A device for growing crystals, includes a crucible and an enveloping unit surrounding it for the thermal insulation of the crucible The enveloping unit is held on the crucible in its position relative thereto by a holding unit The holding unit includes at least one holding element designed to be oblong and preferably non-rigid, having a first and second end section The holding element surrounds the enveloping unit circumferentially on the side facing away from the crucible and contacts it. The two end sections are coupled to one another, wherein a holding force acting on the enveloping unit in the radial direction is applied by the holding element

A device for growing single crystals, in particular single crystals of silicon carbide, includes a crucible, which crucible defines an outer lateral surface and moreover delimits an accommodation space with an axial extension between a bottom section and an opening section, wherein the accommodation space is designed for growing the crystals, wherein the device hast at least one seed crystal layer wherein the crucible is arranged in a chamber, in particular made of a glass material, for example quartz glass, wherein an induction heater is arranged around the chamber. The crucible is designed to have multiple parts and includes a crucible bottom section, at least one crucible wall part, and a crucible cover part, which are releasably connected to one another.

A method for producing an n-type monocrystalline silicon that includes pulling up a monocrystalline silicon from a silicon melt containing a main dopant in a form of red phosphorus to grow the monocrystalline silicon. The monocrystalline silicon exhibits an electrical resistivity ranging from 1.7 mΩcm to 2.0 mΩcm, and is pulled up using a quartz crucible whose inner diameter ranges from 1.7-fold to 2.0-fold relative to a straight-body diameter of the monocrystalline silicon.

A method for producing Si ingot single crystal by NOC growth method including a Si ingot single crystal growing step and a continuous growing step is provided. The growing step includes providing a low temperature region in the Si melt where the Si ingot single crystal is grown along the surface of the Si melt or toward the inside of the Si melt, and the Si ingot single crystal has distribution of a vacancy concentration and an interstitial concentration in which respectively a vacancy concentration and an interstitial concentration vary with a distance from the growth interface; and adjusting a temperature gradient and a growth rate in the Si melt, so that along with the increasing of the distance from the growth interface, the vacancy concentration and the interstitial concentration in the Si ingot single crystal respectively decrease come near to each other.

A pressure container for crystal production having excellent corrosion-resistance is provided. This pressure container produces crystals within the container using a seed crystal, a mineralizer, a raw material, and ammonia in a supercritical state or a subcritical state as a solvent. The pressure container has Ag present over the entire surface of at least the inner surface thereof in contact with the solvent. The Ag can be disposed by one or a combination of two or more among, for instance, Ag lining, Ag welding, and Ag plating. The mineralizer is preferably a fluorine mineralizer containing no halogen atoms other than fluorine.

The present invention provides an optical ZnS material and a preparation method thereof, wherein the preparation method comprises: charging zinc and sulfur into a first crucible and a feeding device of a chemical vapor deposition furnace, respectively; heating the first crucible, the second crucible and a deposition chamber, and charging sulfur into the second crucible through the feeding device; introducing an inert carrier gas into the first crucible, and introducing an inert carrier gas and hydrogen into the second crucible, flowing the carrier gas containing zinc vapor and sulfur vapor respectively into the deposition chamber through pipelines to deposit ZnS, and supplying the second crucible with sulfur regularly and quantitatively through the feeding device during the deposition process to maintain a saturated vapor pressure of sulfur in a range of 0.8 to 1.8 KPa. The preparation method of the present invention does not generate H.sub.2S; thus it can avoid the formation of hydrogen-zinc complexes by H ions produced from the decomposition of H.sub.2S and Zn vapor, which would otherwise affect the transmittance and emissivity of ZnS material.

A crystal puller apparatus comprises a pulling assembly to pull a crystal from a silicon melt at a pull speed; a crucible that contains the silicon melt; a heat shield above a surface of the silicon melt; a lifter to change a gap between the heat shield and the surface of the silicon melt; and one or more computing devices to determine an adjustment to the gap using a Pv-Pi margin, at a given length of the crystal, in response to a change in the pull speed. The computer-implemented method by a computing device comprises determining a pull-speed command signal to control a diameter of the crystal; determining a lifter command signal to control a gap between a heat shield and a surface of a silicon melt from which the crystal is grown; and determining an adjustment to the gap, in response to a different pull-speed, using a Pv-Pi margin.

A quartz glass crucible 1 includes: a quartz glass crucible body 10 having a cylindrical side wall portion 10a, a curved bottom portion 10b, and a corner portion 10c which has a larger curvature than that of the bottom portion 10b and connects the side wall portion 10a and the bottom portion 10b to each other; and an inner-surface coating film 13A which contains a crystallization accelerator and is formed on an inner surface 10i of the quartz glass crucible body 10, in which the inner surface 10i of the quartz glass crucible body 10 is under compressive stress. The quartz glass crucible has high durability even at a high temperature during a single crystal pull-up step and is capable of reducing a generation ratio of pinholes in a silicon single crystal.

The present invention provides a single crystal growth crucible and a single crystal growth method which can suppress the recrystallization of the raw material gas which has been sublimated on the surface of the raw material and can suppress the generation of different polytypes in single crystal growth. The single crystal growth crucible includes an inner bottom, a crystal mounting part, and a deposition preventing member, wherein a raw material is provided in the inner bottom, the crystal mounting part faces the inner bottom, the deposition preventing member has a first surface comprising metal carbide, a first surface is disposed to face the crystal mounting part, the deposition preventing member is disposed in a central area of the inner bottom in a plan view from the crystal mounting part, and the first surface is disposed in accordance with the position of the surface of the raw material.

A method of growing the ingot, including following steps: S1, providing an initial charge into a crucible; S2, heating the crucible to melt the initial charge, and after a set time, rotating the crucible at a rotation speed within a set speed range; S3, after a melting process of the charge is completed, descending a feed device to the position above the melt level in the crucible and a distance between feed device and the melt level being h, the feed device including a feed tube, and the feed tube adding a charge into a feed zone of the crucible; and S4, feeding in the feed zone, and growing an ingot in a growth zone. In Sl, the initial charge is respectively loaded into a first chamber, a second chamber and a third chamber,