Abstract: A semiconductor structure includes a first nanosheet field-effect transistor device having a plurality of first nanosheet channel layers and a first interfacial layer surrounding each of the plurality of first nanosheet channel layers, the first interfacial layer having a first thickness, and a second nanosheet field-effect transistor device vertically stacked above the first field-effect transistor nanosheet device, the second field-effect transistor nanosheet device having a plurality of second nanosheet channel layers and a second interfacial layer surrounding each of the plurality of second nanosheet channel layers, the second interfacial layer having a second thickness greater than the first thickness. A distance between each of the plurality of second nanosheet channel layers is less than a distance between each of the plurality of first nanosheet channel layers.

Abstract: Embodiments of the invention include forming a first transistor having first nanosheets, first dipole gate dielectric material being formed around the first nanosheets. An aspect includes forming a second transistor comprising second nanosheets, second dipole gate dielectric material being formed around the second nanosheets, the first and second transistors being in a vertical stack, a first spacing between the first nanosheets being different from a second spacing between the second nanosheets. An aspect includes forming a workfunction metal stack having a first workfunction metal and a second workfunction metal, the first and second workfunction metals being formed between the first nanosheets, the first workfunction metal being formed to pinch off in the second spacing between the second nanosheets such that the second workfunction metal is absent in the second spacing between the second nanosheets.

Abstract: Structures and methods are provided for integrating a resistance random access memory (ReRAM) in a back-end-on-the-line (BEOL) fat wire level. In one embodiment, a ReRAM device area contact structure is provided in the BEOL fat wire level that has at least a lower via portion that contacts a surface of a top electrode of a ReRAM device area ReRAM-containing stack. In other embodiments, a tall ReRAM device area bottom electrode is provided in the BEOL fat wire level and embedded in a dielectric material stack that includes a dielectric capping layer and an interlayer dielectric material layer.

Abstract: Metal-insulator-metal capacitor designs with increased reliability are provided. In one aspect, a capacitor includes: first and second electrodes; and multiple dielectric layers present in between the first and second electrodes, including a first buffer layer disposed on the first electrode, a ferroelectric film disposed on the first buffer layer, and a second buffer layer disposed on the ferroelectric film, where the ferroelectric film includes a combination of at least a first dielectric material and a second dielectric material having a higher ? value than either the first or second buffer layers. The first and second dielectric materials can each include HfO2 and/or ZrO2, in a crystalline phase, which can be combined in a common layer, or present in different layers. A capacitor device having the present capacitors stacked one on top of another is also provided, as is a method of forming the present capacitors.

Abstract: Structures and methods are provided for integrating a resistance random access memory (ReRAM) in a back-end-on-the-line (BEOL) fat wire level. In one embodiment, a ReRAM device area contact structure is provided in the BEOL fat wire level that has at least a lower via portion that contacts a surface of a top electrode of a ReRAM device area ReRAM-containing stack. In other embodiments, a tall ReRAM device area bottom electrode is provided in the BEOL fat wire level and embedded in a dielectric material stack that includes a dielectric capping layer and an interlayer dielectric material layer.

Abstract: A semiconductor structure, and a method of making the same includes a multiple electrode stacked capacitor containing a sequence of first metal layers interleaved with second metal layers. A quad-layer stack separates each of the first metal layers from each of the second metal layers, the quad-layer dielectric stack includes a first dielectric layer made of Al2O3, a second dielectric layer made of HfO2, a third dielectric layer made of Al2O3, and a fourth dielectric layer made of HfO2.

Abstract: A technique relates to a semiconductor device. A gate stack is formed on a fin, the gate stack being formed to have a length in a vertical direction. A gate contact is formed adjacent to the gate stack for the length of the gate stack in the vertical direction.

Abstract: A technique relates to a semiconductor device. A gate stack is formed on a fin, the gate stack being formed to have a length in a vertical direction. A gate contact is formed adjacent to the gate stack for the length of the gate stack in the vertical direction.

Abstract: A semiconductor device includes an n-type field effect transistor (nFET) including a first fin and a first metal gate formed on the first fin, and a p-type field effect transistor (pFET) including a second fin and a second metal gate formed on the second fin, a thickness of the second metal gate being substantially the same as a thickness of the first metal gate.

Abstract: A semiconductor device includes an n-type field effect transistor (nFET) including a first fin and a first metal gate formed on the first fin, and a p-type field effect transistor (pFET) including a second fin and a second metal gate formed on the second fin, a thickness of the second metal gate being substantially the same as a thickness of the first metal gate.

Abstract: A method of forming a semiconductor device, includes forming a first work function metal and sacrificial layer on an n-type field effect transistor (nFET) and on a p-type field effect transistor (pFET), removing the sacrificial layer and the first work function metal from one of the nFET and the pFET, forming a second work function metal on the one of the nFET and the pFET, a thickness of the second work function metal being substantially the same as a thickness of the first work function metal, and removing the sacrificial layer from the other of the nFET and the pFET.

Abstract: A method of forming a semiconductor device, includes forming a first work function metal and sacrificial layer on an n-type field effect transistor (nFET) and on a p-type field effect transistor (pFET), removing the sacrificial layer and the first work function metal from one of the nFET and the pFET, forming a second work function metal on the one of the nFET and the pFET, a thickness of the second work function metal being substantially the same as a thickness of the first work function metal, and removing the sacrificial layer from the other of the nFET and the pFET.

Abstract: In one exemplary embodiment, a method includes: forming at least one first monolayer of first material on a surface of a substrate by performing a first plurality of cycles of atomic layer deposition; thereafter, annealing the formed at least one first monolayer of first material under a first inert atmosphere at a first temperature between about 650° C. and about 900° C.; thereafter, forming at least one second monolayer of second material by performing a second plurality of cycles of atomic layer deposition, where the formed at least one second monolayer of second material at least partially overlies the annealed at least one first monolayer of first material; and thereafter, annealing the formed at least one second monolayer of second material under a second inert atmosphere at a second temperature between about 650° C. and about 900° C.

Abstract: In one exemplary embodiment, a method includes: forming at least one first monolayer of first material on a surface of a substrate by performing a first plurality of cycles of atomic layer deposition; thereafter, annealing the formed at least one first monolayer of first material under a first inert atmosphere at a first temperature between about 650° C. and about 900° C.; thereafter, forming at least one second monolayer of second material by performing a second plurality of cycles of atomic layer deposition, where the formed at least one second monolayer of second material at least partially overlies the annealed at least one first monolayer of first material; and thereafter, annealing the formed at least one second monolayer of second material under a second inert atmosphere at a second temperature between about 650° C. and about 900° C.

Abstract: A semiconductor device containing a diffusion barrier layer is provided. The semiconductor device includes at least a semiconductor substrate containing conductive metal elements; and, a diffusion barrier layer applied to at least a portion of the substrate in contact with the conductive metal elements, the diffusion barrier layer having an upper surface and a lower surface and a central portion, and being formed from silicon, carbon, nitrogen and hydrogen with the nitrogen being non-uniformly distributed throughout the diffusion barrier layer. Thus, the nitrogen is more concentrated near the lower and upper surfaces of the diffusion barrier layer as compared to the central portion of the diffusion barrier layer. Methods for making the semiconductor devices are also provided.