JP6516981B2 - Radiation detector - Google Patents

Description

  The present invention relates to a radiation detector capable of identifying a position at which radiation is detected.

  A radiation detector used in Positron Emission Tomography (PET) includes a scintillator that absorbs radiation to generate scintillation light and a position detection type photodetector that detects the position where scintillation light is generated. ing. The scintillator includes a plurality of physically or optically separated scintillator cells. The scintillator cells are, for example, optically separated from one another by a light scattering layer formed in a lattice. The light scattering layer is formed by laser light irradiation in the scintillator. Moreover, according to the light transmittance of the light scattering layer, segment separation of the scintillator using the gravity center calculation becomes possible. As a technique regarding such a radiation detector, the technique described in patent documents 1-4 is known.

  The radiation detector of Patent Document 1 includes a scintillator in which a plurality of light scattering surfaces are formed, and two light detectors. At least one photodetector detects scintillation light whose light intensity is attenuated by passing through one or more light scattering surfaces. Since the amount of attenuation of the light intensity corresponds to the number of light scattering surfaces that have passed, it is possible to use the light intensity to specify the region where the scintillation light is generated. The three-dimensional radiation position detector of Patent Document 2 includes a scintillator unit having a plurality of scintillator cells and a light receiving element. Only one of the reflective material and the transmissive material is disposed between the scintillator cells. The radiation position detector of Patent Document 3 includes a multilayer scintillator in which a plurality of layers including a plurality of scintillator cells are stacked, and a light receiving element. The radiation position detector has a light reflecting material disposed between scintillator cells as one of means for equalizing the light intensity incident on the light receiving element. The detector component of U.S. Pat. The scintillator is formed with a plurality of voids for defining an optical boundary which controls scintillation light. This void is formed by focusing the laser beam at the focal point set in the scintillator.

International Publication 2012/105292 Patent No. 4338177 Patent No. 4332613 Patent No. 5013864

  By the way, in a radiation detector, position information data including a detection point corresponding to a position where light is generated is obtained by using a signal output from the light detector. In this position information data, detection points corresponding to other scintillator cells adjacent to a certain scintillator cell need to be separated with respect to a detection point corresponding to a certain scintillator cell to such an extent that they can be discriminated by image processing.

  Therefore, an object of the present invention is to provide a radiation detector that can accurately identify a scintillator cell in which scintillation light is generated.

  A radiation detector according to one aspect of the present invention includes: a first scintillator layer including an incident surface intersecting with an incident direction of radiation; and a plurality of scintillator cells arrayed two-dimensionally along the incident surface; A second scintillator layer including a light coupling surface optically coupled to the scintillator layer of the second light source and parallel to the light incident surface, and a plurality of scintillator cells arrayed two-dimensionally along the light coupling surface And a light detection unit having a light reception unit that is parallel to the incident surface and optically coupled to the plurality of scintillator cells of the second scintillator layer. At least one of the first scintillator layer and the second scintillator layer is parallel to the normal direction of the incident surface with a plurality of first light scattering surfaces parallel to the normal direction of the incident surface, and A plurality of light reflecting surfaces intersecting with the first light scattering surface, and a plurality of scintillator cells are partitioned by a plurality of first light scattering surfaces and a plurality of light reflecting surfaces combined with each other in a lattice shape ing.

  In this radiation detector, radiation enters from the incident surface, and the radiation is absorbed in the first scintillator layer or the second scintillator layer to generate scintillation light having a light intensity corresponding to the dose. For example, when scintillation light is generated in the first scintillator layer, the scintillation light diffuses and propagates from the generation position toward the second scintillator layer. The diffused scintillation light is incident on the light receiving unit. Then, using the signal output from the light receiving unit, the position where the scintillation light is generated is calculated. That is, the diffusion range of the scintillation light influences the calculation of the position where the scintillation light is generated. Here, in any one of the first scintillator layer and the second scintillator layer, a light reflecting surface and a first light scattering surface parallel to the normal direction of the incident surface are provided. The first light scattering surface transmits a certain amount of scintillation light. On the other hand, the light reflecting surface reflects the scintillation light almost without transmitting it. Then, the scintillation light diffuses while passing through the light scattering surface in the direction intersecting the first light scattering surface, but hardly diffuses in the direction intersecting the light reflecting surface. Therefore, in this radiation detector, the diffusion range of scintillation light until reaching the light detector can be controlled. As a result, with respect to a detection point corresponding to a certain scintillator cell, another detection point corresponding to another scintillator cell adjacent to the scintillator cell is separated so as to be distinguishable by image processing. It becomes possible to control the diffusion range. Therefore, the scintillator cell in which the scintillation light is generated can be identified with high accuracy.

  In addition, the first scintillator layer has a first light scattering surface and a light reflecting surface, and the scintillator cells of the first scintillator layer have a plurality of first light scatterings combined with each other in a lattice shape. The second scintillator layer has a second light scattering surface formed in a lattice and parallel to the normal direction of the incident surface, which is partitioned by the surface and the plurality of light reflecting surfaces; The scintillator cells of the scintillator layer may be separated by a plurality of second light scattering surfaces combined together in a grid. According to this configuration, in the first scintillator layer, the diffusion range of the scintillation light is limited in the direction intersecting the light reflection surface. On the other hand, in the second scintillator layer, the scintillation light is diffused uniformly in a two-dimensional manner. Thus, when scintillation light is generated in the first scintillator layer, the second scintillator layer functions as a light guide. Accordingly, since the scintillation light can be received by the plurality of light receiving units, the distribution of light intensity can be obtained even if the number of light receiving units is smaller than the number of scintillator cells. Therefore, the scintillator cell in which the scintillation light is generated can be identified.

  The first scintillator layer is formed in a lattice and has a second light scattering surface parallel to the normal direction of the incident surface, and the scintillator cell of the first scintillator layer is formed in a lattice. Separated by a plurality of second light scattering surfaces combined with each other, the second scintillator layer has a first light scattering surface and a light reflecting surface, and the scintillator cells of the second scintillator layer have It may be configured to be partitioned by a plurality of first light scattering surfaces and a plurality of light reflecting surfaces combined in a grid shape. According to this configuration, in the generation of scintillator light in the second scintillator layer, it is possible to control the distance between detection points obtained by the centroid operation. Therefore, the positions of the detection point corresponding to the first scintillator layer and the detection point corresponding to the second scintillator layer can be made different to such an extent that they can be distinguished. Therefore, the scintillator cell in which the scintillation light is generated can be identified with high accuracy.

  The first scintillator layer and the second scintillator layer respectively have a first light scattering surface and a light reflecting surface, and the respective scintillator cells in the first scintillator layer and the second scintillator layer are And a plurality of first light scattering surfaces and a plurality of light reflecting surfaces combined in a grid shape, and the extending direction of the light reflecting surfaces in the first scintillator layer is the light reflecting surface in the second scintillator layer It may intersect with the extension direction of. According to this configuration, in the first scintillator layer, the diffusion range of the scintillation light is limited in the direction intersecting the light reflection surface of the first scintillator layer. Further, also in the second scintillator layer, the diffusion range of scintillation light is limited in the direction intersecting the light reflection surface of the second scintillator layer. Then, since the extending directions of the respective light reflecting surfaces are different between the first scintillator layer and the second scintillator layer, the directions in which the diffusion range is restricted are also the first scintillator layer and the second scintillator layer. It is different. Therefore, since it becomes possible to control the diffusion range in each scintillator layer, it is possible to more accurately identify the scintillator cell in which the scintillation light is generated.

  The scintillator cells in the first scintillator layer are arranged at a predetermined pitch along a first direction orthogonal to the normal direction, and the scintillator cells in the second scintillator layer are predetermined along the first direction. The scintillator cells in the first scintillator layer may be offset from the scintillator cells in the second scintillator layer by a half of the predetermined pitch along the first direction. According to this configuration, in the position information data, the position of the detection point corresponding to the first scintillator layer and the position of the detection point corresponding to the second scintillator layer can be made different from each other. Therefore, it becomes possible to specify with high accuracy whether the scintillation light is generated in the first scintillator layer or the second scintillator layer.

  The scintillator cells in the first scintillator layer are disposed at a predetermined pitch along the second direction crossing the normal direction and the first direction, and the scintillator cells in the second scintillator layer are arranged in the second scintillator layer. The scintillator cells in the first scintillator layer are arranged at a predetermined pitch along the direction, and the scintillator cells in the first scintillator layer are offset from the scintillator cells in the second scintillator layer by half the predetermined pitch along the second direction. May be According to this configuration, in the position information data, the position of the detection point corresponding to the first scintillator layer and the position of the detection point corresponding to the second scintillator layer can be made different from each other. Therefore, it becomes possible to specify with further accuracy whether scintillation light is generated in the first or second scintillator layer.

  According to the radiation detector of the present invention, a scintillator cell in which light is generated can be identified with high accuracy.

It is a perspective view of the radiation detector concerning one form of the present invention. FIG. 2 is a side view of the radiation detector shown in FIG. 1; It is a disassembled perspective view of the 1st scintillator layer shown by FIG. It is a figure which shows typically distribution of the detection point obtained by the radiation detector shown by FIG. It is a perspective view of the radiation detector concerning modification 1. FIG. FIG. 6 is an exploded perspective view of the radiation detector shown in FIG. 5; It is a figure which shows typically distribution of the detection point obtained by the radiation detector shown by FIG. It is a perspective view of the radiation detector concerning modification 2. FIG. It is a figure which shows typically distribution of the detection point obtained by the radiation detector shown by FIG. It is a perspective view of the radiation detector concerning modification 3. FIG. It is a perspective view of the radiation detector concerning a comparative example. It is a figure which shows typically distribution of the detection point obtained by the radiation detector shown by FIG. It is a figure for demonstrating the effect of the radiation detector shown by FIG.

First Embodiment
Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. In the description of the drawings, the same elements will be denoted by the same reference symbols, without redundant description.

  As shown in FIG. 1, the radiation detector 1 detects radiation by detecting light generated by the incidence of radiation such as gamma rays.

  The radiation detector 1 includes a first scintillator layer 2, a second scintillator layer 3, and a light detector (light detection unit) 4. The first scintillator layer 2 and the second scintillator layer 3 absorb radiation to generate light called scintillation light. Scintillation light generated in the first scintillator layer 2 or the second scintillator layer 3 diffuses in a two-dimensional manner while advancing from the generated position toward the light detector 4, and distribution of light intensity in the light detector 4 Is detected as By performing an operation for obtaining the center of gravity of the two-dimensional light intensity distribution, two-dimensional positional information at which scintillation light is generated can be obtained.

  As shown in FIG. 2, the second scintillator layer 3 is optically coupled to the light receiving surface 7 including the plurality of light receiving portions 6 of the light detector 4. The second scintillator layer 3 has a back surface 8 coupled to the light detector 4 and a light coupling surface 9 opposite to the back surface 8. The back surface 11 of the first scintillator layer 2 is optically coupled to the light coupling surface 9. An optical member transparent to scintillation light is filled between the first scintillator layer 2 and the second scintillator layer 3. Similarly, an optical member transparent to scintillation light is also filled between the second scintillator layer 3 and the light detector 4. Such optical members include, for example, silicone oil, air, transparent adhesives for optics, and the like. In the radiation detector 1 having such a configuration, the surface of the first scintillator layer 2 is used as the radiation incident surface 12, and the radiation is incident on the incident surface 12.

As shown in FIG. 1, the first scintillator layer 2 and the second scintillator layer 3 are composed of crystal masses that generate scintillation light upon incidence of radiation. The crystal mass has a substantially rectangular external shape. For example, as an example, in the first scintillator layer 2, one side A1 is 50 mm, the other side A2 is 50 mm, and the height A3 is about 10 mm. The crystal mass forming the first scintillator layer 2 absorbs radiation incident from the incident surface 12 and generates scintillation light having a light intensity corresponding to the dose of the absorbed radiation. The crystal mass is, for example, Bi ₄ Ge ₃ O ₁₂ (BGO), Ce doped Lu ₂ SiO ₅ (LSO), Lu _{2 (1-X)} Y _{2 X} SiO ₅ (LYSO), Gd ₂ SiO ₅ (GSO) , Pr-doped LuAG (Lu ₃ Al ₅ O ₁₂ ), Ce-doped LaBr ₃ (LaBr ₃ ), Ce-doped LaCl ₃ (LaCl ₃ ), Ce-doped Lu _0.7 Y _It is preferably constituted by any crystal such as _0.3 AlO ₃ (LuYAP) or Lutetium Fine Silicate (LFS).

  As shown in FIG. 1, a light scattering surface 13 and a light reflection surface 14 are formed in the first scintillator layer 2. The light scattering surface 13 and the light reflecting surface 14 separate the first scintillator layer 2 into a plurality of optically separated scintillator cells 16. In the second scintillator layer 3, a lattice-shaped light scattering surface 13 is formed. The light scattering surface 13 separates the second scintillator layer 3 into a plurality of optically separated scintillator cells 22. The specific arrangement of the light scattering surface 13 and the light reflecting surface 14 will be described later. The optical separation means that when light is incident on the adjacent scintillator cells 16 and 22, the light is scattered at the light scattering surface 13 and the light whose intensity is weakened is propagated. In the light reflection surface 14, a predetermined proportion of light is reflected, and the remaining light is transmitted.

  The light scattering surface 13 is configured by a modified region (not shown). The modified region is a region where, for example, void-shaped modified spots are formed so as to overlap each other by laser beam irradiation. The plurality of modified spots form an optical scattering surface. The modified spots are formed by focusing laser light inside the crystal mass. That is, the light scattering surface 13 is not obtained by mechanically or chemically treating the surface of the crystal mass forming the scintillator. Since the modified region does not block or absorb the scintillation light, even if the modified region is formed on the entire surface of the light scattering surface 13, part of the scintillation light is adjacent to the scintillator cells 16 and 22. Is transmitted to Further, the light scattering surface 13 has different light transmittance depending on the incident angle of light to the light scattering surface 13. For example, when the incident angle is vertical, the light transmittance is increased. That is, the incident scintillation light is almost transmitted. On the other hand, when the incident angle increases, the light transmittance decreases as compared with the case where the light is perpendicularly incident.

  The light reflecting surface 14 inhibits the diffusion of scintillation light, and the light transmittance is lower than that of the light scattering surface 13. That is, the light reflecting surface 14 inhibits the diffusion of light more than the light scattering surface 13. Therefore, since it is sufficient if the light transmittance is lower than that of the light scattering surface 13, the reflectance of the light reflecting surface 14 may be 100% or 100% or less. As such a light reflection surface 14, any of members such as Teflon tape (Teflon is a registered trademark), barium sulfate, aluminum oxide, titanium oxide, ESR (Enhanced Specular Reflector) film, and polyester film can be used, for example. .

  As shown in FIG. 3, the first scintillator layer 2 having the light scattering surface 13 and the light reflecting surface 14 first forms a light scattering surface 13 by irradiating a plate-like crystal block with laser light. Therefore, in forming the light scattering surface 13, the process of cutting the crystal mass forming the scintillator is not involved. Then, a light reflecting material forming the light reflecting surface 14 is disposed between the scintillators processed by the laser light and optically joined again. The first scintillator layer 2 is obtained by the above steps. In short, the first scintillator layer 2 is formed by the process of irradiating the crystal mass with laser light and the process of bonding the crystal masses together. On the other hand, since the second scintillator layer 3 does not have the light reflecting surface 14, it can be obtained by forming a light scattering surface 13 by irradiating a plate-like crystal block with a laser beam.

  The light detector 4 outputs an electric signal according to the incident position and the light intensity of the light incident on the light receiving surface 7 having the light receiving unit 6. The photodetector 4 is preferably configured by, for example, a semiconductor photodetector such as a position detection type photoelectron multiplier, an avalanche photodiode (APD), or a multi-pixel photo counter (MPPC). Note that MPPC is a photon counting device composed of a plurality of Geiger mode APD pixels. The photodetector 4 has a plurality of light receiving units 6. The number of light receiving units 6 included in the light detector 4 is smaller than the number of scintillator cells 16. Accordingly, the light receiving unit 6 is disposed so as to straddle the plurality of scintillator cells 16 (see FIG. 2).

  Next, the arrangement of the light scattering surface 13 and the light reflecting surface 14 in the first scintillator layer 2 will be described in detail.

  As shown in FIG. 1, the light scattering surface 13 of the first scintillator layer 2 is parallel to the normal direction (direction D1) of the incident surface 12. That is, the light scattering surface 13 intersects, more specifically, is orthogonal to the incident surface 12. That is, in the radiation detector 1, the light receiving surface 7 of the light detector 4 is orthogonal to the light scattering surface 13 of the first scintillator layer 2. Further, in the radiation detector 1, the incident surface 12 of the first scintillator layer 2 is parallel to the light receiving surface 7 of the light detector 4. Therefore, scintillator light does not necessarily pass through the light scattering surface 13 before reaching the light detector 4. The light scattering surface 13 extends from one side surface 17 to the other side surface 18 of the first scintillator layer 2 and extends from the incident surface 12 to the back surface 11. That is, the light scattering surface 13 has the same shape as the pair of side surfaces 19 and 21 orthogonal to the side surfaces 17 and 18. Such light scattering surfaces 13 are formed to be separated from each other along a direction (direction D3) orthogonal to the normal direction (direction D1). This separation distance corresponds to one side A4 of the scintillator cell 16. The first scintillator layer 2 is optically separated along one side A 1 of the first scintillator layer 2 by the light scattering surfaces 13.

  The light reflecting surface 14 is parallel to the normal direction (direction D1) and intersects the light scattering surface 13. Specifically, the light reflecting surface 14 is orthogonal to the incident surface 12 and the light scattering surface 13 respectively. Therefore, the scintillator light does not necessarily pass through the light reflecting surface 14 before reaching the light detector 4. The light reflecting surface 14 extends from the side surface 19 to the side surface 21 of the first scintillator layer 2 and extends from the incident surface 12 to the back surface 11. That is, the light reflecting surface 14 has the same shape as the side surfaces 17 and 18. Such light reflecting surfaces 14 are separated from each other along directions (direction D2) orthogonal to the normal direction (direction D1) and the direction in which the light scattering surfaces 13 are separated from each other (direction D3). This separation distance corresponds to the other side A6 of the scintillator cell 16. The first scintillator layer 2 is optically separated along the other side A2.

  The scintillator cells 16 optically separated by the light scattering surface 13 and the light reflecting surface 14 are arranged in a two-dimensional manner along the incident surface 12. The scintillator cell 16 has a pair of side surfaces intersecting with the incident surface 12 formed by the light scattering surface 13. In the scintillator cell 16, another pair of side surfaces orthogonal to each of the pair of side surfaces is formed by the light reflecting surface 14. That is, the scintillator cell 16 is a region optically separated by the pair of light scattering surfaces 13 and the pair of light reflecting surfaces 14.

  In the first scintillator layer 2 and the second scintillator layer 3, the scintillator cells 16 and the scintillator cells 22 are arranged to be deviated by a predetermined distance along the first direction (direction D2). The scintillator cells 16 in the first scintillator layer 2 are arranged at a predetermined pitch along a first direction (direction D2) orthogonal to the normal direction (direction D1). This pitch corresponds to the length of the other side A6 of the scintillator cell 16. The scintillator cells 22 in the second scintillator layer 3 are arranged at a predetermined pitch along the first direction (direction D2). This pitch corresponds to the length of the other side A6 of the scintillator cell 22. In the present embodiment, the other side A6 of the scintillator cell 16 and the other side A6 of the scintillator cell 22 have the same length. The scintillator cells 16 in the first scintillator layer 2 are offset from the scintillator cells 16 in the second scintillator layer 3 by a half of the predetermined pitch along the first direction (direction D2). . That is, the scintillator cells 16 of the first scintillator layer 2 are coupled so as to straddle the two scintillator cells 22 along the first direction. In other words, the scintillator cells 22 of the second scintillator layer 3 are coupled to straddle the two scintillator cells 16 along the first direction.

  Hereinafter, the operation and effect of the radiation detector 1 will be described in comparison with the operation and effect of the radiation detector according to the comparative example.

As shown in FIG. 11A, the radiation detector 100A according to Comparative Example 1 is different from the radiation detector 1 in that the first scintillator layer 102A does not have the light scattering surface 13. That is, in the radiation detector 100A according to Comparative Example 1, the first scintillator layer 102A is optically separated into a plurality of scintillator cells C1a by the light reflection surface 14. The second scintillator layer 103A is optically separated into a plurality of scintillator cells C2a by the light reflecting surface 14.
Further, as illustrated in FIG. 11B, the radiation detector 100B according to the comparative example 2 is different from the radiation detector 1 in that the first scintillator layer 102B does not have the light reflecting surface 14. That is, in the radiation detector 100B according to the comparative example 2, the first scintillator layer 102B is optically separated by the light scattering surface 13 into a plurality of scintillator cells C1b. The second scintillator layer 103B is optically separated into a plurality of scintillator cells C2b by the light scattering surface 13.

  FIG. 12A is a hypothetical view schematically showing the distribution of detection points obtained by incidence of radiation on the scintillator cells C1a and C2a of the radiation detector 100A. A plurality of white circle detection points P1a correspond to the scintillator cell C1a in which the scintillation light is generated. For example, the detection point T1a corresponds to the scintillator cell 106a. Therefore, when the detection point T1a is included in the position information data obtained using the radiation detector 100A, it indicates that the radiation is absorbed by the scintillator cell 106a and the scintillation light is generated. A plurality of hatched detection points P2a correspond to the scintillator cells C2a in which the scintillation light is generated. For example, the detection point T2a corresponds to the scintillator cell 107a. Therefore, when the detection point T2a is included in the positional information data obtained using the radiation detector 100A, it indicates that the radiation is absorbed by the scintillator cell 107a and the scintillation light is generated.

  FIG. 12 (b) is a schematic diagram showing a distribution of detection points obtained by incidence of radiation on scintillator cells C1b and C2b of the radiation detector 100B. A plurality of white circle detection points P1b correspond to the scintillator cell C1b in which the scintillation light is generated. For example, the detection point T1b corresponds to the scintillator cell 106b. Therefore, when the detection point T1b is included in the positional information data obtained using the radiation detector 100B, it indicates that the radiation is absorbed by the scintillator cell 106b and the scintillation light is generated. A plurality of hatched detection points P2b correspond to the scintillator cells C2b in which the scintillation light is generated. For example, the detection point T2b corresponds to the scintillator cell 107b. Therefore, when the detection point T2b is included in the position information data obtained using the radiation detector 100B, it indicates that the radiation is absorbed by the scintillator cell 107b and the scintillation light is generated.

  Here, when the scintillator cells C1a and C1b are all surrounded by the light reflection surface 14 as shown in FIG. 11A, the distributions of the detection points P1a and the detection points P2a are as shown in FIG. 12A. . The scintillator cells C1a of the first scintillator layer 102A and the scintillator cells C2a of the second scintillator layer 103A are shifted in pitch along the direction D2. Therefore, the detection point P2a corresponding to the second scintillator layer 103A is located between the detection points P1a corresponding to the first scintillator layer 102A. In other words, in the position information data, detection points P1a and detection points P2a are alternately arranged along the direction D2. However, when the scintillator cells C1b and C2b are all surrounded by the light scattering surface 13 as shown in FIG. 11 (b), as shown in FIG. 12 (b), they correspond to the second scintillator layer 103B. The detection point P2b is entirely shrunk than the detection point P2a in FIG. 12A, and the distance between the detection point P1b corresponding to the first scintillator layer 102B is narrower. Therefore, the detection point T1a corresponding to the peripheral portion of the first scintillator layer 102A is not located between the detection points T2a corresponding to the second scintillator layer 103A, but has overlapped.

  The reason is explained. When the scintillator cells are all surrounded by the light scattering surface 13 as shown in FIG. 11B, as shown in FIG. 13A, scintillation light is emitted from the scintillator cells 106d of the first scintillator layer 102B. As a result, the distance S2 from the generation position S1 of the scintillation light to the light detector 4, specifically, the distance S2 along the normal direction (direction D1) of the incident surface 12 is relatively long. Then, the scintillation light L diffuses in a wide range until the scintillation light L reaches the light detector 4.

  If the diffusion range of the scintillation light L is too wide, the intervals between the detection points become narrow, resulting in a pattern that is shrunk to the center. For example, it is assumed that scintillation light is generated in the scintillator cell 106d of the first scintillator layer 102B. Assuming that the scintillation light L is diffused in a two-dimensional manner, this diffused area is not actually detected because the light receiving section 6 is not disposed outside the first scintillator layer 102B. Then, the intensity distribution of the detected light becomes asymmetric (see FIG. 13B). FIG. 13 (b) is a histogram showing the light output detected by each light receiving unit 6. When the center of gravity calculation is performed based on such a histogram distribution, the result of the center of gravity calculation shown in FIG. 13C can be obtained. Referring to FIG. 13 (c), the position of the center of gravity obtained from the histogram in FIG. 13 (b) is a position (bar B2) closer to the center of the first scintillator layer 2 due to the accurate position (bar B1). It has become. Therefore, the point corresponding to the first scintillator layer 102B is expected to be closer to the periphery, to a position closer to the center of the first scintillator layer 102B with respect to the correct position. That is, in spite of the fact that the scintillation light L is generated in the scintillator cell 106d, the position obtained as a result of the gravity center operation may be the scintillator cell 106e. In short, in the radiation detector 100B according to the comparative example 2, it is a problem that the scintillation light L is diffused too much. The reason why the scintillation light L is diffused too much is because the light transmittance of the light scattering surface 13 is high and the distance S2 from the position where the scintillation light L is generated to the light detector 4 is relatively long.

  When scintillation light is generated in the second scintillator layer 103B, the distance between the position where the scintillation light is generated and the light detector 4 is relatively short. For this reason, the diffusion range of the scintillation light is not large as in the case of the scintillation light L generated in the first scintillator layer 102B. For this reason, the pattern of light detection points does not shrink as much as the first scintillator layer 102B.

  Furthermore, in the radiation detector 100B of Comparative Example 2, as shown in FIG. 12B, a detection point T1b corresponding to the first scintillator layer 102B and a detection point T2b corresponding to the second scintillator layer 103B. Are partially overlapping points. Basically, it is desirable that the detection point P1b corresponding to the first scintillator layer 102B and the detection point P2b corresponding to the second scintillator layer 103B be completely separated, but discrimination is possible by image processing Within this range, the overlap between the detection points P1b and P2b is also permitted to some extent. However, for example, when the degree of overlap is large as in the detection points T1b and T2b, it is difficult to determine which of the first scintillator layer 102B or the second scintillator layer 103B corresponds to the detected point. . Therefore, the accuracy of the determination result as to which scintillator cell the first scintillator layer 102B and the second scintillator layer 103B correspond to is reduced.

  In short, in the radiation detector 100B according to Comparative Example 2, the scintillation light generated in one scintillator cell C1b, C2b diffuses in a two-dimensional manner. In the radiation detector 100B according to the comparative example 2 formed by laminating the first scintillator layer 102B and the second scintillator layer 103B, the upper first scintillator layer 102B and the lower second scintillator layer 103B. And the scintillation light diffuses in two dimensions respectively. Therefore, when the scintillation light L is generated in the first scintillator layer 102B, the distance S2 between the generation position S1 of the scintillation light L and the light detector 4 becomes long, so the diffusion range becomes too wide and detection The pattern of the point P1b is shrunk from the second scintillator layer 103B. Then, the separation characteristic of the scintillator cell C1b around the first scintillator layer 102B and the scintillator cell C2b of the second scintillator layer 103B is degraded.

  In the radiation detector 1 according to the present embodiment, radiation is incident from the incident surface 12, and the radiation is absorbed in the first scintillator layer 2 or the second scintillator layer 3, and scintillation light having an intensity according to the dose Occurs. For example, when scintillation light is generated in the first scintillator layer 2, it diffuses and propagates from the generation position of the scintillation light toward the second scintillator layer 3. The diffused scintillation light is incident on the plurality of light receiving units 6. Then, the center of gravity is calculated using the signal output from the light receiving unit 6 on which the scintillation light is incident, and the position where the scintillation light is generated is calculated. Specifically, the scintillator cell 16 in which the scintillation light is generated is specified. That is, the diffusion range of the scintillation light influences the calculation of the position where the scintillation light is generated.

  Here, the first scintillator layer 2 is provided with a light scattering surface 13 and a light reflecting surface 14 parallel to the normal direction (direction D1) of the incident surface 12. The light scattering surface 13 transmits a certain amount of scintillation light, but hardly transmits the light reflecting surface 14 and reflects the scintillation light. Then, the scintillation light is diffused to some extent in the direction D3 intersecting with the light scattering surface 13, but hardly diffused in the direction D2 intersecting with the light reflecting surface 14. That is, in the radiation detector 1, the diffusion direction of the scintillation light is mainly limited to the one-dimensional direction along the direction D <b> 2 parallel to the light reflecting surface 14. Therefore, the radiation detector 1 can control the diffusion range of the scintillation light until reaching the light detector 4.

  FIG. 4A is a view schematically showing the distribution of the detection point P1 and the detection point P3. The detection point P1 is a point corresponding to the first scintillator layer 102B of the radiation detector 100B according to the second comparative example. The detection point P3 is a point corresponding to the first scintillator layer 2 of the radiation detector 1 according to the present embodiment. The broken line L3 indicates that the scintillator cell 16 of the present embodiment is optically separated by the light scattering surface 13. The dashed-two dotted line L4 shows that the scintillator cell 16 of this embodiment is optically separated by the light reflection surface 14.

  According to the first scintillator layer 2 in which the light reflection surface 14 is disposed, the diffusion range of scintillation light in the normal direction (direction D2) of the light reflection surface 14 is in the direction D3 parallel to the light reflection surface 14 It is more limited than the diffusion range of light. When the gravity center calculation is performed based on such a diffusion range of scintillation light, the shift to the center of the first scintillator layer 2 relative to the actual position is suppressed. Therefore, as shown in FIG. 4A, the distance between the detection points P1 expands in the normal direction (direction D2) of the light reflection surface 14 (two-dot chain line L4).

  And if the 1st scintillator layer 2 and the 2nd scintillator layer 3 are combined, distribution of detection point P3, P4 shown by FIG.4 (b) will be obtained. FIG. 4B is a view schematically showing the distribution of the detection point P3 and the detection point P4. The detection point P3 is a point corresponding to the first scintillator layer 2 of the radiation detector 1. The detection point P4 is a point corresponding to the second scintillator layer 3 of the radiation detector 1. The broken line L6 indicates that the scintillator cells 16 of the first scintillator layer 2 are optically separated by the light scattering surface 13. In addition, a two-dot chain line L7 indicates that the scintillator cell 16 of the first scintillator layer 2 is optically separated by the light reflection surface 14. The broken lines L 8 and L 9 indicate that the scintillator cells 22 of the second scintillator layer 3 are optically separated by the light scattering surface 13.

  According to FIG. 4B, the detection point P3 corresponding to the first scintillator layer 2 and the detection point P4 corresponding to the second scintillator layer 3 do not overlap. Therefore, the separation characteristic of the detection points P3 and P4 corresponding to the scintillator cells 16 and 22 is improved, and consequently, the scintillator cells 16 and 22 in which the scintillation light is generated can be identified with high accuracy.

  That is, the radiation detector 1 according to the present embodiment is separated to the extent that discrimination can be made by image processing from the detection point P3 corresponding to the first scintillator layer 2 and the detection point P4 corresponding to the second scintillator layer 3 As described, the diffusion range of scintillation light is controlled. Therefore, it can be accurately specified whether the calculated detection points P3 and P4 are generated in either the first scintillator layer 2 or the second scintillator layer 3.

  In addition, the first scintillator layer 2 disposed in the upper stage has a light scattering surface 13. According to this configuration, the first scintillator layer 2 limits the diffusion range of scintillation light in the direction D2, while the second scintillator layer 3 does not limit the diffusion range of scintillation light in the direction D2. Thereby, when scintillation light is generated in the first scintillator layer 2, the second scintillator layer 3 functions as a light guide. As a result, the scintillation light can be received by the plurality of light receiving units 6. Therefore, it is possible to specify a two-dimensional position with a configuration in which the number of light receiving units 6 is smaller than the number of scintillator cells 16.

  In addition, the scintillator cells 16 in the first scintillator layer 2 are arranged to be offset with respect to the scintillator cells 22 in the second scintillator layer 3. According to this configuration, in the distribution of detection point P3 and detection point P4, the position of detection point P3 corresponding to scintillator cell 16 and the position of detection point P4 corresponding to scintillator cell 22 can be made to differ in advance. . Therefore, it becomes possible to specify with high accuracy whether the scintillation light is generated in either the first scintillator layer 2 or the second scintillator layer 3.

  Moreover, according to the radiation detector 1 according to the present embodiment, the diffusion range of scintillation light along the normal direction (direction D2) of the light reflecting surface 14 is limited. Therefore, the height A3 of the first scintillator layer 2 can also be increased.

  Further, in the radiation detector 1 of the present embodiment, the diffusion range of the scintillation light is based on the light transmittances of the light scattering surface 13 and the light reflecting surface 14. For this reason, it is possible to set the diffusion range of the scintillation light to an arbitrary range by using the light transmittance of the light scattering surface 13 and the light reflecting surface 14 as a parameter. That is, the positions of the detection points P3 and P4 corresponding to the scintillator cells 16 and 22 can be adjusted using the light transmittances of the light scattering surface 13 and the light reflecting surface 14 as parameters.

  As mentioned above, although one form of the present invention was explained, the present invention is not limited to the above-mentioned embodiment, and various modification is possible in the range which does not deviate from the gist of the present invention.

[Modification 1]
For example, as shown in FIG. 5, the radiation detector 1A according to the first modification may include the first scintillator layer 2 and the second scintillator layer 3A. The first scintillator layer 2 has the same configuration as the first scintillator layer 2 of the above embodiment. The second scintillator layer 3A has a light scattering surface 13 and a light reflecting surface 14 in the same manner as the first scintillator layer 2 of the above embodiment. Therefore, in the radiation detector 1A according to the first modification, the first scintillator layer 2 and the second scintillator layer 3A have the same configuration.

  As shown in FIG. 6, the extending direction (direction D3) of the light reflecting surface 14 in the first scintillator layer 2 is the extending direction (direction D2) of the light reflecting surface 14 in the second scintillator layer 3A. Are orthogonal. According to such a configuration, a direction for limiting the diffusion of scintillation light in the first scintillator layer 2 (direction D2), and a direction for limiting the diffusion of scintillation light in the second scintillator layer 3A (direction D3); Are orthogonal. Thereby, the diffusion of the scintillation light can be suitably suppressed, so that the deterioration of the separation characteristics of the scintillator cells 16 and 22 is suppressed. Therefore, also in the radiation detector 1A, the same effect as the radiation detector 1 according to the above embodiment can be obtained.

  FIG. 7 is a view schematically showing the distribution of the detection point P5 and the detection point P6. The detection point P5 is a point corresponding to the first scintillator layer 2 of the radiation detector 1A. The detection point P6 is a point corresponding to the second scintillator layer 3A of the radiation detector 1A. The broken line L11 indicates that the scintillator cell 16 of the first scintillator layer 2 is optically separated by the light scattering surface 13. The two-dot chain line L12 indicates that the scintillator cells 16 of the first scintillator layer 2 are optically separated by the light reflection surface 14. The broken line L13 indicates that the scintillator cell 22 of the second scintillator layer 3A is optically separated by the light scattering surface 13. The alternate long and two short dashes line L14 indicates that the scintillator cells 22 of the second scintillator layer 3A are optically separated by the light reflection surface 14.

  As shown in FIG. 7, in the radiation detector 1A, the distance between the detection points P5 corresponding to the first scintillator layer 2 is expanded in the normal direction (direction D2) of the light reflection surface 14 (two-dot chain line L12). can do. In other words, the distance between the detection points P5 can be expanded in the direction (direction D2) orthogonal to the light reflection surface 14 (two-dot chain line L12). Further, in the radiation detector 1A, the distance between the detection points P6 corresponding to the second scintillator layer 3A can be enlarged in the normal direction (direction D3) of the light reflecting surface 14 (two-dotted dashed line L14). In other words, the distance between the detection points P6 can be expanded in the direction (direction D3) orthogonal to the light reflection surface 14 (two-dot chain line L14). The detection point P5 corresponding to the first scintillator layer 2 does not overlap with the detection point P6 corresponding to the second scintillator layer 3A. Therefore, it is possible to accurately identify the scintillator cells 16 and 22 in which the scintillation light is generated.

[Modification 2]
As shown in FIG. 8, a radiation detector 1B according to the second modification includes a first scintillator layer 2B having a light scattering surface 13, and a second scintillator layer 3B having a light scattering surface 13 and a light reflecting surface 14. And may be provided. That is, in the radiation detector 1B of the second modification, the light reflecting surface 14 is formed only on the second scintillator layer 3B directly coupled to the light detector 4. Also, the first scintillator layer 2B has the same configuration as the second scintillator layer 3 of the above embodiment. Also in the radiation detector 1B having such a configuration, the same effects as those of the radiation detector 1 according to the above embodiment can be obtained.

  FIG. 9A is a view schematically showing the distribution of the detection point P2 and the detection point P8. The detection point P2 is a point corresponding to the second scintillator layer 103B of the radiation detector 100B according to the second comparative example. The detection point P8 is a point corresponding to the second scintillator layer 3B of the radiation detector 1B according to the second modification. The broken line L16 indicates that the scintillator cell 22 of the second scintillator layer 3B is optically separated by the light scattering surface 13. The alternate long and two short dashes line L17 indicates that the scintillator cell 22 of the second scintillator layer 3B is optically separated by the light reflection surface 14. FIG. 9B schematically shows the distribution of the detection point P7 and the detection point P8. The detection point P7 is a point corresponding to the first scintillator layer 2B of the radiation detector 1B. The detection point P8 is a point corresponding to the second scintillator layer 3B of the radiation detector 1B. The broken line L18 indicates that the scintillator cell 16 of the first scintillator layer 2B is optically separated by the light scattering surface 13.

  As shown in FIG. 9A, in the radiation detector 1B, the distance between the detection points P8 corresponding to the second scintillator layer 3B is the normal direction (direction D3) of the light reflection surface 14 (two-dot chain line L17). Can be expanded to In other words, the distance between the detection points P8 can be expanded in the direction (direction D3) orthogonal to the light reflection surface 14 (two-dot chain line L17). Furthermore, as shown in FIG. 9B, the detection point P7 corresponding to the first scintillator layer 2B and the detection point P8 corresponding to the second scintillator layer 3B do not overlap with each other. Therefore, it is possible to accurately identify the scintillator cells 16 and 22 in which the scintillation light is generated.

[Modification 3]
Further, in the above embodiment, the scintillator cells 16 of the first scintillator layer 2 and the second scintillator layer 3 are shifted only in the first direction (direction D2). However, as in the radiation detector 1C shown in FIG. 10, in addition to the first direction (direction D2), it is also deviated in the second direction (direction D3) orthogonal to the first direction (direction D2) It may be arranged in That is, the scintillator cells 16 in the first scintillator layer 2 are arranged at a predetermined pitch along the second direction (direction D3) intersecting the normal direction (direction D1) and the first direction (direction D2). ing. The scintillator cells 16 in the second scintillator layer 3 are arranged at a predetermined pitch along the second direction (direction D3). The scintillator cells 16 in the first scintillator layer 2 have a predetermined pitch in the first direction (direction D2) and the second direction (direction D3) relative to the scintillator cells 16 in the second scintillator layer 3. It is off by one half.

  According to this configuration, it is possible to make the position of the detection point corresponding to the scintillator cell 16 different from the position of the detection point corresponding to the scintillator cell 22 in advance. Ideally, detection points corresponding to the first scintillator layer 2 and detection points corresponding to the second scintillator layer 3 are distributed in a staggered manner. Therefore, according to the radiation detector 1C, it is possible to specify with high accuracy whether the scintillation light is generated in either the first scintillator layer 2 or the second scintillator layer 3.

1, 1A, 1B, 100A, 100B: radiation detector, 2, 2B, 102A, 102B: first scintillator layer, 3, 3A, 3B, 103A, 103B: second scintillator layer, 4: photodetector, 6 light receiving portion 7 light receiving surface 9 light coupling surface 12 incident surface 13 light scattering surface (first light scattering surface, second light scattering surface) 14 light reflecting surface D1 Direction (normal direction of incident surface), 16, 22, C1a, C1b, C2a, C2b ... scintillator cell.

Claims (3)

A first scintillator layer including a plane of incidence that intersects the direction of incidence of radiation, and a plurality of scintillator cells arranged two-dimensionally along the plane of incidence;
A light coupling surface optically coupled to the first scintillator layer and parallel to the light incident surface, and a plurality of scintillator cells arranged two-dimensionally along the light coupling surface; 2 scintillator layers,
A light detection unit having a light receiving unit that is parallel to the incident surface and optically coupled to the plurality of scintillator cells of the second scintillator layer;
Equipped with
At least one of the first scintillator layer and the second scintillator layer has a plurality of first light scattering surfaces parallel to the normal direction of the incident surface, and a normal direction of the incident surface. A plurality of first light scattering surfaces and a plurality of light reflecting surfaces which are parallel and intersect the first light scattering surface, and a plurality of the scintillator cells are combined with each other in a lattice shape; Separated by the light reflecting surface of the
The first scintillator layer has the first light scattering surface and the light reflecting surface,
The scintillator cells of the first scintillator layer are separated by a plurality of the first light scattering surfaces and a plurality of the light reflecting surfaces which are combined with each other in a grid shape,
The second scintillator layer has a second light scattering surface which is formed in a lattice and is parallel to the normal direction of the incident surface,
A radiation detector, wherein the scintillator cells of the second scintillator layer are separated by a plurality of the second light scattering surfaces combined together in a grid. A first scintillator layer including a plane of incidence that intersects the direction of incidence of radiation, and a plurality of scintillator cells arranged two-dimensionally along the plane of incidence;
A light coupling surface optically coupled to the first scintillator layer and parallel to the light incident surface, and a plurality of scintillator cells arranged two-dimensionally along the light coupling surface; 2 scintillator layers,
A light detection unit having a light receiving unit that is parallel to the incident surface and optically coupled to the plurality of scintillator cells of the second scintillator layer;
Equipped with
At least one of the first scintillator layer and the second scintillator layer has a plurality of first light scattering surfaces parallel to the normal direction of the incident surface, and a normal direction of the incident surface. A plurality of first light scattering surfaces and a plurality of light reflecting surfaces which are parallel and intersect the first light scattering surface, and a plurality of the scintillator cells are combined with each other in a lattice shape; Separated by the light reflecting surface of the
The first scintillator layer has a second light scattering surface which is formed in a lattice and is parallel to the normal direction of the incident surface,
The scintillator cells of the first scintillator layer are separated by a plurality of the second light scattering surfaces combined together in a grid-like manner;
The second scintillator layer has the first light scattering surface and the light reflecting surface,
The radiation detector, wherein the scintillator cells of the second scintillator layer are separated by a plurality of the first light scattering surfaces and a plurality of the light reflecting surfaces combined together in a grid. A first scintillator layer including a plane of incidence that intersects the direction of incidence of radiation, and a plurality of scintillator cells arranged two-dimensionally along the plane of incidence;
A light coupling surface optically coupled to the first scintillator layer and parallel to the light incident surface, and a plurality of scintillator cells arranged two-dimensionally along the light coupling surface; 2 scintillator layers,
A light detection unit having a light receiving unit that is parallel to the incident surface and optically coupled to the plurality of scintillator cells of the second scintillator layer;
Equipped with
At least one of the first scintillator layer and the second scintillator layer has a plurality of first light scattering surfaces parallel to the normal direction of the incident surface, and a normal direction of the incident surface. A plurality of first light scattering surfaces and a plurality of light reflecting surfaces which are parallel and intersect the first light scattering surface, and a plurality of the scintillator cells are combined with each other in a lattice shape; Separated by the light reflecting surface of the
The scintillator cells in the first scintillator layer are arranged at a predetermined pitch along a first direction orthogonal to the normal direction,
The scintillator cells in the second scintillator layer are arranged at the predetermined pitch along the first direction,
The scintillator cells in the first scintillator layer are offset from the scintillator cells in the second scintillator layer by a half of the predetermined pitch along the first direction,
The scintillator cells in the first scintillator layer are arranged at the predetermined pitch along a second direction intersecting the normal direction and the first direction.
The scintillator cells in the second scintillator layer are arranged at the predetermined pitch along the second direction,
A radiation detector, wherein the scintillator cells in the first scintillator layer are offset from the scintillator cells in the second scintillator layer by a half of the predetermined pitch along the second direction .