CN205104520U - Organic electroluminescence device and display device - Google Patents

Abstract

An embodiment of the utility model provides an organic electroluminescence device and display device relates to and shows technical field, can solve organic electroluminescence device's colour temperature control range limitation, and results in the luminous great problem of luminance difference in accommodation process. This organic electroluminescence device includes first electrode, second electrode and organic material functional layer, still including being located the third electrode that the first electrode is close to organic material functional layer one side. The third electrode and first electrode part overlap, and the first electrode between insulating, the distance of first electrode and second electrode is greater than the distance of the third electrode and second electrode.

Description

A kind of organic electroluminescence device and display unit

Technical field

The utility model relates to Display Technique field, particularly relates to a kind of organic electroluminescence device and display unit.

Background technology

Organic electroluminescence device (English full name OrganicLightEmittingDevices, English abbreviation OLEDs), because it has, solid luminescent, visual angle are wide, low in energy consumption, the advantage such as fast response time, high-low temperature resistant, can meet the requirement of low-carbon environment-friendly, green living.

Wherein, the organic electroluminescence device that can send white light is most widely used in display or lighting field.On this basis, in order to the white light sent with organic electroluminescence device under Different periods, different weather state all can adapt with the colour temperature of sunlight, colour temperature organic electroluminescence device being sent to white light is needed to regulate.Such as living in for equatorial user, due to the average color temperature of sunlight higher (at about 11000K), so need the light emission color temperature of display or lighting device to heighten.And for the user living in high latitude, due to the average color temperature of sunlight lower (at about 5600K), so the lower display of light emission color temperature or lighting device are more suitable for the user of high latitude.

In prior art, general by regulating the voltage of organic electroluminescence device negative electrode and anode, to reach the object regulating light emission color temperature.But the reference color temperature adopting above-mentioned regulative mode to cover is less, and when differing greatly when twice, front and back colour temperature in the process regulated, the change of voltage is also comparatively large, thus causes the luminosity of the display or lighting device with above-mentioned organic electroluminescence device to produce larger difference.

Utility model content

Embodiment of the present utility model provides a kind of organic electroluminescence device and display unit, can solve the colour temperature adjustable range limitation of organic electroluminescence device, and in adjustment process, cause the problem that luminosity differs greatly.

For achieving the above object, embodiment of the present utility model adopts following technical scheme:

The one side of the utility model embodiment, a kind of organic electroluminescence device is provided, comprise the first electrode, the second electrode and the organic material functional layer between described first electrode and described second electrode, also comprise and be positioned at the third electrode of described first electrode near described organic material functional layer side; Described third electrode and described first electrode part overlapping, and and insulate between described first electrode; The distance of described first electrode and described second electrode is greater than the distance of described third electrode and described second electrode.

Preferably, described organic material functional layer comprises hole transmission layer, luminescent layer and electron transfer layer.

Preferably, described electron transfer layer is arranged between described luminescent layer and described second electrode.

Preferably, described hole transmission layer is arranged between described third electrode and described luminescent layer.

Preferably, described organic material functional layer also comprises the flatness layer be arranged between described hole transmission layer and described third electrode.

Preferably, the thickness of described third electrode is 5nm ~ 20nm.

Preferably, the material forming described first electrode and described third electrode is any one in metallic aluminium or metallic copper.

Preferably, the material forming described flatness layer is conducting polymer composite, and thickness is 100nm ~ 300nm.

The another aspect of the utility model embodiment, provides a kind of display unit, comprises any one organic electroluminescence device above-mentioned.

The utility model embodiment provides a kind of organic electroluminescence device and display unit, this organic electroluminescence device comprises the first electrode, the second electrode and the organic material functional layer between the first electrode and the second electrode, also comprises and is positioned at the third electrode of the first electrode near organic material functional layer side.This third electrode and the first electrode part overlapping, and and to insulate between the first electrode.The distance of the first electrode and the second electrode is greater than the distance of third electrode and the second electrode.

So, between the first electrode and the second electrode, form the first optical microcavity, between third electrode and the second electrode, form the second optical microcavity.Because the distance between the first electrode to the second electrode is greater than the distance between third electrode to the second electrode.In the case, when applying voltage respectively to the first electrode, the second electrode and third electrode, the first optical microcavity and the second optical microcavity can produce the light of different wave length.

Based on this, when having the light poststack in the first colour temperature light and the second optical microcavity with the second colour temperature in the first optical microcavity, this organic electroluminescence device can be made to send have the light of the 3rd colour temperature.Wherein, the first colour temperature, the second colour temperature and the 3rd colour temperature can be different.So, the first colour temperature and the second colour temperature all can have an impact to the numerical value height of the 3rd colour temperature, the adjustable range of device colour temperature therefore, it is possible to increase organic electroluminescence is given out light.

In addition, because above-mentioned 3rd colour temperature is formed by stacking by the first colour temperature and the second colour temperature, even if therefore finely tune the first colour temperature and the second colour temperature, because the superposition amount of the first colour temperature and the second colour temperature changing value can act on the 3rd colour temperature, therefore the 3rd colour temperature numerical value still can realize change by a relatively large margin.And above-mentioned adjustment process is just finely tuned the first colour temperature and the second colour temperature, therefore the electrode voltage value of the first optical microcavity and the second optical microcavity does not have greatly changed, thus avoids causing organic electroluminescence device to occur the problem that luminance difference is larger before and after colour temperature adjustment.

Accompanying drawing explanation

In order to be illustrated more clearly in the utility model embodiment or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.

The structural representation of a kind of organic electroluminescence device that Fig. 1 provides for the utility model embodiment;

Fig. 2 is the structural representation of the organic electroluminescence device adding other functional layer in Fig. 1;

The manufacture method flow chart of a kind of organic electroluminescence device that Fig. 3 provides for the utility model embodiment;

Fig. 4 is the manufacture method flow chart for the organic electroluminescence device shown in construction drawing 2;

Fig. 5 is the concrete structure schematic diagram of luminescent layer in Fig. 1 or Fig. 2.

Reference numeral:

01-first optical microcavity; 02-second optical microcavity; 10-substrate; 11-first electrode; 12-second electrode; 13-third electrode; 14-insulating barrier; 200-organic material functional layer; 20-luminescent layer; The sub-luminescent layer of 201-first; 202-wall; The sub-luminescent layer of 203-second; 21-hole transmission layer; 22-electron transfer layer; 23-hole injection layer; 24-flatness layer; The distance of H1-first electrode and the second electrode; The distance of H2-third electrode and the second electrode.

Embodiment

Below in conjunction with the accompanying drawing in the utility model embodiment, be clearly and completely described the technical scheme in the utility model embodiment, obviously, described embodiment is only the utility model part embodiment, instead of whole embodiments.Based on the embodiment in the utility model, those of ordinary skill in the art are not making the every other embodiment obtained under creative work prerequisite, all belong to the scope of the utility model protection.

The utility model embodiment provides a kind of organic electroluminescence device, as shown in Figure 1, comprises the first electrode 11, second electrode 12 and the organic material functional layer 200 between the first electrode 11 and the second electrode 12.In addition this organic electroluminescence device can also comprise and is positioned at the third electrode 13 of the first electrode 11 near luminescent layer 20 side.

Wherein, third electrode 13 and the first electrode 11 part overlapping, and and to insulate between the first electrode 11.Concrete, insulating barrier 14 can be set between the first electrode 11 and third electrode 13.As shown in Figure 1, the distance H1 of the first electrode 11 and the second electrode 12 is greater than the distance H2 of third electrode 13 and the second electrode 12.

It should be noted that, the first, the principle of luminosity of organic electroluminescence device is by the formation exciton that meets in the luminescent layer 20 of positive and negative charge carrier in organic material functional layer 200, energy transferring is given the luminous organic material forming luminescent layer 20 by exciton compound, atom in this luminous organic material is excited, from ground state transition to excitation state, the radiation transistion when excited atom gets back to ground state and produce luminescence phenomenon.

Wherein, above-mentioned charge carrier produces after applying voltage to the first electrode 11 and the second electrode 12.Concrete, when the first electrode 11 is anode, under the effect of outer field voltage, this first electrode 11 can produce positive carrier, i.e. hole.In the case, the second electrode 12 as negative electrode, and can produce negative carrier, i.e. electronics under the effect of outer field voltage.Or, when the second electrode 12 is anode, under the effect of outer field voltage, produce positive carrier, i.e. hole.In the case, the first electrode 11 as negative electrode, and can produce negative carrier, i.e. electronics under the effect of outer field voltage.The utility model does not limit the first electrode 11 and the second electrode 12, and following examples are all with the first electrode 11 for anode, the second electrode 12 for negative electrode be the explanation that example is carried out.

The second, organic electroluminescence device can adopt top emitting formula and bottom emitting formula.Concrete, for top emitting formula organic electroluminescence device, light sends from the side of the second electrode 12, and therefore the second electrode 12 can adopt transmitance higher, and the material that conductance is higher is formed.The transparent conductive materials such as such as tin indium oxide (English full name: IndiumTinOxides, English abbreviation: ITO), or indium zinc oxide (English full name: IndiumZincOxide, English abbreviation: IZO).And the first electrode 13 can adopt the metal material that work function is higher, such as, in metallic aluminium or argent any one.

And for bottom emitting formula organic electroluminescence device, light sends from the side of the first electrode 11, therefore the first electrode 11 can adopt ITO or IZO to form.And the second electrode can adopt any one in metallic aluminium or argent.

The type of the utility model to organic electroluminescence device does not limit.Following examples are all the explanations carried out for top emitting formula organic electroluminescence device.

Three, under the effect of outer field voltage, the positive negative carrier that the anode of organic electroluminescence device and negative electrode send meets the energy of generation in luminescent layer 20, can vibrate between the photon that gives off in excited atom and excited atom of certain frequency.In the case, photon in the optical microcavity having negative electrode and anode to form by de excitation Atomic absorption, then radiation, then absorb.Thus make this optical microcavity have the effect of emission peak place emissive porwer enhancing.

Wherein, the intensity I c (λ) of the optical microcavity emission spectrum of vertical light-emitting plane can be drawn by following formula:

$I_c\left(\mathrm{\λ}\right)=\frac{(1-R_d)\[1+R_m+2{\[R_m\]}^{0.5}cos\[\frac{4\mathrm{\π}x}{\mathrm{\λ}}\]\]}{1+R_m{R}_d-2{\left(R_m{R}_d\right)}^{0.5}cos\[\frac{4\mathrm{\π}L}{\mathrm{\λ}}\]}\×|E_n\left(\mathrm{\λ}\right){|}^2---\left(1\right)$

Wherein, in above-mentioned formula, λ is emission wavelength, and x is the distance of luminescent layer 20 to metal electrode (such as the first electrode 11 of anode), Rm and Rd is respectively the specular reflectivity of metal and medium in organic electroluminescence device.In (λ) is the distribution of original spectrum (spectrum of free space).

Have above-mentioned formula to find out, x can determine the cavity length of this optical microcavity, and when x changes, the intensity I c (λ) of this optical microcavity emission spectrum also changes thereupon, and the wavelength that namely this optical microcavity emits beam can change.In the case, the colour temperature that this organic electroluminescence device emits beam also can change.

Based on this, as shown in Figure 1, the organic electroluminescence device that the utility model embodiment provides comprises can form the first optical microcavity 01 by the first electrode 11 and the second electrode 12, also comprises the second optical microcavity 02 be made up of third electrode 13 and the second electrode 12.Because the first optical microcavity 01 is different with the cavity length of the second optical microcavity 02, namely the distance H1 of the first electrode 11 and the second electrode 12 is greater than the distance H2 of third electrode 13 and the second electrode 12.Therefore the colour temperature that emits beam of above-mentioned two optical microcavities is also different.

Concrete, because the first electrode 11 in the first optical microcavity 01 to be greater than in the second optical microcavity 02 third electrode 13 to the distance of luminescent layer to the distance of luminescent layer.Therefore the wavelength that the second optical microcavity 02 emits beam is less than the wavelength that the first optical microcavity 01 emits beam.Therefore the second optical microcavity 02 emits beam partially blue so colour temperature is high, and the second optical microcavity 01 emits beam partially red so colour temperature is low.Further, when the second electrode 12 area and to its apply voltage constant, when the area of the first electrode 11 is larger, or to first electrode 11 applying voltage larger time, the colour temperature that the first optical microcavity 01 emits beam is lower, and light is close to redness.When the area of third electrode 13 is larger, or to third electrode apply voltage larger time, the colour temperature that the second optical microcavity 02 emits beam is higher, and light is close to blueness.The mixed colour temperature of light of two optical microcavities is the colour temperature that this organic electroluminescence device emits beam.

Therefore, before product export, according to the demand of user in the process preparing organic electroluminescence device, the object changing organic electroluminescence device light emission color temperature can be reached by the area controlling the first electrode 11 or third electrode 13.

Or, when after product export, although the area of the first electrode 11 or third electrode 13 is fixed.But appoint and so can pass through adjustment to the first electrode 11 or third electrode 13, and the voltage of the second electrode 12, to change the light emission color temperature of the first optical microcavity 01 or the second optical microcavity 02, finally reach the object changing organic electroluminescence device light emission color temperature.Such as, when the voltage putting on the second electrode 12 is constant, when the voltage V1 putting on the first electrode 11 is 10V, when the voltage V2 putting on third electrode 13 is 0V, this organic electroluminescence device light emission color temperature is 3000K; When V1 is decreased to 8V, and when V2 increases to 10V, this organic electroluminescence device light emission color temperature is 5000K; When V1 is decreased to 0V, when V2 keeps 10V constant, this organic electroluminescence device light emission color temperature is 7000K.Above-mentioned is only illustrating the adjustment of organic electroluminescence device colour temperature.This is no longer going to repeat them for other example.

In addition seen from the above description, when the negative electrode of the second electrode 12 as the first optical microcavity 01 and the second optical microcavity 02, the first electrode 11 is the anode of the first optical microcavity 01, and third electrode 13 is the anode of the second optical microcavity 03.In the case, preferably, above-mentioned third electrode 13 can with the same material of the first electrode 11.Any one formation in metallic aluminium or metallic copper such as also can be adopted when third electrode 13.

In addition, the thickness of this third electrode 13 can be between 5nm ~ 20nm.When the thickness of third electrode 13 is less than 5nm, conductance can decline, and be unfavorable for provides enough charge carriers (such as hole) to luminescent layer 20 under External Electrical Field.When the thickness of third electrode 13 is greater than 20nm, although be beneficial to the supply of charge carrier, because thickness is too large thus the integral thickness of organic electroluminescence device can be caused to increase, be unfavorable for that the ultrathin of device designs.

The utility model embodiment provides a kind of organic electroluminescence device, comprise the first electrode, the second electrode and the organic material functional layer between the first electrode and the second electrode, also comprise and be positioned at the third electrode of the first electrode near organic material functional layer side.This third electrode is overlapping with the first electrode part, and and insulate between the first electrode.The distance of the first electrode and the second electrode is greater than the distance of third electrode and the second electrode.

So, between the first electrode and the second electrode, form the first optical microcavity, between third electrode and the second electrode, form the second optical microcavity.Because the distance between the first electrode to the second electrode is greater than the distance between third electrode to the second electrode.In the case, when applying voltage respectively to the first electrode, the second electrode and third electrode, the first optical microcavity and the second optical microcavity can produce the light of different wave length.

Based on this, when having the light poststack in the first colour temperature light and the second optical microcavity with the second colour temperature in the first optical microcavity, this organic electroluminescence device can be made to send have the light of the 3rd colour temperature.Wherein, the first colour temperature, the second colour temperature and the 3rd colour temperature can be different.So, the first colour temperature and the second colour temperature all can have an impact to the numerical value height of the 3rd colour temperature, the adjustable range of device colour temperature therefore, it is possible to increase organic electroluminescence is given out light.

In addition, because above-mentioned 3rd colour temperature is formed by stacking by the first colour temperature and the second colour temperature, even if therefore finely tune the first colour temperature and the second colour temperature, because the superposition amount of the first colour temperature and the second colour temperature changing value can act on the 3rd colour temperature, therefore the 3rd colour temperature numerical value still can realize change by a relatively large margin.And above-mentioned adjustment process is just finely tuned the first colour temperature and the second colour temperature, therefore the electrode voltage value of the first optical microcavity and the second optical microcavity does not have greatly changed, thus avoids causing organic electroluminescence device to occur the problem that luminance difference is larger before and after colour temperature adjustment.

On this basis, above-mentioned organic material functional layer 200, except comprising luminescent layer 20, can also comprise hole transmission layer 21 and electron transfer layer 22 as shown in Figure 2.Below detailed illustrating is carried out to the structure of organic material functional layer 200.

As shown in Figure 2, in order to improve the transmittability of the charge carrier (such as hole) that the first electrode 11 and third electrode 13 export under the effect of extra electric field, hole transmission layer 21 can be set between third electrode 13 and luminescent layer 20.

Or, in order to improve the transmittability of the charge carrier (such as electronics) that the second electrode 12 exports under the effect of extra electric field, electron transfer layer 22 can be set between luminescent layer 20 and the second electrode 12.

In addition, the charge carrier (such as electronics) exported under the effect of extra electric field to improve the second electrode 12 injects the ability of luminescent layer 20, organic material functional layer 200 can also comprise electron injecting layer 23, and this electron injecting layer is arranged between the second electrode 12 and electron transfer layer 22.

In the case, as shown in Figure 2, because third electrode 13 protrudes from the first electrode 11, therefore, in order to make the surface of all the other thin layers above third electrode 13 smooth, organic material functional layer 200 can also comprise flatness layer 24, and this flatness layer 24 is arranged between hole injection layer 23 and third electrode 13.

Further, the material forming this flatness layer 24 can be conducting polymer composite, such as, and PEDOT:PSS.Wherein PEDOT is the polymer of EDOT (3,4-ethylene dioxythiophene monomer), and PSS is poly styrene sulfonate.So the effect of conduction and hole injection can be played.

In addition, preferably, the thickness of this flatness layer 24 can be 100nm ~ 300nm.When the thickness of flatness layer 24 is less than 100nm, because the too thin therefore flat results of thickness is unsatisfactory.In addition, when the thickness of flatness layer 24 is greater than 300nm, although have desirable flat results, the thickness of device can be increased, be unfavorable for the design of device ultrathin.

The utility model embodiment provides a kind of display unit, comprise any one organic electroluminescence device as mentioned above, there is the structure core beneficial effect that the electroluminescent device of the organic light emission provided with previous embodiment is identical, because previous embodiment is described in detail the structure of this organic electroluminescence device and beneficial effect, repeat no more herein.

It should be noted that, in the utility model embodiment, display unit can be organic LED display device, and such as this display unit can any product or parts with Presentation Function such as television set, DPF, mobile phone or panel computer.

The utility model embodiment provides a kind of preparation method of organic electroluminescence device, as shown in Figure 3, comprising:

S101, on substrate 10 as shown in Figure 1, form the first electrode 11 by patterning processes.

S102, on aforesaid substrate 10, form third electrode 13 by patterning processes, this third electrode 13 and the first electrode 11 part overlapping, and and to insulate between the first electrode 11.

Concrete, on the substrate being formed with the first electrode 11, insulating barrier 14 can be formed by patterning processes, then form third electrode 13 at the substrate surface forming this insulating barrier 14 by patterning processes.Wherein, this insulating barrier 14 can cover the first electrode 11 completely, only can also form this insulating barrier 14 in the part that third electrode 13 is overlapping with the first electrode 11.

S103, on the substrate being formed with third electrode 13, form organic material function layer and the second electrode 12 successively.

Wherein, the distance H1 of the first electrode 11 and the second electrode 12 is greater than the distance H2 of third electrode 13 and the second electrode 12.

It should be noted that, the patterning processes in the utility model embodiment, can refer to comprise photoetching process, or, comprise photoetching process and etch step, other techniques for the formation of predetermined pattern such as printing, ink-jet can also be comprised simultaneously.Wherein, photoetching process, refers to that utilize photoresist, mask plate, the exposure machine etc. that comprise the technical processs such as film forming, exposure, development form the technique of figure.Can according to the structure choice formed in the utility model corresponding patterning processes.

In addition, a patterning processes in the utility model embodiment, be to form different exposure areas by a mask exposure technique, then the removal such as multiple etching, ashing technique carried out to different exposure areas and finally obtain expecting that pattern is the explanation that example is carried out.

So, between the first electrode and the second electrode, form the first optical microcavity, between third electrode and the second electrode, form the second optical microcavity.Because the distance between the first electrode to the second electrode is greater than the distance between third electrode to the second electrode.In the case, when applying voltage respectively to the first electrode, the second electrode and third electrode, the first optical microcavity and the second optical microcavity can produce the light of different wave length.

Based on this, when having the light poststack in the first colour temperature light and the second optical microcavity with the second colour temperature in the first optical microcavity, this organic electroluminescence device can be made to send have the light of the 3rd colour temperature.Wherein, the first colour temperature, the second colour temperature and the 3rd colour temperature can be different.So, the first colour temperature and the second colour temperature all can have an impact to the numerical value height of the 3rd colour temperature, the adjustable range of device colour temperature therefore, it is possible to increase organic electroluminescence is given out light.

In addition, because above-mentioned 3rd colour temperature is formed by stacking by the first colour temperature and the second colour temperature, even if therefore finely tune the first colour temperature and the second colour temperature, because the superposition amount of the first colour temperature and the second colour temperature changing value can act on the 3rd colour temperature, therefore the 3rd colour temperature numerical value still can realize change by a relatively large margin.And above-mentioned adjustment process is just finely tuned the first colour temperature and the second colour temperature, therefore the electrode voltage value of the first optical microcavity and the second optical microcavity does not have greatly changed, thus avoids causing organic electroluminescence device to occur the problem that luminance difference is larger before and after colour temperature adjustment.

Be described in detail the concrete manufacturing process of the organic electroluminescence device shown in Fig. 2 below, concrete making step as shown in Figure 4.

S201, form the first electrode 11 by patterning processes on the substrate 10.

Concrete, be the metal film layer of 10nm ~ 300nm in surface-coated a layer thickness of glass substrate or resin substrate, preferred 150nm.Wherein, the material forming this metal film layer is the metal material that work function is higher, such as, in metallic aluminium or argent any one.

S202, form insulating barrier 14 and third electrode 13 at the substrate surface being formed with the first electrode 11.

Concrete, first, can on the surface of the first electrode 11, coating one deck has the thin layer of high insulativity, such as silicon oxide film layer.Thickness can be 5nm ~ 20nm, preferred 20nm.Then at surface-coated layer of metal aluminium or the argent thin layer of above-mentioned silicon oxide film layer, thickness can be between 5nm ~ 20nm, preferred 10nm.Then, by a patterning processes, form the consistent insulating barrier 14 of pattern and third electrode 13.

S203, on the substrate being formed with third electrode 13, formed flatness layer 24.

Concrete, the substrate being formed with third electrode 13 applies one deck conducting polymer composite, such as PEDOT:PSS, thickness is between 100nm ~ 300nm, and preferably 200nm, to form the flatness layer 24 of surfacing.Because this flatness layer 24 also has higher conductivity, therefore, it is possible to contribute to the injection in hole.

S204, on the substrate being formed with flatness layer 24, by patterning processes formed hole transmission layer 21.

Concrete, this hole transmission layer 21 can be made up of N, N '-two (1-naphthyl)-N, N '-diphenyl-1,1 '-biphenyl-4-4 '-diamines.Thickness between 5nm ~ 50nm, preferred 10nm.

S205, on the surface being formed with hole transmission layer 21, to be formed by patterning processes.

Concrete, this luminescent layer 20 can be made up of single film layer.Also can as shown in Figure 5, be made up of multi-layer thin rete.Thickness can between 5nm ~ 50nm.

Concrete, for the luminescent layer 20 that multi-layer thin rete is formed, the first sub-luminescent layer 201, wall 202 and the second sub-luminescent layer 203 can be comprised.

Wherein, the first sub-luminescent layer 201 is ruddiness or orange photon luminescent layer, and thickness is 5nm; Material of main part is 4,4'-bis-(9-carbazole) biphenyl 4,4'-bis-carbazole-9-base biphenyl), guest materials is (acetylacetone,2,4-pentanedione) two (2-methyldiphenyl also [F, H] quinoxaline) close iridium, guest materials doping is 0.5wt%.Wall 202 thickness is 5nm.Second sub-luminescent layer 203 is blue photons luminescent layer, thickness is 25nm, its material of main part is 4,4'-bis-(9-carbazole) biphenyl 4,4'-bis-carbazole-9-base biphenyl), guest materials is two (4,6-difluorophenyl pyridinato-N, C2) pyridinecarboxylic closes iridium, and the doping of guest materials is 10wt%.

Certainly, this luminescent layer 20 can also comprise red sub-luminescent layer, blue sub-luminescent layer and green sub-luminescent layer etc.

S206, at the substrate surface being formed with luminescent layer 20, form electron transfer layer 22, electron injecting layer 23 and the second electrode 12 successively by patterning processes.

Concrete, the material of this electron transfer layer 22 can be made up of Bphen (4,7-diphenyl-1,10-ferrosin) shape, and thickness is between 5nm ~ 50nm, preferred 40nm.

The second electrode lay 12 can adopt transparent conductive material, such as ITO or IZO, and thickness is between 10nm ~ 20nm, preferred 10nm.

The above; be only embodiment of the present utility model; but protection range of the present utility model is not limited thereto; anyly be familiar with those skilled in the art in the technical scope that the utility model discloses; change can be expected easily or replace, all should be encompassed within protection range of the present utility model.Therefore, protection range of the present utility model should be as the criterion with the protection range of described claim.

Claims (9)

1. an organic electroluminescence device, comprise the first electrode, the second electrode and the organic material functional layer between described first electrode and described second electrode, it is characterized in that, also comprise and be positioned at the third electrode of described first electrode near described organic material functional layer side;

Described third electrode and described first electrode part overlapping, and and insulate between described first electrode;

The distance of described first electrode and described second electrode is greater than the distance of described third electrode and described second electrode.

2. organic electroluminescence device according to claim 1, is characterized in that, described organic material functional layer comprises hole transmission layer, luminescent layer and electron transfer layer.

3. organic electroluminescence device according to claim 2, is characterized in that, described electron transfer layer is arranged between described luminescent layer and described second electrode.

4. organic electroluminescence device according to claim 2, is characterized in that, described hole transmission layer is arranged between described third electrode and described luminescent layer.

5. organic electroluminescence device according to claim 2, is characterized in that, described organic material functional layer also comprises the flatness layer be arranged between described hole transmission layer and described third electrode.

6. organic electroluminescence device according to claim 1, is characterized in that, the thickness of described third electrode is 5nm ~ 20nm.

7. organic electroluminescence device according to claim 1, is characterized in that, the material forming described first electrode and described third electrode is any one in metallic aluminium or metallic copper.

8. organic electroluminescence device according to claim 5, is characterized in that, the material forming described flatness layer is conducting polymer composite, and thickness is 100nm ~ 300nm.

9. a display unit, is characterized in that, comprises the organic electroluminescence device as described in any one of claim 1-8.