JP2000012235A - El element - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the occurrence of a short circuit of electrodes in the EL element, and to improve productivity and a yield ratio, by eliminating the need for a little damage process of low-temperature as a vacuum film forming method of a metal reflective layer. SOLUTION: A metal reflective layer 22 is formed on an opposite substrate 23 set opposite to and spatially separated from metal cathodes 20 on an organic EL layer 19. The metal reflective layer 22 compensates non-reflective portions between the cathodes 20 to realize a uniform reflective surface. Here, the metal reflective layer 22 is not formed on the organic EL layer 19 and the cathodes 20, therefore it does not have adverse effects on them.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in an EL device, and more particularly to an improved structure for improving the productivity and yield of an organic EL device suitable as a backlight of a liquid crystal display panel.

[0002]

2. Description of the Related Art FIG. 4 shows a configuration example of a conventional organic EL display device. In the figure, 17 is a transparent substrate, 18 is a transparent anode electrode, 19 is an organic EL layer, 20 is a metal cathode electrode, 21 is a transparent insulating film, 22 is a metal reflective layer, 37 is a sealing material, and 23 is a substrate. is there.

The transparent anode electrode 18 has a plurality of stripes extending in the row direction.
Is a plurality of stripes extending in a column direction perpendicular to the row direction, and regions where the transparent anode electrode 18 and the metal cathode electrode 20 intersect via the organic EL layer 19 are arranged in a matrix. ing.

In general, the organic EL layer 19 has high transparency to visible light in the thickness direction, unlike the inorganic EL layer. In general, a material having a low work function is selected for the metal cathode electrode 20 from the viewpoint of electron injection properties, and as a result, the metal cathode electrode 20 has a metallic luster and exhibits high reflectivity in the visible light wavelength region. In addition, the metal reflective layer 22 is provided between the metal cathode electrodes 20 and 20 in order to prevent the pattern of the metal cathode electrode 20 generated based on the difference in light reflectivity with and without the metal cathode electrode 20 from being visually recognized. As in the case of the metal cathode electrode 20, a material having a metallic luster and exhibiting high reflectivity in the visible light wavelength region is selected so as to reflect light leaking from the gap to the substrate 23 side.

In such an organic EL display element, electrons and holes are recombined inside the organic EL layer 19 by a voltage applied between the transparent anode electrode 18 and the metal cathode electrode 20, and the recombination causes It has a mechanism to capture the generated singlet exciton and emit light.

[0006] The organic EL display element having the above structure is, for example,
Used as a backlight for liquid crystal display (LCD) panels. That is, one side of the organic EL layer 19 is the transparent substrate 17 and the transparent anode electrode 18, and the other side is the metal cathode electrode 2.
0, the metal reflective layer 22 and the like, and since the electrode 20 and the reflective layer 22 have a specular reflectivity, when a predetermined voltage is applied between the electrodes 18 and 20, visible light is emitted and the transmission LC
Functions as a planar backlight for the D panel. Also, a transparent substrate 17, a transparent anode electrode 18, and an organic EL layer 19
Since the electrodes 20 and the reflective layer 22 reflect external light incident from the outside through the LCD panel when the EL is not emitting light without applying the voltage, the so-called reflective LCD is used, since all of them show transparency to visible light. It becomes the reflector of the panel.

In this display element, a conventional opaque inorganic EL is used.
The decrease in reflectivity in reflective display and the luminance in self-luminous display due to the transflective plate disposed between the LCD panel and the backlight, which has been a problem in transflective LCD devices with a backlight as an element The drop has been improved. Further, a matrix display function as an EL display element is provided.

[0008]

In the EL device having the conventional structure described above, a uniform reflecting surface is realized by the metal surface of the cathode electrode 20 and the metal reflecting layer 22 provided on the transparent insulating film 21. Have been. In this case, the metal reflection layer 22 has a function of compensating the reflectivity between the cathode electrodes 20 when EL is not emitted.

The cathode electrode 20 is made of a metal which is easily oxidized in order to improve the EL emission characteristics, and the organic EL layer 19 is vulnerable to heat. The entire surface is hermetically sealed by the material 37 and the substrate 23.

Particularly, the following problems arise in the EL light emitting device having the conventional structure described above. First, the transparent insulating film 21
There is a possibility that a short circuit may occur between the metal reflection layer 22 and the cathode electrode 20 due to a pinhole generated in the above or a misalignment of the metal reflection layer 22 with respect to the transparent substrate 17.

The method for forming the metal reflection layer 22 is as follows.
Usually, a vacuum film forming method such as sputtering or vapor deposition is employed. However, since this method is formed after the organic EL layer 19 and the metal cathode electrode 20 are formed, a low-temperature and low-damage process is inevitable. As a result, there are adverse effects such as low productivity and poor yield.

It is an object of the present invention to propose a novel structure of an EL element in which productivity and yield are greatly improved by preventing the above-mentioned electrode short circuit and eliminating the need for a low-temperature, low-damage process. is there.

[0013]

In order to achieve the above object, an EL device according to the present invention comprises a first substrate on which a transparent electrode, an EL layer and a back electrode are sequentially formed, and a surface facing the first substrate. A second substrate having a reflective layer exhibiting light reflectivity thereon.

Therefore, the light leaking from the back electrode to the second substrate can be reflected to the back electrode and the first substrate can be reflected.
By separating the substrate and the second substrate, the electrode and the reflection layer can be easily separated. Further, since the reflection layer is provided on the second substrate different from the first substrate provided with the EL layer and the back electrode, the EL layer and the back electrode are not damaged when the reflection layer is formed.

[0015]

FIG. 1 shows an embodiment of the EL device of the present invention. 4, the same reference numerals as in FIG. 4 denote the same or similar members, and in this embodiment, the difference from the conventional example in FIG.
The point is that it is formed on an opposing substrate 23 for sealing provided opposite to the cathode electrode 20 on the organic EL layer 19 and spatially separated from the cathode electrode 20.

By adopting the structure described above, the E
In the L element, a non-reflective portion of the space between the cathode electrodes 20 is formed on a metal reflective layer 22 formed on a sealing opposite substrate 23.
To realize a uniform reflection surface. Moreover, in this case, the metal reflective layer 22 is formed on the opposing substrate 23 where the organic EL layer 19 and the cathode electrode 20 are spatially separated from each other. The organic EL layer 19 and the cathode electrode 20 are formed by a process based on the transparent substrate 17 without causing a short circuit between the layers 22.
2 is separately formed on the counter substrate 23, and finally the organic EL
Transparent substrate 17 provided with layer 19 and cathode electrode 20
And the opposing substrate 23 provided with the metal reflection layer 22 is manufactured by joining with a sealing seal material 37. Therefore, it is not necessary to take a low-temperature, low-damage process when forming the metal reflection layer on the opposing substrate 23. The performance and yield are greatly improved.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which the above-described EL device of the present invention is used as a so-called two-way backlight of a liquid crystal display panel will be described in detail. FIG. 2 shows a liquid crystal display panel 2
And a display device 1 comprising an organic EL panel 3.

As shown in FIG. 1, the display device 1 is configured such that a liquid crystal display panel 2 disposed in front and an organic EL panel 3 disposed behind the liquid crystal panel 2 face each other.

The liquid crystal display panel 2 is generally constructed by sealing a liquid crystal 6 between a front transparent substrate 4 and a rear transparent substrate 5 which face each other. Hereinafter, the configuration of the liquid crystal display panel 2 will be described in detail.

First, when light including a red wavelength region, a green wavelength region, and a blue wavelength region is incident on the rear surface of the front transparent substrate 4 according to a predetermined pixel arrangement, substantially only the red wavelength region is emitted. A color filter layer 7 composed of a red filter that transmits, a green filter that transmits only the green wavelength region, and a blue filter that transmits only the blue wavelength region is formed for each pixel region. In a region between the color filter layers, a black matrix 8 having a light shielding property with respect to visible light is formed. Further, the surface (rear surface) of the color filter layer 7 and the black matrix 8 is formed on an insulating protective film 9.
Covered with. A common electrode 10 made of indium tin oxide (ITO) and a pre-alignment film 11 are sequentially laminated on the surface of the protective film 9 at least over the entire display region. An alignment treatment is performed to align the liquid crystal molecules in contact with each other in a predetermined direction.

On the front surface of the rear transparent substrate 5, pixel electrodes 12 made of ITO are arranged in accordance with a predetermined pixel arrangement, and a switching element covered with a protective film 31 is provided near each of the pixel electrodes 12. A thin film transistor (hereinafter, referred to as a TFT) 13 is connected to the pixel electrode 12. On the pixel electrodes 12 and the TFTs 13 and the like, an alignment film 14 after an alignment process is formed at least over the entire display region.

As shown in FIG. 2, the front transparent substrate 4 side and the rear transparent substrate 5 side maintain a predetermined distance between the alignment films 11 and 14 via a spacer (not shown).
The transparent substrates 4 and 5 are joined by a sealing material (not shown) which surrounds the gap between the display areas. The liquid crystal 6 is sealed in a space formed by the front transparent substrate 4 side, the rear transparent substrate 5 side, and the sealing material. Before and after the liquid crystal cell thus formed, that is, the front transparent substrate 4
As shown in FIG. 2, the front surface of the
A front polarizer 15 and a rear polarizer 16 are arranged and set to normally white.

Next, the configuration of the organic EL element 3 will be described.
As shown in FIGS. 1 and 3B, a plurality of transparent front electrodes (anode electrodes) 18 formed along a predetermined direction and parallel to each other are formed on the surface (rear surface) of the transparent EL substrate 17. ing. The transparent EL substrate 17 is formed of glass or plastic that transmits visible light.
The front electrode 18 is formed of ITO or In ₂ O ₃ (ZnO) m (where m> 0), which transmits visible light. Further, an organic EL layer 19 containing an organic fluorescent material as a light emitter is formed over the entire area corresponding to the display area of the liquid crystal display panel 2 so as to cover the transparent EL substrate 17 and the front electrode 18. I have.

In the case of emitting blue light, the organic EL layer 19 has N, N'-di (α-naphthyl) -N, N'-diph, in order from the front electrode 18 side.
enyl-1,1'-biphenyl-4,4'-diamine (hereinafter α-NPD)
And a 96 wt% of 4,4'-bis (2,2-di
phenyl vinylene) biphenyl (DPVBi) and 4
wt% of 4,4'-bis (2-carbazole) vinylene) biphenyl
(Hereinafter referred to as BCzVBi), and aluminum.
-tris (8-hydroxyquinolinate) (hereinafter referred to as Alq3) and an electron transporting layer, and each layer has a thickness of 4n.
m to about 100 nm. Such an organic EL layer 19
Emits blue light when a predetermined current is applied. A space between the rear electrode (cathode electrode) 20 and the anode electrode 18 is beryllinm-bis (10-hydroxybenzo [h] quinolinat).
e) (hereinafter, BeBq2) was added to the electron-transporting light-emitting layer by adding α-
If NPD is used as the hole transport layer, a light emitting layer that emits green light can be obtained.

As described above, the organic EL layer 19 has a three-layer structure including an organic electron transporting layer, an organic light emitting layer, an organic hole transporting layer, and the like. Various structures such as a two-layer structure also serving as a layer can be adopted. The emission color of the organic EL layer 19 can be arbitrarily set by selecting the material of the organic EL layer 19. Therefore, when the color filter 7 is R
In the case of a filter that transmits each color of (red), G (green), and B (blue), an organic EL layer 19 that emits R, G, and B colors is selected at a corresponding position, and the color filter 7 emits the light of this color. By making the peak in the wavelength range more sharp, display with high color purity can be performed. When an organic EL panel 3 having an R light emitting layer, a G light emitting layer, and a B light emitting layer is used as a backlight, all of the R light emitting layer, the G light emitting layer, and the B light emitting layer can emit light to display white. it can.

Further, the surface (rear surface) of the organic EL layer 19 has a metallic luster and intersects the front electrode 18 via the organic EL layer 19 and has high reflectivity in the visible light wavelength region. As shown, a plurality of rear electrodes 20 made of, for example, a metal material or alloy such as Al, Mg, and Li are formed in parallel. In this embodiment, the front electrode 18 and the rear electrode 2
The position where 0 intersects is set so as to correspond to the position of the pixel electrode 12 and the color filter layer 7 of the liquid crystal display panel 2 described above.

Further, as shown in FIG.
8A and the terminal portion 20A of the rear electrode 20 shown in FIG. 3A, so as to cover the front electrode 18, the organic EL layer 19 and the rear electrode 20 formed on the rear surface side of the transparent EL substrate 17. A transparent insulating film 21 is formed. Further, on a counter substrate 23 which is provided opposite to the rear electrode 20 and is spatially separated therefrom, as a reflection layer having a metallic glossy surface having a high light reflectance similar to that of the rear electrode 20 on the front side. The reflection plate 22 is formed over an area corresponding to the display area.

Therefore, the front electrode 18, the organic EL layer 19, the rear electrode 20, the transparent insulating film 21
Is formed, while the transparent EL substrate 1 is
A reflection plate 22 is formed on the surface facing 7. And
The substrates 17 and 23 are joined by a sealing material 37, and a space surrounded by these members is filled with an inert gas.

It is desirable that the reflection plate 22 be formed of the same metal or alloy as the rear electrode 20, or of a material having a spectral reflectance substantially equal to these. Thus, when the entire organic EL panel 3 is not emitting light, when the reflection of external light is used for display, the reflection function as if the rear electrode 20 and the reflection plate 22 are a uniform reflection plate. Can be provided.

In such an organic EL panel 3,
When a voltage is applied between the front electrode 18 and the rear electrode 20, the carriers injected into the organic EL layer 19 are recombined, and the organic fluorescent material is excited to emit light.

FIG. 3A shows the entire organic EL panel 3. In this case, the rear electrode 20 and the reflection plate 22 are
It functions as a uniform reflector in a plan view. For this reason,
When the display device 1 is used as a reflective liquid crystal display device, the pixels (the front electrode 18 and the rear electrode 20) of the organic EL panel 3 are used.
May be used in a state where no light emission driving voltage is applied between all the front electrodes 18 and all the rear electrodes 20. Therefore, the reflection efficiency is improved, and a display with a high contrast ratio as a reflection type liquid crystal display device can be performed. In addition, since there is a reflector 22 having the same degree of reflectivity between the rear electrodes 20, 20, the display device 1 is uniformly reflected when viewed from the front transparent substrate 4 side. It is possible to perform a good liquid crystal display in which no image is visible. Further, if all the pixels of the liquid crystal display panel 2 are set to the light transmission mode, the organic EL panel 3 can be driven in a simple matrix, and a matrix display other than the uniform luminance surface emission can be performed via the liquid crystal display panel 2.

[0032]

As described above, according to the structure of the EL device of the present invention, short-circuiting of the electrodes can be completely prevented, and a low-temperature, low-damage vacuum deposition method is used for forming the reflective layer. Since there is no necessity, productivity and yield are remarkably improved, and the cost is not increased, and the cost is considerably reduced.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing one embodiment of the present invention.

FIG. 2 is a sectional view of a main part showing an embodiment of the present invention.

FIG. 3A is an explanatory plan view showing a non-light emitting state of all pixels of the organic EL panel in the embodiment, and FIG.
FIG. 2 is a sectional view taken along line II of FIG.

FIG. 4 is a schematic view showing a conventional EL element.

[Explanation of symbols]

 Reference Signs List 17 transparent substrate 18 transparent anode electrode 19 organic EL layer 20 metal cathode electrode 21 transparent insulating film 22 metal reflection layer 23 counter substrate 37 sealing material

Claims (3)

[Claims] A first substrate on which a transparent electrode, an EL layer, and a back electrode are sequentially formed; and a second substrate having a light-reflective reflective layer on a surface facing the first substrate. Characteristic EL element. 2. The EL device according to claim 1, wherein the reflection layer has the same material as the back electrode. 3. The back electrode is a group of a plurality of electrodes spaced apart from each other, and the reflection layer is provided so as to face at least a gap between the back electrodes. 3. The EL device according to 1 or 2.