An object of the present invention is to provide a novel technology capable of achieving high-quality SiC seed crystal, SiC ingot, SiC wafer and SiC wafer with an epitaxial film. The present invention, which solves the above object, is a method for producing a SiC seed crystal for growth of a SiC ingot, the method including a heat treatment step of heat-treating a SiC single crystal in an atmosphere containing Si element and C element. As described above, by heat-treating the SiC single crystal in an atmosphere containing the Si element and the C element, it is possible to produce a high-quality SiC seed crystal in which strain and crystal defects are suppressed.

An oxide thin film transistor includes an oxide active layer, a first loose layer and a first oxygen release layer. The first loose layer is at least disposed on a first surface of the oxide active layer perpendicular to a thickness direction of the oxide active layer, and is in contact with the oxide active layer. A material of the first loose layer includes a first inorganic oxide insulating material. The first oxygen release layer is disposed on a surface of the first loose layer facing away from the oxide active layer, and is in contact with the first loose layer. A material of the first oxygen release layer is a first oxygen-containing insulating material.

A shadow wall for controlling directional deposition of a material is arranged on a substrate. The shadow wall comprises a base portion and a bridge portion. The base portion is arranged on the substrate and is configured to support the bridge portion. The bridge portion overhangs the substrate. The shadow wall may have improved compatibility with non-directional deposition processes, because adatoms on the surface of the substrate may diffuse under the bridge. Also provided are a method of fabricating a device using the shadow wall, and a method of fabricating the shadow wall.

A crystalline IZTO oxide semiconductor and a thin film transistor having the same are provided. The thin film transistor includes a gate electrode, a crystalline In—Zn—Sn oxide (IZTO) channel layer overlapping the upper or lower portions of the gate electrode and having hexagonal crystal grains, and a gate insulating layer disposed between the gate electrode and the IZTO channel layer, and source and drain electrodes respectively connected to both ends of the IZTO channel layer.

A memory device includes a substrate, word line layers, insulating layers, and memory cells. The word line layers are stacked above the substrate. The insulating layers are stacked above the substrate respectively alternating with the word line layers. The memory cells are distributed along a stacking direction of the word line layers and the insulating layers perpendicularly to a major surface of the substrate. Each memory cell includes a source line electrode and a bit line electrode, a first oxide semiconductor layer, and a second oxide semiconductor layer. The first oxide semiconductor layer is peripherally surrounded by one of the word line layers, the source line electrode, and the bit line electrode. The second oxide semiconductor layer is disposed between the one of the word line layers and the first oxide semiconductor layer.

Disclosed are an MPS diode device and a preparation method therefor. The MPS diode device comprises a plurality of cells arranged in parallel, wherein each cell comprises a cathode electrode, and a substrate, epitaxial layer, buffer layer, and anode electrode that are formed in succession on the cathode electrode; two active regions are formed on the side of the epitaxial layer away from the substrate; the width of forbidden band of the buffer layer is greater than the width of forbidden band of the epitaxial layer, and a material of the buffer layer and a material of the epitaxial layer are allotropes; and first openings are formed at the positions in the buffer layer opposite to the active regions, and an ohmic metal layer is formed in the first openings.

An artificial two-dimensional (2D) material includes a layered atomic structure including a middle atomic layer, a lower atomic layer, and an upper atomic layer. The lower and upper atomic layers are disposed on lower and upper surfaces of the middle atomic layer respectively. The middle atomic layer is a 2D planar atomic structure formed of a transition metal. The lower and upper atomic layers are a 2D planar atomic structure formed of heterogeneous atoms. Atoms of the layered atomic structure are bound by chemical bonding.

A multi-layer thin film composite is formed by applying a thin film formed from non-single-crystalline oxide onto a substrate; applying a protection film onto the thin film; and supplying energy to the thin film through at least one of the protection film or the substrate.

A system and method for growing a gallium nitride (GaN) structure that includes providing a template; and growing at least a first GaN layer on the template using a first sputtering process, wherein the first sputtering process includes: controlling a temperature of a sputtering target, and modulating between a gallium-rich condition and a gallium-lean condition, wherein the gallium-rich condition includes a gallium-to-nitrogen ratio having a first value that is greater than 1, and wherein the gallium-lean condition includes the gallium-to-nitrogen ratio having a second value that is less than the first value. Some embodiments include a load lock configured to load a substrate wafer into the system and remove the GaN structure from the system; and a plurality of deposition chambers, wherein the plurality of deposition chambers includes a GaN-deposition chamber configured to grow at least the first GaN layer on a template that includes the substrate wafer.

By widening a terrace on a crystal surface on a bottom face of a recess by step flow caused by heating, a flat face is formed on the bottom face of the recess, a two-dimensional material layer made of a two-dimensional material is formed on the formed flat face, and then a device made of the two-dimensional material layer is produced.