A crystal support for a crystal pulling system includes two catches that have a respective retaining jaw that is placeable against a thickened neck portion of a crystal. The two catches are moveable into a bearing position in which the two catches bear on the thickened neck portion and into a releasing position in which the two catches are away from the thickened neck portion. In the bearing position, respective contact points of each retaining jaw at which the retaining jaws bear on the thickened neck portion are located on respective sides of a parting plane. The parting plane extends at an angle to at least one of the pivot axes of the catches and, in the bearing position, the respective contact points of each retaining jaw are located on both sides of a crystal plane that extends through an axis of the crystal and parallel to the pivot axes.

A crystal support for a crystal pulling system includes two catches that have a respective retaining jaw that is placeable against a thickened neck portion of a crystal. The two catches are moveable into a bearing position in which the two catches bear on the thickened neck portion and into a releasing position in which the two catches are away from the thickened neck portion. In the bearing position, respective contact points of each retaining jaw at which the retaining jaws bear on the thickened neck portion are located on respective sides of a parting plane. The parting plane extends at an angle to at least one of the pivot axes of the catches and, in the bearing position, the respective contact points of each retaining jaw are located on both sides of a crystal plane that extends through an axis of the crystal and parallel to the pivot axes.

A bismuth-substituted rare earth iron garnet single crystal suitable for Faraday rotators and optical isolators with reduced insertion loss due to suppressed valence fluctuation of Fe ions is provided. The bismuth-substituted rare earth iron garnet single crystal of the present invention is characterized by the composition formula (Tb.sub.aLn.sub.bBi.sub.cMg.sub.3−(a+b+c))(Fe.sub.dGa.sub.eTi.sub.fPt.sub.5−(d+e+f))O.sub.12. In the composition formula above, 0.02≤f≤0.05, 0.02≤{3−(a+b+c)}≤0.08, and −0.01≤{3−(a+b+c)}−{f+5−(d+e+f)}≤0.01. Ln is a rare earth element and may be selected from Eu, Gd, Ho, Tm, Yb, Lu, and Y.

A bismuth-substituted rare earth iron garnet single crystal suitable for Faraday rotators and optical isolators with reduced insertion loss due to suppressed valence fluctuation of Fe ions is provided. The bismuth-substituted rare earth iron garnet single crystal of the present invention is characterized by the composition formula (Tb.sub.aLn.sub.bBi.sub.cMg.sub.3−(a+b+c))(Fe.sub.dGa.sub.eTi.sub.fPt.sub.5−(d+e+f))O.sub.12. In the composition formula above, 0.02≤f≤0.05, 0.02≤{3−(a+b+c)}≤0.08, and −0.01≤{3−(a+b+c)}−{f+5−(d+e+f)}≤0.01. Ln is a rare earth element and may be selected from Eu, Gd, Ho, Tm, Yb, Lu, and Y.

[Object] To provide a thin plate-shaped single-crystal production equipment and a thin plate-shaped single-crystal production method that can produce a thin plate-shaped single crystal having a uniform dopant concentration at an optimum chemical composition and a thickness of several hundreds of micrometers continuously at low cost with high precision even when the single crystal is a single crystal of an incongruent melting material or a solid solution material or a single crystal of a congruent melting material.

[Solution] Thin plate-shaped single-crystal production equipment includes: an infrared ray irradiation apparatus that irradiates an upper surface of a raw material lump for production of a thin plate-shaped single crystal with an infrared ray to melt the upper surface; and an elevator apparatus that causes a lower surface of a thin plate-shaped seed single crystal to be immersed in a melt melted using the infrared ray irradiation apparatus and formed on the upper surface and then pulls the thin plate-shaped seed single crystal immersed in the melt upward. The thin plate-shaped single-crystal production equipment is configured such that, by using the elevator apparatus to immerse the lower surface of the thin plate-shaped seed single crystal in the melt formed on the upper surface of the raw material lump for the production of the thin plate-shaped single crystal using the infrared ray irradiation apparatus, growth of a single crystal is started from the lower surface of the immersed thin plate-shaped seed single crystal and that, by using the elevator apparatus to pull the thin plate-shaped seed single crystal upward, the thin plate-shaped single crystal is produced continuously.

[Object] To provide a thin plate-shaped single-crystal production equipment and a thin plate-shaped single-crystal production method that can produce a thin plate-shaped single crystal having a uniform dopant concentration at an optimum chemical composition and a thickness of several hundreds of micrometers continuously at low cost with high precision even when the single crystal is a single crystal of an incongruent melting material or a solid solution material or a single crystal of a congruent melting material.

[Solution] Thin plate-shaped single-crystal production equipment includes: an infrared ray irradiation apparatus that irradiates an upper surface of a raw material lump for production of a thin plate-shaped single crystal with an infrared ray to melt the upper surface; and an elevator apparatus that causes a lower surface of a thin plate-shaped seed single crystal to be immersed in a melt melted using the infrared ray irradiation apparatus and formed on the upper surface and then pulls the thin plate-shaped seed single crystal immersed in the melt upward. The thin plate-shaped single-crystal production equipment is configured such that, by using the elevator apparatus to immerse the lower surface of the thin plate-shaped seed single crystal in the melt formed on the upper surface of the raw material lump for the production of the thin plate-shaped single crystal using the infrared ray irradiation apparatus, growth of a single crystal is started from the lower surface of the immersed thin plate-shaped seed single crystal and that, by using the elevator apparatus to pull the thin plate-shaped seed single crystal upward, the thin plate-shaped single crystal is produced continuously.

Provided is a raw material supply unit comprising: a main body having a space into which raw material is filled; a barrier for dividing the main body into two or more areas in the longitudinal direction; a rod extending from above the main body into the interior of same; and a valve, connected to the rod, for covering or exposing the lower portion of the main body, wherein the bottom surface of the main body has a step.

Provided is a raw material supply unit comprising: a main body having a space into which raw material is filled; a barrier for dividing the main body into two or more areas in the longitudinal direction; a rod extending from above the main body into the interior of same; and a valve, connected to the rod, for covering or exposing the lower portion of the main body, wherein the bottom surface of the main body has a step.

A crystal growing system includes a rotating seed lift assembly to rotate and lift a seed crystal supported by a cable. The seed lift assembly includes a spool that rotates to wrap the cable around the spool, thus raising the cable. As the spool rotates, it moves in an axial direction to avoid displacing the cable in the axial direction. Movement of the spool and rotation of the seed lift assembly induce deviations in the center of mass of the seed lift assembly with respect to its axis of rotation, which can cause undesired movement of the cable and thus seed crystal. A dynamic counterweight system makes use of one or more sensors to detect movement of the seed lift assembly and dynamically control a motor-driven, movable counterweight to offset these deviations, thus maintaining the center of mass at or substantially in line with the axis of rotation.

The present disclosure provides a temperature field device for crystal growth. The temperature field device may include a drum; a filler filled in the drum and configured to support a crucible; a bottom plate mounted on a bottom of the temperature field device and covering a bottom end of the drum; and a cover plate mounted on a top of the temperature filed device and covering a top end of the drum.