JPH05101891A - Full color thin film el panel and display device - Google Patents

Abstract

PURPOSE:To independently control the respective colors R, G, B by dividing a first transparent electrode in two while providing a second transparent electrode having an area corresponding to one picture element between the second and third dielectric layers. CONSTITUTION:ITO is laid on a glass substrate 1 to be patterned so as to form two stripe-shaped electrodes as the first transparent electrodes 21a, 21b. Thereon a first dielectric layer 31, a first luminous layer 41 (ZnS:Tb, F4000nm), a second dielectric layer 32 are laid so as to form a first green-luminous EL layer 61. The ITO is formed in an island shape corresponding to one picture element for being made a common electrode 22. Next, a third dielectric layer 33, a second luminous layer 42 (SnS:Ce, F450nm) and a fourth dielectric layer 34 are laid thereon to form a second blue-luminous EL layer followed by forming a second stripe-shaped transparent electrode 23 orthogonal to an electrode 21. Thereon a fifth dielectric layer 34, a third luminous layer 43 (CaS:Eu, F4500nm), a dielectric layer 35 are laid for being made a red-luminous EL layer 63 so as to form a back plate 5 in parallel with the electrode 21.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thin film flat panel display used for an information terminal of OA equipment, and more particularly to a full color thin film EL panel capable of full color display and a display device using the full color EL panel.

[0002]

2. Description of the Related Art As a color flat panel display using a thin film EL device, two types of structures have been proposed, as shown below. One is a structure in which light emitting layers of a single color are stacked (hereinafter referred to as a stacked type), and the other is a structure in which light emitting layers are arranged in a plane (hereinafter referred to as a planar array type).

FIG. 4 shows an example of a laminated type in which a transparent electrode 2 is deposited on a glass substrate 1, and a dielectric layer 31, a first light emitting layer 41, a dielectric layer 32, a second light emitting layer 42, Dielectric layer 3
3 and a back electrode 5 is finally deposited. In this structure, ZnS: Tb, F is formed in the first light emitting layer.
, And there is a tunable EL using ZnS: Sm, F in the second light emitting layer (Science Technical Report Vol.86, No.386, P).
5). Although this element has the advantage that it is relatively simple in structure and easy to manufacture as a color EL element,
The operation is, as shown in FIG. 5, ZnS that emits red light:
It utilizes the difference in the emission start voltage (Vth) of Sm, F and ZnS: Tb, F that emits green light. When the voltage applied to the element is increased, it changes from red to orange, yellow, and yellow-green. However, it is not possible to obtain green light emission.

There is a system shown in FIG. 6 as a laminated type structure for independently controlling a plurality of colors. The transparent signal electrode 21 on the glass substrate 1 and the signal electrode 5 on the back surface are each divided into two, and the first light emitting layer 41 is sandwiched between the first dielectric layer 31 and the second dielectric layer 32. The first EL layer 61 and the second light emitting layer 42 sandwiched between the third dielectric layer 33 and the fourth dielectric layer 34
The dielectric layers of the EL layer 62 of two colors are laminated via the scanning (transparent) electrode 22, and the first EL layer 61 and the second EL layer are formed by the scanning electrode 22, the signal electrode 21, and the signal electrode 5.
The layer 62 emits light individually or simultaneously.

By the way, in order to obtain full color, R,
G and B light emitting layers of three colors have to be laminated, and in the case of a three-layer structure having such a structure, as shown in FIG. 7, the scanning electrode 5 and the scanning electrode 22, the signal electrode 21 and the signal electrode 23 are formed. Since it is a combination of two groups, it is impossible to emit light in the first EL layer 61 and the third EL layer 63 without causing the second EL layer 62 to emit light, and thus it is difficult to display full color at the same time.

On the other hand, a full-color EL element as shown in FIG. 8 has also been proposed as a planar array type (Japanese Patent Laid-Open No. 61-1).
3597, JP-A-02-257952). Glass substrate 1
The transparent electrode 2 is deposited on top, and the dielectric layer 31 is further deposited. Light-emitting layers 41, 42, 4 showing the respective R, G, B emission colors
3 is deposited and patterned, and then the dielectric layer 3
2. The back electrode 5 is deposited. According to this method, R, G, and B colors can be independently controlled and full color can be realized. However, compared with the above-mentioned stacking method, the light emitting area is smaller because each light emitting section is provided independently. The driving voltage must be increased in order to reduce the brightness and obtain the same brightness. Further, the formation of the patterns of the light emitting layers 41, 42, 43 is performed by photolithography and etching. At this time, the light emitting layer is exposed to a resist or the like, which leads to deterioration of characteristics of the EL element and deterioration of reliability. There was also.

[0007]

A laminated full-color thin film EL panel capable of independently controlling R, G and B colors and a display device using this element are provided.

[0008]

A first electrode formed in a stripe shape for applying a drive voltage to a first EL layer and divided into two substantially equal stripe electrodes, and a second E layer.
A second electrode formed in a stripe shape so that a driving voltage is applied to the L layer so as to intersect with the first electrode, and a shape substantially equal to the shape of the intersection of the second electrode and the first electrode. And a common electrode common to the island-shaped first EL layer and the second EL layer, and the third EL in cooperation with the second electrode.
Stripe-shaped third layer for supplying a driving voltage to the layer
And the electrodes of (1) and (2) form a laminated full-color thin film EL panel. In the display device using the above-described laminated full-color thin film EL panel, control for selectively controlling the voltage applied to the two divided stripe electrodes of the first electrode, the second electrode, and the third electrode Means are provided.

[0009]

[Function] The first transparent electrode is divided into two parts, the second dielectric layer and the third dielectric layer.
By providing a second transparent electrode having an area corresponding to one pixel between the dielectric layers, one of the two divided first transparent electrodes is grounded and the other is floating, and a voltage is applied from the third transparent electrode. When applied, the capacitance (C ₁ ) of the capacitor composed of the first dielectric layer, the first light emitting layer (G) and the second dielectric layer
Is smaller than the capacitance (C ₂ ) of the capacitor composed of the third dielectric layer, the second light emitting layer (B) and the fourth dielectric layer,
Most of the applied voltage is applied to C ₁ , and the first light emitting layer emits light, but the second light emitting layer does not emit light. (G: on, B: off) If both of the divided first transparent electrodes are grounded, C
_1, since C is ₂ the same voltage is applied, is made smaller the light emission start voltage Vth ₂ of the EL unit consisting of the capacitance of C ₂ with respect to the emission start voltage Vth ₁ of the EL unit consisting of the capacitance of C ₁ When,
The second light emitting layer emits light, but the first light emitting layer does not emit light.
(G: on, B: off) When the divided first transparent electrode is grounded and the voltage applied to the third transparent electrode is increased, both the first light emitting layer and the second light emitting layer can emit light. (G: on, B: on) If both the first transparent electrodes are floating,
No voltage is applied to C ₁ and C ₂ , and neither the first light emitting layer nor the second light emitting layer emits light. (G: off, B: off) The EL portion including the fifth dielectric layer, the third light emitting layer (R), and the sixth dielectric layer has the first light emitting layer and the second light emitting layer due to the grounding and floating of the back electrode 5. It can be controlled independently of the layers. (R:
on, off) Therefore, R, G, B and mixed colors thereof can be obtained.

[0010]

Embodiments of the present invention will be described with reference to the drawings. 1A and 1B are views showing the configuration of a full-color EL panel of the present invention, in which FIG. 1A is a sectional view of the structure and FIG. 1B is a plan view.

An ITO film is formed on the glass substrate 1 and etched by a usual method to form a line width of 75 with a pitch of 10 μm.
Two stripe-shaped electrodes of μm are formed to be the first transparent electrodes 21a and 21b. A first dielectric layer 31, a first light emitting layer 41 (ZnS: Tb, F400 nm), and a second dielectric layer 32 are continuously deposited on the first dielectric layer 31 to form a first EL layer 61 that emits green light. Next, an ITO film is deposited and formed in an island shape in an area (160 μm × 160 μm) corresponding to one pixel to form the common electrode 22. A third dielectric layer 33 and a second dielectric layer 33
The light emitting layer 42 (SrS: Ce, F 450 nm) and the fourth dielectric layer 34 are deposited to form a second EL layer 62 that emits blue light, and then ITO is deposited thereon to form the first transparent electrode 21. The second transparent electrodes 23 are formed in stripes (line width 160 μm) so as to be orthogonal to each other. A fifth dielectric layer 34 thereon,
Third light emitting layer 43 (CaS: Eu, F 450 nm), sixth
After the dielectric layer 35 is deposited to form the third EL layer 63 that emits red light, Al is deposited on the dielectric layer 35 to form a stripe shape (line width 160 μm) in parallel with the first transparent electrode 21 to form the third EL layer 63. The electrode (back electrode) 5 is used. Each of the first to sixth dielectric layers 31 to 36 was made of Ta ₂ O ₅ and had a thickness of 300 nm.

In this case, since the capacitance per unit area between the electrodes is constant, the capacitance of each pixel is determined by the electrode area. The operation will be described with reference to the equivalent circuit of FIG. The external extraction electrodes of this EL element are ITO ₁ (a) (corresponding to the first electrode 21a of FIG. 1), ITO ₁ (b) (first electrode of FIG. 1).
The electrode 21b), ITO ₃ (corresponding to the second electrode 23 in FIG. 1), and Al (corresponding to the third electrode 5 in FIG. 1) are four, and the voltage is independently applied to each electrode from the control means. Is applied. Here, the common electrode 2 formed in an island shape
2 is floated.

Consider the case where a voltage Va is applied from ITO ₃ . When both ITO ₁ (a) and ITO ₁ (b) are floating, no voltage is applied to the capacitance Cg of the first EL layer 61 and the capacitance Cb of the second EL layer 62.

[0014] ITO ₁ (a), when grounded either the ITO ₁ (b), when the capacitance Cg of the 1EL layer 61 parts and C ₀ capacitor Cb of the 2EL layer 62 parts 2C ₀ becomes, respectively The voltage applied to the capacitor is Vg≈2 / 3Va, Vb≈1 / 3
It becomes Va. When both ITO ₁ (a) and ITO ₁ (b) are grounded, the capacitance Cg of the first EL layer 61 part and the capacitance Cb of the second EL layer 62 part are almost equal, and the voltage applied to each capacitance is almost the same. They are equal, and Vg≈Vb≈1 / 2Va.

Here, the light emission starting voltage of the first EL layer 61 portion using ZnS: Tb, F for the light emitting layer 41 is Vth (g), and the second EL layer 62 portion using SrS: Ce, F for the light emitting layer 42 portion. Let the light emission start voltage of Vth (b) be 1 / 2Va <Vth (g) <2 / 3Va, 1 / 3Va <Vth (b)
If Va and the respective Vths are set so that the relationship of <1 / 2Va is established, when either ITO ₁ (a) or ITO ₁ (b) is grounded, the first EL layer 61 part One light emitting layer (ZnS: Tb, F) 41 emits green light, and ITO
_{When both 1} (a) and ITO ₁ (b) are grounded, the second light emitting layer (SrS: Ce, F) 42 of the second EL layer 62 part emits blue light. Further, if both the ITO ₁ (a) and the ITO ₁ (b) are grounded and the applied voltage from the ITO ₃ is increased so that Vth (g) <1 / 2Va ', the first EL layer and the Each light emitting layer of the second EL layer (ZnS: Tb, F, SrS: C
Both e and F) can emit light.

When either ITO ₁ (a) or ITO ₁ (b) is grounded, the light emitting area of the first EL layer (ZnS: Tb, F) is half that of one pixel. 1 light emitting layer (ZnS:
The brightness of Tb, F) is the second light emitting layer (SrS: Ce, F),
Since it is higher than the luminance of the third light emitting layer (CaS: Eu, F), there is no problem.

When the third electrode 5 (Al) is floating, no voltage is applied to the capacitance Cr of the third EL layer 63 portion using CaS: Eu, F (Vr = 0), and Electrode 5
When grounded, the applied voltage Va from the second electrode ITO ₃ is applied (Vr = Va). Light emitting layer of the third EL layer (CaS:
Eu, F) 43 when the light emission start voltage Vth (r) is 0 <Vth (r) <Va, the third electrode 5 is grounded or floated to emit a red light emitting layer (CaS: Eu, F). 43
It is possible to control whether or not to emit light.

Therefore, the first electrodes ITO ₁ (a) and ITO ₁ (b)
Then, the grounding state of the third electrode Al and the state of each light emitting layer with respect to the voltage applied from the second electrode ITO ₃ are as shown in FIG. 3, and full color display can be performed.

The line width of the divided electrodes is not limited to 1: 1 and may be changed according to the brightness of each light emitting layer. Further, the divided electrode may be the third electrode made of Al instead of the first electrode, and it is desirable to divide the third electrode in terms of wiring resistance. In that case, the third EL layer and the second
A transparent electrode provided between the EL layers is patterned into a pixel size to be a common electrode, and a transparent electrode between the first EL layer and the second EL layer is used as a second electrode from the second electrode to the first EL layer. A voltage is applied to the second EL layer.

The order of stacking the light emitting layers is not limited to the order shown in the embodiment, but the green light emitting layer (ZnS: Tb,
Since the emission brightness of F) is higher than that of the blue light emitting layer (SrS: Ce, F) and the red light emitting layer (CaS: Eu, F), the light emitting layer closest to the divided electrodes is the green light emitting layer (ZnS). : T
b, F) is desirable.

[0021]

The full color thin film EL panel of the present invention is
Since the light emitting layer does not have to be exposed to photolithography and etching steps in stacking, reliability can be improved, and by controlling the voltage applied to each electrode,
The emission of each color of R, G, B can be controlled independently, and a highly reliable full-color EL panel can be obtained.

[Brief description of drawings]

FIG. 1 is a cross-sectional view and a plan view of a laminated EL device of the present invention.

FIG. 2 is an equivalent circuit diagram of a laminated EL device of the present invention and an explanation of its operation.

FIG. 3 is an illustration of a relationship between a state of each electrode and a light emitting state of the laminated EL device of the present invention.

FIG. 4 Conventional stacked EL (tunable color EL)
The figure which shows the structural example.

FIG. 5 is a diagram showing operating characteristics of a tunable color EL.

FIG. 6 is a view showing a structural example of a conventional laminated EL (two light emitting layers).

FIG. 7 is a diagram showing a structure of a conventional stacked EL (three light emitting layers).

FIG. 8 is a cross-sectional view showing a planar array type full-color EL panel structure.

[Explanation of symbols]

1 glass substrate, 2 transparent electrodes, 21a, 21b
1st transparent electrode 22 2nd transparent electrode, 23 3rd transparent electrode, 31.
..36 Dielectric layer 41 First light emitting layer, 42 Second light emitting layer, 43 Third
Light-Emitting Layer 5 Back Electrode, 61 First EL Layer, 62 Second E
L layer 63 Third EL layer, Cg ZnS: Tb, F EL element capacitance Cb SrS: Ce, F EL element capacitance Cr CaS: Eu, F EL element capacitance Vg ZnS: Tb, F EL element capacitance Vb SrS: Ce, F EL element capacitance Vr CaS: Eu, F EL element capacitance

Claims (2)

[Claims] 1. A full-color thin-film EL panel in which three or more thin-film EL elements exhibiting different emission colors are laminated on the same substrate, and the opposing electrodes of the thin-film EL elements adjacent to each other in the stacking direction are common to each other. In the first EL layer, the first electrode is divided into two substantially equal stripe electrodes for applying a driving voltage to the first EL layer, and the first EL layer is formed in a stripe shape for applying a driving voltage to the second EL layer. A second electrode arranged to intersect with the electrode; and a second electrode formed in a shape substantially equal to the shape of the intersection of the first electrode and the second electrode and in an electrically floating state. A common electrode common to the first EL layer and the second EL layer, and a third electrode formed in a stripe shape that supplies a driving voltage to the third EL layer in cooperation with the second electrode. Characterized by having Full-color thin film EL panel. 2. A full-color thin film EL in which three or more thin film EL elements exhibiting different emission colors are laminated on the same substrate, and the thin film EL elements adjacent to each other in the stacking direction share a common electrode. In a full-color thin-film EL display device comprising a panel and a control means for controlling light emission of the full-color thin-film EL panel, the first EL layer is divided into two substantially equal stripe electrodes for applying a driving voltage to the first EL layer. An electrode, a second electrode formed in a stripe shape for applying a drive voltage to the second EL layer and arranged so as to intersect with the first electrode, the first electrode and the second electrode A common electrode common to the first EL layer and the second EL layer, the common electrode having a shape substantially equal to the shape of the intersecting portion and formed in an electrically floating state; Wherein the third third electrodes formed in stripes for supplying a driving voltage to the EL layer Te first
Full-color thin film comprising: two divided striped electrodes of the above electrode, and a control unit having a light emission control unit for independently controlling the voltage applied to the second electrode and the third electrode. EL panel display device.