The method for manufacturing a crystal for a synthetic gem includes the step of preparing a SiC single crystal including an n-type impurity, and the step of irradiating the SiC single crystal with an electron beam to generate a carbon vacancy in the SiC single crystal. Irradiation energy and dose in electron beam irradiation are set such that the density of the carbon vacancy is higher than the density of the n-type impurity.

This disclosure provides systems, methods, and apparatus related to color centers. In one aspect, a method includes providing diamond doped with a dopant. A heavy-ion is directed to the diamond that passes through the diamond. The heavy-ion forms a line of dopant-vacancy centers as it passes through the diamond.

This disclosure provides systems, methods, and apparatus related to color centers. In one aspect, a method includes providing diamond doped with a dopant. A heavy-ion is directed to the diamond that passes through the diamond. The heavy-ion forms a line of dopant-vacancy centers as it passes through the diamond.

A method for forming a silicon carbide material with a plurality of negatively charged silicon mono-vacancy defects includes irradiating a silicon carbide sample, annealing the irradiated silicon carbide sample in an annealing operation, and quenching the annealed silicon carbide sample. Quenching may include heating the annealed silicon carbide sample to a maximum temperature and quenching the annealed silicon carbide sample to form the silicon carbide sample with the plurality of negatively charged silicon mono-vacancy defects.

A method for forming a silicon carbide material with a plurality of negatively charged silicon mono-vacancy defects includes irradiating a silicon carbide sample, annealing the irradiated silicon carbide sample in an annealing operation, and quenching the annealed silicon carbide sample. Quenching may include heating the annealed silicon carbide sample to a maximum temperature and quenching the annealed silicon carbide sample to form the silicon carbide sample with the plurality of negatively charged silicon mono-vacancy defects.

A method of manufacturing a silicon carbide semiconductor device includes the following steps. In a silicon carbide substrate including a silicon carbide single-crystal substrate and a silicon carbide epitaxial film provided on the silicon carbide single-crystal substrate, a reference mark serving as a reference of two dimensional position coordinates is formed. After forming the reference mark, at least one of polishing or cleaning is performed on a reference mark formation surface of the silicon carbide substrate. Position coordinates of a defect present in the silicon carbide substrate are specified based on the reference mark. A device active region is formed in the silicon carbide substrate. Position coordinates of the device active region are specified based on the reference mark. A pass/fail judgement of the device active region is made by associating the position coordinates of the defect with the position of the device active region.

Embodiments described herein include a method for depositing a material layer on a substrate while controlling a bow of the substrate and a surface roughness of the material layer. A bias applied to the substrate while the material layer is deposited is adjusted to control the bow of the substrate. A bombardment process is performed on the material layer to improve the surface roughness of the material layer. The bias and bombardment process improve a uniformity of the material layer and reduce an occurrence of the material layer cracking due to the bow of the substrate.

Embodiments described herein include a method for depositing a material layer on a substrate while controlling a bow of the substrate and a surface roughness of the material layer. A bias applied to the substrate while the material layer is deposited is adjusted to control the bow of the substrate. A bombardment process is performed on the material layer to improve the surface roughness of the material layer. The bias and bombardment process improve a uniformity of the material layer and reduce an occurrence of the material layer cracking due to the bow of the substrate.

Provided is a synthetic single crystal diamond containing conjugants each composed of one vacancy and one boron atom, wherein the concentration of boron atoms based on atom numbers is 0.1 ppm or more and 100 ppm or less.

Provided is a synthetic single crystal diamond containing conjugants each composed of one vacancy and one boron atom, wherein the concentration of boron atoms based on atom numbers is 0.1 ppm or more and 100 ppm or less.