Organic electroluminescence element

TECHNICAL FIELD

The present invention relates to an organic electroluminescent device constructed by forming at least an emitting layer using an organic material between a hole injection electrode and an electron injection electrode, and is characterized in that stable luminance can be obtained for a long time, and high luminance can be obtained at a low voltage particularly in an organic electroluminescent device having an emitting layer constructed by doping a dopant into a host material.

BACKGROUND ART

In recent years, the needs of flat panel display devices the consumption of electric power and the size of which are smaller than those of a CRT (cathode-ray Tube) which has been heretofore generally employed have been increased as information equipments are diversified, for example. An electroluminescent device has been paid attention to as one of the flat panel display devices.

The electroluminescent device is roughly divided into an inorganic electroluminescent device and an organic electroluminescent device depending on a used material.

The inorganic electroluminescent device is so adapted that a high electric field is generally applied on a luminance portion, and electrons are accelerated within the high electric field to collide with a luminescence center, whereby the luminescence center is excited to emit light. On the other hand, the organic electroluminescent device is so adapted that electrons and holes are respectively injected into a luminescent portion from an electron injection electrode and a hole injection electrode, the electrons and the holes thus injected are recombined with each other in a luminescence center to bring an organic molecule into its excited state, and the organic molecule emits fluorescence when it is returned from the excited state to its ground state.

In the case of the inorganic electroluminescent device, a high voltage of 100 to 200 volts is required as its driving voltage because the high electric field is applied as described above. On the other hand, the organic electroluminescent derive can be driven at a low voltage of approximately 5 to 20 volts.

In the case of the organic electroluminescent device, a luminescent device emitting light in a suitable color can be obtained by selecting a fluorescent material that is a luminescent material. It is expected that the organic electroluminescent device can be also utilized as a multi-color or full-color display device, for example. Further, it is considered that the organic electroluminescent device is utilized as a back light of a liquid crystal display device or the like because it can emit light at a low voltage.

In recent years, various studies have been conducted on such an organic electroluminescent device.

In such an organic electroluminescent device, an emitting layer and a carrier transport layer which is constituted by a hole transport layer for transporting holes to the emitting layer and an electron transport layer for transporting electrons thereto are generally provided between a hole injection electrode and an electron injection electrode. Specifically, used as the structure thereof are a three-layer structure referred to as a DH structure obtained by laminating a hole transport layer, an emitting layer and an electron transport layer between a hole injection electrode and an electron injection electrode, a two-layer structure referred to as an SH-A structure obtained by laminating a hole transport layer and an emitting layer abundant in electron transport properties between a hole injection electrode and an electron injection electrode, and a two-layer structure referred to as an SH-B structure obtained by laminating an emitting layer abundant in hole transporting properties and an electron transport layer between a hole injection electrode and an electron injection electrode.

In a conventional organic electroluminescent device, however, it is generally difficult to obtain as an organic material used for its emitting layer high-purity one by sublimation and purification, for example, and the stability of the organic material to heat or the like is not sufficient. When the organic electroluminescent device emits light for a long time, therefore, some problems occur. For example, the organic material used for the emitting layer is crystallized to form pinholes due to heat or the like at the time of the light emission, so that uniform and sufficient luminance cannot be obtained for a long time.

In recent years, in order to increase luminous efficiency in the emitting layer in the organic electroluminescent device, a dopant having a high quantum efficiency of fluorescent has been doped into a host material constituting the emitting layer.

In thus doping the dopant into the host material constituting the emitting layer, however, there are some problems. For example, unless a combination of the host material and the dopant is suitably selected, sufficient luminance cannot be obtained.

An object of the present invention is to solve the above-mentioned problems in an organic electroluminescent device constructed by forming at least an emitting layer using an organic material between a hole injection electrode and an electron injection electrode.

That is, an object of the present invention is to make it possible to obtain stable luminance for a long time by preventing pinholes from being formed by crystallization of an organic material used for an emitting layer due to heat or the like at the time of emitting light as in the conventional example.

Another object of the present invention is to make it possible to obtain, in an organic electroluminescent device having an emitting layer obtained by doping a dopant into a host material, high luminance by sufficient light emission of a dopant doped into the host material in the emitting layer.

DISCLOSURE OF INVENTION

The present invention is so adapted, in an organic electroluminescent device constructed by providing at least an emitting layer using an organic material between a hole injection electrode and an electron injection electrode, that a dopant selected from coronene, rubicene, pyrene, benzpyrene, chrysene, ovalene, fluorocyclene, picene, triphenylene, aceanthrene, fluoranthene, acenaphthene, acenaphthylene, benzanthracene, naphthafluorene, naphthafluorenone, naphthapyrene, anthraquinone, rubrene peroxide, pentacene quinone, perylene quinone, naphthacene quinone, benzofluorenone, benzofluorene, anthrafluorene, benzperylene, benzpentacene, bispyrenyl propane, tetramethyl naphthacene, dibenzanthracene, pyrene quinone, perylene, and fluoracene, or their derivatives is used, and the difference between the highest occupied molecular orbital in the host material and the highest occupied molecular orbital in the dopant is in a range from −0.3 eV to +0.3 eV.

When the above-mentioned dopant is thus doped into the host material, molphology in air is hardly changed, so that the film stability of the emitting layer is improved, and the organic material used for the emitting layer is prevented from being crystallized due to heat or the like at the time of emitting light. Therefore, stable luminance is obtained for a long time.

When the difference between the highest occupied molecular orbital in the host material and the highest occupied molecular orbital in the dopant is set in a range from −0.3 eV to +0.3 eV, excitation energy is efficiently moved from the host material to the dopant. Therefore, luminous efficiency in the organic electroluminescent device is improved, so that high luminance is obtained. Particularly when the difference between the highest occupied molecular orbital in the host material and the highest occupied molecular orbital in the dopant is in a range from −0.1 eV to +0.1 eV, the excitation energy is more efficiently moved from the host material to the dopant. Therefore, the luminous efficiency is further improved, so that higher luminance is obtained.

The above-mentioned dopant is low in molecular polarity, is easily sublimated, and has high heat resistance. Therefore, a high-purity dopant is easily obtained by sublimation and purification. When the high-purity dopant which is thus obtained by the sublimation and purification is doped into the emitting layer, uniform and higher luminance is obtained for a long time.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1

is a schematic explanatory view of an organic electroluminescent device having an SH-A structure obtained by laminating a hole transport layer and an emitting layer between a hole injection electrode and an electron injection electrode;

FIG. 2

is a schematic explanatory view of an organic electroluminescent device having an SH-B structure obtained by laminating an emitting layer and an electron transport layer between a hole injection electrode and an electron injection electrode;

FIG. 3

is a schematic explanatory view of an organic electroluminescent device having a DH structure obtained by laminating a hole transport layer, an emitting layer and an electron transport layer between a hole injection electrode and an electron injection electrode;

FIG. 4

is a schematic explanatory view showing structures of organic electroluminescent devices in examples 1 to 31 and comparative examples 1 to 8; and

FIG. 5

is a schematic explanatory view showing structures of organic electroluminescent devices in examples 32 to 35 and comparative examples 9 and 10.

BEST MODE FOR CARRYING OUT THE INVENTION

Description is now made of an organic electroluminescent device according to an embodiment of the present invention on the basis of the accompanying drawings.

The organic electroluminescent device according to the embodiment of the present invention may have any one of known structures such as an SH-A structure obtained by laminating a hole transport layer

3

and an emitting layer

4

between a hole injection electrode

2

and an electron injection electrode

6

which are formed on a transparent substrate

1

such as a glass substrate, as shown in

FIG. 1

, an SH-B structure obtained by laminating an emitting layer

4

and an electron transport layer

5

between the hole injection electrode

2

and the electron injection electrode

6

, as shown in

FIG. 2

, and a DH structure obtained by laminating a hole transport layer

3

, an emitting layer

4

and an electron transport layer

5

between the hole injection electrode

2

and the electron injection electrode

6

, as shown in FIG.

3

.

In the organic electroluminescent device according to the present embodiment, a dopant having a condensed ring obtained by condensing three or more rings is doped into a host material in the emitting layer

4

, and the difference between the highest occupied molecular orbital (hereinafter referred to as HOMO) in the host material and the highest occupied molecular orbital (HOMO) in the dopant is set in a range from −0.3 eV to +0.3 eV.

In the above-mentioned organic electroluminescent device, a material having a large work function, for example, gold or an indium-tin oxide (hereinafter referred to as ITO) is used for the hole injection electrode

2

, while an electrode material having a small work function, for example, a material including a magnesium alloy, an alkali metal or an alkali earth metal is used for the electron injection electrode

6

. At least one of the electrodes must be made transparent in order to take out light emitted in the emitting layer

4

. Generally, ITO which is transparent and has a large work function is used for the hole injection electrode

2

.

Examples will be given to specifically describe the organic electroluminescent device according to the present invention, and comparative examples will be given to clarify that in the organic electroluminescent device according to the embodiment of the present invention, high luminance is obtained, and stable luminance can be obtained for a long time.

EXAMPLE 1

In an organic electroluminescent device in an example 1, a transparent hole injection electrode

2

having a thickness of 2000 Å was formed using the above-mentioned ITO on a glass substrate

1

, and a first hole transport layer

3

a

having a thickness of 600 Å using a triphenylamine derivative (hereinafter referred to as MTDATA) indicated by the following chemical formula 1, a second hole transport layer

3

b

having a thickness of 200 Å using NPD indicated by the following chemical formula 2, an emitting layer

4

having a thickness of 500 Å obtained by doping 2% by weight of coronene having a melting point of 438° C. indicated by the following chemical formula 4 as a dopant into a host material composed of a chelate compound Zn(OXZ)

2

indicated by the following chemical formula 3, and an electron injection electrode

6

having a thickness of 2000 Å using a magnesium-indium alloy were laminated on the hole injection electrode

2

, as shown in FIG.

4

.

An example if coronene indicated by the foregoing chemical formula 4 to be contained as a dopant in the emitting layer

4

was one having purity of 99% obtained by sublimating and purifying commercially available coronene (produced by Tokyo Kasei Kogyo Co., Ltd.) for 12 hours using a vacumm heating type sublimating and purifying apparatus. The yield of the coronene which was thus sublimated and purified was 60%.

A method of fabricating the organic electroluminescent device in the example 1 will be specifically described. The glass substrate

1

having the hole injection electrode

2

composed of ITO formed on its surface was cleaned by a neutral detergent, was ultrasonically cleaned in extrapure water, acetone, and ethanol, respectively, for 20 minutes, 20 minutes, and 20 minutes, was further put in boiling ethanol for about one minute and taken out, and was then immediately dried by ventilation, after which the surface of the glass substrate

1

was cleaned for ten minutes using a UV-ozone cleaner.

The above-mentioned MTDATA was vacuum evaporated over the hole injection electrode

2

formed on the glass substrate

1

, to form the first hole transport layer

3

a,

and the above-mentioned NPD was then vacuum evaporated, to form the second hole transport layer

3

b.

The above-mentioned Zn(OXZ)

2

and coronene were co-evaporated over the second hole transport layer

3

b,

to form the emitting layer

4

, and a magnesium-indium alloy was further vacuum evaporated over the emitting layer

4

, to form the electron injection electrode

6

. In any case, the vacuum evaporation was performed at a degree of vacuum of 1×10

−6

Torr.

Comparative Example 1

An organic electroluminescent device in a comparative example 1 was obtained in the same manner as that in the above-mentioned example 1 except that only the emitting layer

4

in the organic electroluminescent device in the example 1 was changed, and only the above-mentioned Zn(OXZ)

2

which is the host material was used, to form an emitting layer

4

.

Comparative Example 2

An organic electroluminescent device in a comparative example 2 was also obtained in the same manner as that in the above-mentioned example 1 except that only the emitting layer

4

in the organic electroluminescent device in the example 1 was changed, and 2% by weight of coumarin 4 having a melting point of 70° C. indicated by the following chemical formula 5 was doped into the above-mentioned Zn(OXZ)

2

which is the host material, to form an emitting layer

4

.

In each of the organic electroluminescent devices in the example 1 and the comparative examples 1 and 2, the HOMOs in the host material and the dopant which were used in the emitting layer

4

were shown in the following Table 1.

A positive voltage and a negative voltage were respectively applied to the hole injection electrode

2

and the electron injection electrode

6

in each of the organic electroluminescent devices in the example 1 and the comparative examples 1 and 2, to find the highest luminance obtained in the organic electroluminescent device and the applied voltage at that time, and each of the organic electroluminescent devices was caused to emit light having luminance of 100 cd/m

2

, to find a time period elapsed until the luminance is reduced by half. The results were shown in the following Table 1.

TABLE 1

reduc-

type of

tion

host

type of

highest

applied

-by-half

material

dopant

luminance

voltage

time

HOMO(eV)

HOMO(eV)

(cd/m

2

)

(V)

(hour)

example 1

Zn(OXZ)

2

chemical

5500

12

300

−5.6

formula 4

−5.6

comparative

Zn(OXZ)

2

none

4600

14

5

example 1

−5.6

comparative

Zn(OXZ)

2

chemical

1200

14

5

example 2

−5.6

formula 5

−6.0

As a result, in the organic electroluminescent device in the example 1 in which the dopant having a condensed ring obtained by condensing three or more rings was used, and the difference in the HOMO between the host material and the dopant was in a range from −0.3 eV to +0.3 eV, higher luminance was obtained at a lower voltage, and a time period elapsed until the luminance is reduced by half was longer, as compared with the respective organic electroluminescent devices in the comparative examples 1 and 2 in which the above-mentioned conditions were not satisfied, so that stable luminance was obtained for a long time.

EXAMPLES 2 TO 7

and

Comparative Examples 3 and 4

Also in organic electroluminescent devices in examples 2 to 7 and comparative examples 3 and 4, only the emitting layer

4

in the organic electroluminescent device in the above-mentioned example 1 was changed, and bis(10-hydroxybenzo[h]-quinolinate)beryllium (hereinafter referred to as BeBq

2

) indicated by the following chemical formula 6 was used as a host material.

The organic electroluminescent devices in the examples 2 to 7 and the comparative examples 3 and 4 were obtained in the same manner that in the example 1 except that an emitting layer

4

was formed using only the above-mentioned host material in the comparative example 3, while 2′,3′-naphtha-2,3-fluorenone indicated by the following chemical formula 7, 2,3-anthrafluorene indicated by the following chemical formula 8, 2,3-benzofluorenone indicated by the following chemical formula 9, picene indicated by the following chemical formula 10, ovalene indicated by the following chemical formula 11, pyrene quinone indicated by the following chemical formula 12, and dioxazine carbazole indicated by the following chemical formula 13 were doped at a ratio of 2 % by weight as a dopant into the above-mentioned host material, respectively, in the example 2, the example 3, the example 4, the example 5, the example 6, the example 7, and the comparative example 4.

In each of the organic electroluminescent devices in the examples 2 to 7 and the comparative examples 3 and 4, the HOMOs in the host material and the dopant which were used in the emitting layer

4

were shown in the following Table 2.

A positive voltage and a negative voltage were respectively applied to the hole injection electrode

2

and the electron injection electrode

6

in each of the organic electroluminescent devices in the examples 2 to 7 and the comparative examples 3 and 4, to find the highest luminance obtained in the organic electroluminescent device and the applied voltage at that time, and each of the organic electroluminescent devices was caused to emit light having luminance of 100 cd/m

2

, to find a time period elapsed until the luminance is reduced by half. The results were shown in the following Table 2.

TABLE 2

reduc-

type of

tion

host

type of

highest

applied

-by-half

material

dopant

luminance

voltage

time

HOMO(eV)

HOMO(eV)

(cd/m

2

)

(V)

(hour)

example 2

BeBq

2

chemical

20000

14

800

−5.5

formula 7

−5.6

example 3

BeBq

2

chemical

20000

14

500

−5.5

formula 8

−5.5

example 4

BeBq

2

chemical

20000

14

400

−5.5

formula 9

−5.7

example 5

BeBq

2

chemical

20000

14

500

−5.5

formula 10

−5.4

example 6

BeBq

2

chemical

20000

14

500

−5.5

formula 12

−5.7

comparative

BeBq

2

none

18000

14

100

example 3

−5.5

comparative

BeBq

2

chemical

200

14

20

example 4

−5.5

formula 13

−5.0

As a result, in the respective organic electroluminescent devices in the examples 2 to 7 in which the dopant having a condensed ring obtained by condensing three or more rings was used, and the difference in the HOMO between the host material and the dopant was in a range from −0.3 eV to +0.3 eV, higher luminance was obtained, and a time period elapsed until the luminance is reduced by half was longer, as compared with the respective organic electroluminescent devices in the comparative examples 3 and 4 in which the above-mentioned conditions were not satisfied, so that stable luminance was obtained for a long time.

EXAMPLES 8 TO 19

and

Comparative Examples 5 and 6

Also in organic electroluminescent devices in examples 8 to 19 and comparative examples 5 and 6, only the emitting layer

4

in the organic electroluminescent device in the above-mentioned example 1 was changed, and 1AZM-Hex indicated by the following chemical formula 14 was used as a host material.

The organic electroluminescent devices in the examples 8 to 19 and the comparative examples 5 and 6 were obtained in the same manner that in the example 1 except that an emitting layer

4

was formed using only the above-mentioned host material in the comparative example 5, while 1′,2′-naphtha-2,3,-fluorene indicated by the following chemical formula 15, 2′,1′-naphtha-1,2-fluorene indicated by the following chemical formula 16, 1,12-benzperylene indicated by the following chemical formula 17, 4,5-benzpyrene indicated by the following chemical formula 18, benzo(a)pyrene indicated by the following chemical 19, naphthapyrene indicated by the following chemical formula 20. 1,3-bis(1-pyrenyl)propane indicated by the following chemical formula 21, 5,6,11,12-tetramethyl naphthacene indicated by the following formula 22, 9,10-bis(phenylethynyl)anthracene indicated by the following chemical formula 23, fluoracene indicated by the following chemical formula 24, fluorocyclene indicated by the following chemical formula 25, perylene indicated by the following chemical formula 26, 1,2,3,4-tetraphenyl-1,3-cyclopentadiene indicated by the following chemical formula 27 were doped at a ratio of 2% by weight as a dopant into the above-mentioned host material, respectively, in the example 8, the example 9, the example 10, the example 11, the example 12, the example 13, the example 14, the example 15, the example 16, the example 17, the example 18, the example 19, and the comparative example 6.

In each of the organic electroluminescent devices in the examples 8 to 19 and the comparative examples 5 and 6,the HOMOs in the host material and the dopant which were used in the emitting layer

4

were shown in the following Table 3.

A positive voltage and a negative voltage were respectively applied to the hole injection electrode

2

and the electron injection electrode

6

in each of the organic electroluminescent devices in the examples 8 to 19 and the comparative examples 5 and 6, to find the highest luminance obtained in the organic electroluminescent device and the applied voltage at that time, and each of the organic electroluminescent devices was caused to emit light having luminance of 100 cd/m

2

, to find a time period elapsed until the luminance is reduced by half. The results were shown in the following Table 3.

TABLE 3

reduc-

type of

tion

host

type of

highest

applied

-by-half

material

dopant

luminance

voltage

time

HOMO(eV)

HOMO(eV)

(cd/m

2

)

(V)

(hour)

example 8

1AZM-Hex

chemical

3000

18

500

−5.7

formula 15

−5.7

example 9

1AZM-Hex

chemical

3000

18

300

−5.7

formula 16

−5.7

example 10

1AZM-Hex

chemical

10000

18

1000

−5.7

formula 17

−5.6

example 11

1AZM-Hex

chemical

2500

18

300

−5.7

formula 18

−6.0

example 12

1AZM-Hex

chemical

2500

18

300

−5.7

formula 19

−6.0

example 13

1AZM-Hex

chemical

3000

18

600

−5.7

formula 20

−5.8

example 14

1AZM-Hex

chemical

2000

16

300

−5.7

formula 21

−5.9

example 15

1AZM-Hex

chemical

7000

16

1000

−5.7

formula 22

−5.7

example 16

1AZM-Hex

chemical

5000

16

1000

−5.7

formula 23

−5.6

example 17

1AZM-Hex

chemical

2000

16

300

−5.7

formula 24

−6.0

example 18

1AZM-Hex

chemical

3000

16

800

−5.7

formula 25

−6.0

example 19

1AZM-Hex

chemical

10000

18

1000

−5.7

formula 26

−5.5

comparative

1AZM-Hex

none

1500

18

10

example 5

−5.7

comparative

1AZM-Hex

chemical

1000

18

10

example 6

−5.7

formula 27

−5.9

As a result, in the respective organic electroluminescent devices in the examples 8 to 19 in which the dopant having a condensed ring obtained by condensing three or more rings was used, and the difference in the HOMO between the host material and the dopant was in a range from −0.3 eV to +0.3 eV, higher luminance was obtained, and a time period elapsed until the luminance is reduced by half was longer, as compared with the respective organic electroluminescent devices in the comparative examples 5 to 6 in which the above-mentioned conditions were not satisfied, so that stable luminance was obtained for a long time.

EXAMPLE 20 TO 31

and

Comparative Examples 7 and 8

Also in organic electroluminescent devices in examples 20 to 31 and comparative examples 7 and 8, only the emitting layer

4

in the organic electroluminescent device in the above-mentioned example 1 was changed, and tris(8-quinolinol)aluminum (hereinafter referred to as Alq

3

) indicated by the following chemical formula 28 was used as a host material.

The organic electroluminescent devices in the examples 20 to 31 and the comparative examples 7 and 8 were obtained in the same manner that in the example 1 except that an emitting layer

4

was formed using only the above-mentioned host material in the comparative example 7, while 1′,2′-naphtha-2,3-fluorenone indicated by the following chemical formula 29, 2′,1′-naphtha-1,2-fluorenone indicated by the following chemical formula 30, rubicene indicated by the following chemical formula 31, 1,2-benzpentacene indicated by the following chemical formula 32, 5,6,11,12-tetraphenyl naphthacene (rubrene) indicated by the following chemical formula 33, rubrene peroxide indicated by the following chemical formula 34, naphthacene quinone indicated by the following chemical formula 35, pentacene-5,12-quinone indicated by the following chemical formula 36, pentacene-6,13-quinone indicated by the following chemical formula 37, 3,9-perylene quinone indicated by the following chemical formula 38, 1,12-perylene quinone indicated by the following chemical formula 39, 3,10-perylene quinone indicated by the following chemical formula 40, dioxazine carbazole indicated by the foregoing chemical formula 13 were doped at a ratio of 2% by weight as a dopant into the above-mentioned host material, respectively, in the example 20, the example 21, the example 22, the example 23, the example 24, the example 25, the example 26, the example 27, the example 28, the example 29, the example 30, the example 31, and the comparative example 8.

In each of the organic electroluminescent devices in the examples 20 to 31 and the comparative examples 7 and 8, the HOMOs in the host material and the dopant which were used in the emitting layer

4

were shown in the following Table 4.

A positive voltage and a negative voltage were respectively applied to the hole injection electrode

2

and the electron injection electrode

6

in each of the respective organic electroluminescent devices in the examples 20 to 31 and the comparative examples 7 and 8, to find the highest luminance obtained in the organic electroluminescent device and the applied voltage at that time, and each of the organic electroluminescent devices was caused to emit light having luminance of 100 cd/m

2

, to find a time period elapsed until the luminance is reduced by half. The results were shown in the following Table 4.

TABLE 4

reduc-

type of

tion

host

type of

highest

applied

-by-half

material

dopant

luminance

voltage

time

HOMO(eV)

HOMO(eV)

(cd/m

2

)

(V)

(hour)

example 20

Alq

3

chemical

20000

16

800

−5.6

formula 29

−5.6

example 21

Alq

3

chemical

19000

16

600

−5.6

formula 30

−5.6

example 22

Alq

3

chemical

23000

16

2000

−5.6

formula 31

−5.6

example 23

Alq

3

chemical

18000

16

500

−5.6

formula 32

−5.5

example 24

Alq

3

chemical

21000

16

2500

−5.6

formula 33

−5.4

example 25

Alq

3

chemical

20000

16

5000

−5.6

formula 34

−5.4

example 26

Alq

3

chemical

19000

16

300

−5.6

formula 35

−5.7

example 27

Alq

3

chemical

18000

16

200

−5.6

formula 36

−5.7

example 28

Alq

3

chemical

18000

16

200

−5.6

formula 37

−5.6

example 29

Alq

3

chemical

19000

16

300

−5.6

formula 38

−5.6

example 30

Alq

3

chemical

20000

16

700

−5.6

formula 39

−5.6

example 31

Alq

3

chemical

20000

16

700

−5.6

formula 40

−5.6

comparative

Alq

3

none

16000

16

150

example 7

−5.6

comparative

Alq

3

chemical

200

14

30

example 8

−5.6

formula 13

−5.0

As a result, in the respective organic electroluminescent devices in the examples 20 to 31 in which the dopant having a condensed ring obtained by condensing three or more rings was used, and the difference in the HOMO between the host material and the dopant was in a range from −0.3 eV to +0.3 eV, higher luminance was obtained, and a time period elapsed until the luminance is reduced by half was longer, as compared with the respective organic electroluminescent devices in the comparative examples 7 to 8 in which the above-mentioned conditions were not satisfied, so that stable luminance was obtained for a long time.

EXAMPLE 32

In an organic electroluminescent device in an example 32, a transparent hole injection electrode

2

having a thickness of 2000 Å was formed using the above-mentioned ITO on a glass substrate

1

, and an emitting layer

4

having a thickness of 500 Å obtained by doping 2% by weight of 2′,3′-naphtha-2,3-fluorene indicated by the following chemical formula 42 as a dopant into a host material composed of polyvinyl carbazole (PVCz) indicated by the following chemical formula 41, a first electron transport layer

5

a,

which has hole blocking properties, having a thickness of 200 Å using a triazole derivative (TAZ) indicated by the following chemical formula 43, a second electron transport layer

5

b

having a thickness of 300 Å using Alq

3

indicated by the foregoing chemical formula 28, and an electron injection electrode

6

having a thickness of 2000 Å using a magnesium-indium alloy were laminated on the injection electrode

2

, as shown in FIG.

5

.

EXAMPLE 33 TO 35

and

Comparative Examples 9 and 10

Organic electroluminescent devices in examples 33 to 35 and comparative examples 9 and 10 were obtained in the same manner as that in the above-mentioned example 32 except that only the emitting layer

4

in the organic electroluminescent device in the above-mentioned example 33 was changed, to form an emitting layer

4

using only the above-mentioned PVCz which is a host material in the comparative example 9, while the dopant to be doped into the host material using the above-mentioned PVCz was changed in the examples 33 to 35 and the comparative example 10, that is, 2% by weight of 2,3-benzofluorene indicated by the following chemical formula 44, 1,2-benzofluorene indicated by the following chemical formula 45, dibenzo(a,h)anthracene indicated by the following chemical formula 46, and 1,4-bis(5-phenyl-2-oxazolyl)benzene (hereinafter referred to as POPOP) indicated by the following chemical formula 47 were respectively doped in the example 33, the example 34, the example 35, and the comparative example 10, to form an emitting layer

4

.

In each of the organic electroluminescent devices in the examples 32 to 35 and the comparative examples 9 and 10, the HOMOs in the host material and the dopant which were used in the emitting layer

4

were shown in the following Table 5.

A positive voltage and a negative voltage were respectively applied to the hole injection electrode

2

and the electron injection electrode

6

in each of the organic electroluminescent devices in the examples 32 to 35 and the comparative examples 9 and 10, to find the highest luminance obtained in the organic electroluminescent device and the applied voltage at that time, and each of the organic electroluminescent devices was caused to emit light having luminance of 100 cd/m

2

, to find a time period elapsed until the luminance is reduced by half. The results were shown in the following Table 5.

TABLE 5

reduc-

type of

tion

host

type of

highest

applied

-by-half

material

dopant

luminance

voltage

time

HOMO(eV)

HOMO(eV)

(cd/m

2

)

(V)

(hour)

example 32

PVCz

chemical

4000

20

500

−5.6

formula 42

−5.7

example 33

PVCz

chemical

2000

20

200

−5.6

formula 44

−5.9

example 34

PVCz

chemical

2000

20

200

−5.6

formula 45

−5.9

example 35

PVCz

chemical

2000

20

200

−5.6

formula 46

−5.7

comparative

PVCz

none

700

20

5

example 9

−5.6

comparative

PVCz

chemical

400

20

5

example 10

−5.6

formula 47

−6.0

As a result, in the respective organic electroluminescent devices in the examples 32 to 35 in which the dopant having a condensed ring obtained by condensing three or more rings was used, and the difference in the HOMO between the host material and the dopant was in a range from −0.3 eV to +0.3 eV, higher luminance was obtained, and a time period elapsed until the luminance is reduced by half was longer, as compared with the respective organic electroluminescent devices in the comparative examples 9 to 10 in which the above-mentioned conditions were not satisfied, so that stable luminance was obtained for a long time.

The organic electroluminescent device in the present invention is not limited to those in the above-mentioned examples, and can be embodied by being suitably changed in a range in which the gist thereof is not changed.

Industrial Applicability

As described in detail above, as in the organic electroluminescent device in the present invention, in forming an emitting layer having a dopant doped into a host material, a dopant having a condensed ring obtained by condensing three or more rings is used, the difference in the HOMO between the host material and the dopant is in a range from −0.3 eV to +0.3 eV, the film stability of the emitting layer is improved, and an organic material in the emitting layer is prevented from being crystallized due to heat or the like at the time of light emission, so that stable and uniform light emission can be performed for a long time, and excitation energy is efficiently moved from the host material to the dopant. Therefore, luminous efficiency in the organic electroluminescent device is improved, so that high luminance is obtained.

Furthermore, it is also possible to improve the film stability of the emitting layer by doping the dopant into a layer other than the emitting layer.

Although only principal examples and representative materials are described herein, the present invention can be further optimized by using as these materials materials having a substituent group, for example, —C

6

H

5

, —CH

3

, —C

2

H

5

, —C(CH

3

)

3

, —OCH

3

, —OCOCH

3

, —OH, —NH

2

, —N(CH

3

)

2

, —N(C

6

H

5

)

2

, —NC

12

H

8

, —NHCOCH

3

, —NH

3

, —CF

3

, —NO

2

, —CN, —COCH

3

, and —CO

2

C

2

H

5

.

Number	Name	Date	Kind
5281489	Mori et al.	Jan 1994	A
5601903	Fujii et al.	Feb 1997	A

Organic electroluminescence element

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Priority Claims (1)

PCT Information

US Referenced Citations (2)

Non-Patent Literature Citations (4)

Entry
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D. J. Fatemi et al; Synthetic Metals, 85 (1997) pp. 1225-1228, (No Month).
Yugi Hamada et al; Jpn. J. Appl. Phys. vol. 34 (1995) pp. L824-L826, (No Month).
M. Yoshida et al; Synthetic Metals, 71 (1995) pp. 2111-2112, (No Month).