Provided is a method for producing a SiC single crystal wherein a 4H—SiC single crystal is grown by minimizing generation of polytypes other than 4H. A method for producing a SiC single crystal by a solution process, wherein a seed crystal is 4H—SiC, and a (000-1) face of the seed crystal is a growth surface, wherein the method includes: setting a temperature at a center section of a region of a surface of a Si—C solution where the growth surface of the seed crystal contacts to 1900° C. or higher, and limiting a ΔTc/ΔTa to 1.7 or greater, wherein the ΔTc/ΔTa is a ratio of a temperature gradient ΔTc between the center section and a location 10 mm below the center section in the vertical direction, with respect to a temperature gradient ΔTa between the center section and a location 10 mm from the center section in the horizontal direction.

A low-resistance p-type SiC single crystal containing no inclusions is provided. A method for producing a SiC single crystal in which a SiC seed crystal substrate is contacted with a Si—C solution having a temperature gradient such that a temperature of the Si—C solution decreases from an interior of the Si—C solution toward a surface of the Si—C solution, to grow the SiC single crystal, wherein the Si—C solution comprises Si, Cr, Al and B, and wherein the Al is comprised in the Si—C solution in an amount of 10 at % or greater, based on the total of the Si, Cr, Al and B, and the B is comprised in the Si—C solution in an amount of greater than 0.00 at % and no greater than 1.00 at %, based on the total of the Si, Cr, Al and B.

An object of the present invention is to provide a SIC single crystal production apparatus that stirs and heats a Si—C solution easily. The apparatus includes a crucible capable of containing a Si—C solution, a seed shaft, and an induction heater. The crucible includes a tubular portion and a bottom portion. The tubular portion includes an outer peripheral surface and an inner peripheral surface. The bottom portion is disposed at a lower end of the tubular portion. The bottom portion defines an inner bottom surface of the crucible. The outer peripheral surface includes a groove extending in a direction crossing the circumferential direction of the tubular portion.

An object of the present invention is to provide a SIC single crystal production apparatus that stirs and heats a Si—C solution easily. The apparatus includes a crucible capable of containing a Si—C solution, a seed shaft, and an induction heater. The crucible includes a tubular portion and a bottom portion. The tubular portion includes an outer peripheral surface and an inner peripheral surface. The bottom portion is disposed at a lower end of the tubular portion. The bottom portion defines an inner bottom surface of the crucible. The outer peripheral surface includes a groove extending in a direction crossing the circumferential direction of the tubular portion.

The provided by the disclosure is a SiC single crystal production method permitting suppression of temperature variation of a Si—C solution even in a case of long-time crystal growth. The SiC single crystal production method includes: a preparation step of preparing a production apparatus including a crucible, a seed shaft, and an internal lid; a formation step of heating the material in the crucible to form the Si—C solution; a growth step of bringing the seed crystal into contact with the Si—C solution to produce the Si—C single crystal on the seed crystal; an internal lid adjustment step of vertically moving one of the internal lid and the crucible relative to the other during the growth step to keep an amount of variation in vertical distance between the internal lid and the Si—C solution within a first reference range.

The provided by the disclosure is a SiC single crystal production method permitting suppression of temperature variation of a Si—C solution even in a case of long-time crystal growth. The SiC single crystal production method includes: a preparation step of preparing a production apparatus including a crucible, a seed shaft, and an internal lid; a formation step of heating the material in the crucible to form the Si—C solution; a growth step of bringing the seed crystal into contact with the Si—C solution to produce the Si—C single crystal on the seed crystal; an internal lid adjustment step of vertically moving one of the internal lid and the crucible relative to the other during the growth step to keep an amount of variation in vertical distance between the internal lid and the Si—C solution within a first reference range.

A production apparatus is used for a solution growth method. The production apparatus includes a seed shaft and a crucible. The seed shaft has a lower end surface to which an SiC seed crystal is attached. The crucible contains an SiC solution. The crucible includes a cylindrical portion, a bottom portion, and an inner lid. The bottom portion is disposed at a lower end of the cylindrical portion. The inner lid is disposed in the cylindrical portion. The inner lid has a through hole and is positioned below a liquid surface of the SiC solution when the SiC solution is contained in the crucible.

A production apparatus is used for a solution growth method. The production apparatus includes a seed shaft and a crucible. The seed shaft has a lower end surface to which an SiC seed crystal is attached. The crucible contains an SiC solution. The crucible includes a cylindrical portion, a bottom portion, and an inner lid. The bottom portion is disposed at a lower end of the cylindrical portion. The inner lid is disposed in the cylindrical portion. The inner lid has a through hole and is positioned below a liquid surface of the SiC solution when the SiC solution is contained in the crucible.

A production method according to an embodiment includes a formation step (S1), a first growth step (S2), a recovery step (S3), and a second growth step (S4). In the formation step (S1), a Si—C solution containing Si, Al and C is formed in a crucible. In the first growth step (S2), a seed shaft is moved down to bring a SiC seed crystal attached to the bottom edge of the seed shaft onto contact with the Si—C solution, and thereafter, an Al-doped p-type SiC single crystal is grown on the SiC seed crystal. After the first growth step (S2), the Al concentration in the Si—C solution is increased in the recovery step (S3). After the recovery step (S3), the Al-doped p-type SiC single crystal is further grown in the second growth step (S4).

A production method according to an embodiment includes a formation step (S1), a first growth step (S2), a recovery step (S3), and a second growth step (S4). In the formation step (S1), a Si—C solution containing Si, Al and C is formed in a crucible. In the first growth step (S2), a seed shaft is moved down to bring a SiC seed crystal attached to the bottom edge of the seed shaft onto contact with the Si—C solution, and thereafter, an Al-doped p-type SiC single crystal is grown on the SiC seed crystal. After the first growth step (S2), the Al concentration in the Si—C solution is increased in the recovery step (S3). After the recovery step (S3), the Al-doped p-type SiC single crystal is further grown in the second growth step (S4).