A method for forming a doped layer is disclosed. The doped layer may be used in a NMOS or a silicon germanium application. The doped layer may be created using an n-type halide species in a n-type dopant application, for example.

A method for growth and fabrication of semipolar (Ga,Al,In,B)N thin films, heterostructures, and devices, comprising identifying desired material properties for a particular device application, selecting a semipolar growth orientation based on the desired material properties, selecting a suitable substrate for growth of the selected semipolar growth orientation, growing a planar semipolar (Ga,Al,In,B)N template or nucleation layer on the substrate, and growing the semipolar (Ga,Al,In,B)N thin films, heterostructures or devices on the planar semipolar (Ga,Al,In,B)N template or nucleation layer. The method results in a large area of the semipolar (Ga,Al,In,B)N thin films, heterostructures, and devices being parallel to the substrate surface.

After a sputtering gas is supplied to a deposition chamber, plasma including an ion of the sputtering gas is generated in the vicinity of a target. The ion of the sputtering gas is accelerated and collides with the target, so that flat-plate particles and atoms of the target are separated from the target. The flat-plate particles are deposited with a gap therebetween so that the flat plane faces a substrate. The atom and the aggregate of the atoms separated from the target enter the gap between the deposited flat-plate particles and grow in the plane direction of the substrate to fill the gap. A film is formed over the substrate. After the deposition, heat treatment is performed at high temperature in an oxygen atmosphere, which forms an oxide with a few oxygen vacancies and high crystallinity.

A wafer includes a buried substrate; a layer of silicon (100) disposed on the buried substrate and forming multiple U-shaped grooves, wherein each U-shaped groove comprises a bottom portion and silicon sidewalls (111) at an angle to the buried substrate; a buffer layer disposed within the multiple U-shaped grooves; and multiple gallium nitride (GaN)-based structures having vertical sidewalls disposed within and protruding above the multiple U-shaped grooves, the multiple GaN-based structures each including cubic gallium nitride (c-GaN) formed at merged growth fronts of hexagonal gallium nitride (h-GaN) that extend from the silicon sidewalls (111).

A semiconductor device with a small variation in characteristics is provided. The semiconductor device includes a first insulator; a second insulator having an opening over the first insulator; a third insulator that has a first depressed portion and is provided inside the opening; a first oxide that has a second depressed portion and is provided inside the first depressed portion; a second oxide provided inside the second depressed portion; a first conductor and a second conductor that are electrically connected to the second oxide and are apart from each other; a fourth insulator over the second oxide; and a third conductor including a region overlapping with the second oxide with the fourth insulator therebetween. The second oxide includes a first region, a second region, and a third region sandwiched between the first region and the second region in a top view. The first conductor includes a region overlapping with the first region and the second insulator. The second conductor includes a region overlapping with the second region and the second insulator. The third conductor includes a region overlapping with the third region.

A method includes forming a protruding semiconductor stack including a plurality of sacrificial layers and a plurality of nanostructures, with the plurality of sacrificial layers and the plurality of nanostructures being laid out alternatingly. The method further includes forming a dummy gate structure on the protruding semiconductor stack, etching the protruding semiconductor stack to form a source/drain recess, and forming a source/drain region in the source/drain recess. The formation of the source/drain region includes growing first epitaxial layers. The first epitaxial layers are grown on sidewalls of the plurality of nanostructures, and a cross-section of each of the first epitaxial layers has a quadrilateral shape. The first epitaxial layers have a first dopant concentration. The formation of the source/drain region further includes growing a second epitaxial layer on the first epitaxial layers. The second epitaxial layer has a second dopant concentration higher than the first dopant concentration.

A method includes depositing a first semiconductor layer and a second semiconductor layer over a substrate; patterning the first semiconductor layer, the second semiconductor layer, and the substrate to form a first nanostructure, a second nanostructure, and a semiconductor fin; forming a recess in the first nanostructure and the second nanostructure, the recess exposing the semiconductor fin; epitaxially growing a first layer in the recess, a first portion of the first layer being disposed along a first sidewall of the first nanostructure, a second portion of the first layer being disposed along the semiconductor fin, the first portion of the first layer comprising two sidewalls extending toward a middle of the recess, the first portion of the first layer further comprising a first surface most distal from the first sidewall and directly interposed between the two sidewalls, the first portion being physically separated from the second portion; and epitaxially growing a second layer over the first portion of the first layer and over the second portion of the first layer, the second layer physically connecting the first portion of the first layer to the second portion of the first layer.

The embodiments described herein are directed to a method for reducing fin oxidation during the formation of fin isolation regions. The method includes providing a semiconductor substrate with an n-doped region and a p-doped region formed on a top portion of the semiconductor substrate; epitaxially growing a first layer on the p-doped region; epitaxially growing a second layer different from the first layer on the n-doped region; epitaxially growing a third layer on top surfaces of the first and second layers, where the third layer is thinner than the first and second layers. The method further includes etching the first, second, and third layers to form fin structures on the semiconductor substrate and forming an isolation region between the fin structures.

Structures including a compound-semiconductor-based device and a silicon-based device integrated on a semiconductor substrate and methods of forming such structures. The structure includes a first semiconductor layer having a top surface and a faceted surface that fully surrounds the top surface. The top surface has a first surface normal, and the faceted surface has a second surface normal that is inclined relative to the first surface normal. A layer stack that includes second semiconductor layers is positioned on the faceted surface of the first semiconductor layer. Each of the second semiconductor layers contains a compound semiconductor material. A silicon-based device is located on the top surface of the first semiconductor layer, and a compound-semiconductor-based device is located on the layer stack.

The embodiments described herein are directed to a method for reducing fin oxidation during the formation of fin isolation regions. The method includes providing a semiconductor substrate with an n-doped region and a p-doped region formed on a top portion of the semiconductor substrate; epitaxially growing a first layer on the p-doped region; epitaxially growing a second layer different from the first layer on the n-doped region; epitaxially growing a third layer on top surfaces of the first and second layers, where the third layer is thinner than the first and second layers. The method further includes etching the first, second, and third layers to form fin structures on the semiconductor substrate and forming an isolation region between the fin structures.