Organic electroluminescent device

Provided is a practical organic electroluminescent (EL) device, of which the luminance is not attenuated in long-term driving. The device has good luminous efficiency and durability. At least one organic compound to be used for forming the organic compound layer of the device has an electron spin number of not more than 10.sup.13 per mg of the compound.

FIELD OF THE INVENTION
 The present invention relates to an organic electroluminescent (EL) device.
 More precisely, it relates to an organic EL device of which the luminance
 is not attenuated in long-term driving and which has good durability.
 BACKGROUND OF THE INVENTION
 As being self-emission, EL devices have high self- distinguishability. In
 addition, they have high impact resistance as being completely solid
 devices. Therefore, the use of EL devices in various displays as light
 source is being widely noticed.
 EL devices are grouped into inorganic EL devices in which are used
 inorganic compounds as light-emitting materials, and organic EL devices in
 which are used light-emitting organic compounds. Of those, organic EL
 devices have been being much studied and expected as practical light
 emitters in the coming generations, since they require a greatly reduced
 driving-voltage and they can be easily small-sized.
 In the circumstances, the most important theme in practical studies of
 organic EL devices is to establish the technique of preventing the
 attenuation of the luminance of the devices in long-term driving and to
 provide practicable organic EL devices.
 In this respect, it is known that the purity of organic compounds to be
 used for producing organic EL devices has a great influence on the
 attenuation of the luminous efficiency and the luminance of the devices
 produced, for example, as in "Monthly DISPLAY, September, p. 15, 1995",
 and "OYOBUTURI, Vol. 66, No. 2, pp. 114-115, 1997". However, the
 influences of the structures and the properties of organic compounds to be
 used for producing organic EL devices on the properties of the devices
 produced are not as yet clarified, and no method is known capable of
 quantitatively determine the influences in question.
 Therefore, the details of the reasons why long-term use of organic EL
 devices brings about the attenuation of the luminance of the devices are
 not as yet known at present.
 SUMMARY OF THE INVENTION
 Given that situation, the object of the invention is to solve the problems
 in the prior art noted above, and to provide a practical organic EL device
 of which the luminance is not attenuated in long-term driving and which
 has good durability.
 We, the present inventors have assiduously studied in order to attain the
 object.
 Through our studies, we measured the number of electron spins existing in
 each organic compound to be used for forming the organic compound layers
 of organic EL devices, and have found that a good correlation was obtained
 between the number of electron spins and the properties of organic EL
 devices. Specifically, of many organic EL devices we produced, those which
 comprised organic compounds having a large number of electron spins
 existing therein were impracticable for long-term driving, as their
 luminance greatly attenuated in practical use.
 The reason is because a large number of electron spins existing in organic
 compound layers of organic EL devices will trap the holes and electrons as
 injected into the layers to thereby probably increase the driving voltage
 for the devices and quench the excited state of the light-emitting
 compounds of the devices.
 On the basis of this knowledge, we have found that, in order to prevent the
 attenuation of the luminance of organic EL devices being driven for a long
 period of time, at least one of organic compounds to be used for forming
 the organic compound layers of each organic EL device must be such that
 the number of electron spins existing therein is not more than 10.sup.13
 per mg of the compound.
 Based on this finding, we have completed the present invention.
 Specifically, the invention provides the following:
 (1) An organic EL device comprising one or more organic compound layers
 that include at least one organic light-emitting layer and are sandwiched
 between a pair of electrodes of anode and cathode, wherein at least one of
 organic compounds used for forming the organic compound layers is such
 that the number of electron spins existing therein is not more than
 10.sup.13 per mg of the compound.
 (2) The organic EL device of (1), wherein the organic compound layers are
 formed through vapor deposition.
 (3) The organic EL device of (1) or (2), wherein the number of electron
 spins existing in the organic compound used for forming the organic
 light-emitting layer is not more than 10.sup.13 per mg of the compound.
 (4) The organic EL device of (1) or (2), wherein the number of electron
 spins existing in the organic compound used for forming the organic
 compound layer for hole injection or transportation is not more than
 10.sup.13 per mg of the compound.
 (5) The organic EL device of (1) or (2), wherein the number of electron
 spins existing in the organic compound used for forming the organic
 compound layer for electron injection or transportation is not more than
 10.sup.13 per mg of the compound.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS CF THE INVENTION
 Now, the invention is described in detail hereinunder.
 The organic EL device of the invention is characterized in that the number
 of electron spins existing in at least one of organic compounds used for
 forming the organic compound layers of the device is not more than
 10.sup.13 per mg of the compound.
 In the organic EL device of the invention, the organic compound layer to be
 between the anode and the cathode includes at least one light-emitting
 layer. The organic compound layer may be composed of light-emitting
 layer(s) only, or may have a multi-layered laminate structure composed of
 light-emitting layer(s), hole injection and transportation layer(s), and
 others.
 In the organic EL device, the light-emitting layer has (1) a function to
 inject holes thereinto from the anode or the hole transportation layer and
 to inject electrons thereinto from the electron injection layer, while it
 is in an electric field, (2) a transportation function to move the
 thus-injected charges (electrons and holes) by the force of the electric
 field, and (3) a light-emitting function to provide the site for
 recombination of those electrons and holes inside the layer so as to emit
 light. The electron injection layer for (1) has a specific function to
 well inject electrons from the cathode into the organic compound layer.
 The type of the light-emitting material for the light-emitting layer is not
 specifically defined, and any and every light-emitting material known in
 the field of organic EL devices is usable for the layer.
 The hole injection and transportation layer comprises a hole-transmitting
 compound, and has a function to transmit the holes having been injected
 thereinto from the anode, to the light-emitting layer. The hole injection
 and transportation layer is put between the anode and the light-emitting
 layer so that many holes are injected into the light-emitting layer in a
 lower electric field. In this structure, an electron barrier is formed in
 the interface between the light-emitting layer and the hole injection and
 transportation layer, and it assists the electrons having been injected
 from the electron injection layer into the light-emitting layer to
 accumulate inside the light-emitting layer around the interface, to
 thereby improve the luminous efficiency of the EL device. Accordingly, the
 EL device having this structure shall have excellent light-emitting
 capabilities. The hole transmitting compound to be used for forming the
 hole injection and transportation layer is not specifically defined, and
 any and every hole-transmitting compound known in the field of organic EL
 devices is usable for the layer. The hole injection and transportation
 layer is not limited to a single-layered one but may be a multi-layered
 one. Apart from those noted above, minor additives of organic compounds
 may be added to any of these layers.
 The minor additives are of so-called dopants, which are to improve the
 charge injectability into the layers constituting organic EL devices or
 are light-emitting species by themselves to improve the properties of
 organic EL devices.
 At least one of organic compounds to be used for forming the organic
 compound layers of the organic EL device of the invention shall be such
 that the number of electron spins existing therein is not more than
 10.sup.13 per mg of the compound, which generally means that the organic
 compound to form at least one organic compound layer of the device or the
 dopant to be added to the organic light-emitting layer (s) and others of
 the device is such that the number of electron spins existing therein is
 not more than 10.sup.13 per mg of the compound or the dopant.
 To measure the number of electron spins existing in the organic compound
 that is to form the organic compound layer of the device, employed is an
 electron spin resonance (ESR) measurement.
 This method is described below.
 First, the weight of an empty sample tube made of quartz is weighed. Next,
 a suitable amount of an organic compound to be used for forming the
 organic compound layer of the device is put into the tube, which is then
 weighed. By subtracting the former from the latter, obtained is the weight
 of the organic compound for forming the organic compound layer. This is
 referred to as .chi. mg.
 Using a commercially-available ESR measurement apparatus, the compound in
 the sample tube is subjected to ESR measurement to obtain its ESR signal
 pattern, from which is obtained the area of ESR. This is designated by E.
 Next, a standard sample of which the electron spin number is known (for
 example, 1,1-diphenyl-2-picrylhydrazyl, DPPH) is measured in the same
 manner as previously, and the area of ESR is obtained from its ESR signal
 pattern. The electron spin number and the ESR area of the standard sample
 are designated by ns and Es, respectively.
 The electron spin number, n, of the organic compound is obtained according
 to the following equations:
EQU n:E=n.sub.s :E.sub.s (1)
EQU n=E/E.sub.s.times.n.sub.s (2)
 Accordingly, the electron spin number, .alpha., per mg of the organic
 compound is represented by the following equation:
 ##EQU1##
 The details of the origin of the electron spins as to from what substances
 the electron spins are derived to be in organic compounds are not clear at
 present, but it is believed that the electron spins will be derived from
 the radical of the organic compound itself or from the ion species or
 radical species of solvents and impurities that may contaminate the
 organic compound.
 Such ion species or radical species, if any, in the organic compound layers
 of organic EL devices will be the factors to cause charge trapping in the
 layers or inactivation of the excited layers, resulting in that the
 driving voltage for the devices is increased and the light-emitting
 capability of the devices is canceled.
 In general, it is well known that purification by sublimation is one
 effective method for purifying the materials for organic EL devices. In
 this connection, we have found that the purification by sublimation is
 especially effective for decreasing the number of electron spins in those
 materials.
 Accordingly, it is expected that the number of electron spins to be in
 organic EL devices that comprise organic compound layers as formed through
 vapor deposition of organic compounds under reduced pressure will be
 somewhat lower than that of electron spins to be in the organic compounds
 that are in vaporization boats.
 On that presumption, if organic compounds to be vaporized for forming the
 organic compound layers of organic EL devices contain a large number of
 electron spins, some of such many electron spins will still remain in the
 devices produced, thereby to worsen the capabilities of the devices.
 Accordingly, in producing organic EL devices, it is extremely effective to
 reduce the number of electron spins to be in the organic compounds of the
 vaporization source through purification by sublimation and to use the
 thus-purified organic compounds for forming the organic compound layers of
 the devices through vapor deposition, thereby to prevent the deterioration
 of the capabilities of the devices produced.
 In order to prevent the attenuation of the luminance of organic EL devices
 according to this extremely effective method, it is important to use at
 least one organic compound of which the value a noted above is not more
 than 10.sup.13. In particular, it is important that the value .alpha. of
 the organic compounds to be used for forming the light-emitting layers of
 the devices is not more than 10.sup.13.
 Apart from the sublimation method noted above, other various methods are
 known for purifying organic compounds to be used for producing organic EL
 devices. For example, known are methods of recrystallization,
 reprecipitation, zone melting, column purification, adsorption, etc.
 However, in any of those conventional purification methods, the
 purification limit is at most such that the electron spin number per mg of
 the purified organic compound, .alpha., falls between 10.sup.13 and
 10.sup.15. The degree of purification on such a level could not
 satisfactorily attain the object of the invention.
 Therefore, in order to maintaain the condition of .alpha..ltoreq.10.sup.13
 /mg, which is required by the invention, by reducing the number of
 electron spins to be in organic compounds that are used for vaporization
 sources, it is necessary to combine some of the conventional purification
 methods for purifying the organic compounds.
 One preferred embodiment of the combination of the conventional
 purification methods comprises the following [1], [2] and [3], by which
 the number of electron spins to be in organic compounds of vaporization
 sources may be more effectively reduced.
 [1] The compound is sublimed at a temperature lower by at least 30.degree.
 C. than its pyrolyzing point.
 [2] The initial sublimate is cut off at a temperature falling a temperature
 range lower by 20 to 50.degree. C. than the sublimation point of the
 compound.
 [3] The vacuum degree for the sublimation falls between 10.sup.-8 and
 10.sup.-2 Torr, but preferably between 10.sup.-8 and 10.sup.-5 Torr.
 In actual purification, suitable methods are selected depending on the
 properties of the organic compounds to be purified, but are not
 specifically defined so far as they maintain the condition of
 .alpha..ltoreq.10.sup.13 /mg.
 Now, the invention is described in more detail with reference to the
 following Examples, which, however, are not intended to restrict the scope
 of the invention.
 PRODUCTION EXAMPLE 1
 Production of Luminous Material:
 This is to demonstrate the production of a luminous material,
 4,4"-bis(2,2-diphenylvinyl-1-yl)-p-tert-phenylene (DPVTP).
 The compound has a structure of the following chemical formula:
 ##STR1##
 In a 100-ml three-neck flask charged with argon, 1.0 g of benzophenone and
 1.2 g of a phosphate, of which the structure is shown below, were
 suspended in 30 ml of dimethylsulfoxide that had been dried through a
 molecular sieve.
 ##STR2##
 The resulting suspension was reacted with 0.5 g of potassium t-butoxide
 added thereto, at room temperature, whereupon the reaction product formed
 immediately colored in reddish brown in the suspension. Next, this was
 stirred for about 1 hour at 27.degree. C., and the reaction product then
 colored in yellow therein. This was further stirred for 2 hours, to which
 was added 40 ml of methanol, and the yellow precipitate was taken out
 through filtration.
 Next, the yellow precipitate was suspended in 100 ml of toluene, and
 subjected to hot extraction. Toluene was evaporated from the resulting
 extract to obtain a white powder. This was purified by sublimation at a
 boat temperature of 320.degree. C. in a vacuum of 10.sup.-2 Torr to obtain
 0.45 g of a pure powder. This is referred to as DPVTP-1.
 This was again purified by sublimation at a boat temperature of 320.degree.
 C. in a vacuum of 10.sup.-5 Torr to obtain 0.38 g of a further purified
 powder. This is referred to as DPVTP-2.
 PRODUCTION EXAMPLE 2
 Production of Hole-Injecting Material:
 This is to demonstrate the production of a hole-injecting material,
 4,4',4"-tris-[N-(m-tolyl)-N-phenylamino]triphenylamine (MTDATA).
 The compound has a structure of the following chemical formula:
 ##STR3##
 1.0 g of 4,4',4"-triiodo-triphenylamine, 1.0 g of N-(3-tolyl)-N-phenylamine
 (by Aldrich), 3 g of potassium carbonate anhydride, and 1.0 g of copper
 powder were put into a 300-ml three-neck flask, dissolved in 200 ml of
 dimethylsulfoxide, and reacted by stirring them at 20.degree. C. for 8
 hours.
 After the reaction, the reaction mixture was filtered, and the mother
 filtrate was extracted with methylene chloride. The solvent was evaporated
 in a rotary evaporator, and the residue was purified through a
 chromatography column charged with silica gel (by Hiroshima Wako Pure
 Chemicals), for which toluene was used as the developer, to obtain 0.3 g
 of a pale yellow powder. This is referred to as MTDATA-1.
 This was purified by subliming it three times at a boat temperature of
 390.degree. C. and in a vacuum of 10.sup.-5 Torr, to obtain 0.24 g of a
 pale yellow powder. This is referred to as MTDATA-2.
 PRODUCTION EXAMPLE 3
 Production of Hole-Transporting Material:
 This is to demonstrate the production of a hole-transporting material,
 N,N'-di-(naphthyl-1-yl)-N,N'-diphenyl-4,4"-benzidine (NPD).
 The compound has a structure of the following chemical formula:
 ##STR4##
 In the same manner of reaction and purification as in Production Example 2,
 except that 2.0 g of 1-iodonaphthalene (by Tokyo Chemical) was used in
 place of 4,4',4"-triiodo-triphenylamine and that 1.0 g of
 N,N'-diphenylbenzidine (by Hiroshima Wako Pure Chemicals) was used in
 place of N-(3-tolyl)-N-phenylamine (by Aldrich), 0.37 g of a pale yellow
 powder was obtained. This is referred to as NPD-1.
 This was purified by subliming it two times at a boat temperature of
 320.degree. C. and in a vacuum of 10.sup.-5 Torr to obtain 0.31 g of a
 pale yellow powder. This is referred to as NPD-2.
 PRODUCTION EXAMPLE 4
 Production of Dopant:
 This is to demonstrate the production of a dopant,
 4,4'-bis-[2-[4-(N,N-diphenylamino)phenyl-1-yl]-vinyl-1-yl]-1,1'-biphenyl
 (DPAVBi).
 The compound has a structure of the following chemical formula:
 ##STR5##
 1.9 g of the same sulfonate as that used in Production Example 1, and 3.0 g
 of N,N-diphenyl-4-aminobenzaldehyde were put into a 200-ml three-neck
 flask, and dissolved in 50 ml of dimethylsulfoxide that had been dried
 through a molecular sieve. While this was stirred with a magnetic stirrer
 at room temperature in an argon gas atmosphere, 1.0 g of powdery potassium
 t-butoxide (by Kanto Chemical) was added thereto little by little. The
 reaction mixture immediately became reddish black, and then faded for a
 while to be greenish yellow. Finally, it gave an ocher precipitate.
 After the reaction, the reaction mixture was stirred for further 3 hours
 still at room temperature. Next, this was allowed to stand at room
 temperature overnight, then 50 ml of aqueous 80 wt. % methanol was added
 thereto, and the yellow precipitate thus formed was taken out through
 filtration. This was washed two times with 50 ml of aqueous 80 wt. %
 methanol, and then two times with 50 ml of methanol. This was dried in
 vacuum at 50.degree. C. for 3 hours to obtain 2.8 g of an yellow powder.
 Next, the thus-obtained yellow powder was developed through a column of
 chromatography as charged with 140 g of silica gel (BW-820MH, trade name
 of Fuji DavisonChemical) along with toluene, using toluene as the
 developer, from which was collected the first developed fraction. In this
 thin-layer chromatography (developer of toluene/n-hexane=2/1, V/V, thin
 layer of silica gel), the rate of flow, Rf was 0.8.
 Next, the fractions containing the intended product were collected, and the
 solvent was evaporated with an evaporator to give a dry solid powder. The
 thus-obtained yellow powder was dissolved in 60 ml of hot toluene, and the
 insoluble was removed by filtration through a membrane filter (by
 Advantec, 1 .mu.m, 25 .mu.mm).
 This toluene solution was allowed to stand at room temperature, and the
 precipitate formed was taken out through filtration, and dried at
 50.degree. C. for 2 hours to obtain 2.3 g of an yellow powder. This is
 referred to as DPAVBi-1.
 This was again dissolved in 50 ml of hot toluene, and recrystallized three
 times. As a result, obtained was 1.6 g of an yellow powder. This is
 referred to as DPAVBi-2.
 PRODUCTION EXAMPLE 5
 Production of Electron-Transporting Material:
 As the electron-transporting material, used herein was a Dojin Chemical's
 commercial product, aluminium-tris(8-hydroxyquinolinol) (Alq).
 This has a structure of the following chemical formula:
 ##STR6##
 1.0 g of Dojin Chemical's Alq (this is referred to as Alq-1) was purified
 by subliming it two times at a boat temperature of 300.degree. C. and in a
 vacuum of 10.sup.-5 Torr to obtain 0.7 g of an yellow powder. This is
 referred to as Alq-2.
 Measurement of Electron Spin Number .alpha.
 The organic compounds produced in Production Examples 1 to 5 were subjected
 to ESR measurement.
 First, the organic compounds were dried in a desiccator for 24 hours, and a
 suitable amount of each was put into an ESR sample tube of quartz (inner
 diameter: 4.0 mm), and subjected to ESR measurement at an atmospheric
 pressure.
 Next, a standard sample, DPPH having an electron spin number of
 6.9.times.10.sup.15 /mg was put into a sample tube of the same material
 and the same size as that used for the organic compounds, and subjected to
 ESR measurement under the same condition as that for the organic
 compounds.
 The ESR apparatus used herein is one manufactured by JEOL (Model JES-FE3XG:
 X-band, wavelength 3 cm).
 The condition for the ESR measurement is mentioned below.
 As the cavity, used was a TE.sub.011, cylindrical mode. The microwave
 output was 1.00 mW; the modulation pulse was 4.00 G;
 and the degree of amplification was 1.times.10.sup.3 In order to evade the
 influence of temperature charge on the sample being measured, city water
 was applied to the outer jacket of the cavity by which the cavity was kept
 at the temperature of water, while the inside of the cavity was kept at a
 constant temperature by introducing dry nitrogen gas thereinto.
 The spectra of the standard sample and the organic compounds thus measured
 were recorded as differential data, and the data were integrated to obtain
 the ESR intensity of each compound. From the integrated data, obtained was
 the electron spin number, .alpha., of each organic compound, according to
 the numerical equations (2) and (3) noted above. The results are in Table
 1 below.
 TABLE 1
 Sample Electron Spin Number (/mg)
 DPVTP-1 2.4 .times. 10.sup.13
 DPVTP-2 7.5 .times. 10.sup.12
 DPAVBi-1 2.O .times. 10.sup.13
 DPAVBi-2 7.4 .times. 10.sup.11
 MTDATA-1 4.9 .times. 10.sup.13
 MTDATA-2 1.3 .times. 10.sup.12
 NPD-1 3.7 .times. 10.sup.13
 NPD-2 8.6 .times. 10.sup.12
 Alq-1 3.4 .times. 10.sup.13
 Alq-2 8.8 .times. 10.sup.12
 EXAMPLE 1
 A film of indium-tin-oxide (In--Ti--O film--hereinafter referred to as ITO
 film) having a thickness of 100 nm (this corresponds to anode) was formed
 on a glass sheet (25 mm.times.75 mm.times.1.1 mm) through vapor deposition
 to prepare a transparent substrate. This transparent substrate was
 ultrasonically washed first with isopropyl alcohol for 5 minutes and then
 with water for 5 minutes, and thereafter further washed in a UV ion washer
 (by Samco International) at a substrate temperature of 150.degree. C. for
 20 minutes.
 This was dried with dry nitrogen gas, and then fixed on a substrate holder
 in a commercially--available vapor deposition apparatus (by ULVAC Japan).
 This vapor deposition apparatus was equipped with a plurality of
 independent resistance-heating boats of molybdenum, into which were put
 vaporizing organic compounds. Precisely, 200 mg of MTDATA-1, 200 mg of
 NPD-1, 200 mg of DPVTP-2, 200 mg of DPAVBi-1 and 200 mg of Alq-1 were
 separately put into those boats.
 After the vaporizing organic compounds were thus separately put on those
 resistance-heating boats, the vacuum chamber of the apparatus was degassed
 to have a vacuum degree of 4.times.10.sup.-6 Torr, and the boat with
 MTDATA-1 being put therein was electrically heated up to 360.degree. C. so
 that the compound in the boat was vaporized and deposited onto the
 transparent substrate at a deposition rate of from 0.1 to 0.3 nm/sec to
 form a layer of MTDATA-1 having a thickness of 60 nm.
 Next, the boat with NPD--1 being put therein was electrically heated up to
 260.degree. C. so that the compound in the boat was vaporized and
 deposited over the MTDATA-1 layer at a deposition rate of from 0.1 to 0.3
 nm/sec to form a layer of NPD-1 having a thickness of 20 nm.
 Next, the boat with DPVTP-2 being put therein and the boat with DPAVBi-1
 being put therein were electrically heated at the same time to form a
 light-emitting layer of DPVTP-2 and DPAVBi-1 having a thickness of 40 nm.
 The deposition rate of DPVTP-2 was from 2.8 to 3.0 nm/sec, and that of
 DPAVBi-1 was from 0.1 to 0.13 nm/sec.
 Next, the boat with Alq-1 being put therein was electrically heated so that
 the compound was vaporized and deposited over the light-emitting layer at
 a deposition rate of from 0.1 to 0.3 nm/sec to form a layer of Alq-1
 having a thickness of 20 nm.
 Next, the thus-layered substrate was taken out of the vacuum chamber, and a
 stainless steel mask was positioned on the electron injection layer, and
 this substrate was again fixed on the substrate holder. Next, a
 cathode-forming, vaporizing material of an aluminium-lithium (Al--Li)
 alloy having a lithium content of 5 atomic % was vaporized and deposited
 over the substrate at a deposition rate of from 0.5 to 1.0 nm/sec to form
 a cathode having a thickness of 150 nm. During the deposition, the vacuum
 chamber was controlled to have a vacuum degree of 1.times.10.sup.-6 Torr.
 A direct current of 6 V was applied to the thus-produced, organic EL
 device, between the ITO electrode (anode) and the Al--Li alloy electrode
 (cathode) of the device, whereupon the device emitted uniform blue light.
 The half-life time of the organic EL device (the time within which the
 initial luminance, 300 cd/m.sup.2, of the device was attenuated to 150
 cd/m.sup.2) was measured by driving the device at a constant current ina
 nitrogen atmosphere. The half-life time of the device thus measured is
 shown in Table 2.
 EXAMPLE 2
 An organic EL device was produced in the same manner as in Example 1,
 except that DPVTP-2 was replaced with DPVTP-1 and that MTDATA-1 was
 replaced with MTDATA-2.
 A direct current of 6 V was applied to this organic EL device, between the
 ITO electrode (anode) and the Al--Li alloy electrode (cathode) of the
 device, whereupon the device emitted uniform blue light. The half-life
 time of the device is shown in Table 2.
 EXAMPLE 3
 An organic EL device was produced in the same manner as in Example 1,
 except that DPVTP-2 was replaced with DPVTP-1 and that NPD-1 was replaced
 with NPD-2.
 A direct current of 6 V was applied to this organic EL device, between the
 ITO electrode (anode) and the Al--Li alloy electrode (cathode) of the
 device, whereupon the device emitted uniform blue light. The half-life
 time of the device is shown in Table 2.
 EXAMPLE 4
 An organic EL device was produced in the same manner as in Example 1,
 except that DPVTP-2 was replaced with DPVTP-1 and that DPAVBi-1 was
 replaced with DPAVBi-2.
 A direct current of 6 V was applied to this organic EL device, between the
 ITO electrode (anode) and the Al--Li alloy electrode (cathode) of the
 device, whereupon the device emitted uniform blue light. The half-life
 time of the device is shown in Table 2.
 EXAMPLE 5
 An organic EL device was produced in the same manner as in Example 1,
 except that DPVTP-2 was replaced with DPVTP-1 and that Alq-1 was replaced
 with Alq-2.
 A direct current of 6 V was applied to this organic EL device, between the
 ITO electrode (anode) and the Al--Li alloy electrode (cathode) of the
 device, whereupon the device emitted uniform blue light. The half-life
 time of the device is shown in Table 2.
 EXAMPLE 6
 An organic EL device was produced in the same manner as in Example 1,
 except that MTDATA-1 was replaced with MTDATA-2, that NPD-1 was replaced
 with NPD-2, that DPAVBi-1 was replaced with DPAVBi-2 and that Alq-1 was
 replaced with Alq-2.
 A direct current of 6V was applied to this organic EL device, between the
 ITO electrode (anode) and the Al--Li alloy electrode (cathode) of the
 device, whereupon the device emitted uniform blue light. The half-life
 time of the device is shown in Table 2.
 COMATIVE EXAMPLE 1
 An organic EL device was produced in the same manner as in Example 1,
 except that DPVTP-2 was replaced with DPVTP-1.
 A direct current of 6 V was applied to this organic EL device, between the
 ITO electrode (anode) and the Al--Li alloy electrode (cathode) of the
 device, whereupon the device emitted uniform blue light. The half-life
 time of the device is shown in Table 2.
 TABLE 2
 Hole- Hole- Light-
 Electron- Half-life
 injecting transporting emitting
 transporting time
 No. Material Material Material Dopant
 Material (hrs)
 Example 1 MTDATA-1 NPD-1 DPVTP-2 DPAVBi-1 Alq-1
 5,200
 Example 2 MTDATA-2 NPD-1 DPVTP-1 DPAVBi-1 Alq-1
 4,700
 Example 3 MTDATA-1 NPD-2 DPVTP-1 DPAVBi-1 Alq-1
 4,900
 Example 4 MTDATA-1 NPD-1 DPVTP-1 DPAVBi-2 Alq-1
 4,200
 Example 5 MTDATA-1 NPD-1 DPVTP-1 DPAVBi-1 Alq-2
 4,600
 Example 6 MTDATA-2 NPD-2 DPVTP-2 DPAVBi-2 Alq-2
 6,000
 Comp. MTDATA-1 NPD-1 DPVTP-1 DPAVBi-1 Alq-1
 1,800
 Example 1
 From the data of Examples 1 to 6 in Table 2, it is known that the half-life
 time of the organic EL devices comprising any one of the organic compounds
 having an electron spin number, .alpha., of not more than 10.sup.13 is
 longer by more than 2 times than that of the organic EL device of
 Comparative Example 1 not comprising it.
 In addition, it is further known that the half-life time of the organic EL
 device, of which all layers are of the organic compounds having an
 electron spin number, .alpha., of not more than 10.sup.13, is much longer
 than that of any others.
 As has been described in detail hereinabove, the organic EL device of the
 invention is produced through vapor deposition, for which are used organic
 compounds having an electron spin number of not more than a defined limit,
 and its luminous efficiency is kept good during long-term driving, and the
 half-life time of the device is much prolonged. In addition, the
 durability of the device is good. Accordingly, the organic EL device of
 the invention is favorably used, for example, in displays in information
 appliances.
 While the invention has been described in detail and with reference to
 specific embodiments thereof, it will be apparent to one skilled in the
 art that various changes and modifications can be made therein without
 departing from the spirit and scope thereof.