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)。     

激基复合物和磷光超薄层相结合的高效率非掺杂白光有机发光二极管

将蓝光激基复合物mCP∶PO-T2T和磷光超薄层结合,分别制备了基于Ir（pq）₂acac（～0.5 nm）/mCP∶PO-T2T/Ir（pq）₂acac（～0.5 nm）结构的双色互补色和基于Ir（ppy）₃（～0.5 nm）/mCP∶PO-T2T/Ir（pq）₂acac （～0.5 nm）结构的三基色非掺杂白光有机发光二极管（White organic light emitting diodes, WOLED）,以探索超薄层在激基复合物中的应用。所制备的双色互补色WOLED,其最大电流效率、功率效率和外量子效率分别为46.1 cd/A、43.9 lm/W和22.2%,而三基色WOLED所实现的最大电流效率、功率效率和外量子效率分别为66.8 cd/A、63.5 lm/W和24.2%。研究分析表明,从高能的蓝光激基复合物发光层向两侧低能的红光和绿光磷光超薄层有效的能量传递是实现非掺杂WOLED高效率的原因。     

利用复合色彩转换膜实现白色有机电致发光

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在4,4′-Bis(carbazol-9-yl)biphenyl(CBP)主体中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和无机荧光粉钇铝石榴石(YAG)按一定的重量比均匀分散到-[CH3CH2COOCH3]n- (PMMA)中经涂敷、固化而成.通过与单纯有机或无机色彩转换膜的比较及调整复合转换膜本身的厚度和荧光颜料的掺杂比例来优化白光器件的发光光谱,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 V升至14 V时,器件的色坐标仅在(0.354,0.304)和(0.357,0.312)之间变化,其最高电流效率约为5.8 cd/A(4.35 mA/cm2),最高亮度为16 800 cd/m2(14 V).     

低效率滚降、发光颜色稳定的磷光白色有机电致发光器件

本文采用多发光层结构,制备了高亮度下具有高发光效率,同时在较宽亮度范围内发光颜色稳定的白色磷光有机电致发光器件(WOLED).在对双发光层结构磷光OLEDs的发光机制和载流子传输过程进行系统研究的基础上,将两种磷光OLEDs的发光层结构相结合,获得的多发光层结构磷光WOLED最大电流效率和外量子效率分别为34.6 cd/A和13.5%;当亮度为1000 cd/m^2时,其电流效率和外量子效率分别为33.9 cd/A和13.3%,外量子效率滚降仅为1.5%;亮度从1000 cd/m^2增至10000 cd/m^2的过程中,其CIE色度坐标从(0.342,0.403)变化至(0.326,0.392),变化量ΔCIE为(0.016,0.011).     

Non-doped-type white organic light-emitting diodes for lighting purpose

We demonstrate a non-doped white organic light-emitting diode (WOLED) in which the blue-, green- and red-emissions are generated from 4,4′-bis(2,2′-diphenylvinyl)-1,1′-biphenyl, tris(8-hydroxyquinoline)aluminum (Alq) and 4-(dicyanomethylene)-2-t-butyl-6-(1,1,7,7-tetramethyl-julolidyl 9-enyl)-4H-pyran (DCJTB), which is used as an ultrathin layer. The DCJTB ultrathin layer plays the chromaticity tuning role in optimizing the white spectral band by modulating the location of the DCJTB ultrathin layer in the green emissive Alq layer. The optimized WOLED gives the Commission Internationale de l’Eclairage-1931 xy coordinates of (0.319, 0.335), a color rendering index of 91.2 at 10 V, a maximum brightness of 21010 cd/m² at 12 V and a maximum current efficiency of 5.17 cd/A at 6.6 V. The electroluminescence mechanism of the white device is also discussed.     

采用复合母体的高效高显色指数白光有机发光二极管

采用复合母体技术制备了一种高效率高显色指数白光有机发光二极管。驱动电压在8 V到12 V变化时,器件的CIE-1931色坐标由(0.343 2, 0.339 7)变化到(0.324 3, 0.321 8),相关色温由5 035 K变化到5 915 K,其显色指数均保持在90以上。器件在14 V时达到最大亮度,为27 853 cd/m²,在7.5 V时达到最大效率为9.58 cd/A。实验中通过调节绿色和红色发光层的厚度来调节器件的发光光谱,通过敏化绿色和红色发光成分以实现电致发光效率的提高,器件的最大效率比没有采用敏化机制的参比器件提高了73.6%。     

不同主体双发光层白色有机电致发光器件的性能研究

制备了结构为ITO/NPB/CBP:TBPe:rubrene/BAlq:Ir(piq)₂(acac)/BAlq/Alq₃/Mg:Ag的白色磷光有机电致发光器件.利用两种不同的主体材料,即用双载流子传输型主体材料CBP掺杂荧光染料TBPe及rubrene作为蓝光和橙黄光发光层;用电子传输型主体材料BAlq掺杂磷光染料Ir(piq)₂(acac)作为红色发光层.以上双发光层夹于空穴传输层NPB与具有电子传输性的阻挡层BALq之间.讨论了如何控制 关键词： 有机电致发光 磷光染料 掺杂 白光     

光谱稳定的互补色双发光层高效混合白光OLED

利用两种颜色的发光层制备了光谱稳定的高效混合WOLED。其中蓝光发光层用14%质量分数的BNE掺杂在BePP₂中,橙光发光层用1%质量分数的Ir（bt）₂（acac）掺杂在49.5%质量分数的NPB和49.5%质量分数的BePP₂组成的混合主体中。在不利用任何光耦合技术的条件下,器件在亮度为100 cd/m²时,功率效率可以达到39 lm/W;当亮度提高到1 000 cd/m²时,效率仅发生轻微滚降至27.5 lm/W。器件的光谱稳定,亮度在1 000 cd/m²和10 000 cd/m²时,CIE坐标分别为（0.37,0.48）和（0.37,0.47）。良好的光谱稳定性归结于设计的双极性中间层平衡了其两侧激子的产生。     

高效、色度稳定的顶发射白光有机发光二极管

顶发射白光有机发光二极管(white organic light-emitting diodes,WOLEDs)因可与有源驱动电路结合实现大开口率和高分辨率,因而在白光照明和全彩显示中有着良好的应用前景．本文制备了红/蓝双磷光发光层的顶发射WOLEDs,通过在红光层与蓝光层间插入电子阻挡层tris(phenypyrazole)iridium(Ir(ppz)₃),降低了对红光掺杂浓度的要求,红光掺杂浓度的提高不仅降低了对制备工艺的要求,提高了工艺可重复性,而且改善了WOLEDs的效率与色度稳定性。分析了色度稳定的原因,优化了红光和蓝光磷光客体的掺杂浓度,制备出发光效率达到7.9 cd·A-1的顶发射WOLED,其色坐标位于暖白光区,在87～2 402 cd·m-2亮度范围内色度很稳定,仅变化(0.006,0.01)。     

White organic light-emitting diodes based on benzothiazole derivative

This paper describes the white organic light-emitting diodes (WOLEDs) made from a benzothiazole derivative, N-(4-(benzo[d]thiazol-2-yl)phenyl)-N-phenylnaphthalen-1-amine (BPNA). The bright yellowish-white emission was obtained from a non-doped triple-layer device: ITO/NPB (40 nm)/BPNA (50 nm)/Alq₃ (40 nm)/LiF/Al. The Commission Internationale de L’Eclairage (CIE) coordinates of the device were (0.24, 0.36) at 10 V. The maximum brightness of the device was 9225 cd/m² at 14.4 V. A current efficiency of 3.08 cd/A, a power efficiency of 1.21 lm/W and an external quantum efficiency of 1.18% at a driving current density of 20 mA/cm² were achieved. WOLED with a DCJTB-doped structure of ITO/TcTa/BPNA/BPNA: DCJTB (0.5%)/BPNA/BCP/Alq₃/LiF/Al was fabricated in comparison with the non-doped device. The device emitted bright white light with the CIE coordinates of (0.33, 0.29) at 10 V and a maximum luminance of 7723 cd/m² at 14.8 V.     

Simplified hybrid white organic light‐emitting diodes with efficiency/efficiency roll‐off/color rendering index/color‐stability trade‐off

A high‐performance hybrid white organic light‐emitting diode (WOLED) based on a simple structure has been developed. The resulting device exhibits a maximum total current efficiency and power efficiency of 35.7 cd/A and 30.6 lm/W, respectively. Even at a high luminance of 1000 cd/m², a current efficiency of 32.0 cd/A and a power efficiency of 19.4 lm/W are obtained, suggesting that the device exhibits a low efficiency roll‐off. Besides, the device shows excellent color‐stability during a wide range of luminance and a high color rendering index (CRI) of 83 is obtained. Moreover, the origin of the superior properties is explored comprehensively. Such achieved results demonstrate that high efficiency, low efficiency roll‐off, stable color and high CRI can be simultaneously realized in a simplified hybrid WOLEDs. (© 2014 WILEY‐VCH Verlag GmbH &Co. KGaA, Weinheim)     

发光层掺杂对红光OLED性能影响研究

制备高效率、高亮度的红光有机发光二极管是显示器实现全彩色的关键,对高性能的红光有机发光二极管器件研究具有十分重要的意义.本文主要研究了掺杂剂(DCJTB)浓度对红光有机发光二极管性能影响.实验采用真空热蒸镀的方法,选取结构为ITO／2-TNATA(20 nm)/NPB(30 nm)/AlQ(50 nm):(X%)DCJTB／AlQ(30 nm)／LiF(0.8 nm)／Al(100 nm)的红光器件,在高准确度膜厚控制仪的监控下,实现了有机薄膜功能材料的精确蒸镀.研究表明:红光掺杂剂掺杂浓度为(2.5~3.0)%时,在12 V电压下,可以得到发光亮度最高达到8 900 cd/m²,发光效率大于2.8 cd/A,且发光光谱波长为610~618 nm较为理想的红光有机发光二极管器件.     

Effects of hole injection layer thickness on the luminescent properties of white organic light-emitting diodes

This work investigates how the thickness of the hole injection layer (HIL) influences the luminescent characteristics of white organic light-emitting diodes (WOLED). Experimental results indicate that inserting a thin HIL (<200 Å) into a WOLED without an HIL reduces the brightness and clearly changes the chromaticity because the surface of the 4,4′,4″-tris{N,-(3-methylphenyl)-N-phenylamino}-triphenylamine) (m-MTDATA) film is extremely rough. In contrast, a dense film structure and the fine surface morphology of m-MTDATA of moderate thickness (350-650 Å) provides a uniform conducting path on which holes cross the indium tin oxide (ITO)/HIL interface, improving luminescent performance, associated with the relatively stable purity of the color of the emission, with Commission Internationale 1′Eclairage (CIE) coordinates of (x = 0.40, y = 0.40). However, inserting a thick HIL (>650 Å) reduces the luminescent performance and causes red-shift, because the holes and electrons in the effective emissive confinement region become less optimally balanced. Moreover, optimizing the device structure enables a bright WOLED with CIE coordinates of (x = 0.34, y = 0.33) to reach a luminance of 7685 cd/m² at a current density of 100 mA/cm², with a maximum luminous efficiency of 1.72 lm/W at 5.5 V.     

白色有机发光器件及其稳定性

报道了一种稳定的白色有机薄膜电致发光器件.电流效率6cd/A,在电流密度20mA/cm²驱动下,亮度为1026cd/m²;最高亮度21200cd/m²,色度(x=0.32,y=0.40).该器件具有较平稳的效率电流关系,即具有弱的电流荧光猝灭.初始亮度100cd/m²下,半亮度寿命达22245h.     

白色有机电致发光器件的制备及掺杂对其色度影响的研究

采用具有空穴阻挡层的器件,结构为ITO/2T-NATA(60nm)/NPB(50nm)/NPB(30nm):DCJTB/NPB(40nm)/BCP(10nm)/Alq(80nm)/LiF(1nm)/Al(20nm),结果表明,DCJTB的掺入量的微小改变对器件的色度影响很大,当DCJTB的掺入量为1.22%时,器件的颜色偏黄绿,其色坐标为（0.3363,0.3871）,峰值波长为561nm,起亮电压为10V。亮度为19000cd/m2。而当DCJTB的掺入量为0.94%时,器件的色度偏蓝,其色坐标为（0.2555,0.2741）峰值波长为449nm,亮度为15000cd/m2。当DCJTB的掺浓度为1.0时,器件接近白色。此时器件的起亮电压为7V,亮度也很好。     

新型高色纯度弱电流猝灭性蓝色有机发光器件

以ADN为基质,分别以不同掺杂剂制备了四种蓝色有机发光器件,器件结构为:CuPc(12 nm)/NPB(40 nm)/AND∶Dopant(50 nm)/Alq(12 nm)/LiF(4 nm)/Al。掺杂剂有:BCzVB(amino-substituted distyrylarylenederivatives)、TBPe、BCzVBi和DSA-ph四种。研究了最佳掺杂浓度以及器件的亮度、电流密度、效率和色坐标等电学特性和光学特性。其中掺杂BCzVB制备了色纯度高、低电流猝灭性的蓝色有机发光器件,色坐标达到x=0.146,y=0.162,最大亮度为11600 cd/m2(15 V),电流效率为2.8 cd/A,流明效率为1.79 lm/W;以ADN为基质,分别以TBPe、BCzVBi和DSA-ph为掺杂剂,制备了另外三种对比器件。器件ADN∶TBPe色坐标为x=0.162,y=0.222(蓝绿光),效率随电流的增加而降低很快;器件ADN∶BczVBi有较好的色纯度(色坐标:x=0.164,y=0.146),但电流效率较低:2.03 cd/A,效率随电流的增加降低幅度也较快。器件ADN∶DSA-ph效率较高为8 cd/A,效率随电流增加变化幅度不大,但色纯度比较差(x=0.153,y=0.306),适合于做白色有机发光器件。     

基于超薄发光层及双极性混合间隔层的白光有机发光器件研究

本文采用非掺杂超薄发光层及双极性混合间隔层结构,获得了高效、光谱稳定的白光有机发光器件.基于单载流子器件及单色蓝光有机发光器件的研究,确定了双极性混合间隔层的最佳比例;通过瞬态光致发光寿命研究,验证了不同发光材料之间的能量传递过程;得到的三波段和四波段白光有机发光器件的最高效率分别为52 cd/A (53.5 lm/W)和13.8 cd/A (13.6 lm/W),最高外量子效率分别为17.1%和11.2%.由于发光层不同颜色之间依次的能量传递结构,三波段白光有机发光器件的亮度从465到15950 cd/m~2时,色度坐标的变化?CIE仅为(0.005, 0.001);四波段白光有机发光器件的亮度从5077到14390 cd/m~2时,色度坐标的变化?CIE为(0.023, 0.012).     

Pure blue and white light electroluminescence in a multilayer organic light-emitting diode using a new blue emitter

We characterized the 6,12-bis{[N-（3,4-dimethylphenyl）-N-（2,4,5-trimethylphenyl）]amino} chrysene （BmPAC）, which has been proven to be a blue fluorescent emission with high EL efficiency. The blue fluorescent device exhibits good performance with an external quantum efficiency of 5.8% and current efficiency of 8.9 cd/A, respectively. Using BmPAC, we also demonstrate a hybrid phosphorescence/fluorescence white organic light-emitting device （WOLED） with high efficiency of 36.3 cd/A. In order to improve the relative intensity of blue light, we plus a blue light-emitting layer （BEML） in front of the orange light emitting layer （YEML） to take advantage of the excess singlet excitons. With the new emitting layer of BEML/YEML/BEML, we demonstrate the fluorescence/phosphorescence/fluorescence WOLED exhibits good performance with a current efficiency of 47 cd/A and an enhanced relative intensity of blue light.     

Small-molecular white organic light-emitting devices employing 2, 5, 2′, 5′-tetra (<Emphasis Type="Italic">p</Emphasis>-trifluoromethylstyryl)-biphenyl as single-emitting component

We demonstrate a promising single layer white light-emitting device using a dimeric trimeric phenylenvinylene derivative as emitting layer. The broad electroluminescence emission band is composed of blue component from singlet excited state of individual 2, 5, 2′, 5′-tetra (p-trifluoromethylstyryl)-biphenyl molecule and long-wavelength electromer emission in electroluminescence. Therefore, white-light emission can also be obtained with a typical three-layer structure of ITO/NPB (50 nm)/TFM-TSB (50 nm)/Alq₃ (30 nm)/LiF/Al device. The maximum brightness of this device is 809 cd/m² at 217 mA/cm² and 13 V, and the maximum luminous efficiency is 1.49 cd/A at 11 mA/cm² and 8 V.      

Fe3O4P型掺杂对有机电致发光器件性能的提高

将金属氧化物Fe3O4在空穴传输材料中进行P型掺杂并制作有机电致发光器件,使器件的开启电压由5 V降至2.5 V;20 mA/cm2电流密度下的功率效率由1.2 lm/W提高到2.0 lm/W;10 V下的亮度由1 680cd/m2提高到30 590 cd/m2.紫外-可见-红外吸收光谱及紫外光电子能谱的测试分析结果表...