Films are modified to include deuterium in an inductive high density plasma chamber. Chamber hardware designs enable tunability of the deuterium concentration uniformity in the film across a substrate. Manufacturing of solid state electronic devices include integrated process flows to modify a film that is substantially free of hydrogen and deuterium to include deuterium.

The present disclosure describes a semiconductor device with counter-doped nanostructures and a method for forming the semiconductor device. The method includes forming a fin structure on a substrate, the fin structure including one or more first-type nanostructures and one or more second-type nanostructures. The method further includes forming a polysilicon structure over the fin structure and forming a source/drain (S/D) region on a portion of the fin structure and adjacent the polysilicon structure, the S/D region including a first dopant. The method further includes doping the one or more second-type nanostructures with a second dopant via a space released by the polysilicon structure and the one or more first-type nanostructures, where the second dopant is opposite to the first dopant. The method further includes replacing portions of the one or more doped second-type nanostructures with additional second-type nanostructures.

An apparatus may include a main chamber, a substrate holder, disposed in a lower region of the main chamber, and defining a substrate region, as well as an RF applicator, disposed adjacent an upper region of the main chamber, to generate an upper plasma within the upper region. The apparatus may further include a central chamber structure, disposed in a central portion of the main chamber, where the central chamber structure is disposed to shield at least a portion of the substrate position from the upper plasma. The apparatus may include a bias source, electrically coupled between the central chamber structure and the substrate holder, to generate a glow discharge plasma in the central portion of the main chamber, wherein the substrate region faces the glow discharge region.

A semiconductor device has a first trench and a second trench of a trench structure located in a substrate. The second trench is separated from the first trench by a trench space that is less than a first trench width of the first trench and less than a second trench width of the second trench. The trench structure includes a doped sheath having a first conductivity type, contacting and laterally surrounding the first trench and the second trench. The doped sheath extends from the top surface to an isolation layer and from the first trench to the second trench across the trench space. The semiconductor device includes a first region and a second region, both located in the semiconductor layer, having a second, opposite, conductivity type. The first region and the second region are separated by the first trench, the second trench, and the doped sheath.

A method for forming an overlap transistor includes forming a gate structure over a III-V material, wet cleaning the III-V material on side regions adjacent to the gate structure and plasma cleaning the III-V material on the side regions adjacent to the gate structure. The III-V material is plasma doped on the side regions adjacent to the gate structure to form plasma doped extension regions that partially extend below the gate structure.

A semiconductor device having an impurity region is provided. The semiconductor device includes a fin active region having protruding regions and a recessed region between the protruding regions. Gate structures overlapping the protruding regions are disposed. An epitaxial layer is disposed in the recessed region to have a height greater than a width. An impurity region is disposed in the fin active region, surrounds side walls and a bottom of the recessed region, has the same conductivity type as a conductivity type of the epitaxial layer, and includes a majority impurity that is different from a majority impurity included in at least a portion of the epitaxial layer.

A graphene compound made from the method of preparing graphene flakes or chemical vapor deposition grown graphene films on a SiO.sub.2/Si substrate; exposing the graphene flakes or the chemical vapor deposition grown graphene film to hydrogen plasma; performing hydrogenation of the graphene; wherein the hydrogenated graphene has a majority carrier type; creating a bandgap from the hydrogenation of the graphene; applying an electric field to the hydrogenated graphene; and tuning the bandgap.

A method for fabricating semiconductor device is disclosed. First, a substrate having a fin-shaped structure thereon is provided, a spacer is formed adjacent to the fin-shaped structure, and the spacer is used as mask to remove part of the substrate for forming an isolation trench, in which the isolation trench includes two sidewall portions and a bottom portion. Next, a plasma doping process is conducted to implant dopants into the two sidewall portions and the bottom portion of the isolation trench.

Ferroelectric structures, including a ferroelectric field effect transistors (FeFETs), and methods of making the same are disclosed which have improved ferroelectric properties and device performance. A FeFET device including a ferroelectric material gate dielectric layer and a metal oxide semiconductor channel layer is disclosed having improved ferroelectric characteristics, such as increased remnant polarization, low defects, and increased carrier mobility for improved device performance.

A method includes forming a fin over a substrate, forming a dummy gate structure over the fin, forming a first spacer over the dummy gate structure, implanting a first dopant in the fin to form a doped region of the fin adjacent the first spacer, removing the doped region of the fin to form a first recess, wherein the first recess is self-aligned to the doped region, and epitaxially growing a source/drain region in the first recess.