CN103579508A - Organic electroluminescent device and manufacturing method thereof - Google Patents

Abstract

An organic electroluminescent device comprises an anode substrate, a hole injection layer, a hole transmission layer, a luminous layer, an electron transmission layer, an electron injection layer and a cathode layer, wherein the anode substrate, the hole injection layer, the hole transmission layer, the luminous layer, the electron transmission layer, the electron injection layer and the cathode layer are stacked up in sequence. The materials of the electron transmission layer include an electron transmission material and first alkali carbonate doped in the electron transmission material, the doped mass percent concentration of the first alkali carbonate is 3%-8%. The materials of the electron injection layer include a main material, an n-type material and second alkali carbonate, the n-type material and the second alkali carbonate are jointly doped in the main material, and the doped mass percent concentration of the second alkali carbonate is 5%-10%. The first alkali carbonate and the second alkali carbonate are respectively selected from one of lithium carbonate, sodium carbonate, potassium carbonate, rubidium carbonate and cesium carbonate. The organic electroluminescent device is higher in luminous efficiency. In addition, a manufacturing method for the organic electroluminescent device is further provided.

Description

Organic electroluminescence device and preparation method thereof

Technical field

The present invention relates to field of electronic devices, particularly a kind of organic electroluminescence device and preparation method thereof.

Background technology

Organic electroluminescence device (OLED) has advantages of that some are unique: (1) OLED belongs to diffused area source, does not need by extra light-conducting system, to obtain large-area white light source as light-emitting diode (LED); (2) due to the diversity of luminous organic material, OLED illumination is the light of design color as required, no matter be little Molecule OLEDs at present, or polymer organic LED (PLED) has all obtained and has comprised white-light spectrum at the light of interior all colours; (3) OLED can make on as glass, pottery, metal, plastic or other material at multiple substrate, freer when this makes to design lighting source; (4) adopt the mode of making OLED demonstration to make OLED illumination panel, can in illumination, show information; (5) OLED also can be used as controlled look in illuminator, allows user to regulate light atmosphere according to individual demand.But the luminous efficiency of traditional organic electroluminescence device is lower.

Summary of the invention

Given this, be necessary to provide organic electroluminescence device that a kind of luminous efficiency is higher and preparation method thereof.

A kind of organic electroluminescence device, comprise the anode substrate, hole injection layer, hole transmission layer, luminescent layer, electron transfer layer, electron injecting layer and the cathode layer that stack gradually, the material of described electron transfer layer comprises electron transport material and is doped in the first alkali carbonate in described electron transport material, and the mass percentage concentration of the first alkali carbonate described in the material of described electron transfer layer is 3% ~ 8%; The material of described electron injecting layer comprises material of main part and co-doped N-shaped material and the second alkali carbonate in described material of main part, and the mass percentage concentration of the second alkali carbonate described in the material of described electron injecting layer is 5% ~ 10%; Wherein, described electron transport material and described material of main part are selected from respectively 4,7-diphenyl-1,10-phenanthroline, 4,7-diphenyl-1,10-Phen, 4-biphenyl phenolic group-bis-(2-methyl-oxine) close aluminium, oxine aluminium, 3-(biphenyl-4-yl)-5-(4-tert-butyl-phenyl)-4-phenyl-4H-1,2, a kind of in 4-triazole and 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene; Described the first alkali carbonate and described the second alkali carbonate are selected from respectively a kind of in lithium carbonate, sodium carbonate, potash, rubidium carbonate and cesium carbonate; Described N-shaped material is selected from a kind of in lithium nitride, cesium fluoride, cesium trinitride, lithia and lithium fluoride.

In an embodiment, the thickness of described electron transfer layer is 10 nanometer ~ 60 nanometers therein; The thickness of described electron injecting layer is 20 nanometer ~ 40 nanometers; The mass percentage concentration of N-shaped material described in the material of described electron injecting layer is 25% ~ 35%.

Therein in an embodiment, described anode substrate is indium tin oxide glass, mix the tin oxide glass of fluorine, mix the zinc oxide glass of aluminium and mix a kind of in the zinc oxide glass of indium; The thickness of described anode substrate is 100 nanometer ~ 150 nanometers.

Therein in an embodiment, the material of described hole injection layer comprises material of main part and is doped in the p-type material in described material of main part, and the mass percentage concentration of p-type material described in the material of described hole injection layer is 25% ~ 35%; Wherein, described material of main part is N, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines, 4,4', 4 " tri-(carbazole-9-yl) triphenylamine, 4,4'-bis-(9-carbazole) biphenyl, N, N'-bis-(3-aminomethyl phenyl)-N; N'-diphenyl-4; 4'-benzidine and 1,1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] a kind of in cyclohexane; Described p-type material is a kind of in molybdenum oxide, tungstic acid, vanadic oxide and rhenium trioxide; The thickness of described hole injection layer is 10 nanometer ~ 15 nanometers.

In an embodiment, the material of described hole transmission layer is N, N'-diphenyl-N therein, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines, 4,4', 4 " tri-(carbazole-9-yl) triphenylamine, 4,4'-bis-(9-carbazole) biphenyl, N, N'-bis-(3-aminomethyl phenyl)-N; N'-diphenyl-4; 4'-benzidine and 1,1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] a kind of in cyclohexane; The thickness of described hole transmission layer is 30 nanometer ~ 50 nanometers.

Therein in an embodiment, the material of described luminescent layer be three (2-phenylpyridines) close iridium doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene; It is 1%～10% that three (2-phenylpyridines) described in the material of described luminescent layer close the mass percentage concentration of iridium; The thickness of described luminescent layer is 10 nanometer ~ 20 nanometers.

In an embodiment, the material of described cathode layer is silver, aluminium, magnesium silver alloy or gold therein; The thickness of described cathode layer is 50 nanometer ~ 200 nanometers.

A preparation method for organic electroluminescence device, comprises the steps:

Anode purge substrate;

In described anode substrate, form hole injection layer;

On described hole injection layer, form hole transmission layer;

On described hole transmission layer, form luminescent layer;

On described luminescent layer, form electron transfer layer, the material of described electron transfer layer comprises electron transport material and is doped in the first alkali carbonate in described electron transport material, and the mass percentage concentration of the first alkali carbonate described in the material of described electron transfer layer is 3% ~ 8%;

On described electron transfer layer, form electron injecting layer, the material of described electron injecting layer comprises material of main part and co-doped N-shaped material and the second alkali carbonate in described material of main part, and the mass percentage concentration of the second alkali carbonate described in the material of described electron injecting layer is 5% ~ 10%; And

On described electron injecting layer, form cathode layer;

Wherein, described electron transport material and described material of main part are selected from respectively 4,7-diphenyl-1,10-phenanthroline, 4,7-diphenyl-1,10-Phen, 4-biphenyl phenolic group-bis-(2-methyl-oxine) close aluminium, oxine aluminium, 3-(biphenyl-4-yl)-5-(4-tert-butyl-phenyl)-4-phenyl-4H-1,2, a kind of in 4-triazole and 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene; Described the first alkali carbonate and described the second alkali carbonate are selected from respectively a kind of in lithium carbonate, sodium carbonate, potash, rubidium carbonate and cesium carbonate; Described N-shaped material is selected from a kind of in lithium nitride, cesium fluoride, cesium trinitride, lithia and lithium fluoride.

In an embodiment, the method that forms described hole injection layer is vacuum vapour deposition therein, and evaporation condition is: vacuum degree is 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described hole transmission layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described luminescent layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described electron transfer layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described electron injecting layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

and

The method that forms described cathode layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

In an embodiment, described anode substrate also comprises the surface activation process step to described anode substrate after cleaning therein.

Above-mentioned organic electroluminescence device, by mixing the second alkali carbonate and mix the first alkali carbonate in the material of main part of electron injecting layer in the electron transport material of electron transfer layer, and the first alkali carbonate and the second alkali carbonate are selected from respectively lithium carbonate, sodium carbonate, potash, a kind of in rubidium carbonate and cesium carbonate, the electron donation of these five kinds of materials is strong, electronics is transferred on the lowest unoccupied molecular orbital of material of main part (LUMO), thereby formed band curvature, improve carrier mobility, and raising electron injection efficiency, and the first alkali carbonate adulterating in the second alkali carbonate adulterating in electron injecting layer and electron transfer layer increases electron concentration, improve electron transport ability, make electron hole compound in the material of luminescent layer more, thereby improved organic electroluminescence device luminous efficiency, therefore, the luminous efficiency of above-mentioned organic electroluminescence device is higher.

Accompanying drawing explanation

Fig. 1 is the structural representation of the organic electroluminescence device of an execution mode;

Fig. 2 is preparation method's the flow chart of the organic electroluminescence device of an execution mode;

Fig. 3 is that the organic electroluminescence device of embodiment 1 ~ 7 preparation and the structure of comparative example 1 preparation are ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃the luminous efficiency curve figure of traditional organic electroluminescence device of/Mg-Ag.

Embodiment

Mainly in conjunction with the drawings and the specific embodiments organic electronic light emitting device and preparation method thereof is described in further detail below.

As shown in Figure 1, the organic electroluminescence device 100 of an execution mode, comprises the anode substrate 110, hole injection layer 120, hole transmission layer 130, luminescent layer 140, electron transfer layer 150, electron injecting layer 160 and the cathode layer 170 that stack gradually.

Anode substrate 110 for indium tin oxide glass (ITO), mix fluorine tin oxide glass (FTO), mix the zinc oxide glass (AZO) of aluminium and mix a kind of in the zinc oxide glass (IZO) of indium, be preferably indium tin oxide glass (ITO).The thickness of anode substrate 110 is 100 nanometer ~ 150 nanometers.

The material of hole injection layer 120 comprises material of main part and is doped in the p-type material in material of main part.In the material of hole injection layer 120, the mass percentage concentration of p-type material is 25% ~ 35%.Wherein, material of main part is N, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines (NPB), 4,4', 4 " tri-(carbazole-9-yl) triphenylamine (TCTA), 4,4'-bis-(9-carbazole) biphenyl (CBP), N, N'-bis-(3-aminomethyl phenyl)-N; N'-diphenyl-4; 4'-benzidine (TPD) and 1,1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] a kind of in cyclohexane (TAPC).P-type material is molybdenum oxide (MoO ₃), tungstic acid (WO ₃), vanadic oxide (V ₂o ₅) and rhenium trioxide (ReO ₃) in a kind of.The thickness of hole injection layer 120 is 10 nanometer ~ 15 nanometers.

The material of hole transmission layer 130 is N, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines (NPB), 4,4', 4 " tri-(carbazole-9-yl) triphenylamine (TCTA), 4; 4'-bis-(9-carbazole) biphenyl (CBP), N; N'-bis-(3-aminomethyl phenyl)-N, N'-diphenyl-4,4'-benzidine (TPD) and 1; 1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] a kind of in cyclohexane (TAPC).The thickness of hole transmission layer 130 is 30 nanometer ~ 50 nanometers.

The material of luminescent layer 140 is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI).In the material of luminescent layer 140, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 1% ~ 10%.The thickness of luminescent layer 140 is 10 ~ 20 nanometers.

The material of electron transfer layer 150 is to comprise electron transport material and be doped in the first alkali carbonate in electron transport material.In the material of electron transfer layer 150, the mass percentage concentration of the first alkali carbonate is 3% ~ 8%.The transmission that the first alkali carbonate that is 3% ~ 8% by doping mass percentage concentration can improve electronics.The thickness of electron transfer layer 150 is 10 nanometer ~ 60 nanometers.

The material of electron injecting layer 160 comprises material of main part and co-doped N-shaped material and the second alkali carbonate in described material of main part.In the material of electron injecting layer 160, the mass percentage concentration of the second alkali carbonate is 5% ~ 10%.The second alkali carbonate that is 5% ~ 10% by doping mass percentage concentration can reduce electronic injection and transport layer energy level difference.In the material of electron injecting layer 160, the mass percentage concentration of N-shaped material is 25% ~ 35%.Mass percentage concentration is that 25% ~ 35% N-shaped material can improve electronic injection ability.The thickness of electron injecting layer 160 is 20 nanometer ~ 40 nanometers.

Wherein, the material of main part of electron transport material and electron injecting layer 160 is selected from respectively 4,7-diphenyl-1,10-phenanthroline (Bphen), 4,7-diphenyl-1,10-Phen (BCP), 4-biphenyl phenolic group-bis-(2-methyl-oxine) close aluminium (BAlq), oxine aluminium (Alq ₃), 3-(biphenyl-4-yl)-5-(4-tert-butyl-phenyl)-4-phenyl-4H-1, a kind of in 2,4-triazole (TAZ) and 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI).In specific embodiment, electron transport material can be identical with the material of main part of electron injecting layer 160, also can be not identical.The first alkali carbonate and the second alkali carbonate are selected from respectively lithium carbonate (Li ₂cO ₃), sodium carbonate (Na ₂cO ₃), potash (K ₂cO ₃), rubidium carbonate (Rb ₂cO ₃) and cesium carbonate (Cs ₂cO ₃) in a kind of.In specific embodiment, the first alkali carbonate can be identical with the second alkali carbonate, also can be not identical.N-shaped material is selected from lithium nitride (Li ₃n), cesium fluoride (CsF), cesium trinitride (CsN ₃), lithia (Li ₂o) a kind of and in lithium fluoride (LiF).

The material of cathode layer 170 is silver (Ag), aluminium (Al), magnesium silver alloy (Mg-Ag) or gold (Au).Wherein, in magnesium silver alloy, magnesium (Mg) is 10:1 with the mol ratio of silver (Ag).The thickness of cathode layer 170 is 50 nanometer ~ 200 nanometers.

Above-mentioned organic electroluminescence device 100, by mixing the second alkali carbonate in the material of main part at electron injecting layer 160 and mix the first alkali carbonate in the electron transport material of electron transfer layer 150, and the first alkali carbonate and the second alkali carbonate are selected from respectively lithium carbonate (Li ₂cO ₃), sodium carbonate (Na ₂cO ₃), potash (K ₂cO ₃), rubidium carbonate (Rb ₂cO ₃) and cesium carbonate (Cs ₂cO ₃) in a kind of, the electron donation of these five kinds of materials is strong, electronics is transferred on the lowest unoccupied molecular orbital of material of main part (LUMO), thereby formed band curvature, improve carrier mobility, and raising electron injection efficiency, and in electron injecting layer 160, in the second alkali carbonate of doping and electron transfer layer 150, the first alkali carbonate of doping increases electron concentration, improve electron transport ability, make electron hole compound in the material of luminescent layer more, thereby improved organic electroluminescence device luminous efficiency, therefore, the luminous efficiency of above-mentioned organic electroluminescence device 100 is higher.

As shown in Figure 2, the preparation method of the organic electroluminescence device 100 of an execution mode, comprises the steps:

Step S210: anode purge substrate 110.In specific embodiment, the cleaning step of anode substrate 110 comprises: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the anode substrate after cleaning 110 is dried, obtain clean anode substrate 110.By above-mentioned cleaning, remove dust and the organic substance on anode substrate 110 surfaces.

Wherein, the surface activation process step that also comprises antianode substrate 110 after anode purge substrate 110.In specific embodiment, surface activation process step is: the anode substrate 110 use UV-OZONE after cleaning are processed 30 minutes.Surface activation process by the anode substrate 110 to after cleaning to be to increase the oxygen content on anode substrate 110 surfaces, thereby improves its surperficial work function.

Step S220: form hole injection layer 120 in anode substrate 110.

Wherein, the method that forms hole injection layer 120 is vacuum vapour deposition, and evaporation condition is: vacuum degree is 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

Step S230: form hole transmission layer 130 on hole injection layer 120.

Wherein, the method that forms hole transmission layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

Step S240: form luminescent layer 140 on hole transmission layer 130.

Wherein, the method that forms luminescent layer 140 is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

Step S250: form electron transfer layer 150 on luminescent layer 140, the material of electron transfer layer 150 comprises electron transport material and is doped in the first alkali carbonate in electron transport material, and in the material of electron transfer layer, the mass percentage concentration of the first alkali carbonate is 3% ~ 8%.

Wherein, the method that forms electron transfer layer 150 is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

Step S260: form electron injecting layer 160 on electron transfer layer 150, the material of electron injecting layer 160 comprises material of main part and co-doped N-shaped material and the second alkali carbonate in material of main part, and the mass percentage concentration of the second alkali carbonate is 5% ~ 10%.Wherein, in the material of electron injecting layer 160, the mass percentage concentration of N-shaped material is 25% ~ 35%.

Wherein, the material of main part of electron transport material and electron injecting layer 160 is selected from respectively 4,7-diphenyl-1,10-phenanthroline (Bphen), 4,7-diphenyl-1,10-Phen (BCP), 4-biphenyl phenolic group-bis-(2-methyl-oxine) close aluminium (BAlq), oxine aluminium (Alq ₃), 3-(biphenyl-4-yl)-5-(4-tert-butyl-phenyl)-4-phenyl-4H-1, a kind of in 2,4-triazole (TAZ) and 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI).The first alkali carbonate and the second alkali carbonate are selected from respectively lithium carbonate (Li ₂cO ₃), sodium carbonate (Na ₂cO ₃), potash (K ₂cO ₃), rubidium carbonate (Rb ₂cO ₃) and cesium carbonate (Cs ₂cO ₃) in a kind of; N-shaped material is selected from lithium nitride (Li ₃n), cesium fluoride (CsF), cesium trinitride (CsN ₃), lithia (Li ₂o) a kind of and in lithium fluoride (LiF).

Wherein, the method that forms electron injecting layer 160 is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

Step S270: form cathode layer 170 on electron injecting layer 160.

Wherein, the method that forms cathode layer 270 is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The preparation method of above-mentioned organic electroluminescence device 100 is simple, and easily operation is conducive to industrialization and produces.

Be below specific embodiment part:

Embodiment 1

The structure of the organic electroluminescence device of the present embodiment is: ITO/NPB:MoO ₃/ NPB/TPBI:Ir(ppy) ₃/ Bphen:Li ₂cO ₃/ Bphen:Li ₃n:Li ₂cO ₃/ Ag.

Being prepared as follows of the organic electroluminescence device of this embodiment:

(1) clean ito anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the ito anode substrate after cleaning is dried, obtain clean ito anode substrate; Ito anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of ito anode substrate is 100 nanometers.

(2) in ito anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is MoO ₃the N of doping, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines (NPB), is expressed as NPB:MoO ₃, MoO in the material of hole injection layer ₃mass percentage concentration be 30%; Evaporation condition is: vacuum degree is 5 * 10 ^-5pa, evaporation rate

the thickness of hole injection layer is 12 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is N, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines (NPB); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of hole transmission layer is 40 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of luminescent layer is 15 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, the material of electron transfer layer is lithium carbonate (Li ₂cO ₃) doping 4,7-diphenyl-1,10-phenanthroline (Bphen), is expressed as Bphen:Li ₂cO ₃, lithium carbonate (Li in the material of electron transfer layer ₂cO ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron transfer layer is 40 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is lithium nitride (Li ₃n) with lithium carbonate (Li ₂cO ₃) co-doped 4,7-diphenyl-1,10-phenanthroline (Bphen), is expressed as Bphen:Li ₃n:Li ₂cO ₃, lithium nitride (Li in the material of electron injecting layer ₃n) doping mass percentage concentration is 30%, and lithium carbonate (Li ₂cO ₃) mass percentage concentration be 7%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of electron injecting layer is 30 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is silver (Ag); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of cathode layer is 100 nanometers.

Finally, the structure that obtains the present embodiment is ITO/NPB:MoO ₃/ NPB/TPBI:Ir(ppy) ₃/ Bphen:Li ₂cO ₃/ Bphen:Li ₃n:Li ₂cO ₃the organic electroluminescence device of/Ag.

Embodiment 2

The structure of the organic electroluminescence device of the present embodiment is: FTO/TCTA:WO ₃/ TCTA/TPBI:Ir(ppy) ₃/ BCP:Na ₂cO ₃/ BCP:CsF:Na ₂cO ₃/ Al.

Being prepared as follows of the organic electroluminescence device of this embodiment:

(1) clean FTO anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the FTO anode substrate after cleaning is dried, obtain clean FTO anode substrate; FTO anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of FTO anode substrate is 150 nanometers.

(2) in FTO anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is WO ₃4 of doping, " tri-(carbazole-9-yl) triphenylamine (TCTA), is expressed as TCTA:WO for 4', 4 ₃, WO in the material of hole injection layer ₃mass percentage concentration be 30%; Evaporation condition is: vacuum degree is 3 * 10 ^-4pa, evaporation rate

the thickness of hole injection layer is 12 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is 4,4', 4 " tri-(carbazole-9-yl) triphenylamines (TCTA); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of hole transmission layer is 40 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 10%; Evaporation condition is: vacuum degree 3 * 10 ^-4pa, evaporation rate

the thickness of luminescent layer is 15 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, the material of electron transfer layer is sodium carbonate (Na ₂cO ₃) doping 4,7-diphenyl-1,10-Phen (BCP), is expressed as BCP:Na ₂cO ₃, sodium carbonate (Na in the material of electron transfer layer ₂cO ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 3 * 10 ^-4pa, evaporation rate

the thickness of electron transfer layer is 40 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is CsF and sodium carbonate (Na ₂cO ₃) co-doped 4,7-diphenyl-1,10-Phen (BCP), is expressed as BCP:CsF:Na ₂cO ₃, in the material of electron injecting layer, the mass percentage concentration of CsF is 30%, and sodium carbonate (Na ₂cO ₃) mass percentage concentration be 7%; Evaporation condition is: vacuum degree 3 * 10 ^-4pa, evaporation rate the thickness of electron injecting layer is 30 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is aluminium (Al); Evaporation condition is: vacuum degree 3 * 10 ^-4pa, evaporation rate

the thickness of cathode layer is 100 nanometers.

Finally, the structure that obtains the present embodiment is FTO/TCTA:WO ₃/ TCTA/TPBI:Ir(ppy) ₃/ BCP:Na ₂cO ₃/ BCP:CsF:Na ₂cO ₃the organic electroluminescence device of/Al.

Embodiment 3

The structure of the organic electroluminescence device of the present embodiment is: ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq:K ₂cO ₃/ BAlq:CsN ₃: K ₂cO ₃/ Mg-Ag.

Being prepared as follows of the organic electroluminescence device of this embodiment:

(1) clean ito anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the ito anode substrate after cleaning is dried, obtain clean ito anode substrate; Ito anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of ito anode substrate is 100 nanometers.

(2) in ito anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is V ₂o ₅4 of doping, 4'-bis-(9-carbazole) biphenyl (CBP), is expressed as CBP:V ₂o ₅, V in the material of hole injection layer ₂o ₅mass percentage concentration be 30%; Evaporation condition is: vacuum degree is 5 * 10 ^-5pa, evaporation rate

the thickness of hole injection layer is 12 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is 4,4'-bis-(9-carbazole) biphenyl (CBP); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of hole transmission layer is 40 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of luminescent layer is 15 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, the material of electron transfer layer is potash (K ₂cO ₃) doping 4-biphenyl phenolic group-bis-(2-methyl-oxine) close aluminium (BAlq), be expressed as BAlq:K ₂cO ₃, potash (K in the material of electron transfer layer ₂cO ₃) mass percentage concentration be 1%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of electron transfer layer is 40 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is CsN ₃with potash (K ₂cO ₃) 4-biphenyl phenolic group-bis-(2-methyl-oxine) of co-doped close aluminium (BAlq), are expressed as BAlq:CsN ₃: K ₂cO ₃, CsN in the material of electron injecting layer ₃mass percentage concentration be 30%, and potash (K ₂cO ₃) mass percentage concentration be 7%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron injecting layer is 30 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is magnesium silver alloy (Mg-Ag) (mol ratio is 10:1); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of cathode layer is 100 nanometers.

Finally, the structure that obtains the present embodiment is ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq:K ₂cO ₃/ BAlq:CsN ₃: K ₂cO ₃the organic electroluminescence device of/Mg-Ag.

Embodiment 4

The structure of the organic electroluminescence device of the present embodiment is: IZO/TPD:ReO ₃/ TPD/TPBI:Ir(ppy) ₃/ Alq ₃: Rb ₂cO ₃/ Alq ₃: Li ₂o:Rb ₂cO ₃/ Au.

Being prepared as follows of the organic electroluminescence device of this embodiment:

(1) clean IZO anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the IZO anode substrate after cleaning is dried, obtain clean IZO anode substrate; IZO anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of IZO anode substrate is 100 nanometers.

(2) in IZO anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is ReO ₃the N of doping, N'-bis-(3-aminomethyl phenyl)-N, N'-diphenyl-4,4'-benzidine (TPD), is expressed as TPD:ReO ₃, ReO in the material of hole injection layer ₃mass percentage concentration be 25%; Evaporation condition is: vacuum degree is 5 * 10 ^-5pa, evaporation rate the thickness of hole injection layer is 10 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is N, N'-bis-(3-aminomethyl phenyl)-N, N'-diphenyl-4,4'-benzidine (TPD); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of hole transmission layer is 30 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of luminescent layer is 10 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, the material of electron transfer layer is rubidium carbonate (Rb ₂cO ₃) doping oxine aluminium (Alq ₃), be expressed as Alq ₃: Rb ₂cO ₃, rubidium carbonate (Rb in the material of electron transfer layer ₂cO ₃) mass percentage concentration be 3%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron transfer layer is 10 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is lithia (Li ₂o) with rubidium carbonate (Rb ₂cO ₃) the oxine aluminium (Alq of co-doped ₃), be expressed as Alq ₃: Li ₂o:Rb ₂cO ₃, lithia (Li in the material of electron injecting layer ₂o) mass percentage concentration is 25%, and rubidium carbonate (Rb ₂cO ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron injecting layer is 20 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is gold (Au); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of cathode layer is 50 nanometers.

Finally, the structure that obtains the present embodiment is IZO/TPD:ReO ₃/ TPD/TPBI:Ir(ppy) ₃/ Alq ₃: Rb ₂cO ₃/ Alq ₃: Li ₂o:Rb ₂cO ₃the organic electroluminescence device of/Au.

Embodiment 5

The structure of the organic electroluminescence device of the present embodiment is: AZO/TAPC:MoO ₃/ TAPC/TPBI:Ir(ppy) ₃/ TAZ:Cs ₂cO ₃/ TAZ:LiF:Cs ₂cO ₃/ Al.

Being prepared as follows of the organic electroluminescence device of this embodiment:

(1) clean AZO anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the AZO anode substrate after cleaning is dried, obtain clean AZO anode substrate; AZO anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of AZO anode substrate is 100 nanometers.

(2) in AZO anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is MoO ₃1 of doping, 1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] cyclohexane (TAPC), be expressed as TAPC:MoO ₃, MoO in the material of hole injection layer ₃mass percentage concentration be 35%; Evaporation condition is: vacuum degree is 5 * 10 ^-5pa, evaporation rate

the thickness of hole injection layer is 15 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is 1,1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] cyclohexane (TAPC); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of hole transmission layer is 50 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of luminescent layer is 20 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, the material of electron transfer layer is cesium carbonate (Cs ₂cO ₃) doping 3-(biphenyl-4-yl)-5-(4-tert-butyl-phenyl)-4-phenyl-4H-1,2,4-triazole (TAZ), is expressed as TAZ:Cs ₂cO ₃, cesium carbonate (Cs in the material of electron transfer layer ₂cO ₃) mass percentage concentration be 8%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of electron transfer layer is 60 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is LiF and cesium carbonate (Cs ₂cO ₃) 3-(biphenyl-4-yl)-5-(4-the tert-butyl-phenyl)-4-phenyl-4H-1 of co-doped, 2,4-triazole (TAZ), is expressed as TAZ:LiF:Cs ₂cO ₃, in the material of electron injecting layer, the mass percentage concentration of LiF is 35%, cesium carbonate (Cs ₂cO ₃) mass percentage concentration be 10%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron injecting layer is 40 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is aluminium (Al); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of cathode layer is 200 nanometers.

Finally, the structure that obtains the present embodiment is: AZO/TAPC:MoO ₃/ TAPC/TPBI:Ir(ppy) ₃/ TAZ:Cs ₂cO ₃/ TAZ:LiF:Cs ₂cO ₃the organic electroluminescence device of/Al.

Embodiment 6

The structure of the organic electroluminescence device of the present embodiment is: ITO/NPB:WO ₃/ NPB/TPBI:Ir(ppy) ₃/ TPBI:Na ₂cO ₃/ TPBI:LiF:Na ₂cO ₃/ Ag.

Being prepared as follows of the organic electroluminescence device of this embodiment:

(1) clean ito anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the ito anode substrate after cleaning is dried, obtain clean ito anode substrate; Ito anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of ito anode substrate is 100 nanometers.

(2) in ito anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is WO ₃the N of doping, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines (NPB), is expressed as NPB:WO ₃, WO in the material of hole injection layer ₃mass percentage concentration be 25%; Evaporation condition is: vacuum degree is 5 * 10 ^-5pa, evaporation rate

the thickness of hole injection layer is 10 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is N, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines (NPB); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of hole transmission layer is 30 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of luminescent layer is 10 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, the material of electron transfer layer is sodium carbonate (Na2CO ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Na ₂cO ₃, sodium carbonate (Na in the material of electron transfer layer ₂cO ₃) mass percentage concentration be 3%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of electron transfer layer is 20 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is lithium fluoride (LiF) and sodium carbonate (Na ₂cO ₃) co-doped 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:LiF:Na ₂cO ₃, the mass percentage concentration of lithium fluoride in the material of electron injecting layer (LiF) is 25%, and sodium carbonate (Na ₂cO ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron injecting layer is 20 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is silver (Ag); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of cathode layer is 80 nanometers.

Finally, the structure that obtains the present embodiment is ITO/NPB:WO ₃/ NPB/TPBI:Ir(ppy) ₃/ TPBI:Na ₂cO ₃/ TPBI:LiF:Na ₂cO ₃the organic electroluminescence device of/Ag.

Embodiment 7

The structure of the organic electroluminescence device of the present embodiment is: ITO/NPB:WO ₃/ TAPC/TPBI:Ir(ppy) ₃/ BCP:Na ₂cO ₃/ TPBI:LiF:K ₂cO ₃/ Ag.

Being prepared as follows of the organic electroluminescence device of this embodiment:

(1) clean ito anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the ito anode substrate after cleaning is dried, obtain clean ito anode substrate; Ito anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of ito anode substrate is 100 nanometers.

(2) in ito anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is WO ₃the N of doping, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines (NPB), is expressed as NPB:WO ₃, WO in the material of hole injection layer ₃mass percentage concentration be 25%; Evaporation condition is: vacuum degree is 5 * 10 ^-5pa, evaporation rate the thickness of hole injection layer is 10 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is 1,1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] cyclohexane (TAPC); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of hole transmission layer is 30 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of luminescent layer is 10 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, the material of electron transfer layer is sodium carbonate (Na ₂cO ₃) doping 4,7-diphenyl-1,10-Phen (BCP), is expressed as BCP:Na ₂cO ₃, sodium carbonate (Na in the material of electron transfer layer ₂cO ₃) mass percentage concentration be 4%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron transfer layer is 20 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is lithium fluoride (LiF) and potash (K ₂cO ₃) co-doped 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:LiF:K ₂cO ₃, the mass percentage concentration of lithium fluoride in the material of electron injecting layer (LiF) is 25%, and potash (K ₂cO ₃) mass percentage concentration be 6%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron injecting layer is 20 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is silver (Ag); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of cathode layer is 150 nanometers.

Finally, the structure that obtains the present embodiment is ITO/NPB:WO ₃/ TAPC/TPBI:Ir(ppy) ₃/ BCP:Na ₂cO ₃/ TPBI:LiF:K ₂cO ₃the organic electroluminescence device of/Ag.

Comparative example 1

The structure of traditional organic electroluminescence device is: ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃/ Mg-Ag.

Being prepared as follows of the organic electroluminescence device that this is traditional:

(1) clean ito anode substrate: first adopt liquid detergent in ultrasonic wave, to clean 5 minutes, then adopt deionized water in ultrasonic wave, to clean 5 minutes, then adopt acetone in ultrasonic wave, to clean 5 minutes, finally adopt ethanol in ultrasonic wave, to clean 5 minutes, after having cleaned, stop 5 minutes at every turn; According to said sequence, clean three times, the ito anode substrate after cleaning is dried, obtain clean ito anode substrate; Ito anode substrate after cleaning is processed 30 minutes with UV-OZONE.The thickness of ito anode substrate is 100 nanometers.

(2) in ito anode substrate, vacuum evaporation forms hole injection layer, and wherein, the material of hole injection layer is V ₂o ₅4 of doping, 4'-bis-(9-carbazole) biphenyl (CBP), is expressed as CBP:V ₂o ₅, V in the material of hole injection layer ₂o ₅mass percentage concentration be 30%; Evaporation condition is: vacuum degree is 5 * 10 ^-5pa, evaporation rate the thickness of hole injection layer is 12 nanometers.

(3) on hole injection layer, vacuum evaporation forms hole transmission layer, and wherein, the material of hole transmission layer is 4,4'-bis-(9-carbazole) biphenyl (CBP); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of hole transmission layer is 40 nanometers.

(4) on hole transmission layer, vacuum evaporation forms luminescent layer, and wherein, the material of luminescent layer is that three (2-phenylpyridines) close iridium (Ir(ppy) ₃) doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene (TPBI), is expressed as TPBI:Ir(ppy) ₃, in the material of luminescent layer, three (2-phenylpyridines) close iridium (Ir(ppy) ₃) mass percentage concentration be 5%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate the thickness of luminescent layer is 15 nanometers.

(5) on luminescent layer, vacuum evaporation forms electron transfer layer, and wherein, material 4-biphenyl phenolic group-bis-(2-methyl-oxine) of electron transfer layer close aluminium (BAlq); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron transfer layer is 40 nanometers.

(6) on electron transfer layer, vacuum evaporation forms electron injecting layer, and wherein, the material of electron injecting layer is CsN ₃4-biphenyl phenolic group-bis-(2-methyl-oxine) of doping close aluminium (BAlq), are expressed as BAlq:CsN ₃, CsN in the material of electron injecting layer ₃doping mass percentage concentration be 30%; Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of electron injecting layer is 30 nanometers.

(7) on electron injecting layer, vacuum evaporation forms cathode layer, and the material of cathode layer is magnesium silver alloy (Mg-Ag) (mol ratio is 10:1); Evaporation condition is: vacuum degree 5 * 10 ^-5pa, evaporation rate

the thickness of cathode layer is 100 nanometers.

Finally, the structure that obtains comparative example 1 preparation is ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃the organic electroluminescence device of/Mg-Ag.

Fig. 3 is that the organic electroluminescence device of embodiment 1 ~ 7 preparation and the structure of comparative example 1 preparation are ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃the luminous efficiency curve figure of traditional organic electroluminescence device of/Mg-Ag.What table 1 represented is that the organic electroluminescence device of embodiment 1 ~ 7 preparation and the structure of comparative example 1 preparation are ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃the luminous efficiency of traditional organic electroluminescence device of/Mg-Ag when different brightness.

Table 1

From Fig. 3 and table 1, can draw, when same brightness, the organic electroluminescence device of embodiment 1 ~ 7 preparation is obviously ITO/CBP:V than the structure of comparative example 1 preparation ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃it is high that the luminous efficiency of traditional organic electroluminescence device of/Mg-Ag is wanted, and when brightness be 100cd/m ²and 3300cd/m ²time, the structure of embodiment 3 preparations is ITO/CBP:V ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq:K ₂cO ₃/ BAlq:CsN ₃: K ₂cO ₃the luminous efficiency of/Mg-Ag organic electroluminescence device is ITO/CBP:V than the structure of comparative example 1 preparation ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃the luminous efficiency of the organic electroluminescence device that/Mg-Ag is traditional has exceeded approximately 0.56 times and 3.7 times; And along with the increase of brightness, the organic electroluminescence device of embodiment 1 ~ 7 preparation is obviously ITO/CBP:V than the structure of comparative example 1 preparation ₂o ₅/ CBP/TPBI:Ir(ppy) ₃/ BAlq/BAlq:CsN ₃the luminous efficiency decay of traditional organic electroluminescence device of/Mg-Ag is little.

The above embodiment has only expressed several execution mode of the present invention, and it describes comparatively concrete and detailed, but can not therefore be interpreted as the restriction to the scope of the claims of the present invention.It should be pointed out that for the person of ordinary skill of the art, without departing from the inventive concept of the premise, can also make some distortion and improvement, these all belong to protection scope of the present invention.Therefore, the protection range of patent of the present invention should be as the criterion with claims.

Claims (10)

1. an organic electroluminescence device, it is characterized in that, comprise the anode substrate, hole injection layer, hole transmission layer, luminescent layer, electron transfer layer, electron injecting layer and the cathode layer that stack gradually, the material of described electron transfer layer comprises electron transport material and is doped in the first alkali carbonate in described electron transport material, and the mass percentage concentration of the first alkali carbonate described in the material of described electron transfer layer is 3% ~ 8%; The material of described electron injecting layer comprises material of main part and co-doped N-shaped material and the second alkali carbonate in described material of main part, and the mass percentage concentration of the second alkali carbonate described in the material of described electron injecting layer is 5% ~ 10%; Wherein, described electron transport material and described material of main part are selected from respectively 4,7-diphenyl-1,10-phenanthroline, 4,7-diphenyl-1,10-Phen, 4-biphenyl phenolic group-bis-(2-methyl-oxine) close aluminium, oxine aluminium, 3-(biphenyl-4-yl)-5-(4-tert-butyl-phenyl)-4-phenyl-4H-1,2, a kind of in 4-triazole and 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene; Described the first alkali carbonate and described the second alkali carbonate are selected from respectively a kind of in lithium carbonate, sodium carbonate, potash, rubidium carbonate and cesium carbonate; Described N-shaped material is selected from a kind of in lithium nitride, cesium fluoride, cesium trinitride, lithia and lithium fluoride.

2. organic electroluminescence device according to claim 1, is characterized in that, the thickness of described electron transfer layer is 10 nanometer ~ 60 nanometers; The thickness of described electron injecting layer is 20 nanometer ~ 40 nanometers; The mass percentage concentration of N-shaped material described in the material of described electron injecting layer is 25% ~ 35%.

3. organic electroluminescence device according to claim 1, is characterized in that, described anode substrate is indium tin oxide glass, mix the tin oxide glass of fluorine, mix the zinc oxide glass of aluminium and mix a kind of in the zinc oxide glass of indium; The thickness of described anode substrate is 100 nanometer ~ 150 nanometers.

4. organic electroluminescence device according to claim 1, it is characterized in that, the material of described hole injection layer comprises material of main part and is doped in the p-type material in described material of main part, and the mass percentage concentration of p-type material described in the material of described hole injection layer is 25% ~ 35%; Wherein, described material of main part is N, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines, 4,4', 4 " tri-(carbazole-9-yl) triphenylamine, 4,4'-bis-(9-carbazole) biphenyl, N, N'-bis-(3-aminomethyl phenyl)-N; N'-diphenyl-4; 4'-benzidine and 1,1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] a kind of in cyclohexane; Described p-type material is a kind of in molybdenum oxide, tungstic acid, vanadic oxide and rhenium trioxide; The thickness of described hole injection layer is 10 nanometer ~ 15 nanometers.

5. organic electroluminescence device according to claim 1, is characterized in that, the material of described hole transmission layer is N, N'-diphenyl-N, N'-bis-(1-naphthyl)-1,1'-biphenyl-4,4'-diamines, 4,4', 4 " tri-(carbazole-9-yl) triphenylamine, 4; 4'-bis-(9-carbazole) biphenyl, N; N'-bis-(3-aminomethyl phenyl)-N, N'-diphenyl-4,4'-benzidine and 1; 1-bis-[4-[N, N '-bis-(p-tolyl) amino] phenyl] a kind of in cyclohexane; The thickness of described hole transmission layer is 30 nanometer ~ 50 nanometers.

6. organic electroluminescence device according to claim 1, is characterized in that, the material of described luminescent layer be three (2-phenylpyridines) close iridium doping 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene; It is 1%～10% that three (2-phenylpyridines) described in the material of described luminescent layer close the mass percentage concentration of iridium; The thickness of described luminescent layer is 10 nanometer ~ 20 nanometers.

7. organic electroluminescence device according to claim 1, is characterized in that, the material of described cathode layer is silver, aluminium, magnesium silver alloy or gold; The thickness of described cathode layer is 50 nanometer ~ 200 nanometers.

8. a preparation method for organic electroluminescence device, is characterized in that, comprises the steps:

Anode purge substrate;

In described anode substrate, form hole injection layer;

On described hole injection layer, form hole transmission layer;

On described hole transmission layer, form luminescent layer;

On described luminescent layer, form electron transfer layer, the material of described electron transfer layer comprises electron transport material and is doped in the first alkali carbonate in described electron transport material, and the mass percentage concentration of the first alkali carbonate described in the material of described electron transfer layer is 3% ~ 8%;

On described electron transfer layer, form electron injecting layer, the material of described electron injecting layer comprises material of main part and co-doped N-shaped material and the second alkali carbonate in described material of main part, and the mass percentage concentration of the second alkali carbonate described in the material of described electron injecting layer is 5% ~ 10%; And

On described electron injecting layer, form cathode layer;

Wherein, described electron transport material and described material of main part are selected from respectively 4,7-diphenyl-1,10-phenanthroline, 4,7-diphenyl-1,10-Phen, 4-biphenyl phenolic group-bis-(2-methyl-oxine) close aluminium, oxine aluminium, 3-(biphenyl-4-yl)-5-(4-tert-butyl-phenyl)-4-phenyl-4H-1,2, a kind of in 4-triazole and 1,3,5-tri-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) benzene; Described the first alkali carbonate and described the second alkali carbonate are selected from respectively a kind of in lithium carbonate, sodium carbonate, potash, rubidium carbonate and cesium carbonate; Described N-shaped material is selected from a kind of in lithium nitride, cesium fluoride, cesium trinitride, lithia and lithium fluoride.

9. the preparation method of organic electroluminescence device according to claim 8, is characterized in that,

The method that forms described hole injection layer is vacuum vapour deposition, and evaporation condition is: vacuum degree is 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described hole transmission layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described luminescent layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described electron transfer layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

The method that forms described electron injecting layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

and

The method that forms described cathode layer is vacuum vapour deposition, and evaporation condition is: vacuum degree 8 * 10 ^-5pa～3 * 10 ^-4pa, evaporation rate

10. the preparation method of organic electroluminescence device according to claim 8, is characterized in that, described anode substrate also comprises the surface activation process step to described anode substrate after cleaning.

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