DE750000C - Process for the production of a layer of high secondary emissivity - Google Patents

Description

In practice, the secondary emission layers used are mostly those that contain silver, Contains silver oxide and cesium. Because of the low temperature which such Can tolerate layers, they have little suitability for use in amplifier tubes with grid control. Such tubes require thorough temperature treatment, before they can be put into operation. In addition, it is important for them that the higher multiplier levels, which are brought to a higher temperature by the heat loss, little or no thermally triggered

Emitting electrons, since by such electron emission the conditions in the Tube are disturbed in a sensitive and undesirable way.

In order to create a layer of high secondary

ao emission capability, which largely avoids these disadvantages, to produce, it is prepared according to the invention in such a way 'that the electrode alkali metal vapor is made to act on ^a 5 a thin, contained in the molten state insulating coating layer.

It is true that there are secondary emission layers known that by vapor deposition of an alkaline earth metal on a solid insulating Coating of an electrode can be produced. A small amount of the alkaline earth metal may be used penetrate the top layers of the insulator. However, this does not result in an atomic distribution, i. H. Solution of alkaline earth metal, achieved in the isolator while it is for the effect achieved by the invention It is precisely such a distribution that counts. The layer according to the invention is produced, for. B. in such a way that the surface of the electrode to be coated which is intended for activation with an aqueous one or an alcoholic solution of an insulator or a poorly conductive substance and then brought to such a high temperature that the layer material to Melting is coming. During this melting process, the vapor becomes an alkali metal brought to action on the layer.

It is essential that the base layer on which the alkali substance acts is very thin (e.g. ion- ⁴ mm), if only to avoid disruptive charging of the layer, which would result from its low conductivity. As materials for the production of the layer are particularly suitable? Halides, e.g. B. chlorides or fluorides of alkali and alkaline earth metals. It is not absolutely necessary that the substances from which the layer consists are themselves detachable. Rather, other soluble compounds can be used to wet the electrode surface, which will provide the desired substances when heated in a vacuum. For example, if you want to obtain the oxides of the alkaline earth metals, nitrates, acetates and oxalates of these metals are preferably used. The amount of alkali metal should be measured or the process should be carried out in such a way that not too much alkali metal is absorbed into the layer. The alkali metal which is brought into action on the halides does not need to be the cation of these halides. Rather, it is preferable to use a different alkali metal. For example, good layers result if cesium vapor is allowed to act on lithium fluoride. The structure of such layers must presumably be imagined in such a way that the atoms of the metaldanipple have reduced some of the layer molecules in the reaction equilibrium. Perhaps the lattice disruption caused by such a type of installation plays a decisive role in achieving the high secondary electron yield.

The layers produced in the manner described are also noticeable when they last for a long time higher exposure due to high secondary emissivity. When using of fluorides of the alkaline earth metals as a base layer material is obtained, for. B. Layers that are still at temperatures of yoo ° C have a high secondary electron yield. Another benefit of this Layers, especially those with alkaline earth oxides and alkaline earth fluorides as base material, is that you can use them in grid-controlled amplifier tubes with highly active oxide cathodes, because they are not impair the activity of the oxide cathode through partial evaporation of the alkali metal.

When treating the impact electrodes according to the method described above what is also achieved is that the layers retain their yield figures regardless of the current density of the secondary current. At the moment it cannot be overlooked to the full extent in which way the manufacturing process described does this Difference in the behavior of the layers according to the invention compared to the known methods pure, but sublimated alkali metal halide layers, which is known lose part of their productivity even when treated with currents of lower density. Another advantage that the layers according to the invention have is that that after treatment in alkali vapor they are exposed to such atmospheric light again without losing their productivity that they are not reheated to near their melting point during further treatment in the tube.

Claims (5)

Patent claims: 1. A method for producing a g ₀ layer of high secondary emissivity, in particular for multiplier tubes, characterized in that alkali metal vapor is brought into action _{on an insulating coating layer of the 8th electrode which is in a molten state.} 2. A method for producing a sheet according to claim 1, characterized in that the surface of the _"0 be coated electrode initially wetted with an aqueous or alcoholic solution of an isolator or poorly conducting material, heating the electrode and the vapor of an alkali metal to the layer to act is brought. 3. The method according to claim 2, characterized by the use of alkali halides for making the base layer. 4. The method according to claim 2, characterized by the use of Alkaline earth oxides as a layer material. 5. The method of claim 2 or 4, characterized in that the loading for ₁₀ _ the electrode used contains solutes networks from which excrete alkaline earth metal oxides upon heating. To distinguish the subject of the application from the state of the art, the granting procedure the following publications have been considered: German Patent No. 617 353; French patent .. - 810432; British Patent - 460,356; Physical Review, Vol. 50, 1936, p. 48.