铕(Ⅲ)/镝(Ⅲ)苯并咪唑-5,6-二羧酸配位聚合物的合成和晶体结构

水热法合成了配合物{[Ln(Hbmdc)(bmdc)(H2O)3].3H2O}n(Ln=Eu,1;Dy,2;H2bmdc=苯并咪唑-5,6-二羧酸),用X-射线单晶衍射分析确定了配合物的晶体结构。配合物为单斜晶系,P21/c空间群。配合物1和2具有相似的一维链状结构。配体H2bmdc以2种不同的类型与Ln3+离子配位:完全去质子化的bmdc配体和咪唑环上的氮原子被质子化的Hbmdc配体。bmdc配体的2个羧基采取双齿螯合/双齿螯合方式配位;Hbmdc配体的1个羧基采取双齿螯合方式配位,另1个羧基未参与配位。每个Ln3+离子与6个羧基氧原子和3个水分子中氧原子配位,形成9配位的扭曲单帽四方反棱柱体。相邻的Ln3+离子通过bmdc配体桥联形成螺旋链状结构。链和链之间通过π-π堆积和氢键进一步连接成三维超分子结构。配合物1和2分别显示Eu3+和Dy3+离子的特征荧光。     

利用稀土位移探针对水溶液中L-精氨酸构象的~(13)C-NMR研究

采用重稀土离子(Dy、Ho、Er、Tm、Yb)研究了水溶液中L-精氨酸的构象。结果表明,距稀土配位中心4个或4个键以上的配体核的接触位移都很小,在稀土离子附近的配体核具有显著的接触位移。通过对配体磁性核结构因子的实验值进行模拟,建立了水溶液中L-精氨酸的整体构象。在L-精氨酸稀土配合物中,配体的羧基与稀土离子配位,配体的骨架结构位于稀土离子的零偶极位移锥面的外侧。对于羧基的双齿配位模式,计算得到的RE~(3+)-O键长为0.21nm。在溶液中配体以伸展状态存在,分子骨架呈全反式构象。     

稀土环己烷酸配合物合成及振动光谱研究

稀土羧酸配合物中,羧基配位方式是个有兴趣的问题。羧基采取单配位、螯合配位、对称桥式配位或单原子桥式(或螯合桥式)配位的那些方式,不但与稀土离子和羧酸结构,而且与配合物制备条件有关。不少研究发现某些配合物中,羧基可以同时存在多种配位方式。用振动光谱研究羧基的配位方式和配合物结构已引起广泛兴趣。环已烷酸(以下用HL和L分别代表酸及其阴离子)与稀土的配合物研究尚少,我们合成了它的十六种稀土的1∶3无水配合物,通过红外和拉曼光谱研究了羧基在各稀土配合物中的配合方式,配位多面体结构及配位键性质。     

谷胱甘肽与衡土离子作用的13^C NMR研究

本文利用顺磁稀土离子的诱导化学位移变化的性质, 研究了多官能团配体谷胱甘肽(GSH)与稀土的配位作用。在水溶液中GSH通过分子两端的羧基负离子与稀土形成遥爪配位结构。谷氨酸和甘氨酸羧基与Eu^3+的配位稳定常数分别为12.5±0.1L.mol和100.0±0.5L/mol。从13^C化学位移的pH变化曲线求得谷氨酸和甘氨酸羧基解离的pK~a值分别为2.20±0.02和3.50±0.04。对Dy^3+、Ho^3+、Er^3+、Tm^3+和Yb^3+作用下, GSH的13^C位移数据分析表明, 配体与这些离子形成同构的配合物, 分子两端羧基均可能以双齿形式与稀土配位。     

谷胱甘肽与衡土离子作用的13^C NMR研究

本文利用顺磁稀土离子的诱导化学位移变化的性质, 研究了多官能团配体谷胱甘肽(GSH)与稀土的配位作用。在水溶液中GSH通过分子两端的羧基负离子与稀土形成遥爪配位结构。谷氨酸和甘氨酸羧基与Eu^3+的配位稳定常数分别为12.5±0.1L.mol和100.0±0.5L/mol。从13^C化学位移的pH变化曲线求得谷氨酸和甘氨酸羧基解离的pK~a值分别为2.20±0.02和3.50±0.04。对Dy^3+、Ho^3+、Er^3+、Tm^3+和Yb^3+作用下, GSH的13^C位移数据分析表明, 配体与这些离子形成同构的配合物, 分子两端羧基均可能以双齿形式与稀土配位。     

N,N-二(2-羧基苯基)-2,6-吡啶二甲酰胺铕配合物的合成及光谱分析

合成了N,N-二(2-羧基苯基)-2,6-吡啶二甲酰胺(简称BCPD)铕配合物,通过元素分析、电导率测定、红外光谱及紫外光谱对其进行了结构表征。结果表明:标题配合物中稀土离子与配体以1∶1的方式结合,化学组成符合C23H21N3O8ClEu,并进一步探讨了配合物配位方式。固体荧光及荧光滴定光谱分析表明:配体与稀土离子间存在明显的"天线效应",铕离子在590,617 nm处的特征荧光敏化效果显著,因此该配合物有望成为理想的光致发光材料。     

钆-邻氟苯甲酸-邻菲咯啉配合物的合成、晶体结构

由于有机羧酸化合物具有多种配位方式,以此为配体的稀土羧酸配合物具有多种多样的晶体结构。这类配合物有单核分子、双核分子和高聚物,可形成1D、2D、3D等多种结构。而且由于这类配合物在萃取分离、催化和发光材料等方面的潜在应用一直受到学者们的广泛研究。稀土与苯甲酸及其衍生物和1,10-邻菲咯啉的混合配体配合物已有很多报道[1￣6]。文献[1,2]报道了在同一个配合物的结构单元中存在两个晶体学不等同的双核分子,是由于羧基桥联方式不同而导致的。其中一个分子的两个中心离子通过4个苯甲酸的羧基桥联,另一个只有2个羧基桥联。我们合成了…     

三个喹啉氧基乙酰胺镧系(Eu、Gd、Er)配合物的合成、结构及Eu配合物的荧光性质（英文）

合成并通过单晶衍射表征了3个稀土配合物Ln(L)(NO3)3(H2O)(L=N-苯基-2-(5-氯-8-喹啉氧基)乙酰胺,Ln=Eu(1),Gd(2),Er(3)),结构与拥有相同有机配体的Pr,Nd和Sm配合物同构。在每个配合物中,十配位的稀土离子采取扭曲的双帽四方反棱柱配位构型,分别与来自1个配体L的2个氧原子和1个氮原子,3个双齿配位硝酸根和1个水分子配位。配合物1能够发射Eu(Ⅲ)离子特征荧光,荧光寿命为437μs。     

NH_4[RE(Ac)_4·H_2O]发光稀土配合物的研究

以乙酸和乙酸铵为配体,合成了新颖发光稀土配合物,通过元素分析、红外光谱、热重分析等手段对配合物进行了表征,确定其结构为NH4[RE(Ac)4.H2O](RE=Tb或Eu).结果表明,配合物中羧基以螯合、双齿和单齿方式与稀土离子配位;并通过荧光光谱分析、荧光寿命研究了其发光性能,配合物能发射强的稀土离子的特征荧光且有较长的荧光寿命.     

镧系元素(La、Tb、Dy)的喹啉氧基乙酰胺配合物的结构及荧光性质（英文）

合成并通过单晶衍射表征了3个稀土配合物[La L2(NO_3)_3]·CH3CN(1),[Ln(L)(NO_3)_3(H_2O)](Ln=Tb(2),Dy(3),L=N-苯基-2-(5-氯-8-喹啉氧基)乙酰胺)。在配合物1中,十二配位的La(Ⅲ)离子采取扭曲的二十面体配位构型,分别与来自2个酰胺配体L的4个氧原子和2个氮原子,及3个双齿配位硝酸根配位。配合物2和3的结构与拥有相同有机配体的Pr、Nd、Sm、Eu、Gd和Er配合物同构。在每个配合物中,十配位的稀土离子与来自1个配体L的2个氧原子和1个氮原子,3个双齿配位硝酸根和1个水分子配位,拥有扭曲的双帽四方反棱柱配位构型。固态配合物2和3在可见区发射强荧光。     

稀土离子配合物与磷脂双分子膜的作用研究

利用一维和二维Ｈ核磁共振方法研究了柠檬酸稀土、稀土－ＤＴＰＡ配合物与磷脂双分子膜的作用，结果表明Ｌ在近生理条件下（ＰＨ＝７．４）及 柠檬酸配体的磷脂双分子膜体系中，稀土离子首先与柠檬酸体作用，形成的配合物对磷脂双分子膜的结构影响较小，稀土－ＤＴＰＡ配合物对磷脂双分子膜的结构没有影响这些结果为科学地评价稀土离子进行体内的毒性提供了实验依据。     

稀土离子及其配合物对二棕榈酰磷脂酰乙醇胺酯双层结构的影响

随着稀土在工农业和医疗保健上的广泛应用，稀土的生物无机化学研究受到了普遍的关注．以往的研究多集中在稀土离子的宏观毒理学[1]，而研究稀土离子与生物膜的作用较少[2]．稀土的生物小分子配体的配合物与生物膜作用的研究则未见报道．本文介绍了用拉曼光谱研究稀土离子及其柠檬酸、二乙三胺五乙酸（DTPA）配合物对二栋相酸乙醇胺（DPPE）脂双层的流动性以及碳氢链的构象转变和晶格有序性排列的影响．1实验部分DPPE系Sigma公司产品。La2O3（99．9％）为跃龙化工厂产品，柠檬酸、DTPA为北京化工厂产品．L3Cl3溶液由L32O3溶于盐酸…     

Isolations and characterization of highly water-soluble dimeric lanthanide citrate and malate with ethylenediaminetetraacetate

Highly water-soluble lanthanum and cerium citrates or malates with ethylenediaminetetraacetate (NH(4))(8)[Ln(2)(Hcit)(2)(EDTA)(2)]·9H(2)O [Ln = La, 1; Ce, 2], K(8)[La(2)(Hcit)(2)(EDTA)(2)]·16H(2)O (3) and K(6)[Ln(2)(Hmal)(2)(EDTA)(2)]·14H(2)O [Ln = La, 4; Ce, 5] (H(4)cit = citric acid, H(3)mal = malic acid, and H(4)EDTA = ethylenediaminetetracetic acid) were prepared from the reactions of lanthanide ethylenediaminetetraacetate trihydrates with citric or malic acid at pH 5.0-6.5. These compounds were characterized by elemental analyses, IR, TG-DTG, solution (13)C{(1)H} NMR, solid state (13)C NMR spectra and X-ray structural analyses. The main structural feature of the compounds consists of a dinuclear unit deca-coordinated by EDTA and citrate or malate. The α-hydroxy and α-carboxy groups of citrate and malate chelate in five-membered ring with one lanthanide ion, while one of the β-carboxy group coordinates with the other lanthanide ion, forming a dimeric structure. The other pendent β-carboxy groups in 1-3 form very strong intramolecular hydrogen bond with α-hydroxy groups [O1O7 2.594(4), 2.587(8) and 2.57(1) ? for 1-3 respectively]. (13)C NMR spectra of the lanthanum compounds show obvious downfield shifts based on solid and solution NMR measurements, indicating the coordinations of mixed-ligand in lanthanum complexes, while highfield shifts are observed in cerium complexes.     

Synthesis and structural properties of lanthanide complexes formed with tropolonate ligands

We have previously reported the unique luminescence properties of ML4 complexes formed between tropolonate ligands and a series of lanthanide cations, several of them emitting in the near-infrared domain. The synthesis and composition of ML4 lanthanide tropolonate complexes have been previously described in the literature, but no structural information has been available so far. In this work, the crystal structures of several lanthanide tropolonate complexes (Ln3+ = Tb3+, Dy3+, Ho3+, Er3+, Tm3+, Yb3+, Lu3+) have been isolated and systematically analyzed by X-ray diffraction and compared by using different criteria including the Kepert formalism. Such comparative work is rare in lanthanide coordination chemistry. The analysis of the structures in the solid state reveals that although the packing of the ML4 complexes depends on the nature of the metal ion, the coordination geometries around the different lanthanides is virtually similar for all the cations that have been analyzed; an indication that lanthanide-centered f orbitals play a role in controlling this coordination geometry. Analysis of the solution's behavior by stability constant determination reveals the formation of complexes with similar ML4 stoichiometries as those observed in the solid state. Nevertheless, analysis of the luminescence lifetimes indicates that the coordination environment around the lanthanide cations are different in the solid state and in solution, with the presence of one molecule of water bound to the lanthanide cation in solution. The presence of such a water molecule is a significant source of nonradiative deactivation of the excited states of the lanthanide cations, an unfavorable condition that leads to significant loss in fluorescence intensity of these lanthanide complexes. This exemplifies that such comparative analysis between the solid state and solution is important for the rationalization of the luminescence properties of the complexes. This analysis will aid us in optimizing ligand design for improved photophysical properties of the complex.     

Eu(III) and Tb(III) complexes of 1,3-bis(4-chlorophenyl)-1,3-propanedione combined with phenanthroline ligand: synthesis,structural characterization,and thermogravimetric studies

β-Diketone lanthanide complexes are used mainly in lighting, telecommunication, screens, safety inks, and marking as well as in the field of luminescent materials for probes in biosciences. Two new lanthanide ternary complexes, the general formula Eu(BCPP)₃(Phen) and Tb(BCPP)₃(Phen), combined 1,3-bis(4-chlorophenyl)-1,3-propanedione (BCPP) with 1,10-phenanthroline as a secondary ligand, were synthesized and structurally characterized by single crystal X-ray diffraction, elemental analysis, FT-IR, and MALDI-TOF MS. Single crystal X-ray diffraction analysis revealed that these Eu(III) and Tb(III) complexes displayed bidentate ligands and a square antiprism geometry for the metal center. Also, the absorption and thermal behavior of these lanthanide complexes were investigated. When the maximum absorption of the lanthanide complexes was compared, it was observed that the absorption wavelength of the lanthanide complexes were red shifted in DMSO, DMF, and DCM, depending on the polarity of the solvent.     

DNA-binding properties and antioxidant activity of lanthanide complexes with the Schiff base derived from 3-carbaldehyde chromone and isonicotinyl hydrazine

Structural analyses indicate that the ligand and lanthanide ions form mononuclear 10-coordinate ([Ln L₂ · (NO₃)₂] · NO₃ [Ln(III) = La, Sm, Nd, and Yb; L is chromone-3-carbaldehyde-(isonicotinoyl) hydrazone) complexes with 1 : 2 metal-to-ligand stoichiometry. DNA-binding studies show that the ligand and its lanthanide complexes can bind to calf thymus DNA via an intercalation mode with binding constants of 10⁵ (mol L^?1)^?1, and the lanthanide complexes bind stronger than the free ligand alone. Antioxidant activities of the ligand and lanthanide complexes were determined by superoxide and hydroxyl radical scavenging methods in vitro. The ligand and complexes possess strong scavenging effects, and the lanthanide complexes show stronger antioxidant activities than the ligand and some standard antioxidants, such as vitamin C.     

Kinetics of Ga(NOTA) formation from weak Ga-citrate complexes

Gallium complexes are gaining increasing importance in biomedical imaging thanks to the practical advantages of the (68)Ga isotope in Positron Emission Tomography (PET) applications. (68)Ga has a short half-time (t(1/2) = 68 min); thus the (68)Ga complexes have to be prepared in a limited time frame. The acceleration of the formation reaction of gallium complexes with macrocyclic ligands for application in PET imaging represents a significant coordination chemistry challenge. Here we report a detailed kinetic study of the formation reaction of the highly stable Ga(NOTA) from the weak citrate complex (H(3)NOTA = 1,4,7-triazacyclononane-1,4,7- triacetic acid). The transmetalation has been studied using (71)Ga NMR over a large pH range (pH = 2.01-6.00). The formation of Ga(NOTA) is a two-step process. First, a monoprotonated intermediate containing coordinated citrate, GaHNOTA(citrate)*, forms in a rapid equilibrium step. The rate-determining step of the reaction is the deprotonation and slow rearrangement of the intermediate accompanied by the citrate release. The observed reaction rate shows an unusual pH dependency with a minimum at pH 5.17. In contrast to the typical formation reactions of poly(amino carboxylate) complexes, the Ga(NOTA) formation from the weak citrate complex becomes considerably faster with increasing proton concentration below pH 5.17. We explain this unexpected tendency by the role of protons in the decomposition of the GaHNOTA(citrate)* intermediate which proceeds via the protonation of the coordinated citrate ion and its subsequent decoordination to yield the final product Ga(NOTA). The stability constant of this intermediate, log K(GaHNOTA(citrate)*) = 15.6, is remarkably high compared to the corresponding values reported for the formation of macrocyclic lanthanide(III)-poly(amino carboxylates). These kinetic data do not only give mechanistic insight into the formation reaction of Ga(NOTA), but might also contribute to establish optimal experimental conditions for the rapid preparation of Ga(NOTA)-based radiopharmaceuticals for PET applications.     

Self-assembly of luminescent ternary complexes between seven-coordinate lanthanide(III) complexes and chromophore bearing carboxylates and phosphonates

Luminescent lanthanide complexes have been prepared by exploiting the interaction between lanthanide DO3A complexes and chromophore bearing carboxylates or phosphonates. This interaction can be utilised to probe the choice of sensitising chromophore suited to a given lanthanide. Furthermore, ternary complexes obtained from chromophore appended carboxylates dissociate in the presence of phosphate, while those obtained from phosphonates do not.     

Azulene-moiety-based ligand for the efficient sensitization of four near-infrared luminescent lanthanide cations: Nd3+, Er3+, Tm3+, and Yb3+

The ML(4) complexes formed by reaction between the bidentate azulene-based ligand diethyl 2-hydroxyazulene-1,3-dicarboxylate (HAz) and several lanthanide cations (Pr(3+), Nd(3+), Gd(3+), Ho(3+), Er(3+), Tm(3+), Yb(3+), and Lu(3+)) have been synthesized and characterized by elemental analysis, FT-IR vibrational spectroscopy and electrospray ionization mass spectroscopy. Spectrophotometric titrations have revealed that four Az(-) ligands react with one lanthanide cation to form the ML(4) complex in solution. Studies of the luminescence properties of these ML(4) complexes demonstrated that Az(-) is an efficient sensitizer for four different near-infrared emitting lanthanide cations (Nd(3+), Er(3+), Tm(3+), and Yb(3+)); the resulting complexes have high quantum yield values in CH(3)CN. The near-infrared emission arising from Tm(3+) is especially interesting for biologic imaging and bioanalytical applications since biological systems have minimal interaction with photons at this wavelength. Hydration numbers, representing the number of water molecules bound to the lanthanide cations, were obtained through luminescence lifetime measurements and indicated that no molecules of water/solvent are bound to the lanthanide cation in the ML(4) complex in solution. The four coordinated ligands protect well the central luminescent lanthanide cation against non-radiative deactivation from solvent molecules.     

稀土有机配合物电致发光研究进展

稀土配合物发射带窄, 发射光谱具有类原子光谱性质, 色纯度高(半宽峰<10 nm), 非常适合于全彩色显示. 另外, 稀土配合物发光效率高, 理论上内量子效率可达100%. 因此, 稀土配合物是全色平板显示器件中理想的发光材料之一, 研究稀土配合物电致发光性质具有重要的实际意义和理论意义. 以稀土镧系离子配合物作为发光中心的电致发光器件的研究主要集中于发光效率比较高的Eu3+, Tb3+ 以及近红外的Nd3+, Yb3+和Er3+ 离子. 分类综述了近年稀土配合物电致发光研究的成果及其进展. 总结了不同类型的铕配合物、铽配合物的电致发光特性, 证明配体对于稀土离子的敏化作用非常重要; 总结了近红外的镱、钕、铒配合物在光放大、激光技术、生物医学等方面的潜在应用价值.