空穴阻挡中间层的加入对WOLEDs光谱稳定性的提高

制备了多层结构合成的白光有机电致发光器件(WOLEDs),通过在发光层中加入一层空穴阻挡层TPBi来提高器件的光谱稳定性。当TPBi厚度为2.5 nm时,在电压由8 V升高到12 V的过程中,CIE色坐标的变化量为(0.031,0.006)。器件的电流效率为24.7 cd/A,外部量子效率最大为8.2%。相对于没有加入中间层的器件,8 V电压下的色坐标由(0.435,0.472)变为(0.333,0.439)。实验结果表明,在发光层中添加中间层可以改变器件发光的色坐标并提升光谱的稳定性。     

一种基于PFO掺杂的理想白光有机电致发光器件

研究了以芴类蓝光材料PFO为主体,通过掺杂MEH-PPV得到单层的白光有机电致发光器件,并从掺杂浓度对器件的光谱特性和色坐标稳定性的影响方面对其发光性能进行了分析研究。在MEH-PPV以2.5Wt%掺杂时,器件开启电压为3V,发光色坐标可达到标准白光等能点(0.33,0.33),器件发光色坐标在5～20V很宽的范围内随电压变化幅度很小,基本稳定在白光区。     

一种白光有机电致发光器件的制备

通过对器件结构的优化设计，提高了白光电致发光器件中蓝光成分的发光效率，从而得到了一种较为理想的有机白光电致发光器件。驱动电压为5V时，电流密度J=0．5mA／cm^2，器件的效率达到最大，流明效率为1．92 lm／W，此时器件的发光亮度接近20cd／m^2。色坐标为(x=O．317，y=0．328)。非常接近白光等能点．是色度很好的白光。并且在很大范围内，色度随器件的驱动电压或电流变化不大，当驱动电压变化至15V时。f=232mA／cm^2，色坐标变化至(x=0．338，y=O．353)。在电压为22V时，器件的亮度达到最大，为17 000cd／m^2。此外器件结构相对简单。器件制备的可重复性得到很大程度的改善。     

高效率和色稳定性的双超薄发光层的黄光有机电致发光器件

主要对rubrene黄光发光材料制作0.1nm厚度的超薄发光层的有机电致发光器件作了研究,并配合BCP空穴阻挡层探讨了对器件效率和色坐标稳定性的影响。双超薄rubrene发光层配合BCP空穴阻挡层的有机电致发光器件的性能得到了很好的改善,外加电压6V时,器件电流效率为6.35cd.A-1;外加电压10V时,器件发光亮度达到了7068cd.m-2。另外,在较大的外加电压驱动范围内,器件的色坐标一直保持在(0.49,0.49)。增加的发光效率和良好的色坐标稳定性主要是取决于空穴与电子的注入与输运平衡以及激子在超薄rubrene发光层中稳定性的复合平衡。     

利用磷光敏化改善聚合物白光OLED性能

基于新型聚合物白光材料PF-DTFO制备了一种聚合物白光发光二极管(PWOLED),通过在聚合物发光层中掺杂蓝光磷光染料FIrpic,利用磷光敏化发光原理,改善器件电致发光性能。在敏化PWOLED中,掺杂的FIrpic染料作为给体将产生的三重态能量传递给白光聚合物的长波发射基团,进一步提高了长波基团的发光强度,改善了白光光谱,使基色更平衡并且光谱更稳定。驱动电压从8 V增加到16 V时,器件电致发光光谱基本不变,色坐标仅从(0.33,0.38)移动至(0.32,0.38)。敏化后的器件发光效率相对于未掺杂器件提高了38%。     

发光层位置对白光有机发光二极管的影响

同一种主体材料MADN中混掺不同的掺杂剂,分别制备了两种白光有机发光二极管,测试并研究了它们的发光效率、寿命、发光亮度、电致发光光谱以及色平衡度。结果表明,两种白光器件的性能受发光层的顺序和厚度的影响显著。发光层顺序由阳极到阴极方向为橙/蓝的器件的稳定性要优于发光层顺序为蓝/橙的器件,这是由于橙光发光层中的rubrene对空穴的陷进作用可捕获穿越橙光发光层中的空穴,从而有效地调控了器件内部的电子、空穴浓度的平衡。通过对器件的优化,制得了色坐标为(0.3201,0.3459)的接近标准白光的有机电致发光器件。     

微腔有机电致发光白光器件设计及制作

用一种宽谱带材料Alq₃作为发光层,设计并制作白色有机微腔电致发光器件。器件结构:Glass/DBR/ITO(194 nm)/NPB(93 nm) /Alq₃(49 nm)/MgAg(150 nm),得到了位于蓝(488 nm)和红(612 nm)光区域的两个腔发射模式,并通过颜色匹配获得了白光。器件的最大电致发光亮度16 435 cd/m²,最大效率11.1 cd/A,典型亮度值100 cd/m²时的发光效率、电压、电流密度分别是9 cd/A,6 V和1.2 mA/cm²,CIE 色坐标为(0.32, 0.34)。在不同的驱动电压下,器件的发光颜色稳定,说明了微腔是一种制作白光OLED的有效结构。     

联苯乙烯类蓝色发光材料DPVBi的合成及发光性质研究

合成了联苯乙烯类蓝色有机发光材料DPVBi[4，4′-二(2，2-二苯乙烯基)-1，l′-联苯]，用^1H-NMR，IR，元素分析等方法对其结构进行了表征。以DPVBi作发光层制备了电致发光器件，其结构为：ITO／CuPc／NPB／DPVBi/Alq3／LiF／Al，研究了器件的电致发光性质。器件最高亮度达4 373cd/cm^2，最大流明效率为1．24 lm／w，在20mA／cm^2电流密度驱动下的亮度为434cd／cm^2，CIE色坐标为x=0．15，y=0．16，器件的蓝色发光具有较好的色纯度。重点对器件发光色度的稳定性进行了研究，结果表明，随电流密度(4～4 000mA／cm^2)的变化，器件色度具有很好的稳定性。     

基于NPB的蓝色有机电致发光器件的制备和表征

在常规的双层绿色有机电致发光器件氧化铟锡(ITO)/N,N′-bis-(1-naphthyl)-N,N′-biphenyl-1,1′-biphenyl-4,4′-diamine(NPB)/8-hydroxyquinolinealuminum(Alq3)/Mg∶Ag的基础上,通过选择适当的空穴阻挡层材料,制备得到以NPB为发光层的蓝色发光器件,其结构为ITO/NPB/bathocuproine(BCP)/Alq3/Mg∶Ag,其最大亮度和最大流明效率分别达到2900cd/m2和0.55lm/W。电致发光谱峰位于445nm,CIE色坐标为(x=0.16,y=0.09),且二者都不随外加电压而变化;利用各功能层的能级结构,对不同结构的器件性能差异进行了分析。     

Nondoped-type White Organic Light-Emitting Diode Using Star-Shaped Hexafluorenylbenzene as an Energy Transfer Layer

采用真空蒸镀的方法以星形六苯芴类新材料1,2,3,4,5,6-hexakis(9,9-diethyl-9H-fluoren-2-yl)benzene(HKEthFLYPh)作为能量传输层制备了indium-tin-oxide(ITO)/N,N′-bis-(1-naphthyl)-N,N′-diphenyl-(1,1'-biphenyl)-4,4′-diamine(NPB)/HKEthFLYPh/5,6,11,12-tetraphenylnaphtacene(rubrene)/tris(8-hydroxyquinoline) aluminum (Alq3)/Mg:Ag的白色有机电致发光器件. NPB和Alq3分别作为蓝色发光层和电子传输层,NPB和Alq3之间的超薄Rubrene层 作为黄色发光层. 结果表明,超薄rubrene层改善了白光器件的色纯度与稳定性,器件的光谱及色坐标几乎不随驱动电压的变化而改变.当rubrene层厚度为0.3 nm时,器件的Commissions Internationale De L′Eclairage (CIE)色坐标为(0.32,0.33). 驱动电压为18 V时,器件的最大亮度为4816 cd/m2.     

Effect of different spacers for performance enhancement on white organic light-emitting devices based on double emissive layers with homogeneous p-/n-type host

White organic light-emitting devices (WOLEDs) based on phosphorescent blue and yellow emitters were fabricated, while p-type di-(4-(N,N-ditolyl-amino)-phenyl)cyclohexane (TAPC) and n-type 2,2′,2″-(1,3,5-benzenetriyl)-tris(1-phenyl-1-H-benzimidazole) (TPBi) were separately utilized as a homogeneous host for both blue and yellow emissive layers (EMLs). Then, various spacers were inserted between the two EMLs for performance characterization. The results showed that for the TAPC-host devices, a device using 4,7-diphenyl-1,10-phenanthroline (Bphen) as the spacer had a maximum current efficiency (CE) of 11.3 cd/A, while stable white light emission with Commission Internationale del’Eclairage (CIE) coordinates of (0.394, 0.435) at a bias of 5 V was observed. Similarly, among the TPBi-host devices, a device using 4,4′-bis(carbazol-9-yl)biphenyl (CBP) as the spacer exhibited a maximum CE of 18.1 cd/A, accompanied by negligible color variation with the CIE coordinates of (0.284,0.333) at 5 V. For the double-EML devices, the improved device efficiency and color stability by introducing proper spacer was attributed to broadened recombination region and efficient energy transfer between the EMLs.     

基于新型空穴传输材料的有机电致发光器件的研究

利用真空蒸镀方法以N2,N7-二(间甲苯胺基)-N2,N7-二苯基-2,7-二胺基-9,9-二甲基芴[2,7-bis(pmethoxyphenyl-m'-tolylamino)9,9-dimethylfluorene,TPF-OMe]为空穴传输层、8-羟基喹啉铝[tris(8-hydroxyquinolinato)aluminum,Alq3)]作为发光层及电子传输层,制备了双层器件.与制作的典型双层结构N,N'-二苯基-N,N'-二(3-甲基苯基)-1,1'-联苯-4,4'-二胺[N,N'-biphenyl-N,N'-bis-(3-methylphenyl)-1,1'-biphenyl-4,4'diamine,TPD/Alq3]器件相比,电流密度较大,发光效率低,发光谱峰为516 nm,色坐标为(0.30,0.53),为Alq3材料发光.以TPF-OMe为发光层兼空穴传输层,2,9-二甲基-4,7-二苯基-1,10-菲罗啉(2,9-dimethyl-4,7-diphenyl-l,10-phenanthroline,bathocuproine或BCP)为空穴阻挡层,Alq3为电子传输层,制作三层有机电致发光器件.结果表明,光谱峰值在414 nm,色坐标为(0.20,0.24),为蓝色光,是TPF-OMe材料本身发光,器件在15 V电压下电流密度为1137 mA/cm2,亮度为900 cd/m2,在3 V偏压下有最大流明效率,为0.11 lm/W.基于TPF-OMe材料的器件的击穿温度比基于TPD材料的器件高近20℃,原因可能在于TPF-OMe材料比TPD材料高19℃的玻璃化转变温度(Tg).     

High-efficiency organic light-emitting diodes (OLEDs) with a mixed layer structure

Improved performance of organic light-emitting diodes (OLEDs) as obtained by a mixed layer was investigated. The OLEDs with a mixed layer which were composed of N,N′-diphenyl-N,N′-bis(1-napthyl-phenyl)-1,1′-biphenyl-4,4′-diamine (NPB), tris-(8-hydroxyquinolato) aluminum (Alq₃) and 4-(dicyanomethylene)-2-t-butyl-6-(1,1,7,7-tetramethyljulolidyl-9-enyl)-4H-pyran (DCJTB) showed the highest brightness and efficiency, which reached 19048 cd/m² at 17 V and 4.3 cd/A at 10 mA/cm², respectively. The turn-on voltage of the device is 2.6 V. Its Commission Internationale del’Eclairage (CIE) coordinate is (0.497, 0.456) at 17 V, and the CIE coordinates of the device are largely insensitive to the driving voltages, which depicts stabilized yellow color.     

Lighting object-based nondoped-type white organic light-emitting diode with N,N'-diphenyl-N,N'-bis(1-naphthyl)-(1,1'-benzidine)-4,4'-diamine as the chromaticity-tuning layer

We demonstrate a nondoped white organic light-emitting diode in which the blue, green, and red emissions are generated from 4,4(')-bis(2,2(')-diphenylvinyl)-1,1(')-biphenyl, tris(8-hydroxyquinoline)aluminum, and a submonolayer of 4-(dicyanomethylene)-2-t-butyl-6-(1,1,7,7- tetramethyl-julolidyl 9-enyl)-4H-pyran layers, respectively. A thin layer of N,N(')-diphenyl-N,N(')-bis(1-naphthyl)(1,1(')-benzidine)-4,4(')-diamine (NPB), which differed from the traditional hole-transporting layer, was introduced into the device. The thickness of this thin NPB layer was changed to tune the chromaticity and optimize the white color quality. The white device with a 3 nm chromaticity-tuning NPB layer gives the Commission Internationale de l'Eclairage-1931 xy coordinate of (0.327, 0.336), a color rendering index of 90.2, a maximum luminance of 19,096 cd/m(2), and a maximum current efficiency of 4.12 cd/A. The electroluminescence mechanism of the white device was also discussed.     

利用色彩转换法制备高色稳定性的柔性白色有机电致发光器件

本文利用色转换方法,将高效的蓝色柔性有机电致发光器件(flexible organic light emitting devices, FOLEDs)与色转换材料(color conversion material, CCM)相结合,制备了柔性白色有机电致发光器件(white organic light emitting devices, WOLEDs).首先利用2, 3, 5, 6-Tetrafluoro-7, 7, 8, 8-tetracyano-quinodimethane (F4-TCNQ)和4, 4', 4"-tris-(N-3-methylphenyl-N-phenylamino) tripheny-lamine (m-MTDATA)组成的多量子阱(multiple quantum well, MQW)结构作为空穴注入层(hole injection layer, HIL)结合新型蓝光材料N⁶, N⁶, N¹², N¹²-tetrap-tolylchrysene-6, 12-diamine (NCA)制备出高效的蓝光FOLEDs,然后将其与色转换材料4-(dicyanomethylene)-2-tert-butyl-6-(1,1,7,7-tetramethyljulolidyl-9-enyl)-4H-pyran (DCJTB) 结合,通过沉积不同厚度的CCM来优化白光器件的发光光谱,获得了色稳定性较高的白光. 实验结果表明:在驱动电压为7 V, DCJTB的厚度为120 nm时得到较接近白光等能点的色坐标 (0.33, 0.27),且当驱动电压由6 V升至11 V 时,器件的色坐标变化仅为(±0.02, ±0.02), 表现出高色稳定性.     

新型双色有机电致磷光器件

所研究的有机电致磷光发光器件(OLED)选用了一种新型金属铱的化合物Ir(C6)₂(acac),这种金属化合物由配位体香豆素C6和乙酰丙酮(acac)与金属铱化合形成。Ir(C6)₂(acac)可同时作为电子传输材料和发光掺杂剂。比较香豆素C6和Ir(C6)₂(acac)固体材料的光致发光谱,可见Ir(C6)₂(acac)明显抑制了有机电致发光材料分子与分子之间的发光猝灭效应。采用ITO/TPD(N,N′-diphenyl-N,N′-bis(3-methyl-phenyl)-1,1′biphenyl-4,4′diamine)/Ir(C6)₂(acac)/BAlq(bis(2-methyl-8-quinolinolato-N₁,O₈)-(1,1′-biphenyl-4-olato)aluminum)/Alq₃aluminum/Liq(8-hydroxyquinolinelithium)/Al结构,可得到CIE(Commission Interationaled′Eclairage)值为x=0.43;y=0.40的橙红色发光器件,最高亮度可达3390cd/m₂,最大电流效率为1.3cd/A。采用同样的器件结构以Ir(C6)₂(acac)掺杂Alq₃主体得到绿色发光器件,发光色的CIE坐标值为x=0.29;y=0.58,最高亮度可达8832cd/m₂,最大电流效率为5.6cd/A。器件的发光机理研究表明Ir(C6)₂(acac)的非掺杂器件发光以Ir(C6)₂(acac)的三线态磷光为主,器件发光为橙色;在Alq₃中的单掺杂器件以Alq₃和Ir(C6)₂(acac)的荧光为主,同时有小比例Ir(C6)₂(acac)的三线态磷光成分存在,器件总体发光为绿色。     

The characterization of electroplex generated from the interface between 2-(4-trifluoromethyl-2-hydroxyphenyl)benzothiazole] zinc and N,N′-diphenyl-N,N′- bis(1-naphthyl)-(1,1′-biphenyl)-4,4′-diamine

The electroplex between (2-(4-trifluoromethyl-2-hydroxyphenyl)benzothiazole) zinc [Zn(4-TfmBTZ)₂] as an electron-acceptor and N,N′-diphenyl-N,N′-bis(1-naphthyl)-(1,1′-biphenyl)-4,4′-diamine (NPB) as an electron-donor was characterized by bilayer, blend, and multilayer quantum-well (MQW) device, respectively. The blend composition and quantum-well number are effective parameters for tuning electroluminescence color. White light with high color purity and color rendering index (CRI) was observed from these devices based on Zn(4-TfmBTZ)₂/NPB. Moreover, the blend and MQW devices all exhibit high operation stability, hence excellent color stability. For the device with 5 mol% NPB in blend layer, its Commission International Del’Eclairage (CIE) coordinate region is x=0.28–0.31, y=0.33–0.35 and CRI is 83.3–91.2 at 5–9 V. For MQW structure device with NPB of 60 nm thickness, its CIE coordinate region is x=0.29–0.32, y=0.31–0.34 and CRI=87.9–92.5 at 10–15 V. Such high color stability and purity and CRI, being close to ideal white light, are of current important for white OLED.     

纯化9,10-二萘蒽对OLED器件光电性能的影响

合成了高稳定性蓝光主体材料9,10-二萘蒽(ADN),研究材料纯化对合成材料光电性能的影响。为进一步分析材料经升华提纯对有机电致发光器件性能的影响,以提纯前后ADN为发光层,以NPB为空穴传输层,分别制作双层器件Ⅰ(提纯前)和器件Ⅱ(提纯后),器件结构为ITO(100nm)/NPB(40nm)/ADN(30nm)/Alq₃(20nm)/LiF(1nm)/Al(100nm),结果表明提纯后材料PL(Photolum inescence)光谱蓝移了2nm,半峰全宽54.2nm,与提纯前一致;杂质影响载流子注入效率和迁移率,对器件光电性能有显著影响,纯化前后器件最大电流效率由1.5cd/A上升至2.5cd/A;器件Ⅱ色纯度有较大提高,CIE色坐标由器件Ⅰ(0.15,0.10)移至(0.15,0.06)。实验结果表明材料提纯是优化器件性能的有效手段之一。     

色彩转换膜对白色有机电致发光光谱的影响

利用蓝色有机发光二极管激发荧光色彩转换膜的方法,制备了一种新型的白色有机电致发光器件。蓝色有机发光二极管的发光层采用4,4’-Bis(carbazol-9-yl)biphenyl(CBP)主体掺杂高效蓝色荧光染料N-(4-((E)-2-(6-((E)-4-(diphenylamino)styryl)naphthalen-2-yl)vinyl)phenyl)-N-phenylbenzenamine (N-BDAVBi)来制备。有机/无机复合色彩转换膜是将有机荧光颜料VQ-D25和无机荧光粉掺铈钇铝石榴石(YAG∶Ce3+)按一定的重量比均匀分散到-[CH₃CH₂COOCH₃]_n-(PMMA)中来制备。获得了色稳定性较高的白色有机电致发光器件。当驱动电压由6升至14 V时,器件光谱非常稳定且CIE色坐标仅从(0.354,0.304)变化到(0.357,0.312),其最高电流效率约为5.8 cd·A-1(4.35 mA·cm-2),最高亮度为16 800 cd·m-2(14 V)。     

利用激基复合物发光的有机白光电致发光器件

以NPB为空穴传输材料,(dppy)BF为发光层,Alq为电子传输层和色度调节层,制备了有机白光电致发光器件.该器件的白光发射是来自于(dppy)BF与NPB的固界表面形成的激基复合物发光,以及NPB与(dppy)BF发射的蓝光.该白光器件的色度稳定,在电压10～25V的变化范围内,色坐标变化由(0.29,0.33)到(0.31,0.35).器件在4V开启,12V电压下亮度和效率分别为200cd/m²和0.45lm/W.