JP2007292597A - Radiation detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radiation detector capable of preventing deterioration in accuracy in discriminating two-dimensional positions, even if the fluorescence output characteristics of individual scintillator elements are not uniform. <P>SOLUTION: A radiation detector 1 comprises a plurality of two-dimensionally arranged scintillator elements 2 and a light-receiving element 4, optically coupled to the plurality of scintillator elements 2. Cells 6 are each constituted of at least two adjacent scintillator elements 2 from among the plurality of scintillator elements 2. Adjacent scintillator element 2 constituting the same cells 6 are optically coupled to one another. Adjacent scintillator element 2 constituting different cells 6 are optically shielded from one another. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a radiation detector, and more particularly to a radiation detector that detects a two-dimensional position of radiation incident on a scintillator element using a plurality of scintillator elements.

  A radiation detector is known in which a large number of scintillator elements arranged two-dimensionally and a light receiving element optically coupled to the scintillator elements are combined (see, for example, Patent Documents 1 to 3). Such a radiation detector has a position discriminating function capable of obtaining position information of radiation incident on the radiation detector, and uses a position discriminating function, for example, a positron emission tomographic imaging apparatus which is a medical diagnostic apparatus (Positron emission tomography; hereinafter referred to as “PET”).

  However, when the fluorescence output characteristics of the individual scintillator elements constituting the radiation detector are slightly different, a large number of scintillator elements are two-dimensionally arranged non-uniformly, and the two-dimensional position discrimination accuracy of the radiation detector is reduced. May be reduced.

  Conventionally, a technique used to prevent a decrease in the accuracy of two-dimensional position discrimination is to select scintillator elements having substantially the same fluorescence output characteristics and to arrange them two-dimensionally. Specifically, for each scintillator element, the scintillator element is optically coupled to the light receiving element, the scintillator element is irradiated with radiation, and the fluorescence output of the scintillator element is measured in advance. When all the scintillator elements have been measured, the scintillator elements are arranged in the order according to the magnitude of the fluorescence output. Then, scintillator elements having similar fluorescence outputs are selected and arranged two-dimensionally to constitute a radiation detector. In this way, the deterioration of the two-dimensional position discrimination accuracy of the radiation detector is prevented.

JP 63-047686 A Japanese Patent Laid-Open No. 03-185385 JP-A-61-050087

  The above method is feasible and useful when the number of scintillator elements (crystals) mounted on PET is as small as several hundred. However, measuring the fluorescence output of each scintillator element in current PET, where the number of mounted scintillator elements is as large as about tens of thousands, takes a lot of time and labor, and it is quite difficult to realize. Become.

  Accordingly, there has been a demand for a radiation detector that does not reduce the two-dimensional position discrimination accuracy without performing the measurement operation of the fluorescence output of each scintillator element.

  Accordingly, an object of the present invention is to provide a radiation detector that can prevent a decrease in two-dimensional position discrimination accuracy even if the fluorescence output characteristics of individual scintillator elements are not uniform.

  The inventor of the present invention, when two-dimensionally arranged scintillator elements are optically coupled, the fluorescence generated when one scintillator element absorbs radiation is propagated across adjacent scintillator elements. As a result, the fluorescence output is distributed to adjacent scintillator elements, and even when the fluorescence output characteristics of the individual scintillator elements are different, the amount of fluorescence reaching the light receiving element corresponding to the scintillator element is found to be averaged. . The present invention relates to a radiation detector that effectively utilizes the above characteristics as a result of ingenuity.

  In order to achieve the above object, a radiation detector according to the present invention is a radiation detector having a plurality of scintillator elements arranged two-dimensionally and a light receiving element optically coupled to the plurality of scintillator elements. A cell is configured by at least two adjacent scintillator elements of the plurality of scintillator elements, and adjacent scintillator elements that constitute the same cell are optically coupled to each other to form different cells. The scintillator element and the scintillator element are optically cut off.

  According to the radiation detector configured as described above, the scintillator element and the scintillator element are optically coupled in the same cell, and in a different cell, the space between the scintillator element and the scintillator element is It is optically blocked. Therefore, the fluorescence generated when one scintillator element absorbs radiation is propagated across adjacent scintillator elements in the same cell, and the fluorescence output is distributed to adjacent scintillator elements and propagates to different cells. do not do. As a result, the fluorescence output transmitted from the individual scintillator elements in the same cell to the corresponding light receiving elements is effectively averaged. Therefore, even if the light emission amounts of the individual scintillator elements are different and the fluorescence output characteristics are non-uniform, it is not necessary to perform the work of measuring the fluorescence output of each scintillator element as in the prior art, and two-dimensional position discrimination is performed. A reduction in accuracy can be prevented.

  In the radiation detector of the present invention, preferably, the scintillator element has a coupling bottom surface coupled to the light receiving element and an upper surface on the opposite side, and the upper surface is optically blocked.

  In the radiation detector configured as described above, since the fluorescence output generated in the cell does not leak from the upper surface, averaging of the fluorescence output transmitted to the light receiving element is more effectively performed.

  In the radiation detector of the present invention, preferably, the number of scintillator elements constituting the inside of the cell is four or less.

  In the above radiation detector of the present invention, the scintillator element is preferably a rare earth oxide single crystal.

  In the radiation detector of the present invention, preferably, the light receiving element is a multi-channel type capable of individually detecting fluorescence of a plurality of scintillator elements.

  The radiation detector according to the present invention can prevent a decrease in two-dimensional position discrimination accuracy even if the fluorescence output characteristics of the individual scintillator elements are not uniform.

  Embodiments of a radiation detector according to the present invention will be described below with reference to the drawings. FIG. 1 is a partial perspective view of a radiation detector according to the present invention.

  The radiation detector 1 has a plurality of scintillator elements 2 arranged two-dimensionally, and a light receiving element 4 optically coupled to the plurality of scintillator elements 2.

The scintillator element 2 is preferably made of a solid scintillator having no hygroscopic property, and more preferably made of a rare earth oxide single crystal having a relatively large amount of fluorescence. For example, the scintillator element 2 is preferably made of Ce-added Lu ₂ SiO ₅ (LSO), Ce-added Gd ₂ SiO ₅ (GSO), or Bi ₄ Ge ₃ O ₁₂ (BGO).

  The scintillator element 2 has a quadrangular prism shape, and has an upper surface 2a positioned on the side on which radiation is incident, a coupling bottom surface 2b positioned on the opposite side and coupled to the light receiving element 4, and four side surfaces 2c. ing. These surfaces 2a, 2b and 2c may be processed into mirror surfaces or processed into rough surfaces.

  The scintillator elements 2 are two-dimensionally arranged so that the side surfaces 2c are adjacent to each other. In the present embodiment, the scintillator elements 2 are arranged in a two-dimensional plane, but may be arranged in a two-dimensional shape. FIG. 1 shows 16 scintillator elements 2 arranged in 4 rows × 4 rows.

  Further, one cell 6 is constituted by four scintillator elements 2 of 2 rows × 2 rows among the plurality of scintillator elements. The number of scintillator elements 2 constituting the cell 6 may be at least two, but if it is too large, the effect of averaging the fluorescence output transmitted to the light receiving element is reduced, and therefore it is preferably 4 or less. .

  Adjacent scintillator elements 2 constituting one cell 6 are optically coupled by optical grease 8 via side surface 2c. Instead of using the optical grease 8, an air layer may be arranged. Further, the adjacent scintillator elements 2 constituting the different cells 6 are optically blocked by a multilayer polymerization reflecting material 10 that reflects light. That is, between the cells 6 is optically blocked. Furthermore, it is preferable that the upper surface 2 a of the scintillator element is also optically blocked by the multilayer polymerization reflector 10.

  The light receiving element 4 is preferably of a type that generates one output for one scintillator element. In this case, a plurality of one-channel type light receiving elements may be prepared and used for each scintillator element, or a multi-channel type light receiving element capable of individually detecting the fluorescence of the plurality of scintillator elements is used. May be. FIG. 1 shows a multi-channel type light receiving element. The light receiving element 4 has an upper surface 4a coupled to the coupling bottom surfaces of the plurality of scintillator elements.

  As a modification, the scintillator elements 2 constituting the cell 6 may be arranged as shown in FIGS. 2 to 4 are schematic plan views of modified cells. For example, the scintillator elements 2 may be linearly arranged like a cell 6 ′ shown in FIG. 2, or the scintillator elements 2 may be arranged in an L shape like a cell 6 ″ shown in FIG. However, scintillator elements 2 having different sizes may be combined as in the cell 6 ′ ″ shown in FIG.

  Next, a radiation detector actually manufactured will be described with reference to FIG. FIG. 5 is a plan sectional view showing a part of the radiation detector according to the embodiment of the present invention and a radiation detector of a comparative example.

  As an example of the present invention, a radiation detector 20 shown in FIG. In the radiation detector 20, 144 scintillator elements having an upper surface 2a and a bottom surface 2c of 1.4 mm × 1.4 mm and a height of 4.5 mm were arranged in 12 rows × 12 rows. The pitch of the scintillator elements 2 was 3.25 mm in order to match the light receiving elements 4 described later. Further, the cell 6 is constituted by four scintillator elements 2 of 2 rows × 2 rows. Accordingly, the cell 6 has 6 columns × 6 columns. As the light receiving element 4, an anode output position sensitive photomultiplier tube (H9500 manufactured by Hamamatsu Photonics) was used. This photomultiplier tube has a size of 52 mm × 52 mm and 16 ch × 16 ch = 256 ch, of which 12 ch × 12 ch = 144 ch are aligned with the scintillator element 2 and used.

  The side surfaces of the scintillator element 2 in the cell 6 were optically bonded using optical grease 8 (Shin-Etsu Chemical Co., Ltd. silicon oil KF96H (1 million CS)). In addition, the space between the cells 6 and the upper surface 2a of the scintillator element 2 was covered with a multilayer polymerization reflector 10 (ESR manufactured by Sumitomo 3M).

  Moreover, the radiation detector 22 shown to (b) of FIG. 5 was created as a comparative example. The radiation detector 22 of the comparative example is one in which the multilayer polymerization reflector 10 is arranged instead of optically coupling the scintillator element 2 in the cell 6 of the radiation detector 20 of the embodiment with the optical grease 8. The non-uniformity of the scintillator element of the comparative example was almost the same as the non-uniformity of the scintillator element of the example.

  The γ-rays obtained from the 137 Cs radiation source are respectively incident on the individual scintillator elements and excited by exciting the scintillator elements to the radiation detector 20 of the example and the radiation detector 22 of the comparative example. The fluorescence output was detected by a light receiving element. Thereby, an energy spectrum was obtained when γ rays were incident on each scintillator. The standard deviation of the photoelectric peak value of the energy spectrum for 144 scintillator elements was 4.00% in the radiation detector 20 of the example, whereas it was 7.96% in the radiation detector 22 of the comparative example. Met. Thereby, it turned out that the two-dimensional position discrimination precision of the radiation detector 20 of the Example of this invention is superior to the radiation detector 22 of a comparative example.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications are possible within the scope of the invention described in the claims. Needless to say, these are also included within the scope of the present invention.

1 is a partial perspective view of a radiation detector according to the present invention. FIG. It is a schematic plan view of the cell of a modification. It is a schematic plan view of the cell of a modification. It is a schematic plan view of the cell of a modification. It is a plane sectional view of a radiation detector of an example and a comparative example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Radiation detector 2 Scintillator element 4 Light receiving element 5 Coupling surface 6 Cell 8 Optical grease 10 Multilayer reflective material 20 Radiation detector 22 of Example 22 Radiation detector of Comparative Example

Claims (5)

A radiation detector having a plurality of scintillator elements arranged two-dimensionally and a light receiving element optically coupled to the plurality of scintillator elements,
A cell is constituted by at least two adjacent scintillator elements of the plurality of scintillator elements,
Between adjacent scintillator elements that make up the same cell are optically coupled,
The radiation detector characterized by optically interrupting | blocking between the adjacent scintillator elements which comprise a different cell. The scintillator element has a coupling bottom surface coupled to the light receiving element and an upper surface on the opposite side.
The radiation detector according to claim 1, wherein the upper surface is optically blocked.   The radiation detector according to claim 1 or 2, wherein the number of scintillator elements constituting the cell is 4 or less.   The radiation detector according to claim 1, wherein the scintillator element is a rare earth oxide single crystal.   The radiation detector according to any one of claims 1 to 4, wherein the light receiving element is a multi-channel type capable of individually detecting fluorescence of a plurality of scintillator elements.

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