EP1459396A1

EP1459396A1 - Organic light-emitting diode (led) and method for the production thereof

Info

Publication number: EP1459396A1
Application number: EP02787404A
Authority: EP
Inventors: Jan Birnstock; Jörg BLÄSSING; Karsten Heuser; Marcus Scheffel; Matthias STÖSSEL; Georg Wittmann
Original assignee: Osram Opto Semiconductors GmbH
Current assignee: Ams Osram International GmbH
Priority date: 2001-12-28
Filing date: 2002-11-27
Publication date: 2004-09-22
Also published as: TW200301578A; WO2003061026A1; DE10164016B4; JP2005515599A; DE10164016A1; TWI267214B; CN1608328A; CN1608328B; US20050122035A1; US7256541B2

Abstract

An organic layer (1) is applied to a transparent carrier (2) in such a way that several partial segments with different refractive indices are configured in the layer. Fewer photons remain trapped in the layer as a result of waveguide losses than in homogenous layers due to diversion at the phase limits within the layer.

Description

description

Organic light emitting diode (OLED) and process for its manufacture

The invention relates to an organic light-emitting diode (OLED for organic light-emitting diode) with at least one polymer layer according to the preamble of claim 1.

Organic light emitting diodes show a number of advantages that make them attractive for use in optoelectronics. These include the availability of many emission colors, low threshold voltages, quick switchability, small thickness and the possibility of using flexible substrates. Typical areas of application for OLEDs are pixelated display instruments and large-area elements for lighting purposes.

An important development goal for OLEDs is to increase the luminous efficacy and thus reduce the power consumption. This is particularly important for mobile applications where only limited energy resources are available.

The majority of previous developments to maximize light output have been concerned with increasing internal quantum efficiency. This is defined as the ratio between the photons generated in the diode to the injected electrons. New materials with improved luminescence properties, optimized layer sequences or better adapted electrode materials have contributed to increasing internal quantum efficiency in recent years.

Another approach to increasing light output is to improve extraction efficiency. Extraction efficiency is the probability with which a photon generated in the emission zone can be coupled out of the diode and can thus be detected. Coupling losses occur by absorption or by waveguiding in one of the layers. Waveguide is due to total reflection at the interface of two layers with different refractive indices. With flat interfaces, the angle between the incident and reflected beam does not change except for the sign. Accordingly, a photon once totally reflected remains enclosed in the corresponding layer and cannot be extracted.

The illustration in FIG. 1 illustrates the process of waveguiding in the layers of an organic light-emitting diode:

A transparent electrode 2 (usually indium tin oxide, ITO for short) is located on a substrate 3. At least one organic layer 1 is deposited thereon, followed by an electrode 5 (e.g. a cathode). In the organic layer 1, 6 photons are generated by emitters. Only photons that do not remain in layers 1-3 and 5 due to waveguiding are extracted. Line IV shows an example of the path of an extracted photon.

Depending on the layer thickness and refractive index of the individual layers, waveguiding effects, indicated in FIG. 1 by the lines I, II and III, can occur in the organic layer, in the transparent electrode or in the substrate. Since the layer thicknesses of the organic layers and the transparent electrode are in the range of the light wavelength or below, discrete optical modes I, II are formed in these layers, while a mode continuum III is present in the substrate and classic radiation optics can be used here. A distinction is therefore made between layer modes and substrate modes.

If it is possible to disrupt the formation of layer modes and thus to minimize undesired waveguiding, the extraction efficiency and thus the light output increase. In addition to the wavelength, the optical modes formed in a thin, flat layer are essentially dependent on the layer thickness and the refractive index of the layer.

A change in the refractive index and thus the disturbance of the waveguiding effects can be achieved by inhomogeneities within the organic layer if the inhomogeneities have a different refractive index than the layer matrix.

So far, the following briefly outlined approaches a) to c) for suppressing waveguiding effects have been proposed, with a) and b) aiming at a change in the refractive index and c) using a change in the layer thickness:

a) Dispersion of nanoparticles in one of the organic layers of the OLED (S.A. Carter et al., Enhanced luminance in polymer composite light emitting devices. Appl. Phys. Lett. 71 (9), p. 1145, 1997)

Here, 30 to 80 nm large particles of Ti0 ₂ , Si0 ₂ or Al ₂ 0 _{3 are} embedded in the polymeric emitter material MEH-PPV.

This method is associated with the following difficulties: It is technically very difficult to evenly disperse nanoparticles in a solvent in which polymers have already been dispersed or dissolved. The consequence of poorly dispersed nanoparticles is an inhomogeneous emission of the LED layer which contains these nanoparticles, which is why diodes produced in this way are not suitable for use in display instruments.

The proposed oxidic nanoparticles can lead to a degradation of the active layer by oxidation. Accordingly, a significantly shorter lifespan was observed for the diodes with nanoparticles than for the reference diodes.

b) Tightly packed Si0 ₂ microspheres (T. Yamasaki, K. Sumioka, T. Tsutsui: Organic light-emitting device with an ordered mono- layer of silica microspheres as a scattering medium, Appl. Phys. Lett. 76 (10), p. 1243, 2000).

Here, individual layers of densely packed Si0 ₂ spheres with a diameter of 550 nm are used as scattering centers. The balls are applied to the substrate next to the ITO anode tracks. This can be used to suppress wave conduction in the organic layers and in the glass. An increase in the coupling-out efficiency was observed.

This method is associated with the following difficulties: The application of densely packed spherical surfaces can only be achieved with great effort. A large-area application of such areas of several square centimeters has also not yet been realized. The scattering centers are located outside the active diode volume. Accordingly, only a small part of the substrate surface can be used to generate light. There is also an inhomogeneous luminance.

Due to the periodic structure of the dense packing, the scattering efficiency is strongly wavelength-selective. Accordingly, there is usually an undesirable lateral color gradient.

c) Corrugated (wavy) organic layers (J.M. Lupton et al., Bragg scattering from periodically microstructured light emitting diodes, Appl. Phys. Lett. 77 (21), p. 3340, 2000).

Here, a polymer LED is applied to a one-dimensional-periodic structure with a period of 388 nm and depths of 10 - 100 nm. The structure acts as a Bragg reflector and in turn leads to a scattering of optical modes in the emitter material.

This method has the following difficulties: The periodicity of the structure leads to a strong angular dispersion. A 15 nm thin gold layer was used as the anode, which despite the small layer thickness already shows strong absorption. A transfer of corrugation to the otherwise Transparent ITO, which is used as a standard anode, is difficult to implement due to the larger ITO layer thicknesses and high process temperatures.

Furthermore, there are various approaches to better decoupling the substrate modes. However, since the formation of optical modes in thin layers cannot be prevented with these methods, they cannot be used to prevent the waveguiding effect.

The object of the invention is to overcome the disadvantages of the prior art. In particular, an organic active OLED layer and a method for the production thereof are to be created in which the waveguiding effect is minimized by special precautions without the life of the layer being greatly shortened by the use of inorganic materials or by periodic structures a strong wavelength selectivity of the extraction occurs.

This object is achieved by an OLED with the features of claim 1 or by a method with the features of claim 9. Advantageous further developments of the OLED and the method are specified in subclaims 2-8 and 10-16.

According to the invention, inhomogeneities are introduced in at least one organic layer of the OLED which themselves have an organic composition. The organic inhomogeneities have a different refractive index than a layer matrix and consequently interfere with the waveguiding effects.

2a) schematically shows the path of a photon, which is emitted by an emitter 6 and extracted from an organic layer 1, when the line 4a is provided with arrows and after it has passed through partial regions 1B with a first refractive index within a layer matrix material 1A with a second refractive index different from the first in one Steeper angle than the critical angle of total reflection strikes a transparent neighboring layer 2, which is, for example, an ITO anode. Layer 5 is, for example, a cathode.

For comparison, the path of a photon which is generated in a homogeneous organic layer consisting entirely of a single material is shown schematically in FIG.

A photon remains trapped in the layer between a cathode 5 and a transparent anode 2 due to the waveguiding effect if the angle of incidence does not exceed the critical angle of total reflection. Layer modes arise.

To produce an organic layer with partial areas with different refractive indices, a mixture of plastics is used, the properties of which permit use as an active OLED layer or as a passive intermediate layer, or a mixture of their starting materials. Separation processes during or after layer formation are used in a targeted manner to obtain a layer that contains two or more phases. In a particularly preferred variant, the phases with different refractive index consist of different plastics.

So that the refractive index inhomogeneities contribute particularly effectively to the extraction of the photons from the transparent layer, it is advantageous that a composite-like structure is formed in the layer by the separation. Composite-like structure is understood here above all to mean the structure of a particle-filled plastic, as well as the structure of a composite with two three-dimensionally interpenetrating individual components, as it also arises, for example, when an open-pore plastic body is poured out with a second plastic.

In order to obtain an at least two-phase layer, at least two polymers are dissolved or dispersed, which are in the Separate the removal of the solvent or dispersion medium or separate them before the layer dries by separating the solvent or dispersion medium.

Instead of working with already polymerized substances, it is conceivable to use monomeric or oligomeric starting materials of the polymers for the coating, the separation of the at least two phases occurring before, during or after the polymerization.

In another preferred variant, the layer consists chemically of a single polymeric material which, in island regions, has differences in material properties, such as crystallinity, degree of branching, degree of crosslinking, density and co-polymerization, and thus differences in the refractive index, compared to the matrix.

Different charge carrier transport materials, emitter materials and any mixtures thereof can be used as plastics. It is also possible to use further, electrically inactive plastics or their precursors.

By varying the manufacturing conditions, the segregation process and chemical reactions and thus the structure and the optical properties of the plastic layer can be influenced in a targeted manner.

The invention is explained in more detail below on the basis of two exemplary embodiments in conjunction with FIGS. 1 to 3b.

Show it:

1 is a schematic representation of the waveguide losses in the layers of a conventional organic light emitting diode,

2a shows a schematic representation of the scattering of photons by refractive index inhomogeneities in an organic layer, 2b is a schematic representation of the waveguide in an organic layer without scattering centers,

3a shows a micrograph of an organic layer according to a first embodiment,

3b shows a microscopic picture of an organic layer according to a second exemplary embodiment.

The explanations for FIGS. 1-2b are already in the general part of the description.

Embodiment 1 (Fig. 3a):

These are the polymer materials poly (para-phenylene-vinylene) derivative (PPV) and poly (N-vinyl carbazole) (PVC), which were mixed and spin-coated in solution as a layer on a substrate.

One third of the mixture of the dissolved plastics consisted of PPV and two thirds of PVC. After the spin coating, the two materials separated, in which large structures made of PVC with smaller satellites were formed in a PPV matrix. This is shown by the microscopic image of the surface of the resulting organic layer shown in FIG. 3a). In a matrix made of PPV, PVC areas with a wide size distribution curve are stored as scattering centers.

Embodiment 2 (Fig. 3b):

As in embodiment 1, it is PPV and PVC, which were mixed and spin-coated as a layer in solution.

In this example, the mixture consists of 50% PPV and 50% PVC. The microscopic image of the organic layer produced in this way, shown in FIG. 3b), shows that spherical PVC regions are in turn embedded as scattering centers in a PPV matrix, but in this case with a very high much narrower size distribution curve than in the first embodiment explained above.

In the two microscopic images, the light areas consist of PVC and the dark areas of PW.

The exemplary embodiments demonstrate how a different size and a different size distribution of the scattering centers can be achieved by varying the mixing ratios of the two plastics. This advantageously offers the possibility of specifically adjusting the optical properties of the organic layer.

The present invention is of course not limited to the polymer materials mentioned in the two exemplary embodiments, but can be used for all materials which are suitable in terms of their electrical properties for organic LEDs.

Furthermore, with a single plastic material, for example, an effect similar to segregation can be achieved if crystalline regions form within an amorphous matrix.

Claims

claims

1. Organic light-emitting diode (OLED) with at least one organic layer which has refractive index inhomogeneities, characterized in that one and the same organic layer has at least a first partial area and at least a second partial area, which consist of organic material and have different refractive indices, and the partial areas one Form a layer with a composite-like structure.

2. OLED according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the different sub-areas are formed by segregation of the applied layer material.

3. OLED according to one of claims 1 or 2, d a d u r c h g e k e n n z e i c h n e t that the organic layer has charge carrier transport material and / or emitter material.

4. OLED according to one of claims 1 to 3, d a d u r c h g e k e n n z e i c h n e t that the organic layer has electrically inactive material.

5. OLED according to one of claims 1 to 4, that the layer has at least two polymers with different refractive indices.

6. OLED according to claim 1, characterized in that the different subregions are produced in a layer from a single type of plastic material by means of local variation of a chemical and / or physical property.

7. OLED according to claim 6, d a d u r c h g e k e n n z e i c h n e t that crystalline areas exist within an amorphous layer matrix material.

8. OLED according to claim 6, d a d u r c h g e k e n n z e i c h n e t that the locally varying property is at least one of the properties degree of crosslinking, degree of branching, density and co-polymerization.

9. A method for producing an organic light-emitting diode (OLED) with at least one organic layer which has refractive index inhomogeneities, characterized in that the material of the organic layer is applied to a support such that during or after the coating step in the Form layer at least a first partial area and at least a second partial area, which have different refractive indices, and the partial areas form a layer with a composite-like structure.

10. The method according to claim 9, so that the subregions are formed by a separation process in the polymer layer being formed from a mixture of soluble or dispersible polymers or monomers, in which at least two phases are formed.

11. The method according to any one of claims 9 or 10, d a d u r c h g e k e n n z e i c h n e t that charge carrier transport material and / or emitter material is used for the organic layer.

12. The method according to any one of claims 9 to 11, characterized in that electrically inactive material is used for the organic layer.

13. The method according to claim 10 or according to one of the claims back to claim 10, that the separation of the polymers is brought about by removing a solvent or a dispersing agent.

14. The method according to claim 10 or according to one of the claims back to claim 10, that the separation of the polymers is caused by a separation of at least two solvents in which the at least two polymers are dissolved.

15. The method according to claim 10 or according to any one of the claims back to claim 10, that the separation of the polymers is caused by a separation of at least two dispersing agents in which the at least two polymers are dispersed.

16. The method according to claim 10 or one of the claims related to claim 10, that the at least two different polymers are formed in the organic layer only during the coating process or afterwards by polymerization, or thereafter.