A SiC single crystal manufacturing apparatus of the present invention includes a growth container having a growth space in which a SiC single crystal is grown in a first direction and a heat insulating material which covers the growth container and includes a plurality of units, and the plurality of units include a first unit and a second unit having at least a thermal conductivity different from that of the first unit, and the first unit includes a container made of at least one of graphite and a metal carbide and a filler filled into the container in a replaceable manner.

A crystal growing apparatus includes: a crucible which includes a main body portion, and a first portion having a radiation rate different from that of the main body portion, and is capable of controlling a temperature of a specific region inside during heating to a higher or lower temperature than that of the other regions; 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 first portion is at a position where the crucible and a line segment connecting a heating center of the heating unit and the specific region intersect with each other.

A system and a method for fabricating crystals, the method comprising heating an irradiation target to a temperature comprised in a range between a boiling point temperature of a material of the irradiation target and a critical point temperature of the material of the irradiation target, thereby generating a plasma plume of particles ablated from a surface of the irradiation target.

An apparatus for sublimation growth of a doped SiC single crystal includes a growth crucible, an envelope, a heater, and a passage for introducing into the envelope from a source outside the envelope a doping gas mixture. The gas mixture includes a gaseous dopant precursor that, in response to entering a space between the growth crucible and the envelope, undergoes chemical transformation and releases into the space between the growth crucible and the envelope dopant-bearing gaseous products of transformation which penetrate the wall of the crucible, move into the crucible, and absorb on a growth interface of a growing SiC crystal thereby causing doping of the growing crystal. A sublimation growth method is also described.

A silicon carbide single crystal manufacturing apparatus includes a crucible constituted by a crucible body and a crucible lid and a base having a crucible lid side surface supported by the lower surface of the crucible lid, and a seed crystal mounting surface on which the seed crystal is mounted and which is a surface on the opposite side of the crucible lid side surface, wherein the base is made of graphite material, the area of the seed crystal mounting surface is larger than the area of the crucible lid side surface, and the base has at least of a portion in which the cross-sectional area orthogonal to the vertical direction connecting the crucible lid side surface and the seed crystal mounting surface is gradually reduced, and a portion that is getting smaller gradually, from the surface of the seed crystal mounting surface toward the crucible lid side surface.

Stabilized, high-doped silicon carbide is described. A silicon carbide crystal is grown on a substrate using chemical vapor deposition so that the silicon carbide crystal includes a dopant and the strain compensating component. The strain compensating component can be an isoelectronic element and/or an element with the same majority carrier type as the dopant. The silicon carbide crystal can then be cut into silicon carbide wafers. In some embodiments, the dopant is n-type and the strain compensating component is selected from a group comprising germanium, tin, arsenic, phosphorus, and combinations thereof. In some embodiments, the strain compensating component comprises germanium and the dopant is nitrogen.

Methods for making metastable lead-free piezoelectric materials are presented herein.

A method of single crystal growth includes disposing a polycrystalline source material in a chamber of a single crystal growth apparatus, disposing a seed layer in the chamber of the single crystal growth apparatus, wherein the seed layer is fixed below a lid of the single crystal growth apparatus, heating the polycrystalline source material by a heater of the single crystal growth apparatus to deposit a semiconductor material layer on the seed layer, and after depositing the semiconductor material layer, providing a coolant gas at a backside of the lid to cool down the seed layer and the semiconductor material layer.

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.

A physical vapor transport growth system includes a growth chamber charged with SiC source material and a SiC seed crystal in spaced relation and an envelope that is at least partially gas-permeable disposed in the growth chamber. The envelope separates the growth chamber into a source compartment that includes the SiC source material and a crystallization compartment that includes the SiC seed crystal. The envelope is formed of a material that is reactive to vapor generated during sublimation growth of a SiC single crystal on the SiC seed crystal in the crystallization compartment to produce C-bearing vapor that acts as an additional source of C during the growth of the SiC single crystal on the SiC seed crystal.