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1.
以1,4-二(2-氰基-2-苯乙烯基)-2,5-二苯基苯(CNDPDSB)为发光层, N,N'-[3-萘基]-N,N'-二苯基[1,1'-二苯基]-4,4'-二胺(NPB)为空穴传输层, 8-羟基喹啉铝(Alq)为电子传输层, 制备了一种色度稳定的有机电致白光器件. 该器件的白光发射是由CNDPDSB与NPB界面形成的激基复合物发出的红光以及NPB与CNDPDSB发射的蓝光混合而成. 该白光器件的光谱稳定, 在工作电压(6~13 V)内, 色坐标由(0.33, 0.34)变化到(0.31, 0.37). 器件在6 V电压下开启, 10 V电压下的亮度和效率分别为1200 cd/m2和0.2 cd/A.  相似文献   

2.
使用中位-四(1-苯基吡唑-4-基)卟啉(TPPyPH2)掺杂空穴传输材料N,N′-二苯基-N,N′-双(4-甲苯基)-1,1′-二苯基-4,4′-二胺(TPD)制备了红色有机电致发光器件.因为TPD的发射光谱与TPPyPH2的吸收光谱具有更大的光谱重叠,为了得到更为有效的从主体材料TPD向红光染料TPPyPH2的能量传递,我们使用TPD代替传统的8-羟基喹啉铝(Alq3)作为主体发光材料.器件在680nm处具有纯的红光发射峰;通过使用Alq3电子传输层以及使用Alq3共掺杂发光层的方法,使器件的发光性能得到了改善,结构为ITO/Alq3+TPPyPH2+TPD(50nm)/Alq3(30nm)/Al的器件的最大发光亮度为177cd/m2.  相似文献   

3.
稀土配合物Tb(p-MBA)3phen的有机电致发光   总被引:2,自引:0,他引:2  
合成了一种新型的稀土铽配合物材料Tb(p-MBA)3phen,把它作为发光材料应用于有机电致发光中.把铽配合物掺杂在导电聚合物PVK中采用旋涂法制得发光层,并利用AlQ作为电子传输层制作了单层、双层有机电致发光器件:器件1(ITO/PVK):Tb(p-MBA)3phen/Al;器件2(ITO/PVK):Tb(p-MBA)3phen/AlQ/LiF/Al,得到了纯正的、明亮的Tb3 离子的绿光发射,4个特征峰分别对应着能级5D4到7Fj(j=6,5,4,3)的跃迁,而PVK的发光完全被抑制.研究了两种器件的电致发光性能,并通过选择AlQ的厚度得到了发光性能较好的器件,其最大亮度在20 V时达到152 cd·m-2.  相似文献   

4.
铽配合物TbY(o-MBA)6(phen)2与PVK掺杂体系的发光性质研究   总被引:2,自引:2,他引:0  
合成了一种新型的稀土铽配合物材料TbY(o-MBA)6(phen)2,把它作为发光材料应用于有机电致发光中.把铽配合物掺杂在导电聚合物PVK中采用旋涂法制得发光层,并利用AlQ作为电子传输层制作了多种结构的电致发光器件 器件A,ITO/PVK∶TbY (o-MBA)6(phen)2/LiF/Al;器件B,ITO/PVK∶TbY (o-MBA)6(phen)2/AlQ/LiF/Al;器件C,ITO/PVK∶TbY (o-MBA)6(phen)2/BCP/AlQ/LiF/Al.对器件A和B得到了纯正的、明亮的Tb3+离子的绿光发射,4个特征峰分别对应着能级5D4到7Fj(j=6,5,4,3)的跃迁,而PVK的发光完全被抑制.研究了掺杂体系的光致发光性能和电致发光性能,认为在光致发光中,铽的发光主要来源于PVK到稀土配合物的Frster能量传递.而在电致发光中,铽的发光主要来源于稀土配合物直接捕获载流子形成激子复合发光.并通过优化选择得到了发光性能较好的器件B,其最大亮度在14 V时达到213 cd·m-2.  相似文献   

5.
基于四苯基乙烯衍生物设计合成了两种蓝光材料TPE-4Br和TPE-3Br,并将其作为有机发光二极管(OLED)器件的发光层,研究发现其可与合适的邻层(空穴传输层/电子传输层)形成电致激基复合物。利用材料的本征激子发光及其电致激基复合物发光,可以得到理想的白光电致发光。将TPE-4Br和TPE-3Br掺杂于mCP中作为发光层,以TAPC和TmPyPB分别作为空穴传输层和电子传输层分别制备器件A和器件B,所得器件在操作电压为9 V时的色坐标分别为(0.32,0.33)和(0.31,0.34)。其中器件B的最大亮度和最大电流效率分别为364.66 cd?m~(-2)与0.79 cd?A~(-1)。  相似文献   

6.
铽配合物[Tb(m-MBA)3phen]2·2H2O的有机电致发光   总被引:5,自引:1,他引:4  
将稀土铽配合物[Tb(m MBA)3phen]2·2H2O作为发光材料应用于有机电致发光。把铽配合物掺杂在PVK中经甩膜制得发光层,并分别用AlQ和PBD作为电子传输层制作了两类有机电致发光器件。器件1:ITO PVK:[Tb(m MBA)3phen]2·2H2O PBD LiF Al;器件2:ITO PVK:[Tb(m MBA)3phen]2·2H2O AlQ LiF Al,研究了两种器件的电致发光性能,并通过选择AlQ的厚度得到了发光性能较好的用AlQ作为电子传输材料的器件,其最大亮度在20V时达到140cd·m-2。  相似文献   

7.
合成了溶解性优良、带有可聚合链段的8-羟基喹啉金属螯合物(Alq3和Znq2)单体,在室温下通过紫外光照射,形成热力学性能稳定、8-羟基喹啉金属螯合物含量高(50(wt)%以上)的交联聚合物.这种材料可以解决使用旋涂的方法制备器件带来的底层溶解的问题,从而实现大面积、多层电致发光器件的制备,还可以通过光刻手段实现器件涂层图案化,是器件实现全彩色、超像素方法之一.其光致发光和电致发光性质证明这种材料本身以及其加工性能在有机/高分子平面显示技术领域有一定应用价值.  相似文献   

8.
设计合成了含噻吩基的新型配体(E)-2-[2-(3-噻吩基)乙烯基]-8-羟基喹啉(4)及相应的锌配合物5,产物结构经核磁共振、红外光谱和元素分析进行表征.利用X射线单晶衍射仪测定了中间体(E)-2-[2-(3-噻吩基)乙烯基]-8-乙酰氧基喹啉(3)和配体4的单晶结构,结果表明中间体3晶体分子间并无明显的氢键作用,分子间呈交错堆叠;配体4分子之间由硫氢氧键弱作用相互排列形成网状结构.通过核磁滴定及紫外和荧光滴定模拟了配体4在溶液中与金属锌的配位过程.固体荧光寿命研究结果表明,配合物5的荧光寿命为18.8 ms.通过电致发光器件研究发现,配合物5作为发光层具有良好的电致发光性能,同时具有较好的电子传输能力.  相似文献   

9.
设计合成了含噻吩基的新型配体(E)-2-[2-(3-噻吩基)乙烯基]-8-羟基喹啉(4)及相应的锌配合物5,产物结构经核磁共振、红外光谱和元素分析进行表征. 利用X射线单晶衍射仪测定了中间体(E)-2-[2-(3-噻吩基)乙烯基]-8-乙酰氧基喹啉(3)和配体4的单晶结构,结果表明中间体3晶体分子间并无明显的氢键作用,分子间呈交错堆叠;配体4分子之间由硫氢氧键弱作用相互排列形成网状结构. 通过核磁滴定及紫外和荧光滴定模拟了配体4在溶液中与金属锌的配位过程. 固体荧光寿命研究结果表明,配合物5的荧光寿命为18.8 ms. 通过电致发光器件研究发现,配合物5作为发光层具有良好的电致发光性能,同时具有较好的电子传输能力.  相似文献   

10.
设计合成了三种新的8-羟基喹啉席夫碱衍生物4-(8-羟基喹啉-5-亚胺甲基)-7-甲氧基苯并吡喃-2-酮(3a),4-(8-羟基喹啉-5-亚胺甲基)-7-己氧基苯并吡喃-2-酮(3b)和4-(8-羟基喹啉-5-亚胺甲基)-7-十八烷氧基苯并吡喃-2-酮(3c)及其铝、锌配合物,产物结构经1H(13C)NMR,MS,HRMS,IR和元素分析表征,研究了它们的荧光发光性能.  相似文献   

11.
合成了四氮杂大环化合物,Tetraazamacrocycliccompound,6,12,19,25 tetramethyl 7,11:20,24 dinitrilo dibenzo[b,m][1,4,12,15]tetra azacyclo docosine(TMCD).TMCD作为电子传送材料,探讨了它在有机电致发光器件中的应用.制作了结构为:玻璃基板/ITO阳极/NPD/Alq/TMCD/LiF/Al阴极的器件.评价的结果显示:该有机电致发光器件在538nm的绿色发光来源于Alq层.它的最大外部量子效率为0.84%,视感效率为1.30lm/W.最先提出了四氮杂大环化合物做为电子传送材料,可应用于电致发光领域.  相似文献   

12.
Previously we characterized the active layer in polymer‐based solar cells containing Poly(3‐hexylthiophene) with the electron acceptor Phenyl‐C61‐butyric acid methyl ester (PCBM) to find a thin, pure polymer layer at the air interface just after spin coating. In this study, we find that when the aluminum back electrode was thermally evaporated onto the active layer, at high enough rate, craters were found in the pure polymer layer. This was determined by dissolving the aluminum and characterizing the active layer with an atomic force microscope. Poor device performance was noted under this condition. However, if the aluminum was evaporated at a slower rate, resulting in a flat active layer surface and no crater formation, the efficiency more than doubled. A similar result is found if lithium fluoride (LiF) is deposited before aluminum evaporation and no craters were found even for the higher aluminum evaporation rate. So, it appears that LiF acts as a momentum shield to crater formation allowing superior device performance. If the active layer is annealed before deposition of the back electrode then, regardless of deposition rate, similar device performance is found. Again, in our previous study, it was found that annealing the active layer forced PCBM to the air interface which apparently also acts as a momentum shield. Annealing the device after aluminum deposition produces poorer performance than annealing before deposition. However, these devices have a better fill factor. Examining the active layer shows that it undergoes a buckling transition due to differences in the aluminum and active layers' thermal expansivities which reduces overall contact with the electrodes. However, whatever contact is made, is superior, accounting for the improved fill factor. If the buckling instability could be avoided then this processing procedure may be used in the future to manufacture even better devices than with any of the other annealing procedures. © 2011 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2011  相似文献   

13.
The mechanism of charge transfer among tris(8-hydroxyquinolinate)aluminum (Alq3) molecules in the electron-transporting layer (ETL) under amorphous conditions was theoretically investigated using both quantum mechanical/molecular mechanical (QM/MM) calculations and molecular dynamics (MD) simulations. The rate constant of the electron transfer was estimated for the equilibrated structure taken from the QM/MM MD simulations, based on the hopping model and Marcus theory. It was found that the coordination of a (LiF)4 cluster in ETL drastically lowers the energy of the lowest unoccupied molecular orbital in the Alq3 molecule. The small rate constant, namely the slow charge mobility, in ETL is believed to be causally related to the low-lying delocalized unoccupied molecular orbital of Alq3 coordinated by the (LiF)4 cluster. The results suggest that their interaction has a considerable influence on efficiency and is attributed in part to ETL degradation in organic light-emitting diodes.  相似文献   

14.
IntroductionInorganiclightemittingdiode(OLED) ,somemetalswithlowworkfunction ,suchasalloyofmag nesiumandsilver(Mg∶Ag) [1] andaluminium[2 ] ,areusedastheelectroninjectioncathodes .InMg∶Agal loysilverisusedtoprotectmagnesiumfromthereac tionofmagnesiumwithoxygenand…  相似文献   

15.
High-efficiency polymer light-emitting diodes were fabricated by inserting a layer of nonionic neutral surfactant between the electroluminescent (EL) layer and the high-work-function aluminum cathode via spin coating. It was found that both the poly(ethylene glycol)- and poly(propylene glycol)-based surfactants as well as their copolymers can all demonstrate similar performance enhancement. Device performances comparable to or even better than those of the control devices using calcium as the cathode have been achieved for both poly(p-phenylene)-based and polyfluorene-based conjugated polymers with orange-red, green, and blue emission colors. It is possible that when both surfactant and aluminum are used as the cathode, the abundant hole injection through a hole-transporting layer and hole pile-up at the inner side of the EL/surfactant interface might cause an effective electric field to induce the realignment of the dipole moment of those polar surfactant molecules, thus lowering the barrier for electron injection. In addition, the coordination between the aluminum and oxygen atoms on the surfactant might cause n-type doping in the areas near surfactant in the EL polymer layer that causes the enhancement of electron injection.  相似文献   

16.
Counterion exchange in cationic conjugated polyelectrolytes provides for a straightforward method to modulate the performance of these materials as the electron transport (injection) layer (ETL) in organic light emitting diodes. The bromide counterions of [(9,9-bis(6'-N,N,N-trimethylammonium)-hexyl)fluorene]bromide (PF-Br) can be easily replaced with trifluoromethylsulfonate (PF-CF3SO3), tetrakis(imidazolyl)borate (PF-BIm4) or tetrakis(3,5-trifluoromethylphenyl)borate (PF-BArF4) by a procedure that involves precipitation and washing. The performance of LEDs using MEH-PPV as the emissive layer, Al as the cathode, and the conjugated polyelectrolytes as the ETL varies in the order: PF-BIm4 > PF-CF3SO3 > PF-Br > PF-BArF4. In the case of PF-BIm4, the luminous efficiencies of the devices are similar to those of devices using Ba as the cathode. Thus, by properly choosing the counterion one can use higher work function metals that are more stable than lower work function metals without a substantial barrier to electron injection.  相似文献   

17.
A soluble and thermally stable arylamine oligomer containing difluorenyl groups was prepared and applied to organic light‐emitting devices (OLEDs) as a hole injection layer. The oligomer layer was doped with a Lewis acid and formed by spin coating from the dichloroethane solution. The OLED with a structure of indium tin oxide (ITO)/Lewis‐acid‐doped arylamine oligomer/N,N′‐dinaphthyl‐N,N′‐diphenyl bendizine (α‐NPD)/tris(8‐quinolinolato)aluminum(III) (Alq3)/LiF/Al showed lower drive voltages and higher power efficiencies, compared with the devices without the hole injection oligomer layer. Copyright © 2005 John Wiley & Sons, Ltd.  相似文献   

18.
我们制备研究了基于结构为氧化铟锡(ITO)/C_(60)(1.2nm):MoO_3(0.4nm)/1,3,5-三(1-苯基-1H-苯并咪唑-2-基)苯(TPBi):三(2-苯基吡啶)铱[Ir(ppy)_3](33%,90 nm)/LiF (0.7 nm)/Al (120 nm)的高效绿色磷光单层有机发光二极管(OLED)。分别将C_(60),MoO_3与C_(60):MoO_3混合物作为空穴注入层(HIL)作为对比。TPBi在发光层中起着主体以及电子传输材料的双重作用。在使用电子传输型主体的单层OLED中,空穴注入层性质对于调节电子/空穴注入以获得电荷载流子传输平衡起重要作用。因此,适当调节空穴注入层是实现高效单层OLED的关键因素。由于MoO_3较大的电子亲和能(6.37 eV)会诱导电子从C_(60)的最高占据分子轨道(HOMO)能级转移至MoO_3,从而形成C_(60)阳离子,并使得Mo元素的价态从+6降至+5,C_(60):MoO_3混合就可以较好的调节空穴注入性质。最终实现最大电流效率为35.88 cd·A~(-1)的单层有机发光器件。  相似文献   

19.
Zhang  Kai  Liu  ShengJian  Guan  Xing  Duan  ChunHui  Zhang  Jie  Zhong  ChengMei  Wang  Lei  Huang  Fei  Cao  Yong 《中国科学:化学(英文版)》2012,55(5):765-770
A series of alkali metal salts doped pluronic block copolymer F127 were used as electron injection/transport layers (ETLs) for polymer light-emitting diodes with poly[2-(4-(3′,7′-dimethyloctyloxy)-phenyl)-p-phenylenevinylene] (P-PPV) as the emission layer. It was found that the electron transport capability of F127 can be effectively enhanced by doping with alkali metal salts. By using Li2CO3 (15%) doped F127 as ETL, the resulting device exhibited improved performance with a maximum luminous efficiency (LE) of 13.59 cd/A and a maximum brightness of 5529 cd/m2, while the device with undoped F127 as ETL only showed a maximum LE of 8.78 cd/A and a maximum brightness of 2952 cd/m2. The effects of the doping concentration, cations and anions of the alkali metal salts on the performance of the resulting devices were investigated. It was found that most of the alkali metal salt dopants can dramatically enhance the electron transport capability of F127 ETL and the performance of the resulting devices was greatly improved.  相似文献   

20.
用新的路径成功地合成了N,N -四(间联苯基)-4,4 -联苯二胺(m TBPBz).以m TBPBz作为正孔传送材料,探讨了它在有机电致发光器件中的应用.制作了结构为玻璃基板/ITO阳极(130nm)/m TBPBz(40nm)/Alq(60nm)/LiF(0.5nm)/Al阴极(100nm)的器件.结果显示:该有机电致发光器件的绿色发光来源于Alq层.10V时,它的最大亮度为9486cd/m2.证明了m TBPBz具有正孔传送性能,可作为电致发光材料使用.  相似文献   

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