Patent Number: 
Section: claims

1. A target for a neutron-generating device that generates neutrons by using a 7Li(p,n)7Be reaction while lithium as a target material is irradiated with proton beams accelerated by an accelerator, the target comprising:a metal substrate that retains the target material; anda metal thin film for sealing that seals the target material onto the metal substrate at a retention surface side holding the target material,the metal substrate comprising: on the retention surface side,a frame portion; andan embossed structure comprising:a plurality of discrete island portions surrounded by the frame portion and regularly arranged in lateral and longitudinal directions, the island portions having the same height as the frame portion; anda recessed portion that is created by decreasing a thickness of a region other than the frame portion and the plurality of island portions by a thickness of the target material,wherein the metal thin film for sealing is bonded to surfaces of the frame portion and the plurality of island portions and configured to keep a thickness of the target material even when the target material is melted while being irradiated with the proton beams,wherein the metal thin film for sealing is configured to seal the target material onto the recessed portion of the metal substrate, and the target material is tightly attached to the metal thin film for sealing. 2. The target for a neutron-generating device according to claim 1, wherein the recessed portion of the embossed structure comprises: a plurality of circular recessed portions that are hexagonally arranged inside the surrounding frame portion and are circular in a planar view; and communicating recessed portions in communication with the adjacent circular recessed portions. 3. The target for a neutron-generating device according to claim 1, wherein a bottom of the recessed portion has an attachment-promoting layer that causes the target material to better attach to the metal substrate. 4. The target for a neutron-generating device according to claim 3, wherein the attachment-promoting layer is a thin film layer made of copper, aluminum, magnesium, or zinc. 5. The target for a neutron-generating device according to claim 1, wherein the metal substrate further comprises a plurality of elongated coolant passages through which a coolant flows at a surface side opposite to the retention surface side. 6. The target for a neutron-generating device according to claim 1, wherein the metal substrate is made of iron or tantalum and the metal thin film for sealing is made of a stainless steel sheet, titanium sheet, titanium alloy sheet, beryllium sheet, or beryllium alloy sheet. 7. The target for a neutron-generating device according to claim 1, wherein the island portions of the embossed structure are made of a lithium alloy comprising any of 1 to 20 mass % of Cu, 20 to 40 mass % of Al, and 45 to 60 mass % of Mg, and the remainder consisting of Li and unavoidable impurities. 8. A method for manufacturing a target for a neutron-generating device that generates neutrons by using a 7Li(p,n)7Be reaction while lithium as a target material is irradiated with proton beams accelerated by an accelerator, the method comprising:an embossed structure processing step of producing an embossed structure comprising: on a retention surface side of a metal substrate holding the target material, a frame portion for sealing the target material; a plurality of discrete island portions that are surrounded by the frame portion and regularly arranged in lateral and longitudinal directions and that have the same height as of the frame portion; and a recessed portion that is created by decreasing a thickness of a region other than the island portions by a thickness of the target material;an attachment-promoting layer formation step of producing an attachment-promoting layer at a bottom of the recessed portion, the layer causing the target material to better attach to the metal substrate;a target material filling step of filling the recessed portion at the retention surface side with the target material so that a level of the target material is higher than surfaces of the frame portion and the island portions, and thereafter;a retention surface smoothing step of grinding and leveling the target material thus solidified so that the surfaces of the frame portion and the island portions are exposed; anda bonding step of bonding a metal thin film for sealing the target material to the recessed portion of the metal substrate onto the surfaces of the frame portion and the island portions at the retention surface side by using hot isostatic pressing (HIP) bonding so that the target material is tightly attached to the metal thin film for sealing and a thickness of the target material is kept even when the target material is melted while being irradiated with the proton beams. 9. A method for manufacturing a target for a neutron-generating device that generates neutrons by using a 7Li(p,n)7Be reaction while lithium as a target material is irradiated with proton beams accelerated by an accelerator, the method comprising:an embossed structure processing step of producing an embossed structure comprising: on a retention surface side of a metal substrate holding the target material, a frame portion for sealing the target material; a plurality of discrete island portions that are surrounded by the frame portion and regularly arranged in lateral and longitudinal directions and that have the same height as of the frame portion; and a recessed portion that is created by decreasing a thickness of a region other than the island portions by a thickness of the target material;a bonding step of bonding a metal thin film for sealing the target material to the recessed portion of the metal substrate onto surfaces of the frame portion and the island portions at the retention surface side by using hot isostatic pressing (HIP) bonding; anda target material filling step comprising:heating the metal substrate after the bonding step to a first predetermined temperature of 200° C. or higher;injecting the target material thus preheated and melted into the metal thin film-covered recessed portion of the metal substrate to be sufficiently filled with the target material;keeping the target material at a second predetermined temperature equal to or less than the first predetermined temperature until contact surfaces between the target material and the metal thin film and between the target material and the metal substrate become sufficiently wet and have no gap so that a thickness of the target material is kept even when the target material is melted while being irradiated with the proton beams. 10. The method for manufacturing a target for a neutron-generating device according to claim 9, the method further comprising an attachment-promoting layer formation step of producing an attachment-promoting layer at a bottom of the recessed portion, the layer causing the target material to better attach to the metal substrate, wherein the attachment-promoting layer formation step is placed after the embossed structure processing step and before the bonding step.