A method of forming crystalline sheets using a Horizontal Ribbon Growth process, where the sheet of material formed in the process is withdrawn from a crucible in a specified manner to reduce instabilities in the process and to regulate crystal growth dynamics.

A method of forming crystalline sheets using a Horizontal Ribbon Growth process, where the sheet of material formed in the process is withdrawn from a crucible in a specified manner to reduce instabilities in the process and to regulate crystal growth dynamics.

A crystal of semiconductor material is produced in an apparatus having a crucible with a crucible bottom and a crucible wall, the crucible bottom having a top surface, an underside, and a multitude of openings disposed between the crucible wall and a center of the crucible bottom, and elevations disposed on the top surface and the underside of the crucible bottom; and an induction heating coil disposed below the crucible for melting semiconductor material and stabilizing a melt of semiconductor material covering a growing crystal of semiconductor material. The growth process comprises generating a bed of a semiconductor material feed on the top surface of the crucible bottom and melting semiconductor material on the bed using the induction heating coil.

A crystal of semiconductor material is produced in an apparatus having a crucible with a crucible bottom and a crucible wall, the crucible bottom having a top surface, an underside, and a multitude of openings disposed between the crucible wall and a center of the crucible bottom, and elevations disposed on the top surface and the underside of the crucible bottom; and an induction heating coil disposed below the crucible for melting semiconductor material and stabilizing a melt of semiconductor material covering a growing crystal of semiconductor material. The growth process comprises generating a bed of a semiconductor material feed on the top surface of the crucible bottom and melting semiconductor material on the bed using the induction heating coil.

An apparatus for producing a single crystal of silicon comprises a plate with a top side, an outer edge, and an inner edge, a central opening adjoining the inner edge, and a tube extending from the central opening to beneath the bottom side of the plate; a device for metering granular silicon onto the plate; a first induction heating coil above the plate, provided for melting of the granular silicon deposited; a second induction heating coil positioned beneath the plate, provided for stabilization of a melt of silicon, the melt being present upon a growing single crystal of silicon. The top side of the plate consists of ceramic material and has elevations, the distance between the elevations in a radial direction being not less than 2 mm and not more than 15 mm.

An apparatus for producing a single crystal of silicon comprises a plate with a top side, an outer edge, and an inner edge, a central opening adjoining the inner edge, and a tube extending from the central opening to beneath the bottom side of the plate; a device for metering granular silicon onto the plate; a first induction heating coil above the plate, provided for melting of the granular silicon deposited; a second induction heating coil positioned beneath the plate, provided for stabilization of a melt of silicon, the melt being present upon a growing single crystal of silicon. The top side of the plate consists of ceramic material and has elevations, the distance between the elevations in a radial direction being not less than 2 mm and not more than 15 mm.

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. γ and X-ray detectors incorporating the crystals of the inorganic compounds are also provided.

A method of fabricating at least one single-crystal alloy semiconductor structure. At least one seed, containing an alloying material, on a substrate for growth of at least one single-crystal alloy semiconductor structure is formed. At least one structural form, formed of a host material, on the substrate is crystallized to form the at least one single-crystal alloy semiconductor structure. The at least one structural form is heated such that the material of the at least one structural form has a liquid state. Also, the at least one structural form is cooled, such that the material of the at least one structural form nucleates at the least one seed and crystallizes as a single crystal to provide at least one single-crystal alloy semiconductor structure, with a growth front of the single crystal propagating in a main body of the respective structural form away from the respective seed.

A method of fabricating at least one single-crystal alloy semiconductor structure. At least one seed, containing an alloying material, on a substrate for growth of at least one single-crystal alloy semiconductor structure is formed. At least one structural form, formed of a host material, on the substrate is crystallized to form the at least one single-crystal alloy semiconductor structure. The at least one structural form is heated such that the material of the at least one structural form has a liquid state. Also, the at least one structural form is cooled, such that the material of the at least one structural form nucleates at the least one seed and crystallizes as a single crystal to provide at least one single-crystal alloy semiconductor structure, with a growth front of the single crystal propagating in a main body of the respective structural form away from the respective seed.

A single-crystal production equipment which includes, at least: a raw material supply apparatus which supplies a granular raw material to a melting apparatus positioned therebelow; the melting apparatus heats and melts the granular raw material to generate a raw material melt and supplies the raw material melt into a single-crystal production crucible positioned therebelow; and a crystallization apparatus which includes the single-crystal production crucible in which a seed single crystal is placed on the bottom, and a first infrared ray irradiation equipment which irradiates an infrared ray to the upper surface of the seed single crystal in the single-crystal production crucible, and the single-crystal production equipment is configured such that the raw material melt is dropped into a melt formed by irradiating the upper surface of the seed single crystal with the infrared ray, and a single crystal is allowed to precipitate out of the thus formed mixed melt.