Abstract: A polishing mixture and related method of polishing a material wafer surface, such as silicon carbide, are disclosed. The polishing mixture comprises; an abrasive and an oxidizer mixed in an acidic solution. Alumina may be used as the abrasive and the polishing mixture may have a pH less than or equal to seven (7).

Abstract: A polishing mixture and related method of polishing a material wafer surface, such as silicon carbide, are disclosed. The polishing mixture comprises; an abrasive and an oxidizer mixed in an acidic solution. Alumina may be used as the abrasive and the polishing mixture may have a pH less than or equal to seven (7).

Abstract: Disclosed is a method for reproducibly producing large size, single crystals in a crystal growth chamber. The method includes the steps of: (a) forming a plurality of smaller size tiles of single crystals of substantially the same crystal orientation as the desired large size, single crystal; (b) assembling the plurality of smaller tiles into a structure having a larger size while minimizing gapping between adjacent tiles; (c) placing the assembly of smaller tiles formed in step (b) into a growth chamber; and (d) through a growth reaction carried out in the growth chamber, forming a large size single crystal using the assembly of smaller tiles formed in step (b) as a seed crystal for the growth reaction.

Abstract: Disclosed is an apparatus and a method for growing single crystals of materials such as silicon carbide through axial gradient transport. A source of the material (10) is placed at one end of a reaction chamber (2) opposite a seed crystal (13). Separate heating elements (16 and 60; 20 and 62) are positioned at opposite ends of the reaction chamber. The reaction chamber (2) is placed in a growth chamber (26). By appropriately controlling the pressure in the growth chamber (26) and the temperature of the heating elements (16, 20), including the temperature differential therebetween, a uniaxial temperature gradient is generated in the reaction chamber (2). In this manner, planar isotherms are generated and a high quality crystal can be grown through a physical vapor transport process.

Abstract: Disclosed is an apparatus and a method for growing single crystals of materials such as silicon carbide through axial gradient transport. A source of the material (10) is placed at one end of a reaction chamber (2) opposite a seed crystal (13). Separate heating elements (16 and 60; 20 and 62) are positioned at opposite ends of the reaction chamber. The reaction chamber (2) is placed in a pressurized growth chamber (26). By appropriately controlling the pressure in the growth chamber (26) and the temperature of the heating elements (16, 20), including the temperature differential therebetween, a uniaxial temperature gradient is generated in the reaction chamber (2). In this manner, substantially planar isotherms are generated and a high quality crystal can be grown through a physical vapor transport process.

Abstract: Disclosed is a method for reproducibly producing large size, single crystals in a crystal growth chamber. The method includes the steps of: (a) forming a plurality of smaller size tiles of single crystals of substantially the same crystal orientation as the desired large size, single crystal; (b) assembling the plurality of smaller tiles into a structure having a larger size while minimizing gapping between adjacent tiles; (c) placing the assembly of smaller tiles formed in step (b) into a growth chamber; and (d) through a growth reaction carried out in the growth chamber, forming a large size single crystal using the assembly of smaller tiles formed in step (b) as a seed crystal for the growth reaction.