A method includes providing a substrate, a semiconductor fin extending from the substrate, and a gate structure over the substrate and engaging the semiconductor fin; etching the semiconductor fin to form a trench; and epitaxially growing a semiconductor structure in the trench, which includes epitaxially growing a first semiconductor layer having silicon germanium (SiGe); epitaxially growing a second semiconductor layer having SiGe above the first semiconductor layer; epitaxially growing a third semiconductor layer having SiGe over the second semiconductor layer; and epitaxially growing a fourth semiconductor layer having SiGe and disposed at a corner portion of the semiconductor structure. Each of the first, second, third, and fourth semiconductor layers includes a p-type dopant, and the fourth semiconductor layer has a higher dopant concentration of the p-type dopant than each of the first, second, and third semiconductor layers.

Methods for depositing group 5 chalcogenides on a substrate are disclosed. The methods include cyclical deposition techniques, such as atomic layer deposition. The group 5 chalcogenides can be two-dimensional films having desirable electrical properties.

Methods of depositing a liner layer in a semiconductor device are described. In some embodiments, the method includes depositing a carbon layer including carbon on a substrate, the substrate having at least one feature including a sidewall surface and the carbon layer having a carbon surface; and selectively depositing the liner layer on the sidewall surface over the carbon surface. In other embodiments, the method includes depositing a carbon layer comprising carbon in a bottom second portion of a substrate feature selectively over a top first portion of the substrate feature, the top first portion having a sidewall surface, the carbon layer having a carbon surface; etching the carbon surface; and depositing the conformal layer on the sidewall surface of the top first portion, the conformal layer deposited on the sidewall surface selectively over the carbon surface.

The present disclosure relates to a multilayer semiconductor-on-insulator structure, comprising, successively from a rear face toward a front face of the structure: a semiconductor carrier substrate with high electrical resistivity, whose electrical resistivity is between 500 .Math.cm and 30 k.Math.cm, a first electrically insulating layer, an intermediate layer, a second electrically insulating layer, which has a thickness less than that of the first electrically insulating layer, an active semiconductor layer, the multilayer structure comprises: at least one FD-SOI region, in which the intermediate layer is an intermediate first semiconductor layer, at least one RF-SOI region, adjacent to the FD-SOI region, in which the intermediate layer is a third electrically insulating layer, the RF-SOI region comprising at least one radiofrequency component plumb with the third electrically insulating layer.

A process for producing nanoclusters of silicon and/or germanium exhibiting a permanent magnetic and/or electric dipole moment for adjusting the work function of materials, for micro- and nano-electronics, for telecommunications, for nano-ovens, for organic electronics, for photoelectric devices, for catalytic reactions and for fractionation of water.

A fin structure on a substrate is disclosed. The fin structure can comprises a first epitaxial region and a second epitaxial region separated by a dielectric region, a merged epitaxial region on the first epitaxial region and the second epitaxial region, an epitaxial buffer region on a top surface of the merged epitaxial region, and an epitaxial capping region on the buffer epitaxial region and side surfaces of the merged epitaxial region.

A method for depositing a film includes conducting electron-enhanced chemical vapor deposition with at least one hydride precursor, at least one reactive background gas, and electrons to deposit a film on a substrate with a positive substrate voltage. In an embodiment, the method is a method for depositing a silicon film, including conducting electron-enhanced chemical vapor deposition with at least one Si precursor, at least one reactive background gas, and electrons to deposit a silicon film on a substrate with a positive substrate voltage. In the embodiment, the at least one Si precursor can include Si.sub.2H.sub.6 and the at least one reactive background gas can include H.sub.2.

Methods for selective deposition are provided. Material is selectively deposited on a first surface of a substrate relative to a second surface of a different material composition. An inhibitor, such as a polyimide layer, is selectively formed from vapor phase reactants on the first surface relative to the second surface. A layer of interest is selectively deposited from vapor phase reactants on the second surface relative to the first surface. The first surface can be metallic while the second surface is dielectric. Accordingly, material, such as a dielectric transition metal oxides and nitrides, can be selectively deposited on metallic surfaces relative dielectric surfaces using techniques described herein.

A method for forming a film, including: atomizing a raw material solution into a mist to form raw material mist; mixing raw material mist and a carrier gas to form gas mixture; placing a substrate on a placement section of susceptor; supplying gas mixture from an atomizer to the substrate to perform film formation by thermal reaction on substrate; and discharging gas mixture after the film formation through an exhaust unit, wherein in the step of supplying the gas mixture from atomizer to substrate to perform film formation by thermal reaction on the substrate, at least a part of gas mixture is supplied from a smooth section adjacent to placement section to a surface of substrate, the smooth section having a surface roughness of 200 m or less. A method for forming a film capable of uniformly and stably producing a high-quality film on a surface of a large-diameter substrate.

Disclosed herein are compositions, methods, and devices. Disclosed herein is a composition comprising a -(Al.sub.xGa.sub.1-x).sub.2O.sub.3, having an x value of less than about 5% and comprising at least one n-carrier dopant. Also disclosed are methods of making the same. Also disclosed are devices comprising the disclosed compositions.