Provided is a three-dimensional semiconductor device and its fabrication method. The semiconductor device includes a first active region on a substrate and including a plurality of lower channel patterns and a plurality of lower source/drain patterns that are alternately arranged along a first direction, a second active region on the first active region and including a plurality of upper channel patterns and a plurality of upper source/drain patterns that are alternately arranged along the first direction, a first gate electrode on a first lower channel pattern of the lower channel patterns and on a first upper channel pattern of the upper channel patterns, and a second gate electrode on a second lower channel pattern of the lower channel patterns and on a second upper channel pattern of the upper channel patterns. The second gate electrode may include lower and upper gate electrodes with an isolation pattern interposed therebetween.

Source/drain silicide that improves performance and methods for fabricating such are disclosed herein. An exemplary device includes a first channel layer disposed over a substrate, a second channel layer disposed over the first channel layer, and a gate stack that surrounds the first channel layer and the second channel layer. A source/drain feature disposed adjacent the first channel layer, second channel layer, and gate stack. The source/drain feature is disposed over first facets of the first channel layer and second facets of the second channel layer. The first facets and the second facets have a (111) crystallographic orientation. An inner spacer disposed between the gate stack and the source/drain feature and between the first channel layer and the second channel layer. A silicide feature is disposed over the source/drain feature where the silicide feature extends into the source/drain feature towards the substrate to a depth of the first channel layer.

SRAM designs based on GAA transistors are disclosed that provide flexibility for increasing channel widths of transistors at scaled IC technology nodes and relax limits on SRAM performance optimization imposed by FinFET-based SRAMs. GAA-based SRAM cells described have active region layouts with active regions shared by pull-down GAA transistors and pass-gate GAA transistors. A width of shared active regions that correspond with the pull-down GAA transistors are enlarged with respect to widths of the shared active regions that correspond with the pass-gate GAA transistors. A ratio of the widths is tuned to obtain ratios of pull-down transistor effective channel width to pass-gate effective channel width greater than 1, increase an on-current of pull-down GAA transistors relative to an on-current of pass-gate GAA transistors, decrease a threshold voltage of pull-down GAA transistors relative to a threshold voltage of pass-gate GAA transistors, and/or increases a ratio of an SRAM cell.

Transistors include multiple stress liners. One or more channel structures are suspended at opposite ends from the plurality of stress liners. The stress liners provide a stress on the one or more channel structures. A gate is formed over and around the one or more channel structures, defining a channel region of the one or more channel structures that is covered by the gate. A source and drain region are formed on opposite sides of the gate.

Transistors and methods of forming the same include forming a fin of alternating layers of a channel material and a sacrificial material. Stress liners are formed in contact with both ends of the fin. The stress liners exert a stress on the fin. The sacrificial material is etched away from the fin, such that the layers of the channel material are suspended between the stress liners. A gate stack is formed over and around the suspended layers of channel material.

A two-dimensional heterostructure is synthesized by producing a patterned first two-dimensional material on a growth substrate. The first two-dimensional material is patterned to define at least one void through which an exposed region of the growth substrate is exposed. Seed molecules are selectively deposited either on the exposed region of the growth substrate or on the patterned first two-dimensional material. A second two-dimensional material that is distinct from the first two-dimensional material is then grown from the deposited seed molecules.

A nanosheet field effect transistor design in which the threshold voltage is adjustable by adjusting the composition of the gate. The channel of the nanosheet field effect transistor may be composed of a III-V semiconductor material, and the gate, which may be separated from the channel by a high dielectric constant dielectric layer, may also be composed of a III-V semiconductor material. Adjusting the composition of the gate may result in a change in the affinity of the gate, in turn resulting in a change in the threshold voltage. In some embodiments the channel is composed, for example, of In.sub.xGa.sub.1-xAs, with x between 0.23 and 0.53, and the gate is composed of InAs.sub.1-yN.sub.y with y between 0.0 and 0.4, and the values of x and y may be adjusted to adjust the threshold voltage.

Device architectures based on trapping and de-trapping holes or electrons and/or recombination of both types of carriers are obtained by carrier trapping either in near-interface deep ambipolar states or in quantum wells/dots, either serving as ambipolar traps in semiconductor layers or in gate dielectric/barrier layers. In either case, the potential barrier for trapping is small and retention is provided by carrier confinement in the deep trap states and/or quantum wells/dots. The device architectures are usable as three terminal or two terminal devices.

Techniques for dielectric isolation in bulk nanosheet devices are provided. In one aspect, a method of forming a nanosheet device structure with dielectric isolation includes the steps of: optionally implanting at least one dopant into a top portion of a bulk semiconductor wafer, wherein the at least one dopant is configured to increase an oxidation rate of the top portion of the bulk semiconductor wafer; forming a plurality of nanosheets as a stack on the bulk semiconductor wafer; patterning the nanosheets to form one or more nanowire stacks and one or more trenches between the nanowire stacks; forming spacers covering sidewalls of the nanowire stacks; and oxidizing the top portion of the bulk semiconductor wafer through the trenches, wherein the oxidizing step forms a dielectric isolation region in the top portion of the bulk semiconductor wafer. A nanowire FET and method for formation thereof are also provided.

A semiconductor structure, comprising a semiconductor substrate; at least one fin, wherein the at least one fin comprises one or more first layers and one or more second layers, wherein the first layers and the second layers are interspersed and the first layers laterally extend further than the second layers; a dummy gate structure comprising a first spacer material disposed on sidewalls of the dummy gate; a second spacer material disposed adjacent to each of the second layers, wherein sidewalls of the fin comprise exposed portions of each of the first layers and the second spacer material, and an epitaxial source/drain material disposed on at least the exposed portions of each of the first layers. Methods and systems for forming the semiconductor structure.