Semiconductor structures and methods for manufacturing the same are provided. The semiconductor structure includes a substrate and semiconductor material layers stacked along a first direction over the substrate and spaced apart from each other. The semiconductor structure also includes inner spacers stacked along the first direction in spaces between the semiconductor material layers and a gate structure extending along a second direction and wrapping around the semiconductor material layers. In addition, the gate structure abuts a first side of the inner spacers. The semiconductor structure also includes a source/drain structure formed over the isolating feature and abutting the second side of the inner spacers.

An integrated circuit (IC) structure with a nanowire power switch device and a method of forming the IC structure are disclosed. The IC structure includes a front end of line (FEOL) device layer having a plurality of active devices, a first back end of line (BEOL) interconnect structure on the (FEOL) device layer, and a nanowire switch on the first BEOL interconnect structure. A first end of the nanowire switch is connected to an active device of the plurality of active devices through the first BEOL interconnect structure. The IC structure further includes a second BEOL interconnect structure on the nanowire switch. A second end of the nanowire switch is connected to a power source through the second BEOL interconnect structure and the second end is opposite to the first end.

Integrated circuit structures having metal-containing source or drain structures, and methods of fabricating integrated circuit structures having metal-containing source or drain structures, are described. For example, an integrated circuit structure includes a vertical arrangement of horizontal nanowires. A gate stack is around the vertical arrangement of horizontal nanowires. A first epitaxial source or drain structure is at a first end of the vertical arrangement of horizontal nanowires, and a second epitaxial source or drain structure is at a second end of the vertical arrangement of horizontal nanowires. The first and second epitaxial source or drain structures include a metal species diffused therein, the metal species further diffused partially into the vertical arrangement of horizontal nanowires.

Semiconductor devices, FinFET devices and methods of forming the same are disclosed. One of the semiconductor devices includes a substrate and a gate strip disposed over the substrate. The gate strip includes a high-k layer disposed over the substrate, an N-type work function metal layer disposed over the high-k layer, and a barrier layer disposed over the N-type work function metal layer. The barrier layer includes at least one first film containing TiAlN, TaAlN or AlN.

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.

Horizontal gate-all-around devices and methods of manufacturing same are described. The hGAA devices comprise a doped semiconductor material between source regions and drain regions of the device. The method includes doping semiconductor material layers between source regions and drain regions of an electronic device.

InGaN offers a route to high efficiency overall water splitting under one-step photo-excitation. Further, the chemical stability of metal-nitrides supports their use as an alternative photocatalyst. However, the efficiency of overall water splitting using InGaN and other visible light responsive photocatalysts has remained extremely low despite prior art work addressing optical absorption through band gap engineering. Within this prior art the detrimental effects of unbalanced charge carrier extraction/collection on the efficiency of the four electron-hole water splitting reaction have remained largely unaddressed. To address this growth processes are presented that allow for controlled adjustment and establishment of the appropriate Fermi level and/or band bending in order to allow the photochemical water splitting to proceed at high rate and high efficiency. Beneficially, establishing such material surface charge properties also reduces photo-corrosion and instability under harsh photocatalysis conditions.

Provided herein are tapered nanowires that comprise germanium and gallium, as well as methods of forming the same. The described nanowires may also include one or more sections of a second semiconductor material. Methods of the disclosure may include vapor-liquid-solid epitaxy with a gallium catalyst. The described methods may also include depositing a gallium seed on a surface of a substrate by charging an area of the substrate using an electron beam, and directing a gallium ion beam across the surface of the substrate.

An integrated circuit device includes a first-type active-region semiconductor structure, a first gate-conductor, a second-type active-region semiconductor structure that is stacked with the first-type active-region semiconductor structure, and a second gate-conductor. The integrated circuit device also includes a front-side conductive layer above the two active-region semiconductor structures and a back-side conductive layer below the two active-region semiconductor structures. The integrated circuit device also includes a front-side power rail and a front-side signal line in the front-side conductive layer and includes a back-side power rail and a back-side signal line in the back-side conductive layer. The integrated circuit device also includes a first source conductive segment connected to the front-side power rail and a second source conductive segment connected to the back-side power rail. The integrated circuit device further includes a drain conductive segment connected to either the front-side signal line or the back-side signal line.

A method of manufacturing a device including micrometer- or nanometer-range wires including a III-V compound, including, for each wire, the forming of at least a portion of the wire by a step of metal-organic vapor epitaxy including the injection into a reactor of a first precursor gas of the group-V element, of a second precursor gas of the group-III element, and of a third precursor gas of an additional element, dopant of the III-V compound, of a gas capable of obtaining a dopant concentration greater than 5.10.sup.19 atoms/cm.sup.3, for example, greater than 1.10.sup.20 atoms/cm.sup.3, in the wire portion in the case where the portion has a homogeneous dopant concentration.