三苯胺-芴类共聚物的合成及发光性能

在主链上嵌入三苯胺基团来改善聚芴的空穴传输能力、平衡载流子的注入是目前改善聚芴材料发光效率的一种好方法。本文用Suzuki缩聚法合成了芴-三苯胺类共聚物。实验结果表明．在聚芴主链上引入少量的TPA(10％～20％)时．不仅提高了EL效率．而且可以改善光谱的色纯度。TPA含量为20％时,共聚物的EL效率为1．28％。     

芴-苯并噻二唑-苯胺类共聚物的合成与发光性能

用Suzuki缩聚反应分别将窄带隙单元-苯并噻二唑-二苯胺(DPABT)和苯并噻二唑-三苯胺(TPABT)引入聚芴主链,合成了共聚物PF-DPABT和PF-TPABT,并比较了共聚物的发光性能.随着窄带隙单元含量的增加,其特征发射逐渐增强,说明发生了从聚合物主体单元到窄带隙单元有效的能量转移.两种共聚物在低窄带隙单元含量(1mol%)下的电致发光光谱仅出现窄带隙单元的特征发射,PF-DPABT共聚物为650～680nm之间的饱和红光,而PF-TPABT共聚物为590～610nm之间的橙红光,聚芴主体单元的发射被完全淬灭,说明与光致发光过程相比,电致发光过程中的能量转移更完全.基于共聚物PF-DPABT-1及PF-TPABT-5器件的最大外量子效率分别为1.3%和2.0%,器件结构为ITO/PEDOT:PSS/polymer/Ba/Al,是一类有希望的红光材料.     

吡啶-芴类电荧光聚合物的光谱特性

用Suzuiki聚合反应将二溴代吡啶 (2 ,5 、2 ,6 、3,5 取代 )与芴共聚 ,合成了不同主链结构的吡啶 芴共聚物 .研究结果表明 ,将吡啶基引人聚芴主链可以调节共聚物的发光颜色 .间位吡啶基引入聚芴主链 ,使聚合物的能级加宽 ,PL、EL光谱发生蓝移 ;对位吡啶基则使光谱红移 .间位吡啶基 (3,5 Py、2 ,6 Py)引入聚芴主链 ,可提高聚合物的色纯度 .共聚物中 3,5 Py含量为 4 0mol%时 ,可得到较纯的蓝光 .     

侧链接枝低聚对亚苯基亚乙烯基聚芴衍生物的合成及其电致发光性能

采用Wittig-Horner反应,将少量端基为磷脂的黄光发射客体低聚对亚苯基亚乙烯基链段(MOPV)接枝到含有醛基单体的蓝光发射主体材料聚芴的侧链上,合成了一种新型的接枝聚芴衍生物PF-g-MOPV.这种接枝聚合物具有很好的热稳定性,可溶于常用的有机溶剂.以接枝共聚物PF-g-MOPV为发光层的单层器件发射出黄绿光,色坐标为(0.30,0.57),最大发光亮度达到1550cm/m2,这说明蓝光聚芴主链向侧链MOPV进行了有效地能量转移.     

芴-呋喃苯并噻二唑共聚物的光电性能

对芴-呋喃苯并噻二唑共聚物的吸收光谱、光致发光光谱、电致发光性能和光伏性能进行了研究. 共聚物在382 nm和530 nm处有两处明显的吸收峰, 其中530 nm处的吸收强度随着共聚物中呋喃苯并噻二唑单元(FBT)含量的增加而增加. 随着FBT单元含量的增加, 电致发光峰值从611 nm红移至702 nm. 以PVK为空穴传输层, 共聚物PFO- FBT0.1为发光层的发光器件, 在33 mA/cm2电流密度下的外量子效率达2.32%, 亮度为441 cd/m2. 实验中观察到快速的链内能量陷阱过程(从芴到FBT单元). 以共聚物PFO-FBT50为电子给体、PCBM为电子受体(重量比1:2)共混制备的光电池能量转换效率为1.13%, 开路电压0.85 V, 短路电流3.39 mA/cm2, 光谱响应边延伸至近750 nm.     

三苯基吡啶-芴交替共轭聚合物的合成与光致发光性能研究

通过Suzuki偶合反应得到了两种间位连接的三苯基吡啶同分异构体和9,9-二辛基芴的交替共聚物PFOTPP1和PFOTPP2.并对它们的紫外-可见吸收光谱、光致发光光谱以及电化学性能等进行了初步研究.结果表明,将间位连接的三苯基吡啶基引入聚芴主链能使聚合物的LUMO能级降低,光致发光光谱发生蓝移,得到了两种有望应用于电致炼光发光器件的共轭聚合物蓝光发光材料.     

电致蓝光芴取代聚芴的合成与光谱稳定性

为了筛选高效稳定的聚合物电致蓝光材料, 设计合成了三苯胺和芴取代的二芳基芴单体, 并通过Suzuki缩聚合成了交替共聚物TPAFF-co-F和TPAFF-co-P. 将二辛基芴引入聚芴的9位可以增加其溶解度, 同时具有屏蔽主链和减少主链芴9位被氧化的作用, 三苯胺基团将有利于提高空穴在阳极界面的注入能力. 200 ℃下空气中退火24 h实验表明, 在相同条件下, 绿光指数(Igreen/Iblue)顺序为聚(9,9-二辛基芴)(1.07)>TPAFF-co-F(0.65)>TPAFF-co-P (0.47), 证明了烷基芴引入减少了主链氧化的几率. 还制作了发光二极管器件, 其结构为ITO/PEDOT:PSS(40 nm)/TPAFF-co-F或TPAFF-co-P(80 nm)/Ba(4 nm)/Al(120 nm). 在高电流密度下它们保持了良好的光谱稳定性, 在547 mA·cm-2电流密度下, TPAFF-co-F的CIE(国际发光照明委员会)坐标为(0.22, 0.24), TPAFF-co-P的CIE坐标为(0.24, 0.26), 后者的电流效率为0.712 cd·A-1.     

含噻吩单元的硅芴共聚物的合成及其蓝色电致发光性能

将少量(摩尔分数为1%—3％)含噻吩的窄带隙单体和宽带隙硅芴单体进行共聚, 合成了聚{9,9-二己基-3,6-硅芴-co-[2,5-二(2-甲基苯撑-4-基)-噻吩]}和聚{9,9-二己基-3,6-硅芴-co-[2,5-二(2-苯撑-4-基)-噻吩]}两类硅芴共聚物, 通过紫外-可见吸收光谱、光致发光光谱, 并制作聚合物发光二极管器件测试电致发光光谱等手段, 系统表征了两类硅芴共聚物材料的性能. 实验结果表明, 噻吩的加入形成了新的蓝色发光中心, 并且实现了从硅芴链段到含噻吩发光中心的有效能量转移. 通过增加发光中心结构的空间位阻来减小其共轭程度, 可以使聚合物的PL和EL光谱发生较大蓝移. 最终得到了效率为0.46%和色坐标(CIE)为(0.19, 0.16)的蓝光LED器件.     

芴与噻吩发光共聚物的合成及其电致发光性能

采用Suzuki偶合方法合成出了一系列新型的 9,9 二辛基芴 (DOF)和噻吩 (Th)的共聚物 .其中 ,DOF与Th的投料比 (摩尔比 )分别为 95∶5 (PTF5 )、90∶1 0 (PTF1 0 )、85∶1 5 (PTF1 5 )、70∶3 0 (PTF3 0 )、5 0∶5 0 (PTF5 0 ) .所有的聚合物均可溶于常用的有机溶剂 ,如THF,CHCl3等 ,其分子量在 60 0 0～ 5 3 0 0 0之间 .当在聚芴主链中引入噻吩后 ,其发光波长发生了红移 ,最大发光波长由PTF5时的 490nm红移到PTF5 0时的 5 41nm .随着聚芴主链中噻吩含量的增加 ,最大电致发光和光致发光效率都逐渐降低 由这些聚合物所制得的器件 ,最大电致发光效率为PTF5和PTF1 0的 0 45 %.由此表明 ,在聚芴主链中引入少量的低带隙单体噻吩可以调节聚芴的发光颜色及发光效率     

基于不同辅助配体螯合电磷光聚合物的合成与性能研究

通过A-A, B-B型的Suzuki缩聚反应将三个具有不同辅助配体的2-(2'-苯并[b]噻吩)吡啶(btp)双环铱金属配合物引入芴和咔唑交替共聚物(PFCz)的主链上, 合成一系列最大发光波长在660 nm的红光螯合电磷光聚合物, 并研究了它们的电致发光性能. 实验证明了在这类电磷光聚合物中配合物单元辅助配体合理的分子设计, 可以提高配合物单体的溶解度, 提高聚合物的分子量和发光性能. 通过优化器件结构, 聚合物PFBtpIrf5单层器件(ITO/PEDOT:PSS/polymer＋PBD(30 wt%)/Ba/Al)的性能最好: 在电流密度为14.3 mA/cm²时, 最大外量子效率为1.93%.     

芳羧酸功能化的聚砜与Tb(III)形成的高分子-稀土配合物的结构与荧光发射性能

通过大分子反应将苯甲酸(BA)键合在聚砜(PSF)侧链,制得芳羧酸功能化的聚砜(PSFBA).以PSFBA为大分子配基,以邻菲啰啉(Phen)为小分子配体,与Tb(Ⅲ)配位,分别制备了二元配合物PSFBA-Tb(Ⅲ)与三元配合物PSFBA-Tb(Ⅲ)-Phen,采用傅里叶变换红外(FTIR)光谱和紫外(UV)吸收光谱对配合物进行了表征,深入研究了配合物(溶液与薄膜)的荧光发射性能及热稳定性与结构的关系.研究结果表明,以PSFBA为大分子配基所形成的高分子-稀土配合物,均能发射出很强的Tb(Ⅲ)特征荧光,即键合在PSFBA侧链的配基BA能有效地敏化Tb(Ⅲ)的荧光发射.二元配合物PSFBA-Tb(Ⅲ)的表观饱和配位数为10,即当二元配合物具有PSF-(BA)5-Tb(Ⅲ)的结构时,BA对Tb(Ⅲ)的配位表观上达到饱和,此时二元配合物具有最强的荧光发射.按n(Phen):n(Tb(Ⅲ))=1的比例将Phen加入二元配合物PSF-(BA)5-Tb(Ⅲ)溶液中进行补充配位,所制备的三元配合物PSF-(BA)5-Tb(Ⅲ)-(Phen)1与惯用比例的三元配合物PSF-(BA)1-Tb(Ⅲ)-(Phen)3或PSF-(BA)1-Tb(Ⅲ)-(Phen)2相比,不仅荧光发射强度高,而且热稳定性能好,是一种高性能的场致发光材料.     

非金属氧化-还原对MO2/MO2-(M=N,S,Cl)的电子转移反应动力学

以Marcus-Hush电子转移理论为基础,提出了用量子化学密度泛函方法研究自交换和异交换电子转移反应的理论方案.在DFTB3LYP/6-311+G(2D)水平上研究了溶液中NO₂/NO₂^-,SO₂/SO₂^-和ClO₂/ClO₂^-等3个氧化-还原对的自交换以及它们之间的6个交叉电子转移反应的动力学性质,获得了与实验较为一致的结果.     

Photolysis and emission spectra of substituted polyacrylophenones

Poly-[3′,4′-dimethoxyacrylophenone], poly-4′-phenylacrylophenone, poly-2′-acrylonaphthone and copolymers of acrylophenone monomers with styrene and methyl methacrylate were prepared. Quantum yields of main chain scission in chlorobenzene by 313 nm radiation were 10³ times lower for all homopolymers and copolymers studied than for polyacrylophenone. The emission spectra of the polymers, copolymers and model compounds were taken for films at 77 K. The 3′,4′-dimethoxyacrylophenone, 4′-phenylacrylophenone and 2′-acrylonaphthone structural units exhibited poorly resolved emission spectra in homopolymer, copolymer and model compound. No difference in the emission spectra of films and dispersed homopolymer or copolymer in a poly(methyl methacrylate) matrix was observed. The decay of the emission of all homopolymers and copolymers under study was exponential, the life-time exceeding 0.20 sec.     

Photoluminescence property of polymer–rare earth complexes containing acetaldehyde/aminophenol type bidentate Schiff base ligand

Acetaldehyde was introduced onto the side chains of polysulfone, and then Schiff base reactions were carried out between the introduced acetaldehyde and ortho-aminophenol (OAP) or meta-aminophenol (MAP). Two bidentate Schiff base (B) ligands of acetaldehyde/aminophenol type, OAPB and MAPB, were bonded on the side chains of polysulfone, and two new bidentate Schiff base ligand functionalized-polysulfones, PSF-OAPB and PSF-MAPB, were obtained. The triplet state energies of OAPB and MAPB are well matched with the resonant level energy of Tb(III), and the Tb(III) complexes emit the strong characteristic fluorescence of Tb(III) (green luminescence). Complexes of Eu(III) have no fluorescence emission because of the mismatching of the energy levels. In comparison, the fluorescence intensity of the binary complex PSF-(MAPB)₃-Tb(III) is stronger than that of the binary complex PSF-(OAPB)₃-Tb(III) because of the structured difference of the chelating ring. The ternary complexes PSF-(MAPB)₃-Tb(III)-(Phen)₁ (Phen represents 1,10-phenanthroline) and PSF-(OAPB)₃-Tb(III)-(Phen)₁ have stronger fluorescence emissions than the corresponding binary complexes. The fluorescence emission intensities of solid films of the complexes are stronger than that of their solutions. The prepared luminescent polymer-Tb(III) complexes containing acetaldehyde/aminophenol type bidentate Schiff base ligands have very high quantum yields (80–86%), reflecting the high intramolecular energy transfer efficiencies from the ligands to Tb(III).     

Photoluminescent behavior of poly(3‐hexylthiophene) derivatives with a high azobenzene content in the side chains

A series of polythiophene derivatives with substantially higher azobenzene contents in the side chains were prepared via copolymerization of 3‐hexylthiophene with four different types of 4‐((4‐(phenyl)azo)phenoxy)alkyl‐3‐thienylacetate. The alkyl spacers with different lengths, i.e. butyl, hexyl, octyl and undecyl groups were used between the azobenzene group and the thiophene ring. The compositions, structures and thermal properties of these polythiophene derivatives were characterized. The structural dependence of photoluminescent emission, photochromic behavior of these copolymers were systematically studied and compared with poly(3‐hexylthiophene). The results show that the azobenzene substitution renders the polythiophene some interesting optical properties that can be modulated by UV light irradiation. In the azobenzene modified polythiophene, the intensity of photoluminescent emission associated with the conjugated polythiophene main chain was found to decrease significantly upon UV irradiation. The finding suggests that the photo‐induced trans‐cis isomerization of the azobenzene pendant groups has a significant effect on photoluminescent emission, particularly when short spacers are used between azobenzene groups and the main chain. However, the effect becomes less prominent when longer spacers are used between the azobenzene group and the main chain. Furthermore, UV irradiation of the copolymers also resulted in an increase in intensity and broadening of bandwidth for the absorption peak associated with the polythiophene backbones. Again the magnitude of intensity changes upon UV irradiation were found to be dependent on the spacer length between the azobenzene group and polythiophene main chain. Copyright © 2005 John Wiley & Sons, Ltd.     

Soluble electroluminescent poly(phenylene vinylene)s with balanced electron- and hole injections.

We report a new route for the design of efficient soluble electroluminescent PPV-based copolymers bearing electron-deficient oxadiazole (OXD) moieties on side chains. The introduction of OXD through a long alkylene spacer with PPV backbone provides a molecular dispersion of OXD in the film; both the side chain OXD and the main chain PPV do retain their own electron-transport and emissive properties, respectively. The use of phenylene vinylene derivatives with asymmetric and branched substituents and a long spacer provides solubility for ease of device fabrication as well as amorphous structure to allow a well-mixing of OXD groups with the main chains. By properly adjusting the OXD content through copolymerization, we can tailor the chemical structure of electroluminescent material to give a balance of hole- and electron injections for various metal cathodes, such that the quantum efficiency is significantly improved and the turn-on voltage is reduced for the devices with aluminum and calcium. For the device with calcium fabricated in open air, a maximum brightness of 15000 cd/m(2) at 15 V/100 nm and a maximum luminance efficiency of 2.27 cd/A can be obtained, respectively, about 30 times brighter and 9.4 times more efficient than those with the corresponding homopolymer, poly[2-methoxy-5-(2'-ethylhexyloxy)-p-phenylenevinylene] (MEH-PPV). The use of physical blends to simulate the copolymers provides no significant improvement, since phase-separation structures appear, causing an inefficient utilization of OXD and sometimes voltage-dependent emission spectra. The present route permits a fabrication of single layer PLED with high brightness, high efficiency, and low turn-on voltage.     

在聚砜侧链合成与键合双齿席夫碱配基及功能化聚砜-Tb(Ⅲ)离子配合物荧光发射性能初探

使氯甲基化聚砜(CMPSF)的氯甲基与乙醛酸(GA)的羧基发生酯化反应,将乙醛(AL)基团键合在聚砜侧链,制得改性聚砜PSF-AL;接着,又使3-氨基吡啶(AP)的伯氨基与PSF-AL的醛基发生席夫碱反应,在聚砜侧链合成与键合了具有特定结构的双齿席夫碱配基AA,从而获得了双齿席夫碱配基功能化聚砜PSF-AA,采用红外光谱(FTIR)和核磁共振氢谱(¹H NMR)等技术手段对其结构进行了表征。 以功能化聚砜PSF-AA为大分子配体,与Tb(Ⅲ)离子及Eu(Ⅲ)离子分别配位,制得了二元高分子-稀土配合物PSF-(AA)₃-Tb(Ⅲ)和PSF-(AA)₃-Eu(Ⅲ),初步探索了两种配合物的光致发光性能。 重点研究了功能化聚砜PSF-AA的制备反应,考察与分析了主要因素对CMPSF与GA之间酯化反应的影响规律,优化了反应条件。 CMPSF与GA之间的酯化反应属氯烷的亲核取代反应,实验结果表明,适宜的溶剂为极性较强的N,N-二甲基乙酰胺,75 ℃为适宜的反应温度。 大分子配体PSF-AA对Eu(Ⅲ)离子不产生敏化作用,而对Tb(Ⅲ)离子的荧光发射则产生强烈的敏化作用,配合物PSF-(AA)₃-Tb(Ⅲ)发射出较强的Tb(Ⅲ)离子的特征荧光,即表现出发射绿光的光致发光性能。     

Highly efficient and stable blue‐light‐emitting binaphthol‐fluorene copolymers: A joint experimental and theoretical study of the main‐chain chirality

In a quest for the main‐chain chiral and highly stable blue‐light‐emitting π‐conjugated polymers, a novel series of soluble conjugated random and alternating copolymers (PF‐BN) derived from fluorene and axially chiral 1,1′‐binaphthol (BINOL) were successfully synthesized by Suzuki coupling polymerization. The polymer structures, optical properties, and their electrochemical properties were investigated by ¹H NMR, TGA/DSC, UV‐Vis absorption, photoluminescence, cyclic voltammetry, circular dichroism spectroscopy, and DFT calculations. The blue‐light‐emitting BINOL‐containing copolymers with proper content of BINOL show highly efficient photoluminescence and ultra highly stable light‐emission with almost unchanged fluorescent spectra after annealing at 200 °C in air for 10 h. The joint experimental and theoretical study of the main‐chain chirality reveals that (1) the chirality of BINOL can be transferred to the polymer backbone, (2) the effective conjugation length is about one BINOL and three fluorenes, (3) the main active chiral block in the copolymers is probably composed by one BINOL with the other two or three fluorenes, and (4) the dihedral angle in the PF‐BN copolymers should be larger than 105°. The incorporation of BINOL into the polyfluorene backbone is an effective way to produce highly efficient and stable blue‐light‐emitting main‐chain chiral conjugated polymer with interesting optoelectronic properties. © 2010 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 48: 3868–3879, 2010     

含超价硫三元无机杂环化合物的理论研究(Ⅰ)

本文应用ab initio方法,研究了含超价硫化合物分子中硫原子的3d轨道的成键作用,并使用Martagh-Sargent梯度优化法,预测了该化合物的几何构型。指出硫二氮三元无机杂环中,d-pπ键在S-N间起重要作用。     

Dielectric properties of polymers based on hexafluoropropylene

Dielectric measurements have been made at frequencies from 10 Hz to 100 kHz and temperatures from 4 K to at least 300 K on a number of polymers containing units of hexafluoropropylene (HFP). These included copolymers of tetrafluoroethylene (TFE) and HFP, the homopolymer of HFP, elastomeric copolymers of HFP and vinylidene fluoride, and alternating copolymers of methyl vinyl ether with TFE and HFP. The effect of an ether linkage between the CF₃ group and the chain was also considered. Most of these polymers exhibited a main chain local mode relaxation near 228 K and a side group relaxation near 93 K.Dedicated to Professor Bernhard Wunderlich on the occasion of his 65th birthdayWe appreciate the helpful discussions with W. W. Schmiegel.