DE10255140A1 - Organic electroluminescent or light emitting device for transmitting white light for use as a lamp or light and having a layer which changes light of one color into light of two different colors - Google Patents

Abstract

The organic light emitting device has a substrate (41). A lower electrode (43) is formed on a surface of the substrate. An organic layer (45) including an organic emission layer is formed on a surface of the lower electrode to emit light of a first color. A counter electrode (47) is formed on the surface of the organic layer. A sealing layer (49) covers the organic layer and the counter electrode. The counter electrode is transparent. A color conversion layer (40) is provided on the inner side of the sealing layer. This converts a component of light having the first color into light of a second color and light of a third color.

Description

The invention relates to the field organic electroluminescent devices (also known as MONEY) and the process for their preparation, and in particular an organic one Electroluminescent device for emitting white light, which is a full color light that provides three different frequency bands, can send directly and continuously, and a method for Manufacture of such an organic electroluminescent device.

Because of their advantages over others The organic electroluminescent device has display fields attracted strong attention. These advantages include self-lighting, the big one Perspective, the short response time, the compact size, that low weight, reduced thickness, high brightness, the low power consumption, the easy manufacture and the Ability, To emit light in a full color range. So it becomes one organic electroluminescent device increasingly required to the white ones currently used To replace light sources such as fluorescent tubes and light bulbs and thereby Saving energy, using their technologies in industry worldwide be extensively examined.

In 1 Fig. 10 is a cross-sectional view of the structure of a conventional organic electroluminescent device in accordance with the prior art. The organic electroluminescent device is characterized in that on a substrate 11 a lower electrode 13 is formed on which an organic layer is successively 15 comprising a hole injection layer, a hole transport layer, an organic emission layer or an electron transport layer, a counter electrode 17 and a sealing encapsulation layer 19 are trained. Because of the limitation of that in the organic layer 15 material used can be as in 1 bechtung bechtung emit only monochromatic light, preferably blue, red or green light according to the different fluorescent materials chosen, while the task of emitting white light or continuous full-color light is not solved. Thus, several modifications must be made to the device structure to obtain a white light source.

For example, Forrest et al. (The Trustees of Princeton University, Princeton, NJ) disclose as US 5,757,026 "Multicolor organic light emitting devices", while Chao et al. (Industrial Technology Research Institute, Hsinchu, TW) as US 6,037,190 "Method for fabricating an organic electro-luminescent device" disclose. In 2 FIG. 4 is a cross-sectional view of the structure of a conventional organic electroluminescent device for emitting white light, which is similar to that in FIG US 6,037,109 disclosed organic electroluminescent device. The organic electroluminescent device for emitting white light in 2 is characterized in that between the lower electrode 13 and a corresponding counter electrode 17 three organic layers 25G . 25R and 25B lying, which emit green light, red light and blue light, respectively. Thus, a white light source is obtained by mixing the light from the three organic layers.

• (1) Das organische Material zum Aussenden von rotem Licht besitzt eine kürzere Lebensdauer als die anderen organischen Materialien, was dazu führt, daß die organische Elektrolumineszenzvorrichtung zum Aussenden von weißem Licht gestört wird, da das organische Material zum Aussenden von rotem Licht ausfällt;
• (2) die Herstellungsverarbeitung zum Ausbilden verschiedener organischer Schichten auf einem Chip ist schwierig auszuführen; und
• (3) da die Spannungen zum Aktivieren der verschiedenen organischen Schichten verschieden sind, ist die Hardware-Implementierung schwierig.

However, there are some problems in the above-mentioned organic electroluminescent device for emitting white light:

• (1) The organic material for emitting red light has a shorter life than the other organic materials, which results in the organic electroluminescent device for emitting white light being disturbed because the organic material for emitting red light fails;
• (2) Manufacturing processing for forming various organic layers on one chip is difficult to carry out; and
• (3) Since the voltages for activating the different organic layers are different, the hardware implementation is difficult.

To avoid the problems arising from the organic electroluminescent device in 2 a number of disclosures have been proposed, such as US 6,008,578 "Full-color organic electro-luminescent device with spaced apart fluorescent areas", submitted by Chen (Hsinchu, TW), US 5,294,870 "Organic electro-luminescent multicolor image display device" submitted by Tang et al. (Eastman Kodak Company, Rochester, NY) and US 5,717,289 "Thin film electro-luminescent element easily regulating emitted light to white", submitted by Tanaka (NEC Corporation, Tokyo, JP). 3 FIG. 14 shows a cross-sectional view of the structure of a conventional organic electroluminescent device for emitting white light, which is similar to that in FIG US 5,717,289 disclosed thin film electroluminescent element. The organic electroluminescent device for emitting white light in 3 is characterized in that between the lower electrode 13 and the substrate 11 a color conversion layer 30 lies. The color conversion layer 30 is made of a fluorescent material. If from the lower electrode 13 a current in the counter electrode 17 is fed, sends the organic layer 15 blue light (B) off. While the blue light (B) through the color conversion layer 30 a certain proportion of the blue light (B) becomes red (R) and green (G). A white light source is thus obtained.

As in 3 is shown, but is characterized in that between the lower electrode 13 and the substrate 11 the color conversion layer 30 lies, the flatness of the subsequent organic layer 15 and hence the lifespan of the organic layer 15 adversely affected.

However, there is a modification of the 3 structure shown therein, the color conversion layer 30 on the organic layer 15 train. In other words, the organic layer 15 is before forming the color conversion layer 30 educated. As a result, due to the high temperature when the color conversion layer is formed 30 by evaporating the organic layer 15 damaged, resulting in poor full color display quality.

Given the above-mentioned problems thus a need to create an organic electroluminescent device for sending white Light and a method for producing such an organic Electroluminescent device that simplify manufacturing processing and a longer one Lifetime as well as better full color display quality of the device to reach.

The invention is therefore the object based, an organic electroluminescent device for emission of white Light and a method of manufacturing such an organic electroluminescent device to create that uses simplified manufacturing processing to a white one Light source with better full color quality and longer device life to realize.

According to the invention, this object is achieved by an organic electroluminescent device for emitting white Light according to claim 1 or 7 or by a method of manufacture an organic electroluminescent device for emitting white Light according to claim 10. Further developments of the invention are specified in the dependent claims.

According to a feature of the invention become an organic electroluminescent device for emission of white Light and a method of making such an organic Electroluminescence device created, the device being a Color conversion layer used on the inside of the sealing encapsulation layer is arranged, which simplifies manufacturing processing leads and prevents the Color conversion layer is influenced when forming the organic layer and vice versa.

According to another method The invention is an organic electroluminescent device for sending white Light and a method of manufacturing an organic electroluminescent device created using a clear sealing encapsulation layer is so that the Device emits light of different colors on both sides.

Other and other features, advantages and benefits of the invention will be apparent from the following description Connection with the attached Drawing. Of course are the foregoing general description and the following detailed Description exemplary and explanatory, but this is not as a limitation the invention are to be understood. The attached drawing is included in this application and forms part of it and serves together with the description for general explanation the principles of the invention. The same reference numbers refer in equal parts throughout Revelation.

Other features and advantages of Invention will become apparent upon reading the following description preferred embodiments, which refers to the drawing; show it:

1 the aforementioned cross sectional view of the structure of a conventional organic electroluminescent device of the prior art;

2 the aforementioned cross sectional view of the structure of a conventional organic electroluminescent device for emitting white light of the prior art;

3 the aforementioned cross-sectional view of the structure of another conventional organic electroluminescent device for emitting white light of the prior art;

4 a cross-sectional view of the structure of an organic electroluminescent device for emitting white light according to a preferred embodiment of the invention;

5 a cross-sectional view of the structure of another organic electroluminescent device for emitting white light according to another embodiment of the invention; and

6 a cross-sectional view of the structure of yet another organic electroluminescent device for emitting white light according to yet another embodiment of the invention.

The invention, which is an organic Electroluminescent device for emitting white light and provides a method for manufacturing such a device, can by the preferred embodiment as described below exemplified become.

First shows 4 a cross-sectional view of the structure of an organic electroluminescent device for emitting white light in accordance with a preferred embodiment of the invention. As shown in the drawing, the organic electroluminescent device for emitting white light comprises: a substrate 41 ; a lower electrode 43 that are on a top of the substrate 41 is trained; an organic layer 45 comprising at least one organic emission layer; and a counter electrode 47 , These elements are formed by the same methods as those for manufacturing a conventional organic electroluminescent device for emitting white light. Indeed the invention is characterized in that a sealing encapsulation layer 49 only then by evaporation on the substrate 41 is formed after on the inside of the sealing encapsulation layer 49 a color conversion layer 40 has been formed from a fluorescent material. The organic conversion layer 40 and the sealing encapsulation layer 49 are on the substrate 41 attached so that the organic electroluminescent device is completed. If from the top electrode 43 a current in the counter electrode 47 is fed, sends the organic layer 45 Light of a first color (blue light (B) in the present embodiment). If a certain amount of blue light (B) through the counter electrode 47 is passed and the color conversion layer 40 reached, part of the blue light (B) becomes light with a second color (red (R) light) and light with a third color (green (G) light). The red (R) light and the green (G) light reach the sealing encapsulation layer 49 and are reflected so that they mix with the blue light (B). A white light source is thus obtained.

In particular, the blue light (B) is directly from the organic layer 45 into the substrate 41 emitted, which leads to a shorter optical path length than with the red light (R) and the green light (G). A color filter can thus be placed on the top of the substrate 42 be provided that attenuates the light intensity of the blue light, so that an improved display quality of the white light is obtained. The lower electrode 43 and the counter electrode 47 are definitely made of transparent materials in the present embodiment. In addition, the color conversion layer 40 on the inside of the sealing encapsulation layer 49 formed before the sealing encapsulation layer 49 is formed in the substrate so that the color conversion layer is prevented from being affected when the organic layer is formed, and vice versa.

Also shows 5 a cross-sectional view of the structure of another organic electroluminescent device for emitting white light in accordance with another embodiment of the invention. The present embodiment is intended to solve the problem that the blue light (B) has a relatively stronger intensity than the red light (R) and the green light (G). As in 5 the organic electroluminescent device for emitting white light comprises: a substrate 41 ; one on top of the substrate 41 trained lower electrode 43 ; and a sealing encapsulation layer 59 , in which several organic layers 55 , each containing at least one organic emission layer, and a plurality of counter electrodes 57 are provided. So there is between two organic layers 55 a space 50 formed, which reduces the light intensity of the blue light (B). Because the organic layers 55 To emit light in all directions, the light intensities of the red light (R) and the green light (G), which are obtained by the blue light (B) through the color conversion layer 40 is reflected, reduced relatively little. An organic electroluminescent device for emitting white light with good full-color display quality is thus obtained.

In addition, the white light obtained by mixing the blue light (B), the red light (R) and the green light (G) when the sealing encapsulation layer 59 is formed from a transparent material, in the present embodiment as shown by the arrows through the sealing encapsulation layer 59 sent out. In this case you need the counter electrode 43 and the substrate 41 not necessarily to be made of transparent materials.

Finally shows 6 a cross-sectional view of the structure of yet another organic electroluminescent device for emitting white light in accordance with yet another embodiment of the invention. Except that the lower sealing encapsulation layer 69 at the bottom of the substrate 41 is made of a transparent material, the organic electroluminescent device is in 6 completely the same as in 1 , On the inside of the lower sealing encapsulation layer 69 before forming the lower sealing encapsulation layer 69 a color conversion layer 40 educated. Thus, by mixing the blue light (B) from the organic layer 45 with the red light (R) and with the green light (G) from the color conversion layer 40 get a white light source.

If the top seal encapsulation layer 49 and the counter electrode 47 are formed from transparent materials in the present embodiment, the blue light (B) from the organic layer 45 through the top sealing encapsulation layer 49 be sent out.

Disclosed according to the above discussion the invention an organic electroluminescent device for Sending out white Light and a process for its manufacture, leading to a simple one Perform manufacturing processing, the full color display quality improve and increase the life of the device. Consequently it has been proven that the Invention is novel, not obvious and technically useful.

Although the invention is related to special embodiments the principles in question have been disclosed and shown Suitable for use in numerous other embodiments for the Those skilled in the art are obvious. Thus the invention is intended be limited only by the scope of the appended claims.

Claims (12)

Organic electroluminescent device for emitting white light, with: a substrate ( 41 ); a lower electrode ( 43 ) on top of the substrate ( 41 ) is trained; at least one organic layer ( 45 ; 55 ) comprising an organic emission layer formed on a surface of the lower electrode ( 43 ) is designed to emit light with a first color; at least one counter electrode ( 47 ; 57 ) on a surface of the at least one organic layer ( 45 ; 55 ) is trained; and a sealing encapsulation layer ( 49 ; 59 ) which the at least one organic layer ( 45 . 55 ) and the at least one counter electrode ( 47 ; 57 ) covered, characterized in that the at least one counter electrode ( 47 ; 57 ) is transparent, and on an inside of the sealing encapsulation layer ( 49 ; 59 ) a color conversion layer ( 40 ) is arranged, which converts a portion of the light with the first color into light with a second color and into light with a third color. Organic electroluminescent device for emitting white light according to claim 1, characterized in that the lower electrode ( 43 ) is made of a transparent material. Organic electroluminescent device for emitting white light according to claim 2, characterized by a color filter ( 42 ) on the underside of the substrate ( 41 ). Organic electroluminescent device for emitting white light according to one of the preceding claims, characterized in that the sealing encapsulation layer ( 49 ; 59 ) is made of a transparent material. Organic electroluminescent device for emitting white light according to one of the preceding claims, characterized in that between two organic layers in each case under a plurality of organic layers ( 55 ) in the sealing encapsulation layer ( 59 ) a space ( 50 ) is arranged. Organic electroluminescent device for emission of white Light according to one of the preceding claims, characterized in that the light with the first color is blue. Organic electroluminescent device for emitting white light, comprising: a substrate ( 41 ); a lower electrode ( 43 ) on top of the substrate ( 41 ) is trained; at least one organic layer ( 45 ) comprising an organic emission layer formed on a surface of the lower electrode ( 43 ) is designed to emit light with a first color; at least one counter electrode ( 47 ) on a surface of the organic layer ( 45 ) is trained; and a sealing encapsulation layer ( 49 ) which the at least one organic layer ( 45 ) and the at least one counter electrode ( 47 ) covered, characterized by a transparent lower sealing encapsulation layer ( 69 ) on the underside of the substrate ( 41 ), with an inside of the transparent lower sealing encapsulation layer ( 69 ) a color conversion layer ( 40 ) is arranged, which converts a portion of the light with the first color into light with a second color and into light with a third color. Organic electroluminescent device for emitting white light according to claim 7, characterized in that the sealing encapsulation layer ( 49 ) and the counter electrode ( 47 ) are made of transparent materials, so that the organic electroluminescent device for emitting white light emits the light with the first color through the sealing encapsulation layer ( 49 ) and through the counter electrode ( 47 ) sends out. Organic electroluminescent device for emission of white Light according to claim 7 or 8, characterized in that the light with the first color is blue. A method for producing an organic electroluminescent device for emitting white light, comprising the following steps: provision of a substrate ( 41 ); Forming a lower electrode ( 43 ) on top of the substrate ( 41 ); Forming an organic layer ( 45 ) on a surface of the lower electrode ( 43 ) for emitting light with a first color; and forming a counter electrode ( 47 ) on a surface of the organic layer ( 45 ); characterized by the further step: forming a color conversion layer ( 40 ), which converts a portion of the light with the first color into light with a second color and into light with a third color, the sealing encapsulation layer ( 49 ) and the color conversion layer ( 40 ) on the surface of the substrate ( 41 ) are attached while the organic layer ( 45 ) and the counter electrode ( 47 ) in the sealing encapsulation layer ( 49 ) are included. A method according to claim 10, characterized by the further step: forming a color filter ( 42 ) on the underside of the substrate ( 41 ). A method according to claim 11, characterized by the further step: forming a lower sealing encapsulation layer ( 69 ) on the underside of the substrate ( 41 ), the lower sealing encapsulation layer ( 69 ) and the color conversion layer ( 40 ) on the underside of the substrate ( 41 ) are attached while the organic layer ( 45 ) and the counter electrode ( 47 ) in the sealing encapsulation layer ( 49 ) are included.