A ferroelectric device comprising a substrate; a textured layer; a first electrode comprising a thin layer of metallic material having a crystal lattice structure divided into granular regions; a seed layer; the seed layer being epitaxially deposited so as to form a column-like structure on top of the granular regions of the first electrode; at least one ferroelectric material layer exhibiting spontaneous polarization epitaxially deposited on the seed layer; the ferroelectric material layer, the seed layer, and first electrode each having granular regions in which column-like structures produce a high degree of polarization normal to the growth plane and a method of making.

A 3C-SiC epitaxial layer is produced by a production method including: epitaxially growing a first 3C-SiC layer on a Si substrate; oxidizing the first 3C-SiC layer; removing an oxide film on a surface of the 3C-SiC layer; and epitaxially growing a second 3C-SiC layer on the 3C-SiC layer after the oxide film is removed.

There is provided a method for manufacturing a nitride semiconductor template, including the steps of: growing and forming a buffer layer to be thicker than a peak width of a projection and in a thickness of not less than 11 nm and not more than 400 nm on a sapphire substrate formed by arranging conical or pyramidal projections on its surface in a lattice pattern; and growing and forming a nitride semiconductor layer on the buffer layer.

Disclosed is a wafer or a material stack for semiconductor-based optoelectronic or electronic devices that minimizes or reduces misfit dislocation, as well as a method of manufacturing such wafer of material stack. A material stack according to the disclosed technology includes a substrate; a basis buffer layer of a first material disposed above the substrate; and a plurality of composite buffer layers disposed above the basis buffer layer sequentially along a growth direction. The growth direction is from the substrate to a last composite buffer layer of the plurality of composite buffer layers. Each composite buffer layer except the last composite buffer layer includes a first buffer sublayer of the first material, and a second buffer sublayer of a second material disposed above the first buffer sublayer. The thicknesses of the first buffer sublayers of the composite buffer layers decrease along the growth direction.

The purpose of the present invention is to provide a technique of manufacturing a nitride semiconductor layer with which, when producing a semiconductor device by forming a nitride semiconductor layer on off-angle inclined substrate, it is possible to stably supply high-quality semiconductor devices by preventing occurrence of a macro step using a material that is not likely to occur lattice strains or crystal defects by mixing with GaN and does not require continuous addition; and provided is a nitride semiconductor device which comprises a nitride semiconductor layer formed on a substrate, wherein the substrate is inclined at an off angle, a rare earth element-added nitride layer to which a rare earth element is added is formed on the substrate as a primed layer, and a nitride semiconductor layer is formed on the rare earth element-added nitride layer.

A method for manufacturing a nitride semiconductor device includes the steps of growing a GaN channel layer on an SiC substrate using a vertical MOCVD furnace set at a first temperature using H.sub.2 as a carrier gas, and TMG and NH.sub.3 as raw materials, holding the SiC substrate having the grown GaN channel layer in the MOCVD furnace set at a second temperature higher than the first temperature using H.sub.2 as a carrier gas, the MOCVD furnace being supplied with NH.sub.3, and growing an InAlN layer on the GaN channel layer using the MOCVD furnace set at a third temperature lower than the first temperature using N.sub.2 as a carrier gas, and TMI, TMA, and NH.sub.3 as raw materials.

Disclosed herein methods of forming an Al—Ga containing film comprising: a) exposing a substrate comprising a β-Ga.sub.2O.sub.3, wherein the substrate has a (100) or (−201) orientation, to a vapor phase comprising an aluminum precursor and a gallium precursor; and b) forming a β-(Al.sub.xGa.sub.1-x).sub.2O.sub.3 thin film by a chemical vapor deposition at predetermined conditions and wherein x is 0.01≤x≤0.7. Also disclosed herein are devices comprising the inventive films.

A wafer suitable for epitaxial growth of gallium nitride (GaN) in a Metal Oxide Chemical Vapor Deposition (MOCVD) process. The wafer includes a silicon substrate having a front side and a back side and an edge extending between the front side and the back side, the edge including a front bevel surface connected to the front side and a back bevel surface connected to the back side, wherein the silicon substrate comprises an oxygen denuded silicon layer surrounding a core. The wafer further includes a protection layer being a thermally grown silicon oxide (SiO.sub.2) layer substantially covering the front bevel surface and the back bevel surface of the edge, while leaving at least a central region of the front side of the silicon substrate exposed, for preventing meltback during the MOCVD process.

The present disclosure is a light-emitting diode (LED) with oxidized aluminum nitride (oxidized-AlN) film, which includes a substrate, an aluminum nitride buffer (AlN-buffer) layer, an oxidized-AlN film and a light-emitting diode epitaxial structure. The AlN-buffer layer is disposed on a patterned surface of the substrate, wherein the patterned surface is formed with a plurality of protrusions and a bottom portion. The oxidized-AlN film is disposed on the AlN-buffer layer on the protrusions, and with none disposed on the AlN-buffer layer on the bottom portion. The LED epitaxial structure includes gallium nitride compound crystal formed on the oxidized-AlN film and the AlN-buffer layer, to effectively reduce defect density of the gallium nitride compound crystal and to improve a luminous intensity of the LED.

Embodiments relate to a layered material (having a substrate, at least a buffer layer, with zero or more growth layers) that has been intercalated via a process that decouples (physically and electronically) the buffer layer from the substrate, thereby resulting in the creation of few-atom thick metal layers that exhibit a range of optical properties, including plasmonic or electronic resonance, that enables superior optical (e.g. Raman) detection of molecules.