DE1289198B - X-ray source with a beta emitter as the source of the radiation that stimulates the X-ray emission - Google Patents

Description

The invention relates to an improved x-ray source. Currently the most widely used X-ray source is the X-ray tube, in which electrons, emitted by a heating wire to bombard a metallic target (Anticathode), from which X-rays are thereby emitted. A disadvantage of such an X-ray tube is that its emission strength, i. H. the intensity of the radiation it emits is not constant.

Recently, a new source of X-rays has come to be known which is known as the Brake radiation source is called and a practical one from the X-rays constant intensity. In the bremsstrahlung source are from Beta particles emitted from a radioactive material to impact a target (Anticathode) from which the X-rays are emitted, which have a characteristic, have a radiation spectrum that depends on the target material. Such sources are known with solid and also with liquid target material.

X-ray sources excited by beta emitters are also known, in which the characteristic radiation of the target material is generated in the target will.

It is also a source with a gaseous beta emitter as an exciting one Known nuclide, but in which the target is also fixed.

The radioactive material chosen is usually one of these known sources such a nuclide emitting beta particles that neither itself nor its decay products Gamma radiation or X-rays as a result of internal conversion are emitted, as these Radiations would overlay the radiation emanating from the target too much.

A disadvantage of these known X-ray sources, the particular occurs when the generated X-rays are low in energy, i. H. having an energy of less than about 20 keV is that the intensity the x-rays are low because of those caused by the solid or liquid target strong absorption of X-rays occurring under the surface layer of the target. In these sources are low-energy X-rays, which are at a depth of 5 thousandths of a centimeter or more are practically absorbed.

With a known source of low-energy bremsstrahlung, at which serves as a stimulating beta emitter tritium in a solid target material how ; Zirconium or titanium is absorbed, the disadvantage is that from it only X-rays are available with the characteristic X-ray spectral features of these target materials.

The object of the invention is to provide an improved, by Beta radiation excited X-ray source, the intensity of which is switched off the absorption in the target is increased.

This task is accomplished in an X-ray source with an X-ray emission excitation of a beta-emitting nuclide serving as target material, which is neither itself nor Via its decay products, gamma radiation or, as a result of internal transformation, X-rays emitted, solved in that the target material is a gas.

In practicing the invention, these are radioactive material and the gaseous target material appropriately in a practically gas-tight, X-ray and beta particle opaque container included at least one made of practically gas-tight, X-ray permeable, for Beta particle impermeable material has made to the window in the Container generated X-rays to allow exit to the outside. For the Invention comes radioactive material in which the highest energy value of the emitted beta particles does not exceed about 0.175 MeV, thus secured is that the window in the container does not have to be unnecessarily thick to prevent Prevent beta particles from entering the container.

The radioactive material can be a solid, for example nickel 63 with a maximum energy of 0.062 MeV or sulfur 35 with a maximum energy of 0.167 MeV. However, preference is given to a gas because it can be intimately mixed with the gaseous target material, thereby reducing self-absorption. Tritium with a maximum energy of 0.018 MeV is particularly suitable for this.

In another embodiment according to the invention, beta emitters are used and target material chemically combined to form a gaseous compound. As examples the following may be mentioned for such compounds: silicon tetrahydride, phosphorus trihydride, phosphorus pentahydride and hydrogen sulfide, in each of which at least one hydrogen atom is replaced by tritium is replaced. A gaseous combination is also conceivable with the beta emitter and target are made of the same element, such as sulfur and sulfur, e.g. B. in hydrogen sulfide.

When choosing beta emitters and target material, this must be taken into account make sure that no corrosive reaction product arises that could attack the container. Is z. B. Tritium used as radioactive material and chlorine or bromine as target material, hydrochloric acid or hydrobromic acid can arise, which a container able to attack from steel.

The target material that you choose in practice depends on the purpose for which the X-ray source is intended.

Should the X-ray source be used to measure the thickness of an object, for example a thin film or another thin-layer material, are needed, one chooses a target material with an X-ray emission maximum practically corresponds to the maximum of the absorption spectrum of the object. For example obtained with a mixture of tritium (as the beta emitter) and argon (as the Target) an intensity maximum at 4.2 A. This combination is especially useful Suitable for testing an object that contains chlorine - chlorine has an absorption maximum at 4.3 A. So z. B. the thickness of a polyvinyl chloride film or that of a coating layer made of a vinylidene chloride copolymer on a transparent to X-rays thin base, for example a film made from regenerated cellulose or from a polyolefin.

The tritium-argon X-ray source is also well suited for Measurement of the sulfur dioxide content of flue gas, since the absorption maximum of sulfur Is 5.01 A. Another source of x-rays according to the invention, the tritium in the mixture with sulfur dioxide gas has a maximum intensity at 5.37 A and is useful for the detection of aluminum, for example when determining the thickness of a foil made of aluminum, the absorption maximum of which is 7.9 A is.

Tritium-substituted silicon tetrahydride emits X-rays, which have an intensity maximum at 7.11 A, tritiated phosphorus trihydride or phosphorus pentahydride emits x-rays that have an intensity maximum at Have 6.14 A, and tritiated hydrogen sulfide emits X-rays, which have an intensity maximum at 5.37 A. Such X-ray sources are also useful for the detection of aluminum by absorption.

If more than one intensity maximum or a broad emission spectrum is required, a mixture of target gases that do not react with one another can be used can be used which give the required radiation spectra.

The volume of the for the inclusion of one designed according to the invention Brake radiation source with useful practical activity required container can be pretty small. For example, when using tritium, approximately 1 cc of tritium with 2 cc of gaseous target material, which is in a 3 cc large Space included, have an activity of 2 to 3 curies. About higher activities To achieve this, larger entrapped amounts are required.

If tritium is used as a beta emitter, it is about 1.6 mm thick stainless steel make a suitable container that is radiolucent Has windows made of 0.13 to 0.25 mm thick beryllium. Because the tritium permeability If the beryllium is large, the window must be thick enough to prevent tritium loss occur even though some X-ray radiation is absorbed in the window as a result.

In the case of a chemical connection between the beta emitter and the target, there are diffusion losses negligibly small due to the size of the molecules, so that thinner windows are used can be.

The X-ray sources according to the invention have the advantage that X-rays can be achieved by using various gaseous targets, which have different X-ray spectral characteristics. By selecting the appropriate gaseous targets, a more suitable wavelength range is available than until now. Due to the low self-absorption in the gaseous target material In addition, the emitted X-ray intensity is greater than that of the previous one known X-ray sources using a solid or liquid target.

An example of an X-ray source designed according to the invention and its use in measuring the thickness of a coating layer on regenerated film Cellulose is described below with reference to the drawing. In this shows Fig. 1 shows a vertical rake cross section through the enclosed in a container X-ray source and FIG. 2 shows a schematic representation of the measurement of the Thickness of a coating layer on a film by means of such a source.

In Fig. 1, the x-ray source is denoted by 1. she consists of the cylindrical container 2 with 1.6 mm thick stainless steel existing walls 3, the window as a cover on its jet outlet end 4 made of 0.25 mm thick beryllium. A mixture 5 of 1 cc of tritium and 2 cc of argon - all dimensions apply to normal temperature and normal pressure - is in the container included, which has a volume of 3 ccm.

The tritium emits beta particles that strike the argon atoms, creating X-rays. These emerge through the window 4 and can be directed at the object to be examined after being masked out. The maximum intensity of the characteristic radiation spectrum is around 4.2 A.

In Fig. 2 is shown how the one in FIG. 1 X-ray source described is used to continuously determine the amount of chlorine in a coating layer made of vinylidene chloride copolymer on one side of a film 6 made of regenerated Cellulose is present. The absorption of the X-rays occurs mainly through Chlorine, which has an absorption maximum at 4.39 A. The thickness of the coating layers can then be calculated from the X-ray attenuation. The absorption of the X-rays in the cellulose carrier material itself are negligibly small. As a radiation detector, for. B. serve a scintillation counter 7.

Claims (3)

Claims: 1. X-ray source with one for X-ray emission excitation a beta-emitting nuclide serving as a target material, which neither itself nor about its decay products are gamma rays or, as a result of internal transformation, x-rays emitted, characterized in that the target material is a gas. 2. X-ray source according to claim 1, characterized in that a beta emitter and target material Mixture of gases that do not react with one another. 3. X-ray source according to claim 1, characterized in that beta emitters and target material to a gaseous compound are chemically combined.