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.

A superconducting magnet device includes a superconducting coil; a radiation shield that thermally protects the superconducting coil; a main cold head that cools the superconducting coil; a sub-cold head that cools the radiation shield; a common compressor that supplies a refrigerant gas to the main cold head and the sub-cold head; a first temperature sensor that measures a temperature of the radiation shield; a second temperature sensor that measures a temperature of the superconducting coil; and a controller configured to activate the sub-cold head for initial cooling of the superconducting magnet device, stop the sub-cold head based on an output of the first temperature sensor or the second temperature sensor, and operate the main cold head in a state where the sub-cold head is stopped.

A superconducting magnet device includes a superconducting coil; a radiation shield that thermally protects the superconducting coil; a main cold head that cools the superconducting coil; a sub-cold head that cools the radiation shield; a common compressor that supplies a refrigerant gas to the main cold head and the sub-cold head; a first temperature sensor that measures a temperature of the radiation shield; a second temperature sensor that measures a temperature of the superconducting coil; and a controller configured to activate the sub-cold head for initial cooling of the superconducting magnet device, stop the sub-cold head based on an output of the first temperature sensor or the second temperature sensor, and operate the main cold head in a state where the sub-cold head is stopped.

A superconducting coil module includes: a first coil composed of a superconducting wire material wound multiple times; and a first heating device coupled to one surface of the first coil and including at least one first heating pattern controlling a threshold current for each turn of the first coil as a minimum threshold current, wherein at least one first heating pattern is disposed on a path according to a predetermined ratio between the inner and outer boundaries of the first coil.

A superconducting coil module includes: a first coil composed of a superconducting wire material wound multiple times; and a first heating device coupled to one surface of the first coil and including at least one first heating pattern controlling a threshold current for each turn of the first coil as a minimum threshold current, wherein at least one first heating pattern is disposed on a path according to a predetermined ratio between the inner and outer boundaries of the first coil.

In a magnet system: —a superconducting main field magnet (7) generates a magnetic field in a first sample volume (16), —a superconducting additional field magnet (22) generates another field in a second sample volume (24), —a cryostat (2) has a cooled main coil container (6), an evacuated RT (room temperature) covering (4), and an RT bore (14) which extends through the main and the additional field magnets, and —a cooled additional coil container (21) in a vacuum. The RT covering has a flange connection (17) with an opening (19) through which the RT bore extends, a front end of the additional coil container protrudes through the opening into the RT covering such that the additional field magnet also protrudes through the opening into the RT covering, and a closure structure (20) seals the RT covering between the flange connection and the RT bore.

In a magnet system: —a superconducting main field magnet (7) generates a magnetic field in a first sample volume (16), —a superconducting additional field magnet (22) generates another field in a second sample volume (24), —a cryostat (2) has a cooled main coil container (6), an evacuated RT (room temperature) covering (4), and an RT bore (14) which extends through the main and the additional field magnets, and —a cooled additional coil container (21) in a vacuum. The RT covering has a flange connection (17) with an opening (19) through which the RT bore extends, a front end of the additional coil container protrudes through the opening into the RT covering such that the additional field magnet also protrudes through the opening into the RT covering, and a closure structure (20) seals the RT covering between the flange connection and the RT bore.

Some embodiments of the present disclosure relate to a displacer for reducing the consumption of a cryogen used in a superconductive magnet device. The displacer may occupy some space within the cryogen storage cavity or limit the cryogen into a relatively small space surrounding a superconductive coil in the cryogen storage cavity. The displacer may also include a displacer cavity that may be vacuum or contain a cryogen or another substance.

Some embodiments of the present disclosure relate to a displacer for reducing the consumption of a cryogen used in a superconductive magnet device. The displacer may occupy some space within the cryogen storage cavity or limit the cryogen into a relatively small space surrounding a superconductive coil in the cryogen storage cavity. The displacer may also include a displacer cavity that may be vacuum or contain a cryogen or another substance.

A superconducting coil device (10) includes: a coil case (20) housing a superconducting coil (30); a superconducting coil (30) housed in the coil case (20); and a resin part (50) formed of a polymer (51) filled in a gap between an inner wall of the coil case (20) and the superconducting coil (30). The resin part (50) is formed of a polymer (51) obtained by polymerizing a polymerizable composition containing a first monomer having a norbornene ring structure.