Abstract:
A coating, composed of an optically effective layer system for substrates, whereby the layer system has a high antireflective effect. On a front side of the substrate, facing the observer, in sequence from the front side to the observer, a first layer is arranged on the substrate, functioning as dielectric and comprising metal oxide. Thereupon follows a second layer comprising nitride, preferably TiN x  (x is equal to or greater than 1, preferably x=1.05). A third layer follows functioning as dielectric and comprising metal oxide. Thereupon a fourth layer follows comprising nitride, preferably TiN x  (x is equal to or greater than 1, preferably x=1.05). A fifth layer follows functioning as dielectric comprising metal oxide. On a backside of the substrate a TiN x  -layer (x≧1, preferably x=1.05) is arranged. The adequate selection of certain materials for the individual layers, of certain layer thicknesses and of a certain sequence of the individual layers results in a surprisingly good antireflective coating, contrast increase and antistatic effect. These good optical features of the layer system are reached with a small number of layers and with thin layer thicknesses. This, in turn, leads to an extremely cost saving manufacturing of the coating.

Description:
BACKGROUND OF THE INVENTION 
     The invention is related to a coating composed of an optically effective layer system, for substrates, whereby the layer system has a high antireflective effect. 
     There is a wide range of layer systems for substrates, particularly for glass, which fulfill certain optical functions. The present invention involves a type of layer system using antireflective layers, or respectively, antireflective layer systems. 
     The German publication DE-OS 3,629,996 revealed an adaptor unit/aggregate for the cathode ray tube of monitors, television sets and such, composed of a glass disk, particularly a gray glass disk, a frontside antireflection device and a backside absorption coating, whereby the absorption coating comprises metal atoms. 
     In this German publication it is suggested that the absorption coating is structured in one-layered fashion from chrome, a chrome/nickel alloy or silicides, established and grounded antistatically, and provided with a thickness which lowers the light transmission compared to the uncoated glass disk by approximately one third. 
     The U.S. Pat. No. 3,854,796 suggests another coating for the reduction of reflection. The coating is to be applied on a substrate having a plurality of layers. In the sequence beginning at the substrate, the &#39;796 patent describes the following arrangement: three groups of at least two lambda/4-layers, the successive layers of the first group have a refractive index lying below the refractive index of the substrate. The layers of the second group have an increasing refractive index and the layers of the third group have a refractive index below that of the substrate. More details can be ascertained from the cited &#39;796 patent. 
     In U.S. Pat. No. 3,761,160 a broadband-antireflection-coating coated onto substrates is suggested. At least four layers are disclosed for glass with a high index and at least six layers are disclosed for glass with a low index. More details can be learned from the cited &#39;160 patent. 
     U.S. Pat. No. 3,695,910 describes a method for the application of a antireflective coating on a substrate. This coating is composed of several individual layers. The method for the application of the antireflection coatings ensues under vacuum, namely with the use of electron beams. 
     U.S. Pat. No. 3,829,197 describes a antireflection coating fashioned as a multilayer system. This coating is to be applied on a strongly refractive substrate. The layer system is composed of five individual layers which are mutually adapted with regard to their refractive indices and optical thicknesses. This adaptation is to achieve a favorable antireflection curve with a broad, flat, center part. 
     Swiss patent 223,344 deals with a coating for the reduction of surface reflection. The coating is composed of at least three layers with various refraction coefficients. The reduction of the surface reflection can be achieved, according to this reference, by a certain selection of refraction coefficients of the individual layers. 
     SUMMARY OF THE INVENTION 
     The invention is based on the following objectives: 
     An object of the invention is to provide effective antireflective coatings for transparent substrates. 
     Transparent substrates are necessary in a plurality of examples of modern equipment and devices. Manufacturers of this equipment and these devices have high requirements regarding optical and other features of these substrates. 
     The invention is to fulfill these requirements, particularly with an antireflection coating, and with regards to a corresponding contrast increase and an increase of an antistatic effect. 
     Another objective is to provide for an economical manufacture of the antireflection coating system. A minimum number of layers is desired. Simultaneously, the thicknesses of the layers are to be thin. Cost saving materials are to be employed. 
     With the invention, a concept is suggested whereby sputtering can be performed in DC-reactive fashion with a magnetron from a metal target. 
     Actually, the use of metal layers for antireflective systems is basically known. It was found, however, that the known metal layers are disadvantageously soft for everyday operation. 
     Therefore, one of the objectives of the present invention is to find a substitute for the known soft metal layers (Ag, Ni, . . . ). This substitute shall be hard and scratch-resistant. On the one hand, it shall be ceramically hard, on the other hand, however, it shall also have the effect of a metal-type optical unit. 
     The invention, the stated objects are solved in that, on a side of the substrate facing the observer, or &#34;front side&#34; in sequence from the front side toward the observer, a first layer is arranged directly on the substrate functioning as a dielectric and comprising metal oxide. Subsequently, a second layer is arranged thereupon, comprising nitride, preferably TiN x  (with x equal to or greater than 1, preferably x=1.05). Subsequently, a third layer is arranged thereupon, functioning as a dielectric, comprising metal oxide. Thereupon a fourth layer is arranged comprising nitride, preferably TiN x  (with x equal to or greater than 1, preferably x=1.05). Thereupon a fifth layer is arranged, functioning as dielectric and comprising metal oxide. 
     It can be provided that the first layer comprises oxides from the group: SnO x  (with x equal to or less than 2, preferably x=2), ZrO 2 , ZnO, Ta 2  O 5 , NiCr-oxide, TiO 2 , Sb 2  O 3 , In 2  O 3  or mixed oxides of the oxides from this group. It is suggested that the second layer comprises nitrides of the group TiN x  (with x equal to or greater than 1, preferably x=1.05), ZrN. The third layer can comprise oxides of the group: SnO x  (with x equal to or less than 2, preferably x=2), ZrO 2 , ZnO, Ta 2  O 5 , NiCr-oxide, TiO 2 , Sb 2  O 3 , In 2  O 3 , or mixed oxides of the oxides from this group. Furthermore, it is provided that the fourth layer comprises nitrides of the group TiN x  (with x equal to or greater than 1, preferably x=1.05), ZrN. 
     As further embodiment of the invention it is suggested that the fifth layer has low-refracting materials, particularly with a refractive index n equal to or less than 1.7. Another provision is that the fifth layer comprises oxides of the group SiO 2 , Al 2  O 3 , AlSi-oxide, NiSi-oxide, MgO or oxide-fluorides of the same group. Alternatively, it is suggested that the fifth layer comprises MgF 2 . 
     In a special group of exemplary embodiments it is provided that between the first and the second layer an adhesive layer is arranged. The adhesive layer can comprise Ni or NiO x  with x less than 1. On the other hand, one can provide that the adhesive layer comprises Cr or Cr-suboxide. In a further exemplary embodiment it is suggested that the adhesive layer comprises a NiCr alloy, preferably NiCr with 80 weight per cent Ni and 20 weight per cent Cr as metal or metal suboxide (NiCr-oxide). It is also possible that the first layer comprises NiCrO x  and can function as adhesive. NiCrO x  can be applied by suboxide coating. 
     In a special exemplary embodiment where the substrate is composed of glass, for example float glass, it is proposed that the first layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) the following third layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following fifth layer comprises Al 2  O 3 , and that on a back side of the substrate facing away from the observer a backside layer comprising TiN x  (with x equal to or greater than 1, preferably x=1.05) is applied. 
     An alternative exemplary embodiment consists thereof that the first layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) the following third layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following fifth layer comprises Al 2  O 3 , that between the first layer and the second layer an adhesive layer is arranged comprising NiCr or NiCr-oxide, and that on the back side of the substrate the backside layer comprising TiN x  (with x equal to or greater than 1, preferably x=1.05) is applied. 
     Another exemplary embodiment is that the first layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following third layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following fifth layer comprises SiO 2 , that between the first layer and the second layer an adhesive layer is arranged comprising NiCr or NiCr-oxide, that on the back side of the substrate the backside layer comprising TiN x  (with x equal to or greater than 1, preferably x=1.05) is applied. 
     In a further exemplary embodiment it is suggested that the first layer comprises NiCr-oxide and can function as dielectric and adhesive, the following second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following third layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following fifth layer comprises Al 2  O 3 , and that on the back side of the substrate the backside layer comprising TiN x  (with x equal to or greater than 1, preferably x=1.05) is applied. 
     In a further exemplary embodiment it is suggested that the first layer comprises NiCr-oxide and can function as dielectric and adhesive, the following second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following third layer comprises SnO x  (with x equal to or less than 2, preferably x=2), the following fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), the following fifth layer comprises SiO 2 , and that on the back side of the substrate the backside layer comprising TiN x  (with x equal to or greater than 1, preferably x=1.05) is applied. 
     Another exemplary embodiment suggests that the first layer has a thickness of 170 angstrom +/-20%, that the second layer has a thickness of 170 angstrom +/-20%, that the third layer has an optical thickness of 5550/4 angstrom +/-20%, that the fourth layer has a thickness of 110 angstrom +/-20%, that the fifth layer has an optical thickness of 5550/4 angstrom, and that such values for the respective layer thicknesses are selected within the cited layer thickness tolerances, which take into account the interdependence between the individual layer thicknesses and the materials used. 
     In a further exemplary embodiment where the substrate is composed of glass, with a refractive index of preferably n=1.52, it is suggested that the first layer comprises SnO x  (with x equal to or less than 2, preferably x=2) and has a thickness of 170 angstrom, that the second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 190 angstrom, that the third layer comprises SnO x  (with x equal to or less than 2, preferably x=2) and has a thickness of 500 angstrom, that the fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 130 angstrom, and that the fifth layer comprises Al 2  O 3  and has a thickness of 730 angstrom. 
     A preferred exemplary embodiment is represented by a substrate composed of glass with a refractive index of preferably n=1.52 whereby it is provided that the first layer comprises SnO x  (with x equal to or less than 2, preferably x=2) and has a thickness of 170 angstrom, that the second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 175 angstrom, that the third layer comprises SnO x  (with x equal to or less than 2, preferably x=2) and has a thickness of 500 angstrom, that the fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 110 angstrom, that the fifth layer comprises Al 2  O 3  and has a thickness of 730 angstrom. 
     Furthermore, the suggestion is made that on the substrate side not facing the observer, the backside layer is arranged comprising TiN x  (with x equal to or greater than 1, preferably x=1.05). 
     Thereby it can be provided that the backside layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 70 angstrom, that the substrate is composed of glass, has a thickness of 2 mm and a refractive index of n=1.52, that the first layer comprises SnO x  (with x equal to or less than 2, preferably x=2) and has a thickness of 170 angstrom and a refractive index n=2.05, that the second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 190 angstrom, that the third layer comprises SnO x  (with x equal to or less than 2, preferably x=2) and has a thickness of 500 angstrom and a refractive coefficient n=2.05, that the fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 130 angstrom, and that the fifth layer comprises Al 2  O 3  and has a thickness of 730 angstrom and a refractive index of n=1.6. 
     In the framework of a further exemplary embodiment it is proposed that the backside layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05), that the substrate is composed of glass, has a thickness of 2 mm and a refractive index n=1.52, that the first layer comprises NiCr-oxide, a thickness of 170 angstrom and a refractive index n=2.1, that the second layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) with a thickness of 170 angstrom, that the third layer comprises SnO x  (with x equal to or less than 2, preferably x=2) has a thickness of 500 angstrom and a refractive coefficient n=2.05, that the fourth layer comprises TiN x  (with x equal to or greater than 1, preferably x=1.05) and has a thickness of 110 angstrom, and that the fifth layer comprises SiO 2  and has a thickness of 730 angstrom and a refractive index n=1.5. 
     For the manufacturing of the coating, a cathode sputtering method is suggested, particularly a DC-reactive sputtering from a target with a magnetron. 
     Particularly, a reactive sputtering from a Sn-target with a magnetron is suggested in the presence of a sputter gas mixture comprising Ar and O 2 , for the generation of a layer composed of SnO x  (with x equal to or less than 2, preferably x=2), given a pressure of approximately 5×10 -3  mbar. 
     In an analogous manner it can be provided that a layer is generated composed of SiO 2  via reactive sputtering from an Si-target with a magnetron a layer in the presence of a sputter gas mixture comprising Ar and O 2 , given a pressure of approximately 5×10 -3  mbar. 
     Furthermore, it is suggested that a layer composed of Al 2  O 3  is generated, via reactive sputtering from an Al-target with a magnetron in the presence of a sputter gas mixture comprising Ar and O 2 , given a pressure of approximately 5×10 -3  mbar. 
     Moreover, it is provided that a layer is generated composed of TiN x  (with x equal to or greater than 1, preferably x=1.05), via reactive sputtering from a Ti-target with a magnetron in the presence of a sputter gas mixture comprising Ar and N 2 , under a pressure of approximately 5×10 -3  mbar. 
     Furthermore, it is suggested that a layer is generated composed of NiCr-oxide via reactive sputtering from a target comprising NiCr, preferably 80 weight percent Ni, 20 weight percent Cr, with a magnetron in the presence of a sputter gas mixture comprising Ar and O 2 , under a pressure of approximately 5×10 -3  mbar. 
     Alternative methods consist thereof that an actually known sputtering process is employed for the coating, that an actually known Chemical Vapor Deposition method (CVD) is employed, that an actually known plasma supported Chemical Vapor Deposition method (CVD) is employed, that an actually known pyrolyse-method is employed. 
     Good antistatic effects are achieved in that the front side of the layer system facing the observer has a surface resistance of 100 to 400 ohm per square, preferably 150 ohm per square. 
     Furthermore, it can be provided that the backside layer of the layer system, on a side of the substrate not facing the observer, has a thickness in the range from 40 to 200 angstrom and a surface resistance of 150 to 500 ohm per square, preferably 450 ohm per square. 
     The following advantages are achieved with the invention. The initially described problems are solved. A high antireflection coating is achieved as well as a strik9ng increase of contrast. By reducing, or respectively, preventing electrostatic charging the antistatic effect is improved. The anti-reflection effect is increased particularly in that the layer reflecting from the backside of the substrate is weakened via absorption in the layer system of the front side. By that a total antireflection coating is achieved which is advantageous over known comparable systems. 
     Compared with the known systems the total thickness of the coating is small. 
     The soft metal layers in the case of known metal optical units, used as antireflective layers, are replaced by the hard scratch-resistant TiN-layer of the invention. On the one hand, this layer has ceramic hardness and, on the other hand, a metal-type optical effect. 
     The low number of layers of the layer system, the thinness of the individual layers of the layer system, the selection of inexpensive material and the ability to sputter in DC-reactive fashion with a magnetron from a metal target, lead to an economical manufacturing of the inventive antireflective systems. 
     More details of the invention, the stated object and the achieved advantages can be taken from the following description of several exemplary embodiments of the invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a cross-sectional view of a layer system applied to a substrate; 
     FIG. 2 is a cross-sectional view of an alternate embodiment of the layer system applied to the substrate; 
     FIG. 3 is a graph showing transmission and reflection curves for a first example of an embodiment of a layer system of the present invention; and 
     FIG. 4 is a graph showing transmission and reflection curves of a second example of an embodiment of the layer system of the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In the immediately following description, five exemplary embodiments are described with respect to FIGS. 1 and 2. 
     A substrate 1 is composed of a transparent material such as glass. A front side 2 of the substrate is that side of the substrate facing an observer viewing from a direction indicated by an arrow 3. A back side 9 of the substrate is that side of the substrate not facing the observer. That layer arranged on the front side of the substrate is a first layer 4. In the direction toward the observer follows the second layer 5, and a third layer 6, a fourth layer 7, and a fifth layer 8. 
     A layer system of a first exemplary embodiment is structured as follows according to FIG. 1. On the backside of the substrate 1 composed of glass, an optically effective backside layer 10 composed of TiN x  is applied. In the direction toward the observer follows the substrate 1. A first optically effective layer is the first layer 4, arranged on the substrate 1 on the frontside 2, and composed of SnO 2 . A second optically effective layer is the second layer 5 following the first layer 4 in the direction toward the observer, arranged on the first layer 4, composed of TiN x . A third optically effective layer is the third layer 6, following the second layer 5 in the direction toward the observer, arranged on the second layer 5, and composed of SnO 2 . A fourth optically effective layer is the fourth layer 7, following the third layer 6 in the direction toward the observer, arranged on the third layer 6, and composed of TiN x . A fifth optically effective layer is the fifth layer 8, following the fourth layer in the direction toward the observer, arranged on the fourth layer 7, and composed of Al 2  O 3 . 
     A layer system of a second exemplary embodiment is structured as follows corresponding to FIG. 2. On the backside 9 of the substrate 1 composed of glass, an optically effective backside layer 10 composed of TiN x  is applied. In the direction toward the observer follows the substrate 1. A first optically effective layer is the first layer 4, arranged on the substrate 1 on the front side 2, and composed of SnO 2 . In the direction toward the observer follows an adhesive layer 11, arranged on the first layer 4, and composed of NiCr-oxide. A second optically effective layer is the second layer 5, following in the direction toward the observer, arranged on the adhesive layer 11, and composed of TiN x . A third optically effective layer is the third layer 6, following the second layer 5 in the direction toward the observer, arranged on the second layer 5, and composed of SnO 2 . A fourth optically effective layer is the fourth layer 7, following the third layer 3 in direction toward the observer, arranged on the third layer 3, and composed of TiN x . A fifth optically effective layer is the fifth layer 8, following the fourth layer 7 in the direction toward the observer, arranged on the fourth layer 7, and composed of Al 2  O 3 . 
     A layer system of a third exemplary embodiment is structured as follows according to FIG. 2. On the backside 9 of the substrate 1 composed of glass, an optically effective backside layer 10 composed of TiN x , is applied. In the direction toward the observer, follows the substrate 1. A first optically effective layer is the first layer 4 arranged on the substrate 1, and composed of SnO 2 . In the direction toward the observer follows an adhesive layer 11, arranged on the first layer 4, and composed of NiCr-oxide. A second optically effective layer is the second layer 5 following in the direction toward the observer, arranged on the adhesive layer 11, and composed of TiN x . A third optically effective layer is the third layer 6 following the second layer 5 in the direction toward the observer, arranged on the second layer 5, and composed of SnO 2 . A fourth optically effective layer is the fourth layer 7, following the third layer 6 in the direction toward the observer, arranged on the third layer, and composed of TiN x . A fifth optically effective layer is the fifth layer 8, following the fourth layer 7 in the direction toward the observer, arranged on the fourth layer 7, and composed of SiO 2 . 
     A layer system of a fourth exemplary embodiment is structured as follows according to FIG. 1. On the backside 9 of the substrate 1 composed of glass an optically effective backside layer 10 composed of TiN x , is applied. In the direction toward the observer follows the substrate 1. A first optically effective layer is the first layer 4, arranged on the substrate 1, and composed of NiCr-oxide; this first layer 4 simultaneously functions as an adhesive layer. A second optically effective layer is the second layer 5, following in the direction toward the observer, arranged on the first layer 4, and composed of TiN x . A third optically effective layer is the third layer 6, following the second layer 5 in the direction toward the observer, arranged on the second layer 5, and composed of SnO 2 . A fourth optically effective layer is the fourth layer 7, following the third layer 6 in the direction toward the observer, arranged on the third layer 6, and composed of TiN x . A fifth optically effective layer is the fifth layer 8, following the fourth layer 7 in the direction toward the observer, arranged on the fourth layer 7, and composed of SiO 2 . 
     A layer system of a fifth exemplary embodiment is structured as follows according to FIG. 1. On the backside of the substrate 1 composed of glass an optically effective backside layer 10 composed of TiN x , is applied. In the direction toward the observer follows the substrate 1. A first optically effective layer is the first layer 4, arranged on the substrate 1, and composed of NiCr-oxide; this first layer 4 simultaneously functions as an adhesive layer. A second optically effective layer is the second layer 5, following in the direction toward the observer, arranged on the first layer 4, and composed of TiN x . A third optically effective layer is the third layer 6, following the second layer 5 in the direction toward the observer, arranged on the second layer 5, and composed of SnO 2 . A fourth optically effective layer is the fourth layer 7, following the third layer 6 in the direction toward the observer, arranged on the third layer 6, and composed of TiN x . A fifth optically effective layer is the fifth layer 8, following the fourth layer 7 in the direction toward the observer, arranged on the fourth layer 7, and composed of Al 2  O 3 . 
     Apart from mineral glass, float glass, plexi-glass, see-through plastic layers, foils etc. can be employed as substrates. Apart from the antireflection coating for the frontside 2 via the described layer systems arranged toward the observer, a further surprisingly low total reflection is achieved via the backside layer 10 composed of TiN x  arranged on the backside 9. 
     The basic idea of the invention permits a plurality of exemplary embodiments, or respectively, layer systems, which are characterized by the subsequently cited materials and layer thicknesses: 
     First layer 4, a dielectric: metal oxide (SnO 2 , ZrO 2 , ZnO, Ta 2  O 5 , NiCr-oxide, TiO 2 , Sb 2  O 3 , In 2  O 3 ), layer thickness: 170 angstrom +/-20%; 
     Second layer 5: nitride (TiN, ZrN), layer thickness: 170 angstrom +/-20%; 
     Third layer 6 dielectric: Metal oxide (SnO 2 , ZrO 2 , ZnO, Ta 2  O 5 , NiCr-oxide, TiO 2 , Sb 2  O 3 , In 2  O 3 ), layer thickness: 500 angstrom +/-20%; 
     Fourth layer 7: nitride (TiN, ZrN), layer thickness: 110 angstrom +/-20%; 
     Fifth layer 8, dielectric: low-refracting materials, n smaller than 1.7, (SiO 2 , Al 2  O 3 , AlSi-oxide, NiSi-oxide, MgF 2 ), Optical thickness: 5550/4 angstrom +/-10%; 
     Adhesive layer 11: Ni, Cr, NiCr (80 weight percent Ni, 20  weight per cent Cr), layer thickness 10 angstrom +/-10%; 
     Backside layer 10: TiN x , layer thickness: 40-150 angstrom. 
     It is a matter of course that such values for the respective layer thickness are selected within the cited layer thickness tolerances, which take into account the interdependence between the individual layer thicknesses and the materials used. 
     In the following, the description of two examples of layer systems follows, whereby the reflection and the transmission were measured in the visible wave range of the light. The results of the measurement are graphically illustrated with curves in the FIGS. 3 and 4. The description of the layer systems uses the reference symbols of the description of FIG. 1. 
     The layer system of a first example is structured as follows: 
     Substrate 1 material: glass, thickness 2 mm, refractive coefficient n=1.52. 
     First layer 4, material: SnO 2 , thickness 170 angstrom, refractive coefficient n=2.05. 
     Second layer 5, material: TiN x , thickness 190 angstrom. 
     Third layer 6, material: SnO 2 , thickness 500 angstrom, refractive coefficient n=2.05. 
     Fourth layer 7, material: TiN x , thickness 130 angstrom. 
     Fifth layer 8, material: Al 2  O 3 , thickness 730 angstrom, refractive coefficient N=1.6. 
     Backside layer 10, material: TiN x , thickness 70 angstrom. 
     The adhesive layer 11 in FIG. 2 is not used in this exemplary embodiment. 
     For this above described layer system of the first example, reflection and transmission were measured in percent, namely for a wavelength range from 400 nm to 700 nm. Subsequently, the measurement results of reflection and transmission are compared to certain wavelengths in a table: 
     
         ______________________________________wavelength     reflection                   transmission(nm)           (%)      (%)______________________________________440            0.48     25.7480            0.64     28.2520            0.61     29.4560            0.40     29.0600            0.30     28.1640            0.29     26.2680            0.32     23.8______________________________________ 
    
     The measurement results, as shown, are graphically illustrated in FIG. 3. On the abscissa 12 of the system of coordinates in FIG. 3 the wavelengths are entered in nm. On the left ordinate 13 of the coordinate system percent values for reflection are entered. On the right ordinate 14 of the coordinate system percent values for transmission are entered. 
     The curves of FIG. 3 reveal clearly that a reflection curve 16 in the core wavelength region of the visible light is extraordinarily low. It lies far under 1%. By that, a desired high antireflective effect has been achieved in surprisingly clear fashion. In the same core wavelength region a transmission curve 15 has relatively high values. 
     The layer system of a second example is characterized as follows: 
     Substrate 1, material: glass, thickness 2 mm, refractive coefficient n=1.52. 
     First layer 4, material: SnO 2 , thickness 170 angstrom, refractive coefficient n=2.1. 
     Second layer 5, material: TiN x , thickness 170 angstrom. 
     Third layer 6, material: SnO 2 , thickness 500 angstrom, refractive coefficient n=2.05. 
     Fourth layer 7, material: TiN x , thickness 110 angstrom. 
     Fifth layer 8, material: SiO 2 , thickness 730 angstrom, refractive coefficient N=1.5. 
     Backside layer 10, material: TiN x , thickness 70 angstrom. 
     No extra adhesive layer 11, shown in FIG. 2 is used in this exemplary embodiment. 
     For this above described layer system of the second example, reflection and transmission were measured in per cent, namely for a wavelength range from 400 nm to 700 nm. Subsequently, the measured results of reflection and transmission are compared to certain wavelengths in a table: 
     
         ______________________________________wavelength     reflection                   transmission(nm)           (%)      (%)______________________________________440            1.22     25.6480            0.26     28.8520            0.24     30.2560            0.26     30.4600            0.29     29.5640            0.31     28.0680            0.34     25.9______________________________________ 
    
     The measured results, as shown, are graphically illustrated as curves in FIG. 4. The abscissa and the ordinates carry the measuring units described in connection with FIG. 3. 
     A reflection curve 18 reveals clearly that reflection has an extreme low point in the region of approximately 500 nm wavelength. By that, a desired high antireflective effect has also been achieved in a convincing manner in this example. A transmission curve 17 has its maximum in the core region of the visible light. 
     The following comments need to be made regarding the transmission curve 15 (FIG. 3) and regarding the transmission curve 17 (FIG. 4): 
     Low transmission values of an attachment disk can be compensated in a simple manner by intensifying the light source, e.g. by turning up the potentiometer in the case of a LCD. 
     The layer systems with which the above commented-on transmission and reflection values were achieved, were manufactured according to the method described in the following: 
     The sputtering was performed with a magnetron in a reactive gas atmosphere. 
     In the following, the left column indicates the sputtering material, the right column the reactive sputter mixture: 
     
         ______________________________________  SnO.sub.2     Ar + O.sub.2  SiO.sub.2     Ar + O.sub.2  Al.sub.2 O.sub.3                Ar + O.sub.2  TiN           Ar + N.sub.2  NiCr          Ar + O.sub.2______________________________________ 
    
     Pressure during the sputtering event: approximately 5×10 -3  mbar. 
     Target material: Sn, Si, Ti, NiCr (80 weight per cent Ni, 20 weight per cent Cr), Al. 
     On a front side of the layer systems toward the observer, a surface resistance of 150 Ohm per square was measured, on a backside of the layer systems a surface resistance of 450 ohm per square. These are relatively low surface resistances. 
     By grounding the surfaces the static charge can be reduced or even eliminated. Thus, the desired antistatic effect is achieved. 
     Although the present invention has been described with reference to a specific embodiment, those of skill in the art will recognize that changes may be made thereto without departing from the scope and spirit of the invention as set forth in the appended claims.