基于N-对甲氧苯基咔唑-2-乙烯基-8-羟基喹啉锌的白色和黄色有机电致发光器件的性能

通过研究新型荧光染料N-对甲氧苯基咔唑-2-乙烯基-8-羟基喹啉锌(MoBCzHQZn)的电致发光(EL)特性, 发现MoBCzHQZn具有较强的发光特性和空穴传输特性, 利用此特性制备了非掺杂型的有机电致白光器件和掺杂型的有机电致黄光器件. 白光器件的结构为ITO/2T-NATA(20 nm)/MoBCzHQZn(25 nm)/NPBX(13 nm)/BCP(8nm)/Alq3(34 nm)/LiF(0.5 nm)/Al, 器件在15 V电压下实现了白光发射, 色坐标为(0.3719, 0.3275), 最大发光亮度为3414 cd·m-2, 在14 V 电压下的最大发光效率为1.69 cd·A-1、黄光器件的结构为ITO/2T-NATA(20 nm)/CBP:6%Ir(ppy)3:10%MoBCzHQZn(25 nm)/TPBi:6%Ir(ppy)3(47 nm)/LiF(0.5 nm)/Al, 器件在15 V电压下实现了黄绿光发射, 色坐标为(0.3590, 0.5787), 最大发光亮度为11073 cd·m-2, 在9 V电压下的最大发光效率为2.51 cd·A-1.     

含咔唑基团的新颖Re(Ⅰ)配合物的合成、表征和光电性质的研究

合成了一种含咔唑基团的新颖配合物Re(CO)_3CLL[L=1-乙基-2-(N-乙基－咔唑 并-4-)咪唑并[4.5-f]1,10-邻菲咯啉],通过元素分析、红外光谱、紫外光谱、~1H NMR、荧光光谱和循环伏安学对其进行了表征，制备了基于真空沉积膜的双层电致 发光器件：ITO/TPD (30 nm)/Re(Co)_3CLL (10 nm)/Mg_(0.9)Ag_(0.1) (110 nm) /Ag(60 nm)该器件启动电压为5V，在电压为9V时达到最大亮度113cd/m~2，发出桔 红色的光。     

含咔唑基团的新颖Re(Ⅰ)配合物的合成、表征和光电性质的研究

合成了一种含咔唑基团的新颖配合物Re(CO)_3CLL[L=1-乙基-2-(N-乙基－咔唑 并-4-)咪唑并[4.5-f]1,10-邻菲咯啉],通过元素分析、红外光谱、紫外光谱、~1H NMR、荧光光谱和循环伏安学对其进行了表征，制备了基于真空沉积膜的双层电致 发光器件：ITO/TPD (30 nm)/Re(Co)_3CLL (10 nm)/Mg_(0.9)Ag_(0.1) (110 nm) /Ag(60 nm)该器件启动电压为5V，在电压为9V时达到最大亮度113cd/m~2，发出桔 红色的光。     

超薄层在白色有机电致发光器件中的应用

以DCJTB为掺杂剂, 以BCP为空穴阻挡层, 研究了两种结构的有机电致发光器件ITO/NPB/BCP/Alq3:DCJTB/Alq3/Al(结构A)和ITO/NPB/BCP/Alq3/Alq3:DCJTB/Alq3/Al(结构B)的电致发光光谱. 实验结果显示, 在结构A器件的电致发光光谱中, 绿光的相对发光强度较弱,增加Alq3层的厚度对绿光的相对发光强度的影响也很小; 而在结构B器件的电致发光光谱中, BCP层与掺杂层(Alq3:DCJTB)之间的Alq3薄层对绿光的相对发光强度影响显著, 用很薄的Alq3层就可以得到强的绿光发射. 进一步改变器件结构, 利用有机超薄层就可以得到稳定的白光器件ITO/NPB(50 nm)/BCP(3 nm)/Alq3(3 nm)/Alq3:DCJTB(1%(w))(5 nm)/Alq3(7 nm)/Al. 随着电压的增加(14-18 V), 该器件的色坐标基本保持在(0.33, 0.37)处不动; 在432 mA·cm-2的电流密度下, 该器件的发光亮度可达11521 cd·m-2.     

一种新型红色三线态喹喔啉铱(Ⅲ)配合物的合成及发光性质

利用2,3-二苯基喹喔啉和水合三氯化铱(IrCl₃?H₂O)反应, 合成了一种新型喹喔啉铱的配合物[Ir(DPQ)₂(acac)], 通过元素分析, ¹H NMR和HRMS对配合物结构进行了表征, 结果显示得到的是目标化合物. 利用紫外光谱和荧光光谱对配合物的吸收光谱和光致发光光谱进行了研究. 利用该材料作为磷光材料制备了结构为[ITO/NPB(30 nm)/NPB∶7% Ir(DPQ)₂(acac)(25 nm)/PBD (10 nm)/Alq₃ (30 nm)/Mg∶Ag (10∶1)(120 nm)/Ag(10 nm)] 的电致发光器件, 研究了其电致发光光谱. 结果表明, 配合物[Ir(DPQ)₂(acac)]在476和625 nm处存在单重态¹MLCT(金属到配体的电荷跃迁)和三重态³MLCT的吸收峰; 发光光谱结果显示, 在660 nm处有较强的金属配合物三重态的磷光发射; 电致发光光谱显示, 该器件的启动电压是4.25 V, 器件的最大亮度为4910 cd/m², 外量子效率为5.14%, 器件的流明效率为1.12 lm/W, 是一种新型红色磷光材料.     

2-对联苯-8-羟基喹啉锌的合成及其应用于新型白光OLED

合成了一种全新的有机发光材料2-对联苯-8-羟基喹啉锌(Zn[2-(p-biPh)-8-Q-O]₂), 通过¹H NMR, UV-Vis等对配合物的结构进行表征. 利用该材料制备了新型白光有机电致发光器件(OLED), 其结构为: ITO/NPB (N,N'-双(1-萘基)-N,N'-二苯基-1,1'-二苯基-4,4'-二胺)/BCP (2,9-二甲基-4,7-二苯基-1,10-菲咯啉)/Zn[2-(p-biPh)-8-Q-O]₂/Al. 通过调节空穴阻挡层BCP的厚度, 实现了NPB(蓝光发射)和Zn[2-(p-biPh)-8-Q-O]₂(黄光发射)作为器件双发光层的有效复合, 并研究了其发光机理. 当BCP层的厚度为2.0 nm时, 获得了稳定的白色发光; 该器件在6 V电压下启亮, 20 V电压时最大发光亮度达到130 cd/m², 电流效率为0.224 cd/A.     

基于Zn(Q-Ph)2与DCJTB非掺杂型OLED的制备及其电致发光性能研究

合成了有机发光材料2-苯基-8-羟基喹啉锌Zn(Q-Ph)2, 通过1H NMR, UV-Vis及MS等手段对配合物进行了结构表征. 利用该材料与高效的红光染料DCJTB复合制备出全新结构的非掺杂型OLED器件, 其结构为ITO/NPB/DCJTB/Zn(Q-Ph)2/AlQ3/Al. 将DCJTB超薄层的厚度调节到0—2.0 nm范围内, OLED器件的发光色调经历了黄光、红光和橙光的转变, 并且探讨了DCJTB厚度对OLED发光机理以及发光复合区域的影响. 当DCJTB的厚度为0.5 nm时, 获得了稳定的红光发射, 该器件在5.5 V电压下启亮, 在25 V外加电压下发光亮度达到420 cd/m2, 对应的电流密度为250 mA/cm2.     

新型黄色磷光吡嗪铱(Ⅲ)配合物的合成及发光性质

利用2,3-二苯基吡嗪与水合三氯化铱反应合成了一种新型吡嗪铱的配合物[Ir(dphp)₂(acac)],通过元素分析,¹HNMR和MS对配合物结构进行了表征,并研究了配合物的吸收光谱和光致发光光谱.利用该材料作为磷光染料制备了结构为[ITO/NPB(30nm)/NPB;8%[Ir(dphp)₂(acac)](25nm)/PBD(10nm)/Alq₃(30nm)/Mg;Ag(质量比9;1)(130nm)的电致发光器件,研究了其电致发光光谱.结果表明,该配合物在393和528nm处存在单重态¹MLCT(金属到配体的电荷跃迁)和三重态³MLCT的吸收峰;荧光光谱结果显示,在588nm处有较强的金属配合物三重态的磷光发射;电致发光光谱显示,该器件的启动电压是3.25V,器件的最大亮度为11478cd/m²,外量子效率为13.85%,器件的流明效率为15.54lm/W,是一种新型的高效率黄色磷光材料.     

高效磷光铱配合物的合成及电致发光性能研究

合成了一种含苯并噻唑结构配体的环金属化铱配合物(ffbi)₂Ir(acac)，(其中ffbi为1-(4-氟苄基)-2-(4-氟苯基)苯并咪唑，acac为乙酰丙酮)，并以其作为发光体, 制备了有机电致发光器件。结果表明该配合物具有强磷光发光特性，器件发绿色光。其中结构为TCTA(40 nm)/CBP∶Ir(6.3%，30 nm)/BCP(10 nm)/Alq(40 nm)的电致发光器件在12 V电压下最大发光亮度达41 499 cd·m^-2，在8 V电压下，最大外量子效率达5.7%。     

稀土配合物的光致和电致发光性能的研究

合成了一种新型的稀土配合物Tb(acac)3dad, 讨论了其光致发光的性质 . 以其为发射层制备了结构为ITO/TPD (50 nm)/Tb(acac)3dad (75 nm)/PBD (50 nm)/Al (400 nm) 的电致发光器件, 该器件的启动电压为7 V, 18 V时得到了最大亮度为62 cd·m -2, 发现器件的电致发光光谱与配合物Tb(acac)3dad的光致发光光谱有明显不同.     

酚基嘧啶铍(Ⅱ)配合物的合成及光电性质

采用Suzuki偶联方法合成了新型有机螯合配体酚基嘧啶(HPP), 利用HPP进一步合成了酚基嘧啶铍配合物Be(PP)₂. 采用核磁共振(¹H NMR)和红外(IR)光谱等方法对其结构进行了表征, 并通过测定紫外-可见(UV-Vis)和光致发光(PL)光谱对Be(PP)₂的光学性质进行了研究. 结果表明, 配合物在460 nm处有最大发射. 以Be(PP)₂为电子传输层和发光层制备了结构为氧化铟锡(ITO)/N,N'-二(萘-2-基)-N,N'-二(苯基)联苯-4,4'-二胺(NPB)(45 nm)/Be(PP)₂(60 nm)/Al(300 nm)的双层模型器件, 获得了最大亮度为103 cd/m²的近白光发射, 色坐标为(0.37, 0.39), 光功率效率为0.13 lm/W.     

A Red‐Emissive Sextuple Hydrogen‐Bonding Self‐Assembly Molecular Duplex Bearing Perylene Diimide Fluorophores for Warm‐White Organic Light‐Emitting Diode Application

A novel sextuple hydrogen‐bonding (HB) self‐assembly molecular duplex bearing red‐emitting perylene diimide (PDI) fluorophores, namely PDIHB , was synthesized, and its molecular structure was confirmed by ¹H NMR, ¹³C NMR, TOF‐MS and 2D NMR. Compared with the small molecular reference compound PDI , PDIHB shows one time enhanced fluorescence efficiency in solid state (4.1% vs. 2.1%). More importantly, the presence of bulky HB oligoamide strands in PDIHB could trigger effective spatial separation between guest and host fluorophores in thin solid film state, hence inefficient energy transfer occurs between the blue‐emitting host 2TPhNIHB and red guest PDIHB in the 2 wt% guest/host blending film. As a result, a solution‐processed organic light‐emitting diode (OLED) with quite simple device structure of ITO/PEDOT:PSS (40 nm)/PVK (40 nm)/ PDIHB (2 wt%): 2TPhNIHB (50 nm)/LiF (0.8 nm)/Al (100 nm) could emit bias‐independent warm‐white electroluminescence with stable Commission Internationale de L'Eclairage coordinates of (0.42, 0.33), and the maximum brightness and current efficiency of this device are 260 cd·m^?2 and 0.49 cd·A^?1, respectively. All these results indicated that HB self‐assembly supramolecular fluorophores could act as prospective materials for white OLED application.     

高效白色磷光有机电致发光器件

采用真空热蒸镀方法以4,4'-bis (carbazol-9-yl) biphenyl (CBP)为主体材料、以bis[2-(4-tert-butylphenyl) benzothiazolato-N,^C2] iridium (acetylacetonate) [(t-bt)₂Ir(acac)]磷光染料为掺杂剂构成黄色发光层, 制备了高效白光的有机电致发光器件(OLEDs). OLEDs的器件结构为indiumtin oxide (ITO)/N,N’-bis-(1-naphthyl)-N,N’-biphenyl-1,1’-biphenyl-4,4’-diamine (NPB)/CBP: (t-bt)₂Ir (acac)/NPB/2,9-dimethyl-4,7-diphenyl-1,10-phenanthroline (BCP)/8-hydroxy quinoline aluminum(Alq₃)/Mg:Ag, 从ITO阳极开始的第一层NPB为空穴传输层, 第二层超薄的NPB为蓝色发光层, BCP为空穴阻挡层和激子阻挡层, Alq₃为电子传输层. 结果表明, 器件电压在3 V启亮, 在16.5 V时, 器件的最高亮度达到15460 cd·m^-2; 在4 V时, 器件达到最大流明效率为7.5 lm·W^-1, 器件启亮后所发出的白光光谱在低电压时随电压变化有稍微的移动, 但是都在白光范围内变化. 在电压达到8 V后Commission Internationale I’Eclairage(国际照明委员会) (CIE)色坐标为(0.33, 0.32), 并且光谱及色坐标稳定, 不随电压变化而改变, 与最佳的白光坐标(0.33, 0.33)几乎重合. 同时, 从机理上解释了光谱移动和效率衰减的原因, 并探讨了载流子陷阱和能量传递的关系.     

Vapor-phase processable novel nonplanar donor-acceptor quateraryls for blue OLEDs(#)

A novel series of thermally stable blue light emitting quateraryls with a piperidine donor and a nitrile acceptor was prepared from a ketene- S, S-acetal under mild conditions without using an organometal catalyst. The performance of a blue quateraryl 6e was investigated by fabricating a multilayer OLED with a configuration of ITO/PEDOT:PSS (40 nm)/quateraryl (60 nm)/BCP (6 nm)/Alq(3) (20 nm)/LiF (0.5 nm)/Al (200 nm), which exhibited blue emission with a low turn on voltage of 4 V at a brightness of 0.22 cd/m(2).     

Synthesis,structures, and electroluminescence properties of a 1D zinc(II) coordination polymer containing both dicyanamide and pyrazinamide ligands

A 1D coordination polymer, {[Zn(μ_1,5-dca)₂(PZA)₂](PZA)₂}_n (1), has been synthesized and characterized by single-crystal X-ray crystallography. The coordination modes of the dicyanamide (dca) and the pyrazinamide (PZA) were inferred by IR spectroscopy. The complex was applied to organic electroluminescent (EL) devices as the emitting materials. The electroluminescent device of ITO/NPB (40 nm)/Zn polymer: CBP (30 nm) (30 nm)/BCP (15 nm)/Alq (30 nm)/LiF (1 nm)/Al (100 nm) was fabricated. The EL device emits cyan light originating from this complex with high brightness and efficiencies. For 1, a maximum luminance of 34.9 cd/A was achieved at 9 V.     

Thermally stable nonaggregating pyrenylarenes for blue organic light-emitting devices

A new series of thermally stable blue light-emitting nonplanar pyrenylarenes having an amine donor and a nitrile acceptor group was prepared from a ketene-S,S-acetal under conventional heating and/or microwave irradiation. The photophysical, electrochemical, and optical behavior of donor-acceptor pyrenylarenes are demonstrated. The performance of blue light-emitting pyrenylarenes was investigated by fabricating a multilayer device with the device configuration of ITO/PEDOT:PSS (40 nm)/NPB (30 nm)/pyrenylarene (55 nm)/BCP (8 nm)/LiF (0.6 nm)/Al (200 nm), which exhibited low turn-on voltage (5 V) with luminance efficiency of 0.8 Cd/A with nonaggregation behavior in both solution and solid state.     

Bright and monochromic red light-emitting electroluminescence devices based on a new multifunctional europium ternary complex

A novel europium(III) complex, tris(dibenzoylmethanato)(2-4'-triphenylamino)imidazo[4,5-f]1,10-phenanthroline)europium(III), Eu(DBM)3(TPIP), is synthesized. The light-emitting center, hole-transporting triphenylamine and electron-transporting phenanthroline fragments are integrated into one molecule. A single-layer device of ITO/Eu(DBM)3(TPIP) (60 nm)/Mg0.9Ag0.1/Ag exhibits Eu(III)-based pure red emission with a maximum brightness of 19 cd m(-2) at 13.5 V and 280 mA cm(-2), and an onset driving voltage of 8 V. A four-layer device of ITO/TPD (20 nm)/Eu(DBM)3(TPIP) (40 nm)/BCP (20 nm)/AlQ(40 nm)/Mg0.9Ag0.1/Ag gives a maximum Eu(III)-based pure red emitting luminance of 1305 cd m(-2) at 16 V and 255 mA cm(-2) with an onset driving voltage of 6 V; the maximum external quantum yield and luminous yield are estimated to be 0.85% and 1.44 lm W(-1), respectively, at 7.5 V and 0.25 mA cm(-2).