Forming a thin-film EL element

Abstract

A thin-film EL element which does not permit the color of the emitted light to change irrespective of a change in the voltage, which remains chemically stable and which emits light of high brightness even on a low voltage. The element comprises two or more polycrystalline thin light emitting layers (4, 5, 6) and one or more thin insulating layers (3, 7). The interface between a thin film and a thin film constituting a light emitting layer is formed by epitaxial growth, and the electrical characteristics of the element are equivalent to those of a single circuit which includes two Zener diodes (12, 13) connected in series, a capacitor (14) connected in parallel with the serially connected Zener diodes, and a capacitor (15) connected to one end of the capacitor (14).

Description

TECHNICAL FIELD

The invention relates to a thin-film EL element in which light emitting layers are respectively constituted by thin films.

BACKGROUND ART

Up to this time, various approaches to obtain a newly different color of the emitted light have been made by forming a thin-film EL element in which two or more light emitting layers, each having a different color of emitted light, are laminated together to change the color of the emitted light by the laminated layers.

For example, "Ryozo FUKAO et. al.: Electronic Information Communication Society Technical Study Report, Vol. 86, No. 368, p. 5, 1987" describes such a thin-film EL element as a "two-terminals type tunable color EL", and as a laminate of a green color light emitting layer formed of ZnS:TbF3 and a red color light emitting layer formed of ZnS:SnF3. It is reported herein that, when applying a voltage to such a element, the color of emitted light is changed from red to yellow-green by an increase in the voltage, as shown in FIG. 11. Also, "S. TANAKA et. al.: Digest 1988 SID Int. Symp., P. 293, 1988" describes another thin-film EL element in which a light emitting layer formed of SrS:Ce, K emitting light of blue-green color and a light emitting layer formed of SrS:Eu emitting light of red color are laminated together. It is also reported therein that a change in the voltage causes the color of the emitted light to change.

However, when making a panel for dot matrix display by using such laminated type of thin-film EL elements mentioned above, the effective voltage applied to the light emitting layer depends on the position in accordance with thickness distributions of the light emitting layer and the insulating layer, so that the color of the emitted light can vary with the location. Also, a voltage drop by line resistance of the electrode causes the color of emitted light to change between the bottom and the tip of the electrode. For these reasons, a problem called "nonuniformity of color" has arisen, so that making a useful panel could not be achieved.

It is considered that the above-mentioned problems are caused by the formation of a high resistant layer where crystallinity is low, also called a "dead layer", between the light emitting layer and the insulating layer with the thickness being from approximately 1000 to approximately 2000 .ANG.. The "dead layer" generally occurs in a light emitting layer formed by conventional light emitting layer forming technique, such as EB (Electron Beam) evaporation method or sputtering method (e.g., see "H. SASAKURA et. al.: J. Appl. Phys. 52 (11), 6901, 1981").

When applying a voltage to a thin-film EL element which includes the conventional laminated type of light emitting layers mentioned above, each respective layer functions as independent thin-film EL elements. Such independent EL elements have "luminance--voltage" characteristics which are different from each other, thus causing the color of the emitted light to change in accordance with a change in the voltage.

For example, when the laminated light emitting strata has two layers, as shown in FIG. 12, it has a structure equivalent to that of a double circuit which includes two pairs of Zener diodes a and b, each pair being connected opposite to each other in series; two capacitors c connected in series, each being connected in parallel with the serially connected Zener diodes; and a capacitor d connected to one end of the two capacitors c.

On the other hand, up to the present, there have been various methods for obtaining full color display with a thin-film EL element. Of these, there are two typical types; one type uses a planar pattern formed of three kinds of materials each of which emits light of a respective one of the three primary colors, red (R), green (G) and blue (B) as shown in FIG. 13; the other type laminates such luminescent materials and decomposes the resulting mixed color emitted light by passing it through filters as shown in FIG. 14.

In FIG. 13, there are provided a glass substrate e, transparent electrodes d patterned on the glass substrate e, first and second insulating layers f and g, a segmented light emitting layer h in which each segment emits light of a respective one of the three primary colors and which are patterned between the insulating layers f and g, and a back plate i.

In FIG. 14, the same references as those of FIG. 13 indicate similar elements except a color filter k, and the light emitting layer h in FIG. 14 is formed by laminating three light emitting layers, each emitting a respective one of the three primary colors R, G and B.

However, the former, which is a patterned light emitting layer type, capable of full color display with the conventional thin-film EL element, has had such problems as the forming process being complicated, the light emitting layer being damaged during patterning, and the like.

Although the forming process is simple for the latter, which is a laminated light emitting layer type, the respective materials have different L-V characteristics. Further, the intensity of the electric field effectively applied to the intermediate light emitting layer is lower than that of each adjacent light emitting layer, so that other problems have arisen such that it was difficult to separate beams of light from the respective layers under a well-balanced condition.

In another method which has also been considered, white light, having a wide spectrum obtained from a single light emitting layer, such as SrS:Ce,Eu or the like, is separated by a color filter. However, efficient brightness can not be obtained from the light emitting layer formed of SrS:Ce,Eu and chemical stability of the base material SrS is worse.

SUMMARY OF THE INVENTION

In consideration of the above-mentioned problems, an object of the present invention is to provide a thin-film EL element in which two or more light emitting layers having differing colors of emitted light, are laminated together to emit light of a newly different color such that the thin-film EL element emits light of high brightness, remains chemically stable, and does not permit the color of the emitted light to change irrespective of a change in the voltage.

Further, another object of the present invention is to provide a thin-film EL element in which a thin-film emitting light and a thin-film not emitting light are laminated together so that the thin-film EL element emits light of high brightness even on a low voltage and remains chemically stable.

According to the present invention, a thin-film EL element, which includes two or more thin light emitting layers and one or more thin insulating layers, has electrical characteristics equivalent to those of a circuit which includes two Zener diodes connected in series opposite to each other, a first capacitor connected in parallel with the series circuit of Zener diodes, and another capacitor connected to one end of the first capacitor. The interface between one thin film and another thin film which constitutes a light emitting layer is formed by epitaxial growth.

Further, the light emitting strata constituting the thin-film EL element can be formed by use of methods, such as MSD (Multi-Source Deposition) method or CVD (Chemical Vapor Deposition) method, in which chemical elements constituting a compound or compounds including the chemical elements, are respectively supplied onto a substrate as source materials during formation of a compound thin film and chemically bonded on the substrate to form a desired compound thin film.

A ZnS:Mn film, which introduces Mn as an impurity for luminescence center into a base material ZnS, and a Ba.sub.x Sr.sub.(1-x) S:Ce film which introduces Ce as an impurity for luminescence center into a base material Ba.sub.x Sr.sub.(1-x) S (0.ltoreq.x.ltoreq.1) are used to produce a composite light emitting strata constituted by the three layers: ZnS:Mn/Ba.sub.x Sr.sub.(1-x) S:Ce/ZnS:Mn.

According to another aspect of the present invention, the light emitting strata can be formed by use of ZnS:Tb,Mn films, which introduce Tb and Mn as impurities for luminescence center into a base material ZnS, and a Ba.sub.x Sr.sub.(1-x) S:Ce film, which introduces Ce as an impurity for luminescence center into a base material Ba.sub.x Sr.sub.(1-x) S (0.ltoreq.x.ltoreq.1).

Three thin films of the above-mentioned materials are laminated together to form the light emitting strata constituted by the three layers: ZnS:Tb,Mn/Ba.sub.x Sr.sub.(1-x) S:Ce/ZnS:Tb,Mn.

According to another aspect of the present invention, Zn and Ba.sub.x Sr.sub.(1-x) S:Ce,Eu, which introduces Ce and Eu as impurities for luminescence center into the base materials Ba.sub.x Sr.sub.(1-x) S, can be used for thin film of the light emitting strata.

Then, thin films of the above-mentioned materials can be formed into the light emitting strata constituted by the three layers: ZnS/Ba.sub.x Sr.sub.(1-x) S:Ce,Eu/ZnS.

In at least the neighborhood of the interface between each ZnS thin film and the Ba.sub.x Sr.sub.(1-x) S thin film in the light emitting strata, the crystal orientation of the ZnS thin film is oriented to the zinc blende structure �111! and/or the wurtzite structure �001!, and the crystal orientation of the Ba.sub.x Sr.sub.(1-x) S thin film is oriented to �111! and/or �110!.

According to another aspect of the present invention, the thin films constituting the light emitting strata are the three layers: ZnS/Y.sub.2 O.sub.2 S:Ce,Eu/ZnS, which introduce Ce and Eu as impurities for luminescence center into base materials ZnS and Y.sub.2 O.sub.2 S, or the three layers: ZnS/Y.sub.2 O.sub.2 S:Ce,Tb,Eu/ZnS which introduce Ce, Tb and Eu as impurities for luminescence center into base materials ZnS and Y.sub.2 O.sub.2 S.

Then, a color filter is placed on the lower or upper side of the laminated light emitting strata, an electrode of the substrate side and an electrode opposite to the substrate side are patterned to intersect each other perpendicularly, and the color filter is placed on the lower or upper side of the intersecting portion.

Further, three kinds of filters are used for the above-mentioned color filter, each transmitting light of a respective one of the three primary colors, red, green and blue, and being periodically disposed.

The electrically equivalent circuit of the thin-film element has the structure mentioned above so that the electrical characteristics of the thin-film element are equivalent to those of a thin-film element including a single light emitting layer. As a result, the "luminance--voltage" characteristic of the thin-film EL element is equal to that of the thin-film element including the single light emitting layer. Accordingly, the thin-film EL element, in which two or more thin films, having different colors of emitted light, are laminated, can not cause the color of the emitted light to change irrespective of a change in the voltage.

Further, the thin-film EL element, in which a thin film emitting light and a thin film not emitting light are laminated together, can remain chemically stable and emit light of high brightness even on a low voltage.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view of a thin-film EL element according to the first embodiment of the present invention;

FIG. 2 is a conceptual diagram of an apparatus used for MSD method;

FIG. 3 is a circuit diagram of a circuit electrically equivalent to the thin-film EL element according to the first embodiment; and

FIG. 4 is a graph showing a luminance--voltage characteristic of the thin-film EL element according to the first embodiment.

FIG. 5 is a graph showing transferred charge density--voltage characteristics between a conventional thin-film EL element and a thin-film EL element according to the second embodiment of the present invention; and

FIG. 6 is a graph showing luminance voltage characteristics between the conventional EL element and the EL element according to the second embodiment.

FIG. 7 is a cross-sectional view of a thin-film EL element according to the third embodiment of the present invention;

FIG. 8 is a graph showing a luminance voltage characteristic of the thin-film EL element according to the third embodiment; and FIG. 9 iS a graph showing an emission spectrum of the thin-film EL element obtained from the third embodiment.

FIG. 10 is a graph showing luminance--voltage characteristics of thin-film EL elements according to the fourth embodiment.

FIG. 11 is a graph showing a luminance--voltage characteristic of a conventional laminated type thin film EL element;

FIG. 12 is a circuit diagram of a circuit electrically equivalent to the conventional laminated type thin-film EL element;

FIG. 13 is a cross-sectional view of a first conventional thin-film EL element; and

FIG. 14 is a cross-sectional view of a second conventional thin-film EL element.

BEST MODE FOR CARRYING OUT THE INVENTION

The first embodiment of the present invention will be described with reference to FIGS. 1 to 4.

In this embodiment, a thin-film EL element will be described, in which the light emitting strata is constituted by the three layers: ZnS:Mn/Ba.sub.0.1 Sr.sub.0.9 S:Ce/ZnS:Mn. FIG. 1 shows an example of this structure which includes a glass substrate 1, a first electrode 2 formed of transparent electrode material, a first insulating layer 3 formed of SION, a first light emitting layer 4 formed of ZnS:Mn, a second light emitting layer 5 formed of Ba.sub.0.1 Sr.sub.0.9 S:Ce, a third light emitting layer 6 formed of ZnS:Mn, a second insulating layer 7 formed of SION, and a second electrode 8 formed of Al, and which is laminated in due order as shown in the drawing.

FIG. 2 conceptually shows an MSD apparatus for forming such a laminated structure, in which the glass substrate 1 is held, facing downwardly, by a substrate holder 10 in an upper portion of a vacuum chamber 9, and chemical elements for forming a light emitting layer are separately put in respective vacuum evaporation sources 11 and disposed opposite to each other in the lower portion of the vacuum chamber 9.

The process of forming a thin-film EL element according to the present invention will be described hereinbelow.

At first, an ITO (Indium Tin Oxide) film of 1 .mu.m thickness is formed on the glass substrate 1 as the first electrode 2, by use of a sputtering method; and then a SiON film of 0.15 .mu.m thickness is formed thereon as the first insulating layer 3, similarly by a sputtering method.

The thus processed glass substrate 1 is held by the substrate holder 10 in the vacuum chamber 9 to form the first light emitting layer by use of an MSD method. That is, chemical elements Zn, S and Mn are put in their respective vacuum evaporation sources 11 in the vacuum chamber 9, and the vapors of these elements are independently supplied by individual temperature control onto the first insulating layer 3 on the glass substrate 1 to be chemically bonded thereon, so that the first light emitting layer 4 is formed.

After forming the first light emitting layer 4, the chemical elements Ba, Sr, S and Ce are put in their respective vacuum evaporation sources 11 in the same chamber 9, and the vapors of these elements are independently supplied by individual temperature control onto the first light emitting layer 4 to be chemically bonded thereon, so that the second light emitting layer 5 is formed. Here, the temperature settings of the elements Ba and Sr in the vacuum evaporation sources 11 can be changed so that the concentration x of Ba and the concentration (1-x) of Sr in the Ba.sub.x Sr.sub.(1-x) S:Ce compound can be freely adjusted from 0 to 1.

The third light emitting layer 6 is formed on the second light emitting layer 5 in the same manner as described in the process of the first light emitting layer 4.

Next, after forming the light emitting layers mentioned above, a SiON film of 0.15 .mu.m thickness is formed as the second insulating layer 7 on the upper light emitting layer 6 by the sputtering method, and finally an Al film is formed as the second electrode 8 on the second insulating layer 7 by electron beam evaporation method.

The second and third light emitting layers 5 and 6, formed in a manner as described above are formed by epitaxial growth on the earlier formed light emitting layer 4 or 5, respectively.

For this, electrons can jump between the respective light emitting layers 4, 5 and 6 laminated in due order, so that the electrical characteristics of the light emitting strata are equivalent to those of a circuit shown in FIG. 3 which includes two Zener diodes 12 and 13 connected opposite to each other in series, a capacitor 14 connected in parallel with the serially connected Zener diodes, and a capacitor 15 connected to one end of the capacitor 14.

The structure is equal to a thin-film EL element having a single light emitting layer.

In addition, the epitaxial growth in this case means that, in the growth of a polycrystalline thin film on a polycrystalline thin film, grains constituting the later formed polycrystalline thin film grow by forming the same lattice as that of the base polycrystalline thin film.

FIG. 4 shows a "luminance--voltage" characteristic of the thin-film EL element formed in the above-mentioned embodiment. Here, the luminance of white light emitted from the thin-film EL element increases substantially linearly in accordance with the increase of the voltage. This characteristic corresponds to that of the thin-film EL element having the single light emitting layer and which has a circuit electrically equivalent to that of the single light emitting layer. Accordingly, the thin-film EL element according to this embodiment of the present invention does not permit the color of the emitted light to change, similar to the thin-film EL element including the single light emitting layer, irrespective of a change in the voltage.

On the other hand, the respective light emitting layers 4, 5, and 6 constituting the above-mentioned three layers can be replaced with other strata wherein each of the first light emitting layer 4 and the third light emitting layer 6 is constituted of a ZnS:Tb,Mn thin film which introduces Tb and Mn as impurities for luminescence center into the base material ZnS, and the second light emitting layer 5 laminated between the layers 4 and 6 is constituted of the Ba.sub.x Sr.sub.(1-x) S:Ce (0.ltoreq.x.ltoreq.1) thin film.

The Ba.sub.x Sr.sub.(1-x) S:Ce, the intermediate layer in the first embodiment, is not as chemically stable as the ZnS:Mn or the ZnS:Tb,Mn layers on either side thereof.

In the light emitting layers 4, 5 and 6, constituting the triple layer strata of the first embodiment, the first and third light emitting layers 4 and 6 are constituted of ZnS:Mn or ZnS:Tb,Mn and can emit light of high brightness in a color range from green to red; while the second light emitting layer 5, constituted of Ba.sub.x Sr.sub.(1-x) S:Ce, for example in the case of x=0, emits light of high brightness in a color range from blue to green.

Here, the three layer light emitting strata according to the first embodiment has the structure in which the second light emitting layer 5, constituted of SrS:Ce and chemically unstable, is sandwiched between the first and third light emitting layers 4 and 6 constituted of ZnS:Mn or ZnS:Tb,Mn and remaining chemically stable, so that the first and third light emitting layers 4 and 6 can serve as a passivation of the second light emitting layer 5, thus, making the overall light emitting strata chemically stable.

Next, a second embodiment of the present invention will be described.

If a thin-film EL element is formed in accordance with the process of forming light emitting strata shown in the first embodiment and the electrically equivalent circuit thereof is equivalent to the circuit of FIG. 3, which includes two Zener diodes 12 and 13 connected opposite to each other in series, a capacitor 14 connected in parallel with the serially connected Zener diodes, and a capacitor 15 connected to one end of the capacitor 14, the thin light emitting strata of the thin-film EL element can constitute the three layers: ZnS/Ba.sub.x Sr.sub.(1-x) S:Ce,Eu/ZnS which introduce Ce and Eu as impurities for luminescence center into base material and Ba.sub.x Sr.sub.(1-x) S (0.ltoreq.x.ltoreq.1).

Two kinds of thin-film EL elements are made on an experimental basis to compare the characteristics. The first one is a thin-film EL element which includes a structure in accordance with the second embodiment having the three layers ZnS/Ba.sub.0.1 Sr.sub.0.9 S:Ce,Eu/ZnS; the second one is a conventional type thin-film EL element B having the electrical characteristics of the element equivalent to those of the conventional circuit, as shown in FIG. 12, which includes two pairs of Zener diodes a and b, each pair being connected opposite to each other in series, two capacitors c connected in series, each being connected in parallel with the serially connected Zener diodes, and a capacitor d connected to one end of the two capacitors c.

The result of comparing and evaluating the characteristics will be described below.

The process of making the trial light emitting strata of the second embodiment is the same as that of the first embodiment, while the trial light emitting strata of the conventional element is formed by the electron beam method. Both of the elements are the same as those of the first embodiment except for the portion of the light emitting strata.

FIG. 5 shows the result of evaluation, in which the voltage dependence of the transferred charge density (dQ) is evaluated as an electrical characteristic. That is, the increase of the dQ value of the element made according to the second embodiment gives an essentially straight line as the voltage increases from 160 V, while the line for the conventional element bends at 200 V. These phenomena correspond to the respective electrical structures, the electrically equivalent circuit of the element made according to the second embodiment being shown in FIG. 3 and the electrically equivalent circuit of the conventional element being shown in FIG. 12.

FIG. 6 shows luminance--voltage characteristics, in which the element made according to the second embodiment starts emitting light at a lower voltage than the conventional element. The luminance increases as the voltage rises, so that the element made according to the second embodiment emits light of higher brightness than that of the conventional element at the same voltage.

Further, a Y.sub.2 O.sub.2 S:Ce,Eu thin film or a Y.sub.2 O.sub.2 S:Ce,Tb,Eu thin film, which introduces Ce and Eu, or Ce, Tb and Eu as impurities for luminescence center into the base material Y.sub.2 O.sub.2 S, can be used as the thin-film of the intermediate layer of the strata ZnS/Ba.sub.x Sr.sub.(1-x) S:Ce,Eu/ZnS to obtain the same evaluation as the case mention above.

Next, the third embodiment of the present invention will be described.

A structure of an element according to the third embodiment includes a color filter 16 inserted between the glass substrate I and the insulating layer 3 as shown in FIG. 7. For the color filter 16, a filter (R), a filter (G) and a filter (B), respectively transmitting light of red (R), green (G) and blue (B), are periodically disposed.

Also, in the thin-film EL element using such a color filter 16, the electrode 2 of the glass substrate I side and the electrode 8 opposite to the substrate side are patterned to intersect each other perpendicularly, so that the color filter 16 can be placed on the lower or upper side of the intersecting portion.

FIG. 8 shows a luminance--voltage characteristic of the element according to the third embodiment, and FIG. 9 shows an emission spectrum previous to transmitting light through the color filter 16. From FIGS. 8 and 9, the element of the third embodiment can emit light of highly bright red (R), green (G) and blue (B) by dividing the wide emission spectrum with the color filter 16.

Next, the fourth embodiment of the present invention will be described.

As thin films constituting a light emitting strata of the fourth embodiment, three kinds of thin-film EL elements are made on an experimental basis by separately combining three kinds of Ba.sub.x Sr.sub.(1-x) S:Ce thin films, having the respective crystal orientations of �100!, �110!, and �111!, with the ZnS:Mn thin films, having the crystal orientation of wurtzite structure �001!. An example of comparing the characteristics will be described below.

The ZnS:Mn thin film, oriented to the wurtzite structure �001!, is obtained by use of the MSD method for forming the film in a predetermined condition.

Also, the crystal orientation of the Ba.sub.x Sr.sub.(1-x) S:Ce thin film can be controlled by changing the ratio of the supply amount of Ba and Sr to S (Ba,Sr/S) with the same MSD method (see "S. TANDA, A. MIYAKOSHI and T. NIRE: Conference Record of the 1988 International Display Research Conference, P. 122").

The structure of the element according to the fourth embodiment is the same as that of the first embodiment and the forming method is also the same except for the film forming conditions of the light emitting strata.

FIG. 10 shows luminance--voltage characteristics of thin-film EL elements which use the Ba.sub.x Sr.sub.(1-x) S:Ce thin films having the respective crystal orientations of �100!, �110! and �111!, and which respectively include structures of �100!, �110! and �111!. Although all of these elements �100!, �110! and �111! do not permit the color of the emitted light to change irrespective of a change in the voltage, the luminances of �111! and �110! are higher than that of �100!. That is because the lattice coordination of the crystal orientation of the ZnS thin film is high with respect to the side of zinc blende structure �111! or the wurtzite structure �001! and the lattice coordination of the Ba.sub.x Sr.sub.(1-x) S thin film is high with respect to the side of �111! or �110!, i.e., a gap of bond distance between lattices is small so that the crystal distortion and the lattice defect can be reduced, thereby obtaining a thin-film EL element enabling emission of light of higher brightness.

INDUSTRIAL APPLICABILITY

The present invention can be effectively used for a thin-film EL element which does not permit the color of the emitted light to change irrespective of a change in the voltage, which emits light of high brightness even on a low voltage, and which remains chemically stable. Also, the present invention can provide a thin-film EL display capable of full color display by combining a filter therein.

Claims

1. A process for forming a thin-film EL element which comprises:

forming a first electrode layer on a substrate,

forming a first insulator layer on said first electrode layer, thereby forming an initial laminate,

utilizing one of a Multi-Source Deposition Method and a Chemical Vapor Deposition Method to expose a surface of said first insulator layer of said initial laminate in a vacuum chamber to vapors of chemical elements to be chemically bonded to said surface of said first insulator layer to form a first polycrystalline light emitting layer, and

utilizing one of a Multi-Source Deposition Method and a Chemical Vapor Deposition Method to supply onto a surface of said first light emitting layer, while said surface of said first light emitting layer is exposed in a vacuum chamber, vapors of chemical elements to be chemically bonded to said surface of said first light emitting layer to form a second polycrystalline light emitting layer by epitaxial growth on said surface of said first light emitting layer,

wherein each of said first and second polycrystalline light emitting layers comprises a base material and is capable of emitting light, with the base material of said first polycrystalline light emitting layer being different from the base material of said second polycrystalline light emitting layer and with the color of light emitted by said first polycrystalline light emitting layer being different from the color of light emitted by said second polycrystalline light emitting layer;

wherein the step of supplying vapors of chemical elements onto a surface of said first insulator layer comprises supplying vapors of Zn and S, and wherein the step of supplying vapors of chemical elements onto a surface of said first polycrystalline light emitting layer comprises supplying vapors of Ba, Sr, and S.

2. A process in accordance with claim 1, further comprising utilizing one of a Multi-Source Deposition Method and a Chemical Vapor Deposition Method to supply onto a surface of said second polycrystalline light emitting layer, while said surface of said second polycrystalline light emitting layer is exposed in a vacuum chamber, vapors of chemical elements to be chemically bonded to said surface of said second polycrystalline light emitting layer to form a third polycrystalline light emitting layer by epitaxial growth on said surface of said second polycrystalline light emitting layer,

wherein said third polycrystalline light emitting layer comprises a base material and is capable of emitting light, with the base material of said third polycrystalline light emitting layer being different from the base material of said second polycrystalline light emitting layer and with the color of light emitted by said third polycrystalline light emitting layer being different from the color of light emitted by said second polycrystalline light emitting layer, whereby said first, second and third polycrystalline light emitting layers form a composite light emitting strata.

3. A process in accordance with claim 2, wherein each step of utilizing one of a Multi-Source Deposition Method and a Chemical Vapor Deposition Method to supply vapors of chemical elements comprises providing a plurality of source materials, and independently controlling the temperature of each of said source materials.

4. A process in accordance with claim 2, further comprising forming on a surface of said third polycrystalline light emitting layer a second insulator layer, and forming on a surface of said second insulating layer a second electrode layer.

5. A process in accordance with claim 4, wherein the base material of each of said first and third polycrystalline light emitting layers is ZnS.

6. A process in accordance with claim 5, wherein the base material of the second polycrystalline light emitting layer consists of Ba.sub.x Sr.sub.(1-x) S:Ce,Eu where 0.ltoreq.x.ltoreq.1.

7. A process in accordance with claim 6, wherein each of said first and third polycrystalline light emitting layers comprises ZnS:Mn.

8. A process in accordance with claim 6, wherein each of said first and third polycrystalline light emitting layers comprises ZnS:Tb,Mn.

9. A process in accordance with claim 5, wherein the second polycrystalline light emitting layer consists of Ba.sub.x Sr.sub.(1-x) S:Ce where 0.ltoreq.x.ltoreq.1.

10. A process in accordance with claim 9, wherein each of said first and third polycrystalline light emitting layers comprises ZnS:Tb,Mn.

11. A process in accordance with claim 9, wherein each of said first and third polycrystalline light emitting layers comprises ZnS:Mn.

12. A process in accordance with claim 11, wherein each of said first and third polycrystalline light emitting layers is formed with a crystal orientation of at least one of the zinc blende structure �111! and the wurtzite structure �001!, and wherein said second polycrystalline light emitting layer is formed with a crystal orientation of at least one of �111! and �110! at each interface of said second polycrystalline light emitting layer with one of said first and second polycrystalline light emitting layers.

13. A process in accordance with claim 12, wherein the crystal orientation of said second polycrystalline light emitting layer is controlled by changing the ratio, of the amounts of Ba and Sr to the amount of S supplied to the vacuum chamber, during the formation of the second polycrystalline light emitting layer.