A semiconductor structure comprises a layer of a first III-nitride material having a first lattice dimension; a non-porous layer of a second III-nitride material having a second lattice dimension different from the first lattice dimension; and a porous region of III-nitride material disposed between the layer of first III-nitride material and the non-porous layer of the second III-nitride material. An optoelectronic semiconductor device, an LED, and a method of manufacturing a semiconductor structure are also provided.

A mist-CVD apparatus contains a first atomizer for atomizing a first metal oxide precursor and generating a first mist of the first metal oxide precursor; a second atomizer for atomizing a second metal oxide precursor and generating a second mist of the second metal oxide precursor; a carrier-gas supplier for supplying a carrier gas to convey the first and second mists; a film-forming unit for forming a film on a substrate by subjecting the first and second mists to a thermal reaction; and a first conveyance pipe through which the first mist and the carrier gas are conveyed to the film forming chamber, a second conveyance pipe through which the second mist and the carrier gas are conveyed to the film forming chamber.

A method of producing a reduced-defect density crystalline silicon film includes forming a first intrinsic silicon film on a substrate, forming a doped film including silicon or germanium on the first intrinsic silicon film, forming a second intrinsic silicon film on the doped film, and annealing to crystallize the doped film, the second intrinsic silicon film, and the first intrinsic silicon, wherein each film is amorphous at formation, wherein crystallization initiates within the doped film. A method of forming a thin film transistor includes forming an active layer in the crystallized second intrinsic silicon layer by doping the crystallized second intrinsic silicon layer in selected areas to form source and drain regions separated by a channel portion, forming a gate insulator layer on the crystallized second intrinsic silicon layer, and forming a gate electrode pattern over the gate insulator layer.

A method for forming layers with silicon is disclosed. The layers may be created by positioning a substrate within a processing chamber, heating the substrate to a first temperature between 300 and 500° C. and introducing a first precursor into the processing chamber to deposit a first layer. The substrate may be heated to a second temperature between 400 and 600° C.; and, a second precursor may be introduced into the processing chamber to deposit a second layer. The first and second precursor may comprise silicon atoms and the first precursor may have more silicon atoms per molecule than the second precursor.

A semiconductor device includes a semiconductor substrate, a semiconductor fin extending from the semiconductor substrate, a gate structure extending across the semiconductor fin, and source/drain semiconductor layers on opposite sides of the gate structure. The source/drain semiconductor layers each have a first thickness over a top side of the semiconductor fin and a second thickness over a lateral side of the semiconductor fin. The first thickness and the second thickness have a difference smaller than about 20 percent of the first thickness.

A laminate contains a crystal substrate; a middle layer formed on a main surface of the crystal substrate, the middle layer comprising a mixture of an amorphous region in an amorphous phase and a crystal region in a crystal phase having a corundum structure mainly made of a first metal oxide; and a crystal layer formed on the middle layer and having a corundum structure mainly made of a second metal oxide, wherein the crystal region is an epitaxially grown layer from a crystal plane of the crystal substrate.

Heterostructures include a layer of a two-dimensional material placed on a multiferroic layer. An ordered array of differing polarization domains in the multiferroic layer produces corresponding domains having differing properties in the two-dimensional material. When the multiferroic layer is ferroelectric, the ferroelectric polarization domains in the layer produce local electric fields that penetrate the two-dimensional material. The local electric fields modulate the charge carriers and carrier density on a nanometer length scale, resulting in the formation of lateral p-n or p-i-n junctions, and variations thereof appropriate for device functions.

There is provided a semiconductor layer structure (100) comprising: a Si substrate (102) having a top surface (104); a first semiconductor layer (110) arranged on said substrate, the first semiconductor layer comprising a plurality of vertical nanowire structures (112) arranged perpendicularly to said top surface of said substrate, the first semiconductor layer comprising AlN; a second semiconductor layer (120) arranged on said first semiconductor layer laterally and vertically enclosing said nanowire structures, the second semiconductor layer comprising Al.sub.xGa.sub.1-xN, wherein 0≤x≤0.95; a third semiconductor layer (130) arranged on said second semiconductor layer, the third semiconductor layer comprising Al.sub.yGa.sub.1-yN, wherein 0≤y≤0.95; and a fourth semiconductor layer (140) arranged on said third semiconductor layer, the fourth semiconductor layer comprising GaN. There is also provided a high-electron-mobility transistor device and methods of producing such structures and devices.

A transistor comprises a top source/drain region, a bottom source/drain region, and a channel region vertically between the top and bottom source/drain regions. A gate is operatively laterally-adjacent the channel region. The top source/drain region, the bottom source/drain region, and the channel region respectively have crystal grains and grain boundaries between immediately-adjacent of the crystal grains. At least one of the bottom source/drain region and the channel region has an internal interface there-within between the crystal grains that are above the internal interface and the crystal grains that are below the internal interface. At least some of the crystal grains that are immediately-above the internal interface physically contact at least some of the crystal grains that are immediately-below the internal interface. All of the grain boundaries that are between immediately-adjacent of the physically-contacting crystal grains that are immediately-above and that are immediately-below the interface align relative one another. The internal interface comprises at least one of (a) and (b), where (a): conductivity-modifying dopant concentration immediately-above the internal interface is lower than immediately-below the internal interface and (b): a laterally-discontinuous insulative oxide. Other embodiments, including method, are disclosed.

A substrate comprising a III-N base layer comprising a first portion and a second portion, the first portion of the III-N base layer having a first natural lattice constant and a first dislocation density; and a first III-N layer having a second natural lattice constant and a second dislocation density on the III-N base layer, the first III-N layer having a thickness greater than 10 nm. An indium fractional composition of the first III-N layer is greater than 0.1; the second natural lattice constant is at least 1% greater than the first natural lattice constant; a strain-induced lattice constant of the first III-N layer is greater than 1.0055 times the first natural lattice constant; and the second dislocation density is less than 1.5 times the first dislocation density.