DE1803806A1 - Micro-neutron guide - Google Patents

Description

ORGANISATION FOR; SOCIETY FOR; PARTY FOR . Karlsruhe, September 13, 1968

NUCLEAR RESEARCH MBH PTA 68/27 Br / jd

Applicant: Institut Max von Laue - Paul Langevin, 38 Grenoble, Rue de Martyrs.

Micro-neutron guide

The invention relates to a device for guiding and steering, in particular for deflecting a sub-thermal neutron beam with boundary surfaces curved in this way at least in one plane, that the neutrons are totally reflected (neutron guide)

Such neutron guides are used as experimental aids in irradiation experiments outside the irradiation channel of the reactor used. They serve the following purposes:

a) Separation of the disturbing background radiation

b) Separation of the sub-thermal from the thermal Neutron beams with the possibility of beam focusing.

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c) Intensity enhancement of the neutron beam, if the effective solid angle in the neutron guide totally reflecting the neutrons is greater than that geometric solid angle of the neutron guide.

By using neutron guides of great length it is possible to detect neutrons from the reactor core to possibly outside the reactor building established experiment! acquisitions and facilities to direct.

This has the following advantages: This outside of the reactor building Laboratories and experiment! achieved by an extremely low subsurface disturbance, especially if the neutron guide is slightly curved, so that the flight in a straight line neutrons arriving from the reactor core are switched off, and if special shielding shields are provided, which the laboratories and experimental facilities in front of the diffuse Protect radiation from the reactor building. Furthermore, the possible number of irradiation experiments can be increased because the neutron guide tubes radiate from the reactor core and with increasing distance from the reactor, ever larger installation areas are obtained for the experimental facilities can. In addition, one end of curved neutron guide tubes can be brought into core zones with the highest neutron flux because they do not transmit fast neutrons.

For the following low-energy experiments, neutron guides are from the Interesting reasons mentioned above: (a) Small angle scattering experiments on ordinary or magnetic materials? (b) Capture γ rays Investigations, especially coincidence experiments, in a high-flow reactor the latter require special consideration of the background radiation; (c) Time-of-flight spectroscopy with slow Neutrons and a chopper? (d) Transmission experiences at very low energies.

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A neutron guide is known which consists of a straight, internally highly polished copper-clad tube of cylindrical cross-section, the diameter of which is in the order of centimeters and the length of which is in the order of 20 to 30 meters, and which is evacuated. Such a straight, tubular neutron guide brings an intensity yield for slow neutrons of G - 4 γ ² / Ο. , where y is the critical angle for total reflection on the inner neutron guide tube wall (e.g. 1.5 X 10 ~ for cold neutrons with a wavelength of 10 Å) and Λ is the effective solid angle with X2 = ttj / L. ($> = Inner radius of the Keutronon guide; L = length of the straight neutron guide).

Next is a curved neutron guide with roughly the same Dimensions known, the radius of curvature being approximately 300 to 500 m. With longer lengths of the neutron guide, this curvature

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measurement radius, for example, also be 2000 m. To a / great warming and to prevent activation of the reflective covering, this ends already outside the high flow area of the reactor-Gore. The materials for the neutron guide are copper coatings on the carrier material aluminum and Niekel coatings Iron materials known (Reactor Science and Technology, Journal of Nuclear Energy, Part A / B, Vol. 17, 1963, pages 217 to 225; Nukleonik, Volume 4, 1962, pages 23 to 25).

Also known is a multichannel collimator for neutrons made from magnetized and polished iron foils. Kit him a very good neutron polarization can be achieved (Journal of Nuclear Energy Part A and B, Reactor Science Technology, Vol. 17, 1963, page 22 " ¹ to 231). Only a small modification is necessary to use these collimators as neutron filters For this purpose, the collimator must consist of two parts and have walls made of materials with neutron reflective properties, for example nickel-plated steel sheets.

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When the inner part is hinged so that the angle can optionally be set between the two parts, the collimator can also be used as a neutron filter. Each The laminated core part has a length of approx. 100 cm and consists about 5 to 6 layers with air gaps in between. However, it is doubted in this reference whether this Reflection collimator system has an equally high cold neutron intensity produces, like a quartz crystal filter or a curved, tubular neutron guide with reflecting walls.

The known neutron guides have the disadvantage that they can achieve. Neutron illuminance at the mouth of the neutron guide is relatively low. In any case, for experimental work it would be more desirable, in addition to the advantage of the Switching off the background radiation and the gain in spatial, freedom of movement and high neutron illuminance levels To have at your disposal. In addition, it is aligned and maintained the radius of curvature lengthy or difficult.

It is therefore the object of the invention to find a neutron guide whose radius of curvature compared to the known devices is small and always remains constant. There is also the task of providing such a neutron guide arrangement with the highest possible illuminance to achieve.

According to the invention, there is a small and always constant radius of curvature achieved in that between the outer boundary surfaces a plurality of parallel thereto, each evenly arranged Jicke, alternating layers Λ and B are provided that the same center of curvature as the outer boundary surfaces and have a radius of curvature on the order of a few tenths to a few meters, those of the order of of a few micrometers thick layer A from one for

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cold neutron permeable material with a value of 1 little different refractive index and the layer B of a die, which is on the order of a few tenths of a micrometer thick cold neutron reflecting material (microneedle neutron guide). The index of refraction for the neutrons in the different Materials is determined by D.J. Hughes too

n-1-A ² -Wa _coh / 2-ir (1)

where N = the atomic density of the material, a, = the coherent scattering

coh

amplitude, Λ - mean the neutron wavelength. Since the index of refraction η in most substances is less than 1, total reflection occurs at a critical angle

(2) a. Jf ₀ = VS (T ^ -K) " ³ W ^Z

Since the refractive index depends on the neutron wavelength, the critical angle according to formula (2) also depends on it. The microneedron guide according to the invention is preferably suitable for cold neutrons with a wavelength of 6 to 20 Angstroms.

In an advantageous embodiment of the microneutron lexter according to the invention, the layers permeable to cold neutrons (layer A) consist of aluminum and the neutron-reflecting layers (layer B) consist of necel. The layer A has a thickness of about 1U, while the layer B has a thickness of about 0.1 Ai .

The micro-neutron guides of the type according to the invention have one Base diameter d of 1 to 20 centimeters, while the radius of curvature is about 1 to 0.2 meters.

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In addition, the microneedle guide according to the invention very easy and yet precise to manufacture. Such manufacturing processes have particularly proven themselves:

a) vacuum deposition on a positive or negative form

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at a vacuum of 10 torr using nuclear-grade vapor deposition materials,

b) the electrolytic application of the individual layers a positive or negative form in an electroplating bath,

c) Cathode sputtering of the respective layer material in a gas discharge at low pressure to a positive or Negative form.

According to the invention, the requirement for high neutron illuminance levels is met achieved with a focusing device made of microneutron guides of the type described above, that several such micro-neutron guide with a curvature in only one plane be assembled to a hollow body, which has the shape of a polygonal truncated cone with convexly curved side winds. Such a focusing device can, however, also have the shape of a spherical half-shell with a truncated spherical cap.

The focusing device exists when used on a beam channel with a circular cross-section from a spherical half-shell with a truncated spherical cap (curvature of the boundary surfaces in two Levels). Thereby one in the reactor wall should be under the radiation channel of the research reactor provided radiation channel as well as a well-known neutron guide described in the introduction be understood of great length. In connection with a radiator canal of rectangular cross-section, the inventive focusing device has the shape of a truncated cone with convexly curved side walls. The boundaries reflecting neutrons in the latter case have a curvature in only one plane.

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180380G

The base diameter d of a focusing device according to the type described in the invention is 1 cm to 20 cm, while the radius of curvature f of layers A and B is approximately 0.2 to 1 meter.

Expediently, during the manufacture of the focusing device the positive form used as a carrier material is made from a salt, because this is then applied after the individual Layers can be removed very easily. The same applies to a manufacturing method of the focusing device a negative form. The production has a negative form even the advantage that this is not necessarily removed again must become.

In the following, anV ~ .i. ·: ■. . schematic representation of the structure and the mode of operation of the microneedron guide according to the invention explained in more detail using the example of the focus device will: ·

The figure shows a longitudinal section through a focusing device circular cross-section.

For the cold neutrons arriving in the beam channel 1 with a diameter d ~ 2 cm, there are two ways of passing the focusing device 2 according to the invention and reaching the target 4a:

a) The neutrons in the area close to the axis fly through the central cavity 3 of the focusing device 2 without any reflection and meet almost perpendicular to the focus point 4b of the target 4a.

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b) The neutrons in the area 5 close to the wall experience the curved neutron-reflecting layers B of the focusing device 2 at least one reflection and are thereby deflected towards the focusing point 4b.

The number of reflections should not be more than 5 or 6, because the energy and thus the wavelength of the neutron radiation is changed with the number of reflections and the associated long flight paths in the neutron-conducting layer A. The radius of curvature £> of the curved layers A and B of the focusing device 2 is determined according to the base diameter d, which should be equal to the beam channel diameter, according to the number of reflections, according to the critical angle Y for total reflection, which is dependent on the wavelength of the neutron radiation , and according to the size of the focusing point 4b on the target 4a.

For the focusing device described in the exemplary embodiment, the thickness of the neutron-conducting layer Λ from .Aluminium 1, u, the thickness of the neutron-ref lecting layer B from nickel 0.1 yes, the radius of curvature f of these layers A and B 10 cm, the Arc length 1 of the outermost layer of the focusing device 2 cm, the critical angle / - 0.2 ° / Ä neutron wavelength.

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The invention is not limited to focusing devices with boundary surfaces curved along the direction of flight of the neutrons. Rather, it can also be done with a microneedron guide arrangement with flat neutron-reflecting layers - with a radiation channel with a rectangular cross-section thus with an ilikroneutronenleiter in the shape of a truncated pyramid with flat side surfaces; at a radiation

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Channel circular cross-section with a microneedle conductor in the shape of a truncated cone with curved only in one plane Side surfaces - in the manner of a multi-layer mirror, a deflection of those in the edge zones near the wall Neutrons can be achieved towards the focus point.

With the focusing micro-neutron guides described in the invention In addition to the properties that generally characterize the neutron guide, in particular extraordinary

11 2

borrowed high neutron flux densities of about 10 n / cm see. and above achieve. In addition, it is easily possible with a microneutron guide of the type according to the invention, even in the tightest of spaces Space to achieve a 90 deflection of the neutron flow, which is at the previously known Neutronenleiterη with their radius of curvature from 300 to 2000 m was simply impossible.

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Claims (1)

ί ι not _- ndari vnrj ^ /, ' 180380G Karlsruhe, September 13, 1968 PTA 68/27 Br / jd jtenta nspräc he; Device for guiding and directing, in particular for deflecting, a subthermal neutron beam with at least one Plane so curved boundary surfaces that the neutrons are totally reflected (neutron guide), characterized by that between the outer boundary surfaces several parallel to it, each of the same thickness, are arranged alternating layers A and B are provided which have the same center of curvature as the outer boundary surfaces and a radius of curvature in the order of magnitude of a few tenths of a meter to a few meters, with the layer A of the order of magnitude of a few ilicrometers thick a material that is permeable to cold neutrons and has a refractive index little different from 1 and that in the Layer B a few tenths of a micrometer thick and made of a material that reflects the cold neutrons exists (microneedle guide). Microneutron guide according to claim 1, characterized in that the layers permeable to cold neutrons (layer A) made of aluminum and the neutron-reflecting layers (layer B) made of nickel. Microneedron guide according to claim 2, characterized in that the / cold neutrons permeable layers (layer A) a strength of about 1 .u and the neutron-reflecting Layers (layer B) have a thickness of approx. 0.1 At. 009823/0685 BATH ORIGINAL -V- 180380G 4. micro-neutron guide according to claims 1 to 3, characterized characterized in that the individual layers are deposited by vacuum deposition are made. 5. Ilikroneutronleiter according to claims 1 to 3, characterized characterized in that the individual layers are produced by electrolytic deposition. 6. micro-neutron guide according to claims 1 to 3, characterized characterized in that the individual layers are produced by cathode sputtering of the respective layer material. 7. Focusing device made of microneutron conductors according to claims 1 to 5, characterized in that several such I'ikroneutronenlei, .r are composed with a curvature in only one plane to form a hollow body which has the shape of a polygonal truncated cone with convexly curved side walls _% . 8. Focusing device from micro-neutron guides according to the Claims 1 to 3, characterized in that this .-; u one Hollow bodies are shaped, which has the shape of a spherical shell Has with a cut off spherical cap. 9. Focusing device according to claims Γι and 7, characterized in that the base size d of the hollow body is about 1 cm to 20 cm and the radius of curvature P of the hollow body walls is about 1 to 0.2 liters. 009823/0685 Blank page