基于面式-三(2-(4-三氟甲基苯基)吡啶)合铱配合物为发光中心的高效绿光有机电致发光器件

用经典的方法合成了面式-三(2-(4-三氟甲基苯基)吡啶)合铱配合物(fac-Ir(tfmppy)₃), 并得到了其晶体结构。在CH₂Cl₂溶液中Ir(tfmppy)₃的发射光谱显示出了峰值位于525 nm的π→π^*跃迁吸收以及金属到配体电荷转移(MLCT)吸收, 色坐标(CIE)为(0.31, 0.62), 量子效率计算为4.59%(以Ru(bpy)₃]Cl₂为参照)。以Ir(tfmppy)₃为发光中心, 制备并研究了有机电致发光器件:ITO/TAPC (60 nm)/Ir(tfmppy)₃ (x%):mCP (30 nm)/TPBi (60 nm)/LiF (1 nm)/Al (100 nm)。4%掺杂浓度的器件在4 197 cd·m^-2的亮度下显示的最大电流效率为33.95 cd·A^-1, 在12.7 V时的最大亮度为43 612 cd·m^-2, 色坐标(CIE)为(0.31, 0.61)。利用瞬态电致发光法(transient electroluminescence (EL))、在1 300 (V·cm^-1)^1/2的电场强度下Ir(tfmppy)₃配合物的电子迁移率测定为4.24×10^-6 cm²·(V·s)^-1。非常接近于常用的电子传输材料八羟基喹啉铝(Alq₃)的电子迁移率。     

含氟绿光铱配合物的设计、合成及其高效磷光电致发光器件

以2-(3-(2',4'-二氟苯基)苯基)吡啶(Hdfbppy)为环金属C^N配体,乙酰丙酮(Hacac)为辅助配体,设计合成了一种绿色磷光铱配合物(Ir(dfbppy)₂(acac));研究了此配合物的光物理性质及其电致发光器件性能。室温下,配合物Ir(dfbppy)₂(acac)的二氯甲烷溶液的最大发射波长为520nm,量子效率为71%,寿命为381ns。将此配合物掺杂在4,4'-N,N'-二咔唑基二联苯(CBP)中,作为发光层制备了有机发光二极管器件。结果显示,该器件在7.2V电压下呈现的最大亮度为68324cd·m^-2,最大电流效率约为53cd·A^-1,最大功率效率为37lm·W^-1,色坐标为(0.33,0.62)。     

新型铱配合物的合成及电致发光性质研究

合成了一种新型橙红色磷光材料铱的配合物(npp)₂Ir(acac)(npp=2-(1-萘基)-4-苯基吡啶，acac=乙酰丙酮)，通过 ¹H NMR、MS、元素分析对其结构进行了表征。以铱配合物(npp)₂Ir(acac)作为发光体，制备了结构为ITO/Ir(5%)：PVK(60 nm)/F-TBB(15 nm)/Alq₃(15 nm)/LiF(1 nm)/Al(150 nm)的电致发光器件，研究了其电致发光性质。结果表明器件的最大发射波长在599 nm，最大发光亮度为3 841 cd·m^-2，最大电流效率达3.9 cd·A^-1。     

一种含载流子传输基的铱配合物:合成及深黄色电致磷光器件

合成了一种含有载流子传输基新的铱配合物(BPPBI)2Ir(ECTFBD)[HBPPBI:1-苯基-2-(4-联苯基)苯并咪唑,HECTFBD:1-(9-乙基-3-咔唑基)-4,4,4-三氟-1,3-丁二酮],其结构和组成经核磁共振氢谱和元素分析所证实。研究了这种铱配合物二氯甲烷溶液的光物理和电化学性质。制作了基于这种铱配合物的电致磷光器件。器件结构是ITO/MoO3(10 nm)/NPB(80 nm)/CBP:x%(BPPBI)2Ir(ECTFBD)(20 nm)/TPBi(45 nm)/LiF/Al[x%:质量百分比为4%和7%的掺杂浓度;NPB:N4,N4′-二(1-萘基)-N4,N4′-二苯基-4,4′-联苯二胺,CBP:4,4′-二(9-咔唑基)联苯,TPBi:1,3,5-三(2-(1-苯基)苯并咪唑基)苯]。这些器件显示出深黄色的发射。对于7%掺杂浓度器件,最大的电流效率和最大发光亮度分别是5.2 cd.A-1和8 690 cd.m-2。     

小分子铱配合物及其电致发光

由于磷光金属配合物可以同时利用单线态和三线态激子发光,使有机电致发光器件的理论内量子效率达到100%,突破了25%的极限。因而以磷光金属配合物为发光材料制成的器件备受关注。在这些金属配合物中,铱配合物由于具有较强的发光特性、发光波长可调性、较好的热稳定性和电化学稳定性以及能够形成便于蒸镀的中性分子,而成为最有应用潜力的电致磷光材料。本文综述了近几年铱配合物磷光材料在分子设计与合成方法、发光机理及器件构筑等方面的研究进展。特别介绍与讨论了磷光铱配合物的两种发光机理,即基于同配体铱配合物或异配体铱配合物的主配体到中心金属离子的电荷转移三线态(³MLCT)发射和基于异配体铱配合物的辅助配体三线态(³LC)发射。根据反应条件的差异,归纳总结了合成铱配合物常用的4种方法以及合成fac式和mer式的铱配合物的方法。还根据材料的发光颜色及其电致发光的不同,对磷光铱配合物材料进行了分类与讨论。此外,简要介绍了用于器件制作的主体材料。最后,展望了金属有机配合物电致磷光材料的发展前景,并提出了今后磷光材料的发展方向。     

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%。     

带烷氧基的苯基蒎烯吡啶铱配合物在聚合物电致发光器件中的应用研究

采用旋涂法将一组带烷氧基的苯基蒎烯吡啶铱(Ⅲ)配合物(Ir(RO-pppy)₃)磷光材料掺杂到PVK中,制作出了聚合物电致发光器件:ITO/PE-DOT:PSS(40 nm)/PVK_0.7:PBD_0.3:(x%.)Ir-complex(80 nm)/CsF(1.5 nm)/Mg:Ag(200 nm).实验结果表明,带有长烷氧基链配体的铱(Ⅲ)配合物能表现出更好的器件行为,当掺杂浓度为3.2%时,器件的最高发光效率达19.9 cd/A(7.8 lm/W,9.1V),CIE为(0.20,0.56);器件最大亮度为15700 cd/m²(8.4V).通过对这组铱(Ⅲ)配合物的光物理行为及电化学性能的研究,考察了主体材料与配合物之间的能级配置以及能量转移的机理.     

一种红光铱配合物的合成和电致发光性能

以1-(4-三氟甲基苯基)异喹啉(tfmpiq)为主配体,二(二(4-三氟甲基苯基)膦酰)胺(tfmtpip)为辅助配体,成功合成了Ir髥配合物Ir(tfmpiq)2(tfmtpip),并得到了配合物的晶体结构。配合物Ir(tfmpiq)2(tfmtpip)的分解温度为373℃,具有良好的热稳定性。Ir(tfmpiq)2(tfmtpip)的发射光谱主要是MLCT发射,峰位置为613 nm,量子效率为3.7%,HOMO和LUMO轨道能级分别为-5.62和-3.54 e V。基于Ir(tfmpiq)2(tfmtpip)的器件ITO/TAPC(40 nm)/Ir(tfmpiq)2(tfmtpip)(x%)∶mCP(20 nm)/TmPyPB(40 nm)/LiF(1 nm)/Al(100 nm),当掺杂浓度为4%(w/w)时,器件达到最大功率效率和电流效率分别为5.73 lm·W-1和7.13 cd·A-1,而且器件在12.8 V的驱动电压下达到亮度10 542 cd·m-2。     

含三氟乙酰苯基喹啉配体的铱配合物的合成及其电致发光性能

通过2-(4'-三氟乙酰苯基)-4-苯基喹啉(tfapqH)与三氯化铱反应生成了二氯桥中间体,然后用吡啶-2-甲酸(picH)解离得到双环金属铱配合物Ir(tfapq)₂pic。Ir(tfapq)₂pic在二氯甲烷中的发光波长为584 nm,量子产率约为0.846,磷光寿命为1.211 μs,比没有三氟乙酰修饰的铱配合物波长蓝移的10 nm,量子效率提高了约5%,磷光寿命降低了0.286 μs,辐射跃迁加快,半波宽度降低了约26%,色纯度提高。其HOMO能级为-5.405 eV,LUMO能级为-3.277 eV,能级相对于未修饰的配合物都有所降低,且HOMO降低更明显,总的效果是能级差增加。Ir(tfapq)₂pic 10%的热失重温度为301 ℃,比未修饰铱配合高近50 ℃。当Ir(tfapq)₂pic以2%质量浓度掺杂于PVK-PBD中做成电致发光器件时的效率最高,电致发光波长为594 nm。器件的启明电压为7.3 V,最大亮度为8 571 cd·m^-2,最大外量子效率为12.65%,对应的流明效率为22.14 cd·A^-1。色坐标是(0.58,0.40)。     

苯基噌啉铱配合物的合成及电致发光性质

合成了一种新型环金属铱(Ⅲ)配合物(dpci)2Ir(pic),通过核磁共振氢谱和飞行时间质谱对配合物的结构进行了确定,同时对其光物理性能和电化学性能进行了表征。结果表明(dpci)2Ir(pic)在二氯甲烷中的发光波长为657 nm,量子产率约为0.005,磷光寿命为226 ns。其HOMO能级为-5.16 eV,LUMO能级为-3.16 eV。将铱配合物以0.5~4.0%质量浓度掺杂于聚乙烯基咔唑(PVK)-2-(4-叔丁基苯)-5-(4-联苯基)-1,3,4-噁二唑(PBD)中,通过旋涂成膜做成电致发光器件。掺杂2.0%的器件表现出最好的性能,电致发光波长为658 nm。器件的启明电压为11.5 V,最大外量子效率为9.1%,最大亮度为2 484 cdm-2,对应的流明效率为5.31cd.A-1。色坐标是(0.66,0.31)接近标准红色的色坐标。     

高效溶液法小分子磷光电致发光器件研究

以小分子化合物CDBP[4,4′-bis(carbazol-9-yl)-9,9-dimethyl-fluorene]为主体材料,Ir(pppy)3[tris(5-phenyl-10,10-dimethyl-4-aza-tricycloundeca-2,4,6-triene)Iridium(III)]为磷光客体材料,采用溶液法和真空蒸镀法相结合的制备工艺,制作了小分子磷光电致发光器件.研究表明,通过器件结构的优化,Ir(pppy)3(重量百分比为2)掺杂的多层绿光电致发光器件效率达22.0 cd/A,最大亮度达到26600 cd/m²,这一结果可与当今基于真空蒸镀的小分子或基于溶液法的高分子磷光电致发光器件性能相媲美.本工作为降低有机电致发光器件的成本,扩展溶液法有机电致发光器件制备工艺中材料的选择范围提供了实验依据.     

Solution-Processed Yellow Organic Light-Emitting Diodes Based on Two New Ionic Ir (III) Complexes

Two new and efficient cationic yellow-emissive Ir (III) complexes (Ir1 and Ir2) are rationally designed by using 2-(4-chloro-3-(trifluoromethyl)phenyl)-4-methylquinoline as the main ligand, and, respectively, 4,4′-dimethyl-2,2′-bipyridyl and 4,4′-dimethoxy-2,2′-bipyridyl as the ancillary ligands. Both complexes show enhanced phosphorescence (546 nm with 572 nm as shoulder and high phosphorescent quantum efficiency in solution, which is in favor of efficient solution-processed phosphorescent organic light-emitting diodes. Compared with Ir2, the Ir1-based device displays excellent device performance, with maximum external quantum efficiency, current efficiency, and power efficiency of up to 7.92%, 26.32 cd/A and 15.31 lm/W, respectively, thus proving that the two new ionic Ir (III) complexes exhibit great potential for future solution-processed electroluminescence.     

Deep-Red and Near-Infrared Iridium Complexes with Fine-Tuned Emission Colors by Adjusting Trifluoromethyl Substitution on Cyclometalated Ligands Combined with Matched Ancillary Ligands for Highly Efficient Phosphorescent Organic Light-Emitting Diodes

Six novel Ir(C^N)₂(L^X)-type heteroleptic iridium complexes with deep-red and near-infrared region (NIR)-emitting coverage were constructed through the cross matching of various cyclometalating (C^N) and ancillary (LX) ligands. Here, three novel C^N ligands were designed by introducing the electron-withdrawing group CF₃ on the ortho (o-), meta (m-), and para (p-) positions of the phenyl ring in the 1-phenylisoquinoline (piq) group, which were combined with two electron-rich LX ligands (dipba and dipg), respectively, leading to subsequent iridium complexes with gradually changing emission colors from deep red (≈660 nm) to NIR (≈700 nm). Moreover, a series of phosphorescent organic light-emitting diodes (PhOLEDs) were fabricated by employing these phosphors as dopant emitters with two doping concentrations, 5% and 10%, respectively. They exhibited efficient electroluminescence (EL) with significantly high EQE values: >15.0% for deep red light0 (λ_max = 664 nm) and >4.0% for NIR cases (λ_max = 704 nm) at a high luminance level of 100 cd m⁻². This work not only provides a promising approach for finely tuning the emission color of red phosphors via the easily accessible molecular design strategy, but also enables the establishment of an effective method for enriching phosphorescent-emitting molecules for practical applications, especially in the deep-red and near-infrared region (NIR).     

Imidazo[1,2-a]pyridine as an Electron Acceptor to Construct High-Performance Deep-Blue Organic Light-Emitting Diodes with Negligible Efficiency Roll-Off

Two novel bipolar deep-blue fluorescent emitters, IP-PPI and IP-DPPI, featuring different lengths of the phenyl bridge, were designed and synthesized, in which imidazo[1,2-a]pyridine (IP) and phenanthroimidazole (PI) were proposed as an electron acceptor and an electron donor, respectively. Both of them exhibit outstanding thermal stability and high emission quantum yields. All the devices based on these two materials showed negligible efficiency roll-off with increasing current density. Impressively, non-doped organic light-emitting diodes (OLEDs) based on IP-PPI and IP-DPPI exhibited external quantum efficiencies (EQEs) of 4.85 % and 4.74 % with CIE coordinates of (0.153, 0.097) and (0.154, 0.114) at 10000 cd m⁻², respectively. In addition, the 40 wt % IP-PPI doped device maintained a high EQE of 5.23 % with CIE coordinates of (0.154, 0.077) at 10000 cd m⁻². The doped device based on 20 wt % IP-DPPI exhibited a higher deep-blue electroluminescence (EL) performance with a maximum EQE of up to 6.13 % at CIE of (0.153, 0.078) and maintained an EQE of 5.07 % at 10000 cd m⁻². To the best of our knowledge, these performances are among the state-of-the art devices with CIE_y≤0.08 at a high brightness of 10000 cd m⁻². Furthermore, by doping a red phosphorescent dye Ir(MDQ)₂ (MDQ=2-methyldibenzo[f,h]quinoxaline) into the IP-PPI and IP-DPPI hosts, high-performance red phosphorescent OLEDs with EQEs of 20.8 % and 19.1 % were achieved, respectively. This work may provide a new approach for designing highly efficient deep-blue emitters with negligible roll-off for OLED applications.     

Improved Efficiency Roll-Off and Operational Lifetime of Organic Light-Emitting Diodes with a Tetradentate Platinum(II) Complex by Using an n-Doped Electron-Transporting Layer

The efficiency roll-off and operational lifetime of organic light-emitting diodes (OLEDs) with a tetradentate Pt(II) emitter is improved by engaging an n-doped electron-transporting layer (ETL). Compared to those devices with non-doped ETL, the driving voltage is lowered, the charged carrier is balanced, and the exciton density in the emissive layer (EML) is decreased in the device with n-doped ETL with 8-hydroxyquinolinolatolithium (Liq). High luminance of almost 70,000 cd m⁻² and high current efficiency of 40.5 cd A⁻¹ at high luminance of 10,000 cd m⁻² is achieved in the device with 50 wt%-Liq-doped ETL. More importantly, the extended operational lifetime of 1945 h is recorded at the initial luminance of 1000 cd m⁻² in the 50 wt%-Liq-doped device, which is longer than that of the device with non-doped ETL by almost 10 times. This result manifests the potential application of tetradentate Pt(II) complexes in the OLED industry.     

4-(2-(4-咪唑)苯乙烯基)吡啶和三种芳香二羧酸的Cd(Ⅱ)配位聚合物的合成、结构及荧光性质

以4-(2-(4-咪唑)苯乙烯基)吡啶(ISPE)为配体,分别与间苯二甲酸(1,3-H_2BDC)、4,4′-联苯二甲酸(4,4′-H_2BPDC)和4,4′-二苯乙烯二甲酸(4,4′-H_2STDC)及过渡金属盐Cd(NO3)2·4H_2O通过溶剂热自组装形成了3种配位聚合物晶体{[Cd_2(ISPE)_2(1,3-BDC)_2]·DMF}_n(1)、[Cd(ISPE)(4,4′-BPDC)]_n(2)和[Cd(ISPE)_2(4,4′-STDC)(H_2O)_2]_n(3)。并用单晶X射线衍射、PXRD、红外光谱、元素分析、热重等对其进行了表征。单晶解析结果表明:配位聚合物1是二维层状网格结构,配位聚合物2是一个六重穿插的类金刚烷三维网格结构,配位聚合物3是由一维网格结构通过氢键和分子间作用力堆积形成的三维网格结构。另外还研究了它们的室温固态荧光性能。     

4-(2-(4-咪唑)苯乙烯基)吡啶和三种芳香二羧酸的Cd(Ⅱ)配位聚合物的合成、结构及荧光性质

以4-（2-（4-咪唑）苯乙烯基）吡啶（ISPE）为配体,分别与间苯二甲酸（1,3-H₂BDC）、4,4′-联苯二甲酸（4,4′-H₂BPDC）和4,4′-二苯乙烯二甲酸（4,4′-H₂STDC）及过渡金属盐Cd（NO₃）₂·4H₂O通过溶剂热自组装形成了3种配位聚合物晶体{[Cd₂（ISPE）₂（1,3-BDC）₂]·DMF}_n （1）、[Cd（ISPE）（4,4′-BPDC）]_n （2）和[Cd（ISPE）₂（4,4′-STDC）（H₂O）₂]_n （3）。并用单晶X射线衍射、PXRD、红外光谱、元素分析、热重等对其进行了表征。单晶解析结果表明：配位聚合物1是二维层状网格结构,配位聚合物2是一个六重穿插的类金刚烷三维网格结构,配位聚合物3是由一维网格结构通过氢键和分子间作用力堆积形成的三维网格结构。另外还研究了它们的室温固态荧光性能。     

Simply Structured Near-Infrared Emitters with a Multicyano Linear Acceptor for Solution-Processed Organic Light-Emitting Diodes

Near-infrared (NIR) organic light-emitting diodes (OLEDs) show great potential in a variety of applications including sensors, night vision, and information security. Despite the superiority of thermally activated delayed fluorescence (TADF) in 100 % exciton harvesting, the development of NIR TADF OLEDs is still a great challenge, especially in terms of solution-processing technology. In this work, a multicyano acceptor of 2-dicyanomethylene-3-cyano-4,5,5-trimethyl-2,5-dihydrofurance (TCF) with strong electron-withdrawing ability was employed to construct solution-processible NIR emitters, CzTCF and tBCzTCF, with the feature of donor–π–acceptor (D –π–A) structure. The significantly enhanced intermolecular charge transfer effects not only render the deep-red and NIR emissions of CzTCF and tBCzTCF films, respectively, but also lead to their typical TADF characteristics. Consequently, the nondoped solution-processed NIR OLED based on tBCzTCF was successfully demonstrated with the peak wavelength of 715 nm, which paves the way for developing NIR emitters without polycyclic aromatic cores and heavy-metal ions.