There are provided a setting process configured to set in a chamber an aluminum nitride substrate in which a semiconductor layer is formed on a first principal plane, and an oxide film forming process configured to heat an inside of the chamber with a water molecule (H.sub.2O) being introduced in the chamber and to form an oxide film including an amorphous oxide film and/or a crystalline oxide film on a second principal plane located on an opposite side to the first principal plane of the aluminum nitride substrate.

A method for manufacturing a silicon carbide substrate includes steps of preparing a silicon carbide substrate having a main surface, polishing the main surface of the silicon carbide substrate using a polishing agent containing a metal catalyst, and cleaning the silicon carbide substrate after the step of polishing. The step of cleaning includes a step of cleaning the silicon carbide substrate with aqua regia.

A method is disclosed for producing a high quality bulk single crystal of silicon carbide in a seeded growth system by reducing the separation between a silicon carbide seed crystal and a seed holder until the conductive heat transfer between the seed crystal and the seed holder dominates the radiative heat transfer between the seed crystal and the seed holder over substantially the entire seed crystal surface that is adjacent the seed holder.

A method is disclosed for producing a high quality bulk single crystal of silicon carbide in a seeded growth system by reducing the separation between a silicon carbide seed crystal and a seed holder until the conductive heat transfer between the seed crystal and the seed holder dominates the radiative heat transfer between the seed crystal and the seed holder over substantially the entire seed crystal surface that is adjacent the seed holder.

A method is disclosed for producing a high quality bulk single crystal of silicon carbide in a seeded growth system by reducing the separation between a silicon carbide seed crystal and a seed holder until the conductive heat transfer between the seed crystal and the seed holder dominates the radiative heat transfer between the seed crystal and the seed holder over substantially the entire seed crystal surface that is adjacent the seed holder.

A CZ silicon ingot is doped with donors and acceptors and includes an axial gradient of doping concentration of the donors and of the acceptors. An electrically active net doping concentration, which is based on a difference between the doping concentrations of the donors and acceptors varies by less than 60% for at least 40% of an axial length of the CZ silicon ingot due to partial compensation of at least 20% of the doping concentration of the donors by the acceptors.

The present invention relates to a single-crystal silicon-carbide substrate provided with a principal surface having an atomic step-and-terrace structure containing atomic steps and terraces derived from a crystal structure, in which the atomic step-and-terrace structure has a proportion of an average line roughness of a front edge portion of the atomic step to a height of the atomic step being 20% or less.

The present invention relates to a single-crystal silicon-carbide substrate provided with a principal surface having an atomic step-and-terrace structure containing atomic steps and terraces derived from a crystal structure, in which the atomic step-and-terrace structure has a proportion of an average line roughness of a front edge portion of the atomic step to a height of the atomic step being 20% or less.

A method of fabricating a wafer according to the embodiment comprises the steps of growing an wafer on a surface of the wafer in a growth temperature; and cooling the wafer after the wafer has been grown, wherein a stepwise cooling is performed when cooling the wafer.

A method of fabricating a wafer according to the embodiment comprises the steps of growing an wafer on a surface of the wafer in a growth temperature; and cooling the wafer after the wafer has been grown, wherein a stepwise cooling is performed when cooling the wafer.