JPWO2019017233A1 - Neutron optical element and neutron source - Google Patents

Abstract

A neutron optical element that collects neutron beams with high efficiency, and a high-intensity neutron source using the same are obtained. A straight line (broken line in the figure corresponding to the neutron beam) passing between each of the upstream openings (21A) (upstream openings) and each of the corresponding downstream openings (22A) (downstream openings) N1 to N5) are configured to pass through a condensing point F set behind the neutron optical element 20. Of the thermal neutrons diffused and radiated backward from the entire surface of the neutron moderator (12), only those that are directed to the focusing point (F) are extracted, so the neutral line intensity at the focusing point (F) is Can be increased locally.

Description

  The present invention relates to a neutron optical element used for selecting and adjusting a traveling direction of a neutron beam, and a neutron source using the neutron optical element.

  The neutron beam is used for investigating the structure of the substance by irradiating the substance with a neutron beam such as neutron diffraction and examining its scattering and diffraction. Unlike electrons, neutrons have no electric charge, have high permeability to substances, and are scattered by atomic nuclei. Therefore, when neutron rays are used, information different from that obtained by using electron beams or X-rays, which are also used for investigating various structural characteristics of substances by scattering/diffraction, can be obtained. In particular, small-angle neutron scattering, which obtains various information by scattering thermal neutrons with low energy, is extremely effective in the analysis of light elements.

  On the other hand, the configuration and characteristics of the neutron source that emits neutron rays are greatly different from those of electron beam sources, X-ray sources, and the like. As an electron beam source or an X-ray source, an energy-controlled (quasi) monochromatic, high-intensity electron beam or an X-ray emitting source can be used, whereas a neutron source having such a property can be used. It is difficult to obtain, and the main neutron sources actually used are, for example, radioactive isotopes and large facilities (reactors and large accelerators). In the former case, only very low intensity neutron beam can be obtained, and in the latter case, high intensity neutron beam can be obtained, but large-scale equipment for performing fission and fragmentation reaction is required. Maintenance of such a nuclear reactor is not easy, so it is not suitable as a neutron source used for the above analysis.

As a neutron source that is smaller in scale than a nuclear reactor or the like and can obtain a high-intensity neutron beam, there is, for example, RANS (Ricken Accelerator-driving compact Neutron Source) described in Non-Patent Document 1. In RANS, a proton beam of about 7 MeV is generated by an accelerator and irradiated on a ⁹ Be thin film. As a result, ⁹ B and neutrons (fast neutrons) are generated, but the energy of this neutron is as high as MeV, so that it is not suitable, for example, for the above-mentioned small-angle neutron scattering experiment. Therefore, in RANS, a block made of polyethylene that serves as a moderator for fast neutrons is fixed rearward of the ⁹ Be thin film as viewed from the proton beam side. Thereby, fast neutrons are decelerated and scattered, and thermal neutrons with energy of about 50 meV are emitted backward with high intensity. Further, since the on/off of the emitted neutron beam is controlled by the on/off of the proton beam generated by the accelerator, a controlled pulsed neutron beam can be obtained.

  On the other hand, in this configuration, the proton beam emitted from the accelerator is thin enough to be regarded as a point source and has high directivity, but the fast neutrons generated thereafter spread when they are decelerated and scattered by the polyethylene block. The generated thermal neutrons are emitted in various directions from a wide area of the polyethylene block. That is, this neutron source becomes a surface light source that emits neutrons from a wide area of the polyethylene block.

"Neutron Utilization by Proton Beam Accelerator Driven RIKEN Small Neutron Source RANS", Yoshie Otake, Tomohiro Kobayashi, Hideo Ota, Masako Yamada, Takao Hashiguchi, ▲Shinjuku ▼Shinzo, Takeya Atsushi, ▲High ▼Murahito 關 Yoshichika, Ikeda Yoshimasa, Hideyuki Sunaga, Omori, Yutaka Yamagata, Junichi Kato, Proceedings of the 12th Annual Meeting of the Accelerator Society of Japan, p. 1358, August 6, 2015.

  Although the total integrated intensity of neutron rays emitted from such a neutron source serving as a surface light source is high, in order to use the neutron ray for various scattering experiments and the like, one point in space (for example, on the sample to be analyzed or It is particularly preferable to concentrate the neutron beam at one point on the detector) and locally increase (focus) the intensity of the neutron beam at this one point. While it is possible to obtain an optical element that collects these with high efficiency by using a static magnetic field or electrostatic field for electron beams and a reflecting mirror for X-rays. For neutron rays, it was difficult to collect them with high efficiency as well.

  Therefore, a neutron optical element that collects neutron beams with high efficiency and a high-intensity neutron source using the neutron optical element have been demanded.

  The present invention has been made in view of the above problems, and an object thereof is to provide an invention that solves the above problems.

The present invention has the following configurations in order to solve the above problems.
The neutron optical element of the present invention is a neutron optical element that collects neutron rays emitted so as to diverge from the surface on one side of the surface having a normal line in one direction, and the neutron optical element is composed of a neutron absorber. A plurality of collimators formed by arranging a plurality of openings penetrating along one direction and penetrating along the one direction, in the collimator provided on the other side opposite to the one side. The upstream side opening which is the opening and the downstream side opening which is the opening in the collimator provided on the one side are respectively provided in plural in the arrangement of the same configuration, and the collimator provided on the other side is provided. A straight line connecting each of the upstream openings and each of the downstream openings in the array corresponding to each of the upstream openings is set on the one side of the collimator provided on the one side. It is characterized in that it is configured so as to pass through the condensing point.
In the neutron optical element of the present invention, in the collimator, the plurality of openings are provided in parallel with a plurality of first beam portions provided in parallel and a second beam portion provided in parallel so as to intersect with the first beam portions. It is characterized in that it is formed by a combination with the beam part of.
In the neutron optical element of the present invention, the collimator is provided at a distance of three or more along the one direction, and for a plurality of combinations of two adjacent collimators in the three or more collimators, , The common condensing point is set.
Neutron optical element of the present invention, the opening width of the downstream side opening, the distance between the adjacent downstream side openings in the array, respectively, the opening width of the upstream side opening, the interval between the upstream side openings adjacent in the array Is also small.
In the neutron optical element of the present invention, the collimator is made of a B ₄ C sintered body.
In the neutron optical element of the present invention, the collimator is made of B ₄ C, Gd, or Cd.
The neutron optical element of the present invention, a plurality of the collimator, at a location spaced apart along the one direction, comprises a support portion that fixes and supports the spacing along the one direction, the support portion is a plurality of types. The distance between the collimators adjacent to each other in the one direction can be adjusted by selecting the supporting portion prepared or by adjusting the fixing position of the collimator with respect to the supporting portion. ..
The neutron optical element of the present invention is characterized in that the collimator is selected and used among a plurality of the collimators having the same shape including the opening and made of different materials.
The neutron source of the present invention is characterized in that a neutron surface light source having a plate-like thermal neutron generating section that emits a thermal neutron beam from a surface is combined with the neutron optical element.
The neutron source of the present invention is characterized in that the collimator provided closest to the other side and the thermal neutron generator are in contact with each other.
The neutron source of the present invention is characterized in that the neutron optical element is arranged in a vacuum atmosphere.
The neutron source of the present invention is, in the neutron surface light source, the thermal neutron generator is composed of a neutron moderator, and a fast neutron generator composed of ⁹ Be is provided on the other side with respect to the thermal neutron generator. The fast neutron generator is configured to be irradiated with a proton beam emitted toward the one side.

  Since the present invention is configured as described above, it is possible to obtain a neutron optical element that collects neutron rays with high efficiency and a high-intensity neutron source using the neutron optical element.

It is a figure which shows the structure of the neutron source in which the neutron optical element which concerns on embodiment of this invention was used. It is a perspective view (the 1) showing composition of a collimator used in a neutron optical element concerning an embodiment of the invention. It is a perspective view (the 2) showing composition of a collimator used in a neutron optical element concerning an embodiment of the invention. It is a figure which shows the structure of the neutron source in which the modification of the neutron optical element which concerns on embodiment of this invention was used. FIG. 4 is a diagram showing a passing state of a neutron source when the collimator is thin in the neutron optical element according to the embodiment of the present invention. FIG. 6 is a diagram showing a passing state of a neutron source when the collimator is thick in the neutron optical element according to the embodiment of the present invention. It is a 1st example which shows the form at the time of using the neutron optical element which concerns on embodiment of this invention for analysis of a sample. It is a 2nd example which shows the form at the time of using the neutron optical element which concerns on embodiment of this invention for analysis of a sample. In the Example of this invention, it is the result of having measured the beam shape (neutron beam intensity distribution) by changing the aperture area of a collimator. In the Example of this invention, it is the result of having measured the flight time of a neutron by changing the opening area of a collimator. It is a perspective view which shows the structure of the 1st modification of the collimator used in the neutron optical element which concerns on embodiment of this invention. It is a perspective view which shows the structure of the 2nd modification of the collimator used in the neutron optical element which concerns on embodiment of this invention.

  A neutron source using the neutron optical element according to the embodiment of the present invention will be described. FIG. 1 is a sectional view showing the structure of the neutron source 1. The neutron source 1 is configured by combining a neutron surface light source 10 and a neutron optical element 20. The neutron surface light source 10 is the RANS described in Non-Patent Document 1, and here a cross section along the traveling direction of a proton beam used in the RANS is shown.

In this neutron surface light source 10, a planar Be foil 11 which is made of ⁹ Be (beryllium) and spreads in the vertical direction and the direction perpendicular to the paper surface in FIG. 1 is used. A proton beam (proton beam) P having an energy of 7 MeV generated by the accelerator is incident on the Be foil 11 toward the rear (right side in the figure: one side) in a direction perpendicular to the Be foil 11. The proton beam P is generated by the accelerator so as to be radiated along the central axis X that is the front-rear direction (the left-right direction in the figure: one direction) and is irradiated from the front, and is spatially around the central axis X of the proton beam P. The spread is sufficiently small, for example, 10 mm or less. As a result, fast neutrons having an energy of about MeV are emitted from the Be foil 11 by the nuclear reaction of ⁹ Be.

  Behind the Be foil 11, a neutron moderator (thermal neutron generator) 12 in the form of a plate thicker than the Be foil 11 is joined via a joining material 13. The size (vertical length in FIG. 1) of the neutron moderator 12 is, for example, about 150 mm, and the thickness (horizontal direction thickness in the figure) is about 40 mm. Both the Be foil 11 and the neutron moderator 12 are centered. It shall be installed perpendicular to the axis X. The neutron moderator 12 is made of polyethylene, for example, as a material that decelerates and scatters fast neutrons. On the contrary, the bonding material 13 is composed of V (vanadium) or the like, which has a low fast neutron scattering ability and a low absorptivity and easily transmits fast neutrons. The fast neutrons are decelerated and scattered in the neutron moderator 12 to become thermal neutrons having an energy of about 50 meV, which are emitted from the rear surface of the neutron moderator 12. Although the spread around the central axis X of the proton beam P is sufficiently smaller than that of the neutron moderator 12, this configuration causes thermal neutrons to be scattered from a wide range within the plane of the neutron moderator 12 (vertical direction in FIG. 1). It is emitted backwards. The above points are the same as those described in Non-Patent Document 1.

  This neutron optical element 20 is used by being mounted on the right side (downstream side) of the neutron surface light source 10 in the figure, and a first collimator (collimator) 21 on the upstream side and a second collimator (collimator) 22 on the downstream side, It is configured to be fixed in a housing (support portion) 25. Since all the parts shown in FIG. 1 are installed in an atmosphere that is evacuated, the scattering of neutrons in the neutron optical element 20 by air can be ignored. Further, in order to suppress the leakage of neutrons and increase the intensity of the obtained neutron beam, it is preferable that the first collimator 21 on the upstream side and the neutron moderator (thermal neutron generating part) 12 are brought into close contact with each other.

  Both the first collimator 21 and the second collimator 22 are composed of neutron absorbers having a high absorption capacity for thermal neutrons. The first collimator 21 and the second collimator 22 are provided with openings 21</b>A and 22</b>A that are arranged so as to pass through them in the front-rear direction (thickness direction), respectively. The first collimator 21 and the second collimator 22 have the same basic configuration, and the sizes and intervals of the openings are different. FIG. 2A is a perspective view showing the configuration of the first collimator 21, and FIG. 2B is a perspective view showing the configuration of the second collimator 22. Both the first collimator 21 and the second collimator 22 have a rectangular plate shape. Further, the rectangular openings 21A and 22A are provided in the same array configuration (a two-dimensional array of vertical and horizontal odd numbers, respectively). In FIG. 1, this number is 5, and this number is generally odd.

  As shown in FIGS. 2A and 2B, the structure in which the openings 22A in the second collimator 22 are arranged is a reduced form of the structure in which the openings 21A in the first collimator 21 are arranged. Therefore, assuming that the length of one side of the opening 21A in FIG. 2A is D1 and the length of one side of the opening 22A in FIG. 2B is D2, D1>D2. Further, the thickness of the first collimator 21 and the thickness of the second collimator 22 are equal, and both are T. In FIG. 1, openings 21A arranged vertically in the center of the first collimator 21 in the left-right direction, an opening 21A at the center of the array in the first collimator 21, and an opening at the center of the array in the second collimator 22. 22A is on the central axis X. Therefore, one opening 21A in the first collimator 21 can be associated with the opening 22A in the second collimator 22 at the same position in the array as this one opening 21A. FIG. 1 shows a cross section of a portion having five openings 21A and five openings 22A arranged at the center in the left-right direction. As described above, this cross section is along the proton beam P and the central axis X.

  In FIG. 1, a straight line (broken line in the figure corresponding to the neutron beam) passing between each of the upstream openings 21A (upstream openings) and each of the corresponding downstream openings 22A (downstream openings). N1 to N5) are configured to pass through a condensing point F set behind the neutron optical element 20. Here, it is assumed that the focal point F is provided on the detector 50 capable of detecting the two-dimensional distribution of the neutron beam intensity. Of the thermal neutrons diffused and radiated backward from the entire surface of the neutron moderator 12, only the thermal neutrons directed to the focal point F are extracted, so that the neutral line intensity at the focal point F can be locally increased. it can. On the right side of FIG. 1, such a neutron intensity distribution detected by the detector 50 is schematically shown.

  In the neutron optical element 20 of FIG. 1, two collimators (the first collimator 21 and the second collimator 22) were used, but more collimators are used to inhibit the neutron beam crossing and further increase the intensity distribution. Can be steep. FIG. 3 shows the structure of a neutron source 2 using a neutron optical element 30 having such a configuration and being a modified example of the neutron optical element 20. Here, a third collimator (collimator) 23 having a similar structure is provided between the first collimator 21 and the second collimator 22. Also in the third collimator 23, the openings 23A are formed in the same array as the openings 21A in the first collimator 21 and the openings 22A in the second collimator 22 (two-dimensional array of five rows and five columns).

  As described above, the positional relationship between the openings 21A (upstream side openings) of the first collimator 21 and the openings 22A (downstream side openings) of the second collimator 22 is such that a straight line passing between them passes through the condensing point F. Is configured. In the structure of FIG. 3, the positional relationship between the openings 21A in the first collimator 21 and the openings 23A in the third collimator 23, and the positional relationship between the openings 23A in the third collimator 23 and the openings 22A in the second collimator 22, The same applies to both, and a straight line passing between corresponding openings is set so as to pass through the focal point F.

  Therefore, similarly to the configuration of FIG. 1, the neutron beams N1 to N5 sequentially pass through the corresponding openings 21A, 23A, 22A and reach the focal point F. On the other hand, in FIG. 1, for example, the neutron beam M1 that passes through the opening 21A at the top and then the second opening 22A from the top and the opening 22A at the top of the neutron beam M1 that passes through the opening 21A at the top The passing neutron beam M2 also reaches the detector 50. Therefore, in the configuration of FIG. 1, the neutron beam reaches the part of the detector 50 away from the converging point F, and thus the neutron beam intensity at the part away from the converging point F cannot be sufficiently reduced. There are cases.

  On the other hand, in the configuration of FIG. 3, the neutron beams M1 and M2 are set to pass through a portion other than the opening 23A in the third collimator 23, and the neutron beams M1 and M2 are located behind the third collimator 23. Passage can be suppressed. Strictly speaking, the neutron beam passing through each opening 21A has a spread and the neutron beams N1 to N5, M1 and M2 also have a spread, so that the actual situation is more complicated, but the third collimator 23 is By using it, the intensity of the neutron beam corresponding to the neutron beams M1 and M2 can be reduced.

  In the configuration of FIG. 3, three collimators (first collimator 21, second collimator 22, third collimator 23) are used, but similarly, by using four or more collimators, the sample S is collected. The neutron beam intensity at points other than the light spot F can be reduced. That is, the neutron beam intensity at the focal point F can be made relatively higher than the surroundings, and the neutron beam intensity contrast can be enhanced.

  For example, when irradiating a sample with such a neutron beam for analysis, the position resolution is determined by the spread of the neutron beam intensity distribution (W in FIG. 1) in the vicinity of the focal point F in the configuration of FIG. Therefore, it is preferable to reduce W in order to improve the position resolution. W depends on the opening widths D1 and D2 of the openings 21A and 22A in FIGS. 2A and 2B, and W can be reduced by narrowing the opening widths. On the other hand, when the opening width is narrowed, the integrated intensity of the neutron beam passing through the aperture is reduced, so that the neutron beam intensity at the focal point F is reduced. Therefore, in the above configuration, the aperture width in each collimator is set in consideration of the neutron beam intensity required on the sample S, the position resolution in the experiment, and the like.

  Further, FIG. 4 is a diagram showing a situation of neutron rays passing through the uppermost opening 21A (upstream side opening) and the opening 22A (downstream side opening) in the configuration of FIG. Here, it is assumed that the reflection and diffraction of neutron rays on the inner surfaces of the first collimator 21 and the second collimator 22 forming the openings 21A and 22A can be ignored. In this case, the neutron beam passing through the uppermost opening 21A and the uppermost opening 22A is in the range between the broken lines N11 and N12.

  On the other hand, FIG. 5 shows a situation similar to that of FIG. 4 except that the thickness T of the first collimator 21 and the second collimator 22 is made larger than that of FIG. In this case, the neutron beam passing through the uppermost opening 21A and the uppermost opening 22A is in the range between the broken lines N21 and N22. In this case, since the components of the neutron beam blocked by the thick first collimator 21 and the second collimator 22 increase, this range is significantly narrowed compared with the case of FIG. Therefore, the thickness T of the first collimator 31 and the second collimator 32 in FIGS. 2A and 2B is preferably thin, and the same applies to the collimators inserted between them. On the other hand, when these are thin, a neutron beam component that transmits them at a place other than the opening is generated. For this reason, it is preferable that each collimator be thinly made of a material having a high neutron absorption capacity and a high mechanical strength.

Specifically, B ₄ C containing boron (B), which has a high neutron absorption ability, can be preferably used as a material forming each collimator. In this case, each collimator can be manufactured as a sintered body obtained by molding and sintering B ₄ C powder. Further, similarly, Cd (cadmium), Gd (gadolinium) or the like, which is a metal having a high neutron absorption ability, can be used. When such a metal material is used, each collimator can be formed thin to increase the transmittance.

  Further, when the number of collimators is increased as shown in FIG. 3 (when another collimator is inserted between the first collimator 21 and the second collimator 22), as described above, except for the condensing point F. W can be reduced by reducing the neutron beam intensity of the neutron beam, but as shown in FIGS. 4 and 5, the component of the neutron beam shielded by the inserted collimator becomes large, so that it is inserted. As the number of collimators increases, the spread of the neutron beam at the focal point F also decreases. Therefore, the number of collimators to be used (the number of layers) is also set in consideration of the required neutron beam intensity, the position resolution in the experiment, and the like, like the above-mentioned opening width.

  Next, a mode for carrying out a small-angle neutron scattering experiment using the above neutron optical element or neutron source will be described. In this case, the sample is placed between the neutron optical element and the detector 50. 1, 3 and the like, the focus point F is set on the detector 50, but the position of the focus point F can be set appropriately.

  In the configuration of FIG. 1, it is preferable that the upstream first collimator 21 and the neutron moderator 12 are in close contact with each other, as described above. Similarly, it is preferable that the sample S is also close to the downstream collimator. FIGS. 6 and 7 are diagrams showing the configuration when the sample S and the detector 50 are arranged in this way. Here, it is assumed that a neutron optical element in which the collimator similar to that in FIG. 3 has a three-layer structure is used.

  In the configuration of FIG. 6, the neutron optical element 31 in which the sample S is installed immediately after the second collimator 22 so as to be in contact with the second collimator 22 and the focal point F is set on the detector 50 is used. Therefore, the detector 50 can detect the neutron beam when there is no scattering by the sample S (when the sample S is not installed) and the neutron beam after scattering by the sample S with high intensity. Here, when the sample S does not exist, as described above, the neutron beams N1 to N5 in the drawing are focused on the focusing point F on the detector 50. On the other hand, the direction of the neutron beam scattered by the sample S changes like scattered neutron beams S1 and S2 in the figure, so that the neutron beam is detected at a position deviating from the focal point F, so that the sample S exists after all. In this case, the intensity distribution detected by the detector 50 is wider than in the case where the sample S is not present. Information on the sample S can be obtained by analyzing the difference in the intensity distribution.

  In this case, by reducing W in the intensity distribution (solid line) in FIG. 1, the position resolution in this analysis is further enhanced. At this time, by setting the condensing point F on the detector 50, the intensity of the signal detected by the detector 50 is increased, so that the S/N ratio can be increased and the measurement can be performed with high accuracy.

  In the configuration of FIG. 7, the sample S is installed immediately after the second collimator 22 in the same manner as above, but the condensing point F is set on the sample S (immediately after the second collimator 22). The optical element 32 is used. Therefore, the neutron beam transmitted through the sample S or diffracted by the sample S is again detected on the detector 50 by being separated into five corresponding to the neutron beams N1 to N5. On the other hand, the neutron beam intensity and its contrast on the sample S, and the positional resolution of the portion of the sample S irradiated with the neutron beam can be improved.

  That is, whether the neutron beam intensity and its resolution in the detector 50 should be increased or the neutron beam intensity and its resolution in the sample S should be increased by changing the mutual distance of the collimators in the neutron optical element, and focusing with the same element. The points can be made variable. In this case, a common one can be used as the most upstream collimator, and this setting can be performed by providing a moving mechanism that changes the mutual position of the downstream collimators. Further, the condensing point F can be set at a place other than the sample S and the detector 50.

The result detected by the detector 50 in the configuration of FIG. 6 using three types of collimators made of B ₄ C sintered body will be described. FIG. 8 shows a common condensing point F (from the thermal neutron generator 12 to the condensing point F) with the three collimator openings in FIG. Is a result of measuring the distance dependence of the neutron beam intensity (count number) from the optical axis center (focus point F) in the case where a distance of up to 1500 mm) is obtained. This shape reflects the beam shape of the neutron beam obtained by the neutron optical element. It can be confirmed that a beam shape with enhanced directivity can be obtained regardless of the opening area, and high neutron beam intensity can be obtained by increasing the opening area. FIG. 9 shows the result of measuring the flight time of neutrons (corresponding to the wavelength of neutrons) corresponding to FIG. 8, and the common peak (the most frequent flight time) was obtained regardless of the aperture area. There is. Therefore, a neutron beam with high directivity can be obtained using the neutron optical element described above, and various measurements such as small-angle neutron scattering can be performed using this.

  In the configurations shown in FIGS. 1 and 3, the distance between adjacent collimators is determined by the housing (support portion) 25 that mechanically supports and fixes the collimator. Therefore, even if the respective collimators used are the same, it is possible to adjust the position (focal length) of the condensing point F by providing a plurality of types of housings 25 and selecting them. Further, it is possible to set a plurality of mounting positions of each collimator with respect to the single housing 25, and thereby it is possible to adjust the position of the focal point F.

  Such a configuration can be easily realized by manufacturing each collimator and the housing 25 as separate bodies. Further, the material having high neutron absorption ability and suitable for the collimator as described above is not always preferable as the material forming the casing 25 that secures the mechanical strength and the like of the entire apparatus. Further, if the collimator has a simple structure in which an opening is formed on a flat plate as described above, the collimator can be easily manufactured at low cost, while the casing 25 is made of such a material. It may not be easy to manufacture. For this reason, it is particularly preferable to manufacture the collimators and the housing 25 separately from each other, which facilitates the adjustment of the focal length as described above.

  On the other hand, the neutron beam intensity or intensity distribution (beam shape) obtained in the vicinity of the focal point F is also affected by the neutron transmittance of the portion other than the opening in the collimator. Therefore, the neutron beam intensity and the beam shape can be adjusted not only by the position (interval) setting of the collimator as described above but also by the setting and thickness of the material forming the collimator. Therefore, as described above, when manufacturing the collimators and the housing 25 separately with different materials, a plurality of collimators having the same shape including the arrangement and size of the openings and different materials are manufactured. The collimator may be selectable from these. At this time, collimators having different thicknesses may be provided.

  As described above, it is easy to change the specifications of the neutron optical element (setting the position of the focusing point F), and the basic structure of the neutron optical element has the shape shown in FIGS. 2A and 2B. It is very simple because it can be obtained by combining the collimators. Therefore, this neutron optical element can be inexpensive.

  In the above example, the collimator was two-dimensionally arranged with five openings in each length and width. However, the configuration and the number can be set appropriately. As described above, it is preferable to make the openings small in order to improve the positional resolution of the analysis.In this case, in order to increase the neutron beam intensity, the number of openings is set to be larger, and neutron beams from a wide range are collected. It is preferable to make it light. In addition, in the above example, as shown in FIGS. 2A and 2B, the rectangular openings are arranged and set in each collimator. In this case, the openings can be efficiently arranged without providing a useless area in the collimator, and the collimator is easy to manufacture. However, the shape of the opening is arbitrary, and for example, a honeycomb shape or the like can be used. Further, although the openings are arranged two-dimensionally in the above example, the openings may be arranged one-dimensionally to collect light only in the arrangement direction.

  Further, the lattice-shaped collimator as shown in FIGS. 2A and 2B can manufacture the sintered body in such a shape. On the other hand, such a shape can be easily manufactured by another manufacturing method. 10A and 10B are views showing the structures of such collimators 120 and 130 in correspondence with FIGS. 2A and 2B.

  In FIG. 10A, the collimator 120 is provided with a plurality of columnar first beam portions 120A that extend in the vertical direction and are provided in parallel in the horizontal direction in the figure, and a plurality of collimators 120 that extend in the horizontal direction and are provided in parallel in the vertical direction. A plurality of 2nd beam parts 120B are combined and constituted. In this case, a plurality of columnar first beam portions 120A and a plurality of second beam portions 120B are manufactured, and a plurality of collimators having openings having different sizes are simply formed by changing the combination type. Can be easily manufactured. Although illustrated in a simplified manner in FIG. 10, the structure of the portion where the first beam portion 120A and the second beam portion 120B intersect can be set as appropriate.

  FIG. 2A. Even when a material for which it is difficult to inexpensively manufacture a collimator having a shape such as 2B is used, the first beam portion 120A and the second beam portion 120B having the above-described simple shapes can be easily manufactured. Therefore, the collimator 120 can be manufactured easily and inexpensively. As described above, by manufacturing the same first beam portion 120A and second beam portion 120B respectively and then changing the combination form to manufacture the collimator 120, a plurality of openings having different sizes can be produced. The collimator 120 can be obtained particularly inexpensively.

  In FIG. 10B, the collimator 130 is configured by combining a plurality of thin plate-shaped first beam portions 130A and a plurality of thin plate-shaped second beam portions 130B in the same manner as in the case of FIG. 10A. Even when it is difficult to manufacture the columnar first beam portion 120A and the second beam portion 120B as described above, the thin plate-shaped first beam portion 130A and the second beam portion 130B are particularly easily formed. Can be manufactured. Therefore, the collimator 130 can be obtained particularly inexpensively, and the collimator 130 can be obtained even when a material that is particularly difficult to process is used.

  Further, in the above example, this neutron optical element is assumed to be combined with RANS, but similarly, a target that emits neutrons by being irradiated with a proton beam by a high-intensity proton accelerator J-PARC (Japan Proton Accelerator Research Complex). It is clear that the same effect can be obtained by using this neutron optical element for a certain surface light source or the like. In particular, this neutron optical element is effective for a surface light source that emits thermal neutrons.

1, 2 Neutron source 10 Neutron surface light source 11 Be foil 12 Neutron moderator (thermal neutron generator)
13 Bonding Material 20, 30, 31, 32 Neutron Optical Element 21 First Collimator (Collimator)
21A opening (upstream side opening)
22 Second collimator (collimator)
22A opening (downstream opening)
23 Third Collimator (Collimator)
23A opening 25 housing (support portion)
50 Detector 120, 130 Collimator 120A, 130A First beam part 120B, 130B Second beam part F Focus points N1 to N5, N11, N11, N12, N21, N22, M1, M2 Neutron beam S1, S2 Scattering Neutron beam P Proton beam (proton beam)
S sample

[0003]
It is particularly preferable to concentrate the neutron beam at one point (for example, one point on the sample to be analyzed or one point on the detector) and locally increase (focus) the intensity of the neutron beam at this one point. Whereas it is possible to obtain an optical element that collects these with high efficiency by using a static magnetic field or an electrostatic field for an electron beam and a reflecting mirror for an X-ray. It was difficult to collect neutron rays with high efficiency as well.
[0008]
Therefore, a neutron optical element that collects neutron beams with high efficiency and a high-intensity neutron source using the neutron optical element have been demanded.
[0009]
The present invention has been made in view of the above problems, and an object thereof is to provide an invention that solves the above problems.
Means for Solving the Problems [0010]
The present invention has the following configurations in order to solve the above problems.
The neutron source of the present invention is a neutron source that emits beam-shaped neutrons, a neutron surface light source having a plate-like thermal neutron generator that emits thermal neutrons from the surface, and one side of the thermal neutron generator. A neutron optical element fixed to the one side of the thermal neutron generator to collect neutron rays emitted so as to diverge from the surface of the neutron optical element, the neutron optical element is from a neutron absorber. And a plurality of collimators provided at different positions along the normal direction, which are formed by arranging a plurality of openings penetrating along the normal direction of the thermal neutron generating section, which are composed of a plurality of thin plates And a casing for fixing the collimator around the normal direction, the opening being the opening in the collimator provided on the other side of the plurality of the collimators opposite to the one side. A plurality of side openings and a plurality of downstream openings, which are the openings in the collimator provided on the one side, are provided in the same arrangement, and each of the upstream openings of the collimator provided on the other side. And a straight line connecting each of the downstream openings in the array corresponding to each of the upstream openings, a converging point set on the one side of the collimator provided on the one side. It is characterized in that the collimator, which is configured to pass through and is closest to the other side, is fixed so as to abut on a surface of the one side of the thermal neutron generating section.

[0004]
The neutron source of the present invention is, in the collimator, the plurality of openings are provided in parallel so as to intersect the first beam portion formed of the plurality of thin plates provided in parallel and the first beam portion. And a second beam portion composed of a plurality of the thin plates.
In the neutron source of the present invention, the collimator is provided at a distance of three or more along the one direction, and for a plurality of combinations of two adjacent collimators among three or more of the collimators, The common condensing point is set.
The neutron source of the present invention has an opening width of the downstream opening, an interval between the downstream openings adjacent in the array is an opening width of the upstream opening, respectively, and an interval between the upstream openings adjacent in the array. Characterized by being small.
In the neutron source of the present invention, the collimator is made of a B ₄ C sintered body.
In the neutron source of the present invention, the collimator is composed of any one of B ₄ C, Gd, and Cd.
In the neutron source of the present invention, the housing, a plurality of the collimator, at a location spaced apart along the normal direction, comprising a support portion for fixing and supporting the interval along the normal direction, It is possible to adjust the distance between the collimators that are adjacent to each other along the normal direction by selecting the supporting part among a plurality of types of supporting parts prepared or by adjusting the fixing position of the collimator with respect to the supporting part. It is characterized by being done.
The neutron source of the present invention is characterized in that the collimator is selected and used among a plurality of the collimators that are formed of the same material including the opening but are made of different materials.
The neutron source of the present invention is characterized in that the neutron optical element is arranged in a vacuum atmosphere.
The neutron source of the present invention is, in the neutron surface light source, the thermal neutron generating section is composed of a neutron moderator, and ⁹ Be on the other side with respect to the thermal neutron generating section.

[0005]
Is provided, and the fast neutron generating section is configured to be irradiated with a proton beam emitted toward the one side.
Effect of the Invention [0011]
Since the present invention is configured as described above, it is possible to obtain a neutron optical element that collects neutron rays with high efficiency, and a high-intensity neutron source using the neutron optical element.
Detailed Description of the Drawings [0012]
FIG. 1 is a diagram showing a configuration of a neutron source using a neutron optical element according to an embodiment of the present invention.
FIG. 2A is a perspective view (No. 1) showing the configuration of a collimator used in the neutron optical element according to the embodiment of the present invention.
FIG. 2B is a perspective view (No. 2) showing the configuration of the collimator used in the neutron optical element according to the embodiment of the present invention.
FIG. 3 is a diagram showing a configuration of a neutron source in which a modified example of the neutron optical element according to the embodiment of the present invention is used.
FIG. 4 is a diagram showing a passing state of a neutron source when the collimator is thin in the neutron optical element according to the embodiment of the present invention.
FIG. 5 is a diagram showing a passing state of a neutron source when the collimator is thick in the neutron optical element according to the embodiment of the present invention.
FIG. 6 is a first example showing a form when the neutron optical element according to the embodiment of the present invention is used for analyzing a sample.
FIG. 7 is a second example showing a form when the neutron optical element according to the embodiment of the present invention is used for analyzing a sample.
FIG. 8 is a result of measuring the beam shape (neutron beam intensity distribution) by changing the opening area of the collimator in the example of the present invention.
FIG. 9 is a result of measuring the flight time of neutrons by changing the opening area of the collimator in the example of the present invention.

Claims (12)

A neutron optical element that collects neutron rays emitted so as to diverge from the surface on one side of the surface whose normal is in one direction,
A plurality of collimators formed by arranging a plurality of openings penetrating along the one direction, which is a plate shape that is formed of a neutron absorber and intersects the one direction,
The upstream side opening which is the opening in the collimator provided on the other side opposite to the one side and the downstream side opening which is the opening in the collimator provided on the one side have the same arrangement. Are provided in each,
A straight line connecting each of the upstream openings in the collimator provided on the other side and each of the downstream openings in the array corresponding to each of the upstream openings is provided on the one side. A neutron optical element configured to pass through a condensing point set on the one side of the collimator.   In the collimator, the plurality of openings are formed by a combination of a plurality of first beam portions provided in parallel and a second beam portion provided in parallel so as to intersect with the first beam portion. It formed, The neutron optical element of Claim 1 characterized by the above-mentioned. The collimator is provided at a distance of three or more along the one direction,
The neutron optical element according to claim 1 or 2, wherein a common condensing point is set for a plurality of combinations of two adjacent collimators among the three or more collimators. ..   The opening width of the downstream opening and the interval between the downstream openings adjacent in the array are smaller than the opening width of the upstream opening and the interval between the upstream openings adjacent in the array, respectively. The neutron optical element according to any one of claims 1 to 3. The neutron optical element according to any one of claims 1 to ₄ , wherein the collimator is made of a B ₄ C sintered body. The _collimator, B 4 _C, Gd, neutron optical element according to any one of claims 1 to 3, characterized in that it is constituted by any one of Cd. A plurality of the collimators, at locations spaced apart along the one direction, comprising a support portion that fixes and supports the spacing along the one direction,
The spacing between the collimators that are adjacent to each other in the one direction can be adjusted by selecting the supporting part among a plurality of types of supporting parts prepared or by adjusting the fixing position of the collimator with respect to the supporting part. The neutron optical element according to any one of claims 1 to 6, which is characterized in that   8. The collimator is selected and used from among a plurality of the collimators prepared in the same form including the opening and made of different materials, and used. The neutron optical element according to Item 1.   A neutron surface light source having a plate-like thermal neutron generator that emits thermal neutrons from the surface, and the neutron optical element according to any one of claims 1 to 8 in combination. Neutron source   The neutron source according to claim 9, wherein the collimator provided closest to the other side and the thermal neutron generator are in contact with each other.   The neutron source according to claim 9 or 9, wherein the neutron optical element is arranged in a vacuum atmosphere. In the neutron surface light source, the thermal neutron generator is composed of a neutron moderator,
A fast neutron generator composed of ⁹ Be is provided on the other side of the thermal neutron generator, and the fast neutron generator is irradiated with a proton beam emitted toward the one side. The neutron source according to any one of claims 9 to 11, characterized in that

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