A semiconductor device and a fabricating method thereof are provided. The semiconductor device includes a substrate, a first nanowire spaced apart from a first region of the substrate, a first gate electrode surrounding a periphery of the first nanowire, a second nanowire spaced apart from a second region of the substrate and extending in a first direction and having a first width in a second direction intersecting the first direction, a supporting pattern contacting the second nanowire and positioned under the second nanowire, and a second gate electrode extending in the second direction and surrounding the second nanowire and the supporting pattern.

Techniques are disclosed for forming thin-film transistors (TFTs) with low contact resistance. As disclosed in the present application, the low contact resistance can be achieved by intentionally thinning one or both of the source/drain (S/D) regions of the thin-film layer of the TFT device. As the TFT layer may have an initial thickness in the range of 20-65 nm, the techniques for thinning the S/D regions of the TFT layer described herein may reduce the thickness in one or both of those S/D regions to a resulting thickness of 3-10 nm, for example. Intentionally thinning one or both of the S/D regions of the TFT layer induces more electrostatic charges inside the thinned S/D region, thereby increasing the effective dopant in that S/D region. The increase in effective dopant in the thinned S/D region helps lower the related contact resistance, thereby leading to enhanced overall device performance.

Manufacturable spin and spin-polaron interconnects are disclosed that do not exhibit the same increase in resistivity shown by Cu interconnects associated with decreasing linewidth. These interconnects rely on the transmission of spin as opposed to charge. Two types of graphene based interconnect approaches are explored, one involving the injection and diffusive transport of discrete spin-polarized carriers, and the other involving coherent spin polarization of graphene charge carriers due to exchange interactions with localized substrate spins. Such devices are manufacturable as well as scalable (methods for their fabrication exist, and the interconnects are based on direct growth, rather than physical transfer or metal catalyst formation). Performance at or above 300 K, as opposed to cryogenic temperatures, is the performance criteria.

A semiconductor device includes a stacked structure having channel formation region layers CH.sub.1 and CH.sub.2, gate electrode layers G.sub.1, G.sub.2, and G.sub.3 alternately arranged on a base, in which a lowermost layer of the stacked structure is formed with a 1.sup.st layer G.sub.1 of the gate electrode layers, an uppermost layer of the stacked structure is formed with an N.sup.th (where N≥3) layer G.sub.3 of the gate electrode layers, the gate electrode layers each have a first end face, a second end face, a third end face opposing the first end face, and a fourth end face opposing the second end face, the first end face of odd-numbered layers G.sub.1, G.sub.3 of the gate electrode layers is connected to a first contact portion, and the third end face of an even-numbered layer G.sub.2 of the gate electrode layers is connected to a second contact portion.

An integrated circuit includes: a germanium-containing fin structure above a layer of insulation material; a group III-V semiconductor material containing fin structure above the layer of insulation material; a first gate structure on a portion of the germanium-containing fin structure; a second gate structure on a portion of the group III-V semiconductor material containing fin structure; a first S/D region above the layer of insulation material and laterally adjacent to the portion of the germanium-containing fin structure, the first S/D region comprising a p-type impurity and at least one of silicon or germanium; a second S/D region above the layer of insulation material and laterally adjacent to the portion of the group III-V semiconductor material containing fin structure, the second S/D region comprising an n-type impurity and a second group III-V semiconductor material; and a layer comprising germanium between the layer of insulation material and the second S/D region.

Embodiments disclosed herein include semiconductor devices and methods of forming such devices. In an embodiment, a semiconductor device comprises a stack of semiconductor channels with a first end and second end. In an embodiment, individual ones of the semiconductor channels comprise a nitrided surface. In an embodiment, the semiconductor device further comprises a source region at the first end of the stack and a drain region at the second end of the stack. In an embodiment, a gate dielectric surrounds the semiconductor channels, and a gate electrode surrounding the gate dielectric.

A method of forming a semiconductor device includes: forming a first fin protruding above a substrate; forming first source/drain regions over the first fin; forming a first plurality of nanostructures over the first fin between the first source/drain regions; forming a first gate structure around the first plurality of nanostructures; and forming a first ferroelectric capacitor over and electrically coupled to the first gate structure.

A transistor structure includes a first channel layer over a second channel layer, where the first and the second channel layers include a monocrystalline transition metal dichalcogenide (TMD). The transistor structure further includes a source material coupled to a first end of the first and second channel layers, a drain material coupled to a second end of the first and second channel layers, a gate electrode between the source material and the drain material, and between the first channel layer and the second channel layer and a gate dielectric between the gate electrode and each of the first channel layer and the second channel layer.

Embodiments disclosed herein include forksheet transistor devices with depopulated channels. In an example, an integrated circuit structure includes a backbone. A first transistor device includes a first vertical stack of semiconductor channels adjacent to a first edge of the backbone. The first vertical stack of semiconductor channels includes first semiconductor channels and a second semiconductor channel over or beneath the first semiconductor channels. A concentration of a dopant in the first semiconductor channels is less than a concentration of the dopant in the second semiconductor channel. A second transistor device includes a second vertical stack of semiconductor channels adjacent to a second edge of the backbone opposite the first edge.

Embodiments disclosed herein include semiconductor devices and methods of making such devices. In an embodiment, the semiconductor device comprises a plurality of stacked semiconductor channels comprising first semiconductor channels and second semiconductor channels over the first semiconductor channels. In an embodiment a spacing is between the first semiconductor channels and the second semiconductor channels. The semiconductor device further comprises a gate dielectric surrounding individual ones of the semiconductor channels of the plurality of stacked semiconductor channels. In an embodiment, a first workfunction metal surrounds the first semiconductor channels, and a second workfunction metal surrounds the second semiconductor channels.