A laser crystallization apparatus includes a plurality of laser generators which generate a plurality of laser beams, a plurality of attenuators which adjust energy intensity of the plurality of laser generators, and an optical module which overlap outputs of the plurality of attenuators to output a line beam. A first attenuator of the plurality of attenuators attenuates the energy intensity of the corresponding laser beam, and a second attenuator of the plurality of attenuators maintains the energy intensity of the corresponding laser beam.

There is provided a method for manufacturing a turbine component which enables obtaining a single crystal structure more easily and manufacturing a good turbine component. In the seed crystal placing step, the seed crystal is placed on the surface of the base in a manner that a first direction along <001> of the seed crystal has an angle within 15 degrees in absolute value in relation to a laminating direction. In the shaped layer forming step, scanning is performed in a manner that the scan direction has an angle within 20 degrees in absolute value in relation to a second direction being <001> orthogonal to the first direction of the seed crystal.

A method of performing regional heating of a substrate by electromagnetic induction heating. The method may include applying a semiconductor film to the substrate and controllably energizing a coil positioned near the substrate. The energized coil(s) thereby generates a magnetic flux, which induces a current in the substrate and/or the semiconductor film, thereby heating the substrate and/or semiconductor film. The method may also include relative motion between the coil and the substrate to provide translation heating of the semiconductor film. Additionally, a crystal seeding mechanism may be employed to further control the crystallization process.

A method of performing regional heating of a substrate by electromagnetic induction heating. The method may include applying a semiconductor film to the substrate and controllably energizing a coil positioned near the substrate. The energized coil(s) thereby generates a magnetic flux, which induces a current in the substrate and/or the semiconductor film, thereby heating the substrate and/or semiconductor film. The method may also include relative motion between the coil and the substrate to provide translation heating of the semiconductor film. Additionally, a crystal seeding mechanism may be employed to further control the crystallization process.

A method of producing a substance includes a producing step of producing a new substance by, in a state in which a raw material absorbing giant pulse laser light is disposed inside a base material or in a state in which the base material and the raw material are brought into contact with each other and are clamped together, performing irradiation with the giant pulse laser light such that the raw material absorbs the giant pulse laser light and thereby generating shock waves such that at least the raw material undergoes phase transition.

A method of performing regional heating of a substrate by electromagnetic induction heating. The method may include applying a semiconductor film to the substrate and controllably energizing a coil positioned near the substrate. The energized coil(s) thereby generates a magnetic flux, which induces a current in the substrate and/or the semiconductor film, thereby heating the substrate and/or semiconductor film. The method may also include relative motion between the coil and the substrate to provide translation heating of the semiconductor film. Additionally, a crystal seeding mechanism may be employed to further control the crystallization process.

A method of performing regional heating of a substrate by electromagnetic induction heating. The method may include applying a semiconductor film to the substrate and controllably energizing a coil positioned near the substrate. The energized coil(s) thereby generates a magnetic flux, which induces a current in the substrate and/or the semiconductor film, thereby heating the substrate and/or semiconductor film. The method may also include relative motion between the coil and the substrate to provide translation heating of the semiconductor film. Additionally, a crystal seeding mechanism may be employed to further control the crystallization process.

A laser crystallization apparatus includes a plurality of laser generators which generate a plurality of laser beams, a plurality of attenuators which adjust energy intensity of the plurality of laser generators, and an optical module which overlap outputs of the plurality of attenuators to output a line beam. A first attenuator of the plurality of attenuators attenuates the energy intensity of the corresponding laser beam, and a second attenuator of the plurality of attenuators maintains the energy intensity of the corresponding laser beam.

A lasing medium having a tailored dopant concentration and a method of fabrication thereof is disclosed. The lasing medium has a single crystal having a continuous body having a selected length, wherein the crystal comprises dopant distributed along the length of the body to define a dopant concentration profile. In one embodiment, the dopant concentration profile results in a uniform heating profile. A method of fabricating a laser crystal having a tailored dopant concentration profile includes arranging a plurality of polycrystalline segments together to form an ingot, the polycrystalline segments each having dopant distributed, providing a crystal seed at a first end of the ingot, and moving a heating element along the ingot starting from the first end to a second end of the ingot, the moving heating element creating a moving molten region within the ingot while passing therealong.

A method of producing a substance includes a producing step of producing a new substance by, in a state in which a raw material absorbing giant pulse laser light is disposed inside a base material or in a state in which the base material and the raw material are brought into contact with each other and are clamped together, performing irradiation with the giant pulse laser light such that the raw material absorbs the giant pulse laser light and thereby generating shock waves such that at least the raw material undergoes phase transition.