DE112015003561B4 - organic component - Google Patents

Abstract

Organic component comprising
- an organic layer stack (3) with a multiplicity of organic functional layers (30) and a top surface (3a),
- at least one reflective electrode (52) which is attached to the top surface (3a) of the organic layer stack (3),
- at least one electrode track (2) having a thickness in a range of less than 100 µm, and
- An electrode layer (1), which is transparent, wherein
- the at least one electrode track (2) and the electrode layer (1) are attached to a side of the organic layer stack (3) facing away from the reflective electrode (52),
- the electrode track (2) is electrically connected exclusively by means of the electrode layer (1),
- all side surfaces (2b) and a top surface (2a) of the electrode track (2) facing away from the electrode layer (1) are completely covered by the organic layer stack (3) and directly adjoin the organic layer stack (3) and the organic layer stack (3) with the at least one electrode track (2) is electrically conductively connected.

Description

The pamphlets WO 2008/040288 A2 , WO 2008/087192 A1 and WO 2010/025696 A2 each describe an organic component and a method for producing an organic component. The pamphlet DE 103 24 880 B4 describes a method for producing OLEDs, the publication DE 10 2008 045 948 A1 describes a method for producing an organic radiation-emitting component and an organic radiation-emitting component.

One problem to be solved is to specify an organic component with a durable organic layer stack and current distribution structures that are easy to produce.

An organic component with the features of claim 1 is specified. In the present case, the organic component can be, for example, an organic optoelectronic element that is provided for the emission and/or detection of electromagnetic radiation. For example, the organic component is an organic light-emitting diode.

In accordance with at least one embodiment of the organic component, the latter comprises an organic layer stack with a multiplicity of organic functional layers and a top surface. The multiplicity of organic functional layers includes, in particular, an active area which is provided for the emission and/or for the detection of electromagnetic radiation.

The organic layer stack has a main extension plane in which it extends in lateral directions. Perpendicular to the main extension plane, in the vertical direction, the organic layer stack has a thickness. The thickness of the organic layer stack is small compared to the maximum extension of the organic layer stack in a lateral direction. A main plane of the organic layer stack forms the top surface of the organic layer stack.

In accordance with at least one embodiment of the organic component, the latter further comprises at least one reflective electrode which is attached to the top surface of the organic layer stack. The reflective electrode is preferably designed to be reflective for the electromagnetic radiation emitted and/or detected by the organic layer stack. Here and below, “reflective” can mean that 90% or more, preferably 95% or more, of the electromagnetic radiation emitted and/or detected by the organic layer stack is reflected by the reflective electrode. In particular, it is possible for the reflecting electrode to have a reflection coefficient of at least 60%, preferably at least 80% and particularly preferably at least 90% for the electromagnetic radiation emitted and/or detected by the organic layer stack. For example, the reflective electrode may be formed of an electrically conductive material such as aluminum and/or silver.

Here and in the following, “electrically conductive” means, for example, a material that has an electrical conductivity of at least 10 ² S/m. Accordingly, if a material is "electrically conductively connected" to a second material, an electrically conductive connecting material is arranged between the two materials to be connected and/or one of the two materials to be connected is electrically conductive and directly adjacent to the second material to be connected .

In accordance with at least one embodiment, the organic component comprises at least one electrode track. The at least one electrode track is used for improved current distribution. The at least one electrode track is therefore a current distribution structure. In other words, the spatial distribution of the current injected into the organic layer stack along the organic layer stack is improved and preferably homogenized by means of the at least one electrode track.

The electrode track can be designed to be radiation-impermeable. In other words, the at least one electrode track can be formed from a material that reflects and/or absorbs at least 90% of the electromagnetic radiation impinging on the at least one electrode track. For example, the at least one electrode track reflects and/or absorbs at least 90% of the electromagnetic radiation emitted and/or detected by the organic layer stack in areas that are directly downstream or upstream of the at least one electrode track in the vertical direction. In particular, it is possible here and below for a “radiation-impermeable” material for the electromagnetic radiation emitted and/or detected by the organic layer stack to have a transmittance of at most 40%, preferably at most 20% and particularly preferably at most 10%.

According to at least one embodiment of the organic component, this further comprises an electrode layer which is transparent to the the organic layer stack emitted and / or absorbed electromagnetic radiation is formed. For example, at least 90%, preferably at least 95%, of the electromagnetic radiation emitted and/or absorbed by the organic layer stack is transmitted through the material of the electrode layer. In particular, it is possible that a “transparent component” here and below means that the electromagnetic radiation emitted and/or detected by the organic layer stack has a transmittance of at least 50%, preferably at least 70% and particularly preferably at least 80% . The electromagnetic radiation generated and/or absorbed in the organic layer stack is preferably coupled out or coupled in via the electrode layer. Light emitted in the direction of the reflecting electrode is reflected by the latter and then also emitted in the direction of the electrode layer.

The electrode layer is formed from an electrically conductive material. For example, the electrode layer can be formed with a transparent oxide and/or a transparent conductive polymer. The at least one electrode track and the electrode layer are preferably in direct electrical contact with one another.

The extent of the electrode layer in at least one spatial dimension is preferably significantly greater than the extent of the electrode track in the same spatial direction. For example, the extent of the electrode track along at least one lateral spatial direction is at most 10%, preferably at most 5%, of the extent of the electrode layer along the same lateral spatial direction. The electrode track is, for example, a thin electrical conductor that has an elongate dimension, while the electrode layer can be applied over the entire surface of the organic component. The at least one electrode track preferably has greater electrical conductivity, preferably at least twice the electrical conductivity, of the electrode layer along at least one lateral direction.

In accordance with at least one embodiment of the organic component, the at least one electrode track and the electrode layer are attached to a side of the organic layer stack that is remote from the reflective electrode. It is possible here for the organic layer stack to be electrically conductively connected to the reflective electrode and/or the electrode layer and the at least one electrode track. For example, the reflective electrode can directly adjoin the top surface of the organic layer stack and/or be in direct electrical contact with it. It is also possible for the electrode layer and/or the at least one electrode track to directly adjoin a bottom surface of the organic layer stack that is remote from the top surface and/or to be in direct electrical contact with it. In this case, the bottom surface of the organic layer stack can serve as a light passage surface. In other words, the bottom area of the organic layer stack can correspond to or form a luminous area of the organic component.

For example, the reflective electrode is the cathode of the organic layer stack, while the at least one electrode track and the electrode layer can be the anode. In other words, charge carriers can be injected into the organic layer stack or extracted from it by means of the reflective electrode and/or the at least one electrode track and the electrode layer.

In accordance with at least one embodiment of the organic component, the at least one electrode track is electrically connected exclusively by means of the electrode layer. This means that only the electrode layer, but not the electrode track, is electrically conductively connected directly to an external connection point. The fact that a component is "directly electrically conductive" connected to a connection point means here and in the following that only a material with an electrical conductivity that corresponds at least to the electrical conductivity of the material of the connection point or the component is arranged between the component and the connection point is. In particular, it is possible for the electrode layer to be in direct contact with the connection point. For example, the electrode layer is electrically connected by means of a contact, while the electrode track is not directly electrically conductively connected to this contact.

In accordance with at least one embodiment of the organic component, all of the side surfaces and a top surface of the at least one electrode track that faces away from the electrode layer are completely covered by the organic layer stack and/or an insulating material. In this case, the areas of the at least one electrode track that are not completely covered by the organic layer stack and/or an insulating material are covered by the electrode layer. In other words, the at least one electrode track is in particular hermetically sealed and is not exposed at any point. The at least one electrode track is therefore not freely accessible from the outside and not directly electrically contacted, but electrically connected via the less conductive electrode layer.

According to at least one embodiment of the organic component, this comprises an organic layer stack with a multiplicity of organic functional layers and a top surface, at least one reflective electrode which is attached to the top surface of the organic layer stack, at least one electrode track and a transparent electrode layer. The at least one electrode track and the electrode layer are attached to a side of the organic layer stack that is remote from the reflective electrode. The electrode track is electrically connected solely by means of the electrode layer. In other words, the electrode track is not directly electrically conductively connected to a contact and is also not freely accessible from the outside. Furthermore, the electrode track is electrically conductively connected only directly to the electrode layer. All side surfaces and a top surface of the electrode track facing away from the electrode layer are completely covered by the organic layer stack and/or an insulating material.

In the case of the organic component, the idea is pursued in particular of providing electrode tracks that are protected from the surrounding air and which homogenize the current distribution along the electrode layer. In particular, a transparent electrode layer has the disadvantage that the current present drops sharply along the electrode layer due to the low electrical conductivity. The current distribution can be improved by means of electrode tracks, which have a high electrical conductivity, as a result of which an organic component with a visually better impression can be made available.

However, the problem arises here that the electrode tracks can be formed from a material which, in the event of direct contact with the air surrounding the organic component, can absorb water and would conduct this into the organic functional layers of the organic component. This would lead to a short circuit and/or destruction of the organic component. Sealing off the electrode tracks from the outside can prevent water from penetrating and thus destroying the organic layer stack. Surprisingly, it has been shown that it is not necessary to electrically contact the electrode tracks directly from the outside. Indirect electrical contacting by means of the electrode layer is sufficient for homogenizing the current distribution. Electrode tracks that are sealed off from the outside, which are buried in the component and are not led out of it at any point, can thus be provided as current distribution structures. An additional encapsulation of the electrode tracks is therefore not necessary since this encapsulation is provided together with the encapsulation of the other components of the organic component. The electrode tracks are also protected by the components of the organic component.

In accordance with at least one embodiment of the organic component, the material of the transparent electrode layer has a lower electrical conductivity than the material of the electrode track. For example, the transparent electrode layer is formed of a transparent conductive oxide such as indium tin oxide. The electrical conductivity of such a material can be in the range of 10 ² to 10 ³ S/m. The electrode track can be formed with silver, copper and/or aluminum, for example. The electrical conductivity of these materials is at least 10 ⁶ S/m. The electrical conductivity of the material of the electrode tracks is therefore several orders of magnitude higher than the electrical conductivity of the material of the transparent electrode layer.

In accordance with at least one embodiment of the organic component, the at least one electrode track is not freely accessible from the outside. The side surfaces, the top surface and/or the bottom surface of the electrode track are thus completely covered either by the organic layer stack, by the electrode layer or by an electrically insulating material. The electrically insulating material can be a substrate or an encapsulation. It is possible here for the electrode track to be hermetically sealed from the outside. The hermetic sealing can take place in particular by means of the organic layer stack and the electrode layer.

According to at least one embodiment of the organic component, the latter further comprises an encapsulation, which is designed to be electrically insulating. The encapsulation can completely cover all of the outer surfaces of the organic layer stack that are remote from the electrode layer. This means that the encapsulation can cover the bottom surface and all side surfaces of the organic layer stack connecting the bottom surface and the top surface. Furthermore, it is possible for the encapsulation to completely cover the reflective electrode. The encapsulation directly adjoins the electrode layer at least in places. The encapsulation protects the components of the organic component, such as the organic layer stack and/or the at least one electrode track, from moisture and atmospheric influences.

The encapsulation can be, for example, a glass body and/or an electrically insulating layer. For example, the encapsulation is a glass cover that is placed over the organic layer stack. Furthermore, the encapsulation can be a cavity cover, which can be formed from glass or a getter material in glass. When using a getter material in the encapsulation, the idea of removing moisture from the organic layer stack by means of sorption is pursued in particular. The encapsulation can therefore both protect the organic layer stack from moisture from the outside and also remove moisture present in the organic layer stack from the latter.

The encapsulation can also be a so-called thin-film encapsulation. The encapsulation can then be produced by deposition processes such as chemical vapor deposition, physical vapor deposition, sputtering, atomic layer deposition (ALD) or other deposition methods. In particular, the encapsulation can comprise at least one ALD layer (ALD: Atomic Layer Deposition) which is produced using an ALD method. This means that at least this layer of the encapsulation is formed using an ALD method. Such ALD layers are, for example, from the US publications U.S. 2011/0049730 A1 and US 2012/0132953 A1 known.

A layer of an encapsulation produced using an ALD method can be clearly distinguished from layers produced using alternative methods such as, for example, conventional CVD (Chemical Vapor Deposition), using electromicroscopic examinations and other analysis methods of semiconductor technology. The feature that the encapsulation is an ALD layer is therefore a physical feature that can be detected on the finished organic component. In accordance with at least one embodiment of the organic component, at least one electrode track has a width and a length running perpendicular to the width within the scope of the manufacturing tolerances. The length of the electrode track is at least twice, preferably at least five times, the width of the electrode track. Accordingly, the electrode track can be an elongate structure. For example, the width of the at least one electrode track is at least 2 μm, preferably at least 20 μm, while the length of the at least one electrode track is at least 5 cm, for example. For example, the width can be up to 1000 μm, preferably at most 100 μm, and the length can be up to 100 cm.

In accordance with at least one embodiment of the organic component, there is a single electrode track which is formed coherently in a plan view. Here and in the following, a “top view” is to be understood as meaning a top view from the direction of the bottom surface of the organic layer stack. It is therefore possible that a single electrode track, which is, for example, elongate, already leads to an improvement in the current distribution. The single electrode track preferably covers at most 10%, particularly preferably at most 5%, of the light passage area of the organic component. This results in a pleasant visual appearance, since only a small area of the light passage surface is covered by the radiation-opaque electrode track.

In accordance with at least one embodiment of the organic component, the single electrode track completely encloses at least one singly connected area in a plan view. It is also possible for the single electrode track to enclose a multiplicity of simply connected surfaces in a plan view. For example, the single electrode track is designed in the shape of a frame. The single electrode track can, for example, completely enclose a single rectangular or hexagonal area. Furthermore, the single electrode track can completely enclose a plurality of rectangular and/or hexagonal areas. Accordingly, the single electrode track can have no beginning and no end.

In accordance with at least one embodiment of the organic component, the electrode layer is formed with a transparent conductive oxide. The transparent conductive oxide can be, for example, indium tin oxide, fluorine tin oxide, aluminum zinc oxide and/or antimony tin oxide. In this case, the electrode layer serves to make electrical contact with the organic functional layer stack.

All side surfaces of the organic component and the top surface of the electrode track are completely covered by the organic layer stack. In other words, the electrode track is directly adjacent to the organic layer stack and is surrounded by the layers of the organic layer stack. A bottom surface of the electrode track then borders on the electrode layer and is electrically conductively connected to it.

In accordance with at least one embodiment of the organic component, the top surface of the at least one electrode track is directly adjacent to a radiation-transmissive substrate. The radiation-transmissive substrate can be, for example, a translucent or transparent substrate. For example, 80% or more of the electromagnetic radiation emitted by the organic layers is transmitted through the material of the radiation-transmissive substrate. In particular, the substrate can have a transmission coefficient of at least 60%, preferably at least 80% and particularly preferably at least 90% for the electromagnetic radiation emitted and/or detected by the organic layers. The substrate can be formed, for example, with glass or a plastic that can be flexible. The radiation-transmissive substrate can also be a film that is formed with a plastic, for example.

The radiation-transmissive substrate preferably has a low absorption coefficient. Less than 10%, particularly preferably less than 5%, of the electromagnetic radiation impinging on the substrate is preferably absorbed. The radiation that is not transmitted through the substrate can thus, for example, be reflected by the reflecting electrode and be transmitted when it strikes the radiation-transmissive substrate again.

All side surfaces and the top surface of the electrode track are completely covered by the material of the radiation-transmissive substrate and/or the material of the electrode layer. For example, the at least one electrode track is in direct contact with the radiation-transmissive substrate. Furthermore, the at least one electrode track and/or the radiation-transmissive substrate can be in direct contact with the electrode layer. It is possible here that the at least one electrode track is not in direct contact with the organic layer stack and is only electrically conductively connected to the electrode layer.

In accordance with at least one embodiment of the organic component, the at least one electrode track is applied using a printing process. For example, the at least one electrode track is applied using an ink jet printing method or a screen printing method. An electrode track applied by means of a printing process is characterized in particular by its small thickness or width. For example, the width and/or the thickness of the electrode tracks running perpendicularly to the width and length within the scope of manufacturing tolerances can be in a range of less than 100 μm, preferably in a range of at least 1 μm to at most 3 μm.

According to at least one embodiment of the organic component, there is a multiplicity of electrode tracks. The electrode tracks are arranged laterally spaced from each other. For example, the electrode tracks are elongated conductor tracks that are arranged parallel to one another within the scope of manufacturing tolerances. In this case, it is possible for the electrode tracks to each have different lengths. In this case, the length of the electrode tracks can correspond to at least 90% of the extension of the organic layer stack in the direction of the length of the electrode tracks.

A method, not according to the invention, for producing an organic component is also specified. An organic component described here can preferably be produced by means of a method described here. This means that all features disclosed for the method are also disclosed for the organic component and vice versa.

In accordance with at least one embodiment of the method, a substrate designed to be radiation-transmissive and having a mounting area is first provided. The radiation-transmissive substrate can be a film, for example. For example, in the present case it is a plastic film or a transparent PT film. The substrate can also be formed with glass and/or a plastic. The substrate preferably has low absorption.

In accordance with at least one embodiment of the method, the electrode layer, the at least one electrode track, the organic layer stack and the reflective electrode are arranged on the substrate.

The at least one electrode track is applied using a printing process. The printing method can be an inkjet printing method, for example. Here, the surface to be printed is sprayed with drops of a coating solution containing conductive particles. The size of the drops is, for example, at most 100 pl, preferably at most 40 pl. The conductive particles can be smaller than 1 μm, for example. Metal particles such as silver particles, aluminum particles, copper particles or particles of other metals are used as conductive particles. It is also possible for a screen printing method to be used to print the at least one electrode track comes. The conductive particles are available in a printing paste that is applied as in conventional screen printing.

The production of the electrode track by means of printing has the particular advantage that the tracks can be produced much more cheaply compared to previous methods. In particular, fewer process steps are necessary, since there is no need for the complex production of a layer that is applied over a large area and then has to be structured by means of photolithography or an etching process. This results in less material loss, and thus a cost saving, and, for example, an advantageous omission of a high-vacuum environment.

The printing process also enables the production of very thin conductor tracks. For example, the width and/or the thickness of the electrode tracks running perpendicularly to the width and to the length within the scope of manufacturing tolerances can be in a range of less than 100 μm.

• Die 1A, 1B und 1C zeigen Ausführungsbeispiele eines hier beschriebenen organischen Bauteils anhand schematischer Schnittdarstellungen.
• Die 2A und 2B zeigen Ausführungsbeispiele eines hier beschriebenen organischen Bauteils anhand schematischer Aufsichten.
• Die 3A, 3B, 3C, 4A, 4B, 5A und 5B zeigen Leuchtdichteverteilungen von Ausführungsbeispielen von hier beschriebenen organischen Bauteilen.

The organic component described here and the method for producing an organic component described here are explained in more detail below on the basis of exemplary embodiments and the associated figures.

• the 1A , 1B and 1C show exemplary embodiments of an organic component described here using schematic sectional views.
• the 2A and 2 B show exemplary embodiments of an organic component described here on the basis of schematic views.
• the 3A , 3B , 3C , 4A , 4B , 5A and 5B show luminance distributions of exemplary embodiments of organic components described here.

Elements that are the same, of the same type or have the same effect are provided with the same reference symbols in the figures. The figures and the relative sizes of the elements shown in the figures are not to be regarded as being to scale. Rather, individual elements can be shown in an exaggerated size for better representation and/or for better understanding.

Based on the schematic sectional views of 1A a first exemplary embodiment of an organic component described here is explained in more detail. Only part of the organic component is shown here. The jagged structure on the right side of the organic component is intended to show that the organic component does not end at this point.

The organic component comprises an organic layer stack 3 with a multiplicity of organic functional layers 30, a top surface 3a, a bottom surface 3c and side surfaces 3b. A reflective electrode 52 is attached to the top surface 3a of the organic layer stack. The reflective electrode 52 completely covers the top surface 3a of the organic layer stack 3 . However, it is also possible--in contrast to what is shown in the figures--for the reflective electrode 52 to cover the top surface 3a of the organic layer stack 3 only in places.

The bottom surface 3c of the organic layer stack 3 serves as a light passage surface. This means that the electromagnetic radiation generated and/or detected in the organic layer stack 3 is preferably coupled out or in through the bottom surface 3c. A transparent electrode layer 1, which can be formed with a transparent conductive oxide, for example, is attached to the bottom surface 3c.

A plurality of electrode tracks 2 are attached to the bottom surface 3c of the organic layer stack 3 between the electrode layer 1 and the organic layer stack 3 . The side surfaces 2b and the top surface 2a of each electrode track 2 are completely covered by the organic layer stack 3 or by the encapsulation 4 . The electrode tracks 2 are not connected to one another laterally. For example, the electrode tracks 2 of the exemplary embodiment shown are elongated conductor tracks that protrude into the plane of the paper. Here and in the following, the lateral direction runs along one of the main extension directions of the electrode layer 1 or of the substrate 10.

The electrode layer 1 is electrically contacted laterally by means of a contact 54 . The electrode tracks 2 are only electrically connected via the electrode layer 1 . For this purpose, the electrode layer 1 protrudes laterally beyond the organic layer stack 3 and is freely accessible there in places. Furthermore, the electrode layer 1 adjoins a substrate 10 designed to be transparent to radiation, which is located on the side of the electrode layer 1 facing away from the organic layer stack 3 .

According to the schematic sectional view of 1B a further exemplary embodiment of an organic component described here is explained. The embodiment shown here differs from the embodiment of the 1A in that there is no substrate 10 on the organic component. The organic component is therefore free of a substrate. Further below separates the embodiment of 1B from the embodiment of 1A due to the presence of an additional metallization 51 on the electrode layer 1. The metallization 51 is used for better electrical contacting of the electrode layer 1.

According to the schematic sectional view of 1C a further exemplary embodiment of an organic component described here is explained in more detail. In the exemplary embodiment shown here, the electrode tracks 2 are applied directly to the substrate 10 . The cover surfaces 2a of the electrode tracks 2 are thus in direct contact with the material of the substrate 10.

The side surfaces 2b of the electrode tracks 2 can be completely covered by the material of the substrate 10 and/or by the material of the electrode layer 1. The electrode layer 1 also borders directly on the organic layer stack 3. The electrode tracks 2 are therefore not directly electrically connected to the organic layer stack 3, but only by means of the electrode layer 1. The electrode tracks 2, however, continue to serve to improve the current distribution along the electrode layer 1.

According to the schematic supervision of 2A a further exemplary embodiment of an organic component described here is explained in more detail. In this case, the top view is from the direction of the bottom surface 3c of the organic layer stack 3. The electrode track 2 is designed to be continuous in the top view of the exemplary embodiment shown. The electrode track 2 encloses a plurality of simply connected areas, each of which has the shape of a hexagon. The organic component has the shape of a circle when viewed from above. The electrode layer 1 is free of the organic layer stack 3 on the outer circular ring surrounding the organic layer stack 3 and can be electrically contacted by means of a contact 54 .

According to the schematic supervision of 2 B a further exemplary embodiment of an organic component described here is explained in more detail. the 2 B serves only to explain the structure of the organic component according to 1A . In the 2 B the region in which the organic layer stack 3 with the organic functional layers 30 is arranged is shown in more detail. The organic layer stack 3 is located in the middle of the organic component and is surrounded on the side surfaces 3b by the uncovered areas of the annular electrode layer 1. The bottom surface 3c, which can be seen in the top view, serves as the luminous surface of the organic component.

According to the luminance distributions of 3A , 3B and 3C further exemplary embodiments of an organic component described here are explained in more detail. The figures each show the simulated luminance distribution of an organic component according to the exemplary embodiments 2A and 2 B . The lateral extension in the respective spatial dimension is given in arbitrary units on the x-axis and the y-axis. The luminance is given in units of cd/m ² . On the right side of the 3A the gray scale assigned to the respective luminance is shown.

For the simulation of the luminance distribution, the current distribution of the respective organic component was determined numerically using the finite element method. The luminance distribution results from a subsequent convolution of the simulated current distribution with a known current-luminance characteristic of an organic component. For the simulations, it was also assumed in each case that the uncovered areas of the electrode layer 1 are electrically contacted over the entire surface. In other words, the contact 54 covers all areas of the electrode layer 1, which is not of the organic layer stack 3 and / or - in the 2A and 2 B not shown - encapsulation 4 are covered.

The luminance distributions of the 3A , 3B and 3C associated organic components differ as follows. The organic component according to 3A has electrode tracks 2 which are not exclusively contacted via the electrode layer 1 . The electrode tracks 2 of 3A are thus directly electrically contacted, for example. In comparison, the 3B an organic component with electrode tracks 2, which are contacted exclusively via the transparent conductive material of the electrode layer 1. In the 3C shows the luminance distribution of an organic component in which the electrode tracks 2 are not electrically contacted. That of the luminance distribution of the 3C The underlying organic component accordingly has no electrode tracks 2 as current distribution structures.

In the 3A , 3B and 3C In each case an increased luminance can be seen on the luminous surface at the edge regions of the organic layer stack 3 located near the side surfaces 3b. This can be explained by the increased current density on the side surfaces 3b due to the spatial proximity to the electrical contacting 54. The luminance is minimal in the center of the organic component.

The presence of electrically connected electrode tracks 2 in the 3A and 3B leads compared to 3C to a homogenization of the luminance distribution. The luminance distributions of 3A and 3B have the same homogeneity. In other words, the transition between the edge regions of the organic layer stack 3 with high luminance and the center of the organic component with low luminance is in the 3A and 3B essentially the same. In addition, the organic components according to the 3A and 3B an almost equal difference in the maximum luminance and the minimum luminance. Only the absolute luminance of the organic component is reduced in the organic component 3B compared to that 3A . This can be explained by the lower conductivity of the material of the transparent electrode layer 1 and thus a lower current density at the electrode tracks 2.

The luminance distribution of the organic component according to the 3C is reduced and the luminance is much more inhomogeneous than that of the organic components according to 3A and 3B . This can also be seen from the greater variation in the quantitative luminance units shown at the right-hand side of the 3C , can be removed. While at the 3A and 3B there is a variation by a maximum of 6 cd/m ² in each case 3C a variation in luminance of more than 20 cd/m ² can be seen. The luminance distribution of an organic component with an electrically poorly conductive transparent electrode layer 1 can consequently be homogenized by electrode tracks 2 .

According to the 4A and 4B further exemplary embodiments of an organic component described here are explained in more detail. Again, each simulated luminance distributions are shown in a plan view of organic components, each with an electrode track 2, the electrode track 2 in FIG 4A is not electrically connected and in the 4B is electrically connected exclusively by means of the electrode layer 1. On the right side of the 4A and 4B the absolute scale for the luminance in the unit cd/m ² is again plotted.

At the in the 4A and 4B In the exemplary embodiments shown, the electrode tracks 2 are designed to be continuous when viewed from above and enclose an area in the form of a rectangle that is simply continuous when viewed from above. In addition, an external anode 53, which can be formed by contacting 54 and/or metallization 51, for example, for contacting electrode layer 1 and a cathode 52' of the organic component for contacting reflective electrode 52—not shown—are shown.

With a non-electrically connected electrode track 2 according to the 4A a luminance distribution results which has a minimum 8 at an edge of the organic component opposite the cathode 52 . In the case of an electrically connected electrode track 2 according to the 4B this minimum no longer exists. The luminance distribution of 4B is thus compared to the luminance distribution of 4A more homogeneous.

According to the 5A and 5B further exemplary embodiments of an organic component described here are explained in more detail. Again, each simulated luminance distributions of organic components are shown in a top view, each with an electrode track 2, the electrode track 2 in FIG 5A is not electrically connected and in the 4B is electrically connected exclusively by means of the electrode layer 1. On the right side of the 5A and 5B the absolute scale for the luminance in cd/m ² is again plotted.

Again, both the luminance distribution and the luminous intensity in the 5B over the entire organic layer stack 3 through the electrically connected electrode track 2 compared to the 5A significantly improved and homogenized. Furthermore, the luminance distribution in the 5B more symmetrical than that of 5A .

The luminance distributions according to the embodiments of 4B and 5B show that the luminance distribution of an organic component can already be homogenized by the presence of a single electrode track 2 . In general, other shapes for the electrode track 2 are also conceivable. For example, the electrode track 2 can have the shape of the letter “U” or the letter “L” in a plan view. Furthermore, the electrode track 2 can enclose the area of a triangle, a trapezium, a circle, an irregular square or another geometric figure in a plan view.

In this case, the enclosed area can be part of the organic layer stack, but it is also possible for the enclosed area to be formed by a further component of the organic component. The shape of the at least one electrode track 2 can be adapted individually to the respective shape of the organic component or the organic layer stack 3 . For this purpose, several electrode tracks 2 can also be present, each of which has the shape of the organic structure are partially adjusted. In this way, in addition to improving the homogeneity, a symmetrization of the luminance distribution can also be achieved. This leads to a visually more pleasant impression of the luminance distribution.

In particular, the luminance distribution of large-area organic components can be optimized with electrode tracks 2, which are electrically contacted only by means of the electrode layer 1, and at the same time a visually appealing design can be achieved.

Such an organic component with only a single electrode track 2 or alternatively a small number of electrode tracks 2 has the advantage that only a few areas of the luminous surface formed by the bottom surface 3c are covered by radiation-opaque electrode tracks 2 and therefore only a few areas of the luminous surface do not light up.

Claims (11)

Organic component comprising - an organic layer stack (3) with a multiplicity of organic functional layers (30) and a top surface (3a), - at least one reflective electrode (52) which is attached to the top surface (3a) of the organic layer stack (3), - at least one electrode track (2) having a thickness in a range of less than 100 µm, and - An electrode layer (1), which is transparent, wherein - the at least one electrode track (2) and the electrode layer (1) are attached to a side of the organic layer stack (3) facing away from the reflective electrode (52), - the electrode track (2) is electrically connected exclusively by means of the electrode layer (1), - all side surfaces (2b) and a top surface (2a) of the electrode track (2) facing away from the electrode layer (1) are completely covered by the organic layer stack (3) and directly adjoin the organic layer stack (3) and the organic layer stack (3) with the at least one electrode track (2) is electrically conductively connected. Organic component according to the preceding claim, in which the material of the transparent electrode layer (1) has a lower electrical conductivity than the material of the electrode track (2). Organic component according to one of the preceding claims, in which the at least one electrode track (2) is not freely accessible from the outside. Organic component according to one of the preceding claims, in which an encapsulation (4), which is designed to be electrically insulating, covers all outer surfaces (3a, 3b, 52a) of the organic layer stack (3) and/or the reflective electrode ( 52) completely covered, the encapsulation (4) adjoining the electrode layer (1). Organic component according to one of the preceding claims, in which the at least one electrode track (2) has a width and a length running perpendicularly to the width within the scope of manufacturing tolerances, the length being at least twice, preferably at least five times, the width. Organic component according to one of the preceding claims, in which there is a single electrode track (2). Organic component according to the preceding claim, in which the single electrode track (2) completely encloses a simply connected area in a plan view of the organic component. Organic device according to one of the preceding claims, in which the electrode layer (1) is formed with a transparent conductive oxide. Organic component according to one of the preceding claims, in which all side surfaces (2b) and the top surface (2a) of the electrode track (2) are completely covered by the organic layer stack (3). Organic component according to one of the preceding claims, in which the at least one electrode track (2) is applied using a printing process. Organic component according to one of Claims 1 until 5 , in which a plurality of electrode tracks (2) is present, the electrode tracks (2) being spaced laterally from one another.

Images