Optical fiber light emitter, light emitter bundle, radiation measuring device, and method for manufacturing an optical fiber light emitter

1 . A method for manufacturing an optical fiber emitter, the method comprising: accommodating a core material constituted by a halide in a cylindrical container constituted by a thermoplastic cladding material, the halide having a melting point lower than that of the cladding material; and forming an optical fiber light emitter comprising a core constituted by a crystal of the halide, and a cladding constituted by the cladding material, by heating the container accommodating the core material and stretching the container, the crystal of the halide configured to emit light by being irradiated with radiation. 2 . A method for manufacturing an optical fiber emitter, the method comprising: preparing a cylindrical cladding; forming a melt by melting a halide having a melting point lower than that of a material constituting the cladding; accommodating the melt in the cladding; and forming an optical fiber emitter whose core is made of a crystal of the halide by cooling and solidifying the melt accommodated in the cladding to form the crystal of the halide, the crystal of the halide configured to emit light by being irradiated with radiation. 3 . The method according to claim 2 , wherein accommodating the melt in the cladding includes sucking up the melt into the inside of the cladding. 4 . The method according to claim 2 , wherein accommodating the melt in the cladding includes pushing up the melt into the inside of the cladding. 5 . The method according to claim 2 , wherein preparing the cylindrical cladding includes providing a cladding array in which a plurality of claddings are bundled, and accommodating the melt in the cladding includes accommodating the melt in each of the plurality of claddings of the cladding array. 6 . A method for manufacturing an optical fiber emitter, the method comprising: accommodating in a cylindrical cladding a core material constituted by a halide having a melting point lower than that of a material constituting the cladding; melting the core material accommodated in the cladding; and forming an optical fiber light emitter whose core is made of a crystal of the halide by cooling and solidifying the molten core material to form the crystal of the halide, the crystal of the halide configured to emit light by being irradiated with radiation. 7 . An optical fiber emitter comprising: a core constituted by a halide crystal that emits light; and a cladding surrounding the core, the cladding constituted by a thermoplastic material. 8 . An optical fiber light emitter comprising: a core constituted by a scintillator; and a cladding, wherein the core and the cladding have a thermal expansion coefficient difference of a value 60×10 −6 /K or less and a thermal conductivity difference of a value 30 W/m/K or less. 9 . The optical fiber emitter according to claim 7 , wherein the optical fiber emitter is formed of a multi-core fiber having a plurality of the cores in the same fiber body. 10 . The optical fiber emitter according to claim 9 , wherein diameter of the core, thickness of the cladding, and the outer diameter of the cladding get smaller as approaching from one end side to the other end side. 11 . The optical fiber emitter according to claim 9 , wherein the core is rectangular in a cross-sectional view and arranged in a rectangular manner in the cross-sectional direction. 12 . An optical fiber emitter comprising: a core constituted by a eutectic having two crystalline phases; and a cladding, wherein at least one of the crystalline phases emits light by being irradiated with radiation. 13 . The optical fiber emitter according to claim 12 , wherein average crystal grain size of the two crystalline phases is 30 μm or less. 14 . The optical fiber emitter according to claim 12 , wherein refractive index difference between the two crystalline phases is 0.1 or less at an emitting wavelength. 15 . The optical fiber emitter according to claim 14 , wherein average crystal grain size of the two crystalline phases is 30 μm or less. 16 . The optical fiber emitter according to claim 7 , wherein the core is constituted by an oxide crystal or a halide crystal that emits light by being irradiated with radiation. 17 . A radiation measuring device comprising the optical fiber emitter according to claim 7 . 18 . A light emitter bundle in which a plurality of the optical fiber emitters according to claim 7 are bundled. 19 . A radiation measuring device comprising the light emitter bundle according to claim 18 . 20 . A radiation measuring device comprising: an optical fiber light emitter including a core constituted by a scintillator that emits light by being irradiated with radiation, and a cladding surrounding the core; a first sensor for detecting light reaching one end side of the optical fiber emitter; a second sensor for detecting light reaching the other end side of the optical fiber emitter; and a calculation circuit for obtaining an incident position of radiation in the optical fiber emitter by at least one of a difference in light detection time and a difference in the detected amount of light, between the first sensor and the second sensor. 21 . The radiation measuring device according to claim 20 , wherein the optical fiber light emitter is formed in a coil shape. 22 . The optical fiber emitter according to claim 8 , wherein the optical fiber emitter is formed of a multi-core fiber having a plurality of the cores in the same fiber body. 23 . The optical fiber emitter according to claim 22 , wherein diameter of the core, thickness of the cladding, and the outer diameter of the cladding get smaller as approaching from one end side to the other end side. 24 . The optical fiber emitter according to claim 22 , wherein the core is rectangular in a cross-sectional view and arranged in a rectangular manner in the cross-sectional direction. 25 . The optical fiber emitter according to claim 8 , wherein the core is constituted by an oxide crystal or a halide crystal that emits light by being irradiated with radiation. 26 . A radiation measuring device comprising the optical fiber emitter according to claim 8 . 27 . A light emitter bundle in which a plurality of the optical fiber emitters according to claim 8 are bundled. 28 . A radiation measuring device comprising the light emitter bundle according to claim 27 .