A method of preparing a carbon nanotube monolayer film includes applying a bifunctional hydrogen-bond linker onto a substrate to prepare a surface-treated substrate, mixing carbon nanotubes having a heteroatom-containing aromatic polymer coating film with a hydrophobic solvent to obtain a composition and contacting the surface-treated substrate with the composition, and heat-treating the surface-treated substrate contacting the composition.

A semiconductor device includes a first transistor formed on a first side of a substrate. The semiconductor device includes a first power rail structure vertically disposed over the first transistor, a second power rail structure vertically disposed over the first power rail structure, and a memory portion vertically disposed over the second power rail structure. The first power rail structure, and a second power rail structure, and the memory portion are all disposed on a second side of the substrate opposite to the first side.

A device includes a substrate, and a first semiconductor channel over the substrate. The first semiconductor channel includes a first nanosheet of a first semiconductor material, a second nanosheet of a second semiconductor material in physical contact with a topside surface of the first nanosheet, and a third nanosheet of the second semiconductor material in physical contact with an underside surface of the first nanosheet. The first gate structure is over and laterally surrounding the first semiconductor channel, and in physical contact with the second nanosheet and the third nanosheet.

Methods and semiconductor structures are provided. A method according to the present disclosure includes receiving a workpiece that includes a first gate structure disposed over a first active region, a second gate structure disposed over a second active region, a first gate spacer extending along a sidewall of the first gate structure and disposed at least partially over a top surface of the first active region, a second gate spacer extending along a sidewall of the second gate structure and disposed at least partially over a top surface of the second active region, and a source/drain feature. The method also includes treating a portion of the first gate spacer and a portion of the second gate spacer with a remote radical of hydrogen or oxygen, removing the treated portions, and after the removal, depositing a metal fill material over the source/drain feature.

A semiconductor structure includes a front-end-of-line level formed by a plurality of field effect transistors. Each field effect transistor includes a source/drain region disposed on opposite sides of the field effect transistor. A metal contact region is disposed above and in contact with a first surface of two adjacent source/drain regions. Each of the two adjacent source/drain regions correspond to a field effect transistor. A backside isolation region cuts through the metal contact region from a backside of the plurality of field effect transistors for electrically isolating the two adjacent source/drain regions.

Self-aligned gate endcap (SAGE) architectures with gate-all-around devices, and methods of fabricating self-aligned gate endcap (SAGE) architectures with gate-all-around devices, are described. In an example, an integrated circuit structure includes a semiconductor fin above a substrate and having a length in a first direction. A nanowire is over the semiconductor fin. A gate structure is over the nanowire and the semiconductor fin, the gate structure having a first end opposite a second end in a second direction, orthogonal to the first direction. A pair of gate endcap isolation structures is included, where a first of the pair of gate endcap isolation structures is spaced equally from a first side of the semiconductor fin as a second of the pair of gate endcap isolation structures is spaced from a second side of the semiconductor fin.

Systems and methods for detection of biological agents are generally described. Certain embodiments relate to circuits comprising a first semiconductor nanosensor and a second semiconductor nanosensor in electrical communication with the first semiconductor nanosensor. The circuit can be configured to output a differential electrical property between the first semiconductor nanosensor and the second semiconductor nanosensor when exposed to a sample comprising an analyte. In certain instances, the first semiconductor nanosensor is functionalized with a detector species, and the second semiconductor nanosensor is not functionalized with the detector species. In some cases, the first semiconductor nanosensor is functionalized with a detector species, and the second semiconductor nanosensor is associated with a gate.

A patterned stack of a first silicon-germanium alloy nanowire, a second silicon-germanium alloy nanowire, and a silicon-containing nanowire is formed on a substrate. After formation of a first dielectric isolation layer around the patterned stack, a disposable gate structure can be formed. End portions of the second silicon-germanium alloy nanowire are removed to form first cavities underlying end portions of the silicon-containing nanowire. Dielectric nanowires are formed in cavities concurrently with formation of a gate spacer. After recessing the first dielectric isolation layer, a second cavity is formed by removing the first silicon-germanium alloy nanowire. The second cavity is filled with a second dielectric isolation layer, and raised active regions can be formed by a selective epitaxy process. After formation of a planarization dielectric layer, the disposable gate structure and the remaining portion of the second silicon-germanium alloy nanowire with a replacement gate structure.

There is provided an electronic device and a method for its manufacture. The device comprises an elongate silicon nanowire less than 0.5 m in cross-sectional dimensions and having a hexagonal cross-sectional shape due to annealing-induced energy relaxation. The method, in examples, includes thinning the nanowire through iterative oxidation and etching of the oxidized portion.

Semiconductor structures and methods for crystalline junctionless transistors used in nonvolatile memory arrays are introduced. Various embodiments in accordance with this disclosure provide a method of fabricating a monolithic 3D cross-bar nonvolatile memory array with low thermal budget. The method incorporates crystalline junctionless transistors into nonvolatile memory structures by transferring a layer of doped crystalline semiconductor material from a seed wafer to form the source, drain, and connecting channel of the junctionless transistor.