Tb（aspirin）3phen和MCM-41组装体的光谱研究

将MCM-41和客体Tb（aspirin）3phen进行组装，采用XRD、IR和PL进行了表征，探讨了主体McM-41和客体Tb（aspirin）1phen间的相互影响。MCM-41焙烧后再进行组装，Tb（aspirin）3phen可增加MCM-41的骨架有序性，充当“二次模板剂”的作用。IR谱图中，Tb（aspirin）3phen-MCM-41组装体在波数1384cm^-1处明显保留了Tb-N键的振动吸收。405nm发射峰强度，L和544nm发射峰强度，ILn的比值I，与McM-41不同的表面环境有关，且McM-41的不同表面环境对配体phen三重态和单重态能级的影响顺序为：MCM-41B外表面〉MCM-41A外表面〉McM-41A内表面。

载体MCM-41对Tb(aspirin)_3phen发光性能的影响

在室温下,乙二胺环境中合成了高度有序的介孔材料MCM-41,并将经热处理的发光客体Tb(aspi-rin)3phen组装进其孔道,通过激发发射光谱对其光致发光性能进行了研究。结果表明,Tb(aspirin)3phen240～375 nm区间的宽激发峰归属于配体aspirin羰基n→π*跃迁、苯环π→π*跃迁,和phen的杂菲基团吸收,Tb3+的特征发射是由于Antenna效应引起的。相对于纯Tb(aspirin)3phen,Tb(aspirin)3phen-MCM-41B和Tb(aspirin)3phen/MCM-41A的激发谱带出现了明显的分裂,而Tb(aspirin)3phen-MCM-41A只在353nm处剩下了相对较窄的单峰。Tb(aspirin)3phen-MCM-41B,Tb(aspirin)3phen/MCM-41A和Tb(aspirin)3phen-MCM-41A的短波段激发峰依次减弱消失,长波段激发峰逐渐增强,而405 nm发射峰强度IL和544 nm发射峰强度ILn的比值I(I=IL/ILn)依次减小。MCM-41骨架与Tb(aspirin)3phen成键后,不同程度降低了配体aspirin和phen单重态S1和三重态T1能级,且对phen的影响大于aspirin。不同的MCM-41表面晶格场对配体能级的影响顺序为:MCM-41B外表面>MCM-41A外表面>MCM-41A内表面。I值可定性表示MCM-41表面晶格场对配体能级影响程度和MCM-41表面Tb(aspirin)3phen的含量。

无机基质MCM-41掺杂Yb^(3+)对组装体中客体Tb(aspirin)_3 phen发光性能的影响

在室温下,以掺Yb3+的MCM-41作为主体,"热处理"后的Tb(aspirin)3phen作为发光客体,将其进行组装,通过XRD和N2-吸附脱附和IR对组装体的结构和物理性质进行了研究。利用激发和发射光谱分析了组装体的光致发光性能和主客体关系。采用了一种新型的掺杂方法"直接焙烧法",用以避免在试样合成中掺杂离子的损失。在Yb/MCM-41和Tb(aspirin)3phen-Yb/MCM-41的XRD谱图中同时在2θ=2.6时出现了(100)晶面衍射峰,表明试样为规则有序,六方结构的MCM-41材料。Tb(aspirin)3phen进入Yb/MCM-41孔道后,无机骨架的有序性进一步增加。相对于MCM-41,Yb/MCM-41在IR谱图中波数963cm-1的谱带减弱,表明Yb3+已经进入无机骨架。另外,波数1 384 cm-1的吸收谱带也能提供组装体Tb(as-pirin)3phen-MCM-41中成键的特征信息。PL测试结果表明,Tb(aspirin)3phen在240~375 nm区间的宽激发吸收分别归属于配体aspirin羰基n→π*跃迁,苯环π→π*跃迁和phen的杂菲基团吸收。对客体Tb(aspi-rin)3phen进行热处理,能增强Tb(aspirin)3phen在MCM-41孔道中的发光效率,并且当基质MCM-41硅骨架掺杂Yb3+后,组装体的发光强度进一步增强,当Yb/Si=7.579×10-3时,发光强度最高。

共掺杂稀土配合物Tb_(0.5)Eu_(0.5)(asprin)_3phen电致发光的研究

合成了共掺杂稀土配合物Tb0.5Eu0.5(asprin)3phen,将其掺杂到导电聚合物PVK中,制成结构为ITO PVK∶RE配合物 PBD Al的电致发光器件。与PVK∶Eu(asprin)3phen体系为发光层的相同结构的器件相比,我们发现铽离子的引入能猝灭PVK的发光,增强铕的发光,而Tb3+本身的发光很弱,几乎看不到,说明Tb3+在其中起到能量的中间传递作用,促进了PVK到Eu3+的能量传递。本文就器件的发光特性及掺杂体系的能量传递进行了初步讨论。

三元配合物Tb(Et_2dtc)_3(phen)的热化学性质

以铜试剂(NaEt2dtc·3H2O)和邻菲咯啉(o-phen·H2O)与水合氯化铽(TbCl3·3.75H2O)在无水乙醇中制得了三元固态配合物.化学分析和元素分析确定其组成为Tb(Et2dtc)3(phen).IR光谱研究表明配合物中Tb3+与NaEt2dtc中的硫原子双齿配位,同时与phen的氮原子双齿配位.用Calvet微热量计测定了298.15 K下液相生成反应的焓变△rHm (1),为(-21.819±0.055)kJ·mol-1,通过热化学循环计算了固相生成反应焓变△rHm (S),为(128.476±0.675)kJ·mol-1改变反应温度,研究了液相生成反应的热动力学.用精密转动弹热量计测得配合物的恒容燃烧能△cU为(-17646.95±8.64)kJ·mol-1,经计算其标准燃烧焓△cHm 和标准生成焓△fHm 分别为(-17666.16±8.64)kJ·mol-1和(-1084.04±9.49)kJ·mol-1.

双核双配体稀土配合物Tb_(1-x)Eu_x(TTA)_3Phen的合成及光学性能研究

合成了系列铕铽双核稀土有机稀土配合物Tb1-xEux(TTA)3Phen,通过差热-热重分析、XRD、红外光谱、紫外光谱和荧光光谱等测试手段研究了配合物的组成、结构和发光性质。由紫外可见光谱可以看出,稀土有机配合物的吸收峰主要来自有机配体HTTA和1,10-Phen;差热-热重分析证明,稀土有机配合物热稳定性较好。荧光光谱和电致发光表明,铽对铕配合物的发光有协同作用。在该系列配合物中,不仅有机配体可以将吸收的能量传递给发光的铕离子使其发光,而且铽离子也可将其吸收的能量通过分子内能量传递给铕离子,增强铕的发光强度。同时就双核稀土有机配合物光致发光和电致发光的特性及掺杂体系的能量传递过程进行了讨论。

新型无机/有机复合发光材料Eu(aspirin)_3phen-MCM-41的光学性能

在室温下,将MCM-41和热处理后的发光客体Eu(aspirin)3phen进行组装,通过XRD、N2-吸脱附和PL等表征技术对组装体进行了研究,考察其光致发光性能。结果表明:Eu(aspirin)3phen进入MCM-41孔道后,充当了'二次模板剂',使MCM-41的骨架有序性增加。经热处理后Eu(aspirin)3phen与MCM-41组装后,组装体的发光强度与相应Eu(aspi-rin)3phen粉末相当。未焙烧的MCM-41表面和稀土有机配合物成键后,Eu(aspirin)3phen分子出现反演中心,5D0→7F2跃迁明显减弱,而焙烧后MCM-41表面对Eu3+的5D0→7F2电偶极跃迁强度没有影响。

Tb(DBM)_3phen/APTES-SBA-15介孔复合体系的制备与表征

以三嵌段化合物P123为模板剂、正硅酸乙酯(TEOS)为无机硅源合成了有序介孔分子筛SBA-15.选择Tb(DBM)3phen为客体,纳米级介孔分子筛为主体,在氯仿中进行分子组装,制备具有强发光性能的超分子纳米复合材料Tb(DBM)3phen/APTES-SBA-15.采用XRD,HRTEM,N2吸附/脱附,FTIR和荧光光谱分析等对复合材料的结构与性能进行了研究.

静电纺丝技术制备Tb(BA)_3phen/PVP复合纤维与发光性质研究

采用静电纺丝技术合成Tb(BA)3phen/PVP复合纤维.扫描电镜分析表明,纤维表面光滑,无交联,直径集中分布在350nm.红外光谱分析表明,Tb3+与配体发生键合,在424cm-1出现了Tb3+-O2-特征振动峰.紫外-可见吸收光谱分析表明,Tb(BA)3phen/PVP复合物的吸收带发生蓝移.激发光谱分析表明,Tb(BA)3phen/PVP复合纤维在214-355nm之间有较宽的吸收谱带,对应着配体的π→π*跃迁,最佳吸收波长位于275nm.发射光谱分析表明,最强发射峰位于545nm处,对应着Tb3+的5 D4→7F5跃迁.

Syntheses and Characterization of Binuclear Complexes Tb_(1-x)Eu_x(TTA)_3 Phen

Rare earth ternary complexes Tb1-xEux（TTA）3Phen（x=0,0.25,0.5,0.75,1.0）were synthesized and characterized by DTA-TG,XRD and infrared（IR）.The photophysical properties of these complexes were studied in detail using ultraviolet absorption spectra and fluorescent spectra.Ultraviolet absorption showed that the energy absorption of the complexes mostly came from ligands.Infrared spectra of Tb1-xEux（TTA）3Phen complexes were similar to the pure complexes.TG curves proved that the complexes were stable.Tb3＋ emission was almost quenched and the Eu3＋ emission was enhanced by codoping the complexes.The Tb3＋ ion acted as an energy transfer bridge that helped energy transfer from poly（N-vinylcar-bazole（PVK）to Eu3＋.In addition,their PL and EL properties were systematically studied.

Doped Organic Electroluminescence from a Novel Rare Earth Complex Tb(3-metho)_3phen

A novel rare earth complex Tb(3 metho) 3phen was synthesized and characterized. The complex was doped into PVK to improve the conductivity and film forming property of Tb(3 metho) 3phen. A device with a structure of ITO/PVK∶Tb(3 metho) 3phen /Al was fabricated to study the electroluminescent properties of Tb(3 metho) 3phen. And the optoluminescent and AFM properties of this device were also studied, which proved the existence of energy transfer from PVK to Tb(3 metho) 3phen. As a result, a pure green emission with sharp spectral band at 547.5 nm was observed.

Fluorescence of Tb-Ibuprofenum-Phen Complex and New Tissue Staining Method

A new complex Tb(IB)_3(phen)·2H_2O that gives off green fluorescence was synthesized. The results show that the strong fluorescence emitting of 490 and 545 nm for Tb 3+ in the Tb(IB)_3(phen)·2H_2O complex is related to the transitions 5D_4-7F_6 and 5D_4-7F_5, respectively. The results indicate that the complex is concentrated on the nuclei regions in the section of onion toot tip tissues and the nuclei are high lighted under fluorescent microscope. It is possible that the Tb(IB)_3(phen)·2H_2O complex can be developed as a fluorescent dye in biological and pathological studies.

Tb(Ⅲ)-氨基多膦酸-邻菲咯啉三元配合物的溶液荧光

The fluorescence of two Tb 3+ aminopolyphosphonic (L 1) acid Phen triple complex (L 1=ethylenediaminetetrakis (methylphosphonic) (EDTP) and ethylaminobis (methylphosphonic) (EDP)) in solution was reported.It was found that fluorescence of Tb L 1 Phen solution apparently increased as compared with that of Tb Phen complex,indicating that Tb L 1 Phen triple complex was formed.The fluorescence was strongest at pH 7.0.Fluorescence for both L 1=EDTP and EDP increase with addition of L 1 and Phen,but excess of ligands did not affect the fluorescence,thus indicating there is cooperation effect between L 1 and Phen.The change of the fluorescence among different complex was also explained according to the enhancing or quenching effect of ligands.

静电纺丝技术制备Tb(BA)_3phen/PANI/PVP光电双功能复合纳米纤维

采用静电纺丝技术将聚苯胺(PANI)和稀土配合物[Tb(BA)3phen]掺杂到高分子材料(PVP)中,制备出一类新型的具有光电双功能的Tb(BA)3phen/PANI/PVP复合纳米纤维.用扫描电子显微镜(SEM)、X射线能量色散谱仪(EDS)、荧光光谱仪及宽频介电松弛谱仪对样品进行了表征.结果表明,复合纳米纤维直径为(331±43)nm.在276 nm紫外光激发下,Tb(BA)3phen/PANI/PVP复合纳米纤维发射出主峰位于491,547和585 nm的绿光,对应Tb3+的5D4→7F6,5D4→7F5和5D4→7F4跃迁.当Tb(BA)3phen∶PANI∶PVP的质量比为15∶10∶100时,复合纳米纤维的荧光发射最强,其电导率随PANI含量的增大而升高,在PANI∶PVP为50%(wt%)时,其电导率在高频(106Hz)下达1.531×10-6S/cm.

稀土有机电致发光器件

我们研制了用有机材料Tb(AcA)_3·phen作为发射层的绿色发光二极管,两层结构为玻璃衬底ITO/芳香族二胺类衍生物TPD/Tb(AcA)_3·phen/A1。各功能层均用真空热蒸发的方法制备。在正向直流偏压驱动下获得了Tb^(3+)的特征发光,同时还发现一个峰位425um的蓝光发射,它来源于空穴输运层TPD。在室温条件下器件的阈值电压为4V,当驱动电压提高到16V时,器件的最高发光亮度达到200cd/m^2,同时在相同条件下制备了结构为玻璃衬底ITO/芳香族二胺类衍生物TPB/Tb(AcA)_3·phen/A1的器件,通过对两种器件光谱及电学特性的测量、比较与分析,探讨了有关稀土有机电致发光的发光机理等问题。