Effect of NaCl doped into Bphen layer on the performance of tandem organic light-emitting diodes

To improve the performance of tandem organic light-emitting diodes （OLEDs）, we study the novel NaCl as n-type dopant in Bphen：NaCl layer. By analyzing their relevant energy levels and cartier transporting characteristics, we discuss the mechanisms of the effective charge generation layer （CGL） of Bphen：NaCl （6 wt%）/MoO3. In addition, we use the Bphen：NaC1 （20 wt%） layer as the electron injection layer （ELL） combining the CGL to further improve the performance of tandem device. For this tandem device, the maximal current efficiency of 9.32 cd/A and the maximal power efficiency of 1.93 lm/W are obtained, which are enhanced approximately by 2.1 and 1.1 times compared with those of the single- emissive-unit device respectively. We attribute this improvement to the increase of electron injection ability by introducing of Bphen：NaCl layer. Moreover, the CGL is almost completely transparent in the visible light region, which is also important to achieve an efficient tandem OLEDs.     

双电子传输层对有机发光二极管效率及其衰减的改善

采用Bphen和BCP制成双电子传输层(Doubleelectrontransportlayers, DETLs)的有机发光二极管器件, 与Bphen单独作ETL的器件相比, DETLs器件具有较小的空穴漏电流, 效率提升10%。与BCP独自作ETL的器件相比, 更多的电子注入使DETLs器件的效率在50~600mA/cm²的电流范围内没有衰减。BCP作ETL的器件的效率从50mA/cm²时的2.5cd/A衰减至300mA/cm²的2.1cd/A, 衰减了16%。Cs₂CO₃:BCP独自作ETL的器件效率在50~300mA/cm²的电流范围内衰减了30%, 而Bphen/Cs₂CO₃:BCP作DETLs的器件效率在50~600mA/cm²的电流范围内衰减幅度为0, 原因是Bphen阻挡了Cs原子扩散至发光层。     

Organic Photovoltaic Cells with Improved Performance Using Bathophenanthroline as a Buffer Layer

采用Bphen作为缓冲层,研究Bphen处在电子受体材料C₆₀和阴极Ag之间对有机薄膜光伏电池(OPV)性能的影响．通过引入2.5nm厚的Bphen,在100 mW/cm²光照下,CuPc/C₆₀结构的器件效率从0.87%提高到2.25%． 对光生电流-电压的分析表明,Bphen缓冲层可以有效的提高电子从C₆₀层向Ag阴极的传输能力和平衡器件中载流子的传输能力．系统研究了Bphen厚度对OPV器件性能的影响,发现随着Bphen厚度的增加,电导率的降低是限制器件性能的主要原因．此外,采用紫外-可见光分光光度计测试了器件的吸收光谱,发现Bphen缓冲层可以增强CuPc/C₆₀的光吸收能力．     

Enhancement of Frster energy transfer from thermally activated delayed fluorophores layer to ultrathin phosphor layer for high color stability in non-doped hybrid white organic light-emitting devices

Fluorescence/phosphorescence hybrid white organic light-emitting devices(WOLEDs) based on double emitting layers(EMLs) with high color stability are fabricated.The simplified EMLs consist of a non-doped blue thermally activated delayed fluorescence(TADF) layer using 9,9-dimethyl-9,10-dihydroacridine-diphenylsulfone(DMAC-DPS) and an ultrathin non-doped yellow phosphorescence layer employing bis[2-(4-tertbutylphenyl)benzothiazolato-N,C2']iridium(acetylacetonate)((tbt)_2Ir(acac)).Two kinds of materials of 4,7-diphenyl-1,10-phenanthroline(Bphen) and 1,3,5-tris(2-Nphenylbenzimidazolyl) benzene(TPBi) are selected as the electron transporting layer(ETL),and the thickness of yellow EML is adjusted to optimize device performance.The device based on a 0.3-nm-thick yellow EML and Bphen exhibits high color stability with a slight Commission International de l'Eclairage(CIE) coordinates variation of(0.017,0.009) at a luminance ranging from 52 cd/m~2 to 6998 cd/m~2.The TPBi-based device yields a high efficiency with a maximum external quantum efficiency(EQE),current efficiency,and power efficiency of 10%,21.1 cd/A,and 21.3 lm/W,respectively.The ultrathin yellow EML suppresses hole trapping and short-radius Dexter energy transfer,so that Forster energy transfer(FRET)from DMAC-DPS to(tbt)_2Ir(acac) is dominant,which is beneficial to keep the color stable.The employment of TPBi with higher triplet excited state effectively alleviates the triplet exciton quenching by ETL to improve device efficiency.     

4,4′,4″-三(N-3-甲基苯基-N-苯基氨基)三苯胺掺杂MoOx作为空穴传输层对有机太阳电池性能的影响

通过采用4,4′,4″-三(N-3-甲基苯基-N-苯基氨基)三苯胺 (m-MTDATA)掺入MoO_x作为器件的空穴传输层来提高酞菁铜(CuPc)/C₆₀小分子 有机太阳电池的效率. 采用真空蒸镀的方法制备了一系列器件, 其中结构为铟锡氧化物 (ITO)/m-MTDATA:MoO_x(3:1)(30 nm)/CuPc(20 nm)/C₆₀(40 nm)/4,7-二苯 基-1,10-菲罗啉 (Bphen)(8 nm)/LiF(0.8 nm)/Al(100 nm)的器件, 在AM1.5 (100 mW/cm²)模拟太阳光的照射条件下, 开路电压V_oc=0.40 V, 短路电流J_sc=6.59 mA/cm², 填充因子为0.55, 光电转换效率达1.46%, 比没有空穴传输层的器件ITO/CuPc(20 nm)/C₆₀(40 nm)/Bphen(8 nm)/LiF(0.8 nm)/Al(100 nm) 光电转换效率提高了38%. 研究表明, 加入m-MTDATA:MoO_x(3:1)(30 nm)空穴传输层减小了有机层和ITO电极之间的接触电阻, 从而减小了整个器件的串联电阻, 提高了器件的光电转换效率.     

新型苯乙烯衍生物掺杂的蓝色及白色有机电致发光器件

研究了新型高效蓝色掺杂剂EBDP的电致发光性能. 分别以EBDP为掺杂剂制备了结构为氧化铟 锡(ITO)/酞菁铜(CuPc)/N,N′-二(1-萘基)-N,N′-二苯基-1,1′-联苯-4-4′-二胺(NPB)/2- 叔丁基-9,10-二-(2-萘基)蒽(TBADN):EBDP/8-羟基喹啉铝(Alq₃)/LiF/Al 与ITO /CuPc/NPB/TBADN:EBDP: 4-二氰亚甲基-2-叔丁基-6-(1,1,7,7-四甲基久咯呢定基-9-烯基)- 4H-吡喃/Alq_{3 关键词： 有机电致发光 蓝色掺杂剂 蓝色电致发光器件 白色电致发光器件}     

高稳定性的红色有机薄膜电致发光器件

有机薄膜电致发光作为新型的平板显示器件受到人们广泛的关注。有机发光器件研究的一个目标是发展全色显示。目前绿色和蓝色器件都实现了高亮度和长寿命。有关红色有机发光器件也有一些报道。如 Ｃ．Ｗ．Ｔａｎｇ等报道的 ＤＣＭ红光器件［１］,Ｊ．Ｋｉｄｏ［２］利用稀土有机物作为红色发射体,Ｐ．Ｅ．Ｂｕｒｒｏｕｓ报道的ＴＰＰ掺杂［３］Ｙ．Ｈａｍａｄａ报道的ＺｎＴＰＰ掺杂［４］, Ｍ． Ａ． Ｂａｌｄｏ利用ＰｔＯＥｐ［５］都得到红光。最近 Ｙ． Ｈａｍａｄａ报道利用ｒｕｂｒｅｎｅ作为辅助掺杂得到的红光器件色度不随电压的…     

利用不同阴极缓冲层来改善Pentacene/C60太阳能电池的性能

制备了结构为ITO/Pentacene/C₆₀/Al的双层光伏电池器件,在C₆₀/Al界面插入了常用的缓冲层材料bathocuproine(BCP)作为阴极缓冲层,通过优化BCP层的厚度来提高电池的性能并研究了阴极缓冲层的作用机理.实验发现,BCP厚度为10 nm时器件的效率最高,为0.46%.在此基础上,利用bathophenanthroline(Bphen)和3,4,9,10-Perylenetetracarb-oxylicdianhydride(PTCDA 关键词： 有机太阳能电池 Pentacene 60')" href="#">C₆₀ 缓冲层     

稳定的蓝色及白色有机薄膜电致发光器件

报道了一种稳定的蓝色和白色有机薄膜电致发光器件,蓝色器件最大亮度为7526cd／m^2,最大效率1．451m／W,半亮度寿命1035h(初始亮度l00cd／m^2)。白色器件的最大亮度为14850cd／m^2,最大效率2．881m／W,色度x=0．31,y=0．38,且色度不随电流增大而变化,半亮度寿命为2860h(初始亮度100cd／m^2)。     

修饰阴极界面提高聚合物白光二极管发光效率

利用聚合物的不同溶解性,研究用旋涂方法制备双层高分子白光二极管(WPLED),采用器件结构为：ITO/PEDOT(50nm)/PVK:PFO-BT: PFO-DBT(40nm)/PFO(40nm)/Ba(4nm) /Al(120nm),当相对比例为PVK: PFO-BT:PFO-DBT=1∶4%：3%时,得到标准白光,最大电流效率为2.4 cd/A,最大亮度为3215 cd/m²,色坐标为(0.33,0.34).用水溶性的聚电介质层修饰阴极界面,器件效率可以进一步提高到5.28 cd 关键词： 聚合物发光二极管 白光 双发光层结构     

High-contrast and high-efficiency top-emitting organic light-emitting devices

The reflection properties of top-emitting organic light-emitting devices with different electrodes and organic layers were calculated. The results guided the fabrication of a high-contrast device: Au/copper phthalocyanine (CuPc: 35 nm)/N,N’-bis-(1-naphthyl)-N,N’diphenyl-1,1’ biphenyl-4,4’diamine (NPB: 15 nm)/tris(8-hydroxyquinoline) aluminum (Alq₃: 50 nm)/Sm (35 nm)/Alq₃ (65 nm). The device has a contrast ratio of 8.3:1 at a luminance of 300 cd/m² under 1000 lx ambient light, and a maximum luminance and efficiency of 5000 cd/m² and 4.14 cd/A, respectively. The high contrast is attributed to the moderate reflection of Au at 380–550 nm, low reflection of Sm in the visible range, and high absorption of CuPc at 600–700 nm. PACS 85.60.Jb; 78.20.Ci; 78.40.-q     

Organic Light-Emitting Diodes with Magnesium Doped CuPc as an Efficient Electron Injection Layer

Bright organic electroluminescent devices are developed using a metal-doped organic layer intervening between the cathode and the emitting layer. The typical device structure is a glass substrate/indium-tin oxide （ITO）/copper phthalocyanine （CuPc）/N,N＇-bis-（1-naphthl）-diphenyl-1,1＇-biphenyl-4,4＇-diamine （NPB）/Tris（8-quinolinolato） aluminum（Alq3）/Mg-doped CuPc/Ag. At a driving voltage of 11 V, the device with a layer of Mg-doped CuPc （1：2 in weight） shows a brightness of 4312cd/m^2 and a current efficiency of 2.52cd/A, while the reference device exhibits 514 cd/m^2 and 1.25 cd/A.     

A comparative study of electrode effects on the electrical and luminescent characteristics of Alq3/TPD OLED: Improvements due to conductive polymer (PEDOT) anode

The performance of organic light emitting device (OLED) structures, based on identically fabricated Alq₃/TPD active regions, with various anode and cathode electrode structures are compared, and performance differences related to the different anode structure. The best performance was achieved with a conductive polymer, 3,4-polyethylenedioxythiopene-polystyrenesultonate (PEDOT), used as an anode layer, yielding a brightness of 1720 cd/m² at 25 V, a turn-on voltage of 3 V, and electroluminescence (EL) efficiency and external quantum efficiency of 8.2 cd/A and 2%, respectively, at a brightness of 100 cd/m² and 5 V. Compared to a baseline device (TPD/Alq₃/Al), PEDOT anodes substantially reduce the turn-on voltage and made current injection almost linear after turn-on, whiles devices incorporating a LiF and CuPc layers significantly improved device efficiency while slightly improving turn-on voltage and maintaining superlinear I-V injection. This is attributed to the reduced barrier at the organic-organic interface in PEDOT, the ‘ladder’ effect of stepping the band offset over several interfaces, and the favorable PEDOT film morphology. The benefit of the PEDOT anode is clearly seen in the improvement in device brightness and the high external quantum efficiency obtained.     

梯度掺杂体异质结对有机太阳能电池光电转换效率的影响

基于传统的体异质结有机太阳能电池结构, 对结构中的混合层改用梯度掺杂的方法, 在AM1.5, 100 mW/cm²光照下, 使得器件的短路电流由原来的7.72 mA/cm²提高到了9.18 mA/cm², 相应的光电转换效率提高了25%. 器件性能的提升归因于梯度掺杂体系的引入使得体异质结混合层中同一材料分子之间形成了较好的连续网络结构, 降低了器件的串联电阻, 提高了电极对载流子的收集效率, 从而提高了器件的光电转换效率. 关键词： 有机太阳能电池 体异质结 梯度掺杂     

同时掺杂磷光和荧光染料的白色有机电致发光器件性能研究

以磷光染料Ir(piq)₂(acac)作为发光掺杂剂,掺入空穴传输性主体材料NPB中得到红色发光层,荧光材料TBP掺入到主体CBP中作为蓝色发光层,制备了结构为ITO/NPB/NPB：Ir(piq)₂(acac)/CBP/CBP：TBPe/BCP/ALq/Mg：Ag的双发光层白色有机电致发光器件.其中ALq₃、未掺杂的NPB和CBP及BCP层分别作为电子传输层、空穴传输层和激子阻挡层.实验中通过调节发光层厚度及Ir(piq)_{2关键词： 磷光 激子阻挡层 有机电致发光}     

Highly efficient blue fluorescent OLEDs with doped double emitting layers based on p—n heterojunctions

We fabricate a kind of novel efficient blue fluorescent organic light emitting device(OLED) based on p-n heterojunctions composed of hole transporting layer(HTL) N,N ’-bis(naphthalen-1-yl)-N,N ’-bis(phenyl)-benzidine(NPB) and electron transporting layer(ETL) 4,7-diphnenyl-1,10-phenanthroline(BPhen),into which a new blue material,DNCA(a derivation of N 6,N 6,N 12,N 12-tetrap-tolylchrysene-6,12-diamine),is partially doped simultaneously,and double emitting layers are configured.With a turn-on voltage of 2.6 V at 1 cd/m 2,this type of OLED presents a maximum luminance efficiency(η max) of 8.83 cd/A at 5.818 mA/cm 2 and a maximum luminance of over 40000 cd/m 2.Meanwhile,the Commission Internationale De L’Eclairage(CIE) coordinates of this device change slightly from(0.13,0.27) to(0.13,0.23) as the driving voltage increases from 3 V to 11 V.This improvement in the electroluminescent characteristics is attributed mainly to the ideal p-n heterojunction which can confine and distribute excitons evenly on two sides of the heterojunction interface so as to improve the carrier combination rate and expand the light-emitting region.     

Co50Fe50-xSix合金的结构相变和磁性

利用实验测量和理论计算相结合的方法,研究了介于B2结构CoFe低有序合金和L2₁结构Co₂FeSi高有序合金之间的Co₅₀Fe_50-xSi_x合金的结构相变、磁相变、分子磁矩和居里温度.采用考虑Coulomb相互作用的广义梯度近似(GGA+U)方法计算了合金的能带结构.研究发现,合金出现较强的原子有序倾向,表现出较强的共价成相作用.合金的晶格常数、磁矩、居里温度随Si含量的增加而线性地降低,极限成分Co₂FeSi合金的分子磁矩和居里温度分别达到5.92μ_B和777 ℃.原子尺寸效应导致合金晶格发生变化,但并未成为居里温度和分子磁矩变化的主导因素.分子磁矩的变化符合Slater-Pauling原理,但发现原子磁矩的变化并非线性,据此提出了共价成相对磁性影响的观点.采用Stearns理论解释了居里温度的变化趋势,排除了原子间距对居里温度的主导影响作用.能带计算的结果还表明,Co₂FeSi作为半金属材料并非十分完美,可能在实际应用中会出现自旋极化率降低的问题.发现该系列合金的结构相变和磁相变随着成分的变化聚集在窄小的成分和温度范围内. 关键词： 磁性 Heusler合金 结构相变     

Enhanced power efficiency for white OLED with MoO3 as hole injection layer and optimized charge balance

White OLEDs with a different hole injection layer (MoO₃ or m-MTDATA), and a different electron transport layer (Alq₃ or Bphen) have been investigated. With 9,10-bis (2-naphthyl)-2-t-butylanthracene (TBADN) doped with 3% P-bis (P-N, N-diphenyl-aminostyryl) benzene (DSA-ph) and 0.05% 4-(dicyanomethylene)-2-t-butyl-6-(1,1,7,7,-tetramethyl-julolidy-9-enyl)-4H-pyran (DCJTB) as white emitting layer, the MoO₃/ /Bphen based device shows the lowest driving voltage and highest power efficiency among the referenced devices. At the current density of 20 mA/cm², its driving voltage and power efficiency are 5.43 V and 4.54 lm/W respectively, which is independently reduced 40% and improved 57% compared with those of the m-MTDATA/ / Alq₃ based one, respectively. The energy level diagram of the devices and single-carrier devices are studied to explain the reasons for the improvement. The results strongly indicate that carrier injection ability and balance shows a key significance in OLED performance.     

基于量子阱结构的高效磷光有机电致发光器件

采用多重量子阱结构制作了高效红色磷光有机电致发光器件。以4,4'-bis(N-carbazolyl)-1,10-biphenyl (CBP)掺杂bis(1-phenyl-isoquinoline)(Acetylacetonato) iridium(Ⅲ) (Ir(piq)₂(acac))为发光层,4,4'-bis(N-carbazolyl)-1,10-biphenyl(Bphen)为电荷控制层,形成了Ⅱ型双量子阱结构,器件的最大亮度为15 000 cd/m²,最大电流效率为7.4 cd/A,相对于参考器件提高了21%。研究结果表明:以Bphen为电荷控制层形成的Ⅱ型多重量子阱结构能有效地将载流子和激子限制在势阱中,并且使空穴和电子的注入更加平衡,从而提高了载流子复合的几率和器件的效率。     

基于铱配合物材料的高效高稳定性有机发光二极管

使用基于重金属Ir的新磷光材料(tpbi)₂Ir(acac)，制备了多层结构有机发光二极管器件: ITO/CuPc (40 nm)/α-NPD (45 nm)/CBP: (tpbi)₂Ir(acac) (3%, 30nm)/BCP(20 nm)/Alq₃ (20 nm)/LiF (1 nm)/Al (100 nm).测试了材料的寿命、光谱吸收性质和器件的I-V-L特性.器件在低电压下电流符合热发射注入模型，高电压下I-V呈线形关系.不同偏压下器件发光光谱稳定，多峰拟合结果表明器件光谱由α-NPD发光峰(450 nm)，(tpbi)₂Ir(acac)主发光峰(518 nm)和肩峰(543 nm)构成.驱动电压为6 V时，器件效率达到最大12.1 lm/W，此时亮度为136 cd/m²，器件亮度最大为13500 cd/m²，此时效率为0.584 lm/W. 关键词： 有机发光二极管 磷光 效率 I-V-L特性')" href="#">I-V-L特性 光谱