Patent Publication Number: US-11024822-B2

Title: Organic electroluminescent element, lighting device, and display device

Description:
TECHNICAL FIELD 
     The present invention relates to an organic electroluminescent element and to a display device and a lighting device including the same. 
     The present application claims the benefit of priority of Japanese Patent Application No. 2016-254302 filed on Dec. 27, 2016, the contents of which are incorporated herein by reference. 
     BACKGROUND ART 
     An organic electroluminescent element (hereafter, also referred to as “organic EL element” for short) is a self-luminescent element including a light emitting layer, made of an organic compound, between a cathode and an anode facing each other. When voltage is applied between the cathode and the anode, electrons injected into the light emitting layer from the cathode side and holes injected into the light emitting layer from the anode side recombine in the light emitting layer to form excitons and the excitons causes the organic EL element to emit light. 
     As an organic EL element capable of achieving high luminance and long lifetime, there is known an element with a multi-photon emission structure (hereafter, referred to as “MPE element” for short) in which a light emitting unit including at least one light emitting layer is considered as one unit and an electrically-insulating charge generating layer is arranged between multiple light emitting units (for example, see Patent Document 1). In the MPE element, when voltage is applied between a cathode and an anode, charges in a charge transfer complex move to the cathode side and the anode side. In the MPE element, holes are thereby injected into one light emitting unit located on the cathode side of the charge generating layer and electrons are injected into another light emitting unit located on the anode side of the charge generating layer. In such an MPE element, since light can be simultaneously emitted from the multiple light emitting units with the same current amount, a current efficiency and an external quantum efficiency multiplied by the number of the light emitting units can be achieved. 
     Moreover, the MPE element can provide white light by combining various light emitting units configured to emit light of different colors. Accordingly, in recent years, there are developed MPE elements aimed to be applied to a display device and a lighting device which basically emit white light. For example, there is known an MPE element suitable for a display device which generates white light with high color temperature at high efficiency by using a combination of a light emitting unit configured to emit blue light and a light emitting unit configured to emit green light and yellow light (for example, see Patent Document 2). Moreover, there is known an MPE element suitable for a lighting device which generates white light with high color temperature and an excellent color rendering property by using a combination of a light emitting unit configured to emit red light and a light emitting unit configured to emit blue light and yellow light (for example, see Patent Document 3). 
     Although the display device and the lighting device both use white light, required performance specifications vary between these devices and MPE elements with structures dedicated to the respective devices have been developed. For example, as described in Patent Documents 2 and 3, in the development of MPE elements characterized by emission of white light with high color temperature, luminous efficiency is focused on in the development of the MPE element for the display device while a color rendering property is focused on in the development of the MPE element for the lighting device. 
     However, from the viewpoint of obtaining excellent white light, it is ideal in both of the display device and the lighting device that the element can provide white light which is excellent not only in some of the characteristics but also in all three important indices of white light, that is color temperature, luminous efficiency, and a color rendering property in a balanced manner. 
     PRIOR ART DOCUMENT 
     Patent Document 
     Patent Document 1: Japanese Patent Application Publication No. 2003-272860 
     Patent Document 2: Published Japanese Translation of PCT International Application No. 2012-503294 
     Patent Document 3: Japanese Patent Application Publication No. 2009-224274 
     SUMMARY OF THE INVENTION 
     Problems to be Solved by the Invention 
     The present invention has been proposed in view of the aforementioned conventional circumstances and an object thereof is to provide an organic electroluminescent element which can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property and is thus suitable for both of a display device and a lighting device and to provide a display device and a lighting device including this organic electroluminescent element. 
     Means for Solving the Problems 
     To achieve the above object, provided are the following aspects. 
     (1) An organic electroluminescent element having a structure in which a plurality of light emitting units each including a light emitting layer made of at least an organic compound are stacked one on top of another between a first electrode and an second electrode with a charge generating layer sandwiched between each pair of the adjacent light emitting units, characterized in that 
     the organic electroluminescent element comprises at least two blue light emitting units each including a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in a blue wavelength band, 
     white light produced by light emission of the plurality of light emitting units has an emission spectrum continuous over a wavelength band of at least 380 nm to 780 nm and has one or two peak wavelengths in a blue wavelength band of 440 nm to 490 nm in the emission spectrum, 
     correlated color temperature of the white light is 3300 K or higher, and 
     R6 and R12 among special color rendering indices (Ri) of the white light are 60 or more and 30 or more, respectively. 
     (2) The organic electroluminescent element according to the above aspect (1), characterized in that R12 among the special color rendering indices (Ri) of the white light is 60 or more. 
     (3) The organic electroluminescent element according to the above aspect (1) or (2), characterized in that the blue light emitting layer is formed of a blue fluorescent light emitting layer containing a blue fluorescent material. 
     (4) The organic electroluminescent element according to the above aspect (3), characterized in that the blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer includes a delayed fluorescence component. 
     (5) The organic electroluminescent element according to the above aspect (1) or (2), characterized in that the blue light emitting layer is formed of a blue phosphorescent light emitting layer containing a blue phosphorescent material. 
     (6) The organic electroluminescent element according to anyone of the above aspects (1) to (5), characterized in that 
     the organic electroluminescent element comprises two of the blue light emitting units which are identical, and 
     the blue light emitting units emit blue light with the same peak wavelength. 
     (7) The organic electroluminescent element according to anyone of the above aspects (1) to (5), characterized in that 
     the organic electroluminescent element comprises two of the blue light emitting units which are different from each other, and 
     the blue light emitting units emit blue light with different peak wavelengths, respectively. 
     (8) The organic electroluminescent element according to the above aspect (7), characterized in that the white light has one peak wavelength in a blue wavelength band of 440 nm to 470 nm and one peak wavelength in a blue wavelength band of 470 nm to 490 nm. 
     (9) The organic electroluminescent element according to anyone of the above aspects (1) to (8), characterized in that 
     the organic electroluminescent element comprises at least one red/green light emitting unit including a light emitting layer formed by stacking a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band one on top of the other, and 
     the white light produced by the light emission of the plurality of units has one peak wavelength in a red wavelength band of 590 nm to 640 nm and one or two peak wavelengths in a green wavelength band of 500 nm to 560 nm. 
     (10) The organic electroluminescent element according to any one of the above aspects (1) to (8), characterized in that 
     the organic electroluminescent element comprises at least one red-green light emitting unit including a light emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material, and 
     the white light produced by the light emission of the plurality of light emitting units has one peak wavelength in a red wavelength band of 590 nm to 640 nm and one or two peak wavelengths in a green wavelength band of 500 nm to 560 nm. 
     (11) The organic electroluminescent element according to any one of the above aspects (1) to (10), characterized in that a light emission intensity of the peak wavelength in the blue wavelength band of 440 nm to 490 nm is higher than either of a light emission intensity of the peak wavelength in the red wavelength band of 590 nm to 640 nm and a light emission intensity of the peak wavelength in the green wavelength band of 500 nm to 560 nm.
 
(12) The organic electroluminescent element according to the above aspect (11), characterized in that the white light has one bottom wavelength in a blue wavelength band and a green wavelength band of 500 nm to 520 nm.
 
(13) The organic electroluminescent element according to the above aspect (12), characterized in that a light emission intensity of the one bottom wavelength in the blue wavelength band and the green wavelength band of 500 nm to 520 nm is lower than a light emission intensity of a bottom wavelength in a wavelength band of 570 nm to 590 nm.
 
(14) The organic electroluminescent element according to the above aspect (12) or (13), characterized in that a ratio of (B) to (A) ((B)/(A)) is 0.50 or smaller, where (A) is a light emission intensity of a peak wavelength having the highest light emission intensity in the wavelength band of 380 nm to 780 nm and (B) is a light emission intensity of the one bottom wavelength in the blue wavelength band and the green wavelength band of 500 nm to 520 nm.
 
(15) The organic electroluminescent element according to any one of the above aspects (1) to (14), characterized in that an average color rendering index (Ra) of the white light is 70 or more.
 
(16) The organic electroluminescent element according to any one of the above aspects (9) to (15), the organic electroluminescent element having the structure in which the plurality of light emitting units each including the light emitting layer made of at least the organic compound are stacked one on top of another between the first electrode and the second electrode with the charge generating layer sandwiched between each pair of the adjacent light emitting units, the organic electroluminescent element capable of providing the white light by causing the plurality of light emitting units to emit light, characterized in that
         the organic electroluminescent element comprises:
           a first light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit;   a second light emitting unit formed of the blue light emitting unit; and   a third light emitting unit formed of the blue light emitting unit,   
           the first light emitting unit and the second light emitting unit are stacked one on top of the other with a first charge generating layer sandwiched therebetween,   the second light emitting unit and the third light emitting unit are stacked one on top of the other with a second charge generating layer sandwiched therebetween, and   the organic electroluminescent element has a structure in which the second electrode, the third light emitting unit, the second charge generating layer, the second light emitting unit, the first charge generating layer, the first light emitting unit, and the first electrode are stacked one on top of another in this order.
 
(17) The organic electroluminescent element according to any one of the above aspects (9) to (15), the organic electroluminescent element having the structure in which the plurality of light emitting units each including the light emitting layer made of at least the organic compound are stacked one on top of another between the first electrode and the second electrode with the charge generating layer sandwiched between each pair of the adjacent light emitting units, the organic electroluminescent element capable of providing the white light by causing the plurality of light emitting units to emit light, characterized in that
   the organic electroluminescent element comprises:
           a first light emitting unit formed of the blue light emitting unit;   a second light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit; and   a third light emitting unit formed of the blue light emitting unit,   
           the first light emitting unit and the second light emitting unit are stacked one on top of the other with a first charge generating layer sandwiched therebetween,   the second light emitting unit and the third light emitting unit are stacked one on top of the other with a second charge generating layer sandwiched therebetween, and   the organic electroluminescent element has a structure in which the second electrode, the third light emitting unit, the second charge generating layer, the second light emitting unit, the first charge generating layer, the first light emitting unit, and the first electrode are stacked one on top of another in this order.
 
(18) The organic electroluminescent element according to any one of the above aspects (9) to (15), the organic electroluminescent element having the structure in which the plurality of light emitting units each including the light emitting layer made of at least the organic compound are stacked one on top of another between the first electrode and the second electrode with the charge generating layer sandwiched between each pair of the adjacent light emitting units, the organic electroluminescent element capable of providing the white light by causing the plurality of light emitting units to emit light, characterized in that
       

     the organic electroluminescent element comprises:
         a first light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit;   a second light emitting unit formed of the blue light emitting unit;   a third light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit; and   a fourth light emitting unit formed of the blue light emitting unit,       

     the first light emitting unit and the second light emitting unit are stacked one on top of the other with a first charge generating layer sandwiched therebetween, 
     the second light emitting unit and the third light emitting unit are stacked one on top of the other with a second charge generating layer sandwiched therebetween, 
     the third light emitting unit and the fourth light emitting unit are stacked one on top of the other with a third charge generating layer sandwiched therebetween, and 
     the organic electroluminescent element has a structure in which the second electrode, the fourth light emitting unit, the third charge generating layer, the third light emitting unit, the second charge generating layer, the second light emitting unit, the first charge generating layer, the first light emitting unit, and the first electrode are stacked one on top of another in this order. 
     (19) The organic electroluminescent element according to any one of the above aspects (9) to (15), the organic electroluminescent element having the structure in which the plurality of light emitting units each including the light emitting layer made of at least the organic compound are stacked one on top of another between the first electrode and the second electrode with the charge generating layer sandwiched between each pair of the adjacent light emitting units, the organic electroluminescent element capable of providing the white light by causing the plurality of light emitting units to emit light, characterized in that 
     the organic electroluminescent element comprises:
         a first light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit;   a second light emitting unit formed of the blue light emitting unit;   a third light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit;   a fourth light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit;   a fifth light emitting unit formed of the blue light emitting unit; and   a sixth light emitting unit formed of the red/green light emitting unit or the red-green light emitting unit,       

     the first light emitting unit and the second light emitting unit are stacked one on top of the other with a first charge generating layer sandwiched therebetween, 
     the second light emitting unit and the third light emitting unit are stacked one on top of the other with a second charge generating layer sandwiched therebetween, 
     the third light emitting unit and the fourth light emitting unit are stacked one on top of the other with a third charge generating layer sandwiched therebetween, 
     the fourth light emitting unit and the fifth light emitting unit are stacked one on top of the other with a fourth charge generating layer sandwiched therebetween, 
     the fifth light emitting unit and the sixth light emitting unit are stacked one on top of the other with a fifth charge generating layer sandwiched therebetween, and 
     the organic electroluminescent element has a structure in which the second electrode, the sixth light emitting unit, the fifth charge generating layer, the fifth light emitting unit, the fourth charge generating layer, the fourth light emitting unit, the third charge generating layer, the third light emitting unit, the second charge generating layer, the second light emitting unit, the first charge generating layer, the first light emitting unit, and the first electrode are stacked one on top of another in this order. 
     (20) The organic electroluminescent element according to any one of the above aspects (1) to (19), characterized in that 
     the charge generating layers are formed of electrically insulating layers made of an electron accepting material and an electron donating material, and 
     a specific resistance of the electrically insulating layers is 1.0×10 2 Ω·cm or more. 
     (21) The organic electroluminescent element according to the above aspect (20), characterized in that the specific resistance of the electrically insulating layers is 1.0×10 5 Ω·cm or more. 
     (22) The organic electroluminescent element according to any one of the above aspects (1) to (19), characterized in that 
     each of the charge generating layers is formed of a mixed layer of different materials and one component of the mixed layer forms a charge transfer complex by redox, and 
     when voltage is applied between the first electrode and the second electrode, charges in the charge transfer complex move to the first electrode side and the second electrode side to cause holes to be injected into one light emitting unit located on the first electrode side of the charge generating layer and cause electrons to be injected into another light emitting unit located on the second electrode side of the charge generating layer. 
     (23) The organic electroluminescent element according to any one of the above aspects (1) to (19), characterized in that 
     each of the charge generating layers is formed of a laminate of an electron accepting material and an electron donating material, and 
     when voltage is applied between the first electrode and the second electrode, in an interface between the electron accepting material and the electron donating material, charges generated by reaction involving electron transfer between the electron accepting material and the electron donating material move to the first electrode side and the second electrode side to cause holes to be injected into one light emitting unit located on the first electrode side of the charge generating layer and cause electrons to be injected into another light emitting unit located on the second electrode side of the charge generating layer. 
     (24) The organic electroluminescent element according to any one of the above aspects (1) to (23), characterized in that the charge generating layers contain a compound having a structure expressed by formula (1): 
     
       
         
         
             
             
         
       
     
     where R represents an electron withdrawing group of F, Cl, Br, I, CN, or CF 3 . 
     (25) The organic electroluminescent element according to any one of the above aspects (1) to (24), characterized in that 
     the organic electroluminescent element comprises at least three color filters different from one another, and 
     an arrangement of the at least three color filters different from one another changes the white light produced by the light emission of the plurality of light emitting units to light of a different color. 
     (26) The organic electroluminescent element according to the above aspect (25), characterized in that the arrangement of the at least three color filters different from one another is one selected from the group consisting of a stripe arrangement, a mosaic arrangement, a delta arrangement, and a pentile arrangement.
 
(27) The organic electroluminescent element according to the above aspect (25) or (26), characterized in that
 
     the at least three color filters different from one another are a red color filter, a green color filter, and a blue color filter, and 
     the organic electroluminescent element has a RGB arrangement in which the three color filters different from one another are arranged in turn. 
     (28) The organic electroluminescent element according to the above aspect (27), characterized in that 
     the organic electroluminescent element has a RGBW arrangement including the RGB arrangement, and 
     the color filters are not arranged in an arrangement portion of W. 
     (29) The organic electroluminescent element according to the above aspect (28), characterized in that the RGBW arrangement is one selected from the group consisting of a stripe arrangement, a mosaic arrangement, a delta arrangement, and a pentile arrangement.
 
(30) A display device characterized in that the display device comprises the organic electroluminescent element according to any one of the above aspects (25) to (29).
 
(31) The display device according to the above aspect (30), characterized in that
 
     the display device comprises a base substrate and a sealing substrate which are formed of flexible substrates, and 
     the display device is flexible. 
     (32) Alighting device characterized in that the lighting device comprises the organic electroluminescent element according to any one of the above aspects (1) to (24). 
     (33) The lighting device according to the above aspect (32), characterized in that the lighting device comprises an optical film on a light extraction surface side of the organic electroluminescent element. 
     (34) The lighting device according to the above aspect (32) or (33), characterized in that an average color rendering index (Ra) of the white light is 80 or more. 
     (35) The lighting device according to the above aspect (34), characterized in that 
     the lighting device comprises a base substrate and a sealing substrate which are formed of flexible substrates, and 
     the lighting device is flexible. 
     Effect of the Invention 
     According to one aspect described above, it is possible to provide an organic electroluminescent element which can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property and is thus suitable for both of a display device and a lighting device and to provide a display device and a lighting device including this organic electroluminescent element. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a cross-sectional view illustrating a schematic configuration of a first embodiment of an organic EL element in the present invention. 
         FIG. 2  is a graph illustrating examples of an emission spectrum of white light obtained in the first embodiment of the organic EL element in the present invention. 
         FIG. 3  is a view illustrating results of simulation conducted to verify effects on R6 and R12 in a white element. 
         FIG. 4  is a view illustrating results of simulation conducted to verify effects on R6 and R12 in the white element. 
         FIG. 5  is a view illustrating results of simulation conducted to verify effects on R6 and R12 in a white element. 
         FIG. 6  is a view illustrating results of simulation conducted to verify effects on R6 and R12 in the white element. 
         FIG. 7  is a cross-sectional view illustrating a schematic configuration of a second embodiment of the organic EL element in the present invention. 
         FIG. 8  is a cross-sectional view illustrating a schematic configuration of a third embodiment of the organic EL element in the present invention. 
         FIG. 9  is a cross-sectional view illustrating a schematic configuration of a fourth embodiment of the organic EL element in the present invention. 
         FIG. 10  is a cross-sectional view illustrating a schematic configuration of a fifth embodiment of the organic EL element in the present invention. 
         FIG. 11  is a cross-sectional view illustrating a schematic configuration of a sixth embodiment of the organic EL element in the present invention. 
         FIG. 12  is a cross-sectional view illustrating a schematic configuration of an embodiment of a lighting device in the present invention. 
         FIG. 13  is a cross-sectional view illustrating a schematic configuration of one embodiment of a display device in the present invention. 
         FIG. 14  is a cross-sectional view illustrating an element structure of an organic EL element in Example 1. 
         FIG. 15  is a view illustrating evaluation results of the organic EL element in Example 1. 
         FIG. 16  is a cross-sectional view illustrating an element structure of an organic EL element in Example 2. 
         FIG. 17  is a view illustrating evaluation results of the organic EL element in Example 2. 
     
    
    
     MODE FOR CARRYING OUT THE INVENTION 
     Detailed description is given of embodiments of an organic electroluminescent element of the present invention and a display device and a lighting device including the same with reference to the drawings. 
     Note that, for the sake of convenience, in the drawings used in the following description, characteristic parts are sometimes illustrated in an enlarged manner to facilitate understanding of characteristics, and proportions of dimensions of constitutional elements and the like are not always the same as actual ones. Moreover, materials, dimensions, and the like exemplified in the following description are merely examples and the present invention are not necessarily limited to those and can be carried out with the materials, dimensions, and the like appropriately changed within a scope not changing the spirit of the invention. 
     [Organic Electroluminescent Element (Organic EL Element)] 
     First Embodiment 
       FIG. 1  is a cross-sectional view illustrating a schematic configuration of a first embodiment of the organic EL element in the present invention. 
     As illustrated in  FIG. 1 , the organic EL element  10  of the embodiment has a structure in which multiple light emitting units  13 A,  13 B,  13 C each including a light emitting layer made of at least an organic compound are stacked one on top of another between a first electrode  11  and a second electrode  12  with each of charge generating layers (CGL)  14 A,  14 B sandwiched between a corresponding pair of the adjacent light emitting units. The organic EL element  10  is an organic EL element capable of providing white light by causing the multiple light emitting units  13 A,  13 B,  13 C to emit light. 
     The organic EL element  10  of the embodiment includes the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C. 
     The first light emitting unit  13 A is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The second light emitting unit  13 B is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in a blue wavelength band. The blue light emitting layer may be a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The third light emitting unit  13 C is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in the blue wavelength band. The blue light emitting layer may be either a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The first light emitting unit  13 A and the second light emitting unit  13 B are stacked one on top of the other with the first charge generating layer  14 A sandwiched therebetween. 
     The second light emitting unit  13 B and the third light emitting unit  13 C are stacked one on top of the other with the second charge generating layer  14 B sandwiched therebetween. 
     The organic EL element  10  of the embodiment has a structure in which the second electrode  12 , the third light emitting unit  13 C, the second charge generating layer  14 B, the second light emitting unit  13 B, the first charge generating layer  14 A, the first light emitting unit  13 A, and the first electrode  11  are stacked one on top of another in this order. Specifically, the organic EL element  10  of the embodiment has an MPE structure in which the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C are stacked one on top of another with each of the first charge generating layer  14 A and the second charge generating layer  14 B sandwiched between the corresponding pair of adjacent light emitting units. 
     In the organic EL element  10  of the embodiment, the white light produced by light emission of the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C has an emission spectrum continuous over a wavelength band of at least 380 nm to 780 nm. Moreover, in the organic EL element  10  of the embodiment, the white light has one or two peak wavelengths in the blue wavelength band of 440 nm to 490 nm in this emission spectrum. Furthermore, in the organic EL element  10  of the embodiment, the white light has one peak wavelength in the red wavelength band of 590 nm to 640 nm and one or two peak wavelengths in the green wavelength band of 500 nm to 560 nm in this emission spectrum. 
     Generally, a metal with a small work function, an alloy of such a metal, a metal oxide, or the like is preferably used as the first electrode  11 . For example, as a metal forming the first electrode  11 , it is possible to use a metal single substance like an alkaline metal such as lithium (Li), an alkaline earth metal such as magnesium (Mg) or calcium (Ca), or a rare-earth metal such as europium (Eu) or use an alloy containing any of these metals and aluminum (Al), silver (Ag), indium (In), or the like. 
     Alternatively, the first electrode  11  may have a configuration in which an organic layer doped with a metal is used in an interface between the first electrode  11  and an organic layer as described in, for example, “Japanese Patent Application Publication No. Hei 10-270171” and “Japanese Patent Application Publication No. 2001-102175.” In this case, it is only necessary to use an electrically conductive material as the material of the first electrode  11  and the material is not limited to one with particular properties such as the work function. 
     As another alternative, the first electrode  11  may have a configuration in which an organic layer in contact with the first electrode  11  is made of an organic metal complex compound containing at least one type selected from the group consisting of alkali metal ions, alkaline earth metal ions, and rare-earth metal ions as described in, for example, “Japanese Patent Application Publication No. Hei 11-233262” and “Japanese Patent Application Publication No. 2000-182774.” In this case, a metal capable of reducing the metal ions contained in the organic metal complex compound to metal in vacuum, for example, a metal (with a thermal reduction property) such as aluminum (Al), zirconium (Zr), titanium (Ti), and silicon (Si) or an alloy containing any of these metals can be used as the first electrode  11 . Among these, Al which is generally widely used as a wiring electrode is particularly preferable from the viewpoint of ease of vapor deposition, high light reflectance, chemical stability, and the like. 
     The material of the second electrode  12  is not limited to a particular material. When light is to be extracted from the second electrode  12  side, a transparent, electrically conductive material such as, for example, ITO (Indium Tin Oxide) or IZO (Indium Zinc Oxide) can be used. 
     Moreover, in contrary to a general organic EL element, light can be extracted from the first electrode  11  side by using a metal material or the like for the second electrode  12  and using a transparent, electrically conductive material for the first electrode  11 . For example, by employing the method described in “Japanese Patent Application Publication No. 2002-332567,” the first electrode  11  made of the aforementioned transparent, electrically conductive material such as ITO and IZO can be formed by sputtering which does not damage an organic film. 
     Accordingly, when both of the first electrode  11  and the second electrode  12  are formed to be transparent, since the first light emitting unit  13 A, the second light emitting unit  13 B, the third light emitting unit  13 C, the first charge generating layer  14 A, and the second charge generating layer  14 B are also similarly transparent, it is possible to manufacture a transparent organic EL element  10 . 
     Note that the order of film formation does not have to start from the second electrode  12  side and may start from the first electrode  11  side. 
     The first light emitting unit  13 A is formed of a first electron transport layer  15 A, a first light emitting layer  16 A, and a first hole transport layer  17 A. The second light emitting unit  13 B is formed of a second electron transport layer  15 B, a second light emitting layer  16 B, and a second hole transport layer  17 B. The third light emitting unit  13 C is formed of a third electron transport layer  15 C, a third light emitting layer  16 C, and a third hole transport layer  17 C. 
     The first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C may employ any of various structures similar to those of conventionally-known organic EL elements and may have any laminated structure as long as they include light emitting layers made of at least an organic compound. For example, each of the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C may be configured such that an electron injection layer, a hole blocking layer, and the like are arranged on the first electrode  11  side of the light emitting layer and a hole injection layer, an electron blocking layer, and the like are arranged on the second electrode  12  side of the light emitting layer. 
     The electron transport layers are made of, for example, a conventionally well-known electron transport material. In the organic EL element  10  of the embodiment, an electron transport material with a relatively deep HOMO (Highest Occupied Molecular Orbital) level is preferably used among electron transport materials generally used for organic EL elements. Specifically, an electron transport material with a HOMO level of at least about 6.0 eV is preferably used. For example, 4,7-Diphenyl-1,10-phenanthroline (Bphen), 2,2′,2″-(1,3,5-Benzinetriyl)-tris(1-phenyl-1-H-benzimidazol e) (TPBi), and the like can be used as such an electron transport material. 
     The electron injection layers are provided between the first electrode  11  and the first electron transport layer  15 A and between the first charge generating layer  14 A and the second electron transport layer  15 B to improve injection efficiency of electrons from at least one of the first electrode  11  and the first charge generating layer  14 A. An electron transport material having properties similar to the electron transport layers can be used as the material of the electron injection layers. The electron transport layers and the electron injection layers are sometimes collectively referred to as electron transport layers. 
     The hole transport layers are made of, for example, a conventionally well-known hole transport material. The hole transport material is not limited to a particular material. For example, an organic compound (electron donating material) which has an ionization potential less than 5.7 eV and which has a hole transport property, that is an electron donating property is preferably used as the hole transport material. For example, an arylamine compound such as 4,4′-bis-[N-(2-naphthyl)-N-phenyl-amino]biphenyl (α-NPD) or the like can be used as the electron donating material. 
     The hole injection layers are provided between the second electrode  12  and the second hole transport layer  17 B and between the first charge generating layer  14 A and the first hole transport layer  17 A to improve injection efficiency of holes from at least one of the second electrode  12  and the first charge generating layer  14 A. An electron donating material having properties similar to the hole transport layers can be used as the material of the hole injection layers. The hole transport layers and the hole injection layers are sometimes collectively referred to as hole transport layers. 
     When the first light emitting unit  13 A is the red/green light emitting unit, the light emitting layer included in the first light emitting unit  13 A is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the first light emitting unit  13 A is the red-green light emitting unit, the light emitting layer included in the first light emitting unit  13 A is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the first light emitting unit  13 A, a material with an electron transport property, a material with a hole transport property, a material obtained by mixing these materials, or the like can be used. Specifically, for example, 4,4′-biscarbazolylbiphenyl (CBP), 2,9-dimethyl-4,7-diphenyl-9,10-phenanthroline (BCP), or the like can be used as the host material of the phosphorescent light emitting layer. 
     The guest material of the light emitting layer included in the first light emitting unit  13 A is also referred to as dopant material. The guest material utilizing fluorescent light emission is generally referred to as fluorescent light emitting material. Alight emitting layer made of the fluorescent light emitting material is referred to as fluorescent light emitting layer. Meanwhile, the guest material utilizing phosphorescent light emission is generally referred to as phosphorescent light emitting material. A light emitting layer made of the phosphorescent light emitting material is referred to as phosphorescent light emitting layer. 
     In the phosphorescent light emitting layer out of these layers, it is possible to utilize not only 75% of triplet excitons, which are generated by recombination of electrons and holes, but also 25% of the triplet excitons, which are generated by energy transfer from singlet excitons. Accordingly, an internal quantum efficiency of 100% can be achieved in theory. Specifically, the excitons generated by the recombination of electrons and holes are converted to light in the light emitting layer without thermal quenching or the like. In an organic metal complex including heavy atoms such as iridium or platinum, an internal quantum efficiency close to 100% is actually achieved by optimization of the element structure and the like. 
     The guest material of the phosphorescent light emitting layer is not limited to a particular material. For example, in the red phosphorescent light emitting layer, a red phosphorescent light emitting material such as Ir(piq) 3  and Ir(btpy) 3  can be used. Meanwhile, in the green phosphorescent light emitting layer, a green phosphorescent light emitting such as Ir(ppy) 3  can be used. 
     Each of the blue light emitting layers included in the second light emitting unit  13 B and the third light emitting unit  13 C is formed of a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. Each blue light emitting layer contains a host material which is a main component and a guest material which is a minor component as the organic compound. The blue fluorescent material or the blue phosphorescent material corresponds to the guest material out of these materials. In either case, emission of the blue light is attributable particularly to the properties of the guest material. 
     As the host material of the blue light emitting layers included in the second light emitting unit  13 B and the third light emitting unit  13 C, a material with an electron transport property, a material with a hole transport property, a material obtained by mixing these materials, or the like can be used. In the blue fluorescent light emitting layers, for example, a styryl derivative, an anthracene compound, a pyrene compound, or the like can be used. Meanwhile, in the blue phosphorescent light emitting layer, for example, 4,4′-biscarbazolylbiphenyl (CBP), 2,9-dimethyl-4,7-diphenyl-9,10-phenanthroline (BCP), or the like can be used. 
     As the guest material of the blue light emitting layers included in the second light emitting unit  13 B and the third light emitting unit  13 C, in the blue fluorescent light emitting layer, for example, a styrylamine compound, a fluoranthene compound, an aminopyrene compound, a boron complex, or the like can be used. Moreover, a material such as 4,4′-bis[4-(diphenylamino)styryl]biphenyl (BDAVBi) or 2,7-bis{2-[phenyl (m-tolyl)amino]-9,9-dimethyl-fluoren-7-yl}-9,9-dimethyl-fluorene (MDP3FL) can be used. Meanwhile, in the blue phosphorescent light emitting layer, for example, a blue phosphorescent light emitting material such as Ir(Fppy) 3  can be used. 
     For example, a vacuum deposition method, a spin coating method, or the like can be used as a film forming method of the layers forming the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C. 
     The first charge generating layer  14 A and the second charge generating layer  14 B are each formed of an electrically insulating layer made of an electron accepting material and an electron donating material. The specific resistance of the electrically insulating layer is preferably 1.0×10 2 Ω·cm or more, more preferably 1.0×10 5 Ω·cm or more. 
     Alternatively, the first charge generating layer  14 A and the second charge generating layer  14 B may each be configured such that the charge generating layer is formed of a mixed layer of different materials and one component of the mixed layer forms a charge transfer complex by redox. In this case, when voltage is applied between the first electrode  11  and the second electrode  12 , charges in the charge transfer complex move to the first electrode  11  side and the second electrode  12  side. In the organic EL element  10 , holes are thereby injected into the second light emitting unit  13 B located on the first electrode  11  side of the second charge generating layer  14 B and into the first light emitting unit  13 A located on the first electrode  11  side of the first charge generating layer  14 A. Moreover, in the organic EL element  10 , electrons are injected into the third light emitting unit  13 C located on the second electrode  12  side of the second charge generating layer  14 B and into the second light emitting unit  13 B located on the second electrode  12  side of the first charge generating layer  14 A. Light can be thereby simultaneously emitted from the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C can be obtained. 
     Alternatively, the first charge generating layer  14 A and the second charge generating layer  14 B may each be a laminate of an electron accepting material and an electron donating material. In this case, when voltage is applied between the first electrode  11  and the second electrode  12 , in an interface between the electron accepting material and the electron donating material, charges generated by reaction involving electron transfer between these electron accepting material and electron donating material move to the first electrode  11  side and the second electrode  12  side. In the organic EL element  10 , holes are thereby injected into the second light emitting unit  13 B located on the first electrode  11  side of the second charge generating layer  14 B and into the first light emitting unit  13 A located on the first electrode  11  side of the first charge generating layer  14 A. Moreover, in the organic EL element  10 , electrons are injected into the third light emitting unit  13 C located on the second electrode  12  side of the second charge generating layer  14 B and into the second light emitting unit  13 B located on the second electrode  12  side of the first charge generating layer  14 A. Light can be thereby simultaneously emitted from the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C can be obtained. 
     For example, materials described in Japanese Patent Application Publication No. 2003-272860 can be used as materials forming the first charge generating layer  14 A and the second charge generating layer  14 B. Among these, materials described in paragraphs [0019] to [0021] can be preferably used. Alternatively, materials described in paragraphs [0023] to [0026] of “International Patent Application Publication No. WO2010/113493” can be used as materials forming the first charge generating layer  14 A and the second charge generating layer  14 B. Among these, a strong electron accepting material (HATCN6) described in paragraphs [0059] in particular can be preferably used. When substituent groups represented by R in the structure expressed by the following formula (1) are CN (cyano groups), this compound is HATCN6 described above. 
                         
where R represents an electron withdrawing group of F, Cl, Br, I, CN, or CF 3  (1)
 
       FIG. 2  is a graph depicting an example of an emission spectrum of white light provided by the organic EL element  10  of the embodiment. 
     Specifically, as illustrated in  FIG. 2 , the white light provided by the organic EL element  10  has an emission spectrum S continuous over the wavelength band of at least 380 nm to 780 nm as so-called visible light. 
     The emission spectrum. S has one peak wavelength p 1  in the red wavelength band R of 590 nm to 640 nm, one peak wavelength p 2  in the green wavelength band G of 500 nm to 560 nm, and one peak wavelength p 3  or two peak wavelengths p 3 , p 4  in the blue wavelength band B of 440 nm to 490 nm. 
     The blue light emitted by each blue light emitting layer is an important factor for obtaining white light with high color temperature. Specifically, it is desirable that, as illustrated in  FIG. 2 , the emission spectrum S has the one peak wavelength p 3  or the two peak wavelengths p 3 , p 4  in the blue wavelength band B of 440 nm to 490 nm. 
     The organic EL element  10  of the embodiment can thereby provide white light with high color temperature. Moreover, in a conventional organic EL element, light emission in a low color temperature region such as incandescent lamp color is suitable for achieving highly-efficient light emission and highly-efficient light emission is difficult to achieve in a color temperature equal to or higher than warm white which is higher than the incandescent lamp color. Specifically, the maximum color temperature of the incandescent lamp color (L) is 3250 K in chromaticity ranges specified in “JIS Z 9112” and the organic EL element  10  of the embodiment can emit white light with correlated color temperature of 3300 K or higher with high efficiency. 
     Moreover, it is desirable that the light emission intensities of the peak wavelengths p 3 , p 4  in the blue wavelength band B of 440 nm to 490 nm are higher than either of the light emission intensity of the peak wavelength p 1  in the red wavelength band R of 590 to 640 nm and the light emission intensity of the peak wavelength p 2  in the green wavelength band G of 500 nm to 560 nm. 
     This can further increase the color temperature of the white light in the organic EL element  10  of the embodiment. The organic EL element  10  of the embodiment can provide white light with correlated color temperature of 5000 K or higher. 
     Moreover, the position wavelength of the peak wavelength in the green wavelength band of 500 nm to 560 nm is an important factor for obtaining white light with high luminous efficiency. Specifically, as illustrated in  FIG. 2 , the emission spectrum S desirably has the peak wavelength p 2  around 540 nm in the green wavelength band G of 500 nm to 560 nm. 
     The organic EL element  10  of the embodiment can thereby provide white light with a high luminous efficiency. The organic EL element  10  of the embodiment can provide white light with an external quantum efficiency of 20% or more. 
     Note that, when the position of the peak wavelength p 2  is on the shorter wavelength side of 540 nm, the luminous efficiency of the white light decreases together with a decrease in luminosity function. Meanwhile, when the position of the peak wavelength p 2  is on the longer wavelength side of 540 nm, an amount of a green component of 550 nm to 600 nm increases and a light emission ratio of a pure green component on the short wavelength side thereby decreases. As a result, the color rendering property becomes poor. 
     Moreover, it is desirable that, as illustrated in  FIG. 2 , the light emission intensity of the peak wavelength p 2  in the green wavelength band G of 500 nm to 560 nm is lower than the light emission intensity of the peak wavelength p 1  in the red wavelength band R of 590 to 640 nm and the light emission intensities of the peak wavelengths p 3 , p 4  in the blue wavelength band B of 440 nm to 490 nm. 
     The organic EL element  10  of the embodiment can be thereby further improved in the luminous efficiency of the white light. The organic EL element  10  of the embodiment can provide white light with an external quantum efficiency of 30% or more. 
     Note that, when the light emission intensity of the peak wavelength p 2  in the green wavelength band G of 500 nm to 560 nm is increased relative to the light emission intensity of the peak wavelength p 1  in the red wavelength band R of 590 to 640 nm and the light emission intensities of the peak wavelengths p 3 , p 4  in the blue wavelength band B of 440 nm to 490 nm, the light emission intensity of a blue component relatively decreases and the color temperature thereby decreases. 
     Moreover, presence of a bottom wavelength in a wavelength band of 550 nm to 600 nm is an important factor for obtaining white light with an excellent color rendering property. Specifically, as illustrated in  FIG. 2 , the emission spectrum S desirably has one bottom wavelength b 1  in the wavelength band of 550 nm to 600 nm. 
     The organic EL element  10  of the embodiment can thereby provide white light with an excellent color rendering property. The organic EL element  10  of the embodiment can provide white light in which the average color rendering index (Ra) is 70 or more and R6 and R12 among the special color rendering indices (Ri) are 60 or more and 30 or more, respectively. 
     Table 1 and  FIGS. 3 and 4  depict results of simulation verifying the effects on R6 and R12 in a white element. 
     This simulation was performed such that the green and red light emission intensities were fixed to 1.0 in a three (blue, green, and red)-wavelength white element and numerical values were standardized by dividing the spectral intensity of the white light by the red peak wavelength intensity, the white light obtained with the light emission intensity of the blue spectrum set to a certain ratio. Moreover, various characteristic values were calculated with the light emission intensity of the blue spectrum varied at a certain ratio. The green and red light emission intensities were fixed to 1.0 to quantitatively evaluate the effects of the blue light emission on R6 and R12. 
     
       
         
           
               
               
             
               
                   
                 TABLE 1 
               
             
            
               
                   
                   
               
               
                   
                 Spectrum No. 
               
            
           
           
               
               
               
               
               
               
               
               
               
               
            
               
                   
                 1 
                 2 
                 3 
                 4 
                 5 
                 6 
                 7 
                 8 
                 9 
               
               
                   
                   
               
            
           
           
               
               
               
               
               
               
               
               
               
               
            
               
                 Blue (450 nm) light 
                 0.120 
                 0.237 
                 0.355 
                 0.472 
                 0.589 
                 0.763 
                 0.936 
                 1.108 
                 1.280 
               
               
                 emission intensity 
               
               
                 CCT (K) 
                 — 
                 — 
                 3630 
                 3860 
                 4100 
                 4530 
                 5000 
                 5520 
                 6140 
               
               
                 Deviation duv 
                 0.0247 
                 0.0202 
                 0.0166 
                 0.0134 
                 0.0107 
                 0.0075 
                 0.0053 
                 0.0037 
                 0.0032 
               
               
                 Ra 
                 61 
                 64 
                 68 
                 71 
                 73 
                 77 
                 80 
                 83 
                 85 
               
               
                 R6 
                 54 
                 61 
                 67 
                 72 
                 76 
                 82 
                 87 
                 91 
                 93 
               
               
                 R12 
                 6 
                 18 
                 29 
                 38 
                 46 
                 54 
                 60 
                 70 
                 72 
               
               
                   
               
            
           
         
       
     
     “Blue (450 nm) light emission intensity” in Table 1 refers to the light emission intensity at 450 nm which is the peak wavelength in the blue spectrum. 
       FIG. 3  illustrates white spectra calculated by simulation performed with the intensity of the blue spectrum varied. 
     The blue spectrum, the green spectrum, and the red spectrum used in the simulation have the same wavelengths and waveforms as those of the emission spectrum of Example 1 to be described later. 
     It is found from Table 1 and  FIG. 4  that the higher the blue light emission intensity is, the greater the values of Ra, R6, and R12 are. 
     In the spectrum No. 1 in which R6 is lower than 60, the value of the deviation duv is 0.02 or higher. Accordingly, the spectrum No. 1 has light emission color to which the definition of correlated color temperature cannot be applied. 
     In each of the spectrum No. 2 and the spectrum No. 3, although R6 is 60 or higher, the value of R12 is below 30 and the value of the deviation duv is thus high. The spectrum No. 2 has light emission color to which the definition of correlated color temperature cannot be applied like the spectrum No. 1. Moreover, the spectrum No. 3 also greatly deviates from the black body radiation and emission of white light with good color cannot be achieved. 
     Meanwhile, in the spectra No. 4 to No. 9 which satisfy the conditions of R6 being 60 or more and R12 being 30 or more, emission of white light with a low value of deviation duv and an excellent color rendering property can be achieved. The deviation duv is preferably within a range of −0.015 to +0.015, more preferably within a range of −0.01 to +0.01. 
     Moreover, in the spectra No. 7 to No. 9 in which the value of R12 is 60 or more, light emission with higher color temperature and a better color rendering property than those in No. 4 to No. 6 is achieved and the values of the deviation duv are also small. Accordingly, emission of white light with an excellent color rendering property and high color temperature in particular are achieved. 
     Moreover, Table 2 and  FIGS. 5 and 6  depict results of simulation verifying effects on R6 and R12 in a white element. 
     This simulation was performed such that the blue and red light emission intensities were fixed to 1.0 in a three (blue, green, and red)-wavelength white element and numerical values were standardized by dividing the spectral intensity of the white light by the blue peak wavelength intensity, the white light obtained with the light emission intensity of the green spectrum set to a certain ratio. Moreover, various characteristic values were calculated with the light emission intensity of the blue spectrum varied at a certain ratio. The blue and red light emission intensities were fixed to 1.0 to quantitatively evaluate the effects of green light emission on R6 and R12. 
     Moreover, in  FIG. 5 , when the light emission intensity of the green spectrum is changed, the intensity of the red spectrum is also changed. This is because the peak wavelengths in the green spectrum and the red spectrum are close to each other and the light emission intensity in a tail portion of the green spectrum affects the light emission intensity of the red spectrum. 
     As illustrated in the spectrum. No. 5 of  FIG. 5 , the light emission intensity of the peak wavelength in the green wavelength band of 500 nm to 560 nm is lower than the light emission intensity of the peak wavelength in the blue wavelength band of 440 nm to 490 nm and the light emission intensity of the peak wavelength in the red wavelength band of 590 nm to 640 nm. 
     Moreover, as illustrated in the spectrum No. 5 of  FIG. 5 , the ratio of the light emission intensity of the peak wavelength in the green wavelength band of 500 nm to 560 nm to the light emission intensity of the peak wavelength in the red wavelength band of 590 nm to 640 nm is 0.9 or less. 
     
       
         
           
               
               
             
               
                   
                 TABLE 2 
               
             
            
               
                   
                   
               
               
                   
                 Spectrum No. 
               
            
           
           
               
               
               
               
               
               
            
               
                   
                 1 
                 2 
                 3 
                 4 
                 5 
               
               
                   
                   
               
            
           
           
               
               
               
               
               
               
            
               
                 Green 
                 1.180 
                 1.136 
                 1.037 
                 0.993 
                 0.934 
               
               
                 (544 nm) 
               
               
                 light 
               
               
                 emission 
               
               
                 intensity 
               
               
                 CCT (K) 
                 4650 
                 4750 
                 4850 
                 4930 
                 5020 
               
               
                 duv 
                 0.0122 
                 0.008 
                 0.0023 
                 −0.0001 
                 −0.0034 
               
               
                 Ra 
                 77 
                 81 
                 86 
                 88 
                 90 
               
               
                 R6 
                 78 
                 84 
                 91 
                 93 
                 93 
               
               
                 R12 
                 48 
                 56 
                 65 
                 69 
                 78 
               
               
                   
               
            
           
         
       
     
     “Green (544 nm) light emission intensity” in table 2 refers to the light emission intensity at 544 nm which is the peak wavelength in the green spectrum. 
       FIG. 5  illustrates white spectra calculated by simulation performed with the intensity of the blue spectrum varied. 
     The blue spectrum, the green spectrum, and the red spectrum used in the simulation have the same wavelengths and waveforms as those of the emission spectrum of Example 1 to be described later. 
     It is found from Table 2 and  FIG. 6  that the lower the green light emission intensity is, the greater the values of Ra, R6, and R12 are. Accordingly, it is found that the color rendering property can be improved by reducing the green light emission intensity in addition to the method of increasing the light emission intensity of the blue spectrum described in [0052] to [0056]. 
     Moreover, in the organic EL element  10  of the embodiment, as illustrated in  FIG. 2 , the emission spectrum. S desirably has one bottom wavelength b 2  between the two peak wavelengths p 2 , p 3  adjacent to each other in the blue wavelength band B and the green wavelength band G of 500 nm to 520 nm. 
     The luminous efficiency and the color rendering property of the white light can be thereby optimized at the same time by preferably controlling the ratio between the light emission intensities of the peak wavelengths p 2 , p 3 . 
     Moreover, in the organic EL element  10  of the embodiment, as illustrated in  FIG. 2 , the light emission intensity of the one bottom wavelength b 2  in the blue wavelength band B and the green wavelength band G of 500 nm to 520 nm is preferably lower than the light emission intensities of the bottom wavelengths b 1 , b 3  in the wavelength band (green wavelength band G or red wavelength band R) of 570 nm to 590 nm. 
     The color temperature of the white light can be thereby optimized by appropriately controlling the light emission intensity ratio between peak wavelengths p 1  and p 2  forming the bottom wavelength b 1  and the light emission intensity ratio between the peak wavelengths p 3  and p 4  forming the bottom wavelength b 3 . 
     Moreover, in the organic EL element  10  of the embodiment, as illustrated in  FIG. 2 , a ratio of (B) to (A) ((B)/(A)) is preferably 0.50 or smaller, where (A) is the light emission intensity of the peak wavelength having the highest light emission intensity (peak wavelength p 1  in  FIG. 2 ) and (B) is the light emission intensity of the one bottom wavelength b 1  in the blue wavelength band B and the green wavelength band G of 500 nm to 520 nm. 
     The color temperature and the color rendering property of the white light can be thereby optimized at the same time. 
     As described above, the organic EL element  10  of the embodiment can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property. Moreover, since the organic EL element  10  of the embodiment has the MPE structure in which the first light emitting unit  13 A, the second light emitting unit  13 B, and the third light emitting unit  13 C are stacked one on top of another with each of the first charge generating layer  14 A and the second charge generating layer  14 B sandwiched between the corresponding pair of adjacent light emitting units, the organic EL element  10  can provide the white light while achieving high-luminance light emission and long-life driving. 
     The organic EL element  10  of the embodiment can be thus preferably used in both of a display device and a lighting device. 
     Second Embodiment 
       FIG. 7  is a cross-sectional view illustrating a schematic configuration of a second embodiment of the organic EL element in the present invention. 
     As illustrated in  FIG. 7 , the organic EL element  20  of the embodiment has a structure in which multiple light emitting units  23 A,  23 B,  23 C each including a light emitting layer made of at least an organic compound are stacked one on top of another between a first electrode  21  and a second electrode  22  with each of charge generating layers (CGL)  24 A,  24 B sandwiched between a corresponding pair of the adjacent light emitting units. The organic EL element  20  is an organic EL element capable of providing white light by causing the multiple light emitting units  23 A,  23 B,  23 C to emit light. 
     The organic EL element  20  of the embodiment includes the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C. 
     The first light emitting unit  23 A is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in the blue wavelength band. The blue light emitting layer may be a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The second light emitting unit  23 B is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The third light emitting unit  23 C is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in a blue wavelength band. The blue light emitting layer may be a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The first light emitting unit  23 A and the second light emitting unit  23 B are stacked one on top of the other with the first charge generating layer  24 A sandwiched therebetween. 
     The second light emitting unit  23 B and the third light emitting unit  23 C are stacked one on top of the other with the second charge generating layer  24 B sandwiched therebetween. 
     The organic EL element  20  of the embodiment has a structure in which the second electrode  22 , the third light emitting unit  23 C, the second charge generating layer  24 B, the second light emitting unit  23 B, the first charge generating layer  24 A, the first light emitting unit  23 A, and the first electrode  21  are stacked one on top of another in this order. Specifically, the organic EL element  20  of the embodiment has an MPE structure in which the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C are stacked one on top of another with each of the first charge generating layer  24 A and the second charge generating layer  24 B sandwiched between the corresponding pair of adjacent light emitting units. 
     In the organic EL element  20  of the embodiment, the white light produced by light emission of the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C has an emission spectrum continuous over a wavelength band of at least 380 nm to 780 nm. Moreover, in the organic EL element  20  of the embodiment, the white light has one or two peak wavelengths in the blue wavelength band of 440 nm to 490 nm in this emission spectrum. Furthermore, in the organic EL element  20  of the embodiment, the white light has one peak wavelength in the red wavelength band of 590 nm to 640 nm and one or two peak wavelengths in the green wavelength band of 500 nm to 560 nm in this emission spectrum. 
     The same electrode as the first electrode  11  in the aforementioned first embodiment can be used as the first electrode  21 . 
     The same electrode as the second electrode  12  in the aforementioned first embodiment can be used as the second electrode  22 . 
     The first light emitting unit  23 A is formed of a first electron transport layer  25 A, a first light emitting layer  26 A, and a first hole transport layer  27 A. The second light emitting unit  23 B is formed of a second electron transport layer  25 B, a second light emitting layer  26 B, and a second hole transport layer  27 B. The third light emitting unit  23 C is formed of a third electron transport layer  25 C, a third light emitting layer  26 C, and a third hole transport layer  27 C. 
     The first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C may employ any of various structures similar to those of conventionally-known organic EL elements and may have any laminated structure as long as they include light emitting layers made of at least an organic compound. For example, each of the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C may be configured such that an electron injection layer, a hole blocking layer, and the like are arranged on the first electrode  21  side of the light emitting layer and a hole injection layer, an electron blocking layer, and the like are arranged on the second electrode  22  side of the light emitting layer. 
     The electron transport layers have the same configuration as that of the electron transport layers in the aforementioned first embodiment. 
     The hole transport layers have the same configuration as that of the hole transport layers in the aforementioned first embodiment. 
     Each of the blue light emitting layers included in the first light emitting unit  23 A and the third light emitting unit  23 C is formed of a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. Each blue light emitting layer contains a host material which is a main component and a guest material which is a minor component as the organic compound. The blue fluorescent material or the blue phosphorescent material corresponds to the guest material out of these materials. In either case, emission of the blue light is attributable particularly to the properties of the guest material. 
     As the host material of the blue light emitting layers included in the first light emitting unit  23 A and the third light emitting unit  23 C, the same material as the host material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     As the guest material of the blue light emitting layers included in the first light emitting unit  23 A and the third light emitting unit  23 C, the same material as the guest material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     When the second light emitting unit  23 B is the red/green light emitting unit, the light emitting layer included in the second light emitting unit  23 B is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the second light emitting unit  23 B is the red-green light emitting unit, the light emitting layer included in the second light emitting unit  23 B is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the second light emitting unit  23 B, the same material as the host material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     As the guest material of the light emitting layer included in the second light emitting unit  23 B, the same material as the guest material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     For example, a vacuum deposition method, a spin coating method, or the like can be used as a film forming method of the layers forming the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C. 
     The first charge generating layer  24 A and the second charge generating layer  24 B are each formed of an electrically insulating layer made of an electron accepting material and an electron donating material. The specific resistance of the electrically insulating layer is preferably 1.0×10 2 Ω·cm or more, more preferably 1.0×10 5 Ω·cm or more. 
     Alternatively, the first charge generating layer  24 A and the second charge generating layer  24 B may each be configured such that the charge generating layer is formed of a mixed layer of different materials and one component of the mixed layer forms a charge transfer complex by redox. In this case, when voltage is applied between the first electrode  21  and the second electrode  22 , charges in the charge transfer complex move to the first electrode  21  side and the second electrode  22  side. In the organic EL element  20 , holes are thereby injected into the second light emitting unit  23 B located on the first electrode  21  side of the second charge generating layer  24 B and into the first light emitting unit  23 A located on the first electrode  21  side of the first charge generating layer  24 A. Moreover, in the organic EL element  20 , electrons are injected into the third light emitting unit  23 C located on the second electrode  22  side of the second charge generating layer  24 B and into the second light emitting unit  23 B located on the second electrode  22  side of the first charge generating layer  24 A. Light can be thereby simultaneously emitted from the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C can be obtained. 
     Alternatively, the first charge generating layer  24 A and the second charge generating layer  24 B may each be a laminate of an electron accepting material and an electron donating material. In this case, when voltage is applied between the first electrode  21  and the second electrode  22 , in an interface between the electron accepting material and the electron donating material, charges generated by reaction involving electron transfer between these electron accepting material and electron donating material move to the first electrode  21  side and the second electrode  22  side. In the organic EL element  20 , holes are thereby injected into the second light emitting unit  23 B located on the first electrode  21  side of the second charge generating layer  24 B and into the first light emitting unit  23 A located on the first electrode  21  side of the first charge generating layer  24 A. Moreover, in the organic EL element  20 , electrons are injected into the third light emitting unit  23 C located on the second electrode  22  side of the second charge generating layer  24 B and into the second light emitting unit  23 B located on the second electrode  22  side of the first charge generating layer  24 A. Light can be thereby simultaneously emitted from the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C can be obtained. 
     As materials forming the first charge generating layer  24 A and the second charge generating layer  24 B, the same materials as the materials forming the first charge generating layer  14 A and the second charge generating layer  14 B in the aforementioned first embodiment can be used. 
     The organic EL element  20  having the structure described above can provide white light by causing the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C to emit light. 
     Moreover, the organic EL element  20  of the embodiment can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property as in the organic EL element  10  in the aforementioned first embodiment. Moreover, the organic EL element  20  of the embodiment has the MPE structure in which the first light emitting unit  23 A, the second light emitting unit  23 B, and the third light emitting unit  23 C are stacked one on top of another with each of the first charge generating layer  24 A and the second charge generating layer  24 B sandwiched between the corresponding pair of adjacent light emitting units. Accordingly, the organic EL element  20  can provide the white light while achieving high-luminance light emission and long-life driving. 
     The organic EL element  20  of the embodiment can be thus preferably used in both of a display device and a lighting device. 
     Third Embodiment 
       FIG. 8  is a cross-sectional view illustrating a schematic configuration of a third embodiment of the organic EL element in the present invention. 
     As illustrated in  FIG. 8 , the organic EL element  30  of the embodiment has a structure in which multiple light emitting units  33 A,  33 B,  33 C,  33 D each including a light emitting layer made of at least an organic compound are stacked one on top of another between a first electrode  31  and a second electrode  32  with each of charge generating layers (CGL)  34 A,  34 B,  34 C sandwiched between a corresponding pair of the adjacent light emitting units. The organic EL element  30  is an organic EL element capable of providing white light by causing the multiple light emitting units  33 A,  33 B,  33 C,  33 D to emit light. 
     The organic EL element  30  of the embodiment includes the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D. 
     The first light emitting unit  33 A is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The second light emitting unit  33 B is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in the blue wavelength band. The blue light emitting layer may be a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The third light emitting unit  33 C is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The fourth light emitting unit  33 D is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in the blue wavelength band. The blue light emitting layer may be a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The first light emitting unit  33 A and the second light emitting unit  33 B are stacked one on top of the other with the first charge generating layer  34 A sandwiched therebetween. 
     The second light emitting unit  33 B and the third light emitting unit  33 C are stacked one on top of the other with the second charge generating layer  34 B sandwiched therebetween. 
     The third light emitting unit  33 C and the fourth light emitting unit  33 D are stacked one on top of the other with the third charge generating layer  34 C sandwiched therebetween. 
     The organic EL element  30  of the embodiment has a structure in which the second electrode  32 , the fourth light emitting unit  33 D, the third charge generating layer  34 C, the third light emitting unit  33 C, the second charge generating layer  34 B, the second light emitting unit  33 B, the first charge generating layer  34 A, the first light emitting unit  33 A, and the first electrode  31  are stacked one on top of another in this order. Specifically, the organic EL element  30  of the embodiment has an MPE structure in which the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D are stacked one on top of another with each of the first charge generating layer  34 A, the second charge generating layer  34 B, and the third charge generating layer  34 C sandwiched between the corresponding pair of adjacent light emitting units. 
     In the organic EL element  30  of the embodiment, the white light produced by light emission of the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D has an emission spectrum continuous over a wavelength band of at least 380 nm to 780 nm. Moreover, in the organic EL element  30  of the embodiment, the white light has one or two peak wavelengths in the blue wavelength band of 440 nm to 490 nm in this emission spectrum. Furthermore, in the organic EL element  30  of the embodiment, the white light has one peak wavelength in the red wavelength band of 590 nm to 640 nm and one or two peak wavelengths in the green wavelength band of 500 nm to 560 nm in this emission spectrum. 
     The same electrode as the first electrode  11  in the aforementioned first embodiment can be used as the first electrode  31 . 
     The same electrode as the second electrode  12  in the aforementioned first embodiment can be used as the second electrode  32 . 
     The first light emitting unit  33 A is formed of a first electron transport layer  35 A, a first light emitting layer  36 A, and a first hole transport layer  37 A. The second light emitting unit  33 B is formed of a second electron transport layer  35 B, a second light emitting layer  36 B, and a second hole transport layer  37 B. The third light emitting unit  33 C is formed of a third electron transport layer  35 C, a third light emitting layer  36 C, and a third hole transport layer  37 C. The fourth light emitting unit  33 D is formed of a fourth electron transport layer  35 D, a fourth light emitting layer  36 D, and a fourth hole transport layer  37 D. 
     The first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D may employ any of various structures similar to those of conventionally-known organic EL elements and may have any laminated structure as long as they include light emitting layers made of at least an organic compound. For example, each of the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D may be configured such that an electron injection layer, a hole blocking layer, and the like are arranged on the first electrode  31  side of the light emitting layer and a hole injection layer, an electron blocking layer, and the like are arranged on the second electrode  32  side of the light emitting layer. 
     The electron transport layers have the same configuration as that of the electron transport layers in the aforementioned first embodiment. 
     The hole transport layers have the same configuration as that of the hole transport layers in the aforementioned first embodiment. 
     When the first light emitting unit  33 A is the red/green light emitting unit, the light emitting layer included in the first light emitting unit  33 A is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the first light emitting unit  33 A is the red-green light emitting unit, the light emitting layer included in the first light emitting unit  33 A is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the first light emitting unit  33 A, the same material as the host material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     As the guest material of the light emitting layer included in the first light emitting unit  33 A, the same material as the guest material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     The blue light emitting layer included in the second light emitting unit  33 B is formed of a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light emitting layer contains a host material which is a main component and a guest material which is a minor component as the organic compound. The blue fluorescent material or the blue phosphorescent material corresponds to the guest material out of these materials. In either case, emission of the blue light is attributable particularly to the properties of the guest material. 
     As the host material of the blue light emitting layer included in the second light emitting unit  33 B, the same material as the host material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     As the guest material of the blue light emitting layer included in the second light emitting unit  33 B, the same material as the guest material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     When the third light emitting unit  33 C is the red/green light emitting unit, the light emitting layer included in the third light emitting unit  33 C is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the third light emitting unit  33 C is the red-green light emitting unit, the light emitting layer included in the third light emitting unit  33 C is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the third light emitting unit  33 C, the same material as the host material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     As the guest material of the light emitting layer included in the third light emitting unit  33 C, the same material as the guest material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     The blue light emitting layer included in the fourth light emitting unit  33 D is formed of a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light emitting layer contains a host material which is a main component and a guest material which is a minor component as the organic compound. The blue fluorescent material or the blue phosphorescent material corresponds to the guest material out of these materials. In either case, emission of the blue light is attributable particularly to the properties of the guest material. 
     As the host material of the blue light emitting layer included in the fourth light emitting unit  33 D, the same material as the host material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     As the guest material of the blue light emitting layer included in the fourth light emitting unit  33 D, the same material as the guest material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     For example, a vacuum deposition method, a spin coating method, or the like can be used as a film forming method of the layers forming the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D. 
     The first charge generating layer  34 A, the second charge generating layer  34 B, and the third charge generating layer  34 C are each formed of an electrically insulating layer made of an electron accepting material and an electron donating material. The specific resistance of the electrically insulating layer is preferably 1.0×10 2 Ω·cm or more, more preferably 1.0×10 5 Ω·cm or more. 
     Alternatively, the first charge generating layer  34 A, the second charge generating layer  34 B, and the third charge generating layer  34 C may each be configured such that the charge generating layer is formed of a mixed layer of different materials and one component of the mixed layer forms a charge transfer complex by redox. In this case, when voltage is applied between the first electrode  31  and the second electrode  32 , charges in the charge transfer complex move to the first electrode  31  side and the second electrode  32  side. Holes are thereby injected into the third light emitting unit  33 C located on the first electrode  31  side of the third charge generating layer  34 C, the second light emitting unit  33 B located on the first electrode  31  side of the second charge generating layer  34 B, and the first light emitting unit  33 A located on the first electrode  31  side of the first charge generating layer  34 A. Moreover, electrons are injected into the fourth light emitting unit  33 D located on the second electrode  32  side of the third charge generating layer  34 C, the third light emitting unit  33 C located on the second electrode  32  side of the second charge generating layer  34 B, and the second light emitting unit  33 B located on the second electrode  32  side of the first charge generating layer  34 A. Light can be thereby simultaneously emitted from the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D can be obtained. 
     Alternatively, the first charge generating layer  34 A, the second charge generating layer  34 B, and the third charge generating layer  34 C may each be a laminate of an electron accepting material and an electron donating material. In this case, when voltage is applied between the first electrode  31  and the second electrode  32 , in an interface between the electron accepting material and the electron donating material, charges generated by reaction involving electron transfer between these electron accepting material and electron donating material move to the first electrode  31  side and the second electrode  32  side. In the organic EL element  30 , holes are thereby injected into the third light emitting unit  33 C located on the first electrode  31  side of the third charge generating layer  34 C, the second light emitting unit  33 B located on the first electrode  31  side of the second charge generating layer  34 B, and the first light emitting unit  33 A located on the first electrode  31  side of the first charge generating layer  34 A. Moreover, in the organic EL element  30 , electrons are injected into the fourth light emitting unit  33 D located on the second electrode  32  side of the third charge generating layer  34 C, the third light emitting unit  33 C located on the second electrode  32  side of the second charge generating layer  34 B, and the second light emitting unit  33 B located on the second electrode  32  side of the first charge generating layer  34 A. Light can be thereby simultaneously emitted from the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D can be obtained. 
     As materials forming the first charge generating layer  34 A, the second charge generating layer  34 B, and the third charge generating layer  34 C, the same materials as the materials forming the first charge generating layer  14 A and the second charge generating layer  14 B in the aforementioned first embodiment can be used. 
     The organic EL element  30  having the structure described above can provide white light by causing the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D to emit light. 
     Moreover, the organic EL element  30  of the embodiment can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property as in the organic EL element  10  in the aforementioned first embodiment. Moreover, the organic EL element  30  of the embodiment has the MPE structure in which the first light emitting unit  33 A, the second light emitting unit  33 B, the third light emitting unit  33 C, and the fourth light emitting unit  33 D are stacked one on top of another with each of the first charge generating layer  34 A, the second charge generating layer  34 B, and the third charge generating layer  34 C sandwiched between the corresponding pair of adjacent light emitting units. Accordingly, the organic EL element  30  can provide the white light while achieving high-luminance light emission and long-life driving. 
     The organic EL element  30  of the embodiment can be thus preferably used in both of a display device and a lighting device. 
     Fourth Embodiment 
       FIG. 9  is a cross-sectional view illustrating a schematic configuration of a fourth embodiment of the organic EL element in the present invention. 
     As illustrated in  FIG. 9 , the organic EL element  40  of the embodiment has a structure in which multiple light emitting units  43 A,  43 B,  43 C,  43 D,  43 E,  43 F each including a light emitting layer made of at least an organic compound are stacked one on top of another between a first electrode  41  and a second electrode  42  with each of charge generating layers (CGL)  44 A,  44 B,  44 C,  44 D,  44 E sandwiched between a corresponding pair of the adjacent light emitting units. The organic EL element  40  is an organic EL element capable of providing white light by causing the multiple light emitting units  43 A,  43 B,  43 C,  43 D,  43 E,  43 F to emit light. 
     The organic EL element  40  of the embodiment includes the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F. 
     The first light emitting unit  43 A is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The second light emitting unit  43 B is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in the blue wavelength band. The blue light emitting layer may be a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The third light emitting unit  43 C is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The fourth light emitting unit  43 D is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The fifth light emitting unit  43 E is a blue light emitting unit. The blue light emitting unit includes a light emitting layer formed of a blue light emitting layer which emits blue light with one or two peak wavelengths in the blue wavelength band. The blue light emitting layer may be a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light provided by the blue light emitting unit including the blue fluorescent light emitting layer may include a delayed fluorescence component. 
     The sixth light emitting unit  43 F is a red/green light emitting unit or a red-green light emitting unit. The red/green light emitting unit includes a light emitting layer formed of a red phosphorescent light emitting layer which emits red light with one peak wavelength in a red wavelength band and a green phosphorescent light emitting layer which emits green light with one or two peak wavelengths in a green wavelength band. Specifically, the red/green light emitting unit is a layer formed by stacking the red phosphorescent light emitting layer and the green phosphorescent light emitting layer one on top of the other. The red-green light emitting unit includes alight emitting layer formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. Specifically, the red-green light emitting unit is one layer (single layer) containing the red phosphorescent material and the green phosphorescent material. 
     The first light emitting unit  43 A and the second light emitting unit  43 B are stacked one on top of the other with the first charge generating layer  44 A sandwiched therebetween. 
     The second light emitting unit  43 B and the third light emitting unit  43 C are stacked one on top of the other with the second charge generating layer  44 B sandwiched therebetween. 
     The third light emitting unit  43 C and the fourth light emitting unit  43 D are stacked one on top of the other with the third charge generating layer  44 C sandwiched therebetween. 
     The fourth light emitting unit  43 D and the fifth light emitting unit  43 E are stacked one on top of the other with the fourth charge generating layer  44 D sandwiched therebetween. 
     The fifth light emitting unit  43 E and the sixth light emitting unit  43 F are stacked one on top of the other with the fifth charge generating layer  44 E sandwiched therebetween. 
     The organic EL element  40  of the embodiment has a structure in which the second electrode  42 , the sixth light emitting unit  43 F, the fifth charge generating layer  44 E, the fifth light emitting unit  43 E, the fourth charge generating layer  44 D, the fourth light emitting unit  43 D, the third charge generating layer  44 C, the third light emitting unit  43 C, the second charge generating layer  44 B, the second light emitting unit  43 B, the first charge generating layer  44 A, the first light emitting unit  43 A, and the first electrode  41  are stacked one on top of another in this order. Specifically, the organic EL element  40  of the embodiment has an MPE structure in which the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F are stacked one on top of another with each of the first charge generating layer  44 A, the second charge generating layer  44 B, the third charge generating layer  44 C, the fourth charge generating layer  44 D, and the fifth charge generating layer  44 E sandwiched between the corresponding pair of adjacent light emitting units. 
     In the organic EL element  40  of the embodiment, the white light produced by light emission of the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F has an emission spectrum continuous over a wavelength band of at least 380 nm to 780 nm. Moreover, in the organic EL element  40  of the embodiment, the white light has one or two peak wavelengths in the blue wavelength band of 440 nm to 490 nm in this emission spectrum. Furthermore, in the organic EL element  40  of the embodiment, the white light has one peak wavelength in the red wavelength band of 590 nm to 640 nm and one or two peak wavelengths in the green wavelength band of 500 nm to 560 nm in this emission spectrum. 
     The same electrode as the first electrode  11  in the aforementioned first embodiment can be used as the first electrode  41 . 
     The same electrode as the second electrode  12  in the aforementioned first embodiment can be used as the second electrode  42 . 
     The first light emitting unit  43 A is formed of a first electron transport layer  45 A, a first light emitting layer  46 A, and a first hole transport layer  47 A. The second light emitting unit  43 B is formed of a second electron transport layer  45 B, a second light emitting layer  46 B, and a second hole transport layer  47 B. The third light emitting unit  43 C is formed of a third electron transport layer  45 C, a third light emitting layer  46 C, and a third hole transport layer  47 C. The fourth light emitting unit  43 D is formed of a fourth electron transport layer  45 D, a fourth light emitting layer  46 D, and a fourth hole transport layer  47 D. The fifth light emitting unit  43 E is formed of a fifth electron transport layer  45 E, a fifth light emitting layer  46 E, and a fifth hole transport layer  47 E. The sixth light emitting unit  43 F is formed of a sixth electron transport layer  45 F, a sixth light emitting layer  46 F, and a sixth hole transport layer  47 F. 
     The first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F may employ any of various structures similar to those of conventionally-known organic EL elements and may have any laminated structure as long as they include light emitting layers made of at least an organic compound. For example, each of the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F may be configured such that an electron injection layer, a hole blocking layer, and the like are arranged on the first electrode  41  side of the light emitting layer and a hole injection layer, an electron blocking layer, and the like are arranged on the second electrode  42  side of the light emitting layer. 
     The electron transport layers have the same configuration as that of the electron transport layers in the aforementioned first embodiment. 
     The hole transport layers have the same configuration as that of the hole transport layers in the aforementioned first embodiment. 
     When the first light emitting unit  43 A is the red/green light emitting unit, the light emitting layer included in the first light emitting unit  43 A is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the first light emitting unit  43 A is the red-green light emitting unit, the light emitting layer included in the first light emitting unit  43 A is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the first light emitting unit  43 A, the same material as the host material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     As the guest material of the light emitting layer included in the first light emitting unit  43 A, the same material as the guest material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     The blue light emitting layer included in the second light emitting unit  43 B is formed of a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light emitting layer contains a host material which is a main component and a guest material which is a minor component as the organic compound. The blue fluorescent material or the blue phosphorescent material corresponds to the guest material out of these materials. In either case, emission of the blue light is attributable particularly to the properties of the guest material. 
     As the host material of the blue light emitting layer included in the second light emitting unit  43 B, the same material as the host material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     As the guest material of the blue light emitting layer included in the second light emitting unit  43 B, the same material as the guest material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     When the third light emitting unit  43 C is the red/green light emitting unit, the light emitting layer included in the third light emitting unit  43 C is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the third light emitting unit  43 C is the red-green light emitting unit, the light emitting layer included in the third light emitting unit  43 C is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the third light emitting unit  43 C, the same material as the host material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     As the guest material of the light emitting layer included in the third light emitting unit  43 C, the same material as the guest material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     When the fourth light emitting unit  43 D is the red/green light emitting unit, the light emitting layer included in the fourth light emitting unit  43 D is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the fourth light emitting unit  43 D is the red-green light emitting unit, the light emitting layer included in the fourth light emitting unit  43 D is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the fourth light emitting unit  43 D, the same material as the host material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     As the guest material of the light emitting layer included in the fourth light emitting unit  43 D, the same material as the guest material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     The blue light emitting layer included in the fifth light emitting unit  43 E is formed of a blue fluorescent light emitting layer containing a blue fluorescent material or a blue phosphorescent light emitting layer containing a blue phosphorescent material. The blue light emitting layer contains a host material which is a main component and a guest material which is a minor component as the organic compound. The blue fluorescent material or the blue phosphorescent material corresponds to the guest material out of these materials. In either case, emission of the blue light is attributable particularly to the properties of the guest material. 
     As the host material of the blue light emitting layer included in the fifth light emitting unit  43 E, the same material as the host material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     As the guest material of the blue light emitting layer included in the fifth light emitting unit  43 E, the same material as the guest material of the blue light emitting layers in the aforementioned first embodiment can be used. 
     When the sixth light emitting unit  43 F is the red/green light emitting unit, the light emitting layer included in the sixth light emitting unit  43 F is formed of a red phosphorescent light emitting layer and a green phosphorescent light emitting layer. The red phosphorescent light emitting layer and the green phosphorescent light emitting layer each contain a host material which is a main component and a guest material which is a minor component as the organic compound. When the sixth light emitting unit  43 F is the red-green light emitting unit, the light emitting layer included in the sixth light emitting unit  43 F is formed of a mixed layer of a red phosphorescent material and a green phosphorescent material. The mixed layer of the red phosphorescent material and the green phosphorescent material contains a host material which is a main component and a guest material which is a minor component as the organic compound. The red phosphorescent material and the green phosphorescent material correspond to the guest material out of these materials. In either case, emission of the red light and the green light is attributable particularly to the properties of the guest material. Moreover, when the light emitting layer is formed of the mixed layer of the red phosphorescent material and the green phosphorescent material, it is important that light is efficiently emitted from both light emitting materials. To achieve this, it is effective to set the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material. This is due to the following reason. Since the energy level of the red phosphorescent material is lower than the energy level of the green phosphorescent material, energy transfer to the red phosphorescent material is more likely to occur. Accordingly, setting the proportion of the red phosphorescent material lower than the proportion of the green phosphorescent material allows both of the red phosphorescent material and the green phosphorescent material to efficiently emit light. 
     As the host material of the light emitting layer included in the sixth light emitting unit  43 F, the same material as the host material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     As the guest material of the light emitting layer included in the sixth light emitting unit  43 F, the same material as the guest material of the light emitting layer included in the first light emitting unit  13 A in the aforementioned first embodiment can be used. 
     For example, a vacuum deposition method, a spin coating method, or the like can be used as a film forming method of the layers forming the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F. 
     The first charge generating layer  44 A, the second charge generating layer  44 B, the third charge generating layer  44 C, the fourth charge generating layer  44 D, and the fifth charge generating layer  44 E are each formed of an electrically insulating layer made of an electron accepting material and an electron donating material. The specific resistance of the electrically insulating layer is preferably 1.0×10 2 Ω·cm or more, more preferably 1.0×10 5 Ω·cm or more. 
     Alternatively, the first charge generating layer  44 A, the second charge generating layer  44 B, the third charge generating layer  44 C, the fourth charge generating layer  44 D, and the fifth charge generating layer  44 E may each be configured such that the charge generating layer is formed of a mixed layer of different materials and one component of the mixed layer forms a charge transfer complex by redox. In this case, when voltage is applied between the first electrode  41  and the second electrode  42 , charges in the charge transfer complex move to the first electrode  41  side and the second electrode  42  side. In the organic EL element  40 , holes are thereby injected into the fifth light emitting unit  43 E located on the first electrode  41  side of the fifth charge generating layer  44 E, the fourth light emitting unit  43 D located on the first electrode  41  side of the fourth charge generating layer  44 D, the third light emitting unit  43 C located on the first electrode  41  side of the third charge generating layer  44 C, the second light emitting unit  43 B located on the first electrode  41  side of the second charge generating layer  44 B, and the first light emitting unit  43 A located on the first electrode  41  side of the first charge generating layer  44 A. Moreover, in the organic EL element  40 , electrons are injected into the sixth light emitting unit  43 F located on the second electrode  42  side of the fifth charge generating layer  44 E, the fifth light emitting unit  43 E located on the second electrode  42  side of the fourth charge generating layer  44 D, the fourth light emitting unit  43 D located on the second electrode  42  side of the third charge generating layer  44 C, the third light emitting unit  43 C located on the second electrode  42  side of the second charge generating layer  44 B, and the second light emitting unit  43 B located on the second electrode  42  side of the first charge generating layer  44 A. Light can be thereby simultaneously emitted from the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F can be obtained. 
     Alternatively, the first charge generating layer  44 A, the second charge generating layer  44 B, the third charge generating layer  44 C, the fourth charge generating layer  44 D, and the fifth charge generating layer  44 E may each be a laminate of an electron accepting material and an electron donating material. In this case, when voltage is applied between the first electrode  41  and the second electrode  42 , in an interface between the electron accepting material and the electron donating material, charges generated by reaction involving electron transfer between these electron accepting material and electron donating material move to the first electrode  41  side and the second electrode  42  side. In the organic EL element  40 , holes are thereby injected into the fifth light emitting unit  43 E located on the first electrode  41  side of the fifth charge generating layer  44 E, the fourth light emitting unit  43 D located on the first electrode  41  side of the fourth charge generating layer  44 D, the third light emitting unit  43 C located on the first electrode  41  side of the third charge generating layer  44 C, the second light emitting unit  43 B located on the first electrode  41  side of the second charge generating layer  44 B, and the first light emitting unit  43 A located on the first electrode  41  side of the first charge generating layer  44 A. Moreover, in the organic EL element  40 , electrons are injected into the sixth light emitting unit  43 F located on the second electrode  42  side of the fifth charge generating layer  44 E, the fifth light emitting unit  43 E located on the second electrode  42  side of the fourth charge generating layer  44 D, the third fourth light emitting unit  43 D located on the second electrode  42  side of the third charge generating layer  44 C, the third light emitting unit  43 C located on the second electrode  42  side of the second charge generating layer  44 B, and the second light emitting unit  43 B located on the second electrode  42  side of the first charge generating layer  44 A. Light can be thereby simultaneously emitted from the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F with the same current amount. Accordingly, a current efficiency and an external quantum efficiency proportionate to the sum of luminous efficiencies of the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F can be obtained. 
     As materials forming the first charge generating layer  44 A, the second charge generating layer  44 B, the third charge generating layer  44 C, the fourth charge generating layer  44 D, and the fifth charge generating layer  44 E, the same materials as the materials forming the first charge generating layer  14 A and the second charge generating layer  14 B in the aforementioned first embodiment can be used. 
     The organic EL element  40  having the structure described above can provide white light by causing the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F to emit light. 
     Moreover, the organic EL element  40  of the embodiment can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property as in the organic EL element  10  in the aforementioned first embodiment. Moreover, the organic EL element  40  of the embodiment has the MPE structure in which the first light emitting unit  43 A, the second light emitting unit  43 B, the third light emitting unit  43 C, the fourth light emitting unit  43 D, the fifth light emitting unit  43 E, and the sixth light emitting unit  43 F are stacked one on top of another with each of the first charge generating layer  44 A, the second charge generating layer  44 B, the third charge generating layer  44 C, the fourth charge generating layer  44 D, and the fifth charge generating layer  44 E sandwiched between the corresponding pair of adjacent light emitting units. Accordingly, the organic EL element  40  can provide the white light while achieving high-luminance light emission and long-life driving. 
     The organic EL element  40  of the embodiment can be thus preferably used in both of a display device and a lighting device. 
     Fifth Embodiment 
       FIG. 10  is a cross-sectional view illustrating a schematic configuration of a fifth embodiment of the organic EL element in the present invention. 
     As illustrated in  FIG. 10 , the organic EL element  50  of the embodiment has a structure in which multiple organic EL elements  10  in the aforementioned first embodiment are provided side by side on a transparent substrate  58 . In this configuration, the organic EL elements  10  are sectioned based on the respective second electrodes  12  provided on the transparent substrate  58  at certain intervals. 
     Each of the organic EL elements  10  forms a light emitting portion of the organic EL element  50  and three different color filters  59 A,  59 B,  59 C of red, green, and blue are arranged in turn at positions corresponding to the respective light emitting portions with the transparent substrate  58  therebetween. 
     White light provided by each organic EL element  10  is converted to red light, green light, or blue light by one of the three different color filters  59 A,  59 B,  59 C of red, green, and blue (red color filter  59 A, green color filter  59 B, or blue color filter  59 C) and is emitted to the outside. 
     In the organic EL element  50  of the embodiment, it is thus possible to extract red light, green light, and blue light with high color purity based on white light with high color temperature, high luminous efficiency, and an excellent color rendering property. 
     An arrangement in which the red color filter  59 A, the green color filter  59 B, and the blue color filter  59 C are arranged in turn forms an RGB arrangement. The RGB arrangement may be any arrangement selected from the group consisting of a stripe arrangement in which R, G, and B are arranged linearly, a mosaic arrangement in which R, G, and B are arranged diagonally, a delta arrangement in which R, G, and B are arranged in a triangular shape, and a pentile arrangement in which RG and GB are arranged alternately. 
     Image display with high resolution and natural color can be thereby achieved in a display device. 
     The organic EL element  50  of the embodiment can be thus preferably used in a display device. 
     Note that the organic EL element  50  of the embodiment is not necessarily limited to the aforementioned configuration and can be changed as appropriate. In the organic EL element  50  of the embodiment, the organic EL element  20  of the second embodiment, the organic EL element  30  of the third embodiment, or the organic EL element  40  of the fourth embodiment described above can be used instead of the organic EL element  10 . 
     Moreover, the organic EL element  50  of the embodiment may have such a structure that the three different color filters of red, green, and blue are provided between the transparent substrate  58  and the second electrodes  12 . 
     Sixth Embodiment 
       FIG. 11  is a cross-sectional view illustrating a schematic configuration of a sixth embodiment of the organic EL element in the present invention. 
     As illustrated in  FIG. 11 , the organic EL element  60  of the embodiment has a structure in which multiple organic EL elements  10  in the aforementioned first embodiment are provided side by side on a transparent substrate  68 . In this configuration, the organic EL elements  10  are sectioned based on the respective second electrodes  12  provided on the transparent substrate  68  at certain intervals. 
     Each of the organic EL elements  10  forms a light emitting portion of the organic EL element  60  and three different color filters  69 A,  69 B,  69 C of red, green, and blue and a no-color-filter portion are arranged in turn at positions corresponding to the respective light emitting portions with the transparent substrate  68  therebetween. 
     White light provided by each organic EL element  10  is converted to red light, green light, or blue light by one of the three different color filters  69 A,  69 B,  69 C of red, green, and blue (red color filter  69 A, green color filter  69 B, or blue color filter  69 C) and is emitted to the outside. 
     In the organic EL element  60  of the embodiment, it is thus possible to extract red light, green light, blue light with high color purity based on original white light with high color temperature, high luminous efficiency, and an excellent color rendering property. 
     Moreover, in the no-color-filter portion (portion where none of the red color filter  69 A, green color filter  69 B, and blue color filter  69 C is provided on the transparent substrate  68  illustrated in  FIG. 11 ), the white light provided by the organic EL element  10  is emitted to the outside as it is. 
     An arrangement in which the red color filter  69 A, the green color filter  69 B, and the blue color filter  69 C are arranged in turn and the no-color-filter portion form an RGBW arrangement. The RGBW arrangement may be any arrangement selected from the group consisting of a stripe arrangement in which R, G, B, and W are arranged linearly, a mosaic arrangement in which R, G, B, and Ware arranged diagonally, a delta arrangement in which R, G, B, and Ware arranged in a triangular shape, and a pentile arrangement in which RG and BW are alternately arranged. 
     When white is displayed on a display, in the RGB method described in [0136], light of a white backlight is absorbed by the color filters of the respective colors upon passing the color filters and the luminance of the light is thereby reduced. Accordingly, the light amount of the backlight needs to be increased and this leads to an increase in the power consumption of the display. 
     Meanwhile, in the RGBW method, there is no color filter in the light emitting portion of W. Accordingly, when white is displayed, the light emission from the white backlight can be effectively used as it is. Hence, there is no decrease in luminance and an operation can be achieved with low power consumption. 
     Thus, low power consumption and image display with high resolution and natural color can be both achieved in a display device. 
     The organic EL element  60  of the embodiment can be thus preferably used in a display device. 
     Note that the organic EL element  60  of the embodiment is not necessarily limited to the aforementioned configuration and can be changed as appropriate. In the organic EL element  60  of the embodiment, the organic EL element  20  of the second embodiment, the organic EL element  30  of the third embodiment, or the organic EL element  40  of the fourth embodiment described above can be used instead of the organic EL element  10 . 
     Moreover, the organic EL element  60  of the embodiment may have such a structure that the three different color filters of red, green, and blue are provided between the transparent substrate  68  and the second electrodes  12 . 
     [Lighting Device] 
     An embodiment of the lighting device in the present invention is described. 
       FIG. 12  is a cross-sectional view illustrating a configuration of the embodiment of the lighting device in the present invention. Although an example of the lighting device to which the present invention is applied is described herein, the lighting device of the present invention is not necessarily limited to such a configuration and various changes can be made as appropriate. 
     The lighting device  100  of the embodiment includes, for example, any one of the organic EL elements  10 ,  20 ,  30 ,  40 ,  50  as a light source. 
     As illustrated in  FIG. 12 , in the lighting device  100  of the embodiment, multiple anode terminal electrodes  111  and cathode terminal electrodes (illustration omitted) are formed at sides or vertices of a periphery of a glass substrate  110  so that the organic EL element  10 ,  20 ,  30 ,  40 ,  50  can uniformly emit light. Note that the entire surfaces of the anode terminal electrodes  111  and the entire surfaces of the cathode terminal electrodes are covered with solder (underlying solder) to reduce wiring resistance. Moreover, the anode terminal electrodes  111  and the cathode terminal electrodes uniformly supply an electric current to the organic EL element  10 ,  20 ,  30 ,  40 ,  50  from the sides or vertices of the periphery of the glass substrate  110 . For example, in order to uniformly supply an electric current to the organic EL element  10 ,  20 ,  30 ,  40 ,  50  formed in a quadrilateral shape, the lighting device  100  includes the anode terminal electrodes  111  on the sides and the cathode terminal electrodes at the vertices. Alternatively, for example, the lighting device  100  includes the anode terminal electrodes  111  on peripheries of L-shaped portions each including a vertex and extending over two sides and the cathode terminal electrodes in center portions of the respective sides. 
     Moreover, a sealing substrate  113  is arranged on the glass substrate  110  to cover the organic EL element  10 ,  20 ,  30 ,  40 ,  50  to prevent degrading of the performance of the organic EL element  10 ,  20 ,  30 ,  40 ,  50  due to oxygen, water, and the like. The sealing substrate  113  is provided on the glass substrate  110  with a peripheral sealing member  114  therebetween. A small gap  115  is provided between the sealing substrate  113  and the organic EL element  10 ,  20 ,  30 ,  40 ,  50 . This gap  115  is filled with a hygroscopic agent. The gap  115  may be filled with, for example, an inert gas such as nitrogen, silicone oil, or the like instead of the hygroscopic agent. Moreover, the gap  115  may be filled with a gel resin in which the hygroscopic agent is dispersed. 
     Note that, although the glass substrate  110  is used as a base substrate for forming the element in the embodiment, a substrate made of a material such as plastic, metal, or ceramic may also be used. Moreover, in the embodiment, a glass substrate, a plastic substrate, or the like can be used as the sealing substrate  113 . When plastic substrates are used as the base substrate and the sealing substrate, the lighting device  100  of the embodiment is flexible. 
     Moreover, a UV curable resin or a thermal setting resin with low oxygen permeability and low water permeability, a laser glass frit, or the like can be used for the sealing member  114 . 
     The lighting device of the embodiment may have a configuration including an optical film for improving the luminous efficiency, on the light extraction surface side of the organic EL element  10 ,  20 ,  30 ,  40 ,  50  in the aforementioned embodiment. 
     The optical film used in the lighting device of the embodiment is provided to improve the luminous efficiency while maintaining the color rendering property. 
     An organic EL element emits light in a light emitting layer with a higher refractive index (refractive index of about 1.6 to 2.1) than air and it is generally said that only about 15% to 20% of light emitted from the light emitting layer can be extracted. This is because light incident on an interface at an angle equal to or greater than a critical angle is totally reflected and cannot be extracted to the outside of the element. Specifically, light is totally reflected between a transparent substrate and a transparent electrode or the light emitting layer to be guided through the transparent electrode or the light emitting layer and resultantly escapes in directions toward side surfaces of the element. 
     As a method for improving the extraction efficiency of the light, there are, for example, the following methods: a method of making a surface of the transparent substrate rough to prevent total reflection on an interface between the transparent substrate and air (see, for example, “U.S. Pat. No. 4,774,435”); a method of providing the substrate with a light condensing property to improve the efficiency (see, for example, “Japanese Patent Application Publication No. Sho 63-314795”); a method of forming reflection surfaces on the side surfaces of the element and the like (see, for example, “Japanese Patent Application Publication No. Hei 1-220394”); a method of introducing a flat layer with an intermediate refractive index between the substrate and the light emitting body to form a reflection prevention film (see, for example, “Japanese Patent Application Publication No. Sho 62-172691”); a method of introducing a flat layer with a lower refractive index than the substrate, between the substrate and the light emitting body (see, for example, “Japanese Patent Application Publication No. 2001-202827”); a method of forming a diffraction grading between any two of the substrate, the transparent electrode layer, and the light emitting layer (including between the substrate and the outside) (see, for example, “Japanese Patent Application Publication No. Hei 11-283751”); and the like. 
     Note that, in order to improve the aforementioned color rendering property, the lighting device  100  may have a structure in which a microlens array or the like is further provided on a surface of the aforementioned optical film or may be combined with a light condensing sheet. This allows the light to be condensed in a specific direction, for example, a direction frontward of the element light emitting surface, thereby improving the luminance in the specific direction. Furthermore, a light diffusion film may be used together with the light condensing sheet to control a light emission angle from the organic EL element. For example, a light diffusion film (LIGHT-UP) manufactured by Kimoto Co., Ltd. or the like can be used as the light diffusion film. 
     Note that the present invention is not necessarily limited to the aforementioned embodiment and various changes can be made within a scope not departing from the spirit of the present invention. 
     Specifically, in the present invention, any of the organic EL elements  10 ,  20 ,  30 ,  40 ,  50  capable of providing the aforementioned white light can be preferably used as the light source of the lighting device  100  which is, for example, a general lighting device. Meanwhile, in the present invention, the organic EL elements  10 ,  20 ,  30 ,  40 ,  50  are not limited for use as the light source of the lighting device  100  and may be used in various applications such as, for example, a backlight of a liquid crystal display. 
     [Display Device] 
     An embodiment of the display device in the present invention is described. 
       FIG. 13  is a cross-sectional view illustrating a configuration of the embodiment of the display device in the present invention. In  FIG. 13 , the same constitutional elements as those in the first embodiment of the organic EL element in the present invention illustrated in  FIG. 1  and the fifth embodiment of the organic EL element in the present invention illustrated in  FIG. 10  are denoted by the same reference numerals and description thereof is omitted. Moreover, although an example of the display device to which the present invention is applied is described herein, the display device of the present invention is not necessarily limited to such a configuration and changes can be made as appropriate. 
     The display device  200  of the embodiment includes, for example, the organic EL element  10  as the light source, the organic EL element  10  having a light emitting layer  16  including a first light emitting portion  16 A, a second light emitting portion  16 B, and a third light emitting portion  16 C as described above. 
     The display device  200  of the embodiment is a top emission type and is an active matrix type. 
     As illustrated in  FIG. 13 , the display device  200  of the embodiment includes a TFT substrate  300 , an organic EL element  400 , a color filter  500 , and a sealing substrate  600 . In the display device  200  of the embodiment, the TFT substrate  300 , the organic EL element  400 , the color filter  500 , and the sealing substrate  600  are stacked one on top of another in this order to form a laminated structure. 
     The TFT substrate  300  includes a base substrate  310 , TFT elements  320  which are provided on one surface  310   a  of the base substrate  310 , and an insulating layer  330  which is a planarization film layer (protection layer) provided on the one surface  310   a  of the base substrate  310  to cover the TFT elements  320 . 
     A glass substrate, a flexible substrate made of plastic, and the like can be given as examples of the base substrate  310 . 
     The TFT elements  320  each include a source electrode  321 , a drain electrode  322 , a gate electrode  323 , a gate insulating layer  324  formed on the gate electrode  323 , and a channel region provided on the gate insulating layer  324  and being in contact with the source electrode  321  and the drain electrode  322 . 
     The organic EL element  400  has the same configuration as the organic EL element  10 . 
     The light emitting layer  16  in the organic EL element  400  includes the first light emitting portion  16 A which emits red light, the second light emitting portion  16 B which emits green light, and the third light emitting portion  16 C which emits blue light. 
     First partition walls (banks)  410  and second partition walls (ribs)  420  stacked thereon are provided between the first light emitting portion  16 A and the second light emitting portion  16 B, between the second light emitting portion  16 B and the third light emitting portion  16 C, and between the third light emitting portion  16 C and the first light emitting portion  16 A. 
     The first partition walls  410  are provided on the insulating layer  330 . The first partition walls  410  have a shape tapered in a direction away from the insulating layer  330 . The width of the first partition walls  410  gradually becomes smaller as the distance from the insulating layer  330  increases. 
     The second partition walls  420  are provided on the first partition walls  410 . The second partition walls  420  have a shape reverse-tapered in a direction away from the first partition walls  410 . The width of the second partition walls  420  gradually becomes greater as the distance from the first partition walls  410  increases. 
     The first partition walls  410  and the second partition walls  420  are made of an insulating material. A fluorine-containing resin can be given as an example of the material forming the first partition walls  410  and the second partition walls  420 . Vinylidene fluoride, vinyl fluoride, trifluoroethylene, copolymers of these, and the like can be given as examples of a fluorine compound contained in the fluorine-containing resin. A phenol novolac resin, a polyvinyl phenol resin, an acrylic resin, a methacrylic resin, and combination of these can be given as examples of a resin contained in the fluorine-containing resin. 
     The first light emitting portion  16 A, the second light emitting portion  16 B, and the third light emitting portion  16 C are provided on a second electrode  13  formed on the insulating layer  330  of the TFT elements  320 , with a hole transport layer  15  provided between the insulating layer  330  and the light emitting portions  16 A,  16 B,  16 C. 
     The second electrode  13  is connected to the drain electrodes  322  of the TFT elements  320 . 
     The color filter  500  is provided on a first electrode  12  of the organic EL element  400 . 
     The color filter  500  includes a first color filter  510  corresponding to the first light emitting portion  16 A, a second color filter  520  corresponding to the second light emitting portion  16 B, and a third color filter  530  corresponding to the third light emitting portion  16 C. 
     The first color filter  510  is a red color filter and is arranged to face the first light emitting portion  16 A. 
     The second color filter  520  is a green color filter and is arranged to face the second light emitting portion  16 B. 
     The third color filter  530  is a blue color filter and is arranged to face the third light emitting portion  16 C. 
     A glass substrate, a flexible substrate made of plastic, and the like can be given as examples of the sealing substrate  600 . When plastic is used for the base substrate  310  and the sealing substrate  600 , the display device  200  of the embodiment is flexible. 
     Note that, as illustrated in  FIG. 13 , although the example in which the light emitting layer  16  of the organic EL element  400  includes the first light emitting portion  16 A which emits red light, the second light emitting portion  16 B which emits green light, and the third light emitting portion  16 C which emits blue light are described in the embodiment, the embodiment is not limited to this. The light emitting layer  16  may include the first light emitting portion  16 A which emits red light, the second light emitting portion  16 B which emits green light, the third light emitting portion  16 C which emits blue light, and a fourth light emitting portion  16 D which emits white light. Note that none of the color filters are disposed at a position corresponding to the fourth light emitting portion  16 D. 
     The display device  200  of the embodiment can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property. Moreover, since the display device  200  of the embodiment includes the organic EL element  50  in the fifth embodiment, the display device  200  can provide white light whose correlated color temperature is 3300 or more, average color rendering index (Ra) is 70 or more, and R6 and R12 among the special color rendering indices (Ri) are 60 or more and 30 or more, respectively. 
     Note that the present invention is not necessarily limited to the aforementioned embodiment and various changes can be made within a scope not departing from the spirit of the present invention. In the display device  200  of the embodiment, the organic EL element  60  in the aforementioned sixth embodiment can be used instead of the organic EL element  50 . 
     EXAMPLES 
     Effects of the present invention are made clearer below by using Examples. 
     Note that the present invention is not limited to following Examples and changes can be made as appropriate within a scope not departing from the spirit of the invention. 
     Example 1 
     “Manufacturing of Organic EL Element” 
     In Example 1, an organic EL element having an element structure illustrated in  FIG. 14  was manufactured. 
     Specifically, first, there was prepared a soda-lime glass substrate with a thickness of 0.7 mm on which an ITO film with a thickness of 100 nm, a width of 2 mm, and a sheet resistance of about 20Ω/□ was formed. 
     Then, the substrate was subjected to ultrasonic cleaning by using neutral detergent, ion-exchanged water, acetone, and isopropyl alcohol for 5 minutes for each cleaner and then subjected to spin drying and UV/O 3  treatment. 
     Next, vapor deposition crucibles (made of tantalum or alumina) in a vacuum deposition apparatus were filled respectively with materials used to form layers illustrated in  FIG. 14 . Then, the substrate was set in the vacuum deposition apparatus, electric power was supplied to the vapor deposition crucibles to heat them in a reduced pressure atmosphere with a degree of vacuum of 1×10 −4  Pa or less, and each of the layers was vapor-deposited to a predetermined film thickness at a deposition rate of 0.1 nm per second. Moreover, each of the layers made of two or more materials such as the light emitting layers was formed by supplying power to the corresponding vapor deposition crucibles and performing co-deposition such that the layer was formed to have a predetermined mix ratio. 
     Moreover, the first electrode was vapor-deposited to a predetermined film thickness at a deposition rate of 1 nm per second. 
     “Evaluation of Organic EL Element” 
     The organic EL element of Example 1 manufactured as described above was connected to a power supply (KEITHLEY 2425) and power with a constant current of 3 mA/cm 2  was supplied to the organic EL element of Example 1 to cause it to emit light. An emission spectrum of light emitted from the organic EL element in the frontward direction in this case was measured by using a multichannel analyzer (trade name: PMA-11, manufactured by Hamamatsu Photonics K. K.). 
     Then, the emitted light color was evaluated based on the measurement result by using chromaticity coordinates in the CIE color system. Moreover, the emitted light color was classified into one of light source colors specified in “JIS Z 9112” based on the chromaticity coordinates. Furthermore, the deviation duv from a blackbody locus was derived based on the specifications of “JIS Z 8725.” Moreover, the average color rendering index (Ra) of the emitted light color was derived by using the method specified in “JIS Z 8726.” The results (no film) of these evaluations are collectively illustrated in  FIG. 15 . 
     Example 2 
     An organic EL element of Example 2 having an element structure illustrated in  FIG. 16  was manufactured by using the same manufacturing method as that of Example 1. 
     Then, the organic EL element of Example 2 was evaluated in the same methods as those in Example 1. The evaluation results (no film) are illustrated in  FIG. 17 . 
     As illustrated in  FIGS. 15 and 17 , the organic EL elements of Examples 1 and 2 both provided the white light with high color temperature, high luminous efficiency, and an excellent color rendering property. Accordingly, it was found that lighting devices and display devices including such an organic EL element can be lighting devices and display devices with high color temperature, high luminous efficiency, and an excellent color rendering property. 
     Example 3 
     An optical film was attached to the light extraction surface (second electrode) side of the organic EL element of the aforementioned Example 1 to manufacture a lighting device of Example 3. 
     Then, the lighting device of Example 3 was evaluated in the same methods as those in Example 1. The evaluation results (with film) are illustrated in  FIG. 15 . 
     Example 4 
     An optical film was attached to the light extraction surface (second electrode) side of the organic EL element of the aforementioned Example 2 to manufacture a lighting device of Example 4. 
     Then, the lighting device of Example 4 was evaluated in the same methods as those in Example 1. The evaluation results (with film) are illustrated in  FIG. 17 . 
     As illustrated in  FIGS. 15 and 17 , it was found that, in the lighting devices of Examples 3 and 4, attaching the optical film to the light extraction surface (second electrode) side of the organic EL element changed the shape of the emission spectrum from that in the case where no optical film was attached (illustrated by broken lines in  FIGS. 15 and 17 ). Particularly, it was found that the light emission intensities of the two peak wavelengths appearing in the green wavelength band and the red wavelength band were increased as compared with those obtained without the films. 
     Thus, in the lighting devices of Examples 3 and 4, the luminous efficiency was greatly improved while maintaining the high color temperature and the excellent color rendering property of the organic EL elements in Examples 1 and 2. The luminous efficiency was improved to about 1.4 times the luminous efficiency of the organic EL element of Example 1 while maintaining high color temperature of 3300 K or more and an excellent color rendering property of Ra of 80 or more, R6 of 60 or more, and R12 of 30 or more. 
     INDUSTRIAL APPLICABILITY 
     One aspect described above can provide an organic electroluminescent element which can provide white light with high color temperature, high luminous efficiency, and an excellent color rendering property and is thus suitable for both of a display device and a lighting device and also provide a display device and a lighting device including this organic electroluminescent element. 
     DESCRIPTION OF REFERENCE NUMERALS 
     
         
           10 ,  20 ,  30 ,  40 ,  50 ,  60  organic EL element 
           11 ,  21 ,  31 ,  41 ,  51 ,  61  first electrode 
           12 ,  22 ,  32 ,  42 ,  52 ,  62  second electrode 
           13 A,  23 A,  33 A,  43 A,  53 A,  63 A first light emitting unit 
           13 B,  23 B,  33 B,  43 B,  53 B,  63 B second light emitting unit 
           33 C,  43 C third light emitting unit 
           33 D,  43 D fourth light emitting unit 
           43 E fifth light emitting unit 
           43 F sixth light emitting unit 
           14 A,  24 A,  34 A,  44 A,  54 A,  64 A first charge generating layer 
           14 B,  24 B,  34 B,  44 B,  54 B,  64 B second charge generating layer 
           15 A,  25 A,  35 A,  45 A first electron transport layer 
           16 A,  26 A,  36 A,  46 A first light emitting layer 
           17 A,  27 A,  37 A,  47 A first hole transport layer 
           15 B,  25 B,  35 B,  45 B second electron transport layer 
           16 B,  26 B,  36 B,  46 B second light emitting layer 
           17 B,  27 B,  37 B,  47 B second hole transport layer 
           15 C,  25 C,  35 C,  45 C third electron transport layer 
           16 C,  26 C,  36 C,  46 C third light emitting layer 
           17 C,  27 C,  37 C,  47 C third hole transport layer 
           35 D,  45 D fourth electron transport layer 
           36 D,  46 D fourth light emitting layer 
           37 D,  47 D fourth hole transport layer 
           45 E fifth electron transport layer 
           46 E fifth light emitting layer 
           47 E fifth hole transport layer 
           45 F sixth electron transport layer 
           46 F sixth light emitting layer 
           47 F sixth hole transport layer 
           100  lighting device 
           111  anode terminal electrode 
           113  sealing substrate 
           114  sealing member 
           115  gap 
           200  display device 
           300  TFT substrate 
           310  base substrate 
           320  TFT element 
           321  source electrode 
           322  drain electrode 
           323  gate electrode 
           324  gate insulating layer 
           330  insulating layer 
           400  organic EL element 
           410  first partition wall 
           420  second partition wall 
           500  color filter 
           510  first color filter 
           520  second color filter 
           530  third color filter 
           600  sealing substrate