DE19757874A1 - Conductive layer system and its use in electroluminescent arrangements - Google Patents

Abstract

The invention relates to a transparent or semi-transparent conductive layer system consisting of organic and inorganic electrically conductive materials. Said layer system comprises at least two layers, the first layer containing an organic or organometallic electrically conductive polymer which is transparent or semi-transparent in the visible range of the electromagnetic spectrum. The second layer contains at least one electrically conductive inorganic compound or a metal or a metalloid doped accordingly. The inventive layer system forms a multi-layer hybrid electrode for use as a cathode in electroluminescent systems.

Description

State of the art

The present invention relates to an electrical conductive, transparent layer system consisting of at least one electrically conductive organic layer and an electrically conductive inorganic layer the genus of the main claim.

Electroluminescent arrangements (EL) are thereby characterized that they are under application of an electrical Send voltage under current flow light. Such Arrangements are called "light emitting diodes" (LED = light emitting diodes) has been known for a long time. As Direct conversion is called electroluminescence electrical energy in light. This phenomenon comes through different depending on the material used Mechanisms. Generally, inorganic Semiconductors, for example ZnS doped with foreign atoms or GaS connections used. The origin of the Electroluminescence in inorganic semiconductor materials lies in the excitation caused by electron injection  of luminescent centers (for example the doping atoms such as Mn or Tb) in the inorganic guest lattices.

As a material for the anode of an electroluminescent Arrangement is generally indium tin oxide (ITO) or doped tin oxide used. These materials have that Advantage that they are transparent or semi-transparent and therefore are optically transparent to the emitted light. With These metal oxides have surface resistances of up to a few Ohm square realized, the transparency greater than 70% Transmission is. Typical surface resistances of commercially available ITO are in the range of 20-50 Ohm square. Disadvantage of these conductive oxide layers is the relatively high manufacturing price because the layers in Vacuum processes, e.g. B. produced by reactive sputtering will.

It is known from EP 0 686 662 A2 that, instead of transparent metal oxides, electrically conductive, transparent or semitransparent polymers, for example polythiophenes, can be used. The production of thin layers from these polymers is carried out by means of simple, known methods from a solution, such as. B. spin coating, knife coating, casting or printing. It is also known from WO 96/08 047 to use polyaniline (PAN) and poly-3,4-ethylene-dioxythiophene (PEDOT) as the transparent electrode. Other similar systems are described in EP 302 304 A1 based on polypyrroles and in EP 440 957 A1 based on polythiophenes. The disadvantage of all these polymeric transparent electrodes is that the transparency of the layers is significantly lower than that of the metal oxide electrodes that are usually used. With fairly acceptable values for the transparency of approximately 50% transmission, surface resistances of more than 100 ohm square can be achieved at best. This makes it impossible to use industrially usable light emitting devices such as. B. in electroluminescent systems containing inorganic or organic charge transport and luminescent compounds with electrodes based on such polymeric systems. Since currents flow in light-emitting arrangements, a voltage drop occurs across the electrode in large-scale arrangements, which leads to visible inhomogeneities in the light emission. A proposal for a solution through the use of a hybrid inorganic-organic system was proposed by P.Gómez-Romero and M. Lira-Cantú in: Advanced Materials 1997, 9, pp. 144-147. An electrically conductive polypyrrole is reacted chemically or electrochemically with a phosphoromolybdate anion ([PMo ₁₂ O ₄₀ ] ^3- ) and the reaction product thus obtained is used as an electrode.

Advantages of the invention

The conductive layer system according to the invention consists of a combination of at least two layers, one Layer an organic or organometallic electrical conductive, in the visible range of the electromagnetic Spectrum of transparent or semi-transparent polymer contains and a second layer at least one electrical conductive inorganic compound or a metal or a contains correspondingly doped semimetal. Both that let organic system as well as the inorganic system out of solutions using methods such as Deposit, spin, pour, print or knife. By the physical combination of an organic with a inorganic system will be an excellent one  Surface resistance of the layer system constructed in this way achieved.

In a particularly preferred embodiment, the first Layer an electrically conductive, transparent or semi-transparent polymer used. In particular are Polymers from the compound classes of polythiophenes, Polypyrroles, polyanilines, polyacetylenes or their substituted derivatives preferred.

Materials are advantageously used for the second layer from the group Cu, Ag, Au, Pt, Pd, Fe, Cr, Sn, Al as well their alloys or conductive carbon used so that a this layer has high electrical conductivity.

The inorganic layer is preferably in the form of a Openwork structure forming openwork lattice structure upset. The mean conductivity of the inorganic layer and the entire layer system increases without the transparency of the layer system suffers significantly.

In a preferred embodiment, this becomes conductive Layer system as anode instead of ITO in one Electroluminescent arrangement consisting generally from a transparent substrate, a first electrode, the anode, consisting of the conductive according to the invention Layer system, an electroluminescent element and a second electrode, the cathode, is used. Of course, other applications in areas which are also electrodes with low sheet resistances require, possible, for example in LCD technology, microelectronics, sensor technology etc.  

The first layer is advantageously for electroluminescent element arranged adjacent and the second layer is on top of the first layer the transparent substrate.

In a preferred embodiment, the width is individual grid elements forming the conductor tracks Lattice structure 5-500 µm, so that the emitting areas of the inorganic system through human eyes can be resolved. This appears to the viewer Overall system as a homogeneous, emitting surface.

In a further preferred embodiment is above the Transparent substrate arranged a diffuser. this will thereby allowing the light emitting Whole system shown or illustrated luminous Areas, such as symbols of a clock face, Display elements or displays are so small that they lie between the conductive inorganic areas. This means that the track spacing can also be selected that an elaborate miniaturization of the same is not necessary is.

In a further advantageous embodiment, the Width of the individual grid elements of the conductor tracks forming lattice structure more than 300 microns, so this Dimensions can be resolved by the human eye. These are advantageously electroluminescent Arrangements with the electrode according to the invention in the Layer structure according to the invention in lighting areas used the symbols or signs correspond to them for example with display elements or on screens or used in display technology.  

drawing

The invention is illustrated by the drawings below explained in more detail. Show it

Fig. 1 shows an electroluminescent device according to the invention, Fig. 2 shows another embodiment of the electroluminescent arrangement and Fig. 3 a still further embodiment.

Description of the embodiments Embodiment 1

A polymeric layer system, for example based of polythiophene derivatives, as described in EP 0 686 662 A2 with a squeegee onto a substrate, for example, a glass plate. The The wet layer thickness of the polymeric layer is approximately 50-100 µm. The layer is after the solvent has evaporated annealed in an oven at about 2000 Celsius. The reached Sheet resistance is between 100 and 300 ohm square. Then using a screen printing process Printed conductor tracks made of conductive silver. To that prepared electrode is, for example in Screen printing process, an inorganic electroluminescent element, for example based printed on ZnS doped with Mn or Tb. Subsequently becomes a counter electrode, for example made of aluminum or MgAl applied.

In further exemplary embodiments, the conductor tracks exist according to the invention from structured organic conductive Layers whose conductivity is along the conductor tracks  through inorganic, also structured, very thin Conductor tracks is reinforced. The light transmits through the transparent or semi-transparent organic Areas. For applications in the area of displays, the organic layer in structures with typical Structure sizes divided from 50 to 1000 microns. But there are even structures with dimensions of more than one Millimeters possible. The conductivity in the area of this Application is typically between 200 to 10,000 Ohms / square. 500 to 3000 are particularly preferred Ohms / square. The layer thicknesses range from 0.1 to 1 µm for the organic layer. The inorganic layer preferably has layer thicknesses in the range from 0.01 to 100 μm on.

Embodiment 2

5 g of the solution described in EP 0 686 662 A2, the 3,4- Contains polyethylene dioxythiophene while stirring with 5 ml Isopropanol, 400 mg glycerin, 25 mg Glycidyloxypropyltrimethoxysilane, 400 mg of a 5% aqueous solution of a surfactant and 500 mg of a 1% aqueous solution of an ammonium polyacrylate. The the resulting solution was placed on a PET film at 800 rpm spun on and then in for 5 hours at 140 ° C annealed in an oven. The absorption of the layers is less than 10% in the visible spectral range. Of the Surface resistance is approximately 1.5 kOhm / square. On the transparent film coated in this way becomes conductor tracks Printed conductive silver with dimensions of approx. 2 mm that the border light-emitting field and for contacting to serve. The light emitting field has dimensions of 40 × 80 square millimeters. The next layer was a layer consisting of an encapsulated phosphor (ZnS: Cu, medium  Particle size: 28 µm) from Osram Silvania in a binder applied by screen printing. Was on this layer another layer printed, made of barium titanate and a binder. At the end there was a counter electrode consisting of printed conductive silver. When creating one The system emits AC voltage (100 volts, 400 Hertz) blue light. The color coordinates are at X = 0.15, Y = 0.16. The intensity is about 50 Cd / m2. The Light emission is homogeneous across the light emitting field distributed.

Embodiment 3

Another layer system was used for comparison Indium tin oxide (ITO) coated PET substrate applied. The layer sequence corresponds to embodiment 2 from this system at an operating voltage of 100 volts and 400 Hertz emitted light has the same intensity and the same color coordinates as in the embodiment 2nd

In Fig. 1, the basic structure of the electroluminescent device 10 of the invention using a layer system 13 according to the invention 14 is shown as an electrode.

The electroluminescent arrangement 10 consists of an electrode, the cathode 11 , for example of MgAl or other materials used in electroluminescent arrangements. The electroluminescent element 12 arranged adjacent to it consists, for example, of ZnS doped with Mn or Tb. All other known inorganic electroluminescent materials can of course also be used, e.g. B. correspondingly doped GaAs or InS connections. The adjacent layer 13 consists of an inorganic layer which is designed as a grid structure forming conductor tracks. It consists of conductive silver or another electrically conductive compound, for example Cu, Ag, Au, Cr, their alloys or conductive carbon. A layer 14 made of an electrically conductive, transparent or semi-transparent polymer, for example a polythiophene or a polypyrrole, is arranged adjacent to this. A transparent substrate 15 , for example made of glass, is arranged adjacent to this.

The structures or the conductor tracks of the electrically conductive inorganic layer 13 are very fine. The structure size, ie the width of the conductor tracks, is designated by X in FIG. 1. It is in the range of 5-500 µm. As a result, the non-emitting areas are not resolved by the human eye and the viewer sees the overall system as a homogeneously emitting surface. With this arrangement, larger elements can be realized, for example, on screens and displays.

The structure of the electroluminescent arrangement in FIG. 2 is identical to that of FIG. 1, except that the areas between the conductor tracks of the layer 13 are larger. In addition, a dial 16 consisting of transparent and non-transparent areas is attached adjacent to the transparent substrate 15 such that the non-transparent areas of the dial correspond to the orders of magnitude of the conductor tracks in layer 13 . Of course, the exemplary embodiment is not restricted to dials, but all display elements or displays, whose luminous symbols are in the order of magnitude of the transparent areas between the conductor tracks of the layer 13 , can be realized with this arrangement.

The structure of the electroluminescent arrangement in FIG. 3 is identical to that of FIG. 1, except that the lattice structures or conductor tracks in layer 13 have a width X of more than 300 μm. They can thus be resolved by the human eye, which no longer sees a homogeneous total emitting area. Therefore, in addition to the transparent substrate 15, a diffuser 17 is attached adjacent, which homogenizes the distribution of the emitted light. With this structure, large-area display elements and displays can therefore also be implemented.

Of course, the exemplary embodiments are not a limitation of the invention, rather it is also possible, for example, to interchange the order of the layers 13 and 14 .

Claims (19)

1. Conductive layer system, in particular for a transparent or semi-transparent electrode of an electroluminescent arrangement, consisting of at least two layers, characterized in that the first layer is an organic or organometallic electrically conductive polymer that is transparent or semi-transparent in the visible range of the electromagnetic spectrum and the second layer contains at least one electrically conductive inorganic compound or a metal or a correspondingly doped semimetal. 2. Conductive layer system according to claim 1, characterized characterized in that the first layer selected a polymer from the group polythiophene, polypyrrole, polyaniline, Polyacetylene or its optionally substituted derivatives contains. 3. Conductive layer system according to claim 1 or 2, characterized characterized in that the thickness of the first layer is 0.05-10  µm, in particular 0.1-1 µm. 4. Conductive layer system according to claim 1, characterized characterized in that the second layer is a material selected from the group Cu, Ag, Au, Pt, Pd, Fe, Cr, Sn, Al contains their alloys or conductive carbon.   5. Conductive layer system according to claim 1 or 4, characterized characterized in that the second layer is a conductor tracks forming openwork lattice structure. 6. Conductive layer system according to one of the preceding Claims, characterized in that the averaged Surface resistance of the layer system <300 ohm square is. 7. Electroluminescent arrangement with a conductive Layer system according to one of the preceding claims, which is an electroluminescent element, a transparent one Substrate, a first electrode and a second electrode are provided, characterized in that the second Electrode is formed by the conductive layer system. 8. Electroluminescent arrangement according to claim 7, characterized characterized in that the first layer for electroluminescent element is arranged adjacent and that the second layer is on top of the first layer the transparent substrate. 9. Electroluminescent arrangement according to claim 7, characterized characterized in that the second layer for electroluminescent element is arranged adjacent and that the first layer is on top of the second layer the transparent substrate. 10. Electroluminescent arrangement according to claim 7, characterized in that the first and second layers are arranged in a layer plane.   11. Electroluminescent arrangement according to claim 7 thereby characterized in that the second layer is a conductor tracks forming openwork lattice structure. 12. Electroluminescent arrangement according to claim 11, characterized in that the width of each Lattice elements of the lattice structure 5-500 forming conductor tracks  µm is. 13. Electroluminescent arrangement according to claim 12, characterized in that the width of each Lattice elements of the grid structure forming conductor tracks is more than 300 µm. 14. Electroluminescent arrangement according to claim 7, characterized in that over the transparent substrate a display element with transparent and absorbent Areas is arranged. 15. Electroluminescent arrangement according to claim 14, characterized in that over the transparent substrate a diffuser is arranged. 16. Electroluminescent arrangement according to claim 7, characterized in that over the transparent substrate a display element or a screen with transparent and absorbing areas and adjacent to it a diffuser is arranged. 17. Electroluminescent arrangement according to claim 7, characterized in that over the transparent substrate a display element or a screen with transparent and absorbent areas is arranged.   18. Electroluminescent arrangement according to claim 17, characterized in that over the transparent substrate a diffuser is arranged. 19. Electroluminescent arrangement according to one of the Claims 7 to 13, characterized in that the distances between the conductor tracks that form a lattice structure second layer form areas that correspond to the symbols or Illuminated areas representing characters or shaped surfaces the arranged on the transparent substrate Display elements or a screen.