CN104193738A - Benzimidazole-based electronic transmission compound - Google Patents

Abstract

The invention discloses a benzimidazole-based electronic transmission compound disclosed as the following structural formula (I). The compound has favorable heat stability, can be used for manufacturing organic electroluminescent devices, and is applicable to the field of organic solar cells, organic thin film transistors or organic photoreceptors.

Description

A kind of electric transmission compound based on benzoglyoxaline

Technical field

The present invention relates to organic electroluminescent field, relate to specifically a kind of electric transmission compound based on benzoglyoxaline.

Background technology

The device of organic electroluminescence device (OLEDs) for being prepared from by spin coating or vacuum evaporation deposition one deck organic materials between two metal electrodes, three layers of classical organic electroluminescence device comprise hole transmission layer, luminescent layer and electron transfer layer.The hole being produced by anode is followed the electronics being produced by negative electrode to be combined in luminescent layer through electron transfer layer and is formed exciton through hole transmission layer, then luminous.Organic electroluminescence device can regulate the light of the various needs of transmitting as required by changing the material of luminescent layer.

Organic electroluminescence device is as a kind of novel technique of display, have that luminous, wide visual angle, less energy-consumption, efficiency are high, thin, rich color, fast response time, Applicable temperature scope are wide, low driving voltage, can make the distinct advantages such as flexible and transparent display panel and environmental friendliness, can be applied in flat-panel monitor and a new generation's illumination above, also can be used as the backlight of LCD.

Since invention at the bottom of the eighties in 20th century, organic electroluminescence device is industrially application to some extent, and such as screens such as camera and mobile phones, but current OLED device is because efficiency is low, the factors such as work-ing life is short restrict it and apply widely, particularly large screen display.And restrict the performance that one of them important factor is exactly the electroluminescent organic material in organic electroluminescence device.Because OLED device is applying voltage-operated time, can produce joule heating in addition, make organic materials that crystallization easily occur, affect life-span and the efficiency of device, therefore, also need to develop the electroluminescent organic material of stability and high efficiency.

In OLED material, because the speed of most electroluminescent organic material transporting holes is faster than the speed of transmission electronic, easily cause the electronics of luminescent layer and number of cavities uneven, the efficiency of device is just lower like this.Three (oxine) aluminium (Alq ₃) since invention, be extensively studied, but still very low as its electronic mobility of electron transport material, and the intrinsiccharacteristic that self can degrade, take in the device of electron transfer layer, there will be the situation of voltage drop, simultaneously, due to lower electronic mobility, make a large amount of holes enter into Alq ₃in layer, excessive hole is with non-luminous form quantity of radiant energy, and when as electron transport material, due to the characteristic of its green light, in application, is restricted.Therefore, development stability and have the electron transport material of larger electronic mobility, has great value to being widely used of organic electroluminescence device.

Summary of the invention

First the present invention provides a kind of electric transmission compound based on benzoglyoxaline, and it is the compound with following structural formula I:

Wherein, R ₁, R ₂, R ₃, R ₄, R ₅, R ₆, R ₇and R ₈respectively independently selected from replacement or the unsubstituted alkynyl of the replacement of the replacement of the replacement of the alkyl of hydrogen, D atom, halogen, cyano group, nitro, C1-C8, C1-C8 alkoxyl group, C6-C30 or unsubstituted aryl, C3-C30 or unsubstituted heteroaryl, C2-C8 or unsubstituted thiazolinyl, C2-C8;

L ₁and L ₂respectively independently selected from the alkyl of sky, singly-bound, C1-C6, the replacement of the replacement of C6-C30 or unsubstituted aryl, C3-C30 or unsubstituted heteroaryl,

X ₁and X ₂respectively independently selected from O, S, S=O, S (O) ₂, Se, NAr;

A is selected from O, S, S=O, S (O) ₂, Se;

Wherein Ar is selected from replacement or the unsubstituted heteroaryl of the replacement of hydrogen, C1-C12 alkyl, C6-C60 or unsubstituted aryl, C3-C60;

Wherein preferred mode is:

R ₁, R ₂, R ₃, R ₄, R ₅, R ₆, R ₇and R ₈respectively independently selected from hydrogen, halogen, cyano group, nitro, C1-C8 alkyl, C1-C8 alkoxyl group, phenyl, naphthyl, pyridyl, pyrimidyl, thiadiazolyl group, triazol radical, three nitrogen piperazine bases, quinoline;

L ₁and L ₂respectively independently selected from sky, singly-bound, phenyl, the phenyl being replaced by C1-C4 alkyl, naphthyl, the naphthyl that replaced by C1-C4 alkyl;

X ₁and X ₂respectively independently selected from O, S, S=O, S (O) ₂, NAr;

A is selected from O, S, S=O, S (O) ₂;

Ar is selected from alkyl, phenyl, naphthyl, anthryl, phenanthryl, pyrenyl, perylene base, the fluoranthene base, (9 of C1-C8,9-dialkyl group) fluorenyl, (9,9-bis-replaces or unsubstituted aryl) fluorenyl, 9,9-is Spirofluorene-based, dibenzothiophene base, dibenzofuran group, pyridyl, pyrimidyl, thiadiazolyl group, triazol radical, three nitrogen piperazine bases, quinolyl;

Wherein above-mentioned phenyl, naphthyl, anthryl, phenanthryl, pyrenyl, perylene base, fluoranthene base, (9,9-dialkyl group) fluorenyl, (9,9-bis-replaces or unsubstituted aryl) fluorenyl, 9,9-is Spirofluorene-based, dibenzothiophene base, dibenzofuran group, pyridyl, pyrimidyl, thiadiazolyl group, triazol radical, three nitrogen piperazine bases, quinolyl can further be replaced by the aryl of the alkyl of C1-C4 or C6-C30;

Further preferred mode is:

R ₁, R ₂, R ₃, R ₄, R ₅, R ₆, R ₇and R ₈respectively independently selected from hydrogen, fluorine, nitro, methyl, ethyl, propyl group, sec.-propyl, the tertiary butyl, normal-butyl, n-hexyl, phenyl, naphthyl;

L ₁and L ₂respectively independently selected from sky, singly-bound, phenyl, naphthyl;

X ₁and X ₂respectively independently selected from O, S, NAr;

A is selected from O and S;

Wherein Ar is selected from methyl, ethyl, propyl group, sec.-propyl, the tertiary butyl, normal-butyl, n-hexyl, the replacement of C1-C4 alkyl or unsubstituted following aryl and heteroaryl:

Further preferred, the electric transmission compound based on benzoglyoxaline of the present invention is the compound of following structural 1-70.

Electric transmission compound based on benzoglyoxaline of the present invention can prepare by Suzuki linked reaction.

Electric transmission compound based on benzoglyoxaline of the present invention can be applied in organic electroluminescence device, organic solar batteries, OTFT or organophotoreceptorswith field.

The present invention also provides a kind of organic electroluminescence device, this device comprises anode, negative electrode and organic layer, organic layer comprises one or more layers in luminescent layer, hole injection layer, hole transmission layer, hole blocking layer, electron injecting layer or electron transfer layer, has at least one deck to contain just like the electric transmission compound based on benzoglyoxaline structural formula (I) Suo Shu in wherein said organic layer:

R wherein ₁-R ₈, Ar, A, X ₁-X ₂and L ₁-L ₂definition as previously mentioned.

Wherein organic layer is luminescent layer and electron transfer layer;

Or organic layer is luminescent layer, hole injection layer, hole transmission layer and electron transfer layer;

Or organic layer is luminescent layer, hole injection layer, hole transmission layer, electron transfer layer and electron injecting layer;

Or organic layer is luminescent layer, hole injection layer, hole transmission layer, electron transfer layer, electron injecting layer and blocking layer;

Or organic layer is luminescent layer, hole transmission layer, electron transfer layer, electron injecting layer and blocking layer;

Or organic layer is luminescent layer, hole transmission layer, electron injecting layer and blocking layer;

Wherein the layer at the electric transmission compound place based on benzoglyoxaline as described in structural formula (I) is electron transfer layer or electron injecting layer;

Wherein the described electric transmission compound based on benzoglyoxaline of structural formula (I) is the compound of structural formula 1-70;

The electric transmission compound based on benzoglyoxaline as described in structural formula I can be used separately, also can use with other compound; The electric transmission compound based on benzoglyoxaline as described in structural formula I can be used separately a kind of compound wherein, also can use two or more the compound in structural formula I simultaneously.

Organic electroluminescence device of the present invention, further preferred mode is, this organic electroluminescence device comprises anode, hole transmission layer, luminescent layer, electron transfer layer, electron injecting layer and negative electrode, the compound that wherein contains structural formula (I) in electron transfer layer or electron injecting layer; Further preferred, the compound in electron transfer layer or electron injecting layer is the compound of structural formula 1-70.

Organic electroluminescence device of the present invention, structural formula I compound also can doublely be done electron injecting layer during as electron transfer layer.

The total thickness of organic electroluminescence device organic layer of the present invention is 1-1000nm, preferably 50-500nm.

Organic electroluminescence device of the present invention is when being used the present invention to have the compound of structural formula I, can use collocation other materials, as hole injection layer, hole transmission layer, luminescent layer, electron transfer layer, electron injecting layer and blocking layer etc., and obtain blue light, green glow, gold-tinted, ruddiness or white light.

The hole transmission layer of organic electroluminescence device of the present invention and hole injection layer, material requested has good hole transport performance, can effectively hole be transferred to luminescent layer from anode.Can comprise other small molecules and macromolecular organic compound, include but not limited to carbazole compound, triaromatic amine compound, benzidine compound, compound of fluorene class, phthalocyanine-like compound, the assorted triphen (hexanitrilehexaazatriphenylene), 2 of six cyano group six, 3,5,6-tetrafluoro-7,7', 8,8'-, tetra-cyanogen dimethyl para benzoquinone (F4-TCNQ), Polyvinyl carbazole, Polythiophene, polyethylene or polyphenyl sulfonic acid.

The luminescent layer of organic electroluminescence device of the present invention, has the good characteristics of luminescence, can regulate as required the scope of visible ray.Can contain following compound, include, but are not limited to naphthalene compounds, pyrene compound, compound of fluorene class, luxuriant and rich with fragrance compounds, bend compounds, fluoranthene compounds, anthracene compounds, pentacene compounds, perylene compounds, two aromatic ethylene compounds, triphenylamine ethylene compounds, aminated compounds, carbazole compound, benzimidazoles compound, furfuran compound, metal organic fluorescence complex compound, the organic phosphorescence complex compound of metal is (as Ir, Pt, Os, Cu), polyvinyl carbazole, poly organic silicon compound, the organic polymer luminescent materials such as Polythiophene, they can use separately, also can use by multiple mixture.

The Organic Electron Transport Material of organic electroluminescence device of the present invention requires to have good electronic transmission performance, can, effectively during electronics is from cathode transport to luminescent layer, have very large electronic mobility.Except of the present invention, have structural formula I compound, can also select following compound, but be not limited to this, oxa-oxazole, thiazole compound, triazole compound, three nitrogen piperazine compounds, triazine compounds, quinoline compounds, phenazine compounds, siliceous heterocyclic compound, quinolines, phenanthroline compounds, metallo-chelate (as Alq3), fluorine substituted benzene compound, benzimidazoles compound.

The electron injecting layer of organic electroluminescence device of the present invention, can effectively electronics be injected into organic layer from negative electrode, except of the present invention, have structural formula I compound, mainly be selected from basic metal or alkali-metal compound, or be selected from compound or the alkali metal complex of alkaline-earth metal or alkaline-earth metal, can select following compound, but be not limited to this, basic metal, alkaline-earth metal, rare earth metal, alkali-metal oxide compound or halogenide, the oxide compound of alkaline-earth metal or halogenide, the oxide compound of rare earth metal or halogenide, the organic complex of basic metal or alkaline-earth metal, be preferably lithium, lithium fluoride, Lithium Oxide 98min, lithium nitride, oxine lithium, caesium, cesium carbonate, oxine caesium, calcium, Calcium Fluoride (Fluorspan), calcium oxide, magnesium, magnesium fluoride, magnesiumcarbonate, magnesium oxide, these compounds can be used separately also and can use by mixture, also can be used in conjunction with other electroluminescent organic materials.

Every one deck of organic layer in organic electroluminescence device of the present invention, can prepare by modes such as vacuum vapour deposition, molecular beam vapour deposition method, the dip coating that is dissolved in solvent, spin-coating method, excellent painting method or spray ink Printings.For metal motor, can use vapour deposition method or sputtering method to be prepared.

Device experimental shows, the electric transmission compound based on benzoglyoxaline of the present invention as described in structural formula (I), has better thermostability, high-luminous-efficiency, high luminance purity.The organic electroluminescence device that adopts this organic electroluminescent compounds to make have advantages of the good and purity of color excellence of electroluminescent efficiency and the life-span long.

Accompanying drawing explanation

Fig. 1 is the hydrogen nuclear magnetic spectrogram of compound 31.

Fig. 2 is the hydrogen nuclear magnetic spectrogram of compound 51.

Fig. 3 is that compound 31 and compound 51 are 1 * 10 in concentration ^-5the uv-visible absorption spectra recording with Varian Cary 500 ultraviolet-visible spectrophotometers under the dichloromethane solution of mole every liter.

Fig. 4 is that compound 31 and compound 51 are 1 * 10 in concentration ^-5the fluorescence emission spectrum recording with Varian Cary Eclipse spectrophotofluorometer under the dichloromethane solution of mole every liter.

Fig. 5 is a kind of organic electroluminescence device structural representation of the present invention

Wherein, 110 are represented as glass substrate, and 120 are represented as anode, and 130 are represented as hole transmission layer, and 140 are represented as luminescent layer, and 150 are represented as electron transfer layer, and 160 are represented as electron injecting layer, and 170 are represented as negative electrode.

Fig. 6 is that embodiment 3 is at 25mA/cm ²current density under emmission spectrum.

Embodiment

In order more to describe the present invention in detail, especially exemplified by following example, but be not limited to this.

Embodiment 1

Synthesizing of compound 31

Intermediate 31-1's is synthetic

In flask, add the acetic acid of thioxanthone (5.0g, 24mmol) and 45ml, reflux, slowly drips bromine (9.6g, 60mmol), drips off, reflux 12 hours, cooling, filter, obtain 6.2g yellow solid, productive rate is 70%. ¹H?NMR(400MHz,CDCl ₃,δ):8.74(s,2H),7.73-7.75(d,J＝8.4Hz,2H),7.46-7.48(d,J＝8.4Hz,2H).

Intermediate 31-2 and intermediate 31-3's is synthetic

In there-necked flask, add magnesium chips (0.32g, 13.5mmol), the iodine that adds catalytic amount, slowly drips 15ml tetrahydrofuran (THF) (THF) solution that is dissolved with 2-bromo biphenyl (3g, 13.5mmol), reflux 2 hours, cooling, the liquid of gained is slowly added drop-wise to the 30ml tetrahydrofuran solution that is dissolved with intermediate 31-1 (2.5g, 6.8mmol), dropwise, reflux 6 hours, cooling, reaction solution is poured into water, be extracted with ethyl acetate three times, merge organic phase, dry, the concentrated intermediate 31-2 that obtains.The acetic acid that adds 30ml toward the intermediate 31-2 of gained, reflux, the concentrated hydrochloric acid of dropping 0.5ml, refluxes 2 hours, cooling, filters and obtains 2.4g white solid, and productive rate is 71%. ¹H?NMR(400MHz,CDCl ₃,δ):7.79-7.81(d,J＝7.6Hz,2H),7.52-7.54(d,J＝7.6Hz,2H),7.41-7.45(m,2H),7.23-7.26(m,6H),6.60(s,2H).

Synthesizing of compound 31

In single port flask, add compound 31-3 (0.25g, 0.5mmol), 4-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) phenylo boric acid (0.4g, 1.24mmol), the 2M K of the THF of 20ml and 8ml ₂cO ₃the aqueous solution; under nitrogen protection, add 10mg tetra-(triphenyl phosphorus) palladium (0.0075mmol), then reflux is 5 hours; reacted; cooling, use dichloromethane extraction three times, organic layer anhydrous sodium sulfate drying; organic solvent is removed in rotation; crude product carries out column chromatography purification, obtains 0.42g off-white color solid, and productive rate is 95%. ¹H?NMR(400MHz,CDCl ₃,δ):7.85-7.87(d,J＝8.0Hz,2H),7.77-7.79(d,J＝7.6Hz,2H),7.63-7.64(d,J＝7.6Hz,2H),7.20-7.48(m,28H),7.13-7.15(d,J＝8.0Hz,4H),6.75(s,2H).

The hydrogen nuclear magnetic spectrogram of compound 31 is shown in Fig. 1.Compound 31 is 1 * 10 in concentration ^-5under the dichloromethane solution of mole every liter, with the maximum absorption wavelength that Varian Cary 500 ultraviolet-visible spectrophotometers record, be 350nm, uv-visible absorption spectra is shown in Fig. 3, and Fig. 4 is that compound 31 is 1 * 10 in concentration ^-5the fluorescence emission spectrum recording with Varian Cary Eclipse spectrophotofluorometer under the dichloromethane solution of mole every liter, the maximum emission wavelength recording is 410nm.

Embodiment 2

Synthesizing of compound 51

In single port flask, add compound 31-3 (0.25g, 0.5mmol), 3-(1-phenyl-1H-benzimidazolyl-2 radicals-yl) phenylo boric acid (0.4g, 1.24mmol), the 2M K of the THF of 20ml and 8ml ₂cO ₃the aqueous solution; under nitrogen protection, add 10mg tetra-(triphenyl phosphorus) palladium (0.0075mmol), then reflux is 5 hours; reacted; cooling, use dichloromethane extraction three times, organic layer anhydrous sodium sulfate drying; organic solvent is removed in rotation; crude product carries out column chromatography purification, obtains 0.31g off-white color solid, and productive rate is 70%. ¹H?NMR(400MHz,CDCl ₃,δ):7.86-7.88(d,J＝7.6Hz,2H),7.77-7.79(d,J＝7.6Hz,2H),7.60-7.62(d,J＝7.6Hz,2H),7.16-7.51(m,28H),7.07-7.10(m,4H),6.70(s,2H).

The hydrogen nuclear magnetic spectrogram of compound 51 is shown in Fig. 2.Compound 51 is 1 * 10 in concentration ^-5under the dichloromethane solution of mole every liter, with the maximum absorption wavelength that Varian Cary 500 ultraviolet-visible spectrophotometers record, be 330nm, uv-visible absorption spectra is shown in Fig. 3, and Fig. 4 is that compound 31 is 1 * 10 in concentration ^-5the fluorescence emission spectrum recording with Varian Cary Eclipse spectrophotofluorometer under the dichloromethane solution of mole every liter, the maximum emission wavelength recording is 380nm.

Embodiment 3

The preparation of organic electroluminescence device

Use the compound 51 preparation OLED of embodiment 2

First, by electrically conducting transparent ito glass substrate 110 (above with anode 120) (China Nanbo Group Co) successively warp: deionized water, ethanol, acetone and deionized water are cleaned, then use oxygen plasma treatment 30 seconds.

Then, evaporation NPB, forms the thick hole transmission layer 130 of 60nm.

Then, the compd A lq that evaporation 30nm is thick on hole transmission layer ₃as luminescent layer 140.

Then, the compound 51 that evaporation 20nm is thick on luminescent layer is as electron transfer layer 150.

Finally, evaporation 1nm LiF is that electron injecting layer 160 and 100nm Al are as device cathodes 170.

Prepared device (structural representation is shown in Fig. 5) records at 25mA/cm with Photo Research PR650 spectrograph ²current density under efficiency be 0.5cd/A, the current density under the driving voltage of 8V is 346mA/cm ², Fig. 6 represents that the organic electroluminescence device of the present embodiment is at 25mA/cm ²current density under emmission spectrum, be green spectral.

Comparative example 1

First, by electrically conducting transparent ito glass substrate 110 (above with anode 120) (China Nanbo Group Co) successively warp: deionized water, ethanol, acetone and deionized water are cleaned, then use oxygen plasma treatment 30 seconds.

Then, evaporation NPB, forms the thick hole transmission layer 130 of 60nm.

Then, the thick Alq of evaporation 30nm on hole transmission layer ₃as luminescent layer 140.

Then, the thick Alq of evaporation 20nm on luminescent layer ₃as electron transfer layer 150.

Finally, evaporation 1nm LiF is that electron injecting layer 160 and 100nm Al are as device cathodes 170.

Prepared device records at 25mA/cm with Photo Research PR650 spectrograph ²current density under efficiency be 0.28cd/A, the current density under the driving voltage of 8V is 168mA/cm ², transmitting green light.

Under identical condition, apply the efficiency of organic electroluminescence device prepared by the electric transmission compound based on benzoglyoxaline of the present invention and current density higher than comparative example, as mentioned above, compound of the present invention has high stability, and organic electroluminescence device prepared by the present invention has high efficiency and optical purity.

Structural formula described in device

Claims (5)

1. the electric transmission compound based on benzoglyoxaline, it is the compound with following structural formula I:

Wherein, R ₁, R ₂, R ₃, R ₄, R ₅, R ₆, R ₇and R ₈respectively independently selected from replacement or the unsubstituted alkynyl of the replacement of the replacement of the replacement of the alkyl of hydrogen, D atom, halogen, cyano group, nitro, C1-C8, C1-C8 alkoxyl group, C6-C30 or unsubstituted aryl, C3-C30 or unsubstituted heteroaryl, C2-C8 or unsubstituted thiazolinyl, C2-C8;

L ₁and L ₂respectively independently selected from the alkyl of sky, singly-bound, C1-C6, the replacement of the replacement of C6-C30 or unsubstituted aryl, C3-C30 or unsubstituted heteroaryl,

X ₁and X ₂respectively independently selected from O, S, S=O, S (O) ₂, Se, NAr;

A is selected from O, S, S=O, S (O) ₂, Se;

Wherein Ar is selected from replacement or the unsubstituted heteroaryl of the replacement of hydrogen, C1-C12 alkyl, C6-C60 or unsubstituted aryl, C3-C60.

2. the electric transmission compound based on benzoglyoxaline according to claim 1, is characterized in that wherein

R ₁, R ₂, R ₃, R ₄, R ₅, R ₆, R ₇and R ₈respectively independently selected from hydrogen, halogen, cyano group, nitro, C1-C8 alkyl, C1-C8 alkoxyl group, phenyl, naphthyl, pyridyl, pyrimidyl, thiadiazolyl group, triazol radical, three nitrogen piperazine bases, quinoline;

L ₁and L ₂respectively independently selected from sky, singly-bound, phenyl, the phenyl being replaced by C1-C4 alkyl, naphthyl, the naphthyl that replaced by C1-C4 alkyl;

X ₁and X ₂respectively independently selected from O, S, S=O, S (O) ₂, NAr;

A is selected from O, S, S=O, S (O) ₂;

Ar is selected from alkyl, phenyl, naphthyl, anthryl, phenanthryl, pyrenyl, perylene base, the fluoranthene base, (9 of C1-C8,9-dialkyl group) fluorenyl, (9,9-bis-replaces or unsubstituted aryl) fluorenyl, 9,9-is Spirofluorene-based, dibenzothiophene base, dibenzofuran group, pyridyl, pyrimidyl, thiadiazolyl group, triazol radical, three nitrogen piperazine bases, quinolyl;

Wherein above-mentioned phenyl, naphthyl, anthryl, phenanthryl, pyrenyl, perylene base, fluoranthene base, (9,9-dialkyl group) fluorenyl, (9,9-bis-replaces or unsubstituted aryl) fluorenyl, 9,9-is Spirofluorene-based, dibenzothiophene base, dibenzofuran group, pyridyl, pyrimidyl, thiadiazolyl group, triazol radical, three nitrogen piperazine bases, quinolyl can further be replaced by the aryl of the alkyl of C1-C4 or C6-C30.

3. the electric transmission compound based on benzoglyoxaline according to claim 1, wherein

R ₁, R ₂, R ₃, R ₄, R ₅, R ₆, R ₇and R ₈respectively independently selected from hydrogen, fluorine, nitro, methyl, ethyl, propyl group, sec.-propyl, the tertiary butyl, normal-butyl, n-hexyl, phenyl, naphthyl;

L ₁and L ₂respectively independently selected from sky, singly-bound, phenyl, naphthyl;

X ₁and X ₂respectively independently selected from O, S, NAr;

A is selected from O and S;

Wherein Ar is selected from methyl, ethyl, propyl group, sec.-propyl, the tertiary butyl, normal-butyl, n-hexyl, the replacement of C1-C4 alkyl or unsubstituted following aryl and heteroaryl:

。

4. the electric transmission compound based on benzoglyoxaline according to claim 1, it is the compound of following structural formula 1-70:

。

5. the electric transmission compound based on benzoglyoxaline described in claim 1-4 any one, its application in organic electroluminescence device.