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.

Embodiments of this disclosure relate to methods for removing a dummy material from under a superlattice structure. In some embodiments, after removing the dummy material, it is replaced with a bottom dielectric isolation layer beneath the superlattice structure.

Some embodiments include an integrated assembly having a CMOS region with fins extending along a first direction, and with gating structures extending across the fins. A circuit arrangement is associated with the CMOS region and includes a pair of the gating structures spaced by an intervening region having a missing gating structure. The circuit arrangement has a first dimension along the first direction. A second region is proximate to the CMOS region. Conductive structures are associated with the second region. Some of the conductive structures are electrically coupled with the circuit arrangement. A second dimension is a distance across said some of the conductive structures along the first direction. The conductive structures and the circuit arrangement are aligned such that the second dimension is substantially the same as the first dimension. Some embodiments include methods of forming integrated assemblies.

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.

A semiconductor device including semiconductor material having a bend and a trench feature formed at the bend, and a gate structure at least partially disposed in the trench feature. A method of fabricating a semiconductor structure including forming a semiconductor material with a trench feature over a layer, forming a gate structure at least partially in the trench feature, and bending the semiconductor material such that stress is induced in the semiconductor material in an inversion channel region of the gate structure.

The present disclosure provides many different embodiments of a FinFET device that provide one or more improvements over the prior art. In one embodiment, a FinFET includes a semiconductor substrate and a plurality of fins having a first height and a plurality of fin having a second height on the semiconductor substrate. The second height may be less than the first height.

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.

An integrated circuit device including a substrate including first and second device regions; a first fin active region on the first device region; a second fin active region on the second device region; an isolation film covering side walls of the active regions; gate cut insulating patterns on the isolation film on the device regions; a gate line extending on the fin active regions, the gate line having a length limited by the gate cut insulating patterns; and an inter-region insulating pattern on the isolation film between the fin active regions and at least partially penetrating the gate line in a vertical direction, wherein the inter-region insulating pattern has a bottom surface proximate to the substrate, a top surface distal to the substrate, and a side wall linearly extending from the bottom to the top surface.

Various embodiments of the present application are directed towards a method to integrate NVM devices with a logic or BCD device. In some embodiments, an isolation structure is formed in a semiconductor substrate. The isolation structure demarcates a memory region of the semiconductor substrate, and further demarcates a peripheral region of the semiconductor substrate. The peripheral region may, for example, correspond to BCD device or a logic device. A doped well is formed in the peripheral region. A dielectric seal layer is formed covering the memory and peripheral regions, and further covering the doped well. The dielectric seal layer is removed from the memory region, but not the peripheral region. A memory cell structure is formed on the memory region using a thermal oxidation process. The dielectric seal layer is removed from the peripheral region, and a peripheral device structure including a gate electrode is formed on the peripheral region.