A single crystal production apparatus that is designed to produce a single crystal by cooling a melting zone formed by a heating part including an infrared generation part and a reflection part, wherein: the reflection part includes a spheroidal mirror and a concave spherical mirror; the infrared generation part is disposed at one focal point of the spheroidal mirror; an opening is formed in the spheroidal mirror on the side of the other focal point of the spheroidal mirror; and the one focal point and the spherical center of the concave spherical mirror fall on the same location.

FZ single crystals are pulled by melting a polycrystal with electromagnetic melting apparatus and then recrystallizing. First, a lower end of the polycrystal is melted; second, a monocrystalline seed is attached to the lower end of the polycrystal and melted beginning from an upper end thereof; third, between a lower section of the seed and the polycrystal, a thin neck is formed whose diameter (d.sub.D) is smaller than that (d.sub.I) of the seed; and fourth, between the thin neck section and the polycrystal, a conical section is formed. Before the conical growth, a switchover position (h′) of the polycrystal, the position at which the rate of polycrystal movement relative to the melting apparatus is to be reduced is determined, and the rate is reduced, in amount when the switchover position (h′) is reached.

FZ single crystals are pulled by melting a polycrystal with electromagnetic melting apparatus and then recrystallizing. First, a lower end of the polycrystal is melted; second, a monocrystalline seed is attached to the lower end of the polycrystal and melted beginning from an upper end thereof; third, between a lower section of the seed and the polycrystal, a thin neck is formed whose diameter (d.sub.D) is smaller than that (d.sub.I) of the seed; and fourth, between the thin neck section and the polycrystal, a conical section is formed. Before the conical growth, a switchover position (h′) of the polycrystal, the position at which the rate of polycrystal movement relative to the melting apparatus is to be reduced is determined, and the rate is reduced, in amount when the switchover position (h′) is reached.

To provide a single crystal production apparatus capable of efficiently producing a single crystal of relatively high quality, by cooling a melting zone, the device including: a heating part that forms the melting zone from a raw material by irradiation of light; and a supporting part that supports the melting zone in a non-contact manner.

To provide a single crystal production apparatus capable of efficiently producing a single crystal of relatively high quality, by cooling a melting zone, the device including: a heating part that forms the melting zone from a raw material by irradiation of light; and a supporting part that supports the melting zone in a non-contact manner.

A single crystal is pulled by an FZ method, in which a polycrystal is melted by means of an electromagnetic melting apparatus and then recrystallized, wherein a first phase (P.sub.1) a lower end of the polycrystal, which is moved toward the melting apparatus, is melted by the melting apparatus to form a drop, and in a second phase (P.sub.2) a monocrystalline seed is attached to the lower end of the polycrystal and is melted beginning from an upper end of the seed, where a power (P) of the melting apparatus during the first phase (P.sub.1) and during the second phase (P.sub.2) is predetermined at least temporarily in dependence on a temperature and/or geometrical dimensions of crystal material used which comprises the drop and/or the seed and/or the polycrystal.

A single crystal is pulled by an FZ method, in which a polycrystal is melted by means of an electromagnetic melting apparatus and then recrystallized, wherein a first phase (P.sub.1) a lower end of the polycrystal, which is moved toward the melting apparatus, is melted by the melting apparatus to form a drop, and in a second phase (P.sub.2) a monocrystalline seed is attached to the lower end of the polycrystal and is melted beginning from an upper end of the seed, where a power (P) of the melting apparatus during the first phase (P.sub.1) and during the second phase (P.sub.2) is predetermined at least temporarily in dependence on a temperature and/or geometrical dimensions of crystal material used which comprises the drop and/or the seed and/or the polycrystal.

A single crystal is pulled by the FZ method, in which in a first phase, a lower end of the polycrystal is melted by the melting apparatus, in a second phase, a monocrystalline seed is attached to the lower end of the polycrystal, and in a third phase, between a lower section of the seed and the polycrystal, a thin neck section is formed whose diameter is smaller than that of the seed, where the power of the melting apparatus before the third phase is dynamically adapted in dependence on a position of a lower phase boundary (P.sub.U) between liquid material and solid material on the part of the seed, and where the power of the melting apparatus during the third phase is dynamically adapted in dependence on the position of an upper phase boundary (P.sub.O) between liquid material and solid material on the part of the polycrystal plant.

A single crystal is pulled by the FZ method, in which in a first phase, a lower end of the polycrystal is melted by the melting apparatus, in a second phase, a monocrystalline seed is attached to the lower end of the polycrystal, and in a third phase, between a lower section of the seed and the polycrystal, a thin neck section is formed whose diameter is smaller than that of the seed, where the power of the melting apparatus before the third phase is dynamically adapted in dependence on a position of a lower phase boundary (P.sub.U) between liquid material and solid material on the part of the seed, and where the power of the melting apparatus during the third phase is dynamically adapted in dependence on the position of an upper phase boundary (P.sub.O) between liquid material and solid material on the part of the polycrystal plant.

Methods for purifying reaction precursors used in the synthesis of inorganic compounds and methods for synthesizing inorganic compounds from the purified precursors are provided. Also provided are methods for purifying the inorganic compounds and methods for crystallizing the inorganic compounds from a melt. and X-ray detectors incorporating the crystals of the inorganic compounds are also provided.