Neutron generation source, and neutron generation device
|発明の名称 （英語）||Neutron generation source, and neutron generation device|
|発明の概要（英語）||The present invention provides a novel neutron source. A neutron source (1) of the present invention includes a neutron producing material layer (3) and a metal layer (2), and the metal layer (2) contains a metal element which has a high hydrogen diffusivity and generates radionuclides having a short half-life upon receipt of irradiation of neutron beams.|
In recent years, instead of a method of producing neutron beams with high energy efficiency as used in a large facility, there has been tried to be developed a method of producing neutron beams with use of low energy beams. In such a method, neutron beams are produced by, for example, irradiating a target (e.g., Be, Li, or the like) with proton beams to thereby cause a nuclear reaction. This method can produce neutron beams with use of extremely low energy proton beams.
According to the above method, for example, there is no need to provide a gigantic radiation blocking structure which can be accepted only in a large facility. It is therefore considered that a neutron source employing the above method is extremely suitable for use in a small facility. In particular, in a case where proton beams having an energy of not more than 13 MeV are used, the neutron source can be easily handled because an amount of a resultant radioactivated material is extremely low.
However, low energy proton beams penetrate a target extremely shallowly. Therefore, a proton, with which a material is irradiated becomes hydrogen and the hydrogen is easily accumulated in the target locally. In view of this, it is known that a target is broken mainly by a mechanism of hydrogen embrittlement for an extremely short time. This phenomenon is called blistering. From a practical standpoint, the blistering is a fatal problem in a low energy neutron generator employing the above method.
In view of this problem, various researches have been conducted. There is reported a neutron source for producing neutron with use of a Li (p, n) reaction in which Li is used (Non-patent Literatures 1-4).
In Non-patent Literatures 1 through 3, blistering of a Li target was verified. Specifically, Non-patent Literatures 1 through 3 report that, in a case where a Li target is irradiated with proton beams of 2.5 MeV or 1.9 MeV, blistering occurs due to a beam current having 10 mA after 3.5 hours from this irradiation. Those literatures conclude that the blistering is not problematic from a practical standpoint, because a single irradiation time period in a BNCT therapy (Boron Neutron Capture Therapy) is shorter than the above time period.
Non-patent Literature 4 reports a structure for preventing hydrogen embrittlement of a target. According to the report, protons (hydrogen atoms) which have passed through Li are absorbed and diffused by the structure in which a thin film made from Pd having high hydrogen transparency is formed under Li.
Non-patent Literature 5 shows a result of simulation for preventing hydrogen embrittlement with use of a target other than Li. From the simulation, such a result was obtained that, when a neutron source is formed by joining thin Be and Nb, hydrogen embrittlement is preventable because almost all irradiated proton beams penetrate Be and are remained in Nb. Therefore, there is a possibility that the structure stably prevents hydrogen embrittlement of a neutron source for a long time.
Non-patent Literature 6 reports results of tests regarding conditions for causing blistering in various metals when the various metals are irradiated with proton beams. The test is carried out by observing the metals which have been irradiated with proton beams of 200 keV with use of, for example, an electron microscope by an optical method. As the result of this, it is reported that blistering does not occur in V and Ta under the tested conditions.
Non-patent Literature 1
B. Bayanov et. al., Neutron producing target for acceleratorbased neutron capture therapy, Journal of Physics Conference Series 41 pp. 460-465, 2006 Institute of Physics Publishing
Non-patent Literature 2
B. Bayanov et. al., A neutron producing target for BINP accelerator-based neutron source, Applied Radiation and Isotopes, Volume 67, Issues 7-8, Supplement, Pages S282-S284, 2009
Non-patent Literature 3 V. Aleynik et. al., BINP accelerator based epithermal neutron source, Applied Radiation and Isotopes vol. 69, pp. 1635-1638, 2011
Non-patent Literature 4
C. Willis et. al., High-power lithium target for accelerator-based BNCT, Proceedings of the XXIV Linear Accelerator Conference, pp. 223-225, 2008
Non-patent Literature 5
J. Ju et. al., Simulation and design of beryllium target combined with hydrogen diffusible metal for compact neutron source in RIKEN, PS2-074, p. 359, Abstract of 1 st Asia-Oceania Conference on Neutron Scattering, 2011
Non-patent Literature 6
S. V. Polosatkin et. al., Experimental Studies of Blisteringof Targets Irradiated by Intense 200 keV Proton Beam, Proceedings of the 9th Conference on Modification of Materials with Particle Beams and Plasma Flows, Sep. 21-26, pp. 131-134, 2008
1. A neutron source, comprising:
a neutron producing material layer for producing neutron beams upon receipt of irradiation of proton beams; and
a metal layer joined with the neutron producing material layer,
the metal layer containing, as a main content, such a metal element that has a hydrogen diffusion coefficient of not less than 10-11 (m2/sec.) at 60°C, and generates radionuclides upon receipt of the irradiation of the neutron beams, among which radionuclides, a type of radionuclides having a largest total radiation dose has a half-life of not more than 12 hours.
2. The neutron source as set forth in claim 1,
wherein the metal element is selected from the group consisting of V, Ni, Ti, and alloys of any combinations of V, Ni, and Ti.
3. The neutron source as set forth in claim 1 or 2,
wherein the neutron producing material layer is 50 µm to 1.2 mm in thickness.
4. The neutron source as set forth in any one of claims 1 to 3,
wherein the neutron producing material layer contains a neutron producing material which is selected from the group consisting of Be, Be compounds, Li, and Li compounds.
5. The neutron source as set forth in any one of claims 1 to 4,
wherein the neutron producing material layer and the metal layer are joined by diffusion bonding or brazing.
6. A neutron generator, comprising
a neutron source recited in any one of claims 1 to 5.
|指定国||Contracting States: AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR|
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