A doped SiOC liquid starting material provides a p-type polymer derived ceramic SiC crystalline materials, including boules and wafers. P-type SiC electronic devices. Low resistivity SiC crystals, wafers and boules, having phosphorous as a dopant. Polymer derived ceramic doped SiC shaped charge source materials for vapor deposition growth of doped SiC crystals.

A method of manufacturing silicon carbide seed crystal and method of manufacturing silicon carbide ingot are provided. The silicon carbide seed crystal has a silicon surface and a carbon surface opposite to the silicon surface. A difference D between a basal plane dislocation density BPD1 of the silicon surface BPD1 and a basal plane dislocation density BPD2 of the carbon surface satisfies the following formula (1):

D=(BPD1−BPD2)/BPD1≤25%  (1).

A crystal growing apparatus includes: a crucible including a main body portion and a low radiation portion having a radiation rate lower than that of the main body portion; and a heating unit which is positioned on the outside of the crucible and is configured to heat the crucible by radiant heat, and the low radiation portion is provided on an outer surface of a first point which is a heating center, in a case where the crucible does not include the low radiation portion.

Molecular-beam epitaxy (MBE) and more particularly suboxide MBE (S-MBE) and related structures are disclosed. S-MBE is disclosed that includes the use of a molecular beam of a suboxide that may be subsequently oxidized in a single step reaction to form an oxide film. By way of example, for a gallium oxide (Ga.sub.2O.sub.3) film, a molecular beam including a suboxide of gallium (Ga.sub.2O) may be provided. S-MBE may be performed in adsorption-controlled regimes where there is an excess of source material containing species in order to promote high growth rates for oxide films with improved crystallinity. Source mixtures for providing molecular beams of suboxides are disclosed that include mixtures of a particular element and an oxide of the element in ratios that promote such adsorption-controlled growth regimes. Related structures include oxide films having increased thickness with reduced crystal defects, including single polymorph films of gallium oxide.

The invention relates in part to a growth model for the growth of Group III-Group V (III-V) alloys by molecular beam epitaxy (MBE) based on the kinetics of adsorption, desorption, incorporation, anion exchange, anion-assisted removal, and surface droplet accumulation of the Group V elements. The invention also relates to methods to optimize MBE growth conditions used to produce a target III-V alloy composition. The invention is further related to methods of predicting III-V alloy compositions resulting from a set of MBE growth conditions.

In various embodiments, single-crystal aluminum nitride boules and substrates are formed from the vapor phase with controlled levels of impurities such as carbon. Single-crystal aluminum nitride may be heat treated via quasi-isothermal annealing and controlled cooling to improve its ultraviolet absorption coefficient and/or Urbach energy.

Vapor phase transport systems and methods of depositing perovskite films are described. In an embodiment, a deposition method includes feeding a perovskite solution or constituent powder to a vaporizer, followed by vaporization and depositing the constituent vapor as a perovskite film. In an embodiment, a deposition system and method includes vaporizing different perovskite precursors in different vaporization zones at different temperatures, followed by mixing the vaporized precursors to form a constituent vapor, and depositing the constituent vapor as a perovskite film.

The disclosure provides a silicon carbide seed crystal and a method of manufacturing a silicon carbide ingot. The silicon carbide seed crystal has a silicon surface and a carbon surface opposite to the silicon surface. A difference D between a basal plane dislocation density BPD1 of the silicon surface and a basal plane dislocation density BPD2 of the carbon surface satisfies the following formula (1), a local thickness variation (LTV) of the silicon carbide seed crystal is 2.5 μm or less, and a stacking fault (SF) density of the silicon carbide seed crystal is 10 EA/cm.sup.2 or less:

D=(BPD1−BPD2)/BPD1≤25%  (1).

A silicon carbide ingot is provided, which includes a seed end, and a dome end opposite to the seed end. In the silicon carbide ingot, a ratio of the vanadium concentration to the nitrogen concentration at the seed end is in a range of 5:1 to 11:1, and a ratio of the vanadium concentration to the nitrogen concentration at the dome end is in a range of 2:1 to 11:1.

A high-purity semi-insulating silicon carbide crystal growing apparatus and a method therefor are provided, the apparatus comprising a growth crucible, a bottom part of the growth crucible having inserted a gas pipe, a top part of the growth crucible being provided with a growth crucible cover, a feedstock crucible having a bowl-shaped structure being disposed in the growth crucible, an upper part of the feedstock crucible being provided with a baffle, a bottom part of the feedstock crucible being provided with a ring-shaped supporting feedstock crucible bottom foot, the diameter of the feedstock crucible bottom foot being ⅛ the diameter of the feedstock crucible, and the feedstock crucible bottom foot having disposed thereon 8-36 evenly distributed gas holes.