A device including a templating structure and a magnetic layer on the templating structure is described. The templating structure includes D and E. A ratio of D to E is represented by D.sub.1-xE.sub.x, with x being at least 0.4 and not more than 0.6. E includes a main constituent. The main constituent includes at least one of Al, Ga, and Ge. Further, E includes at least fifty atomic percent of the main constituent. D includes at least one constituent that includes Ir, D includes at least 50 atomic percent of the at least one constituent. The templating structure is nonmagnetic at room temperature. The magnetic layer includes at least one of a Heusler compound and an L1.sub.0 compound, the magnetic layer being in contact with the templating structure.

A device including a templating structure and a magnetic layer on the templating structure is described. The templating structure includes D and E. A ratio of D to E is represented by D.sub.1-xE.sub.x, with x being at least 0.4 and not more than 0.6. E includes a main constituent. The main constituent includes at least one of Al, Ga, and Ge. Further, E includes at least fifty atomic percent of the main constituent. D includes at least one constituent that includes Ir, D includes at least 50 atomic percent of the at least one constituent. The templating structure is nonmagnetic at room temperature. The magnetic layer includes at least one of a Heusler compound and an L1.sub.0 compound, the magnetic layer being in contact with the templating structure.

An apparatus for manufacturing hexagonal crystals using HVPE includes: a reaction tube; a reaction boat disposed on one side in the reaction tube; a halogenation reaction gas supply pipe for supplying a halogenation reaction gas to the reaction boat; a nitrification reaction gas supply pipe for supplying a nitrification reaction gas to the reaction boat; and a heater for heating the reaction tube. The reaction boat includes a source part for receiving source materials; and a crystal growth part disposed beneath the source part and having a depressed growth mold of a predetermined shape. The source part includes: at least one penetration hole formed on a bottom surface; a first allocating area formed around the at least one penetration hole, for receiving aluminum; and a second allocating area formed around the first allocating area, for receiving a main material of the hexagonal crystal and gallium.

An apparatus for manufacturing hexagonal crystals using HVPE includes: a reaction tube; a reaction boat disposed on one side in the reaction tube; a halogenation reaction gas supply pipe for supplying a halogenation reaction gas to the reaction boat; a nitrification reaction gas supply pipe for supplying a nitrification reaction gas to the reaction boat; and a heater for heating the reaction tube. The reaction boat includes a source part for receiving source materials; and a crystal growth part disposed beneath the source part and having a depressed growth mold of a predetermined shape. The source part includes: at least one penetration hole formed on a bottom surface; a first allocating area formed around the at least one penetration hole, for receiving aluminum; and a second allocating area formed around the first allocating area, for receiving a main material of the hexagonal crystal and gallium.

The present disclosure discloses a shell mold chamber, a foundry furnace and a method for casting single crystal, fine crystal and non-crystal, which employ the technique of asynchronous-curving supercooling, and belongs to the technical field of precise casting apparatuses. Such a three-function foundry furnace includes a heating coil winding, a first thermal-shield assembly, a first superconducting coil, a second thermal-shield assembly and a second superconducting coil; and the first superconducting coil is provided at an inside of the first thermal-shield assembly, and the second superconducting coil is provided at an inside of the second thermal-shield assembly; and directions of a magnetic field generated by the first superconducting coil and a magnetic field generated by the second superconducting coil are opposite; and the first superconducting coil and the heating coil winding form a forward-directional static-magnetic-field heating zone, and the second superconducting coil forms a reverse-directional static-magnetic-field zone.

The present disclosure discloses a shell mold chamber, a foundry furnace and a method for casting single crystal, fine crystal and non-crystal, which employ the technique of asynchronous-curving supercooling, and belongs to the technical field of precise casting apparatuses. Such a three-function foundry furnace includes a heating coil winding, a first thermal-shield assembly, a first superconducting coil, a second thermal-shield assembly and a second superconducting coil; and the first superconducting coil is provided at an inside of the first thermal-shield assembly, and the second superconducting coil is provided at an inside of the second thermal-shield assembly; and directions of a magnetic field generated by the first superconducting coil and a magnetic field generated by the second superconducting coil are opposite; and the first superconducting coil and the heating coil winding form a forward-directional static-magnetic-field heating zone, and the second superconducting coil forms a reverse-directional static-magnetic-field zone.

A directional solidification casting method includes fluidly coupling a feed line conduit with a source of molten metal and with a directional solidification mold at a gating. The mold has an interior chamber with a shape of an object to be cast using directional solidification in a growth direction. The feed line conduit is fluidly coupled with the gating in a downward direction oriented at an angle that is closer to the growth direction of the mold than to another direction that is perpendicular to the growth direction of the mold. The method also includes positioning a downstream portion of the feed line conduit below the gating, directing the molten metal into the mold via the feed line conduit, and casting the object in the mold using directional solidification.

A method of additive manufacturing a structure on a pre-existing includes disposing the pre-existing component in a bed of powdery base material and levelling the component, such that a manufacturing plane of the component can be recoated with the base material and alternatingly recoating and irradiating the manufacturing plane with an energy beam in order to additively build up the structure, wherein the irradiation is carried out in that the manufacturing plane is scanned by the beam in a non-continuous way, wherein, for the irradiation according to a second vector for the structure, the beam is either only guided parallel with respect to a previous first vector, or the irradiation process is paused after the irradiation of the first vector for a time span between 1/10 second to 2 seconds until the irradiation is continued with the second vector.

A single crystal particle powder having a crystal structure of TbCu.sub.7-type of the present invention is represented by the general formula:

[Chemical Formula 1]

(R.sub.1-zM.sub.z)T.sub.x  (1)

or the general formula:

[Chemical Formula 2]

(R.sub.1-zM.sub.z)T.sub.xN.sub.y  (2)

and has a crystal structure of TbCu.sub.7-type,
wherein R is at least one element selected from the group consisting of Sm and Nd, T is at least one element selected from the group consisting of Fe and Co, x is 7.0≤x≤10.0, y is 1.0≤y≤2.0, and z is 0.0≤z≤0.3.

A single crystal particle powder having a crystal structure of TbCu.sub.7-type of the present invention is represented by the general formula:

[Chemical Formula 1]

(R.sub.1-zM.sub.z)T.sub.x  (1)

or the general formula:

[Chemical Formula 2]

(R.sub.1-zM.sub.z)T.sub.xN.sub.y  (2)

and has a crystal structure of TbCu.sub.7-type,
wherein R is at least one element selected from the group consisting of Sm and Nd, T is at least one element selected from the group consisting of Fe and Co, x is 7.0≤x≤10.0, y is 1.0≤y≤2.0, and z is 0.0≤z≤0.3.