Patent Number: 
Section: claims

1. A method of manufacturing a scintillator panel configured to convert radiation into scintillation light, the method comprising:a first process of forming a plurality of convex sections that protrude in a predetermined direction from a rear surface toward a front surface and concave section defined by the convex sections, on the front surface of the substrate having the front surface and the rear surface;a second process of forming first scintillator units respectively extending from the convex sections of the substrate in the predetermined direction through crystal growth of a columnar crystal of a scintillator material; anda third process of radiating a laser beam to contact portions of the first scintillator units extending from the adjacent convex sections and separating the first scintillator units extending from the adjacent convex sections by scanning the concave section with the laser beam. 2. The method of manufacturing the scintillator panel according to claim 1, further comprising, before the third process, a fourth process of forming second scintillator unit on bottom surfaces of the concave section of the substrate. 3. The method of manufacturing the scintillator panel according to claim 2, wherein,in the first process, the concave section defined in a lattice shape are formed on the front surface of the substrate by forming the convex sections to be arranged on the front surface of the substrate in a two-dimensional array, andin the fourth process, a thickness of the second scintillator unit in a crossing region of the concave section is larger than a thickness of the second scintillator unit at a position other than the crossing region. 4. A scintillator panel configured to convert radiation into scintillation light, the scintillator panel comprising:a substrate having a front surface and rear surface, the substrate is formed with a plurality of convex sections protruding from the front surface in a predetermined direction from the rear surface toward the front surface, and concave section defined by the convex sections; anda plurality of first scintillator units respectively extending from the convex sections in the predetermined direction and separated from each other,wherein the first scintillator units are respectively formed through crystal growth of a plurality of columnar crystals on the convex sections, andat least a part of the columnar crystals constituting the first scintillator unit over bottom surface of the concave section are fused and adhered to each other through radiation of a laser beam. 5. The scintillator panel according to claim 4, further comprising second scintillator unit formed on the bottom surfaces of the concave section of the substrate. 6. The scintillator panel according to claim 5, wherein the convex sections are arranged on the front surface of the substrate in a two-dimensional array,the concave section is defined on the front surface of the substrate by the convex sections in a lattice shape, anda thickness of the second scintillator unit in a crossing region of the concave section is larger than a thickness of the second scintillator unit at a position other than the crossing region. 7. The scintillator panel according to claim 5, wherein at least a part of the second scintillator unit is solidified after being melted by radiation of the laser beam. 8. A radiation detector configured to detect radiation, the radiation detector comprising:a substrate comprising a plurality of photoelectric conversion elements and having a front surface and rear surface, the substrate is formed with a plurality of convex sections protruding from the front surface in a predetermined direction from the rear surface toward the front surface, and concave section defined by the convex sections, the plurality of convex sections being formed so that the plurality of convex sections respectively correspond to the plurality of photoelectric conversion elements; anda plurality of first scintillator units respectively extending from the convex sections in the predetermined direction and separated from each other,wherein the first scintillator units are respectively formed through crystal growth of a plurality of columnar crystals on the convex sections, andat least a part of the columnar crystals constituting the first scintillator unit over bottom surface of the concave section are fused and adhered to each other through radiation of a laser beam. 9. The scintillator panel according to claim 6, wherein at least a part of the second scintillator unit is solidified after being melted by radiation of the laser beam. 10. The radiation detector according to claim 8, further comprising second scintillator unit formed on the bottom surfaces of the concave section of the substrate. 11. The radiation detector according to claim 10, wherein the convex sections are arranged on the front surface of the substrate in a two-dimensional array,the concave section is defined on the front surface of the substrate by the convex sections in a lattice shape, anda thickness of the second scintillator unit in a crossing region of the concave section is larger than a thickness of the second scintillator unit at a position other than the crossing region. 12. The radiation detector according to claim 10, wherein at least a part of the second scintillator unit is solidified after being melted by radiation of the laser beam. 13. The radiation detector according to claim 11, wherein at least a part of the second scintillator unit is solidified after being melted by radiation of the laser beam. 14. A method of manufacturing a radiation detector configured to detect radiation, the method comprising:a first process of forming a plurality of convex sections that protrude in a predetermined direction from a rear surface toward a front surface and concave section defined by the convex sections, on the front surface of the substrate comprising a plurality of photoelectric conversion elements and having the front surface and the rear surface, the plurality of convex sections being formed so that the plurality of convex sections respectively correspond to the plurality of photoelectric conversion elements;a second process of forming first scintillator units respectively extending from the convex sections of the substrate in the predetermined direction through crystal growth of a columnar crystal of a scintillator material; anda third process of radiating a laser beam to contact portions of the first scintillator units extending from the adjacent convex sections and separating the first scintillator units extending from the adjacent convex sections by scanning the concave section with the laser beam. 15. The method of manufacturing the radiation detector according to claim 14, further comprising, before the third process, a fourth process of forming second scintillator unit on bottom surfaces of the concave section of the substrate. 16. The method of manufacturing the radiation detector according to claim 15, wherein,in the first process, the concave section defined in a lattice shape are formed on the front surface of the substrate by forming the convex sections to be arranged on the front surface of the substrate in a two-dimensional array, andin the fourth process, a thickness of the second scintillator unit in a crossing region of the concave section is larger than a thickness of the second scintillator unit at a position other than the crossing region.