The present invention provides a single crystal growth method capable of suppressing the recrystallization of the raw material gas subjected to sublimation on the surface of the raw material, and suppressing the generation of different polytypes in the crystal growing single crystal. The single crystal growth method is carried out in a crucible comprising an inner bottom for providing a raw material and a crystal mounting part facing the inner bottom. The method comprises in the following order: providing the raw material in the inner bottom; covering at least a part of a surface of the raw material with a metal carbide powder in a plan view from the crystal mounting part; and growing a single crystal disposed in the crystal mounting part by sublimating the raw material by heating.

In various embodiments, controlled heating and/or cooling conditions are utilized during the fabrication of aluminum nitride single crystals and aluminum nitride bulk polycrystalline ceramics. Thermal treatments may also be utilized to control properties of aluminum nitride crystals after fabrication.

A method for evaluating the quality of a SiC single crystal by a non-destructive and simple method; and a method for producing a SiC single crystal ingot with less dislocation and high quality with good reproducibility utilizing the same. The method for evaluating the quality of a SiC single crystal body is based on the graph of a second polynomial equation obtained by differentiating a first polynomial equation, the first polynomial equation approximating the relation between a peak shift value and a position of the measurement point and the peak shift value being obtained by an X-ray rocking curve measurement. The method for producing a SiC single crystal ingot manufactures a SiC single crystal ingot by a sublimation recrystallization method using, as a seed crystal, the SiC single crystal body evaluated by the evaluation method.

The present invention provides a method of manufacturing by the sublimation-recrystallization method more accurately detecting a thermal state of a starting material in a crucible and enabling control of the growth conditions while manufacturing an SiC single crystal. The method obtains the high frequency current to be supplied through the induction coil by a converter for converting AC current to DC current and an inverter means for converting the DC current output from the converter to a high frequency to obtain a high frequency current, obtains a grasp, in advance, of a relationship between a variation over time of a DC equivalent resistivity (DCV/DCI), calculated from a DC voltage value (DCV) and DC current value (DCI) converted by the converter at the time of growth of the silicon carbide single crystal, and a density of micropipes formed in the grown silicon carbide single crystal, and adjusts at least one of the DCV or DCI at the converter based on the relationship of the DC equivalent resistivity and micropipe density grasped in advance.

In the SiC substrate, when resistivities at a plurality of first measurement points that are in a region inside a boundary located 5 mm inward from an outer circumferential end thereof and that include a center and a plurality of measurement points separated by 10 mm from each other in the [11-20] direction or the [?1-120] direction from the center, and at two second measurement points that are located 1 mm inward from the outer circumferential end and located in each of the [11-20] direction from the center and the [?1-120] direction from the center are measured, a difference between the maximum resistivity and the minimum resistivity among the resistivities of each of the plurality of first measurement points and the two second measurement points is 2 m?.Math.cm or less, and a region other than a high nitrogen concentration region called a facet is included.

Provided is a method of producing a high purity molybdenum oxychloride by including means of sublimating and reaggregating a raw material molybdenum oxychloride in a reduced-pressure atmosphere, or means of retaining a gaseous raw material molybdenum oxychloride, which was synthesized in a vapor phase, in a certain temperature range, and thereby growing crystals to obtain a higher purity molybdenum oxychloride having a high bulk density and high hygroscopicity resistance.

The embodiments of the present disclosure disclose a method and an apparatus for crystal growth. The method for crystal growth may include: placing a seed crystal and a target source material in a growth chamber of an apparatus for crystal growth; executing a growth of a crystal based on the seed crystal and the target source material according to physical vapor transport; determining whether a preset condition is satisfied during the crystal growth process; and in response to determining that the preset condition is satisfied, replacing a sublimated target source material with a candidate source material. In the present disclosure, by replacing the sublimated target source material with the candidate source material, a crystal with large-size and high-quality can be grown.

Methods and systems for growing thin films via molecular-beam epitaxy (MBE) on substrates are provided. The methods and systems utilize a thermally conductive backing plate including an infrared-absorbing coating (IAC) formed, for example, on one side of the thermally conductive backing plate to provide an asymmetric emissivity that absorbs infrared radiation (IR) on the side having the IRC and does not on the non-coated side of the thermally conductive backing plate (e.g., refractive metal or alloy). The asymmetric emissivity shields the thin film being deposited on a substrate from the IR during formation.

In various embodiments, controlled heating and/or cooling conditions are utilized during the fabrication of aluminum nitride single crystals and aluminum nitride bulk polycrystalline ceramics. Thermal treatments may also be utilized to control properties of aluminum nitride crystals after fabrication.

The invention relates to a crystal growth device for growing a semiconductor from a gas phase, the crystal growth device comprising, a crucible, a heater, and a holding plate. The crucible on a crucible vessel and a crucible lid supported on the crucible vessel, wherein the crucible vessel is configured to receive and hold a source material for the semiconductor during growth of the semiconductor. The heater is configured and arranged to heat the source material in the crucible vessel so that the source material at least partially changes to its gaseous phase and flows toward the crucible lid. The holding plate is configured to hold a seed crystal on a side of the holding plate facing the crucible lid, and to allow deposition of the source material that has changed into its gas phase on the seed crystal for growing the semiconductor. The holding plate is further configured to be spaced from a crucible bottom of the crucible vessel for growing the semiconductor, such that it is located between the source material and the crucible lid.