Various embodiments include a device for producing structurally modified materials. In some embodiments, the device includes a floating zone furnace which holds a feed rod in contact with seed crystal. One or more laser diodes are then used to heat a portion of the feed rod and cause it to transition to a molten state. A magnetic field is applied to the floating zone to change the underlying crystal structure of the material as it solidifies upon exiting the floating zone. In some instances, the changes may include manipulating the bond angle of the crystal structure or altering the unit cell volume of the crystal. Changes in the crystal structure directly affect the electrical resistivity and/or the magnetization and other physical properties of the crystal.

Various embodiments include a device for producing structurally modified materials. In some embodiments, the device includes a floating zone furnace which holds a feed rod in contact with seed crystal. One or more laser diodes are then used to heat a portion of the feed rod and cause it to transition to a molten state. A magnetic field is applied to the floating zone to change the underlying crystal structure of the material as it solidifies upon exiting the floating zone. In some instances, the changes may include manipulating the bond angle of the crystal structure or altering the unit cell volume of the crystal. Changes in the crystal structure directly affect the electrical resistivity and/or the magnetization and other physical properties of the crystal.

For evaluating a polycrystalline silicon rod to be used as a raw material for production of FZ Si single crystals, novel evaluation values (values of characteristics×amount of crystals) including the amount of crystals grown in the growth direction (radial direction) are defined and the homogeneity in crystal characteristics in the growth direction (radial direction) is evaluated. Specifically, the homogeneity of the polycrystalline rod is evaluated by sampling a plurality of specimen plates each having, as a principal plane thereof, a cross-section perpendicular to a radial direction of the polycrystalline rod grown by a Siemens method at equal intervals in the radial direction, determining values of characteristics of the crystals of the specimen plates by measurements, and by using evaluation values obtained by multiplying amounts of the crystals (relative amounts of the crystals) at sites where the specimen plates have been sampled by the values of the crystal characteristics.

For evaluating a polycrystalline silicon rod to be used as a raw material for production of FZ Si single crystals, novel evaluation values (values of characteristics×amount of crystals) including the amount of crystals grown in the growth direction (radial direction) are defined and the homogeneity in crystal characteristics in the growth direction (radial direction) is evaluated. Specifically, the homogeneity of the polycrystalline rod is evaluated by sampling a plurality of specimen plates each having, as a principal plane thereof, a cross-section perpendicular to a radial direction of the polycrystalline rod grown by a Siemens method at equal intervals in the radial direction, determining values of characteristics of the crystals of the specimen plates by measurements, and by using evaluation values obtained by multiplying amounts of the crystals (relative amounts of the crystals) at sites where the specimen plates have been sampled by the values of the crystal characteristics.

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.

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.

One or more embodiments relate to a method for controlling fiber growth and fiber diameter in a laser heated pedestal growth (LHPG) system so as to provide long, continuous single-crystal optical fibers of uniform diameter. The method generally provides three independent parameter feedback controls to control the molten zone height, laser power, and fiber drawing rates simultaneously in order to reduce the mismatch between instantaneous diameter changes and current diameter. The method permits the growth of fibers with non-uniform diameters along the fiber's length. The method also provides the capability to stop the LHPG system, remove the exhausted pedestal feedstock with a second pedestal feedstock, and restart the LHPG system to provide a continuous fiber.

One or more embodiments relate to a method for controlling fiber growth and fiber diameter in a laser heated pedestal growth (LHPG) system so as to provide long, continuous single-crystal optical fibers of uniform diameter. The method generally provides three independent parameter feedback controls to control the molten zone height, laser power, and fiber drawing rates simultaneously in order to reduce the mismatch between instantaneous diameter changes and current diameter. The method permits the growth of fibers with non-uniform diameters along the fiber's length. The method also provides the capability to stop the LHPG system, remove the exhausted pedestal feedstock with a second pedestal feedstock, and restart the LHPG system to provide a continuous fiber.

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.