CN1953233B - Light emitting device - Google Patents

Light emitting device Download PDF

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CN1953233B
CN1953233B CN2006101019072A CN200610101907A CN1953233B CN 1953233 B CN1953233 B CN 1953233B CN 2006101019072 A CN2006101019072 A CN 2006101019072A CN 200610101907 A CN200610101907 A CN 200610101907A CN 1953233 B CN1953233 B CN 1953233B
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layer
hole
illuminating element
organic illuminating
zone
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CN1953233A (en
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濑尾哲史
山崎舜平
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Semiconductor Energy Laboratory Co Ltd
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Semiconductor Energy Laboratory Co Ltd
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Abstract

A carrier filling quality between layers in an organic luminescent element is enhanced by application of a hole transporting mixed layer comprising a hole injecting material 811 and a hole transporting material 812, a bipolar-natured mixed layer comprising a hole transporting material 812 and an electron transporting material 813 or an electron transporting mixed layer comprising an electron transporting material 813 and an electron injecting material 814 and further, formation of concentration gradients as shown in Graph 810. By means of this measure, an organic luminescent element of low power consumption and long life is provided, and the organic luminescent element is used to manufacture a luminescent device and an electric appliance.

Description

Luminescent device
The application is that application number is 200610059597.2, the applying date is December 28 calendar year 2001 and while denomination of invention dividing an application for the application of " luminescent device ".
Technical field
The present invention relates to the luminescent device of a kind of use one organic illuminating element, this light-emitting component has anode, and negative electrode and is included in the film that is suitable for producing luminous organic compound when applying electric field (below be called " organic compound layer ").Especially, the present invention relates to a kind of luminescent device of use one organic illuminating element, it is than the lower and longer service life of existing device drive voltage.In addition, the luminescent device that illustrates in the application's specification points out to use a kind of image display device or a kind of luminescent device of an organic illuminating element as light-emitting component.Equally, this luminescent device comprises all modules, connector wherein, flexible printer circuit) or TAB (band automated bonding Tape Automated Bonding) band or TCP (band carrier package Tape Carrier Package) anisotropic conductive film (FPC: for example, be installed to the module on the organic illuminating element, wherein printed circuit board (PCB) is provided at TAB with going up or the module of TCP on most advanced and sophisticated, or wherein IC (integrated circuit) is directly installed on the module on the organic illuminating element in COG (chip is at the Chip OnGlass on glass) system.
Background technology
Organic illuminating element is a kind of luminous element that is suitable for producing when applying electric field.The luminescence mechanism of always thinking is, one organic compound layer is put between the electrode, the electronics of filling from negative electrode when applying voltage there and be combined with each other from the luminescence center of hole organic compound layer that anode is filled and form excited molecule (below be called " molecule exciton "), and it is luminous to emit the energy generation when the molecule exciton is got back to ground state.
In addition, the various molecule excitons that formed by organic compound can comprise singlet excited and triplet excited state, and specification of the present invention comprises any excitation state to luminous contributive situation.
In this organic illuminating element, organic compound layer forms the film less than 1 μ m usually.Equally, because organic illuminating element is the radiative self-luminous type of an organic compound layer light-emitting component itself, the bias light that is used in the conventional liquid crystal display no longer needs.Therefore, organic illuminating element can be formed thin and lightweight highly beneficially.
Equally, the organic compound layer that is about 100-200nm for for example thickness, consider the range of movement of charge carrier in the organic compound layer, be filled into its compound institute from charge carrier and the elapsed time cycle be about for tens nanoseconds, even and comprise when charge carrier is compound to luminous step, luminously in being less than a microsecond approximately, realize. therefore, one of characteristics are that response speed is very big.
In addition, because organic illuminating element is the light-emitting component that a charge carrier is filled type, it can use direct voltage drive, and is difficult to produce noise.With regard to driving voltage, by the thickness of at first making organic compound layer is even, the ultrathin membrane of about 100nm, selects electrode material, and this fills reduce the charge carrier relevant with organic compound layer with potential barrier, and further introduce single heterojunction structure (double structure), can obtain 100cd/m at 5.5V 2Abundant aura (luminance) (document 1:C.W.Tang and S.A.Vanslyke, " organic field luminescence diode ", the Applied Physics communication, the 51st volume, the 12nd phase, 913-915 page or leaf (1987)) (" Organic electroluminescent diodes ", Applied Physics Letters, Vol.51, No.12,913-915 (1987)).
Owing to as thin and in light weight, high-speed response degree, dc low-voltage drive and similar these performances, organic illuminating element receives publicity as flat panel displaying element of future generation.Equally, because organic illuminating element is that self-luminous type and aspect angle are big, they are more favourable aspect visibility and believe that as the element that is used for the portable equipment display be feasible.
So in the formation of the organic illuminating element described in the document 1, by using the Mg of metastable low work function: the Ag alloy improves electronics as negative electrode and injects quality, makes that the charge carrier filling potential barrier relevant with organic compound layer is little.This makes that a large amount of charge carriers fillings are entered organic compound layer becomes possibility.
In addition, be enhanced by jump and constraint by the combined efficiency of using single heterojunction structure charge carrier, in this structure, the hole transport layer of forming by diamine compound and by three (oxine base) aluminium (tris (8-quinolinolato) aluminium, abbreviation; Alq 3) the electron transport luminescent layer formed is stacked as organic compound layer, this will illustrate below.
Only has single Alq at for example organic illuminating element 3Under the situation of layer, because Alq 3Be the electron transport quality, the electronics that major part is filled from negative electrode with under the situation of hole-recombination does not arrive anode, make luminous efficiency very low. promptly launch light (or in low voltage drive) effectively for the organic illuminating element that makes individual layer, need to use a kind of material that can deliver electronics and hole (below be called " bipolar material ") in the mode of balance, and Alq 3Do not satisfy this requirement.
But, use the single heterojunction structure described in the document 1 and make the electronics of filling be stopped by the interface between hole transport layer and electron transport luminescent layer from negative electrode, be enclosed in the electron transport luminescent layer.Therefore, charge carrier is effectively compound in the electron transport luminescent layer provides effectively luminous.
After the notion of this charge carrier barrier functionality was developed, the compound zone of control charge carrier became possibility.As an example, one report is arranged, in view of the above by between hole transport layer and electron transport layer, insert one can blocking hole layer (hole blocking layer), be enclosed in the hole in the hole transport layer and make the luminous achieving success of hole transport layer (document 2:Yasunori KIJIMA, Nobutoshi ASAI and Shin-ichiro TAMURA, " blue organic LED ", Japan's applicating physical magazine, the 38th volume, 5274-5277 (1999)) (" ABlueOrganic Light Emitting Diode ", Japanese Journal of Applied Physics, Vol.38,5274-5277 (1999)).
Equally, can think that the organic illuminating element described in the document 1 is based on, we can say, the thought that function is separated, the delivery in hole is undertaken by hole transport layer in view of the above, and the delivery of electronics and luminously undertaken by the electron transport luminescent layer.The notion that this function is separated has been further development of the notion of double-heterostructure (three-decker), luminescent layer is inserted into (document 3:Chihaya ADACHI between hole transport layer and the electron transport layer in view of the above, Shizuo TOKITO, TetsuoTSUTSUI and Shogo SAITO, " has the electroluminescent in the organic membrane of three-decker ", Japan's applicating physical magazine, the 27th volume, the second phase, L269-L271 page or leaf (1988)) (" Electroluminescence in Organic Films with Three-LayeredStructure ", Japanese Journal of Applied Physics, Vol.27, No2, L269-L271 (1988)).
The advantage that this function is separated is, it is (luminous that the function separation makes a kind of organic material not need to have multiple function simultaneously, charge carrier delivery quality, come the filling quality of the charge carrier of self-electrode, Deng), this provides abundant freedom (for example, not needing excessively to seek bipolar material) for MOLECULE DESIGN or similar problem. and promptly have the material of good luminous quality and charge carrier delivery quality respectively, can easily obtain high-luminous-efficiency by combination.
Owing to these advantages, the notion of the laminated construction described in the document 1 (charge carrier barrier functionality or function are separated) itself is widely adopted so far.
But as the joint between the variety classes material (the particularly joint between insulating material), above-mentioned laminated construction must be in the interface of material produce power potential barrier.Because the existence of energy barrier suppresses the motion of charge carrier at the interface, will cause following two problems.
One of problem is that it causes the potential barrier that causes further reducing driving voltage.In fact existing report, with regard to existing organic illuminating element, the element of single layer structure that utilizes conjugated polymer is fine and keep the maximum data (with the luminous comparison from singlet excited) (document 4:Tetsuo Tsutsui " organic molecule/bioelectronics bulletin " branch of Applied Physics association aspect power efficiency (unit: " lm/W ") aspect driving voltage, the 11st volume, the 1st phase, the 8th page (2000)). (" bulletin of organic molecular/bioelectronics " subcommittee of Society of Applied Physics, Vol.11, P.8 (2000))
In addition, conjugated polymer described in the document 4 is a kind of bipolar material, and with regard to the combined efficiency of charge carrier, can obtain to be equivalent to the level of laminated construction. therefore, its explanation, as long as under the situation of not using any laminated construction, utilize the method for bipolar material that suitable charge carrier combined efficiency can be provided, in fact driving voltage is low to have the single layer structure at less interface.
This can be interpreted as because the interface of motion each interlayer in organic compound layer of charge carrier, and (for example, between hole transport layer and luminescent layer, and being called " organic interface " below) stoped, so need higher drive.
For example, a kind of method is arranged, the interface that the material that wherein is used to relax energy barrier is inserted between electrode and the organic compound layer is filled quality and is reduced driving voltage (document 5:Takeo Wakimoto to improve charge carrier, Yoshinori Fukuda, Kenichi Nagayama, AkiraYokoi, Hitoshi Nakada, with Masami Tsuchida, " use the organic field luminescence unit of alkali metal compound " as the electronics injection material, The Institution of Electrical Engineers's electronic device proceedings, the 44th volume, the 8th phase, 1245-1248 page or leaf (1977)) (" Organic EL CellsUsing Alkaline Metal Compounds as Electron Injection Materials ", IEETRANSACTIONS ON ELECTRON DEVICES, VOL.44, NO.8.1245-1248 (1977)).In document 5, use Li 2O has successfully reduced driving voltage as electron injecting layer.
But, have the still unsolved field of carrier moving quality of organic interface, and this field for reach low driving voltage in utilizing the single layer structure of bipolar material emphasis is proposed.
In addition, another problem that is caused by energy barrier is considered to the influence to the useful life of organic illuminating element.The motion that is charge carrier is prevented from, and because the accumulation brightness decline of electric charge.
When the mechanism that reduces for this quality is not set up any clear and definite when theoretical as yet, one report is arranged, by between anode and hole transport layer, inserting a hole injection layer, and do not use DC driven and with the AC driving of square wave, can suppress lowering of luminance (document 6:S.A.VanSlyke, C.H.Chen, and C.W.Tang, " organic electroluminescenoe device " with stability of having improved, the Applied Physics communication, the 69th volume, the 15th phase, 2160-2162 page or leaf (1996)) (" Organic electroluminescent devices with improvedstability ", Applied Physics Letters, Vol.69, No.15,2160-2162 (1996)).Can think that the document has provided experimental evidence, promptly, can suppress lowering of luminance by eliminating the electric charge accumulation because insert hole injection layer and alternating voltage driving.
Can think from above-mentioned explanation, the advantage of laminated construction is on the one hand, separation can easily improve the combined efficiency of charge carrier and enlarge the material range of choice according to function, stoped the motion of charge carrier and influential and form a plurality of organic interfaces (particularly, for stopping that charge carrier forms organic interface with compound charge carrier) on the other hand to reducing driving voltage and brightness.
Summary of the invention
Therefore the object of the present invention is to provide a kind of organic illuminating element, advantage of the laminated construction that this element optimal utilization is used in correlation technique (function separation) and the energy barrier that is present in the organic compound layer by mitigation improve the mobility of charge carrier rate, and compare the lower while longer service life of this element drives voltage with the element in the correlation technique.
Especially, the objective of the invention is to, the element that has the laminated construction different concepts of using with routine by manufacturing, removal is present in the organic interface in the organic compound layer and improves the mobility of charge carrier rate, wherein the charge carrier in the luminescent layer is blocked with compound, and simultaneously with laminated construction in the function that relates to separate the function (below be called " functional configuration " (functional realization)) that identical mode realizes multiple different materials. thus, the object of the present invention is to provide a kind of organic illuminating element, it is than the lower and longer service life of element drives voltage in the correlation technique.
In addition, the object of the present invention is to provide a kind of luminescent device, it utilizes this organic illuminating element thus than the lower and longer service life of device drive voltage in the correlation technique. in addition, the object of the present invention is to provide a kind of electric device, it with this luminescent device manufacturing with lower and more durable than the rating of set consumption in the correlation technique thus.
The mitigation of energy barrier is obviously found in the technology as document 5 described insertion charge carrier packed layers in the laminated construction. and utilize the energy band diagram among Figure 1B to schematically illustrate hole injection layer.
Among Figure 1A, anode 101 and hole injection layer 102 directly engage one another, relevant with anode 101 and hole injection layer 102 in this case energy barrier 104 is big. still, by inserting a kind of its highest material that is occupied the middle part between the HOMO energy level that molecular orbital energy level (below be called " HOMO ") is positioned at the ionization potential (being equivalent to work function under the metal situation) of anode and hole transport layer as hole injection layer 103, mode (Figure 1B) design that energy barrier can segmentation.
The segmentation energy barrier of design shown in Figure 1B makes the filling quality that improves the charge carrier that comes self-electrode, and necessarily reduce driving voltage to becoming possibility to a certain degree. still, the problem that produces is that the increase of the number of layer causes the increase of organic interface number. this is considered to single layer structure keeps the maximum data aspect driving voltage and power efficiency reason in document 4.
On the contrary, by overcoming this problem, during the advantage in the optimum utilization laminated construction (various materials can be combined, and do not need complicated MOLECULE DESIGN), reach with single layer structure in same drive voltage and power efficiency level be possible.
Therefore basic concept can be, can relax the energy barrier that is present in the organic compound layer under the situation that does not increase the organic interface number, and not stop the motion of charge carrier.The inventor has designed a kind of component structure that can realize this notion by following mode.
At first, the method that relaxes the energy barrier relevant with the hole can provide one deck (below be called " hole transports mixed layer "), this layer mixes by the hole conveying material with the hole-injecting material of high HOMO energy level (ionization potential is little) and high hole mobility and obtains. and this method makes individual layer realize comprising that the two-layer function of conventional hole injection layer and conventional hole transport layer becomes possibility, make to transport in the mixed layer that hole-injecting material is used to receive from the hole of anode one side and the hole input material is used to deliver the hole in the hole.
Equally, preferably transport and form concentration gradient in the mixed layer in above-mentioned hole. promptly as shown in Figure 2, increase towards anode direction hole-injecting material ratio, and along with increasing away from anode hole transport material ratio. owing to form this concentration gradient, the hole is steadily received and delivery from anode one side under the situation that does not produce any macro-energy potential barrier, and this has contribution to reducing driving voltage and increasing the service life.
In addition, in Fig. 2, concentration gradient is shown for simplicity but not necessarily needs requirement to be defined as this straight line with straight line, and concentration gradient is formed increase or reduces just enough. in fact, it is generally acknowledged that the curve when concentration gradient is by control is under many circumstances determined. the same applies to other concentration gradient described in the present specification.
Secondly, the method that relaxes the energy barrier relevant with electronics can provide one deck (below be called " electron transport mixed layer "), and this layer mixes and obtains by hanging down minimum molecular orbit (below be called " LUMO ") the electronics injection material of energy level (electron affinity is big) and the electron transport material of high electron mobility of not occupied.This method makes individual layer realize comprising that conventional electrical implanted layer and the two-layer function of conventional electrical transport layer become possibility, makes in the electron transport mixed layer, and the electronics injection material is used to receive from the electronics of negative electrode one side and electron transport material is used to deliver electronics.
Equally, preferably in above-mentioned electron transport mixed layer, form concentration gradient. promptly as shown in Figure 3, increase towards cathode direction electronics injection material ratio, and along with increasing away from cathode electronics conveying material ratio. owing to form this concentration gradient, electronics is steadily received from negative electrode one side and is delivered under the situation that does not produce any macro-energy potential barrier, and this has contribution to reducing driving voltage and increasing the service life.
In addition, a kind of method that relaxes the energy barrier relevant with luminescent layer is arranged.Be that luminescent layer can be provided by bipolar layer (below be called " mixed layer of dipole characteristic "), this layer mixes by the electron transport material with the hole conveying material of high hole mobility and high electron mobility and obtains. in this case, luminescent layer reduces its two ends charge carrier barrier functionality at the interface, but because between electron transport layer and the dipole characteristic mixed layer, and the difference of mobility between hole transport layer and the dipole characteristic mixed layer, the combination frequency of charge carrier is higher.
Equally, preferably in above-mentioned dipole characteristic mixed layer, form concentration gradient. promptly as shown in Figure 4, increase towards anode direction hole conveying material ratio, and increase towards cathode direction electronics transporting material ratio. owing to form this concentration gradient, under the situation that does not produce any macro-energy potential barrier, hole and electronics steadily carry out from being carried to compound step, and this has contribution to reducing driving voltage and increasing the service life.
Can think that in addition in the dipole characteristic mixed layer, the material emission light with low excitation energy is more. refer to energy difference between HOMO and the LUMO in the excitation energy described in the present specification.HOMO available light electronic spectrum is measured, and can think and be equal to ionization potential. and same, for simplicity, excitation energy is defined in the end of absorption spectrum, can calculate LUMO. from excitation energy and HOMO energy level value
In addition, have that doped luminescent material is used for photoemissive method in a kind of superincumbent dipole characteristic mixed layer. in this case, must have than being included in the hole conveying material in the dipole characteristic mixed layer and the low excitation energy of excitation energy of electron transport material as the luminescent material of alloy. especially, preferably use a kind of alloy (lycid alkene) of carrier capture type to be used for further increasing the charge carrier combined efficiency.
Equally, hole blocking layer described in the document 2 is made up of barrier material usually. and barrier material is generally a kind of material that has than the bigger excitation energy of excitation energy of luminescent material (promptly can prevent the disperse of molecule exciton), and material can stop charge carrier. under many circumstances, be that the hole is blocked.
The application's inventor has designed the method for a kind of formation one deck (below be called " barrier properties mixed layer "), this layer obtains by the material (or host material of luminescent layer) that mixes barrier material and luminescent layer. in this case, the barrier properties mixed layer can play luminescent layer equally, can be considered to a luminescent layer that charge carrier and molecule exciton effectively can be stopped wherein equally.
Especially, the barrier properties mixed layer is preferably formed to having concentration gradient. and this is because the charge carrier (electronics under the hole barrier materials situation) that is not blocked in one of multilayer can steadily move by the concentration along with the barrier material that increases gradually away from luminescent layer.
So, in recent years, the organic illuminating element that the energy of emitting (below be called " triple excitation energy ") can be converted to aura when triplet excited state is got back to ground state is successfully proposed, and noticed their luminous efficiency (document 7:D.F.O ' Brien, M.A.Baldo, M.E.Thompson and S.R.Forrest, " improved power conversion in control phosphorescence (eletrophosphorescent) device ", the Applied Physics communication, the 74th volume, the 3rd phase, 442-444 page or leaf (1999) (" Improved energy transfer in electrophosphorescentdevices ", Applied Physics Letters, Vol.74.No.3,442-444 (1999)), (document 8:Tetsuo TSUTSUI, Moon-Jae YANG, Masayuki YAHIRO, KenjiNAKAMURA, Teruichi WATANABE, Taishi TSUJI, YoshinoriFUKUDA, Takeo WAKIMOTO and Satoshi MIYAGUCHI, " use iridium complex " as the high-quantum efficiency in the organic luminescent device of triple launching centres, Japan's applicating physical magazine, the 38th volume, L1502-L1504 page or leaf (1999) (" High QuantumEfficiency in Organic Luminescent devices with Iridium-Complex as aTriplet Emissive Center ", Japanese Journal of Applied Physics, Vol.38, L1502-L1504 (1999)).
Use the metal complex of a kind of its central metal in the document 7, and use the metal complex of a kind of its central metal in the document 8 as iridium as platinum.These organic illuminating elements (below be called " triple light-emitting diode ") that triple excitation energy can be converted to aura can obtain the luminous efficiency than more high-intensity aura and Geng Gao in the correlation technique.
But document 8 is given in preliminary glow and is set at 500cd/m 2Situation under, the half-life of aura is about 170 hours example, so therefore problem in producing component useful life., the present invention is applied to triple light emitting diodes can provide high function light-emitting component, based on the aura from triplet excited state, it goes back long service life except that having high-intensity aura and high-luminous-efficiency.
Therefore, the present invention relates to its notion is applied to triple light emitting diodes, make the motion that a mixed layer comes steady charge carrier with the number (or relaxing energy barrier) that reduces the interface according to this notion charge carrier delivery layer and luminescent layer.
Good, the application's inventor has the consideration of two kinds of following mechanism as a model, wherein by forming the motion that organic interface stops charge carrier.
At first, one of mechanism of being considered is to be produced by the form of organic interface.Organic compound layer in the organic illuminating element is made up of amorphous film usually, this molecule of organic compound is assembled owing to the main molecular separating force based on dipole-dipole interaction. still, when this gathering of molecule was used to form heterostructure (laminated construction), the difference of molecular size and molecular configuration form may be to the very large influence in interface (being organic interface) of heterostructure.
Especially, being used to form under the situation of heterostructure, can believing that the aligning in the junction of organic interface degenerates at the very different material of molecular size. this notion is shown in Figure 21.In Figure 21, the ground floor of being made up of micromolecule 2,101 2111 and the second layer of being made up of big molecule 2,102 2112 are laminated in together. and in this case, the alignment area 2114 of difference is created on the organic interface 2113 of formation.
Because the alignment area 2114 of the difference shown in Figure 21 may cause the potential barrier (or energy barrier) that stops carrier moving, this means that they have made obstacle for further reducing driving voltage.Equally, the charge carrier that can not cross energy barrier as electric charge accumulation may bring out as mentioned above reduce luminous.
Another mechanism of being considered is created in the technology that forms laminated construction (being organic interface).From the viewpoint that stops that charge carrier separates with function, the organic illuminating element of laminated construction usually uses multichamber type (type in upright arrangement) deposition apparatus manufacturing as shown in figure 22 to pollute when each layer formation avoiding.
Figure 22 is a conceptual view, illustrate and be used to form by hole transport layer, luminescent layer, the example of the deposition apparatus of the three-decker of forming with electron transport layer (double-heterostructure). at first, have anode (indium tin oxide (below be called " ITO ") or similar oxide) substrate be loaded into the chamber of packing into, and in the ultraviolet irradiation chamber, under vacuum environment, be subjected to ultraviolet irradiation anode purge surface. particularly, when anode is made by the oxide of for example ITO, need in pretreatment chamber, carry out oxidation. in addition, in order to form each layer of laminated construction, hole transport layer needs to carry out deposit in deposition chamber 2201, luminescent layer (comprises red in Figure 22, green and blue three-color) deposit in deposition chamber 2202 to 2204, electron transport layer deposit in deposition chamber 2205, and negative electrode deposit in deposition chamber 2206.At last, in closed chamber, seal, and from take out the chamber, take out, obtain an organic illuminating element.
The characteristics of this type deposition apparatus in upright arrangement are that the deposit of each layer is carried out respectively in different deposition chamber 2201 to 2205. be equipment is so constructed and makes that the material of each layer is mixed mutually hardly.
Though the inside of deposition apparatus is depressurized to about 10 usually -4-10 -5Pa, but have trace gas component (oxygen, water etc.). under this vacuum degree situation, it is generally acknowledged, even trace gas component also will in seconds form an adsorption layer that is equivalent to be about monolayer easily.
Therefore, be used to make at equipment shown in Figure 22 under the situation of organic illuminating element of laminated construction, the big time interval that produces when forming each layer becomes problem. and the adsorption layer of worrying to be caused by trace gas component (below be called " impurity layer ") may be in the time interval in forming each layer process, particularly in formation when second takes out the chamber transportation.
Figure 23 illustrates above-mentioned notion.Figure 23 illustrates a state, wherein work as the ground floor of forming by first organic compound 2,301 2311 and the second layer of forming by second organic compound 2,302 2312 and be laminated in a time-out, the impurity layer of being made up of trace impurity 2303 (water, oxygen or similar impurity) 2313 is formed between first and second layers.
Be formed on impurity layer between each layer (organic interface) by this way and make and after finishing organic illuminating element, become the extrinsic region that is easy to capture charge carrier, stop the motion of charge carrier thus, so cause the rising of driving voltage.In addition, when existence was easy to capture the extrinsic region of charge carrier, electric charge may bring out the reduction aura as mentioned above in this zone accumulation.
Consider these mechanism, for overcoming the problem that produces at above-mentioned organic interface (form of organic interface degenerates and the formation of impurity layer), need component structure and manufacturing process all irrelevant with the conventional element of laminated construction. an example of the organic illuminating element of being removed fully from it as organic interface, a kind of organic illuminating element is in the news, has only the simple layer only be made up of the mixture of hole conveying material and electron transport material (below be called " single mixed layer ") to be provided between two electrodes in this element.(document 9:Shigeki NAKA, Kazuhisa SHINNO, Hiroyuki OKADA, Hiroshi ONNAGAWA and Kazuo MIYASHITA, " use the organic electroluminescenoe device of the individual layer that mixes ", Japan's applicating physical magazine, the 33rd volume, the 12B phase, L1772-L1774 page or leaf (1994)) (" Organic ElectroluminescentDevices Using a Mixed Single Layer ", Japanese Journal of AppliedPhysics, Vol.33, No.12B, L1772-1774 (1994)).
In document 9, transport 4 of quality by having the hole by 1: 4 mixed, 4 '-two [N-(3-aminomethyl phenyl)-N-phenyl amino] biphenyl (4,4 '-bis[N-(3-methylphenyl)-N-phenyl-amino]-biphenyl, be called " TPD " below) and Alq with electron transport quality 3Form single layer structure.But, with single layer structure and laminated construction (promptly by TPD and Alq 3The heterostructure that the organic interface of forming forms) compare and show that with regard to luminous efficiency, the former is not as laminated construction.
Its reason is considered to, and for single mixed layer, does not often have the compound opposite electrode that promptly passes to from hole that anode is filled and the electronics of filling from negative electrode. because the laminated construction effect is to stop charge carrier, can not cause this problem.
In other words, unless can think that this is because do not produce functional configuration in document 9 described single mixed layers. promptly in organic compound layer, provide the zone that can realize various functions, for example be used as the zone that the hole transports near anode, near the zone of negative electrode as electron transport, with light-emitting zone (being the compound zone of charge carrier) away from two electrodes, even when organic interface is removed, can not produce effective light emission yet. because whole organic compound layer is as luminescent layer, light emission might be near electrode. and the result causes quencher in energy is passed to the process of electrode.
So, consider that single mixed layer can not show its function fully, the application's inventor has designed a kind of method that realizes organic illuminating element, wherein when the mixed layer of dipole characteristic shown in Fig. 4 forms light-emitting zone, remove any organic interface, and functional configuration may be different from document 7 disclosed contents.Figure 24 illustrates above-mentioned notion.
Among Figure 24, be provided at and in the organic compound layer of forming by two kinds of materials that comprise hole conveying material and electron transport material 2403 be, the hole of being made up of the hole conveying material transports zone 2405, the electron transport zone of forming by electron transport material 2406, though wherein Mixed Zone 2407. anodes 2402 that mix of hole conveying material and electron transport material are provided on the substrate 2401, can adopt negative electrode 2404 to be provided at inversion structures on the substrate. in addition, by this element, do not form for example layer structure of determining of hole transport layer, thereby use every kind of function of term " zone " expression.
Under the situation that forms this element, the hole conveying material can receive and the delivery hole in anode-side, and electron transport material can receive and the delivery electronics at cathode side simultaneously.In addition, because Mixed Zone 2407 is dipole characteristic, hole and electronics all can move for 2407 li past Mixed Zone, and charge carrier compound generation aura in Mixed Zone 2407.Promptly different with disclosed single mixed layer in the document 9, can show that the zone of various functions is present in the organic compound layer 2403.
In addition, for element shown in Figure 24, functional configuration is possible, but does not have the organic interface in the conventional laminated construction.Equally, by being separated with two electrodes as far as possible far, light-emitting zone can prevent quencher.Therefore, it is possible solving the problem that produces at above-mentioned organic interface (the organic interface form degenerates and the formation of impurity layer).
At first, to provide the explanation that solution organic interface form degenerates with reference to Figure 25. Figure 25 illustrates an organic illuminating element, it has the feature of Figure 24, and comprise the zone of forming by micromolecule 2,501 2511, the zone of forming by big molecule 2,502 2512 and comprise micromolecule 2501 and both Mixed Zones 2513 of big molecule 2502.Conspicuous from Figure 25, not only there is not the organic interface 2113 shown in Figure 21, there is not poor alignment area 2114 yet.
Equally, the solution that forms impurity layer is simple and clear. in the manufacturing of as shown in Figure 24 organic illuminating element, the hole conveying material is deposited on the anode, additionally the deposit electron transport material forms the Mixed Zone with the form of codeposition midway, and after forming the Mixed Zone, the deposit that can stop the hole conveying material is to allow the deposit of electron transport material.Therefore, there is not the time interval that produces in the process of using the manufacturing of deposition apparatus shown in Figure 22 organic illuminating element. promptly do not form the chance of any impurity layer.
So, do not form organic interface, so the motion of charge carrier is mild and to the driving voltage of element with there is not negative effect useful life according to organic illuminating element of the present invention.In addition, separate by relating to the function that resembles laminated construction, no problem aspect luminous efficiency.
Equally, conventional laminated construction has the simple heterogeneous joint between different material, and has so-called mixing joint and can think a kind of organic illuminating element based on new ideas according to structure of the present invention.
Therefore, the invention provides a kind of luminescent device that comprises an organic illuminating element, this light-emitting component comprises anode, negative electrode and be provided at anode and negative electrode between organic compound layer, and wherein organic compound layer comprises that the hole of being made up of its hole mobility hole conveying material higher than electron mobility transports the zone, the electron transport zone of forming by its electron mobility electron transport material higher than hole mobility, the hole transports the zone than the close anode arrangement in electron transport zone, and is provided at the Mixed Zone that the hole transports between zone and the electron transport zone and comprises hole conveying material and electron transport material.
In addition, for structure shown in Figure 24, fill the hole injection zone that the material of quality (below be called " hole-injecting material ") forms and to be inserted between anode and the organic compound layer by being used to improve holoe carrier.Equally, fill the electron injection region territory that the material of quality (below be called " electronics injection material ") forms and can be inserted between negative electrode and the organic compound layer by being used to improve electronic carrier. in addition, hole injection zone and electron injection region territory can all be inserted into.
In this case, because hole-injecting material or electronics injection material are the materials that a kind of charge carrier that is used to reduce from the electrode to the organic compound layer is filled potential barrier, the motion of charge carrier from the electrode to the organic compound layer that it is steady, therefore be effective aspect the accumulation of elimination electric charge. still, for fear of the formation of above-mentioned any impurity layer, preferably deposit is carried out in not free compartment of terrain between each packing material and organic compound layer.
So, with regard to carrier balance control, preferably in the Mixed Zone that comprises hole conveying material and electron transport material, form concentration gradient, make and to reduce gradually and the concentration of electron transport material increases gradually along the direction hole input material concentration from the anode to the negative electrode. same, because the Mixed Zone is the charge carrier recombination region equally, it has 10nm or thicker thickness is that the present invention is desirable.
Equally, the present invention relates to the structure as shown in Figure 26 A, wherein be provided at having in the organic compound layer 2603, the hole of being made up of the hole conveying material transports zone 2605, the electron transport zone of forming by electron transport material 2606, and the Mixed Zone 2607 that is mixed together of hole conveying material and electron transport material wherein, and provide the luminescent material 2608 of aura to add Mixed Zone 2607 as alloy.In addition, though anode 2602 is provided on the substrate 2601, can adopt negative electrode 2604 to be provided at inversion structures on the substrate.Same hole injection zone and electron injection region territory can be provided between electrode and the organic compound layer.
When luminescent material 2608 added Mixed Zones 2607, luminescent material 2608 was captured charge carrier, made combined efficiency improve and can expect high-luminous-efficiency. can think that one of feature is, and can be by luminescent material 2608 control glow colors.But in this case, excitation energy is minimum among the preferred compound of luminescent material 2608 in being included in Mixed Zone 2607.
The quencher that causes when light-emitting zone can be prevented that energy from passing to electrode material away from two electrodes as far as possible. therefore, the zone of doped luminescent material is not the whole zone in the Mixed Zone and may be the part (particularly, core) of Mixed Zone.
In addition, the present invention relates to a structure as shown in Figure 26 B, wherein be provided at having in the organic compound layer 2603, the hole of being made up of the hole conveying material transports zone 2605, the electron transport zone of forming by electron transport material 2606, and the Mixed Zone 2607 that is mixed together of hole conveying material and electron transport material wherein, and barrier material 2609 is added into Mixed Zone 2607. in addition, though anode 2602 is provided on the substrate 2601, can adopt negative electrode 2604 wherein to be configured in inversion structures on the substrate. same, hole injection zone and electron injection region territory can be provided between electrode and the organic compound layer.
When barrier material 2609 adds Mixed Zone 2607, the charge carrier combined efficiency improves and prevents the disperse of molecule exciton in the Mixed Zone 2607, make and can expect high luminous efficiency. but in this case, excitation level is the highest among the preferred material of barrier material in being included in Mixed Zone 2607.
Equally, because barrier material plays the effect of one of blocking hole and electronics as a rule, it destroys the carrier balance in this Mixed Zone sometimes when mixing in whole Mixed Zone.Therefore, the zone of doping barrier material is not the whole zone in the Mixed Zone and may be the part (particularly, boundary member) of Mixed Zone.
In addition, as preferred examples more among Figure 26 B, add luminescent material 2608.Promptly this structural form comprise with Figure 26 A in the combination of structural form.Have at barrier material 2609 under the situation of hole barrier quality,, shown in Figure 26 B, make luminescent material 2608 effectively luminous by adding hole barrier materials in a side than the more close negative electrode in zone that adds luminescent material 2608.
Equally, apply the present invention to triple light emitting diodes a kind of H.D light-emitting component can be provided, this light-emitting component removes to have based on high-intensity aura and high-luminous-efficiency from the triplet excited state aura, compares with disclosed element in the document 8 also to have long useful life.
In addition, because bigger than three weight molecule exciton diffusion lengths with substance molecule excitonic phase, preferably, barrier material is included in the Mixed Zone.Promptly with reference to Figure 26 B explanation, the material (below be called " triple luminescent material ") that triple excitation energy can be converted to aura is used as luminescent material 2608 and adds barrier material 2609 simultaneously is desirable.
Thereafter, the example that is suitable for making will be described in relating in the structure of adding luminescent material shown in Figure 26 A and 26B. and Figure 27 illustrates this component structure.
For element shown in Figure 27, be provided at and in the bag and the organic compound layer 2703 of hole conveying material and electron transport material be, the hole of being made up of the hole conveying material transports zone 2705, the electron transport zone of forming by electron transport material 2706, the Mixed Zone 2707 that hole conveying material and electron transport material mix by certain ratio wherein, and provide the luminescent material 2708 of aura to add Mixed Zone 2707 formation light-emitting zones.Though anode 2702 is provided on the substrate 2701, can adopt negative electrode 2704 to be provided at inversion structures on the substrate.
In addition, Figure 28 illustrates the CONCENTRATION DISTRIBUTION under the situation that the concentration ratio of hole conveying material and electron transport material in the Mixed Zone is x: y.
Forming under the situation of this element, the hole conveying material can receive and delivery hole and electron transport material can receive and the delivery electronics at cathode side in anode-side.In addition, because Mixed Zone 2707 is dipole characteristic, hole and electronics all can move for 2707 li past Mixed Zone. and same, owing to the certain proportion x in the Mixed Zone 2707: y, manufacturing is easy.
At this, it is basic that the light-emitting zone that comprises luminescent material is formed in the Mixed Zone 2707.Promptly in Mixed Zone 2707, add luminescent material and prevent that charge carrier from not having compound and pass the Mixed Zone, and make light-emitting zone simultaneously away from the quencher of electrode to prevent to cause by electrode.
Therefore, the invention provides a kind of luminescent device that comprises an organic illuminating element, this light-emitting component comprises anode, negative electrode, and be provided at organic compound layer between anode and the negative electrode, and wherein organic compound layer comprises that the hole of being made up of the hole conveying material transports the zone, the electron transport zone of forming by electron transport material, and be provided at that the hole transports between zone and the electron transport zone and, and be provided in the Mixed Zone and add the light-emitting zone of the luminescent material that is suitable for providing aura therein by the Mixed Zone that comprises hole conveying material and electron transport material of special ratios.
In addition, compare with electron transport material with the hole conveying material, the excitation energy of preferred luminescent material is little. this is for preventing that the energy in the molecule exciton from shifting.
Equally, for structure shown in Figure 27, fill the hole injection zone that the material of quality (below be called " hole-injecting material ") forms and can be inserted between anode and the organic compound layer by being used to improve the hole. same, the electron injection region territory of being made up of the material that is used to improve electronics filling quality (below be called " electronics injection material ") can be inserted between negative electrode and the organic compound layer.In addition, hole injection zone and electron injection region territory can all be inserted into.
In this case, because hole-injecting material or electronics injection material are a kind of materials of filling potential barrier from electrode to the organic compound layer charge carrier that is used to reduce, the motion of charge carrier from the electrode to the organic compound layer that it is steady, therefore be effective aspect the accumulation of elimination electric charge. still, for avoiding the formation of above-mentioned any impurity layer, preferably no time interval ground carries out deposit between each packing material and organic compound layer.
Equally, the part that is used for compound charge carrier is (when it becomes dipole characteristic, basically be in the middle of being arranged in) determine in the Mixed Zone basically with depending on its mixing ratio. therefore, luminescent material can add (Figure 29 A) in whole Mixed Zone, but also can add (Figure 29 B) in the part of Mixed Zone.In addition, reference number is used for presentation graphs 29A and 29B among Figure 27.
In addition, the present invention relates to a structure as shown in Figure 30 A, wherein be provided at having in the organic compound layer 2703, the hole of being made up of the hole conveying material transports zone 2705, the electron transport zone of forming by electron transport material 2706, wherein hole conveying material and electron transport material are mixed together, and luminescent material is added into Mixed Zone 2707 wherein, and barrier material 2709 is added into Mixed Zone 2707.In addition, though anode 2702 is provided on the substrate 2701, can adopt negative electrode 2704 wherein to be provided at inversion structures on the substrate. same, hole injection zone and electron injection region territory can be provided between electrode and the organic compound layer.
In this case, excitation level is maximum among the preferred material of barrier material in being included in Mixed Zone 2707, and is a kind of material that stops charge carrier or prevent molecule exciton diffusion that has.When barrier material 2709 is added into Mixed Zone 2707, charge carrier combined efficiency in the Mixed Zone 2707 is enhanced and the Mass of molecule exciton can be prevented from, make high-luminous-efficiency to expect. still, because barrier material plays the effect of one of blocking hole and electronics as a rule, it destroys the carrier balance in this Mixed Zone sometimes when adding in whole Mixed Zone. and therefore, the zone of adding barrier material is not whole zone in the Mixed Zone but the part of Mixed Zone.
Equally, low to effectively a kind of HOMO energy level of barrier material usually, material that promptly can blocking hole.Therefore, shown in Figure 30 B, the method that barrier material is added the zone of cathode side rather than adding luminescent material 2708 is useful.
In addition, use triple light-emitting materials and can provide a kind of high function light-emitting component as the luminescent material that adds this component structure, based on aura from triplet excited state, it also has the long life except that having high-intensity aura and high-luminous-efficiency. in addition, because bigger than three weight molecule exciton diffusion lengths with substance molecule excitonic phase, preferred barrier material is included in the Mixed Zone.
So, because the above-mentioned Mixed Zone of being made up of hole conveying material and electron transport material need have dipole characteristic, the quality of hole conveying material is more than or equal to 10% and is less than or equal to 90%. still with the ratio of the gross mass of hole conveying material and electron transport material in the preferred Mixed Zone, can believe the combination of depending on material, the excursion of this ratio is very big.
Equally, because the Mixed Zone be made up of hole conveying material and electron transport material comprises a light-emitting zone, i.e. charge carrier recombination region, it need have some thickness so that do not allow charge carrier to pass.Therefore, the Mixed Zone has 10nm or thicker thickness is desirable.Equally, it should be noted that the regional resistance height that becomes dipole characteristic, above-mentioned thickness be 100nm or thinner be desirable.
A kind of luminescent device of and longer service life lower than existing device drive voltage, can provide by putting into practice foregoing invention. in addition, a kind of electric device, it is lower and more durable than rating of set consumption of the prior art, can provide when using this luminescent device to make.
Description of drawings
Figure 1A and 1B are the view that the hole injection layer effect is shown.
Fig. 2 is the view that concentration gradient is shown.
Fig. 3 is the view that concentration gradient is shown.
Fig. 4 is the view that concentration gradient is shown.
Fig. 5 is the view that a kind of structure of organic illuminating element is shown.
Fig. 6 is the view that a kind of structure of organic illuminating element is shown.
Fig. 7 is the view that a kind of structure of organic illuminating element is shown.
Fig. 8 is the view that a kind of structure of organic illuminating element is shown.
Fig. 9 is the view that a kind of structure of organic illuminating element is shown.
Figure 10 is the view that a kind of structure of organic illuminating element is shown.
Figure 11 is the view that a kind of deposition apparatus is shown.
Figure 12 A and 12B are the view that a luminescent device profile construction is shown.
Figure 13 A and 13B are the view that luminescent device top surface structure and profile construction are shown.
Figure 14 A to 14C is the view that luminescent device top surface structure and profile construction are shown.
Figure 15 A and 15B are the view that luminescent device structure is shown.
Figure 16 A and 16B are the view that luminescent device structure is shown.
Figure 17 A to 17F is the view that the electric device instantiation is shown.
Figure 18 A and 18B are the view that the electric device instantiation is shown.
Figure 19 A and 19B are the view that energy band diagram is shown.
Figure 20 A and 20B are the view that energy band diagram is shown.
Figure 21 is the view that the organic compound layer state is shown.
Figure 22 is the view that a deposition apparatus is shown.
Figure 23 illustrates the view that forms impurity layer.
Figure 24 is the view that the structure of organic illuminating element is shown.
Figure 25 is the view that the organic compound layer state is shown.
Figure 26 A and 26B are the view that the structure of organic illuminating element is shown.
Figure 27 is the view that the structure of organic illuminating element is shown.
Figure 28 is the view that CONCENTRATION DISTRIBUTION is shown.
Figure 29 A and 29B are the view that the structure of organic illuminating element is shown.
Figure 30 A and 30B are the view that the structure of organic illuminating element is shown.
Figure 31 A and 31B are the view that a deposition apparatus is shown.
Figure 32 A and 32B are the view that a deposition apparatus is shown.
Figure 33 is the view that the structure of organic illuminating element is shown.
Figure 34 is the view that a luminescent device profile construction is shown.
Figure 35 is the view that a luminescent device profile construction is shown.
Figure 36 A to 36C is the view that a luminescent device structural form is shown.
Figure 37 is the view that circuit structure is shown.
Embodiment
Below embodiments of the invention will be described. in addition, anode in the organic illuminating element and at least one in the negative electrode can be fully transparent luminous to take out, and embodiment puts up with wherein transparent anode and is formed on the substrate and light is described by the component structure that takes out from anode.In fact, the light structure of taking out from negative electrode wherein all is applicatory with the structure from a relative side-draw bright dipping with substrate wherein.
At first, provide to form with reference to Fig. 5 and have the explanation of embodiment that the hole transports a kind of organic illuminating element of mixed layer. a kind of structure shown in Fig. 5, wherein the hole transports mixed layer 503, luminescent layer 504, electron transport layer 505 and negative electrode 506 are laminated on the substrate 501 with anode 502.In addition, it is possible that luminescent layer 504 is not inserted into, and is responsible for luminous but the hole transports mixed layer 503 or electron transport layer 505. the hole transports mixed layer 503 and is formed by the mixture of hole-injecting material and hole conveying material.
In addition, as shown in Figure 2, the hole of being made up of hole-injecting material and hole conveying material transports mixed layer 503 and is formed and has concentration gradient. in this case, when high insulating material when for example aluminium oxide is used as hole-injecting material, preferred hole-injecting material has steep concentration gradient (weakening to anode-side fast).
Thereafter, provide the explanation of the embodiment of a kind of organic illuminating element that forms the electron transport mixed layer with reference to Fig. 6. a kind of structure shown in Fig. 6, wherein hole transport layer 603, luminescent layer 604, electron transport mixed layer 605 and negative electrode 606 are laminated on the substrate 601 with anode 602.In addition, it is possible that luminescent layer 604 is not inserted into, but electron transport mixed layer 605 or hole transport layer 603 are responsible for luminous.Electron transport mixed layer 605 is formed by the mixture of electronics injection material and electron transport material.
In addition, as shown in Figure 3, the electron transport mixed layer of being made up of electronics injection material and electron transport material 605 can be formed has concentration gradient.In this case, when high insulating material when for example lithium fluoride is used as the electronics injection material, the preferred electron injection material has steep concentration gradient (weakening to anode-side fast).
Thereafter, provide the explanation of the embodiment that forms a kind of organic illuminating element with dipole characteristic mixed layer with reference to Fig. 7. a kind of structure shown in Fig. 7, wherein hole injection layer 703, the mixed layer 704 of dipole characteristic, electron injecting layer 705 and negative electrode 706 are laminated on the substrate 701 with anode 702. and the mixed layer 704 of dipole characteristic is formed by the mixture of hole conveying material and electron transport material.
In addition, as shown in Figure 4, the mixed layer 704 of the dipole characteristic of being made up of hole conveying material and electron transport material can be formed has concentration gradient.
Equally, as shown in figure 24, by the hole being transported the electron transport material that zone 2405 constituent material is used for being included in the hole conveying material of Mixed Zone 2407 and the constituent material in electron transport zone 2406 is used for being included in Mixed Zone 2407, can be with Mixed Zone 2407, the hole transports zone 2405 and electron transport zone 2406 engages successively.One advantage is arranged in this case, and two kinds of compounds (hole conveying material and electron transport material) can play and comprise in the prior art that the hole transports the zone, three layers the effect in light-emitting zone and electron transport zone.In addition, though not shown in Figure 24, hole injection layer can insert anode 2402 and the hole transports between the zone 2405, and electron injecting layer can insert between negative electrode 2404 and the electron transport zone 2406.
Implement this component structure to prevent to form impurity layer. in this case, the manufacturing process of organic illuminating element is important. at this, will a kind of example that is suitable for making the method for this component structure be described.
Figure 31 A and 31B are the conceptual view that deposition apparatus is shown.Figure 31 A illustrates the top view of equipment.Deposition apparatus is the single chamber type, and wherein single vacuum chamber 3110 is installed as deposition chamber, and a plurality of deposits source is provided in the vacuum tank.Being placed in respectively in a plurality of deposits source is the various materials with difference in functionality, hole-injecting material for example, hole conveying material, electron transport material, electronics injection material, barrier material, the constituent material of luminescent material and negative electrode.
In this deposition apparatus with deposition chamber, the substrate that has anode (ITO or similar material) at first is transported to conveying room, and under the situation of anode, in pretreatment chamber, carry out oxidation (in addition for for example oxide of ITO, though not shown in Figure 31 A, a ultraviolet irradiation chamber is installed, and to be used for the anode purge surface be possible).In addition, all material that forms organic illuminating element carries out deposit in vacuum chamber 3110.But negative electrode can form in vacuum chamber 3110, or can be the deposition chamber that the formation negative electrode provided open in a fen. in a word, realize that in single vacuum chamber 3110 deposit is enough up to forming negative electrode.At last, seal and after take out the carrying chamber, obtain organic illuminating element from conveying room at closed chamber.
To provide the explanation of the step of the deposition apparatus manufacturing organic illuminating element of the present invention that utilizes this single chamber type with reference to Figure 31 B (vacuum chamber 3110 profiles).Be purposes of simplicity of explanation, Figure 31 B illustrates and utilizes the vacuum chamber 3110 with two deposit sources (organic compound deposit source a3118 and organic compound deposit source b3119), forms the step of the organic compound layer that comprises hole conveying material 3116 and electron transport material 3117.
At first, the substrate 3101 that has an anode 3102 is loaded into vacuum chamber 3110 and is fixed on (substrate rotates usually in deposition process) on the fixed pedestal 3111. subsequently, and in vacuum chamber 3110 decompressions (preferred 10 -4Pa or lower) after, heating container a3112 opens baffle plate a3114 and begins deposit with evaporation hole conveying material 3116 and after reaching predetermined deposition rate (unit: [nm/s]).Simultaneously, also heating container b3113 and baffle plate b3115 closes.
Thereafter, under the situation that baffle plate a3114 opens, open baffle plate b3115 and allow electron transport material 3117 to carry out codeposition (state shown in Figure 31 B) and be later than the hole to transport zone 3103 and form Mixed Zone 3104. these operations and avoid transporting poly-doped impurity layer between zone 3103 and the Mixed Zone 3104 in the hole.
In addition, in order to form the electron transport zone, under the situation that baffle plate b3115 opens, close baffle plate a3114 and stop heating container a3112.This operation is avoided forming impurity layer between Mixed Zone 3104 and electron transport zone.
In addition, have a kind of in the Mixed Zone shown in Figure 26 A 2607 doped luminescent material to produce identical luminous method.In this case, the excitation energy that need have as the luminescent material of alloy is than low with electron transport material that is included in hole conveying material in the Mixed Zone 2607.
Under the situation with doped luminescent material, in order to prevent to form impurity, the technology of making organic illuminating element is important. manufacturing step will be described below.
Figure 32 A is the top view that single chamber type deposition apparatus is shown, and wherein vacuum chamber 3210 is installed as deposition chamber, and a plurality of deposits source is provided in the vacuum chamber.Being placed in respectively in a plurality of deposits source is the various materials with difference in functionality, for example comprises hole-injecting material, hole conveying material, electron transport material, electronics injection material, barrier material, luminescent material, the constituent material of negative electrode.
In having the deposition apparatus of this deposition chamber, the substrate that has anode (ITO or similar material) is by the conveying room of at first packing into, and under the situation of anode, in pretreatment chamber, carry out oxidation (in addition for for example oxide of ITO, though not shown in Figure 32 A, it is possible providing a ultraviolet irradiation chamber to be used for the anode purge surface). in addition, all material that forms organic illuminating element carries out deposit in vacuum chamber 3210.But negative electrode can form in vacuum chamber 3210, or can be the deposition chamber that the formation negative electrode provided open in a fen. in a word, realize that in single vacuum chamber 3210 deposit is enough up to forming negative electrode.At last, seal and after take out the carrying chamber, obtain organic illuminating element from conveying room at closed chamber.
To provide the explanation of the step of the deposition apparatus manufacturing organic illuminating element of the present invention that utilizes this single chamber type with reference to Figure 32 B (vacuum chamber 3210 profiles).Figure 32 B illustrates, as the simplest example, utilization has three deposit sources (organic compound deposit source a3216, organic compound deposit source b3217, with organic compound deposit source c3218) vacuum chamber 3210, formation comprises hole conveying material 3221, the step of the organic compound layer of electron transport material 3222 and luminescent material 3223.
At first, the substrate 3201 that has an anode 3202 is loaded into vacuum chamber 3210 and is fixed on (substrate rotates usually in deposition process) on the fixed pedestal 3211. subsequently, and in vacuum chamber 3210 decompressions (preferred 10 -4Pa or lower) after, heating container a3212 opens baffle plate a3214 and begins deposit with evaporation hole conveying material 3221 and after reaching predetermined deposition rate (unit: [nm/s]). simultaneously, and also heating container b3213 and baffle plate b3215 closes.
Under situation that baffle plate a3214 open, open baffle plate b3215 allow electron transport material 3222 carry out codeposition in hole to transport zone 3203 after form Mixed Zone 3204 thereafter.This operation is avoided transporting poly-doped impurity layer between zone 3203 and the Mixed Zone 3204 in the hole.At this, in the process that forms Mixed Zone 3204, add very small amount of luminescent material 3223 (state shown in Figure 32 B).
In addition, in order to form the electron transport zone, under the situation that baffle plate b3215 opens, close baffle plate a3214 and stop heating container a3212.This operation is avoided forming impurity layer between Mixed Zone 3204 and electron transport zone.
With regard to the measure of dealing with problems, use this step and make that making all organic illuminating elements noted earlier becomes possibility.For example, barrier material is being added under the situation of Mixed Zone 3204, the deposit source that is used for the deposition preventing material is being installed and is evaporating this material just enough shown in Figure 32 B in the process that forms the Mixed Zone.
Equally, under the situation that forms hole injection zone or electron injection region territory, it is just enough that the deposit source that is used for each packing material is installed in same vacuum 3210.For example in Figure 32 B, transporting the zone and providing under the situation of hole injection zone between 3203 by being deposited on anode 3202 and hole, have time interval ground evaporation hole conveying material 3221 by being deposited on moment on the anode 3202, can avoid forming impurity layer with hole-injecting material.
In addition, owing to can in above-mentioned Mixed Zone, form concentration gradient, with reference to a kind of exemplary method of concentration gradient that forms.At this, described is because the situation that deposit is carried out in the deposit of resistance heating vacuum available. with regard to the method that forms concentration gradient, evaporating temperature and deposition rate (usually, unit is nm/s) at material are set up under the situation of correlation, and it is possible controlling deposition rate by temperature.But, particularly use the common heat conductivity of organic material of particle form relatively poor, be easy to produce inhomogeneities with temperature control. therefore, preferably in the deposit source that separates, preparing two kinds of materials that are used to form concentration gradient, and utilize baffle plate to carry out deposition rate control (monitoring film thickness) with crystal oscillator. Figure 11 illustrates this structural form.
In Figure 11, the explanation of formation as the concentration gradient of component structure shown in Figure 24 will be provided.Therefore, used reference number is used for representing Figure 11 among Figure 24.At first, the substrate 1101 that has an anode 1102 is loaded into film and forms chamber 1110 and be fixed on (substrate rotates usually in deposition process) on the fixed pedestal 1111.
Subsequently, heating is laid the sample room a1112 of hole conveying material 1116 and is opened baffle plate a1114, and the hole that causes deposit to be made up of hole conveying material 1116 transports zone 2405.Simultaneously, also heating is simultaneously laid the sample room b1113 of electron transport material 1117 and is closed baffle plate bl115.
After the hole transports zone 2405 and reaches predetermined film thickness, close baffle plate a1114 gradually and open baffle plate b1115 simultaneously gradually.At this moment the speed of Da Kaiheguanbiing has formed the concentration gradient of Mixed Zone 2407. and the speed of opening and closing can be set, make when baffle plate a1114 closes fully, Mixed Zone 2407 reaches predetermined film thickness, and electron transport material 1117 reaches predetermined deposition rate (2406 o'clock the speed in deposit electron transport zone). thereafter, baffle plate b1115 stays open and forms electron transport zone 2406, and to have concentration gradient be possible to the element that forms in component structure shown in Figure 24 thus.
In addition, this method can all be applicable to the situation that forms concentration gradient in other component structure except that structure shown in Figure 24.Equally, be added at luminescent material under the situation of dipole characteristic mixed layer or Mixed Zone, in Figure 11, increase a deposit source more and only in the time cycle of mixing, open the baffle plate that is used for alloy deposit source just enough.
But the measure that is used to form concentration gradient is not limited to top method.
So, above-mentioned several embodiment use capable of being combined. for example, the hole transports mixed layer, and electron transport mixed layer and the combination of dipole characteristic mixed layer apply. and example for this reason is shown in Figure 8.
In component structure shown in Figure 8, be layered in and on the substrate 801 with anode 802 be, the hole of being made up of hole-injecting material 811 and hole conveying material 812 transports mixed layer 803, the dipole characteristic mixed layer of forming by hole conveying material 812 and electron transport material 813 804, the electron transport mixed layer of forming by electron transport material 813 and electronics injection material 814 805, and negative electrode 806.
In addition, for present embodiment, the light-emitting zone 807 of a small amount of luminescent material 815 that wherein mixes is provided in the dipole characteristic mixed layer 804. and same, concentration gradient is formed in each layer shown in the figure 810.In addition, Figure 19 B is the schematic diagram that is illustrated in energy band diagram desired under the situation that forms this concentration gradient.
For this component structure, three-decker (Figure 19 B) comprises in the prior art by hole injection layer, hole transport layer, the four-layer structure (Figure 19 A) that electron transport layer and electron injecting layer are formed.In addition, shown in Figure 19 B, in each mixed layer, only have mild energy barrier, and each mixed layer is connected successively with electron transport material 813 by the hole conveying material 812 that helps carrier moving.
Subsequently, will provide the explanation of a kind of embodiment, this embodiment is, wherein the element that makes up in top mode of each mixed layer is applied to the situation of triple light emitting diodes.Usually, the basic structure of triple light emitting diodes is the structures as shown in the Fig. 9 that proposes in the document 8.Promptly this structure is by substrate 901, anode 902, hole transport layer 903, luminescent layer 904 by triple light-emitting materials formation of in host material, mixing, barrier layer 905, electron transport layer 906 and negative electrode 907 formed. and barrier layer 905 is made by barrier material, and blocking hole is with combined efficiency that improves charge carrier in the luminescent layer 904 and the molecule exciton scattering that is used for preventing generation in luminescent layer 904. same, this layer is the material that is used to deliver electronics equally.
In component structure shown in Figure 9,, hole injection layer and electron injecting layer can further improve luminous efficiency by being provided.But, in five-layer structure shown in Figure 9, add one or more layers, so cause the increase of interface number., be suitable for the present invention.
Promptly, these measures are provided, wherein the hole transport layer among Fig. 9 903 is made into to transport mixed layer by the hole that hole-injecting material and hole conveying material are formed, luminescent layer 904 is made into the dipole characteristic mixed layer formed by by hole conveying material and luminescent layer host material, and electron transport layer 906 is made into the electron transport mixed layer be made up of electron transport material and electronics injection material. and triple light-emitting materials can mix the part that has the luminescent layer host material.Equally, be shown in each mixed layer as Fig. 2 to 4 that to form concentration gradient be effective.
In addition, when barrier layer 0905 with Fig. 9 in form of single sheet when using, it can mix (can form and stop mixed layer) with the host material of luminescent layer in practice of the present invention.But,, be preferably formed concentration gradient and make barrier material at negative electrode one side concentration height from preventing the viewpoint of molecule exciton Mass.
Consider top described, Figure 10 illustrates the example of embodiment, the element that wherein makes up each mixed layer is applied to triple light emitting diodes. more especially, be layered in and on the substrate 1001 that has anode 1002 be, the hole of being made up of hole-injecting material 1011 and hole conveying material 1012 transports mixed layer 1003, the dipole characteristic mixed layer of forming by hole conveying material 1012 and host material 1,013 1004, stop mixed layer 1005 by what host material 1013 and barrier material 1014 were formed, the electron transport mixed layer of forming by barrier material 1014 (in this case equally as electron transport material) and electronics injection material 1,015 1006, and negative electrode 1007.Be formed on concentration gradient in each layer shown in figure 1010.
In addition, because embodiment comprises triple light emitting diodes, provide the light-emitting zone 1008 of a small amount of triple light-emitting material 1016 that wherein mixes.Light-emitting zone 1008 preferred arrangement are in the zone that host material 1013 concentration are high as shown in figure 10.Equally, Figure 20 B is the schematic diagram that is illustrated in energy band diagram desired under the situation of formation concentration gradient shown in figure 1010.
For this component structure, four-layer structure (Figure 20 B) comprises in the prior art by hole injection layer, hole transport layer, luminescent layer, the five-layer structure (Figure 20 A) that barrier layer (equally as electron transport layer) and electron injecting layer are formed.In addition, shown in Figure 20 B, only have mild energy barrier in each mixed layer, and each mixed layer is by the hole conveying material 1012 that helps carrier moving, host material 1013 is connected successively with barrier material 1014 (equally as electron transport material).
At last, what enumerate below is to be suitable for as constituent material, hole-injecting material for example, hole conveying material, electron transport material, electronics injection material, barrier material, luminescent material and negative electrode, material. still, the material that is used for organic illuminating element of the present invention is not limited to above-mentioned material.
As hole-injecting material, the compound based on porphyrin in the organic compound is effectively, and comprises phthalocyanine (abbreviation; H2Pc), copper phthalocyanine (abbreviation; CuPc) etc. same, have by applying the material that chemical doping obtains, and comprise with poly-sulfonated phenylethylene (polystyrene sulfonate, abbreviation to the conduction macromolecular compound; PSS) the poly-dihydroxy thiofuran ethylene of Can Zaing (polyethylene dioxythiophene, abbreviation; PEDOT), polyaniline (polyaniline, abbreviation; PAni), polyvinylcarbazole (abbreviation; PVK) etc. same, smooth as the macromolecular compound antianode of insulator is effectively, and often uses polyimides (abbreviation; PI).In addition, use inorganic compound, and comprise aluminum oxide (aluminium oxide) ultrathin membrane and gold, the thin metal film of metalloids such as platinum.
Being widely used as most (aromatic amine-based) compound that is based on aromatic amine (compound that promptly has phenyl ring nitrogen coupling (benzene ring-nitrogen coupling)) of hole conveying material. widely used material comprises, remove foregoing TPD, its derivative, promptly 4,4 '-two [N-1-naphthyl-N-phenyl amino] biphenyl (4,4 '-bis[N-(1-naphthyl)-N-phenyl-amino]-biphenyl, abbreviation; α-NPD) and star flash type (star-bursttype) aromatic amine compound for example 4,4 ', 4 " three (N, N-xenyl amino) triphenylamine (4,4 ', 4 " tris (N, N-diphenyl-amino)-triphenylamine, abbreviation; TDATA), 4,4 ', 4 " three [N-3-aminomethyl phenyl-N-phenyl amino] triphenylamine (4,4 ', 4 " tris IN, (3-methylphenyl)-N-phenyl-amino]-triphenylamine, abbreviation; MTDATA) and similar compounds.
Metal complex removes Alq noted earlier through being often used as electron transport material 3, also comprise chinoline backbone or benzoquinoline skeleton metal complex outward, for example three (4-methyl-oxine base) aluminium (tris (4-methyl-8-quinolinolato) aluminium, abbreviation; Al (mq 3)), two (10-hydroxyphenyl and quinolyl) beryllium (bis (10-hydrexybenzo[h]-quinolinato) beryllium, abbreviation; Be (Bq) 3), and mixed ligand complex compound for example two (2-methyl-oxine base-(4-phenyl phenates) aluminium (bis (2-methyl-8-quinolinolato)-(4-phenylphenolate)-aluminium, abbreviations; Similar complex compound such as BAlq). same, has complex compound in the metal complex based on the ligand of the ligand of thiazole and Ji Yu oxazole, for example two [2-(2-hydroxyphenyl) benzoxazolyl] and zinc (bis[2-(2-hydroxyphenyl)-benzoxazolato] zinc, abbreviation; Zn (BOX) 2), two [2-(2-hydroxyphenyl) benzothiazolyl] zinc (bis[2-(2-hydroxyphenyl)-benzothiazolato] zinc, abbreviation; Zn (BTZ) 2) wait similar complex compound. in addition, remove metal complex, for example 2-4-xenyl-5-4-tert-butyl-phenyl-1,3 of oxadiazole derivative is arranged, 4-oxadiazole (2-(4-biphenylyl)-5-(4-tert-butylphenyl)-1,3,4-oxadiazole, abbreviation; PBD), 1,3-two [5-(p-tert-butyl-phenyl)-1,3,4-oxadiazole-2-idol acyl] benzene (1,3-bis[5-(p-tert-butylphenyl)-1,3,4-
Oxadiazole-2-il] benzene, abbreviation; Similar derivative thing such as OXD-7), triazole derivative is 5-4-xenyl-3-4-tert-butyl-phenyl-4-phenyl-1,2 for example, 4-triazole (5-(4-biphenylyl)-3-(4-tert-butylphenyl)-4-phenyl-1,2,4-triazole, abbreviation; TAZ), 5-4-xenyl-3-4-tert-butyl-phenyl-4-4-ethylphenyl-1,2,4-triazole (5-(4-biphenylyl)-3-(4-tert-butylphenyl)-4-(4-ethylphenyl-1,2,4-triazole) (abbreviation; For example bathophenanthroline (bathophenanthroline, the abbreviation of similar derivative thing such as p-EtTAZ), and phenanthroline derivative; BPhen), and bathocuproine (bathocuproine, abbreviation, like derivatives such as BCP), these derivatives have electron transport character.
Above-mentioned electron transport material can be used as the electronics injection material.In addition, often use by alkali halide similar compound such as lithium fluoride for example, alkali metal oxide is the insulator ultrathin membrane made of similar compound such as lithia for example.Equally, alkali metal complex is acetylacetone,2,4-pentanedione lithium (lithum acetylacetonate, abbreviation, Li (acac)) for example, oxine base lithium (8-quinolinolato-lithium, abbreviation; Liq) etc. similar complex compound is easy to use.
As barrier material, because their excitation level height, above-mentioned BAlq, OXD-7, TAZ, p-EtTAZ, BPhen, BCP etc. are easy to use.
As the luminescent material material of alloy (comprise as), various fluorescent dyes and above-mentioned metal complex be Alq for example 3, Al (mq) 3, Be (Bq) 2, BAlq, Zn (BOX) 2, Zn (BTZ) 2Deng being easy to use. same, be that triple light-emitting materials that the complex compound of platinum or iridium is formed are easy to use mainly by its central metal.Known as triple light-emitting materials be three 2-phenylpyridine iridium (tris (2-phenylpyridine) iridium, the abbreviation; Ir (ppy) 3), 2,3,7,8,12,13,17,18-octaethyl-21H, 23H-porphyrin platinum (2,3,7,8,12,13,17,18-octaethyl-21H, 23H-porphyrin-platinum, abbreviation; PtOEP) etc.
Have the above-mentioned material of corresponding function by combination respectively, and these materials be applied to organic illuminating element of the present invention, make than existing element drives voltage lower with longer organic illuminating element of life-span be possible.
[embodiment 1]
In the present embodiment, specify one and use the element that hole shown in Figure 5 transports mixed layer.
At first, with sputter with indium tin oxide (below be called " ITO ") be deposited on the glass substrate 501 to the about 100nm of thickness so that anode 502 to be provided.Subsequently, as the CuPc of hole-injecting material, and to carry out codeposition as the α-NPD of hole conveying material than 1: 1 with deposition rate be that the hole of 50nm transports mixed layer 503. to form thickness
In addition, by at Alq 3The layer that the lycid alkene of last doping 5wt% obtains be laminated to thickness for 10nm providing luminescent layer 504. last, Alq 3Be deposited to thickness for 40nm so that electron transport layer 505 to be provided, and Al: Li alloy (mass ratio of Li is 0.5wt%) is deposited to the about 150nm of thickness so that negative electrode 506 to be provided, and makes that making the organic illuminating element that produces sodium yellow by lycid alkene becomes possibility.
[embodiment 2]
In the present embodiment, specify the element of application electron transport mixed layer shown in Figure 6.
At first, with sputter with ITO be deposited on the glass substrate 601 to the about 100nm of thickness providing anode 602. subsequently, being deposited to thickness as the α-NPD of hole conveying material is that 50nm is to form hole transport layer 603 thus.
In addition, perylene (perylene) be laminated to thickness for 10nm so that a luminescent layer 604 to be provided, then as the BPhen of electron transport material with as the Alq of electronics injection material 3Carrying out codeposition than 1: 1 with deposition rate is that the electron transport mixed layer 605. of 40nm is last to form thickness, Al: Li alloy (mass ratio of Li is 0.5wt%) is deposited to the about 150nm of thickness so that negative electrode 606 to be provided, and makes the organic illuminating element of making by perylene generation blue light become possibility.
[embodiment 3]
In the present embodiment, specify an organic illuminating element, obtain this element by inserting a hole injection zone of forming by hole-injecting material between anode in organic illuminating element shown in Figure 24 2402 and the organic compound layer 2403.
At first, prepare a glass substrate 2401, with sputter ITO is deposited on this glass substrate and forms glass substrate 2401 that anode 2402. has anode 2402 to the about 100nm of thickness and be loaded in the vacuum chamber shown in Figure 31 A and 31B. in this embodiment, four kinds of materials of deposit (wherein three kinds be organic compound and a kind of be the metal that forms negative electrode), therefore need four deposit sources.
At first, deposit as the CuPc of hole-injecting material to thickness 20nm, and not free compartment of terrain of the moment when reaching thickness 20nm and stopping deposit CuPc, beginning deposit with deposition rate 0.3nm/sec, to have the reason of ground beginning deposit of such time interval as the α-NPD. of hole conveying material be for preventing to form above-mentioned impurity layer.
After the hole transport layer 2405 that formation only is made up of α-NPD had thickness 30nm, beginning was with the Alq of deposition rate 0.3nm/sec deposit as electron transport material 3, and the deposition rate of α-NPD remains fixed in 0.3nm/sec. promptly by codeposition formation α-NPD and Alq 3Ratio be 1: 1 Mixed Zone 2407.
After Mixed Zone 2407 reaches thickness 30nm, stop the deposit of α-NPD and only continue deposit Alq 3Forming thickness will be last for the electron transport zone 2406. of 40nm, Al: the Li alloy be deposited to the about 150nm of thickness as negative electrode to obtain by Alq 3Produce the organic illuminating element of green light.
[embodiment 4]
In the present embodiment, specify an organic illuminating element, obtain this element by inserting a hole injection zone of forming by hole-injecting material between anode in organic illuminating element shown in Figure 29 A 2702 and the organic compound layer 2703.
At first, prepare a glass substrate 2701, with sputter ITO is deposited on this glass substrate and forms glass substrate 2701 that anode 2702. has anode 2702 to the about 100nm of thickness and be loaded in the vacuum chamber shown in Figure 32 A and 32B. in this embodiment, five kinds of materials of deposit (wherein four kinds be organic compound and a kind of be the metal that forms negative electrode), therefore need five deposit sources.
At first, to thickness 20nm, and the not free compartment of terrain of the moment when reaching thickness 20nm and stopping deposit CuPc begins the α-NPD of deposit as the hole conveying material with deposition rate 0.3nm/sec as the CuPc of hole-injecting material in deposit.Not having the reason of ground beginning deposit of such time interval is for preventing to form above-mentioned impurity layer.
After hole transport layer 2705 to the thickness that formation only is made up of α-NPD is 30nm, begin the Alq of deposit as electron transport material with deposition rate 0.3nm/sec 3, and the deposition rate of α-NPD remains fixed in 0.3nm/sec. promptly by codeposition formation α-NPD and Alq 3Ratio be 1: 1 Mixed Zone 2707.Simultaneously, add fluorescent dye (4-methylene dicyanoethyl-2-methyl-6-(the two methylamino styryls of p-)-4H-pyrans (4-(dicyanomethylene)-2-methyl-6-(p-dimethylaminostyryl)-4H-pyran, abbreviation; DCM) as luminescent material 2708.The control deposition rate is to realize ratio α-NPD: Alq 3: DCM=50: 50: 1.
After Mixed Zone 2707 reached thickness 30nm, the deposit of α-NPD and DCM stopped, and has only Alq 3Continuing deposit is the electron transport zone 2706 of 40nm to form thickness.At last, Al: the Li alloy be deposited to the about 150nm of thickness as negative electrode to obtain producing the organic illuminating element of red light by DCM.
[embodiment 5]
In the present embodiment, specify the organic illuminating element shown in Figure 29 B.
At first, prepare a glass substrate 2701, with sputter ITO is deposited on this glass substrate and forms the glass substrate 2701 that anode 2702. has anode 2702 to the about 100nm of thickness and be loaded in the vacuum shown in Figure 32 A and the 32B.In this embodiment, four kinds of materials of deposit (wherein three kinds be organic compound and a kind of be the metal that forms negative electrode), therefore need four deposit sources.
After hole transport layer 2705 to the thickness that formation only is made up of the α-NPD as the hole conveying material is 40nm, begin the Alq of deposit as electron transport material with deposition rate 0.3nm/sec 3, and the deposition rate of α-NPD remains fixed in 0.3nm/sec. promptly by codeposition formation α-NPD and Alq 3Ratio be 1: 1 Mixed Zone 2707.
After Mixed Zone 2707 formed and has thickness 30nm, this moment, thickness in Mixed Zone 2707 was that the zone line (being the part of 10nm to 20nm in the Mixed Zone 2707 of thickness 30nm) of 10nm is with fluorescent dye (4-methylene dicyanoethyl-2-methyl-6-(the two methylamino styryls of p-)-4H-pyrans (abbreviation; DCM) mix with the ratio of 1wt% as luminescent material 2708.
After Mixed Zone 2707 reached thickness 30nm, the deposit of α-NPD stopped, and has only Alq 3Continuing deposit is that the electron transport zone 2706. of 40nm is last to form thickness, the Al:Li alloy be deposited to the about 150nm of thickness as negative electrode to obtain organic illuminating element by DCM generation red light.
[embodiment 6]
In the present embodiment, specify by applying the element that concentration gradient obtains to the element of Mixed Zone shown in the application drawing 29B.In addition, in order to form concentration gradient, equipment shown in Figure 11 is used to make this element.In the present embodiment, the hole conveying material, electron transport material and luminescent material need three deposit sources.
At first, with sputter ITO is deposited on the glass substrate 2601 and has the about 100nm of 20nm thickness to thickness and form anode 2602.Subsequently, deposit transports zone 2605 as the α-NPD of hole conveying material to thickness 40nm formation hole.
In addition, as described in regard to this embodiment, (be Alq in the present embodiment by opening electron transport material gradually 3) baffle plate in deposit source closes simultaneously the hole conveying material gradually (baffle plate in deposit source of α-NPD), deposit is by α-NPD and Alq 3The Mixed Zone of forming and have concentration gradient 2607 is to thickness 20nm. this moment, and the 10nm zone line in the Mixed Zone 2607 of 20nm thickness mixes with the ratio of 5wt% as luminescent material 2608 with lycid alkene.
Reach the thickness of 20nm in the Mixed Zone after, having only electron transport material (Alq 3) baffle plate in deposit source is that the state of opening forms by Alq down 3The electron transport zone of forming 2606. is last, Al: Li alloy (Li is 0.5wt% by weight) be deposited to the about 150nm of thickness as negative electrode 2604 to obtain organic illuminating element by lycid alkene generation sodium yellow.
[embodiment 7]
In the present embodiment, specify an organic illuminating element, this element is by in organic illuminating element shown in Figure 26 B, between anode 2602 and organic compound layer 2603, insert a hole injection zone of forming by hole-injecting material, and insertion one is formed the electron injection region territory by the electronics injection material and is obtained between negative electrode 2604 and organic compound layer 2603.
At first, prepare a glass substrate 2601, with sputter ITO is deposited on this glass substrate and forms glass substrate 2601 that anode 2602. has anode 2602 to the about 100nm of thickness and be loaded in the vacuum chamber shown in Figure 31 A and 31B. in this embodiment, seven kinds of materials of deposit (wherein six kinds be organic compound and a kind of be the metal that forms negative electrode), therefore need seven deposit sources.
At first, deposit as the CuPc of hole-injecting material to thickness 20nm, and the not free compartment of terrain of the moment when reaching thickness 20nm and stopping deposit CuPc, beginning is with the TPD of deposition rate 0.2nm/sec deposit as the hole conveying material.Not having the reason of ground beginning deposit of such time interval is for preventing to form above-mentioned impurity layer.
Forming the hole transport layer 2605 only form to thickness 30nm, begin the BeBq of deposit with deposition rate 0.8nm/sec equally as electron transport material by TPD 2, and the deposition rate of TPD remains fixed in 0.2nm/sec. promptly by codeposition formation TPD and BeBq 2Ratio be 1: 4 Mixed Zone 2607.
After Mixed Zone 2607 forms and has thickness 30nm, this moment, zone line (being the part of 10nm to 20nm in the Mixed Zone 2607 of 30nm) the lycid alkene that is used as fluorescent dye of 10nm in Mixed Zone 2607 mixed with the 5wt% ratio as luminescent material 2608. and same, the final area of 10nm in the Mixed Zone 2607 (being the part of 20nm to 30nm in the Mixed Zone of 30nm) mixes as barrier material 2609 with BCP.The deposition rate of various materials is TDP: BeBq when mixing with BCP 2: BCP=1: 4: 3[nm/s].
After Mixed Zone 2607 reached thickness 30nm, the deposit of TPD and BCP stopped, and has only BeBq 2Continue to be deposited form thickness be 40nm electron transport zone 2606. with stop BeBq 2Deposit the time not free compartment of terrain of the moment, the beginning deposit as the Li (acac) of electronics injection material to the reason that the about 2nm. of thickness has such time interval ground to begin deposit be for preventing to form above-mentioned impurity layer.
At last, deposit aluminium to the about 150nm of thickness as negative electrode to obtain producing the organic illuminating element of sodium yellow by lycid alkene.
[embodiment 8]
In the present embodiment, specify the organic illuminating element shown in Figure 30 B.
At first, prepare a glass substrate 2701, with sputter ITO is deposited on this glass substrate the glass substrate 2701 that has anode 2702 to about 100nm formation anode 2702. and is loaded in the vacuum shown in Figure 32 A and 32B.In this embodiment, five kinds of materials of deposit (wherein four kinds be organic compound and a kind of be the metal that forms negative electrode), therefore need five deposit sources.
After hole transport layer 2705 to the thickness that formation only is made up of the MTDATA as the hole conveying material is 40nm, begin the PBD of deposit with deposition rate 0.3nm/sec as electron transport material, and the deposition rate of MTDATA to remain fixed in ratio that 0.3nm/sec. promptly forms MTDATA and PBD by codeposition be 1: 1 Mixed Zone 2707.
After Mixed Zone 2707 forms and has thickness 30nm, be used as luminescent material 2708 as the zone line (being the part of 10nm to 20nm in the Mixed Zone 2707 of 30nm) that the perylene of fluorescent dye adds 10nm in the Mixed Zone 2707 this moment, and the control deposition rate makes that the ratio of this interpolation is MTDATA: PBD: perylene=4: 16: 1.Equally, BCP is added into last 10nm zone (being the part of 20nm to 30nm in the 30nm Mixed Zone) in the Mixed Zone 2707 as barrier material 2709, and ratio is MTDATA: PBD: BCP=1: 4: 5.
After the Mixed Zone reached thickness 30nm, the deposit of MTDATA and BCP stopped, and had only PBD to continue deposit to form the electron transport zone 2706 of thickness 40nm.At last, Al: the Li alloy be deposited to about 150nm as negative electrode to obtain producing the organic illuminating element of blue light by perylene.
[embodiment 9]
In the present embodiment, specify hole shown in Figure 8 and transport mixed layer, dipole characteristic mixed layer and electron transport mixed layer are combined and use a element on it.In addition, in order to form concentration gradient (figure 810 among Fig. 8) in the present embodiment, use baffled deposit source shown in Figure 11.
At first, with sputter with ITO be deposited on the glass substrate 801 to about 100nm formation anode 802. subsequently, deposit forms concentration gradient shown in the figure 810 by transporting 803 to 40nm. this moments of mixed layer as the CuPC of hole-injecting material 811 with as the hole that the α-NPD of hole conveying material 812 forms by opening and closing baffle plate.
At this moment, by in the baffle plate of closing α-NPD deposit source gradually, opening Alq gradually as electron transport material 813 3The baffle plate in deposit source, deposit has 804 to 20nm. this moments of dipole characteristic mixed layer of concentration gradient, (the 4-methylene dicyanoethyl-2-methyl-6-(the two methylamino styryls of p-)-4H-pyrans (abbreviation of zone line 807 usefulness of 10nm in the dipole characteristic mixed layer 804 of 20nm; DCM) mix with the ratio of 1wt% as luminescent material 815.
After dipole characteristic mixed layer 804 reaches 20nm thickness, having only Alq 3The state opened of baffle plate under deposit Alq 3To 35nm. by in the end closing Alq gradually in the 5nm zone 3Open baffle plate in the time of the baffle plate in deposit source gradually, form the electron transport mixed layer 805 that adds up to 40nm as Li (acac) the deposit source of electronics injection material 814.That is, to be set at be steep (though the gradient of electronics injection material 814 is constant shown in the figure 810, the decline of present embodiment sharply raises) to the concentration gradient of Li (acac).
At last, aluminium be deposited as negative electrode 806 to about 150nm to obtain producing the organic illuminating element of red light by DCM.
[embodiment 10]
In the present embodiment, specify the example of an organic illuminating element, this element is by in the organic illuminating element shown in Figure 29 B, between anode 2702 and organic compound layer 2703, insert the hole injection zone of forming by hole-injecting material, between negative electrode 2704 and organic compound layer, inserting the electron injection region territory of forming by the electronics injection material, and apply triple light-emitting materials and obtain as luminescent material. this component structure is shown in Figure 33.
At first, prepare a glass substrate, ITO is deposited on the glass substrate to about 100nm formation ITO (anode) with sputter.The glass substrate that has ITO is loaded in the vacuum chamber shown in Figure 32 A and the 32B. and in this embodiment, seven kinds of materials of deposit (wherein five kinds is that organic compound and two kinds are the inorganic material that forms negative electrode) therefore need seven deposit sources.
At first, deposit is as the CuPc to 20nm of hole-injecting material, and and not free compartment of terrain between the moment when reaching 20nm and stopping deposit CuPc, beginning deposit with deposition rate 0.3nm/sec, to have the reason of ground beginning deposit of such time interval as the α-NPD. of hole conveying material be for preventing to form above-mentioned impurity layer.
Form the hole transport layer only form by α-NPD to 30nm thick after, begin the BAlq of deposit with deposition rate 0.3nm/sec equally as electron transport material, and the deposition rate of α-NPD to remain fixed in ratio that 0.3nm/sec. promptly forms α-NPD and BAlq by codeposition be 1: 1 Mixed Zone (α-NPD+BAlq).
The Mixed Zone is formed has thickness 20nm, and this moment is as the Ir (ppy) of triple light-emitting materials 3The zone line (being the part of 5nm to 15nm in the 20nm Mixed Zone) that adds 10nm in the Mixed Zone is as luminescent material.The ratio of this interpolation is α-NPD: BAlq: Ir (ppy) 3=50: 50: 7.
After the Mixed Zone reaches 20nm thickness, α-NPD and Ir (ppy) 3Deposit stop, forming thickness be the electron transport zone of 20nm and have only BAlq to continue deposit. the not free compartment of terrain of the moment when stopping deposit BAlq, the beginning deposit is as the Alq of electronics injection material 3Not having the reason of ground beginning deposit of such time interval to about 30nm. is for preventing to form above-mentioned impurity layer.
At last, LiF is deposited to about 1nm and aluminium and is deposited to about 150nm and forms negative electrode and obtain by Ir (ppy) 3Produce triple light-emitting materials of green light.
[embodiment 11]
In the present embodiment, specify one by applying the present invention to the element that triple light emitting diode shown in Figure 9 obtains.Component structure is shown in Figure 10. in addition,, use the baffled deposit source shown in Figure 11 in order to form concentration gradient (figure 1010 among Figure 10) in the present embodiment.
At first, with sputter with ITO be deposited on the glass substrate 1001 to about 100nm formation anode 1002. subsequently, deposit is by transporting mixed layer 1003 to 40nm as the CuPc of hole-injecting material 1011 with as the hole that the α-NPD of hole conveying material 1012 forms.This moment is by opening and closing the concentration gradient of baffle plate formation shown in figure 1010.
Then, by deposition rate that reduces α-NPD gradually and the host material 1013 that increases triple light-emitting materials, 4-4 '-N, the two carbazole biphenyl of N-(4-4 '-N, the deposition rate of '-dicarbazole-biphenyl) (below be called " CBP "), formation form by α-NPD and CBP and dipole characteristic mixed layer 1004 with concentration gradient to thickness 20nm. this moment, by deposition rate that reduces CBP and the deposition rate that increases barrier material 1014BCP, form and the mixed layer 1005. that stops with concentration gradient stops that the thickness of mixed layer is 10nm. so form by CBP and BCP
Because present embodiment relates to a kind of triple light emitting diode, for the three 2-phenylpyridine iridium (tris (2-phenylpyridine) iridium) of triple light-emitting materials 1016 (below be called Ir (ppy) 3), be doped forming dipole characteristic mixed layer 1004 and stop in the process of mixed layer 1005. as the high zone of concentration of the CBP of host material, promptly near dipole characteristic mixed layer 1004 and stop that the zone of boundary between the mixed layer 1005 is suitable as doped regions 1008. most in the present embodiment, near the boundary ± and the zone of 5nm, the zone that promptly amounts to width and be 10nm is made into to reach the doped region 1008. that 6wt% mixes
In addition, electron transport mixed layer 1006 is by electron transport ability high BCP and Alq 3Form.Form concentration gradient, make along with reducing away from anode BCP concentration, and along with away from anode A lq 3Concentration increases on the contrary.Promptly in this case, BCP is as barrier material and electron transport material, and Alq 3As electronics injection material 1015.Electron transport mixed layer 1006 has 40nm thickness.
At last, Al: Li alloy (Li is 0.5wt% by weight) is deposited to about 150nm as negative electrode 1007, can form to present by Ir (ppy) 3Produce the organic illuminating element of green light.
[embodiment 12]
Present embodiment is described a kind of luminescent device that comprises according to organic illuminating element of the present invention.Figure 12 A is the profile of the active matrix light emitting device of use organic illuminating element of the present invention.Use thin-film transistor (being called TFT hereinafter) as active element at this, but active element can be a MOS transistor.
Shown in as an example TFT be top grid TFT (specifically, plane TFT), but the alternative use of bottom grid TFT (being typically one reverse interleaved (reverse stagger) TFT).
Among Figure 12 A, 1201 expression substrates.Substrate can see through visible light as used herein.Particularly, can use glass substrate, quartz substrate, crystal glass substrate, or plastic (comprising plastic film). substrate 1201 refers to that substrate adds the dielectric film that is formed on the substrate surface.
On substrate 1201, pixel portion 1211 and drive circuit 1212 are provided.Pixel portion 1211. is at first described
Pixel portion 1211 is zones of display image.Many pixels are set on the substrate, and each pixel is furnished with the electric current mobile (being called Current Control TFT hereinafter) that a TFT1202 is used for controlling organic illuminating element, one pixel electrode (anode), 1203, one organic compound layers 1204 and a negative electrode 1205.Though Current Control TFT only is shown in Figure 12 A, each pixel has a TFT to be used to control to impose on the TFT (being called switching TFT hereinafter) of the voltage of Current Control TFT grid.
Current Control TFT1202 is preferably a P channel TFT at this.Though the alternative use of n channel TFT, if Current Control TFT is connected with the anode of organic illuminating element shown in Figure 12 A, the p channel TFT as Current Control TFT reduce aspect the current drain more successful.Notice that switching TFT can be formed by n channel TFT or p channel TFT.
The drain electrode of Current Control TFT1202 is electrically connected with pixel electrode 1203. in the present embodiment, electric conducting material with 4.5-5.5eV work function is used as the material of pixel electrode 1203, and therefore, pixel electrode 1203 plays the organic illuminating element anode. light transmitting material, typically, indium oxide, tin oxide, zinc oxide, or these compound is (for example, ITO), be used to pixel electrode 1203.On pixel electrode 1203, form organic compound layer 1204.
On organic compound layer 1204, provide negative electrode 1205.The material ideal of negative electrode 1205 is the electric conducting material of work function at 2.5-3.5eV.Typically, negative electrode 1205 is by the conducting film that comprises alkali metal or alkali earth metal, or by the conducting film that comprises aluminium, or by by with aluminium or the silverskin lamination that stratification obtains on one of above-mentioned conducting film, form.
By pixel electrode 1203, the layer that organic compound layer 1204 and negative electrode 1205 formed by provide diaphragm 1206 to avoid oxygen and moisture coated with diaphragm 1206. with the protection organic illuminating element.The material that can be used as diaphragm 1206 comprises silicon nitride, silicon oxynitride, aluminium oxide, tantalum oxide, and carbon (diamond-like-carbon particularly).
Below, drive circuit 1212 will be described.Drive circuit 1212 is the zones that are used to control the timing of the signal (gate signal and data-signal) that will be sent to pixel portion 1211, and is furnished with shift register, buffer, and latch, and analog switch (transmission gate) or level shifter.Among Figure 12 A, the cmos circuit that the elementary cell of these circuit is made up of n channel TFT 1207 and p channel TFT 1208.
Known circuit structure can be applied to shift register, buffer, though latch and analog switch or level shifter. pixel portion 1211 and drive circuit 1212 are provided on the same substrate in Figure 12 A, but IC or LSI can be electrically connected with substrate, substitute drive circuit 1212 is arranged on the substrate.
Pixel electrode among Figure 12 A (anode) 1203 is electrically connected with Current Control TFT1202, but negative electrode can replace being connected with Current Control TFT. and in this case, pixel electrode is formed by the material of negative electrode 1205 and negative electrode is formed by the material of pixel electrode (anode) 1203. and Current Control TFT is preferably the n channel TFT in this case.
By the technology that before forming wiring lines 1209, forms pixel electrode 1203, light-emitting component shown in the shop drawings 12A. still, this technology may make the surperficial roughening of pixel electrode 1203.Because it is a current drive-type element, pixel electrode 1203 coarse surfaces may reduce the performance of organic illuminating element.
Forming wiring lines 1209 back formation pixel electrodes 1203 to obtain luminescent device shown in Figure 12 B.In this case, compare with the structure of Figure 12 A, electric current can be enhanced from the injection of pixel electrode 1203.
In Figure 12 A and 12B, the bank structure of forward taper (forward-tapered bankstructure) 1210 pixels that will be arranged in the pixel portion 1211 are separated from each other.If this bank structure is reverse taper, can avoid contacting between bank structure and the pixel electrode.The example is shown in Figure 34.
In Figure 34, the wiring lines play partitioned portion equally, form wiring lines and partitioned portion 3410. by will constituting the lines that connect up metal and etch rate than the low material of metal (for example, metal nitride) stratification and this lamination of etching subsequently, obtain the shape (that is the structure of band eaves) of wiring lines shown in Figure 34 and partitioned portion 3410.This shape can prevent the short circuit between negative electrode 3405 and pixel electrode 3403 or the wiring lines.Different with common active matrix light emitting device, the negative electrode 3405 in the device of Figure 34 on the pixel is striped (being similar to the negative electrode in the passive matrix device).
Figure 13 (a) and 13 (b) illustrate the outside of illustrated active matrix light emitting device among Figure 12 B. and Figure 13 A is its top view and Figure 13 B is the profile along Figure 13 A line P-P '. and the symbol among Figure 12 A and the 12B is used among Figure 13 A and the 13B.
Among Figure 13 A, 1301 remarked pixel parts, 1302 expression gate signal side drive circuit, and 1303 expression data-signal side drive circuit. the signal that is sent to gate signal side drive circuit 1302 and data-signal side drive circuit 1303 from TAB (band automated bonding) though be with 1305 through 1304 inputs of input wiring lines. not shown in figures, TAB can be by TCP (band carrier package) replacement by obtaining to TAB band configuration IC (integrated circuit) with 1305.
By providing of 1306 expressions on light-emitting component top shown in Figure 12 B, and the covering that combines with the seal 1307 that forms by resin.Covering 1306 only can be otherwise sees through any material of oxygen and water. in the present embodiment, shown in Figure 13 B, covering 1306 is made up of working of plastics 1306a and carbon film (the diamond-like carbon film particularly) 1306b and the 1306c that are respectively formed on the working of plastics 1306a front and rear.
Shown in Figure 13 B, 1308 coverings of the sealing spare that seal 1307 is formed from a resin (sealingmember) make organic illuminating element be sealed in fully in the airtight space 1309.With inactive gas (typically, nitrogen or inert gas), resin, or torpescence liquid (for example, its representative instance is the liquid fluorocarbon of perfluoroalkane (perfluoro alkane)) is filled airtight space 1309.Putting into adsorbent or deoxidier in this space is effective equally.
One polarising sheet can be provided on the display surface of luminescent device shown in the present embodiment (spectators watch the face of display image on it).Polarising sheet has an outside reflection of incident light of minimizing and to prevent display surface thus the effect of spectators' reflection is shown. usually, adopt a Circular Polarisation plate.But polarising sheet preferably has by adjusting refractive index and have the structure of less internal reflection, is reflected and counter motion at polarising sheet from the light of organic compound layer emission preventing.
Can be used as the organic illuminating element that is included in the present embodiment luminescent device according to any organic illuminating element of the present invention.
[embodiment 13]
Present embodiment illustrates an active matrix light emitting device, as the example that comprises according to the luminescent device of organic illuminating element of the present invention. different with embodiment 12, in the luminescent device of present embodiment, the opposite side that light forms the substrate of active element from it takes out (being called upwards emission hereinafter).Figure 35 is its profile.
Thin-film transistor (being called TFT hereinafter) is used as active element at this, but active element can be MOS transistor.The TFT that is shown example is top grid TFT (specifically, plane TFT), but the alternative use of bottom grid TFT (being typically a reverse interleaved TFT).
The substrate 3501 of present embodiment is formed on Current Control TFT3502 in the pixel portion, the structure identical with having of embodiment 12 with drive circuit 3512.
First electrode 3503 that is connected with the drain electrode of Current Control TFT3502 in the present embodiment is as anode, and therefore preferably forming by electric conducting material with big work function. the typical example of electric conducting material comprises for example nickel, palladium, tungsten, gold, metal with silver. in the present embodiment, the first desirable electrode 3503 is light tight. and even more ideal, electrode is that the material by high light reflectivity forms.
Organic compound layer 3504 is formed on first electrode 3503. be provided in the present embodiment on the organic compound layer 3504 be cathodic process second electrode 3505. therefore, the material ideal ground of second electrode 3505 is the electric conducting material of work function at 2.5-3.5eV. typically, use comprises the conducting film of alkali metal or alkali earth metal, or comprise the conducting film of aluminium, or by with aluminium or the silverskin lamination that stratification obtains on one of above-mentioned conducting film.Because use upwards emission light-emitting device in the present embodiment, for the material of second electrode 3505, transmittance is absolutely necessary. therefore, when as second electrode, metal is preferably formed the extremely thin film into the about 20nm of thickness.
By the layer that first electrode 3503 is formed, organic compound layer 3504 is provided diaphragm 3506 to avoid contacting oxygen and moisture with the protection organic illuminating element with second electrode 3505 coated with diaphragm 3506..In the present embodiment, as long as its printing opacity, any material all can be used to do diaphragm.
Among Figure 35, first electrode (anode) 3503 is electrically connected with Current Control TFT3502, but negative electrode can replace being connected with Current Control TFT.In this case, first electrode can be formed by the material of negative electrode and second electrode can be formed by the material of anode. and Current Control TFT is preferably the n channel TFT in this case.
3507 expression one coverings also combine with the seal 3508 that is formed by resin. and covering 3507 can be to need only its printing opacity but any material of oxygen flow and water not. in the present embodiment, use glass. with inactive gas (typically, nitrogen or inert gas), resin, or torpescence liquid (for example, its representative instance is the liquid fluorocarbon of perfluoroalkane (perfluoro alkane)) is filled, and airtight space 3509. is put into adsorbent in this space or deoxidier is effective equally.
The signal that is sent to gate signal side drive circuit and data-signal side drive circuit is with 3514 through 3513 inputs of input wiring lines from TAB (band automated bonding).Though not shown in the accompanying drawings, TAB can be by replacing by the TCP (band carrier package) that obtains to TAB band configuration IC (integrated circuit) with 3514.
One polarising sheet can be provided on the display surface of luminescent device shown in the present embodiment (spectators watch the face of display image on it).Polarising sheet has an outside reflection of incident light of minimizing and to prevent display surface thus the effect of spectators' reflection is shown. usually, adopt a Circular Polarisation plate.But polarising sheet preferably has by adjusting refractive index and have the structure of less internal reflection, is reflected and counter motion at polarising sheet from the light of organic compound layer emission preventing.
Can be used as the organic illuminating element that is included in the present embodiment luminescent device according to any organic illuminating element of the present invention.
[embodiment 14]
Present embodiment illustrates a passive matrix luminescent device, and its is as comprising the example of the luminescent device of disclosed organic illuminating element in the present invention. and Figure 14 A is its top view and Figure 14 B is the profile along Figure 14 A line P-P '.
In Figure 14 A, 1401 substrates that form by plastic material in this expression.Operable plastic material is a polyimides, polyamide, acrylic resin, epoxy resin, PES (polyethylene sulfile), PC (Merlon), PET (polyethylene terephthalate), or plate or the film of PEN (polyethylene naphthalate).
The scan line (anode) that 1402 expressions are formed by conductive oxide film. in the present embodiment, obtain conductive oxide film by doping gallium oxide in zinc oxide.1403 represent by metal film the film formed data wire of bismuth (negative electrode) in the present embodiment.The bank that 1404 expressions are formed by acrylic resin.Bank is used as data wire 1403 separated partition walls.Though multi-strip scanning line 1402 and many data wires 1403 form bar paten respectively and pattern is in right-angle crossing. not shown in Figure 14 A, organic compound layer be sandwiched between scan line 1402 and the data wire 1403 and intersection point part 1405 as pixel.
Scan line 1402 and data wire 1403 are with 1407 to be connected with external drive circuit through TAB.Though 1408 expressions comprise one group of wiring lines .1409 of a large amount of scan lines 1402 and represent to comprise one group of wiring lines of the connecting wiring lines 1406 that are connected with data wire 1403 in a large number. not shown, TAB can be by replacing by the TCP that obtains to TAB band configuration IC (integrated circuit) with 1407.
Among Figure 14 B, 1410 expression seals, but and the covering that 1411 expressions combine with working of plastics 1401 by seal 1410. the resin of light healing (photo-curable) can be used for seal 1410.The seal preferred material is the material that allows a small amount of gas permeation and absorb small amount of moisture.Covering is preferably by making with substrate 1401 identical materials, and can use glass (comprising quartz glass) or plastics.At this, plastic material is used for covering.
Figure 14 C is the zoomed-in view of pixel region structure.1413 expression organic compound layers.The lower floor of bank 1404 is narrower than the upper strata, and bank can physically be separated from each other data wire 1403.Sealed 1410 pixel portion 1414 of surrounding breaks away to prevent the organic compound layer degeneration with extraneous air by the sealing spare 1415 that is formed by resin.
In the luminescent device as structure as described in above according to the present invention, pixel portion 1414 comprises scan line 1402, data wire 1403, bank 1404 and organic compound layer 1413.Therefore luminescent device can be by very simple technology manufacturing.
One polarising sheet can be provided on the display surface of luminescent device shown in the present embodiment (spectators watch the face of display image on it). and polarising sheet has one to be reduced outside reflection of incident light and to prevent display surface thus the effect of spectators' reflection is shown. usually, adopt a Circular Polarisation plate. still, polarising sheet preferably has by adjusting refractive index and have the structure of less internal reflection, is reflected and counter motion at polarising sheet from the light of organic compound layer emission preventing.
Can be used as the organic illuminating element that is included in the present embodiment luminescent device according to any organic illuminating element of the present invention.
[embodiment 15]
Present embodiment illustrates printed substrate is installed in shown in the embodiment 14 on the luminescent device device is made the example of a module.
In a module shown in Figure 15 A, TAB is with 1504 to be installed on the substrate 1501 (comprising pixel portion 1502 and wiring lines 1503a and 1503b at this), and printed substrate 1505 is with 1504 to be installed on the substrate through TAB.
The functional-block diagram of printed substrate 1505 shown in Figure 15 B. in printed substrate 1505, provide IC, data-signal side drive circuit 1507 and gate signal side drive circuit 1508. as I/O interface (inputing or outputing part) 1506 at least and 1509
In this manual, have on the substrate that is formed on its lip-deep pixel portion by the TAB band is installed in as mentioned above, and had the module of external drive circuit by special called after by being installed in the module of constructing on the substrate through the TAB band as the printed substrate of drive circuit.
Any disclosed in the present invention organic illuminating element can be used as the organic illuminating element that comprises in the present embodiment luminescent device.
[embodiment 16]
Present embodiment illustrates printed substrate is installed in embodiment 12,13, or shown in 14 on the luminescent device this device is made the example of a module.
In module shown in Figure 16 A, TAB is with 1605 to be installed in substrate 1601 and (to comprise pixel portion 1602 at this, data-signal side drive circuit 1603, gate signal side drive circuit 1604, with wiring lines 1603a and 1604a) on, and printed circuit board (PCB) 1606 is installed on the substrate with 1605 through TAB. the functional-block diagram of printed circuit board (PCB) 1606 shown in Figure 16 B.
Shown in Figure 16 B, in printed circuit board (PCB) 1606, provide IC and control unit 1608 as I/O interface 1607 at least and 1610.Provide memory cell 1609 at this, but it is not always required.Control unit 1608 is the parts with control Driver Circuit and correction image data function.
In this manual, be installed in the module of constructing on the substrate that forms organic illuminating element thereon and had the module of peripheral control unit by having printed circuit board (PCB) as controller function as mentioned above by special called after.
Any disclosed in the present invention organic illuminating element can be used as the organic illuminating element that comprises in the present embodiment luminescent device.
[embodiment 17]
Present embodiment illustrates the example of a luminescent device, and wherein the triple light-emitting diodes shown in the embodiment 10 and 11 are according to gray level display driving digit time.The luminescent device of present embodiment can provide even image by using in digit time from the luminous of triple excited states the gray level display, and therefore very useful.
The circuit structure .Tr that Figure 36 A illustrates the pixel of using organic illuminating element represents transistor and Cs represents holding capacitor.In this circuit, when gate line was selected, electric current flowed into Tr1 from source electrode line and accumulates among Cs corresponding to voltage of signals simultaneously. then by the gate source voltage (V of Tr2 Gs) electric current of control flows into Tr2 and organic illuminating element.
After Tr1 is selected, Tr1 is disconnected to keep the voltage (V of Cs Gs).Therefore, electric current is with one and V GsRelevant amount continues to flow.
Figure 36 B illustrate according to digit time gray level display drive the sketch map of this circuit. in the digit time gray level display, frame is divided into the subframe more than. Figure 36 B illustrates six gray scales that one of them frame is divided into six subframes.In this case, the light emissioning cycle of subframe ratio is 32: 16: 8: 4: 2: 1.
Figure 36 C schematically shows the drive circuit of TFT substrate in the present embodiment.Gate driver and Source drive are provided on the same substrate.In the present embodiment, to be designed to be digital driving for image element circuit and driver.Therefore, the fluctuation of TFT performance can not influence device and device and can show even image.
[embodiment 18]
The luminescent device of describing among the embodiment in the above of the present invention has the advantage of low power consumption and long life. therefore, comprise that those luminescent devices are as the low operation of the comparable conventional equipment power consumption of the electric device of its display unit and durable.Especially for the electric device that uses battery as power supply, mancarried device for example, this advantage is very useful, because low power consumption directly brings convenience (battery longer duration).
Luminescent device be self luminous with eliminate as in the LCD to the needs of bias light, and to have its thickness be organic compound layer less than 1 μ m.Therefore luminescent device can be made into thin and lightweight. and therefore the equipment than conventional is thinner and lighter as the electric device of its display unit to comprise luminescent device. and this also directly brings convenience (light and miniaturization when carrying) and very useful for portable equipment and other electric device especially everywhere. in addition, with regard to transportation (a large amount of equipment can betransported) and installation (the saving interior space), undoubtedly, thin (non-bulky (unvoluminous)) all is useful for all electric devices.
Because self-luminous, luminescent device is feature to have than the better definition of liquid crystal display device at the light place with having wide visual angle.Therefore comprise the electric device of luminescent device as its display unit, equally with regard to be easy to watch show with regard to, be very favorable.
In a word, use the electric device of luminescent device of the present invention, remove and have the advantage of conventional organic illuminating element, outside promptly thin/light and high definition, also have the new feature of low power consumption and long life, and so it is very useful.
Present embodiment illustrates the example that comprises as the electric device of the luminescent device of the present invention of display unit.Its specific example is shown in Figure 17 A to 17F and the 18A to 18B.Disclosed in the present invention any metal complex can be used for being included in the organic illuminating element in the electric device of the present invention. and the luminescent device that is included in the electric device of the present invention can have arbitrary structural form shown in Figure 12 to 16 and 34 to 36.
Figure 17 A illustrates the display unit of using an organic illuminating element. and this display device is by housing 1701a, supporting base 1702a, form with display unit 1703a. by luminescent device of the present invention is used as display unit 1703a, display device can be thin, in light weight, and durable. therefore, simplified transportation, installation is to have saved the space, and long service life.
Figure 17 B illustrates a video camera, it is by main body 1701b, display unit 1702b, with audio frequency input unit 1703b, console switch 1704b, battery 1705b and image receiving unit 1706b form. by luminescent device of the present invention is used as display unit 1702b, video camera can be in light weight and power consumption is low. and therefore, it is comparatively convenient that battery consumption can be lowered and carry video camera.
Figure 17 C illustrates a digital camera, and it is by main body 1701c, display unit 1702c, and ocular unit 1703c, console switch 1704c forms.By with luminescent device of the present invention as display unit 1702c, digital camera can be in light weight and power consumption is low. therefore, it is comparatively convenient that battery consumption can be lowered and carry digital camera.
Figure 17 D illustrates the image-reproducing means of being furnished with recording medium.This installs by main body 1701d, recording medium (for example, CD, LD, or DVD) 1702d, and console switch 1703d, display unit (A) 1704d, and display unit (B) 1705d forms.The main displays image information of display unit (A) 1704d and the main videotex information of display unit (B) 1705d. by with luminescent device of the present invention as display unit (A) 1704d and display unit (B) 1705d, the power consumption of image-reproducing means is lower and in light weight and durable. the image-reproducing means of being furnished with recording medium comprises CD-audio player and game machine equally.
Figure 17 E illustrates one (moving) portable computer, it is by main body 1701e, display unit 1702e, image receiving unit 1703e, console switch 1704e, memory bank 1705e forms.By luminescent device of the present invention is used as display unit 1702e, portable computer can be thin and lightweight, and it is low in energy consumption. therefore, battery consumption reduces and to carry computer comparatively convenient. portable computer information can be deposited in flash memory or the recording medium that obtains by integrated nonvolatile storage in, and can reproduce canned data.
Figure 17 F illustrates a personal computer, and it is by main body 1701f, housing 1702f, display unit 1703f and keyboard 1704f form. by with luminescent device of the present invention as display unit 1703f, personal computer can be thin and lightweight, and low in energy consumption.With regard to battery consumption with gently, special in the notebook personal computer that carries everywhere, luminescent device is very big strong point.
Now these electric devices show that the chance of the frequent information, particularly animation information (animation information) that send through the electronic communication circuit of for example Internet with through the radio communication of for example radio wave is increasing.Because organic illuminating element has the very fast speed of response, luminescent device is applicable to that animation shows.
Figure 18 A illustrates a cell phone, and it is by main body 1801a, audio frequency output unit 1802a, and audio frequency input unit 1803a, display unit 1804a, console switch 1805a and antenna 1806a form.By luminescent device of the present invention is used as display unit 1804a, cell phone can be thin and lightweight, and low in energy consumption. and therefore, battery consumption can be lowered, and it is easy to carry cell phone, and main body can miniaturization.
Figure 18 B illustrates a stereo set (particularly on-vehicle acoustic apparatus), it is by main body 1801b, display unit 1802b, and console switch 1803b and 1804b composition. by luminescent device of the present invention is used as display unit 1802b, stereo set can be lightweight and low in energy consumption.Though as the example in the present embodiment, stereo set can be the family expenses stereo set with on-vehicle acoustic apparatus.
It is effective this function being provided for the electric device shown in Figure 17 A to 17F and the 18A to 18B, promptly by provide light-sensitive device to electric device as the means that detect surrounding environment brightness, the radiative aura of brightness regulation of the surrounding environment of using according to electric device. if the contrast rating of radiative aura and surrounding brightness is 100-150, user can have no problem ground recognition image or text message.By this function, the aura of the image that can raise when surrounding environment is bright to be watching better, and the aura that can reduce image when surrounding environment is dark is to reduce power consumption.
Adopt luminescent device of the present invention to can be thin and lightweight equally as the various electric devices of light source and can consume still less power operation, this makes it become very useful device.The light source of liquid crystal display device, for example bias light or preceding light, or the light source of illumination clamping device is included in the luminescent device of the present invention as light source. and therefore, luminescent device can be thin, and is lightweight, and power consumption is low.
According to present embodiment, when LCD is used as the display unit of electric device shown in Figure 17 A to 17F and the 18A to 18B, if those LCD are used luminescent device of the present invention light or preceding light as a setting, electric device can be thin and lightweight and power consumption lower.
[embodiment 19]
In the present embodiment, describe the example of an active array type constant current drive circuit, this circuit is by the constant current driven that flows in organic illuminating element of the present invention.Its circuit structure is shown in Figure 37.
Pixel 1810 shown in Figure 37 has holding wire Si, the first scan line Gj, the second scan line Pj and power line Vi. are in addition, pixel 1810 has transistor (below be called " Tr ") 1, Tr2, Tr3, Tr4 mixes the organic illuminating element 1811 of bond types and keeps capacitor (retention capacitor) 1812.
Two grids of Tr3 and Tr4 are connected with the first scan line Gj.As for source electrode and the drain electrode of Tr3, one is connected with holding wire Si, and another is connected with the source electrode of Tr2.In addition, the source electrode of Tr4 and drain electrode, one is connected with the source electrode of Tr2, so another is connected with the grid of Tr1., any one in Tr3 source electrode and the drain electrode and source electrode or the drain electrode of Tr4 interconnect.
The source electrode of Tr1 is connected with power line Vi and the drain electrode of Tr1 is connected with the source electrode of Tr2.The grid of Tr2 is connected with the second scan line Pj. and the drain electrode of Tr2 is connected with pixel electrode in the organic illuminating element 1811.Organic illuminating element 1811 has pixel electrode, reverse electrode and be provided at pixel electrode and reverse electrode between organic luminous layer.The reverse electrode of organic illuminating element 1811 applies constant voltage by the power supply that is provided at light expelling plate outside.
Tr3 and Tr4 both can adopt n channel-type TFT also can adopt p channel-type TFT.But the polarity of Tr3 and Tr4 is identical.In addition, Tr1 both can adopt n channel-type TFT also can adopt p channel-type TFT.Tr2 both can adopt n channel-type TFT also can adopt p channel-type TFT. as for polarity, have in organic illuminating element under the situation of pixel electrode and reverse electrode, one is anode and another is a negative electrode.At Tr2 is under the situation of p channel-type TFT, preferably use anode as pixel electrode, and negative electrode is as reverse electrode. opposite, and be under the situation of n channel-type TFT at Tr2, preferably use negative electrode as pixel electrode, and anode is as reverse electrode.
Keep capacitor 1812 to be formed between the grid and source electrode of Tr1.Provide and keep capacitor 1812 to be used for keeping more definitely voltage (V between Tr1 grid and the source electrode GS). still, it does not need always to provide.
In pixel shown in Figure 37, supply with the current source place control of electric current in signal-line driving circuit of holding wire Si.
By using the foregoing circuit structure, can realize constant current driven, the retainable brightness of constant current of in organic illuminating element, flowing by this. the organic illuminating element with Mixed Zone of the present invention has the useful life longer than existing organic illuminating element. because can realize very long useful life by implementing above-mentioned constant current driven, organic illuminating element is effective.
Practice of the present invention can provide the luminescent device that a kind of power consumption is little and the life-span is fabulous.In addition, by this luminescent device being used for light source or the display part can obtain, bright and power consumption is little and long-time durable electric device.

Claims (16)

1. organic illuminating element, described organic illuminating element comprises:
Anode on the substrate;
The ground floor that comprises hole-injecting material and hole conveying material on described anode;
The second layer that comprises host material and hole conveying material on described ground floor;
On the described second layer, comprise hole barrier materials and host material the 3rd layer;
On described the 3rd layer, comprise electronics injection material and hole barrier materials the 4th layer; And
Negative electrode on described the 4th layer;
Wherein luminescent material is entrained in the part and described the 3rd a layer part of the described second layer, and
The highest in the wherein said hole barrier materials occupied molecular orbit and the minimum energy difference that is not occupied between the molecular orbit is occupied molecular orbit than the highest in described hole conveying material and described host material and the minimum energy difference that is not occupied between the molecular orbit is big.
2. according to the organic illuminating element of claim 1, wherein said ground floor is that the hole transports mixed layer.
3. according to the organic illuminating element of claim 1, the wherein said second layer is the dipole characteristic mixed layer.
4. according to the organic illuminating element of claim 1, wherein said the 3rd layer is to stop mixed layer.
5. according to the organic illuminating element of claim 1, wherein said the 4th layer is the electron transport mixed layer.
6. according to the organic illuminating element of claim 1, wherein said hole barrier materials is as electron transport material.
7. according to the organic illuminating element of claim 1, wherein said luminescent material is triple light-emitting materials.
8. according to the organic illuminating element of claim 7, wherein said triple light-emitting materials have the central metal that is selected from platinum or iridium.
9. according to the organic illuminating element of claim 1, wherein said luminescent material is the material that is selected from metal complex or fluorescent dye.
10. electric device, described electric device has the organic illuminating element according to claim 1.
11. according to the electric device of claim 10, wherein said electric device is selected from automobile audio, video camera, digital camera, image-reproducing means, personal computer and cell phone.
12., be electrically connected to Current Control TFT one of in wherein said anode and the negative electrode according to the organic illuminating element of claim 1.
13. a luminescent device, described luminescent device comprises the organic illuminating element according to claim 1.
14. according to the electric device of claim 11, wherein said image-reproducing means is a display unit.
15. according to the electric device of claim 11, wherein said personal computer is the mobile portable computer.
16. a passive matrix luminescent device, described passive matrix luminescent device comprises the organic illuminating element according to claim 1.
CN2006101019072A 2000-12-28 2001-12-28 Light emitting device Expired - Fee Related CN1953233B (en)

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US5925980A (en) * 1997-05-01 1999-07-20 Motorola, Inc. Organic electroluminescent device with graded region

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US5925980A (en) * 1997-05-01 1999-07-20 Motorola, Inc. Organic electroluminescent device with graded region

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