EP2494577A1 - Device for reflecting accelerated electrons - Google Patents

Abstract

The invention relates to a device, by means of which accelerated electrons discharged by an electron source can be reflected onto a surface area of an object (2), comprising at least one dielectric main body (30), on which at least one electrically conductive layer (39) is applied at least in one surface area (A; B), wherein at least one electrically conductive contacting element (31) extends from the electrically conductive layer (39) through the dielectric main body (30).

Description

 Apparatus for reading accelerated electrons

The invention relates to a device for reflecting electrons on the surface of an object, which is to be acted upon for the purpose of property modification with accelerated electrons.

From the prior art, a variety of applications are known in which the surface of an object, an edge layer of an object or even an entire object volume is exposed to accelerated electrons to change properties of the object. For example, accelerated electrons are used to kill germs and microorganisms attached to seeds, to sterilize medical or pharmaceutical products, or to modify the properties of plastics and oils.

In most applications, an object to be modified is guided past a rigidly arranged electron source and in the meantime charged with the accelerated electrons emitted by the electron source. Particularly in the case of large-volume objects, not all surface areas or not the entire object volume are exposed to electrons when the object is passed once. Therefore, both devices are known in which an object either past several times with temporal change in position of the object to at least one electron source, as well as devices in which a plurality of electron sources are arranged around the object volume, whereby an object in one pass and without change in position over the entire surface can be acted upon with electrons.

It is also known to employ reflectors in electron beam processes to reflect electron beams passing the object towards the object surface and or to reflect electrons to those surface areas of an object that are not in the direct exposure region of the electron source.

In DE 198 16 246 C 1, a device is described in which an applied on an object paint layer is exposed to accelerated electrons. The object has a 90 ° angle so that one surface of the object is parallel and one surface of the object is aligned perpendicular to the electron exit window of an electron source. Laterally of the electron exit window, a hinged reflector is arranged, by means of which a part of the electrons emerging from the window are reflected onto the object surface oriented perpendicular to the electron exit window. However, the document does not disclose any further details on the structure and materials of the reflector.

From WO 2007/107331 A1, a device is known in which a molded part for the purpose of sterilization between two area beam generators moves through and can be acted upon in the meantime with accelerated electrons. This device has a plurality of gold reflectors, with which edge rays emitted by the area beam generators are reflected onto surface areas of the molded part which are not in the immediate area of influence of the area beam generators. The reflectors are also part of a sensor system. Connected to measuring devices can be detected by the reflectors electron currents and as a result statements about electron current density distributions are made. Since the reflectors known from this document are made of pure gold, such devices are very expensive and thus affect their cost-effectiveness. Solutions, if and how the share of

Reflection and transmission of the impinging electrons on a reflector can not be deduced from the document.

task

The invention is therefore based on the technical problem of a device for

Reflecting accelerated electrons to create, can be overcome by the disadvantages of the prior art, not least in terms of its efficiency. In particular, electrons emitted by an electron source with the device should be able to be reflected onto the surface of an object to be modified by means of accelerated electrons. Furthermore, the device should be usable as part of a sensor system for determining electron currents and electron current density distributions. Likewise, solutions are to be specified as to how the proportion of reflection and transmission of the electrons striking a reflector can be adjusted. The solution of the technical problem results from objects with the features of claim 1. Further advantageous embodiments of the invention will become apparent from the dependent claims. A device according to the invention, by means of which accelerated electrons emitted by an electron source are reflectable to a surface region of an object, comprises at least one dielectric base body, on which at least in one surface region at least one electrically lettable layer is applied, on which a portion of the emitted from the electron source and is reflected on the electrically conductive layer incident accelerated electrons. For the purpose of

 Contacting the electrically conductive layer extends from the electrically conductive layer at least one electrically conductive contacting element through the dielectric base body. Due to the charging of the electrically conductive layer with accelerated electrons, a charge carrier excess and thus an electrical voltage with respect to the electrical ground builds up on it. Therefore, a measuring device can be connected between the contacting element and the electrical ground, by means of which an electron current can be detected. The electrons accelerated onto the electrically conductive layer by the electron source (also referred to as electron accelerator) are thus reflected to a first portion of the electrically conductive layer and are at a second portion of the flow of an electrical current from the electrically conductive layer through the contacting element involved. As will be explained later, the ratio of the two components can be changed or adjusted. With a fixed proportion of the reflected electrons, a qualitative statement can then be made as a function of the detected electrical current as to which energy or absorbed dose applies a surface region of an object onto which the accelerated electrons are reflected by the electrically conductive layer become. The higher the detected electric current, the higher the energy or the absorbed dose, which is applied to the surface area of the object.

With a device according to the invention, on the one hand, accelerated electrons emitted by an electron source can therefore be reflected and, on the other hand, a device according to the invention can be incorporated as part of a sensor system or a measuring system used to make statements about the energy that is applied to an object.

Usually, the surface region of the dielectric base body, within which the electrically conductive layer is located, is planar, the dielectric base itself being plate-shaped. Depending on the application and / or depending on the shape of the object to be modified with electron energy, this surface area may also have a different geometric shape. For example, this surface area may be concave in a convex-shaped object and vice versa.

If a plurality of devices according to the invention are arranged next to one another within a spatial dimension and an electrical current is detected for each device, which flows from the respective electrically conductive layer through an associated contacting element, then a qualitative statement about the distribution of the electrical currents can also be made depending on the individual detected electrical currents Energy that is applied to the object within the spatial dimension. Of course, this qualitative statement is all the more accurate the more devices according to the invention are arranged next to one another in a spatial extent and the more electric currents are consequently detected.

As an alternative to the embodiment that a dielectric base body has only one surface area with an electrically conductive layer, a dielectric base body may also have a plurality of surface areas within which an electrically conductive layer is formed, wherein the individual electrically conductive layer areas are formed electrically insulated from one another and wherein Each electrically conductive layer region has at least one contacting element, which extends from the associated electrically conductive layer region through the dielectric base body. Each contacting element is then connected to an associated measuring device for detecting an electric current. In such an embodiment, any number of electrically conductive layer regions can be arranged one-dimensionally or even two-dimensionally next to one another on the surface of a dielectric base body. With a device according to the invention in which in each case at least two electrically conductive layer regions are formed on a planar surface of a dielectric base body, a two-dimensional statement regarding the distribution can be obtained by evaluating the respective detected electrical currents flowing over the electrically conductive layer regions the electron energy are hit, with which an object to be modified is applied. Here, too, applies the previously described: The more and the denser the electrically conductive layer areas are arranged side by side in a spatial dimension, the higher the spatial resolution of the current density of an electron beam and the more accurate statements can be made regarding the distribution of energy with which Surface of an object is acted upon.

The dielectric base essentially acts as a carrier of the electrically conductive layer or of the electrically conductive layer regions and gives the device the necessary mechanical stability. With respect to the material for the dielectric base body, in addition to a required strength, there is a requirement that it must also be resistant to ionizing radiation. Ceramic materials are very well suited, for example. By way of example, ceramics such as aluminum oxide or zirconium oxide may be mentioned at this point, but all other known ceramics may also be used for this purpose. In addition to ceramic materials but also, for example, glass materials for the dielectric base body can be used.

For the at least one electrically conductive layer, all materials can be used which have an electrical conductivity. When an electron beam impinges on the electrically conductive layer, the kinetic energy of the beam electrons is partially converted into heat or excitation energy of the atoms by interactions with atoms of the layer material. The large number of elastic and inelastic collisions, which the jet electrons carry out with the atoms of the layer material, not only causes an energy loss but also a change of direction of the beam electrons, which is why a portion of the beam electrons is backscattered and thus reflected by the electrically conductive layer. The intensity distribution of the reflected electrons over the solid angle is club-shaped and has an intensity maximum whose direction corresponds to the optical reflection law - angle of incidence equal to the angle of reflection. The proportion of backscattered or reflected electrons essentially depends on the angle of incidence of the electron beam and on the atomic number of the elements involved in the layer structure certainly. The flatter the angle of incidence of the electron beam on the electrically conductive layer and the higher the atomic number of the elements involved in Schtchtauf construction, the higher is the proportion of the reflected beam electrons. Since in a device according to the invention the reflection of beam electrons represents an essential task, those electrically conductive materials are particularly suitable for the electrically conductive layer, which consist of one or more elements having a high atomic number. Thus, in one embodiment, the electrically conductive layer consists of one or more elements from the group of elements with an atomic number of 40 to 79 inclusive.

Due to the thermal effects of the impact of accelerated electrons on the electrically conductive layer, it is also advantageous if the material used for the electrically conductive layer has a melting temperature of about 1000 ° C. However, it is also possible to use materials with a lower melting temperature down to 200 ° C. for the electrically conductive layer, if, for example, only small ones are used

Electron beam powers are used and or when measures are taken to cool the electrically conductive layer. Thus, for example, the dielectric base body can be traversed by cooling channels and flowed through by a cooling medium in order to dissipate heat from the electrically conductive layer.

Very suitable for an electrically conductive layer of a device according to the invention are materials such as gold, tantalum, molybdenum, tungsten or alloys of two or more of the aforementioned elements, because these materials have both a good electrical conductivity and a high melting temperature and thus no additional Require cooling.

Especially suitable for the electrically conductive layer is gold. In addition to a relatively high melting temperature, a very good electrical conductivity, a high proportion of reflected electrons due to a relatively high atomic number, gold is also a layer material which can be used in such applications in which electrons are to be applied to pharmaceutical or medical products.

A contacting element, which extends from an electrically conductive layer through the dielectric base body in a device according to the invention, likewise consists of an electrically conductive material. As a contacting element is not exposed to the direct electron bombardment exist with respect to it

Temperature resistance no high requirements. For this, therefore, materials such as gold, platinum, titanium, molybdenum, iron, chromium, tantalum or alloys of at least two of the aforementioned elements are suitable. A contacting element is preferably designed as a pin-shaped contact pin (also called contact pin) and may have a cross-section of any desired geometric shape. It is advantageous if the contact pin has a standardized cross-section, so that standardized contact means, such as connectors, for contacting the contact pins can be used.

Particular attention is paid to inserting the contact pin (s) into a dielectric base body. In particular, when a device according to the invention is used in the manufacture or processing of pharmaceutical or medical products, very high demands can be made with regard to the tightness of the joint between the dielectric base body and the contacting element. In such

 In many cases, the reflector according to the invention is at the same time designed as a wall between a room of high sterility and a room of lower sterility, wherein the room with high sterility to the electrically conductive layer and the room with lower sterility to the back of the reflector, ie to the dielectric Basic body adjacent. Here it must be ensured that no germs can pass through the joint between the dielectric base body and the contacting element from the space of lower sterility. With the relatively middle one! a gas pressure test can be checked, for example, if a joint is gas-tight. If a joint is gas-tight, then in any case it is also ensured that no germ can get through the joint. In one embodiment of the invention, the joint is therefore gas-tight between the dielectric base body and the contacting element.

Various methods are suitable for the gas-tight insertion of a contacting element into a dielectric base body. In all methods, a hole corresponding to the cross-section of the contacting element must first be introduced into the dielectric base body, which extends through the entire thickness of the dielectric base body and into which Contacting element is introduced. The hole can be formed with a constant cross-section through the entire thickness of the body or even to the back of the body towards a Have cross-sectional enlargement, which acts in this thickness range of the body as an expansion space for the contacting element in subsequent processing steps. The contacting element must have a length such that it extends through the entire thickness of the dielectric base body on the one hand and then protrudes so far on the rear side of the dielectric base body that it can be contacted with contact means such as, for example, with connectors. On the side of the dielectric base body on which the electrically conductive layer is applied (also called front side in this document), the contacting element must extend at least as far as the surface of the main body, but may initially protrude slightly beyond it when introduced into the dielectric base body.

The material of which a contacting element consists is partly also determined by the insertion method. Thus, a contacting element, for example, by means of a soldering process in a dielectric base body made of a ceramic gas-tight be inserted. When this method of insertion is used, such metals or metal alloys are suitable as the material for the contacting element with which a known ceramic-metal solder connection can be produced. Another requirement is that the ceramic used for the dielectric base body and the material for the contacting element have at least approximately a similar coefficient of thermal expansion so that upon heating and subsequent cooling of the solder joint no mechanical stresses in the joint, which can lead to cracking.

When inserting a contacting element by means of a soldering method, it is therefore possible to use, for example, materials such as molybdenum or a NiCoSil alloy for the contacting element.

An alternative approach when inserting a contacting element into a ceramic dielectric base body is sintering, ie, the contacting element is inserted into the dielectric base body as soon as the ceramic is fired. As materials for the contacting element, for example platinum, tungsten, titanium or alloys of the aforementioned elements can be used in this insertion process. As a further alternative for the insertion of a contacting element, an adhesive method can be selected in which all the aforementioned materials for a

Contacting element can be used. In this case, if a gas-tight adhesive bond between the dielectric base body and contacting element are produced, it is not sufficient to use a purely organic adhesive because it is decomposed under the influence of ionizing radiation, whereby the joint loses its strength on the one hand and on the other hand permeable to gases or for germs. It is therefore advantageous to add solid particles such as ceramic particles to an adhesive. It has been found that despite the decomposition of the organic adhesive constituents in the joint under the influence of ionizing radiation, the residual solid particles ensure both the necessary hold of the contacting element and a required tightness of the joint.

If the at least one contacting element is firmly inserted into the dielectric base body, the side of the dielectric base body on which the electrically conductive layer is to be applied and on which the contacting element after the

Insert slightly protrude, ground so smoothly that the surface of the dielectric base body with the end of the contacting element forms a flat surface on which subsequently the at least one electrically conductive layer is applied. The finer the cut, the more durable the electrically conductive layer is

Coating defects are minimized. In one embodiment, therefore, the ground surface has a roughness of less than 0.05. The electrically conductive layer and the contacting element form an electrically conductive connection after the application of the electrically conductive layer.

Various methods can also be used for the application of the at least one electrically conductive layer. Vacuum methods of chemical or physical vapor deposition are suitable, for example, for applying the electrically conductive layer in its full thickness or initially applying only a partial layer of the electrically conductive layer, which can subsequently be reinforced by means of a galvanic deposition method. However, the electrically conductive layer can also be completely deposited by means of galvanic methods. Another alternative method for applying the electrically conductive layer is before sintering a ceramic dielectric base body, a paste, in which conductive particles are mixed, applied to the dielectric base body. After a sintering process, a layer of the conductive particles then remains on the surface of the dielectric base body. For this purpose, for example, a gold-containing paste may be used, from which, after a sintering process, a gold layer remains on the surface of the dielectric base body. In a further alternative embodiment, the paste with conductive particles can also be applied to the dielectric base body only after sintering. As already mentioned before, in a device according to the invention the proportion of the electrons reflected by the electrically conductive layer can be adjusted. The choice of the applied layer thickness of the electrically conductive layer (hereinafter also referred to as reflection layer) makes it possible, in combination with the choice of the layer material, to precisely set the proportion of reflected electrons to the transmission component. If the total layer thickness of the reflection layer is at least as great as the maximum penetration depth of the accelerated electrons, then it is ensured that a maximum proportion of the electrons is also reflected. The amount of electrons available for the measuring signal is correspondingly low. As the layer thickness of

Reflection layer (starting from a layer thickness which corresponds to the maximum penetration depth of the electrons) is reduced, also reduces the proportion of reflected electrons, whereas the transmission component, that is, the proportion of electrons available for the measurement signal is increased. For completeness, it should be mentioned at this point that the impact of accelerated electrons on the electrically conductive layer in addition to backscattered or reflected electrons and the flow of an electric current from the electrically conductive layer, via a contacting element to a measuring device even the dissolution of secondary electrons and of thermal electrons and the generation of heat and X-rays causes. With regard to the device according to the invention, however, only the facts of the reflected electrons and the current flow are considered in more detail.

The maximum penetration depth of accelerated electrons due to their kinetic energy in a material depends on various factors, but can be determined by known formulas or from known tables and overviews. Thus, depending on the task, ie depending on whether more electrons are to be reflected or whether more electrons for the measurement signal should be available in the Before a thickness for the reflection layer determined and thereby the ratio of the available reflection and transmission electrons can be adjusted.

In an embodiment for predominantly reflecting the accelerated electrons, the layer thickness d _{R of} the reflection layer is set in a range that is greater than the maximum penetration depth of the electrons and is given by the following formula:

Ub = acceleration voltage

p _w = density of water

p _G = density of the reflection layer

p _F = density of the window foil of the electron accelerator

d _F = thickness of the window foil of the electron accelerator

k, = 1 * V ¹

s = safety factor (s> 1, 5).

In a device according to the invention, the electrically conductive layer can also consist of two or more partial layers. For better adhesion of the cover layer acting as the actual reflection layer, one or more partial layers may be arranged below the reflection layer, for example, which act as adhesion promoter layer (s) between the dielectric base body and the reflection layer. Furthermore, at least one partial layer may also be formed as a barrier layer in order to prevent particles from an adhesive layer and / or from the dielectric base body from diffusing into the reflection layer. However, one requirement for a sub-layer acting as a bonding agent layer and as a barrier layer is that these must be electrically conductive so that an electric current can flow from the reflection layer to the contacting element. Thus, a partial layer of the electrically conductive layer formed as an adhesion promoter layer may consist of one or more elements of the group chromium, manganese, iron, and cobalt, and platinum, tantalum, gold or titanium containing materials may be used for a partial layer formed as a barrier layer be used. embodiment

The invention will be explained in more detail below with reference to a preferred embodiment. Components which have the same reference numerals in different figures agree functionally or structurally. The figures show:

 Fig. 1 is a schematic representation of a device for applying a

 Object with accelerated electrons;

Fig. 2 is a schematic representation of a reflector group of the device of Fig. 1; Fig. 3 is a schematic representation of the structure of a reflector of the reflector group of Fig. 2;

 Fig. 4 is a schematic representation of an alternative construction of a reflector of

 Reflector group of FIG. 2.

In FIG. 1, a device 1 is shown schematically in cross-section, by means of which the surface of a molded part 2 can be acted upon by accelerated electrons in order to sterilize the surface of the molded part 2. Molding 2 is an elongate article with a trapezoidal cross-section. Device 1 consists of two electron accelerators 3a, 3b designed as area beam generators, which each comprise an electron acceleration space 4a, 4b and an electron exit window 5a, 5b. Here, the electron exit windows are each formed as 11 pm thick titanium foil. The electron accelerators 3a, 3b are arranged such that the flat-shaped

Electron emission windows 5a, 5b are aligned parallel opposite. Between the two electron exit windows 5a, 5b is molded part 2 on a level of the

Electron exit window 5b broken and shown in Fig. 1 dotted conveyor belt system 6 continuously passed in the direction of image depth and thereby applied its entire surface with electron energy. In each case, the lowest energy dose at the points farthest from the electron exit windows would be transmitted at the oblique side surfaces of the molded part 2, which is achieved by the arrangement of electron reflectors 7a1, 7b1, 7a2, 7b2 (hereinafter only

Reflector (s) called) is compensated. This is done by the unused marginal rays 8a1, 8a2, 8b1, 8b2 of the respective electron beam of the two electron accelerators 3a, 3b meet the respective nearest reflector, are reflected there and are guided by the angular arrangement of the reflectors in the region of the lowest dose on the molded part , From such an overall arrangement results in an absorbed dose on the entire surface or in an entire surface layer of the molded part with a minimum overdosage factor, a maximum utilization of the electron flow and a minimum amount of reactive ozone generated in the air gap.

FIG. 2 shows the reflector group 7a1, 7b1 in a somewhat more detailed schematic representation. It can be seen that the reflectors 7a1, 7b1 on the one hand are spaced apart from each other and thus have no electrical contact with each other and on the other hand are provided on the back of each with contact elements 20 to which electrical lines 21 are connected, which in turn with a in Fig. 2 not shown measuring device are connected. By means of this measuring device, values for electric currents are detected which flow through the reflectors 7a1 and 7b1 towards the associated contact elements 20. Here, each contact element 20 may be assigned a separate measuring device or a plurality of contact elements 20 are connected to a measuring device which has a plurality of measuring inputs. The structure of the reflectors 7a 1, 7a2, 7b 1, 7b2 of FIG. 1 is identical and is shown schematically in FIG. 3 by way of example with reference to the reflector 7a1 in an exploded view. The base of the reflector 7a 1 forms a dielectric base body 30 made of high-density, ie at least 99.5% pore-free Al ₂ 0 ₃ which has a purity of at least 99.5%. The ceramic base body 30 gives the reflector 7a 1 its mechanical stability. It is plate-shaped and has a plate thickness of 12 mm. The horizontal extent of the reflector 7a 1 in Fig. 3 corresponds to the extension, which has the reflector 7a 1 in Figs. 1 and 2 in the image depth. From Fig. 3 it is further apparent that a contact element 20 according to FIG. 2 consists of two individual components, a contact pin 31 made of platinum and a contact socket 32. Each base body 30 is provided with two contact pins 31, each extending through the entire plate thickness of

 Base body 30 extend, as the left half of the main body 30 can be seen in Fig. 3, which is shown there in a sectional view. The contact pins 31 have already been introduced into the material of the base body 30 prior to sintering, in such a way that a contact pin 31 extends completely through the whole

Plate thickness of the base body 30 extends and so far protrudes on the back of the body that on the protruding end of the contact pin 31 still a contact socket 32 can be plugged. Alternatively, a contact socket 32 may also be clamped, screwed or otherwise secured to a contact pin 31. During sintering of the base body 30, the contact pins 31 inserted into the raw material of the base body are firmly inserted into the material of the base body, thereby creating a gas-tight connection at the joints between the contact pin and the base body. After sintering, the front side of the main body 30 is ground smooth, so that the ends of all the contact pins 31 with the front of the main body 30 form a flat surface.

After the front of the body is ground smooth, two identical layer stacks are applied thereto in surface areas A and B, wherein the two layer stacks, however, are formed electrically isolated from each other. This requirement can be implemented by, for example, applying one or more layers over the entire area on the front side, wherein subsequently, for example with an etching method, a separation is carried out between the two layer areas.

Alternatively, the layer regions which are electrically insulated from one another can also be applied separately at the same time by means of a mask on the front side of the base body.

As already described above, a reflector according to the invention, in addition to a dielectric base body with embedded contact pin, also includes an electrically conductive layer. In the exemplary embodiment, the electrically conductive layer 39 consists of several sub-layers deposited on top of each other. The cover layer of the layer stack, which acts as the actual reflection layer, should be formed in the embodiment as a gold layer. Because a gold layer on a ceramic body of Al ₂ 0 ₃ does not have very good adhesion, a 100 nm thick electrically conductive adhesive layer 33 of chromium is first deposited by means of a vacuum coating process on the smooth-ground front of the base body 30. However, chrome particles from adhesion layer 33 may diffuse into and through an adjacent gold layer and oxidize to the surface thereof, which may have adverse effects in medical and pharmaceutical applications. Therefore, a 200 nm thick electrically conductive diffusion barrier layer 34 made of titanium and then a 500 nm thick electrically conductive diffusion barrier layer 35 made of platinum are deposited on the adhesion layer 33 also by means of a vacuum coating process. Because of the better adhesion, a 1000 nm thick gold layer 36 is then applied again by means of a vacuum coating process on the platinum layer 35, which is finally galvanically reinforced with a gold layer 37 at least 22 pm thick, because by means of galvanic deposition faster layer thickness increases with closed surface structure can be realized. The electrically conductive layer 39, which is in a device according to the invention on a dielectric base body, thus comprises in the embodiment, the sub-layers 33, 34, 35, 36 and 37, wherein the sub-layers 36 and 37 of gold in combination act as the actual reflection layer.

A portion of the electrons of the electron beam 38, which impinges on the gold layer (consisting of the sub-layers 37 and 36) in the region A or B, are partially reflected on or within the gold layer. A portion of the non-reflected electrons causes a flow of current from the gold layer through the likewise electrically conductive layers 35, 34 and 33 towards the associated contact pin 31. This electric current continues to flow through the contact socket 32 and the electrical line 2 connected thereto to the measuring device, not shown in which values for the flowing electric current are detected. Due to their kinetic energy, the electrons of the electron beam 38 impinging on the gold layer can penetrate into the gold layer up to a maximum depth z. In the exemplary embodiment, in which it is important to reflect beam electrons on the surface of an object, the thickness of the gold layer (consisting of the sub-layers 37 and 36) was dimensioned such that it is greater than the maximum penetration depth z. As a result, a large proportion of beam electrons is reflected from the gold layer.

If the thickness of the gold layer were to be smaller than the penetration depth z, a proportion of the beam electrons would reach the dielectric layers 30, below the conductive layers 35, 34 and 33 lying below the gold layer. The kinetic energy of this

Electron portion would then no longer be sufficient for a reflection, so that this electron component flows through the electrically conductive layer 33 toward the associated contact pin 31, via the contact socket 32 and the connected thereto electrical line 21 to the measuring device, not shown, in which values for the flowing electrical current are detected. In this embodiment, the proportion of reflected electrons would therefore be lower than in the previously described embodiment, in which the thickness of the gold layer is greater than the penetration depth z.

4, an alternative structure of the reflector 7a 1 is shown schematically. This embodiment variant also comprises a dielectric base body 30 made of aluminum oxide embedded contact pins 31, the attached contact sockets 32 with associated electrical line 21 which leads to a measuring device, not shown. Before sintering of the base body 30, it was coated in areas A and B with a gold-containing paste consisting of gold particles and a sinterable binder. During the sintering process, the gold particles contained in the paste are firmly inserted into the surface of the base body 30 or firmly bonded to the surface of the base body 30 by means of the binder and thus form a gold-containing layer 43 on which in a subsequent process step a least 22 pm thick gold layer is deposited, which then has a high adhesive strength on the body. Before the application of the electrodeposited gold layer, the surface of the body on the front side, as described for Fig. 3, smoothed, so that any protruding from the body contact pins are shortened to the height of the flat surface of the body. In this case, however, care must be taken that, in spite of maximally minimizing the roughness of the surface as a result of grinding, the gold particles baked on the surface of the base body during sintering are not removed again, since otherwise the adhesion of the subsequently electrodeposited gold layer is adversely affected.

Claims

claims

1. Device, by means of the delivered by an electron source accelerated

 Electrons on a surface region of an object (2) are reflective, comprising at least one dielectric base body (30) on which at least in a surface region (A; B) at least one electrically conductive layer (39) is applied, which differs from the electrically conductive layer (39) at least one electrically conductive contacting element (31) through the dielectric base body (30) extends therethrough.

2. Apparatus according to claim 1, characterized in that the dielectric base body (30) consists of a ceramic or glass.

3. A device according to claim 2, characterized in that the ceramic

 Alumina or zirconia.

4. Device according to one of the preceding claims, characterized in that the electrically conductive layer (39) at least on its surface consists of a material which has at least one of the elements gold, tantalum, molybdenum, tungsten.

5. The device according to claim 4, characterized in that the electrically conductive layer is formed as at least 5 μιτι thick gold layer.

6. Device according to one of the preceding claims, characterized in that the electrically conductive layer (39) on the surface of the dielectric base body (3) into a plurality of layer regions (A; B) is divided, which are formed electrically isolated from each other and wherein each layer region (A; B) is assigned at least one contacting element (31) which extends from the respective layer region (A; B) of the electrically conductive layer (39) through the dielectric base body (30).

7. Device according to one of the preceding claims, characterized in that the electrically conductive layer (39) consists of at least two superimposed sublayers (33; 34; 35; 36; 37).

8. The device according to claim 7, characterized in that at least one partial layer (33) is formed as an adhesion-promoting layer.

Apparatus according to claim 8, characterized in that the adhesion promoter layer has at least one of the elements of the group chromium, manganese, iron or cobalt.

10. Device according to one of claims 7 to 9, characterized in that

 at least one partial layer (34; 35) is formed as a barrier layer.

1 1. A device according to claim 10, characterized in that the barrier layer comprises at least one of the elements from the group of platinum, titanium, tantalum or gold.

Device according to one of the preceding claims, characterized in that the contacting element (31) is designed as a contact pin whose material has at least one of the elements from the group gold, platinum, titanium, molybdenum, iron, chromium or tantalum.

13. Device according to one of the preceding claims, characterized in that the joint between the dielectric base body (30) and contact pin (31) is gas-tight.