It is inverted blue light quantum point membrane electro luminescent device
Technical field
The present invention relates to light emitting device technologies field, and blue light quantum point TFEL device is inverted more particularly, to one kind
Part.
Background technology
Quantum dot (QDs, quantum dots) is semiconductor nano that some can not visually see, extremely small
Body, particle diameter are generally less than 10nm.Stimulated when by light or electricity, quantum dot can send coloured light, and the color of light is by measuring
The composition material and size shape of son point determine that this characteristic enables quantum dot to change the light color that light source is sent.By
In electronics, hole and exciton on three-dimensional space direction by quantum confinement so that QDs band structure by block continuous structure
Become the discrete energy level structure with molecular characterization.When the bohr of QDs particle diameters and ten thousand Neil excitons (Wannier exciton) half
Footpath (Bohr radius) is quite or more hour, the locality of electronics and coherence's enhancing, the absorption coefficient of exciton band increase, gone out
Existing exciton absorbs by force, can launch hyperfluorescence after being excited, and symmetrical emission spectrum, width and continuous absorption spectra etc. with narrow
Advantage.With QDs change in size, the effect of quantum effect enables it to gap width and changed therewith, so as to send different colours
Light.With light emitting diode with quantum dots made of QDs (QLEDs, quantum dot light emitting diodes) also by
This possesses the features such as high efficiency, rich in color, high stability.
However, the hole of traditional quantum dot film electroluminescent device (QLED) is not easy injection, it is necessary to high HOMO
The hole-injecting material of (Highest Occupied Molecular Orbital, highest occupied molecular orbital) energy level helps
The injection in hole.Especially for blue light quantum point membrane electro luminescent device, the HOMO energy levels of blue light quantum point are generally large,
About 6.8eV, and the work function of in general transparent anode is about less than 5.0eV, both differ farther out, cause in QLED devices
Hole injection barrier is universal higher, and the HOMO energy levels of conventional hole-injecting material are generally 5.0eV~5.5eV, Wu Faman
The requirement of sufficient hole injection.
The content of the invention
Based on this, it is necessary to provide a kind of inversion blue light quantum point TFEL that can meet hole injection and require
Device.
One kind be inverted blue light quantum point membrane electro luminescent device, including stack gradually substrate, negative electrode, electric transmission
Layer, blue light quantum point luminescent layer, hole transmission layer and anode;
The hole transmission layer includes the first hole transmission layer and the second hole transmission layer of stacking, and first hole passes
Defeated layer directly contacts with the blue light quantum point luminescent layer, and the thickness of first hole transmission layer is 5nm~15nm;
It is mixed that the material of first hole transmission layer is that the first hole mobile material and the second hole mobile material are formed
Compound, the material of second hole transmission layer is the second hole mobile material and the mixing of the 3rd hole mobile material formation
Thing;
The HOMO energy levels of first hole transmission layer are 5.5eV~6.8eV, the HOMO energy of second hole transmission layer
Level is 4.2eV~5.5V, and the HOMO energy levels of first hole transmission layer are more than the HOMO energy levels of second hole transmission layer.
In one embodiment, the material of the blue light quantum point luminescent layer is selected from CdSe@ZnS core shell structure blue light amounts
One kind in son point and ZnCdS@ZnS core shell structure blue light quantum points, wherein ,@represents cladding, and CdSe or ZnCdS are the core
The core of core-shell structure quantum dots, ZnS are the shell of the nuclear shell structure quantum point.
In one embodiment, the thickness of the blue light quantum point luminescent layer is 20nm~30nm.
In one embodiment, the HOMO energy levels of first hole mobile material, second hole mobile material
HOMO energy levels and the HOMO energy levels of the 3rd hole mobile material be sequentially reduced.
In one embodiment, first hole mobile material is selected from 2- hydroxy-3-methyl -2- cyclopentene-1-ones
With 6,6- bis- (4-9 hydrogen-carbazole -9- bases) phenyl) one kind in -6 hydrogen-pyrroles [3,2,1-de] acridine.
In one embodiment, second hole mobile material is selected from N, and N '-two (1- naphthyls)-N, N '-diphenyl-
1,1 '-biphenyl -4-4 '-diamines, 2,2 ' two (3- dimethyl benzenes aminobenzene) 1,1 ' biphenyl, 4,4'- double (9H- carbazole -9- bases) connection
Benzene, (4- (9 hydrogen-carbazole -9- bases) phenyl) -8 hydrogen-indoles [3,2,1-de] acridines (FPCC) of 8,8- bis- and (9 hydrogen-click of 3,5- bis-
Azoles -9- bases)-nitrogen, one kind in nitrogen-biphenyl ammonia.
In one embodiment, the 3rd hole mobile material is selected from molybdenum trioxide, tungstic acid, vanadium oxide and titanium
One kind in cyanines copper.
In one embodiment, the first hole mobile material described in first hole transmission layer and second sky
The mass ratio of hole transport materials is 1:1~2:1, first hole mobile material be selected from 2- hydroxy-3-methyl -2- cyclopentene -
1- ketone and 6,6- bis- (4-9 hydrogen-carbazole -9- bases) phenyl) one kind in -6 hydrogen-pyrroles [3,2,1-de] acridine, described second is empty
Hole transport materials are selected from N, N '-two (1- naphthyls)-N, N '-diphenyl -1,1 '-biphenyl -4-4 '-diamines, 2,2 ' two (3- dimethyl
Phenyl amino phenyl) 1,1 ' biphenyl, 4,4'- double (9H- carbazole -9- bases) biphenyl, 8,8- bis- (4- (9 hydrogen-carbazole -9- bases) phenyl) -8
Hydrogen-indoles [3,2,1-de] acridine and 3,5- bis- (9 hydrogen-carbazole -9- bases)-nitrogen, one kind in nitrogen-biphenyl ammonia.
In one embodiment, the second hole mobile material described in second hole transmission layer and the 3rd sky
The mass ratio of hole transport materials is 2:3~1:1, second hole mobile material is selected from N, N '-two (1- naphthyls)-N, N '-two
Double (9H- carbazoles-the 9- of phenyl -1,1 '-biphenyl -4-4 '-diamines, 2,2 ' two (3- dimethyl benzenes aminobenzene) 1,1 ' biphenyl, 4,4'-
Base) biphenyl, (4- (9 hydrogen-carbazole -9- bases) phenyl) -8 hydrogen-indoles [3,2,1-de] acridines of 8,8- bis- and (9 hydrogen-click of 3,5- bis-
Azoles -9- bases)-nitrogen, one kind in nitrogen-biphenyl ammonia, the 3rd hole mobile material is selected from molybdenum trioxide, tungstic acid, oxidation
One kind in vanadium and titanium cyanines copper.
In one embodiment, the thickness of second hole transmission layer is 15nm~30nm.
Above-mentioned inversion blue light quantum point membrane electro luminescent device, including stack gradually substrate, negative electrode, electric transmission
Layer, blue light quantum point luminescent layer, hole transmission layer and anode.Hole transmission layer includes the first hole transmission layer and the of stacking
Two hole transmission layers.Wherein, the thickness of the first hole transmission layer directly contacted with blue light quantum point luminescent layer be 5nm~
15nm, the first hole transmission layer of thinner thickness, on the basis of enough hole injections are ensured, electroluminescent hair can be effectively reduced
The leakage current of optical device, improve luminous efficiency.The material of first hole transmission layer and the second hole transmission layer is two kinds of holes
The mixture that transmission material is formed, and have a kind of identical hole mobile material in two layers of hole transmission layer so that hole transport
Potential barrier change is gentle between layer, further reduces blue light QLED driving voltage.The HOMO energy levels of first hole transmission layer are
6.04eV~6.8eV, it is close with the HOMO energy levels of blue light quantum point, the HOMO energy levels of the second hole transmission layer for 4.2eV~
6.03eV, it is close with the work function of anode, and the HOMO energy levels of the first hole transmission layer are more than the second hole transmission layer
HOMO energy levels, so as to form steps potential barrier between blue light quantum point luminescent layer and anode, reach and step up sub- hole biography
The Hole injection capacity of defeated layer, meet the requirement of the hole injection of blue light quantum point membrane electro luminescent device.
Brief description of the drawings
Fig. 1 is the structural representation of the inversion blue light quantum point membrane electro luminescent device of an embodiment;
Fig. 2 is the level structure principle schematic for being inverted blue light quantum point membrane electro luminescent device;
Fig. 3 is the flow chart of the preparation method of the inversion blue light quantum point membrane electro luminescent device of an embodiment;
Fig. 4 is respectively to the inversion blue light quantum point thin-film electro in embodiment 1, embodiment 2, embodiment 3 and comparative example
Electroluminescence device carries out the result figure of luminance test.
Embodiment
It is described in further detail below mainly in combination with accompanying drawing to being inverted blue light quantum point membrane electro luminescent device.
As shown in figure 1, the inversion blue light quantum point membrane electro luminescent device 10 of an embodiment, including stack gradually
Substrate 100, negative electrode 200, electron transfer layer 300, blue light quantum point luminescent layer 400, hole transmission layer 500 and anode 600.
The material of substrate 100 can be glass, and glass transmission is good, and conveniently sputter or be deposited conducting film thereon.
The material of negative electrode 200 can be indium tin oxide (ITO), fluorine doped tin oxide (FTO), the zinc oxide (AZO) for mixing aluminium,
Indium-doped zinc oxide (IZO) etc..The thickness of negative electrode 200 can be 80nm~200nm.
Electron transfer layer 300 has preferable electron mobility, can be zinc oxide (ZnO) or titanium dioxide (TiO2) etc..
Specifically, the thickness of electron transfer layer 300 is 30nm~50nm.
The material of blue light quantum point luminescent layer 400 is selected from CdSe@ZnS core shell structure blue light quantum points and ZnCdS@ZnS cores
One kind in shell structure blue light quantum point, wherein ,@represents cladding, CdSe or the core that ZnCdS is the nuclear shell structure quantum point,
ZnS is the shell of the nuclear shell structure quantum point.The particle diameter of CdSe@ZnS core shell structure blue light quantum points is generally 3nm~6nm,
The particle diameter of ZnCdS@ZnS core shell structure blue light quantum points is generally 8nm~15nm, both nuclear shell structure quantum points, brightness compared with
Height, luminous efficiency are high.
Specifically, the thickness of blue light quantum point luminescent layer 400 is 20nm~30nm.
Hole transmission layer 500 includes the first hole transmission layer 510 and the second hole transmission layer 520 of stacking, the first hole
Transport layer 510 directly contacts with blue light quantum point luminescent layer 400, and the thickness of the first hole transmission layer 510 is 5nm~15nm.
The first hole transmission layer 510 that the side for being close to blue light quantum point luminescent layer 400 sets a layer thickness to be 5nm~15nm can be
On the basis of ensureing enough hole injections, the leakage current of electroluminescent device is effectively reduced, improves luminous efficiency.
Further, the thickness of the first hole transmission layer 510 is 6nm~8nm.
The level structure principle schematic of blue light quantum point membrane electro luminescent device 10 is inverted as shown in Fig. 2 first is empty
The material of cave transport layer 510 is the mixing that the first hole mobile material (HTL1) and the second hole mobile material (HTL2) are formed
Thing, the material of the second hole transmission layer 520 is the second hole mobile material (HTL2) and the 3rd hole mobile material (HTL3) shape
Into mixture.The HOMO energy levels of the HOMO energy levels of first hole transmission layer 510 and blue light quantum point luminescent layer 400 (are generally
6.8eV or so) it is close, and the HOMO energy levels of the second hole transmission layer 520 with anode work function number (for example, Al work function is
4.0eV or so) it is close, the first hole transmission layer 510 and the second hole transmission layer 520 form stair-stepping relationship between energy levels, work as sky
When cave migrates from anode to cathode direction, hole injection barrier is small, and transport efficiency is high.
Specifically, the first hole mobile material (HTL1), the second hole mobile material (HTL2) and the 3rd hole transport material
The HOMO energy levels of material (HTL3) are sequentially reduced.First hole transmission layer 510 and the second hole transmission layer 520 use two kinds of holes
Transmission material (HTL) doping forms doping system.Compared to a kind of traditional only hole transmission layer of hole mobile material, by two
Kind hole mobile material (HTL) doping forms doping system, and easily realization obtains different HOMO energy levels, so as to form ladder
The potential barrier of shape.And there is a kind of identical hole mobile material in the first hole transmission layer 510 and the second hole transmission layer 520,
So that potential barrier change is gentle between hole transmission layer, be advantageous to the injection in hole, further reduce blue light QLED driving voltage.
Specifically, the HOMO energy levels of the first hole transmission layer 510 are 6.04eV~6.8eV, the second hole transmission layer 520
HOMO energy levels are 4.2eV~6.03eV, and the HOMO energy levels of the first hole transmission layer 510 are more than the second hole transmission layer 520
HOMO energy levels.The HOMO energy levels of first hole transmission layer 510 and the HOMO energy levels of blue light quantum point luminescent layer 400 (are about
It is 6.8eV) close, and the HOMO energy levels of the second hole transmission layer 520 are close with the work function of anode, pass through the first hole transport
The hole transmission layer 520 of layer 510 and second forms steps potential barrier between blue light quantum point luminescent layer and anode, reaches and progressively carries
The Hole injection capacity of high hole transport layer, meet the requirement of the hole injection of blue light quantum point membrane electro luminescent device.
Traditional quantum dot film electroluminescent device for just putting structure, because quantum dot light emitting layer (QDs luminescent layers) needs
To be prepared using solwution method, when preparing cave transport layer 500, solwution method limit hole injection and hole mobile material can
Selectivity.The blue light quantum point membrane electro luminescent device 10 of the present invention uses inverted structure, and anode 600 is in the superiors, from base
Bottom 100 is farthest.Hole transmission layer 500 can be made after the completion of the preparation of blue light quantum point luminescent layer 400 with the mode of vacuum evaporation
It is standby, therefore the high HOMO energy levels hole mobile material selectable range matched with blue light quantum point luminescent layer 400 is wider.
Specifically, the first hole mobile material (HTL1) is selected from 2- hydroxy-3-methyl -2- cyclopentene-1-ones (mCP) and 6,
6- bis- (4-9 hydrogen-carbazole -9- bases) phenyl) one kind in -6 hydrogen-pyrroles [3,2,1-de] acridine (BCPPA).HTL1 HOMO energy
Level one is higher, close to the HOMO energy levels of blue light quantum point luminescent layer 400 so that hole easily passes from the first hole transmission layer 510
Lead into blue light quantum point luminescent layer 400, improve luminous efficiency.
Second hole mobile material (HTL2) is selected from N, and N '-two (1- naphthyls)-N, N '-diphenyl -1,1 '-biphenyl -4-4 ' -
Double (9H- carbazole -9- bases) biphenyl of diamines (NPB), 2,2 ' two (3- dimethyl benzenes aminobenzene) 1,1 ' biphenyl (BTPD), 4,4'-
(CBP), (4- (9 hydrogen-carbazole -9- bases) phenyl) -8 hydrogen-indoles [3,2,1-de] acridines (FPCC) of 8,8- bis- and 3,5- bis- (9 hydrogen -
Carbazole -9- bases)-nitrogen, one kind in nitrogen-biphenyl ammonia (DCDPA).In general, HTL2 HOMO energy levels are less than HTL1 HOMO energy
Level.
3rd hole mobile material (HTL3) is selected from molybdenum trioxide (MoO3), tungstic acid (WO3), vanadium oxide (V2O5) and
One kind in titanium cyanines copper (CuPc).In general, HTL3 HOMO energy levels are less than HTL2 HOMO energy levels.HTL3 HOMO energy levels one
As it is relatively low, close to the work function of anode so that hole easily from anode conduction enter the second hole transmission layer 520 in, improve hair
Light efficiency.
Specifically, the mass ratio of the first hole mobile material and the second hole mobile material in the first hole transmission layer 510
For 1:1~2:1.Wherein, the first hole mobile material (HTL1) be selected from 2- hydroxy-3-methyl -2- cyclopentene-1-ones (mCP) and
6,6- bis- (4-9 hydrogen-carbazole -9- bases) phenyl) one kind in -6 hydrogen-pyrroles [3,2,1-de] acridine (BCPPA), the second hole passes
Defeated material (HTL2) is selected from N, N '-two (1- naphthyls)-N, N '-diphenyl -1,1 '-biphenyl -4-4 '-diamines (NPB), 2,2 ' two
(3- dimethyl benzenes aminobenzene) 1,1 ' biphenyl (BTPD), 4,4'- double (9H- carbazole -9- bases) biphenyl (CBP), (4- (9 of 8,8- bis-
Hydrogen-carbazole -9- bases) phenyl) -8 hydrogen-indoles [3,2,1-de] acridine (FPCC) and 3,5- bis- (9 hydrogen-carbazole -9- bases)-nitrogen, nitrogen -
One kind in biphenyl ammonia (DCDPA).
The mass ratio of second hole mobile material and the 3rd hole mobile material is 2 in second hole transmission layer 520:3~
1:1.Wherein, the second hole mobile material (HTL2) is selected from N, N '-two (1- naphthyls)-N, N '-diphenyl -1,1 '-biphenyl -4-
Double (9H- carbazole -9- bases) biphenyl of 4 '-diamines (NPB), 2,2 ' two (3- dimethyl benzenes aminobenzene) 1,1 ' biphenyl (BTPD), 4,4'-
(CBP), (4- (9 hydrogen-carbazole -9- bases) phenyl) -8 hydrogen-indoles [3,2,1-de] acridines (FPCC) of 8,8- bis- and 3,5- bis- (9 hydrogen -
Carbazole -9- bases)-nitrogen, one kind in nitrogen-biphenyl ammonia (DCDPA), the 3rd hole mobile material (HTL3) is selected from molybdenum trioxide
(MoO3), tungstic acid (WO3), vanadium oxide (V2O5) and titanium cyanines copper (CuPc) in one kind.
By adjusting the quality of HTL1 and HTL2 in the first hole transmission layer 510 when the second hole transmission layer 520 respectively
Middle HTL2 and HTL3 mass ratio, the first hole transmission layer 510 and the second hole that can obtain multiple different HOMO energy levels pass
Defeated layer 520, so as to which the HOMO energy levels formed layer by layer successively decrease relation, between the blue light quantum point luminescent layer 400 and anode 600 that make
Potential barrier change is gentle, beneficial to the transmission in hole, improves luminous efficiency.
Specifically, the first hole transmission layer 510 is less than the thickness of the second hole transmission layer 520.It is close to blue light quantum point hair
The thinner thickness of first hole transmission layer 510 of photosphere 400, because the hole mobility of the first hole transmission layer 510 is relatively low,
5nm~15nm relatively thin thickness effectively reduces the leakage of electroluminescent device on the basis of enough hole injections are ensured
Electric current, improve luminous efficiency.The thickness of second hole transmission layer 520 determines according to the property of hole mobile material.
Specifically, the thickness of the second hole transmission layer 520 is 15nm~30nm.
Traditional QLED only has the hole transmission layer 500 of individual layer, or has sandwich construction, is typically also to make identical thickness
Degree, due to hole, the mobility at each position is not quite similar in hole transmission layer 500, and the efficiency of hole transport is low.The application
In the first hole transmission layer 510 thickness be less than the second hole transmission layer 520 thickness, according to stair-stepping potential barrier change and
Hole mobility, the thickness of each layer of hole transmission layer is rationally designed, improve the efficiency of transmission in hole, and then improve QLED hair
Light efficiency.
The one kind of anode 600 in aluminium, silver, gold and platinum.Aluminium (Al), silver-colored (Ag), the work function of golden (Au) and platinum (Pt)
It is higher, be advantageous to reduce the barrier potential difference between anode 600 and blue light quantum point luminescent layer 400.
Specifically, the thickness of anode 600 is 100nm~150nm.
Above-mentioned inversion blue light quantum point membrane electro luminescent device 10, including substrate 100, negative electrode 200, the electricity stacked gradually
Sub- transmitting layer 3 00, blue light quantum point luminescent layer 400, hole transmission layer 500 and anode 600.Hole transmission layer 500 include according to
The first hole transmission layer 510 and the second hole transmission layer 520 of secondary stacking.Wherein, it is close to the first of blue light quantum point luminescent layer
The thickness of hole transmission layer is 5nm~15nm, the first hole transmission layer of thinner thickness, is ensureing the base of enough hole injections
On plinth, the leakage current of electroluminescent device can be effectively reduced, improves luminous efficiency.First hole transmission layer 510 and second is empty
The material of cave transport layer 520 is the mixture that two kinds of hole mobile materials are formed, and has a kind of phase in two layers of hole transmission layer
Same hole mobile material so that potential barrier change is gentle between hole transmission layer, further reduces blue light QLED driving voltage.
The HOMO energy levels of first hole transmission layer 510 are 6.04eV~6.8eV, close with the HOMO energy levels of blue light quantum point;Second is empty
The HOMO energy levels of cave transport layer 520 are 4.2eV~6.03eV, close with the work function of anode 600;And the first hole transmission layer
510 HOMO energy levels are more than the HOMO energy levels of the second hole transmission layer 520, so as in blue light quantum point luminescent layer 400 and anode
Steps potential barrier is formed between 600, reaches the Hole injection capacity for stepping up hole transmission layer, meets blue light quantum point film
The requirement of the hole injection of electroluminescent device.
In addition, the present invention also provides a kind of preparation method of above-mentioned inversion blue light quantum point membrane electro luminescent device 10,
As shown in figure 3, this method comprises the following steps S110~S140.
S110, substrate is provided, negative electrode is formed in substrate.
The material of substrate can be glass, can respectively be ultrasonically treated substrate with detergent, acetone, ethanol and isopropanol successively
15min.Evaporation, spraying plating, sputtering or electrochemistry hydatogenesis form negative electrode in substrate afterwards.The material of negative electrode can be indium tin
Oxide (ITO), fluorine doped tin oxide (FTO), the zinc oxide (AZO) for mixing aluminium, indium-doped zinc oxide (IZO) etc., the thickness of negative electrode
For 80nm~200nm.
Preferably, indium tin oxide (ITO) is sputtered onto in substrate of glass using the method for sputtering.
In present embodiment, after forming negative electrode in substrate, include to formed the substrate of negative electrode use successively detergent,
Acetone, ethanol and isopropanol are respectively ultrasonically treated 15min, then carry out UV ozone (UV-ozone) processing 15min.
Electron transfer layer and blue light quantum point luminescent layer are sequentially formed on S120, the negative electrode obtained in S110.
Electron transfer layer can be prepared on negative electrode conducting film using solution spin-coating method, electron transfer layer can be zinc oxide
Or titanium dioxide (TiO (ZnO)2) etc., thickness 30nm~50nm of electron transfer layer.
Equally, blue light quantum point luminescent layer, blue light quantum point hair can be formed on the electron transport layer using solution spin-coating method
The thickness of photosphere is 20nm~30nm.The material of blue light quantum point luminescent layer can be CdSe ZnS core shell structure blue light quantum points
Or ZnCdS@ZnS core shell structure blue light quantum points.
Form hole transmission layer on S130, the blue light quantum point luminescent layer obtained in S120, hole transmission layer include according to
The first hole transmission layer and the second hole transmission layer of secondary stacking.
First hole transmission layer, the first hole transmission layer can be formed on blue light quantum point luminescent layer using vacuum vapour deposition
The mixture that is formed for the first hole mobile material (HTL1) and the second hole mobile material (HTL2) of material, the first hole biography
The thickness of defeated layer is 5nm~15nm.Vacuum evaporation forms the second hole transmission layer, the second hole on the first hole transmission layer again
The mixture that the material of transport layer is formed for the second hole mobile material (HTL2) and the second hole mobile material (HTL3), second
The thickness of hole transmission layer can be 15nm~30nm
S140, obtain in S130 forming anode on the second hole transmission layer.
Anode can be formed on the second hole transmission layer using evaporation, spraying plating, sputtering or the method for electrochemistry hydatogenesis.
The material of anode may be selected from one kind in aluminium, silver, gold and platinum.
This preparation method for being inverted blue light quantum point membrane electro luminescent device, technique are simple, easy to operate.It is prepared
Blue light quantum point membrane electro luminescent device blue light quantum point luminescent layer and anode between form steps potential barrier, hole passes
The Hole injection capacity of defeated layer is strong, meets the requirement of the hole injection of blue light quantum point membrane electro luminescent device.
It is embodiment part below.
In following examples, unless otherwise instructed, the experimental method of unreceipted actual conditions, generally according to normal condition,
Experiment material used is purchased from Sigma-Aldrich (Shanghai) trade Co., Ltd, lark prestige Science and Technology Ltd..
Embodiment 1
The structure for being inverted blue light quantum point membrane electro luminescent device is substrate, negative electrode, electron transfer layer, blue light quantum point
Luminescent layer, hole transmission layer and anode, its hole-transporting layer include the first hole transmission layer stacked gradually and the second sky
Cave transport layer.First hole transmission layer directly contacts with blue light quantum point luminescent layer.Wherein, the thickness of the first hole transmission layer is
8nm, the material of the first hole transmission layer is the first hole mobile material (HTL1) and the second hole mobile material (HTL2) formation
Mixture, wherein HTL1 is 6,6- bis- (4-9 hydrogen-carbazole -9- bases) phenyl) -6 hydrogen-pyrroles [3,2,1-de] acridine
(BCPPA), HTL2 3,5- bis- (9 hydrogen-carbazole -9- bases)-nitrogen, nitrogen-biphenyl ammonia (DCDPA), BCPPA and DCDPA mass ratioes are
1:1.The thickness of second hole transmission layer is 25nm, the material of the second hole transmission layer for the second hole mobile material (HTL2) and
The mixture that 3rd hole mobile material (HTL3) is formed, wherein HTL2 are 3,5- bis- (9 hydrogen-carbazole -9- bases)-nitrogen, nitrogen-biphenyl
Ammonia (DCDPA), HTL3 are molybdenum trioxide (MoO3), DCDPA and MoO3Mass ratio be 2:3.
The specific preparation process for being inverted blue light quantum point membrane electro luminescent device is as follows:
Substrate of glass is respectively ultrasonically treated 15min with detergent, acetone, ethanol and isopropanol successively.Then in glass base
A layer thickness is sputtered on plate and is 150nm ITO conducting films, then carries out UV ozone (UV-ozone) processing 15min.Then use
Solution spin-coating method prepares ZnO electron transfer layers in full of nitrogen and the extremely low glove box of water oxygen content, using 20mg/ml's
ZnO nano particle ethanol solution, it is 1500 revs/min (Resolutions per minute, rpm) in rotating speed, temperature 150
Anneal 30min at DEG C, and the thickness of ZnO electron transfer layers is 40nm.Blue light quantum point is prepared on the electron transport layer afterwards to light
Layer, using 20mg/ml blue light CdSe@ZnS quantum dot toluene solutions, in rotating speed 2000rpm, temperature is to be annealed at 150 DEG C
30min, blue light quantum point light emitting layer thickness are 20nm.Device is transferred to pressure as 10 afterwards-4In high vacuum cavity under Pa,
It is successively 1 by mass ratio:1 BCPPA and DCDPA vacuum evaporation forms the first hole transmission layer, mass ratio 2:3 DCDPA
With MoO3Vacuum evaporation forms the second hole transmission layer.Last vacuum evaporation 100nm Al electrodes obtain being inverted indigo plant as anode
Light quanta point membrane electro luminescent device.
The first hole transmission layer and the second hole transmission layer are tested respectively, the HOMO energy levels of the first hole transmission layer
For 6.04eV, the HOMO energy levels of the second hole transmission layer are 5.88eV.
Luminance test is carried out to the inversion blue light quantum point membrane electro luminescent device being prepared, as a result as shown in Figure 4.
From fig. 4, it can be seen that inversion blue light quantum point membrane electro luminescent device brightness height in embodiment 1 is apparently higher than comparative example.
Embodiment 2
The thickness of the first hole transmission layer is 5nm in the inversion blue light quantum point membrane electro luminescent device of the present embodiment,
The material of first hole transmission layer is the mixture that HTL1 and HTL2 are formed, and wherein HTL1 is BCPPA, HTL2 DCDPA,
BCPPA is 1 with DCDPA mass ratioes:1.The thickness of second hole transmission layer is 15nm, and the material of the second hole transmission layer is HTL2
The mixture formed with HTL3, wherein HTL2 is DCDPA, HTL3 MoO3, DCDPA and MoO3Mass ratio is 1:1.Remaining and reality
It is identical to apply example 1.
The specific preparation method for being inverted blue light quantum point membrane electro luminescent device is same as Example 1.
The HOMO energy levels of first hole transmission layer are 6.04eV, and the HOMO energy levels of the second hole transmission layer are 5.88eV.
Luminance test is carried out to the inversion blue light quantum point membrane electro luminescent device being prepared, as a result as shown in Figure 4.
From fig. 4, it can be seen that inversion blue light quantum point membrane electro luminescent device brightness height in embodiment 2 is apparently higher than comparative example.
Embodiment 3
The thickness of the first hole transmission layer is 15nm in the inversion blue light quantum point membrane electro luminescent device of the present embodiment,
The material of first hole transmission layer is the mixture that HTL1 and HTL2 are formed, and wherein HTL1 is BCPPA, HTL2 DCDPA,
BCPPA is 3 with DCDPA mass ratioes:2.The thickness of second hole transmission layer is 30nm, and the material of the second hole transmission layer is HTL2
The mixture formed with HTL3, wherein HTL2 is DCDPA, HTL3 MoO3, DCDPA and MoO3Mass ratio is 2:3.Remaining and reality
It is identical to apply example 1.
The specific preparation method for being inverted blue light quantum point membrane electro luminescent device is same as Example 1.
The HOMO energy levels of first hole transmission layer are 6.04eV, and the HOMO energy levels of the second hole transmission layer are 5.88eV.
Luminance test is carried out to the inversion blue light quantum point membrane electro luminescent device being prepared, as a result as shown in Figure 4.
From fig. 4, it can be seen that inversion blue light quantum point membrane electro luminescent device brightness height in embodiment 3 is apparently higher than comparative example.
Embodiment 4
The thickness of the first hole transmission layer is 10nm in the inversion blue light quantum point membrane electro luminescent device of the present embodiment,
The material of first hole transmission layer is the mixture that HTL1 and HTL2 is formed, and wherein HTL1 is BCPPA, HTL2 NPB, BCPPA
It is 2 with NPB mass ratioes:1.The thickness of second hole transmission layer is 25nm, and the material of the second hole transmission layer is HTL2 and HTL3
The mixture of formation, wherein HTL2 are NPB, and HTL3 CuPc, NPB and CuPc mass ratio are 1:1.Remaining is same as Example 1.
The specific preparation method for being inverted blue light quantum point membrane electro luminescent device is same as Example 1.
The HOMO energy levels of first hole transmission layer are 6.04eV, and the HOMO energy levels of the second hole transmission layer are 5.4eV.
Embodiment 5
The thickness of the first hole transmission layer is 15nm in the inversion blue light quantum point membrane electro luminescent device of the present embodiment,
The material of first hole transmission layer is the mixture that HTL1 and HTL2 is formed, and wherein HTL1 is BCPPA, HTL2 BTPD, BCPPA
It is 1 with BTPD mass ratioes:1.The thickness of second hole transmission layer is 20nm, and the material of the second hole transmission layer is HTL2 and HTL3
The mixture of formation, wherein HTL2 are BTPD, HTL3 WO3, BTPD and WO3Mass ratio is 2:3.Remaining is same as Example 1.
The specific preparation method for being inverted blue light quantum point membrane electro luminescent device is same as Example 1.
The HOMO energy levels of first hole transmission layer are 6.04eV, and the HOMO energy levels of the second hole transmission layer are 5.57eV.
Embodiment 6
The thickness of the first hole transmission layer is 5nm in the inversion blue light quantum point membrane electro luminescent device of the present embodiment,
The material of first hole transmission layer is the mixture that HTL1 and HTL2 is formed, and wherein HTL1 is mCP, HTL2 CBP, mCP and CBP
Mass ratio is 2:1.The thickness of second hole transmission layer is 18nm, and the material of the second hole transmission layer is HTL2 and HTL3 formation
Mixture, wherein HTL2 are CBP, HTL3 V2O5, CBP and V2O5Mass ratio is 3:4.Remaining is same as Example 1.
The specific preparation method for being inverted blue light quantum point membrane electro luminescent device is same as Example 1.
The HOMO energy levels of first hole transmission layer are 6.1eV, and the HOMO energy levels of the second hole transmission layer are 5.9eV.
Embodiment 7
The thickness of the first hole transmission layer is 6nm in the inversion blue light quantum point membrane electro luminescent device of the present embodiment,
The material of first hole transmission layer is the mixture that HTL1 and HTL2 are formed, and wherein HTL1 be mCP, HTL2 DCDPA, mCP and
DCDPA mass ratioes are 1:1.The thickness of second hole transmission layer is 15nm, and the material of the second hole transmission layer is HTL2 and HTL3
The mixture of formation, wherein HTL2 are DCDPA, HTL3 V2O5, DCDPA and V2O5Mass ratio is 1:1.Remaining and the phase of embodiment 1
Together.
The specific preparation method for being inverted blue light quantum point membrane electro luminescent device is same as Example 1.
The HOMO energy levels of first hole transmission layer are 6.1eV, and the HOMO energy levels of the second hole transmission layer are 5.88eV.
Embodiment 8
The thickness of the first hole transmission layer is 8nm in the inversion blue light quantum point membrane electro luminescent device of the present embodiment,
The material of first hole transmission layer is the mixture that HTL1 and HTL2 are formed, and wherein HTL1 be mCP, HTL2 FPCC, mCP and
FPCC mass ratioes are 2:1.The thickness of second hole transmission layer is 30nm, and the material of the second hole transmission layer is HTL2 and HTL3 shapes
Into mixture, wherein HTL2 is FPCC, HTL3 V2O5, FPCC and V2O5Mass ratio is 2:3.Remaining is same as Example 1.
The specific preparation method for being inverted blue light quantum point membrane electro luminescent device is same as Example 1.
The HOMO energy levels of first hole transmission layer are 6.1eV, and the HOMO energy levels of the second hole transmission layer are 6.03eV.
Comparative example
The structure of the blue light quantum point membrane electro luminescent device of comparative example is substrate, negative electrode, electron transfer layer, blue light amount
Son point luminescent layer, hole transmission layer and anode.Cathode material is ITO, and electron transfer layer ZnO, luminescent layer is blue light quantum
Point, hole transmission layer are one layer of NPB and one layer of MoO3, anode Al.Luminance test is carried out to comparative example, as a result as shown in Figure 4.
From fig. 4, it can be seen that the brightness of comparative example is significantly less than the inversion blue light quantum point in embodiment 1, embodiment 2 and embodiment 3
Membrane electro luminescent device.
Embodiment described above only expresses the several embodiments of the present invention, and its description is more specific and detailed, but simultaneously
Therefore the limitation to the scope of the claims of the present invention can not be interpreted as.It should be pointed out that for one of ordinary skill in the art
For, without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to the guarantor of the present invention
Protect scope.Therefore, the protection domain of patent of the present invention should be determined by the appended claims.