrate, a first source/drain contact on the first source/drain region, and a second spacer between the first source/drain contact and the first gate structure.

A method of forming matched PFET/NFET spacers with differential widths for SG and EG structures and a method of forming differential width nitride spacers for SG NFET and SG PFET structures and PFET/NFET EG structures and respective resulting devices are provided. Embodiments include providing PFET SG and EG structures and NFET SG and EG structures; forming a first nitride layer over the substrate; forming an oxide liner; forming a second nitride layer on sidewalls of the PFET and NFET EG structures; removing horizontal portions of the first nitride layer and the oxide liner over the PFET SG and EG structures; forming RSD structures on opposite sides of each of the PFET SG and EG structures; removing horizontal portions of the first nitride layer and the oxide liner over the NFET SG and EG structures; and forming RSD structures on opposite sides of each of the NFET SG and EG structures.