噻吩基联苯乙烯蓝色发光材料的合成与发光性能

设计并合成了新型含噻吩基团的联苯乙烯类蓝色有机电致发光材料4,4′-双(2-苯基-2-(2-噻吩)乙烯基)-1,1′-联苯(TPVBi),通过红外、核磁共振、元素分析对其结构进行了表征。利用紫外可见吸收光谱、荧光光谱和循环伏安法等研究了其HOMO、LUMO能级及发光性能。TPVBi溶液的荧光发射峰值波长为451nm,薄膜的荧光光谱最大发射波长为464nm。循环伏安测得其氧化峰电位为1.227V。TPVBi的HOMO能级为-5.55eV,LUMO能级为-2.67eV。以TPVBi作为发光层制作了结构为ITO/CuPc(10nm)/NPB(30nm)/TPVBi(35nm)/TPBi(35nm)/Al(100nm)的有机发光二极管器件,并研究了该器件的电致发光性能。该器件在电压为19.5V时,达到最大亮度1782.3cd/m2,在电流密度为15.69mA/cm2时,最大电流效率为1.73cd/A;器件的发光CIE色坐标为x=0.25,y=0.40。     

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.     

单向发射的透明红光有机发光器件

采用双层银膜夹入有机物薄膜形成的复合阳极结构,结合具有高透射率的银锗银复合阴极制备了单向发射的半透明红光有机电致发光器件。由于共振隧穿效应使得复合电极对不同波段可见光具有选择性透过的特点,制备的器件表现出单向发射特征。在相同偏压下,器件在非发射方向的亮度始终在发射方向的3%以下。器件在9.5 V电压下达到最大亮度,在发射方向和非发射方向上的亮度分别为15 550 cd/m2和387cd/m2。在7.5 V电压下,器件达到其最高电流效率7.01 cd/A。在该偏压下,其发射与非发射方向亮度分别为4 968 cd/m2和151.7 cd/m2。器件光谱的稳定性很好,随着电压的增加,没有发生明显的变化。此外,随着视角的变化,器件的光谱也无明显的角度特性。当视角从0°增加到60°时,其色坐标仅改变(-0.002,0.001),这是由于银锗银复合阴极具有较高的透射率和低的反射率。     

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。     

基于Ag/Ge/Ag阳极的as

通过在Ag层中引入一层Ge薄膜, 获得了具有低反射率和高反射相移的Ag/Ge/Ag复合阳极, 并制备了基于该阳极的蓝光顶发射有机电致发光器件.阳极高的反射相移使得器件在有机层厚度为100 nm时获得了顶发射蓝光发射, 且阳极较低的反射率减弱了器件内的微腔效应, 使得其电致发光光谱在不同视角下具有良好的稳定性.当Ge的厚度为20 nm时, 器件性能表现最为优良, 最高亮度和最大电流效率分别可达3 612 cd/m²和5.4 cd/A, 且色坐标在视角从0°变化到60°时仅移动了(0.007, 0.006).     

新有机材料的电致发光的研究

采用新合成的有机材料－硅烷衍生物作为发光物质制备了发蓝、绿光的薄膜电致发光器件。其结构为glass/ITO/PVK SiH/Alq/Mg:Ag。分别测量了SCS－SiH,聚乙烯咔唑（PVK）薄膜的光致发光光谱以及器件的电致发光光谱。其中SCS－SiH薄膜的光致发光谱峰位置在496nm,有机器件的电致发光光谱的峰值为500nm。随着驱动电压的增加发光谱峰蓝移,其变化范围为25nm。在电流密度为89mA/cm^2下器件的发光亮度可达810cd/m^2。     

DPVBi为激子阻挡层的亚单层有机发光器件的制备与光电性能研究

结合亚单层的有机发光技术,制备了一种多层有机电致发光器件,其结构为ITO/m-MTDATA (50nm)/ C545T (0.05nm) /DPVBi (d nm)/DCM2(0.05nm)/ Alq (60nm) /LiF(1nm) /Al.荧光材料C545T和DCM2以亚单层的方式插入DPVBi前后,通过改变DPVBi的厚度,观察器件性能的变化,当DPVBi为4 nm时,器件在4V电压下最大发光效率是4.19 cd/A,在13 V电压下最大亮度是17050 cd/m2.分析对比了四种不同厚度器件的电流密度-电压曲线、亮度-电压曲线、电致发光光谱图和色坐标,发现选择合适厚度的激子阻挡层,可以得到效率较高的器件.激子阻挡层一般选择载流子传输能力较差,HOMO能级较低的材料.所得结果对有机发光器件尤其是采用亚单层有机白光器件的设计和制作有一定的指导作用.     

双空穴注入的绿色磷光有机电致发光器件

制作了一种新型绿色磷光有机电致发光二极管。器件结构为ITO/HAT-CN(x nm)/MoO3(30 nm)/NPB(40 nm)/TCTA(10 nm)/CPB∶GIr1(30 nm,14%)/BCP(10 nm)/Alq3(25 nm)/LiF(1 nm)/Al(100 nm),其中X=0,8,10,12,14,15 nm。电流密度-电压-亮度特性表明该结构有利于降低驱动电压和增加器件亮度。当HAT-CN厚度为12 nm时,器件的最高亮度可以达到32 480 cd/m2,起亮电压为3.5 V左右,发光效率为24.2cd/A。所设计的空穴型器件证明该器件结构具有很好的空穴注入和传输特性。     

铱金属配合物磷光材料掺杂聚合物体系的电致发光特性

通过对一种新型贵金属铱的配合物磷光材料(pbi)₂Ir(acac)与咔唑共聚物进行物理掺杂, 制备了结构为indium-tin oxide(ITO)/poly(N-vinylcarbazole)(PVK): (pbi)₂Ir(acac)(x)/2,9-dimethyl-4,7-diphenyl-1,10-phenan throline(BCP)(20nm)/8-Hydroxyquinoline aluminum(Alq₃)(10nm)/Mg:Ag的聚合物电致磷光器件,研究了磷光聚合物掺杂体系在低掺杂浓度时(0.1%和0.5%(质量百分数,全文同))的光致发光(PL)和电致发光(EL)特性. 结果表明, 该掺杂体系的PL光谱和EL光谱中均同时存在主体材料PVK与磷光客体(pbi)₂Ir(acac)的发光光谱, 但主客体的发射强度不同,推测该掺杂体系在电致发光条件下, 同时存在主体材料到客体的不完全的能量传递和载流子直接俘获过程. 磷光掺杂浓度为0.1%的器件在19V电压下实现了白光发射, 色坐标为(0.32, 0.38), 掺杂浓度为0.5%的器件在20.6V电压下的最大发光亮度为11827 cd·m^-2, 而在13.4V电压下的最大流明效率为4.13 cd·A^-1. 关键词： 有机电致发光器件 铱配合物磷光 聚合物掺杂     

两种宽谱带蓝光发射材料的制备、表征及光学特性

合成了两种以钙为中心金属离子的有机电致发光材料2-(2-羟基苯基)苯并噻唑钙Ca(BTZ)₂和2-(2-羟基苯基苯并噻唑)-(1,10-邻菲罗啉)合钙Ca(BTZ)₂phen。通过红外光谱、紫外-可见光吸收光谱、循环伏安曲线、原子力显微镜以及光致发光光谱表征了材料的结构、光学带隙、能带结构、成膜性以及光学性能。实验结果表明,在DMSO溶液中,Ca(BTZ)₂的紫外吸收峰主要为290,330,422nm;Ca(BTZ)₂phen的紫外吸收峰主要为292,330,428nm。Ca(BTZ)₂的荧光发射峰为458nm和500nm,色坐标为x=0.2176,y=0.3223;Ca(BTZ)₂phen的荧光发射峰主要为465nm和514nm,色坐标为x=0.2418,y=0.3817。利用真空热蒸镀法可以得到均匀致密的Ca(BTZ)₂phen的薄膜,其粗糙度为1.56。Ca(BTZ)₂薄膜也有望通过旋涂制备。实验发现Ca(BTZ)₂与Ca(BTZ)₂phen的荧光光谱几乎覆盖整个可见光区域,为宽谱带发光材料,有望设计成合理的器件结构实现白光发射。     

Synthesis and electroluminescent properties of a carbozole-functionalized europium(III) complex

A novel europium(III) complex, tris(dibenzoylmethanate){1-[9-hexyl-9H-carbazole]-2-(2-pyridyl)-benzimidazole}europium(III) [Eu(DBM)₃(CAR-PyBM)] functionalized by a carbozole fragment, was synthesized and used as emitting material in organic electroluminescent (EL) devices. Compared with the device based on an unfunctional Eu(III) complex, [Eu(DBM)₃HPyBM] (HPyBM=2-(2-pyridyl)benzimidazole), the EL performances of the device using [Eu(DBM)₃(CAR-PyBM)] as an emitter was significantly enhanced due to the improvement of hole-transporting ability. The maximum efficiency and luminance of red emission achieved from the device with the configuration of ITO/N,N′-diphenyl-N,N′-bis(3-methylphenyl)-1,1′-biphenyl-4,4′diamine (TPD, 50 nm)/ [Eu(DBM)₃(CAR-PyBM)] (30 nm)/1,3,5-tirs-(N-phenylbenzimidazol-2-yl)benzene (TPBI, 20 nm)/LiF (1.5 nm)/Al were 4.2 cd/A and 200 cd/m², respectively.     

High-Efficiency Blue Electroluminescence Based on Coumarin Derivative 3-(4-(anthracen-10-yl)phenyl)-benzo[5,6]coumarin

The electroluminescent (EL) properties of a new coumarin derivative, 3-(4-(anthracen-10-yl)phenyl)-benzo[5,6]coumarin (APBC), were investigated. The results show that the EL devices comprised of vacuum vapor-deposited films using the derivative as dopant exhibited blue emission that is identical to the photoluminescence of the thin film. The electroluminescence device of ITO/2-TNATA (5?nm)/NPB (40?nm)/CBP : APBC (1.0?wt%, 30?nm)/PBD (30?nm)/LiF (1?nm)/Al (100?nm) gives a maximum luminous efficiency of 2.3?cd/A at the current density of 20?mA/cm², and maximum luminance of 5169?cd/m² at 16?V. The external quantum efficiency of the device is 1.85?%.     

Non-doped red to yellow organic light-emitting diodes with an ultrathin 4-(dicyanomethylene)-2-t-butyl-6(1,1,7,7-tetramethyljulolidyl-9-enyl)-4H-pyran (DCJTB) layer

In this letter, bright non-doped red to yellow organic light-emitting diodes (OLEDs) with ultrathin 4-(dicyanomethylene)-2-t-butyl-6(1,1,7,7-tetramethyljulolidyl-9-enyl)-4H-pyran (DCJTB) layer as the emitting layer were fabricated. It was investigated that the effect of the ultrathin DCJTB layer on the electroluminescent (EL) performance of OLEDs. The DCJTB layer was incorporated at different positions in the conventional tris(8-quinolinolato)-aluminum (AlQ)-based devices (ITO/NPB/AlQ/LiF/Al). The emission of DCJTB was dominative in the EL spectra of the devices, in which the position of 0.3 nm DCJTB layer was less than 10 nm from the NPB/AlQ interface. The EL peak emission of DCJTB shifted to blue side as DCJTB position moved gradually from AlQ to NPB layer. The highest brightness of the device with 0.3 nm DCJTB layer inserted into NPB reached 16,200 cd/m² at 15 V, with the CIE coordinates of (0.522, 0.439).     

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。     

Photoluminescence and electroluminescence of a novel green-yellow emitting material-5,6-Bis-[4-(naphthalene-1-yl-phenyl-amino)-phenyl]-pyrazine-2,3-dicarbonitrile

A new compound with intramolecular charge transfer (ICT) property—5,6-Bis-[4-(naphthalene-1-yl-phenyl-amino)-phenyl]-pyrazine-2,3-dicarbonitrile(BNPPDC) was synthesized. The new compound was strongly fluorescent in non-polar and moderately polar solvents, as well as in thin solid film. The absorption and emission maxima shifted to longer wavelength with increasing solvent polarity. The fluorescence quantum yield also increased with increasing solvent polarity from non-polar to moderately polar solvents, then decreased with further increase of solvent polarity. This indicates both “positive” and “negative” solvatokinetic effects co-existed. Using this material as hole-transporting emitter and host emitter, we fabricated two electroluminescent (EL) devices with structures of A (ITO/BNPPDC (45 nm)/1,3,5-tris(N-phenylbenzimidazol-2-yl)benzene (TPBI) (45 nm)/Mg:Ag (200 nm) and B (ITO/N,N′-diphenyl-N,N′-bis-(3-methylphenyl) (1,1′-diphenyl)4,4′-diamine (TPD) (50 nm)/BNPPDC (20 nm)/1,3,5-tris(N-phenylbenzimidazol-2-yl)benzene (TPBI) (45 nm)/Mg:Ag (200 nm). The devices showed green-yellow EL emission with good efficiency and high brightness. For example, the device A exhibited a high brightness of 17400 cd/m² at a driving voltage of 11 V and a very low turn-on voltage (2.9 V), as well as a maximum luminous efficiency 3.61 cd/A. The device B showed a similar performance with a high brightness of 12650 cd/m² at a driving voltage of 13 V and a maximum luminous efficiency 3.62 cd/A. In addition, the EL devices using BNPPDC as a host and 4-(dicyanomethylene)-2-t-butyl-6-(1,1,7,7-tetramethyljulolidyl-9-enyl)-4H-pyran (DCJTB) as a dopant (configuration: ITO/TPD (60 nm)/BNPPDC:DCJTB (2%) (30 nm)/TPBI (35 nm)/Mg:Ag (200 nm)) showed a good performance with a brightness of 150 cd/m² at 4.5 V, a maximum brightness of 12600 cd/m² at 11.5 V, and a maximum luminous efficiency of 3.30 cd/A.     

全湿法制备聚合物白光器件

使用全溶液法制备聚合物白光器件,通过引入修饰层并改变各层薄膜厚度来优化器件性能。针对ITO 阴极功函数较高的问题,引入功函数较低的蓝光聚芴衍生物：聚[9,9-二辛基芴-9,9-双（N,N-二甲基胺丙基）芴]（PFN）,有效地降低了阴极的复合功函数。同时PFN也是电子注入材料和发光材料。为降低器件的启动电压,引入Cs₂CO₃作为修饰层,同时也提高了电子传输能力。使用MEH-PPV作为橙红光材料。使用二次溶剂掺杂获得的高导PEDOT：PSS聚合物并通过滴膜的方法制备阳极取代了传统的金属电极真空镀膜法,从而使器件制备简单、快捷。最终得到了湿法制作的聚合物白光器件的光谱范围为400~800 nm,涵盖了整个可见光区域。器件的启亮电压为4 V,亮度为1 500 cd/m²,电流效率为0.55 cd/A。     

陶瓷基片薄膜电致发光器件

本文报道了一种新颖的陶瓷基片薄膜电致发光器件(CSTFEL),使用高介电常数的陶瓷片作器件的基片,同时又作为器件中的绝缘层,陶瓷片表面无需抛光处理,直接制作发光器件,工艺简单,用市电50Hz,220V驱动,亮度大于30cd/m2,寿命大于10000小时.     

发光层厚度变化的高效红色有机电致磷光器件

以铱配合物红色磷光体为掺杂剂，制备了基于TPBi材料的红色电致磷光器件,其结构为ITO/CuPc/NPB/TPBi:Btp₂Ir(acac)/ TPBi/Alq/LiF/Al.取得了在x=0.62，y=0.35的色度下，效率最高达2.43cd/A；电流密度为20mA/cm²时，亮度431cd/m²；电流密度为400mA/cm²时，亮度4798 cd/m²的结果.讨论了不同的发光层厚度影响器件色度和 关键词： 三线态 红光掺杂剂 有机电致磷光 T-T湮没     

White organic electroluminescence from fluorescent bis (2-(2-hydroxyphenyl) benzoxazolate)zinc doped with phosphorescent material

Efficient white electroluminescence has been obtained by using an electroluminescent layer comprising of a blue fluorescent bis (2-(2-hydroxyphenyl) benzoxazolate)zinc [Zn(hpb)₂] doped with red phosphorescent bis (2-(2′-benzothienyl) pyridinato-N,C^3′)iridium(acetylacetonate) [Ir(btp)₂acac] molecules. The color coordinates of the white emission spectrum was controlled by optimizing the concentration of red dopant in the blue fluorescent emissive layer. Organic light-emitting diodes were fabricated in the configuration ITO/α-NPD/Zn(hpb)₂:0.01 wt%Ir(btp)₂acac/BCP/Alq₃/LiF/Al. The J-V-L characteristic of the device shows a turn on voltage of 5 V. The electroluminescence (EL) spectra of the device cover a wide range of visible region of the electromagnetic spectrum with three peaks around 450, 485 and 610 nm. A maximum white luminance of 3500 cd/m² with CIE coordinates of (x, y=0.34, 0.27) at 15 V has been achieved. The maximum current efficiency and power efficiency of the device was 5.2 cd/A and 1.43 lm/W respectively at 11.5 V.     

LiF超薄层引起的OLEDs发光光谱展宽

将LiF插入到发光层Alq₃中,制备了有机电致发光器件(OLED),其器件的结构为:ITO/NPB (45 nm)/Alq₃ (x nm)/LiF (0.3 nm)/Alq₃ /Al(150 nm)。发现器件的电致发光谱(Electroluminescence spectra, EL)有非常明显的展宽现象,这为白光器件的制备提供了一条简单的途径。通过对比LiF在Alq₃中不同厚度处的发光谱,发现在x=10时谱线展宽最显著,器件最大亮度在22 V时达到8 260 cd/m²,最大效率可达 4.83 cd/A,并对其光谱展宽的机理及器件特性进行了分析。