JP4285947B2 - Luminescent organometallic compound and light emitting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an organometallic compound that has good luminous efficiency and can emit spectral components in the red or blue wavelength region, and a light emitting device such as an organic electroluminescence device using the same.
[0002]
[Prior art]
In recent years, with the rise of information technology (IT), there is an increasing demand for a thin display element that is thin, about several millimeters thick, and capable of full color display. The means for realizing full color display can be broadly classified as follows: (1) a method of arranging a large number of light emitting elements that emit red, green, and blue monochromatic light, which are the three primary colors of light, and (2) a white light emitting element and light. (3) A combination of a light emitting element that emits ultraviolet light or blue light, and a wavelength conversion means that converts the wavelength of the light into the three primary colors of light. There are three types of methods used.
[0003]
A display device using an electroluminescence element is known as a display device capable of full color display by the method (1). As an electroluminescence element, an inorganic electroluminescence element using an inorganic substance such as sulfide as a light emitting substance is known. Since the inorganic electroluminescence element has a very high driving voltage and requires AC driving, it is difficult to increase the reliability of the peripheral driving circuit, and the cost also increases. In addition, since it is driven with a high alternating voltage, there is a problem that strong electromagnetic waves are radiated, which may adversely affect peripheral electronic devices.
[0004]
In recent years, in order to realize a thin light-emitting element that solves the above-described problem, organic electroluminescence elements that use an amorphous thin film of an organic substance as a light-emitting substance have been actively developed.
[0005]
In general, a high-performance green light-emitting element can be realized relatively easily, but it is difficult to realize a blue or red thin light-emitting element. Also in an organic electroluminescent element, the element which can light-emit the spectral component of a blue or red wavelength range is desired.
[0006]
In Appl. Phys. Lett., 1999, 75 (1), 4-6 by Forrest, Stephen R. et al., Tris (2-phenylpyridine) iridium (Ir (ppy)), which is a green phosphorescent substance, is obtained. , 4,4'-bis (carbazol-9-yl) -biphenyl (CBP) is disclosed as an organic electroluminescent device using a light-emitting layer mixed in a concentration of 1 to 12% by mass. . In such a light-emitting element, a light emission peak that is considered to be from a triplet excited state of Ir (ppy) is recognized, and good light emission efficiency is obtained.
[0007]
[Problems to be solved by the invention]
Those capable of emitting light from the triplet excited state as described above emit light via a triplet excited state that is not involved in normal light emission and has not been used effectively, so that the light emission efficiency can be greatly improved. it can. Accordingly, there is a demand for an organic electroluminescence device capable of emitting light via a triplet excited state even in red or blue light emission.
[0008]
An object of the present invention is to provide a light-emitting organometallic compound having good light emission efficiency and capable of emitting red or blue light and a light-emitting element using the same.
[0009]
[Means for Solving the Problems]
The luminescent organometallic compound of the present invention is represented by the following general formula (1) or general formula (2).
[0010]
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[0011]
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[0012]
[In General Formulas (1) and (2), A and B represent a cyclic structure, M represents a metal atom, X represents a heteroatom other than carbon and hydrogen, and Y represents at least one bonded to the cyclic structure B. One electron withdrawing group, Lb represents a monodentate or multidentate ligand, and p, q and r are natural numbers. ]
In the general formulas (1) and (2), A and / or B preferably exhibit aromaticity. Further, when the number of π electrons of the aromatic ring A is 4m + 2 (m is a natural number) and the number of π electrons of the aromatic ring B is 4n + 2 (n is a natural number), m is preferably larger than n. .
[0013]
The bond between the heteroatom X and the metal atom M may be a covalent bond or a coordination bond, but is generally preferably a coordination bond.
The heteroatom X is preferably an element having a higher electronegativity than carbon, for example, nitrogen, oxygen, sulfur, boron, silicon, germanium, phosphorus, arsenic, selenium, tellurium, fluorine, chlorine, bromine, and iodine. It is preferable that it is an element chosen from these. In particular, nitrogen, oxygen, or sulfur is preferable.
[0014]
The metal atom M is preferably an element having an atomic number of 56 or more, more preferably an element having an atomic number of 75 or more. Specifically, at least one element selected from tungsten, rhenium, osmium, iridium, platinum, and gold is particularly preferable.
[0015]
The substituent Y bonded to the cyclic structure B is not particularly limited as long as it is a substituent that exhibits an electron-withdrawing property compared with hydrogen. For example, a halogen, a cyano group, or an alkyl substituted with a halogen or a cyano group Group, a phenyl group, or an aryl group.
[0016]
Examples of the luminescent organometallic compound of the present invention include organometallic compounds having a structure represented by the following general formulas (3) to (10).
[0017]
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[0018]
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[0019]
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[0020]
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[0021]
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[0022]
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[0023]
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[0024]
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[0025]
[In General Formulas (3) to (10), A represents a cyclic structure, M represents a metal atom, X represents a heteroatom other than carbon and hydrogen, and Y represents an electron-withdrawing group bonded to the benzene ring. Lb represents a monodentate or polydentate ligand, and p, q and r are natural numbers. ]
Examples of the luminescent organometallic compound of the present invention include organometallic compounds having a structure represented by the following general formulas (11) to (14).
[0026]
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[0027]
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[0028]
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[0029]
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[0030]
[In the general formulas (11) to (14), A represents a cyclic structure, M represents a metal atom, X and Z represent different heteroatoms other than carbon and hydrogen, and Y represents a heterocycle. Represents an electron-withdrawing group bonded to, Lb represents a monodentate or multidentate ligand, and p, q, and r are natural numbers. ]
Examples of the luminescent organometallic compound of the present invention include organometallic compounds having a structure represented by the following general formulas (15) to (18).
[0031]
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[0032]
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[0033]
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[0034]
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[0035]
[In the general formulas (15) to (18), A represents a cyclic structure, M represents a metal atom, X and Z represent different heteroatoms other than carbon and hydrogen, and Y represents a heterocyclic ring. Represents an electron-withdrawing group bonded to, Lb represents a monodentate or multidentate ligand, and p, q, and r are natural numbers. ]
Examples of the luminescent organometallic compound of the present invention include organometallic compounds having a structure represented by the following general formulas (19) to (22).
[0036]
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[0037]
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[0038]
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[0039]
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[0040]
[In General Formulas (19) to (22), A represents a cyclic structure, M represents a metal atom, X and Z represent hetero atoms other than carbon and hydrogen, which may be different from each other, and Y represents a heterocyclic ring. Represents an electron-withdrawing group bonded to, Lb represents a monodentate or multidentate ligand, and p, q, and r are natural numbers. ]
In the general formulas (3) to (22), A preferably represents aromaticity. The number of π electrons in the aromatic ring A is preferably 4m + 2 (m is a natural number).
[0041]
The heteroatom Z is preferably an element having a higher electronegativity than carbon, for example, nitrogen, oxygen, sulfur, boron, silicon, germanium, phosphorus, arsenic, selenium, tellurium, fluorine, chlorine, bromine, and iodine. It is preferable that it is an element chosen from these. In particular, nitrogen, oxygen, or sulfur is preferable. The heteroatom Z may be the same as or different from the heteroatom X.
[0042]
The luminescent organometallic compound of the present invention preferably emits a spectrum in a blue or red wavelength region. Moreover, it is preferable that it emits light via a triplet excited state. Moreover, it is preferable that it has sublimation property. A thin film of a light-emitting organometallic compound can be formed by a vapor deposition method as long as it has sublimation properties.
[0043]
The light-emitting organometallic compound according to another aspect of the present invention includes a first structural portion having a bond between a carbon atom and a metal atom, and a second structure having a bond between a heteroatom other than carbon and hydrogen and the metal atom. A light-emitting organometallic compound having a structural site, wherein at least one hydrogen in the first structural site is substituted with an electron-withdrawing group.
[0044]
In the light-emitting organometallic compound of the above aspect, it is preferable that the first structural portion and / or the second structural portion forms an aromatic ring. In addition, the bond between the heteroatom and the metal atom in the second structural portion is preferably a coordination bond.
[0045]
The light emitting device of the present invention is characterized in that the light emitting organometallic compound of the present invention is contained in a light emitting layer disposed between a pair of electrodes.
Specific examples of the laminated structure of the light emitting device include a laminated structure in which anode / hole transport layer / light emitting layer / hole blocking layer / cathode are arranged in this order, and anode / hole injection layer / hole transport layer / light emitting layer. There may be mentioned a laminated structure arranged in the order of / hole blocking layer / electron injection layer / cathode.
[0046]
In the light-emitting organometallic compound of the present invention, since at least one electron-withdrawing group Y is bonded to the cyclic structure B, the electron density in the carbon bonded to the metal atom M is reduced, and the effective electricity of carbon is reduced. Negativeness increases. As a result, the bond between the metal atom M and carbon becomes strong, and the chemical stability of the organometallic compound increases.
[0047]
Considering the light emission process of a luminescent material in terms of quantum mechanics, a triplet excited state in which electron spins are parallel at a ratio of about three-quarters of all excited states generated by combining electrons and holes by energization. A singlet excited state is generated in which the electron spins are antiparallel and the sum of the spin quantum numbers is 0 at a ratio of approximately one quarter. Of these two types of excited states, the light emission phenomenon that occurs when electrons in the singlet excited state transition to the ground state is called fluorescence. Fluorescence is spin tolerant. That is, fluorescence occurs easily because it does not need to be accompanied by inversion of electron spin. Therefore, fluorescence is widely used in light emitting phenomena such as fluorescent materials and organic electroluminescence.
[0048]
On the other hand, light emission due to transition of electrons in a triplet excited state to a ground state is called phosphorescence. Phosphorescence is forbidden to spin. According to Pauli's exclusion principle, there cannot be two electrons whose electron spins are parallel to the same electron orbit (in this case, the ground state corresponds), so the electrons transition to the ground state and emit light. In order to achieve this, the electron spin of the transitioning electron needs to be reversed by receiving some perturbation. In the majority of fluorescent materials and materials commonly used for organic electroluminescence, inversion of electron spin is difficult. Therefore, phosphorescence is known as a special phenomenon observed only in a cryogenic region below the liquid nitrogen temperature in a limited substance.
[0049]
In the luminescent organometallic compound of the present invention, the perturbation received by the electron spin of the transition electron, that is, the spin-orbit interaction is increased, so that light emission via the triplet excited state is significantly observed. Therefore, usually, light emission is performed via a triplet excited state that is not involved in light emission and has not been effectively used, and the light emission efficiency can be greatly improved.
[0050]
The luminescent organometallic compound of the present invention can be produced by reacting a first raw material that provides a metal atom M with a second raw material that provides an organic compound molecule that binds to the organometallic atom M.
[0051]
As the first raw material, a metal complex of a metal atom M can be used. The oxidation number of the metal atom M is preferably 0-3. As the metal atom M, as described above, tungsten, rhenium, osmium, iridium, platinum, gold and the like are preferably used. Examples of the most preferable oxidation number of each metal include tungsten (0), rhenium (I), osmium (II), iridium (III), platinum (II), and gold (I).
[0052]
The ligand of the metal complex is preferably a bidentate β-diketonate group, picolinic acid, N-methyl salicylimine, or the like. As the β-diketonate group, an acetylacetonate group is generally used, but an acetylacetonate group substituted with a substituent such as a phenyl group may be used as necessary. As the first raw material, a metal complex is preferably used as described above, but a metal chloride or a carbonyl complex having a corresponding oxidation number may be used instead of the metal complex.
[0053]
As the second raw material, an organic compound that is bonded to the metal atom M in the general formulas (1) and (2) is used. That is, an organic compound having the cyclic structures A and B, the hetero atom X, and the electron withdrawing group Y bonded to the cyclic structure B is used.
[0054]
The organic compound molecule used as the second raw material is substituted with an electron-withdrawing group. Examples of the organic compound molecule in a state before being substituted with the electron-withdrawing group include 1,7-phenanthroline, 2 -Phenylquinoline, benzo [h] quinoline, 4-phenylpyrimidine, 2- (1-naphthyl) pyridine, 2- (2-naphthyl) pyridine, 2-phenylpyridine, 2- (thiophen-2'-yl) pyridine, 2- (benzothiophen-2'-yl) pyridine, 2-phenyloxazole, 2-phenyl (benzoxazole), 2- (1-naphthyl) benzoxazole, 2- (2-naphthyl) benzoxazole, 2-phenylthiazole 2-phenyl (benzothiazole), 2- (1-naphthyl) benzothiazole, 2- (2-naphthyl) ben Thiazole, 2- (thiophen-2'-yl) thiazole, 2- (thiophen-2'-yl) benzotisol, 2- (benzothiophen-2'-yl) benzothiazole, 2- (1-naphthyl) quinoline, 2 -(2-naphthyl) quinoline and the like can be mentioned, and those obtained by bonding an electron-withdrawing group to these compounds can be used as the organic compound molecule as the second raw material.
[0055]
Examples of organic compound molecules having 2-phenylpyridine as a basic skeleton and having an electron-withdrawing group bonded thereto include 2- (2-fluorophenyl-1-yl) -pyridine and 2- (3-fluorophenyl-1-yl ) -Pyridine, 2- (4-fluorophenyl-1-yl) -pyridine;
2- (2,3-difluorophenyl-1-yl) -pyridine, 2- (2,4-difluorophenyl-1-yl) -pyridine, 2- (2,5-difluorophenyl-1-yl) -pyridine 2- (3,4-difluorophenyl-1-yl) -pyridine, 2- (3,5-difluorophenyl-1-yl) -pyridine, 2- (4,5-difluorophenyl-1-yl)- Pyridine;
2- (2,3,4-trifluorophenyl-1-yl) -pyridine, 2- (2,3,5-trifluorophenyl-1-yl) -pyridine, 2- (2,4,5-tri Fluorophenyl-1-yl) -pyridine, 2- (3,4,5-trifluorophenyl-1-yl) -pyridine;
2- (2,3,4,5-tetrafluorophenyl-1-yl) -pyridine;
2- (2-trifluoromethylphenyl-1-yl) -pyridine, 2- (3-trifluoromethylphenyl-1-yl) -pyridine, 2- (4-trifluoromethylphenyl-1-yl) -pyridine Etc.
[0056]
By reacting the first raw material and the second raw material, all or part of the ligand in the first raw material is replaced by the second raw material, whereby the above general formula (1) or general formula (2 The luminescent organometallic compound of this invention represented by this can be obtained. The ligand Lb in the general formula (2) may be the one that remains without replacing the ligand in the metal complex of the first raw material.
[0057]
As a reaction solvent for synthesizing the luminescent organometallic compound of the present invention, a solvent having a high polarity and a high boiling point is preferable. Suitable examples of the reaction solvent include 1,2-dinitrobenzene (boiling point 300 ° C. or higher), 1,3-dinitrobenzene (boiling point 297 ° C.), glycerol (1,2,3-propanetriol, boiling point 290 ° C.), Diethylene glycol (2,2′-oxybis-ethanol, boiling point 244 ° C.), 1,2,3-trichlorobenzene (boiling point 218 ° C.), 1,2,4-trichlorobenzene (boiling point 214 ° C.), nitrobenzene (boiling point 210 ° C.) , Ethylene glycol (1,2-ethanediol, boiling point 197 ° C.), dimethyl sulfoxide (boiling point 189 ° C.), propylene glycol (1,2-propanediol, boiling point 187 ° C.), 1,2-dichlorobenzene (boiling point 180 ° C.) N, N-dimethylformamide (boiling point 153 ° C.), ethylene glycol monoethyl ether ( -Ethoxyethanol, boiling point 136 ° C., chlorobenzene (boiling point 132 ° C.), 1,4-dioxane (boiling point 101 ° C.), ethanol (boiling point 78 ° C.), tetrahydrofuran (boiling point 66 ° C.), water and mixtures thereof. .
[0058]
Specific examples of the luminescent organometallic compound of the present invention include organometallic compounds having structures as shown in the following (Chemical Formula 45) to (Chemical Formula 56).
45: Tris (2- (3,5-difluorophenyl-1-yl) -pyridinato-N, C ² ′) Iridium (III)
46: Bis (2- (7-fluorobenzothiophen-2′-yl) -pyridinato-N, C ² ′) Acetylacetonate Iridium (III)
47: Tris (2- (4-fluorophenyl-1-yl) -pyridinato-N, C ² ′) Rhenium (III)
48: Tris (2- (5-fluorothiophen-2'-yl) -pyridinato-N, C ² ′) Iridium (III)
49: Tris (2- (4-fluorophenyl-1-yl) -1,3-oxazolate-N, C ² ′) Iridium (III)
50: Bis (2- (6-cyanonaphthalen-2-yl) benzothiazolate-N, C ² ′) Acetylacetonate Iridium (III)
51: Bis (7-fluorobenzo [h] quinolinato-N, C ^Ten ) Acetylacetonate Iridium (III)
52: Bis (2- (4-fluorophenyl-1-yl) pyridinato-N, C ² ′) Platinum (II)
53: Tris (2- (5-fluorophenyl-1-yl) pyridinato-N, C ² ′) Gold (III)
54: Tris (2- (4-fluorophenyl-1-yl) benzo [c] quinolinato-N, C ² ′) Iridium (III)
55: Tris (2- (4-cyanophenyl-1-yl) quinolinato-N, C ² ′) Iridium (III)
Formula 56: Bis (2- (4-cyanophenyl-1-yl) benzothiazolate-N, C ² ′) Acetylacetonate Iridium (III)
[0059]
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[0060]
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[0061]
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[0062]
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[0063]
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[0064]
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[0065]
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[0070]
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[0071]
DETAILED DESCRIPTION OF THE INVENTION
EXAMPLES Hereinafter, the present invention will be described more specifically with reference to examples. However, the present invention is not limited to the following examples, and can be implemented with appropriate modifications.
[0072]
Example 1 Tris (2- (3,5-difluorophenyl-1-yl) -pyridinato-N, C ² ′) Synthesis of iridium (III)
As a reaction vessel, the capacity is about 500cm. ^Three A four-necked flask made of boro-silicate glass (hereinafter simply referred to as a reaction vessel), and a ball-type water-cooled cooling tube (hereinafter simply referred to as a cooling tube) having a cooling part length of about 20 cm, A common rubbing joint was used to maintain airtightness. The connection port at the top of the reaction vessel is connected to a mechanical stirrer consisting of a motor, a joint, a glass stirrer bar, and a fluororesin stirrer blade, and an airtight seal through which the stirrer penetrates to maintain airtightness. The contents of the reaction vessel were allowed to be efficiently stirred. A sealed connection pipe for introducing an inert gas is connected to one side connection port of the reaction vessel, and the inert gas is introduced into the upper space in the reaction vessel while maintaining airtightness. I was able to introduce it. A glass tube for blowing inert gas into the contents of the reaction vessel is connected to the other connection port on the side of the reaction vessel, and the inert gas is blown into the contents while maintaining airtightness. The dissolved oxygen can be removed.
[0073]
50cm as reaction solvent ^Three Glycerol (hereinafter simply referred to as reaction solvent) was put into a reaction vessel, and nitrogen gas from which oxygen was removed as inert gas (hereinafter simply referred to as inert gas) was blown through a glass capillary for about 15 minutes. Dissolved oxygen was removed. While blowing an inert gas, the mixture was gradually heated to 100 ° C. to reduce the viscosity and the solubility of oxygen, and the dissolved oxygen was highly removed. Thereafter, the reaction solvent was cooled to room temperature (about 25 ° C.) while introducing an inert gas from the connecting pipe.
[0074]
While introducing an inert gas from a connecting pipe, 1 mmol of tris (acetylacetonato) iridium (III) as a first raw material was put in a reaction vessel and dissolved in a reaction solvent from which the dissolved oxygen was highly removed. I let you. Then, while introducing an inert gas from the connecting pipe, 3.5 mmol of (3,5-difluorophenyl-1-yl) pyridine was added as the second raw material, stirred for about 10 minutes at room temperature, and mixed well I let you. The mixture was heated gently with stirring, the reaction solvent evaporated, condensed in the cooling tower and continued to heat for 10 hours while maintaining the condition of refluxing to the reaction vessel. The outer wall temperature at the bottom of the reaction vessel at reflux was about 295 ° C.
[0075]
After slowly cooling the reaction mixture to about 30 ° C., a dilute hydrochloric acid aqueous solution having a concentration of 1 mol / liter was added to 200 cm. ^Three In addition, the unreacted second raw material was dissolved as a hydrochloride. At this time, it is considered that the unreacted first raw material was mostly dissolved in the solution. A pale yellow precipitate formed and the precipitate was collected by suction filtration. Furthermore, in order to remove impurities with high solubility, the precipitate on the filter was washed with a small amount of methanol, and then the solvent was evaporated to obtain the target organometallic compound.
[0076]
About 0.4 mmol of the target organometallic compound was obtained by the above operation (yield: about 40%). When this compound was irradiated with ultraviolet rays having a wavelength of about 370 nm, blue light emission was observed.
[0077]
In order to further purify the target organometallic compound, it was purified to sublimation by heating to about 300 ° C. at a vacuum of 5 Pa or less. The loss by sublimation purification was about 50%, and a brown non-sublimable residue was observed. Elemental analysis of the purified sublimation product gave an analysis result almost identical to the expected composition.
[0078]
Example 2 Bis (2- (7-fluorobenzothiophen-2'-yl) pyridinato-N, C ² ′) Synthesis of acetylacetonato iridium (III)
Example except that diethylene glycol was used as the reaction solvent, 1 mmol of iridium (III) chloride as the first raw material, and 2.5 mmol of 2- (6-fluorobenzothiophen-2'-yl) pyridine as the second raw material Reaction was carried out in the same manner as in Example 1 to synthesize an intermediate considered to be a binuclear complex of iridium.
[0079]
Next, a capacity of about 100 cm as a reaction vessel ^Three Except that diethylene glycol was used as a reaction solvent, 0.1 mmol of the above intermediate as a first raw material, 0.25 mmol of acetylacetone as a ligand, and 110 mg of sodium carbonate as an absorbing agent for chlorine to be eliminated. Reacted in the same manner as in Example 1 to obtain the desired organometallic compound. When this compound was irradiated with ultraviolet rays having a wavelength of about 370 nm, red light emission was observed. Elemental analysis of the purified sublimation product gave an analysis result almost identical to the expected composition.
[0080]
Example 3 Tris (2- (4-fluorophenyl-1-yl) -pyridinato-N, C ² ′) Synthesis of rhenium (III)
Example 1 except that 1,3-dinitrobenzene was used as the reaction solvent, 1 mmol rhenium (III) chloride as the first raw material, and (4-fluorophenyl-1-yl) -pyridine as the second raw material. The reaction was carried out to obtain the desired organometallic compound. When this compound was irradiated with ultraviolet rays having a wavelength of about 370 nm, blue light emission was observed. Elemental analysis of the purified sublimation product gave an analysis result almost identical to the expected composition.
[0081]
Example 4 Production and Evaluation of Light-Emitting Element
In advance ₂ O _Three -SnO ₂ On a glass substrate on which an anode made of (ITO) is formed, 10 ^-Four An organic thin film and then a cathode made of an alloy of indium and magnesium (Mg: In) were formed by a vapor deposition method at a degree of vacuum on the order of Pa, and a light emitting element was manufactured. Hereinafter, the formation process of an organic thin film is demonstrated in detail.
[0082]
As a hole injection layer on the anode surface made of ITO, a layer made of 4,4,4-tris (3-methylphenylphenylamino) triphenylamine (abbreviated as MTDATA; hereinafter the same) shown in (Chemical Formula 57), then As the hole transport layer, a layer made of 4,4′-bis [N- (1-naphthyl) -N-phenyl-amino] biphenyl (NPB) shown in (Chemical Formula 58) was formed. Thereafter, tris (2- (3,5-difluorophenyl) synthesized in Example 1 was used as a mixture light-emitting layer on 4,4′-bis (carbazol-9-yl) -biphenyl (CBP) shown in (Chemical Formula 59). -1-yl) -pyridinato-N, C ² ′) A layer in which 10% by mass of iridium (III) is mixed is formed, and then as a hole blocking layer, from 2,9-dimethyl-4,7-diphenyl-1,10-phenanthroline (BCP) shown in (Chemical Formula 60) After forming the layer, a layer made of aluminum tris (8-hydroxyquinoline) (Alq) shown in (Chemical Formula 61) is formed as an electron injection layer, and further, a magnesium alloy containing 10% by mass of indium (Mg: In) is used. A cathode was formed to produce a light emitting device.
[0083]
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[0085]
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[0086]
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[0087]
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[0088]
The film thickness of each layer obtained by a quartz oscillator type film thickness meter is shown in parentheses in the following formula.
ITO / MTDATA (20 nm) / NPB (10 nm) / light emitting layer (20 nm) / BCP (10 nm) / Alq (20 nm) / Mg: In (200 nm).
[0089]
The simplified molecular formula of MTDATA is C ₅₇ H ₄₈ N _Four (The number in the simplified molecular formula represents the number of atoms in the molecule, the same applies hereinafter), the molar mass is 789.04 g / mol, the melting point is 203 ° C., the glass transition temperature is 75 ° C., and the ionization potential is The energy gap between the highest occupied molecular orbital (HOMO) and the lowest unoccupied molecular orbital (LUMO) was 3.1 eV.
[0090]
The simplified molecular formula of NPB is C ₄₄ H ₃₂ N ₂ The molar mass is 588.75 g / mol, the melting point is 277 ° C., the glass transition temperature is 96 ° C., the ionization potential is 5.4 eV, and the energy gap between HOMO and LUMO is 3.1 eV. Met.
[0091]
The simplified molecular formula of BCP is C ₂₆ H ₂₀ N ₂ The molar mass was 360.45 g / mol, the melting point was 279-283 ° C., the ionization potential was 6.7 eV, and the energy gap between HOMO and LUMO was 3.5 eV. Since the ionization potential of BCP is large, it is difficult for holes to be injected into the BCP layer, and it is considered that it functions as a hole blocking layer.
[0092]
The simplified molecular formula of Alq is C ₂₇ H ₁₈ N _Three O _Three Al, having a molar mass of 459.4318 g / mol, no melting point, a thermal decomposition temperature of 412 ° C., a glass transition temperature of 175 ° C., an ionization potential of 5.7 eV, HOMO and LUMO, The energy gap between was 2.7 eV.
[0093]
When a direct current voltage was applied to the light emitting element and the current was applied, the luminance was 100 cd / m. ² Blue light emission was obtained, and the current light emission efficiency at this time was 3.1 cd / A. Since the brightness was roughly proportional to the current density, it was confirmed that the brightness was very easy to control.
[0094]
Example 5 Production and Evaluation of Light-Emitting Element
Bis (2- (6-fluorobenzothiophen-2'-yl) pyridinato-N, C synthesized in Example 2 on CBP as a mixture light emitting layer ² ′) A light emitting device was produced in the same manner as in Example 4 except that 10% by mass of acetylacetonatoiridium (III) was mixed. When a direct current voltage was applied to the light emitting element and the current was applied, the luminance was 100 cd / m. ² Red light emission was obtained, and the current luminous efficiency at this time was 3 cd / A. The brightness was roughly proportional to the current density.
[0095]
(Examples 6 to 15 and Comparative Examples 1 to 12) Production and evaluation of light-emitting elements
A light emitting device was produced in the same manner as in Example 4 except that 10 wt% of the organometallic compound shown in Table 1 was mixed with CBP as the mixture light emitting layer. As shown in Table 1, in Examples 6 to 15, organometallic compounds having structures shown in (Chemical Formula 47) to (Chemical Formula 56) were used. Moreover, in Comparative Examples 1-12, the organometallic compound of the structure which does not have the substituent F or CN in the organometallic compound shown to (Chemical Formula 45)-(Chemical Formula 56) is used.
[0096]
The obtained light emitting element was energized by applying a DC voltage, and the luminance was 100 cd / m. ² The light emission color and light emission efficiency in Table 1 are shown in Table 1. Table 1 also shows the results of Examples 4 and 5.
[0097]
[Table 1]
[0098]
(Examples 16 to 38 and Comparative Examples 13 to 17) Production and Evaluation of Light-Emitting Elements
A light emitting device was produced in the same manner as in Example 4 except that CBP was mixed with 10 mass% of the organometallic compounds shown in Tables 2 and 3 as the mixture light emitting layer.
[0099]
In Examples 16 to 38, organometallic compounds represented by M, s, Lb, and t shown in Tables 2 and 3 in the general formulas (23) to (28) were used. In the ligand Lb, acac is an acetylacetonato ligand represented by the formula (29), pic is a picolinato ligand represented by the formula (30), and CO is a carbonyl ligand.
[0100]
In Comparative Examples 13-17, the substituent CF in Examples 17-21 _Three An organometallic compound having no structure was used.
The obtained light emitting element was energized by applying a DC voltage, and the luminance was 100 cd / m. ² Table 2 and Table 3 show the emission color and emission efficiency.
[0101]
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[0102]
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[0103]
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[0104]
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[0105]
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[0106]
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[0107]
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[0108]
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[0109]
[Table 2]
[0110]
[Table 3]
[0111]
【The invention's effect】
According to the present invention, it is possible to obtain an organometallic compound that has good luminous efficiency and can emit red or blue light.
[0112]
Moreover, the light emitting element of this invention can be set as the full color display apparatus etc. with favorable luminous efficiency by containing the said luminescent organometallic compound of this invention in a light emitting layer.

Claims (7)

A luminescent organometallic compound represented by the following chemical formula:
A luminescent organometallic compound represented by the following chemical formula:
A luminescent organometallic compound represented by the following chemical formula:
A luminescent organometallic compound represented by the following chemical formula:
A luminescent organometallic compound represented by the following chemical formula:
A luminescent organometallic compound represented by the following chemical formula:
A luminescent organometallic compound represented by the following chemical formula: