卤代芳香族羧酸与含氮配体合成镧系配合物的结构、热化学和荧光性质（英文）

采用室温溶液挥发法合成了五种结构新颖的镧系配合物,其结构通式为[Ln(2,4-DFBA)₃(phen)]₂ (Ln=Sm 1, Eu2, Er 3, 2,4-DFBA为2,4二氟苯甲酸的简写,phen为1,10-菲啰啉的简写),[Ln(2-Cl-6-FBA)₂(terpy)(NO₃)(H₂O)]₂ (Ln=Tb4, Dy 5, 2-Cl-6-FBA为2-氯-6-氟苯甲酸的简写, terpy为2,2’:6’2’’-三联吡啶的简写)。五个配合物可以分为两个系列,使用不同的镧系离子作为中心离子。通过X射线单晶分析,5种配合物均属于单斜晶系,空间群为P21/n。配合物1,2和配合物3虽然具有相同的分子通式,但配位方式明显不同,形成了前者为9配位的松饼型,后者是8配位的双帽三棱柱几何构型。二维面状超分子结构的形成方式也明显不同,区别在于配合物1和2通过微弱的π-π堆积作用形成。配合物4和5是同构的,结构中引入了硝酸根离子较为有趣,通过C―H···F氢键和π-π堆积作...     

多齿席夫碱配体构筑的Ln2Ⅲ配合物的晶体结构及磁性

使用多齿席夫碱配体,通过溶剂热法,设计与合成了3例新的稀土配合物[Ln₂(L)₂(acac)₂(CH₃OH)₂]·2CH₃OH(Ln=Sm(1)、Gd(2)、Ho(3),H₂L=吡啶?2?羧酸?(1?甲基?3?氧代丁烯基)?酰肼),并对配合物1~3的结构与磁性质进行了系统的研究。单晶结构测试结果表明配合物1~3为同构,每个中心稀土Ln(Ⅲ)离子为八配位,其配位几何构型为扭曲的四方反棱柱;相邻的中心稀土Ln??离子通过2个μ₂?O连接形成了平行四边形的[Ln₂O₂]核心。磁性测试揭示配合物2具有磁制冷性质,其最大磁熵变(-ΔS_max)为31.9 J·K^-1·kg^-1(T=2.0 K,ΔH=70 kOe);配合物3表现出了慢磁驰豫行为。     

基于席夫碱配体构筑的LnⅢ2配合物的结构、荧光性质及生物活性

以多齿席夫碱配体H₂L(H₂L=(E)-N′-(3-乙氧基-2-羟基亚苄基)-3-羟基吡啶甲酰肼)为配体,与Ln(acac)₃·2H₂O(Ln=Tb、Ho、Er;acac^-=乙酰丙酮根)反应,通过溶剂热法,成功得到了3例新的双核稀土配合物[Ln₂(acac)₂(L)₂(C₂H₅OH)₂](Ln=Tb((1)、Ho((2)、Er(3))。单晶X射线衍射分析表明：配合物1～3的结构主要由2个Ln^Ⅲ离子、2个乙酰丙酮根(acac^-)、2个L^2-及2个C₂H₅OH组成,中心Ln^Ⅲ离子通过2个μ₂-O原子相互连接,形成一个平行四边形的Ln₂O₂核心。固体荧光实验测...     

基于2，5-二溴对苯二甲酸配体的锰/钴配合物的合成、晶体结构及性质

将有机物2,5-二溴对苯二甲酸(H₂L₁)作为主配体,2,2′-联吡啶(L₂)、1,10-菲咯啉(L₃)分别作为辅配体,通过溶剂热法与一水硫酸锰、六水合硝酸钴分别反应得到配合物[Mn₂(L₁)₂(L₂)₂(H₂O)₂]_n (1)和[Co₂(L₁)₂(L₃)₂(H₂O)₂]_n(2)。通过单晶X射线衍射法、荧光光谱、热重分析等测试手段对这2种配合物进行分析研究。结果表明配合物1是由Mn²⁺配位连接L₁^2-与L₂形成无限延伸的二维网络状结构,各层在分子间氢键和π-π堆积作用...     

系列Ln(Ⅲ)配位聚合物(Ln=Eu,Sm,Tb,Pr,Gd)的合成及其荧光分析

采用水热法合成了4个具有1D结构的Ln(Ⅲ)配位聚合物,[Eu₂(C₉H₇O₂)₆(C₉H₇O₂H)(C₂H₅OH)]n(1)、[Sm(C₉H₇O₂)₃]n(2)、[Tb(C₉H₇O₂)₃]n(3)和[Gd(C₉H₇O₂)₃]n(4)(C₉H₈O₂=肉桂酸)。 通过X射线单晶衍射确定了它们的结构。 这4个Ln(Ⅲ)配合物中,Ln(Ⅲ)的配位数均为9,桥配体均为肉桂酸根,但其配位方式有差异。 对配合物进行了IR、UV-Vis-NIR和荧光光谱等表征。 分析了各配合物的荧光发射,结果表明,在可见区,配合物1发射较明显的红光,配合物2、3发射绿光,配合物4发射蓝光,但很弱。 讨论了具有刚柔相混杂性质的肉桂酸配体对配位聚合物的构筑及稀土离子发光的影响。     

配合物[Eu(4-MOBA)3(terpy)(H2O)]2的合成、表征、热分解机理及性质

合成了一个新的配合物[Eu(4-MOBA)₃(terpy)(H₂O)]₂ (4-MOBA:4-甲氧基苯甲酸根, terpy:2, 2':6', 2"-三联吡啶)。采用傅里叶变换红外(FTIR)光谱、元素分析和X射线粉末衍射(XRD)技术对标题配合物进行了表征,用X射线单晶衍射仪测定了配合物的晶体结构,在配合物中每个Eu³⁺离子与一个三联吡啶分子、一个水分子和三个羧酸分子结合,配位数为9,羧酸基团的配位模式包含三种:双齿螯合,桥连双齿,单齿。根据热重-差示扫描量热/傅里叶变换红外(TG-DSC/FTIR)联用技术,研究了配合物的热分解机理。配合物的发射光谱显示出Eu³⁺离子的特征荧光发射,表明三联吡啶和4-甲氧基苯甲酸在该体系中可作为敏化集团。另外,文中还讨论了配合物对白色念珠菌和大肠杆菌的抑菌活性。     

基于锌(Ⅱ)Schiff碱构筑模块和6-羧基吡啶-2-甲醇的3d-4f异金属四核簇合物的荧光和磁弛豫性质

用溶剂热方法合成了2个新的3d-4f异金属四核簇合物：[Zn₂Ln₂（salen）₂（CO₂PyCH₂O）₂（MeOH）2]（ClO₄）₂·2MeOH（Ln=Dy（1）,Tb（2）;H₂salen=N,N'-双（3-甲氧基水杨基）-1,3-二氨基丙烷;HCO₂PyCH₂OH=6-羧基吡啶-2-甲醇）。它们是由锌（Ⅱ）Schiff碱构筑模块和6-羧基吡啶-2-甲醇辅助配体组装而成的Zn-Ln₂-Zn型簇合物。磁性测量表明稀土离子间存在铁磁性相互作用。Zn₂Dy₂配合物1在2 000 Oe直流磁场下显示出磁弛豫行为;而Zn₂Tb₂配合物2不但有磁场导致的磁弛豫行为,而且还具有荧光性质。     

3-((4，6-二甲基-2-嘧啶基)硫代)-丙酸和菲咯啉三元稀土配合物的晶体结构和发光性能

制备了以3-((4,6-二甲基-2-嘧啶基)硫代)-丙酸(HL)和菲咯啉(Phen)为配体的2个三元稀土配合物[Eu(L)₃(Phen)]₂·2H₂O(1)和[Tb(L)₃(Phen)]₂·2H₂O(2),并对其结构进行了表征。单晶X射线衍射分析表明它们是同构的。2个稀土离子(Ln)由4个羧酸配体桥接,形成二聚体排列。其余2个羧酸配体和Phen以双齿螯合方式与Ln配位。Ln的配位数为9,具有扭曲的单端方形反棱柱配位多面体构型。固态光致发光测试表明,这2种配合物都显示了金属中心的特征发射带。     

一系列基于杂多酸构筑的配合物的合成,晶体结构及光催化性能

通过引入菲咯啉衍生物配体并改变反应体系中的金属盐,得到了3个新的含有杂多酸的金属-有机配合物（MOCs）,{[Cu₂（Do）₂（H₂O）₄(SiW₁₂O₄₀)]·10H₂O}_n（1）,[Ag₃（Do）₅][Ag（Do）₂](SiW₁₂O₄₀)（2）,[Cu₂（Do）₄（H₂O）₂Cl](PMo₁₂O₄₄)·2CH₃OH（3）（Do=1,10-菲咯啉-5,6-二酮）。在配合物1中,Keggin型杂多酸与Cu（Ⅱ）连接形成了二维网状结构。配合物2中的Ag（Ⅰ）显示了多种不同的配位模式,构建了一个新颖的线性三核簇状结构。在配合物3中,Cu（Ⅱ）通过氯原子连接形成了一个双核结构。结构多样性表明金属离子与第二配体Do在构建不同结构的POMs中起到很重要的作用。光催化研究表明,配合物3不仅能在UV光照射下有效地催化降解罗丹明B（RhB）,而且很稳定,能够从反应体系中分离以循环利用。     

4,5-二氮芴-9-酮Cu(Ⅱ),Zn(Ⅱ)配合物的合成、晶体结构、热分析及理论计算

合成了4,5-二氮芴-9-酮(dafo)的Cu(Ⅱ), Zn(Ⅱ)配合物[Cu(dafo)₂(H₂O)₂] (NO₃)₂和[Zn(dafo)₂ (H₂O)₂] (NO₃)₂,通过单晶X射线衍射法确定了它们的结构.晶体结构分析表明,配合物分子中Cu(Ⅱ), Zn(Ⅱ)分别和来自两配体的四个氮原子及两个水分子中的氧原子配位,处于六配位的配位环境中,两配体基本处于同一平面,两水分子垂直于两配体所在平面,Cu(Ⅱ)处于畸变八面体中心,Zn(Ⅱ) 处于正常八面体中心,对两种配合物进行了元素分析、红外和热分析表征,在实验的基础上,采用Gaussian-98w中的DFT-B3LYP/LANL2DZ对两种配合物进行了全几何优化以及后续计算.     

Synthesis,Spectroscopic, Thermochemical Properties of Lanthanide Complexes with 3,4-Diethoxybenzoic Acid and 1,10-Phenanthroline

Three novel lanthanide complexes [Ln(3,4-DEOBA)₃phen]₂[Ln=Eu(1), Tb(2), Dy(3); 3,4-DEOBA=3,4- diethoxybenzoate; phen=1,10-phenanthroline] were synthesized and characterized by elemental analysis, molar conductance, X-ray diffraction and infrared spectrometry. The luminescence spectra of complexes 1 and 2 show the characteristic emission of Eu³⁺ ion(⁵D₀→⁷F_0-3) and Tb³⁺ ion(⁵D₄→⁷F_6-3). The thermal decomposition mechanism of the title complexes and the analysis of the evolved gases were investigated by thermogravimetry/differential scanning calorimetry-Fourier transform infrared(TG/DSC-FTIR) technology. The results indicate the complexes are thermally stable. In the thermal decomposition of the complexes, phen molecules lost firstly, and then 3,4-DEOBA ligand decomposed into H₂O, CO₂ and other gaseous molecules. Besides, several gaseous organic fragments were also detected. The heat capacities of complexes 1―3 were measured by DSC in a temperature range of 263.15―340.15 K. Based on the fitted polynomial and thermodynamic equations, the smoothed heat capacities and thermodynamic functions of the three complexes were calculated. The study on biological activity showed that the complexes exhibited good antibacterial activity against Candida albicans, Staphylococcus aureus and Escherichia coli.     

稀土冠醚络合物的研究(Ⅲ)——轻稀土及钇的硝酸盐与2,3,11,12-四苯基-1,4,7,10,13,16-六氧-2,11-十八环二烯的络合物的合成及性质的研究

由三价轻稀土、钇(Ⅲ)和铈(Ⅳ)的硝酸盐分别与2,3,11,12-四苯基-1,4,7,10,13,16-六氧-2,11-十八环二烯反应,合成了相应的六种固体络合物,並进行了元素分析,IR、NMR、TG、DTA、电导及溶解度等性质的研究。     

2, 4, 6-三甲基苯甲酸与5, 5'-二甲基-2, 2'-联吡啶构筑的系列镧系超分子配合物的晶体结构、热分解机理和性能

Six ternary lanthanide complexes formulated as [Ln(2, 4, 6-TMBA)₃(5, 5'-DM-2, 2'-bipy)]₂ (Ln = Pr 1, Nd 2, Sm 3, Eu 4, Gd 5, Dy 6; 2, 4, 6-TMBA = 2, 4, 6-trimethylbenzoate; 5, 5'-DM-2, 2'-bipy = 5, 5'-dimethyl-2, 2'-bipyridine) have been synthesized under solvothermal conditions and characterized by single-crystal X-ray diffraction, elemental analysis, thermogravimetric analysis, etc. The results of crystal diffraction analysis show that complexes 1–6 are binuclear units, crystallizing in the triclinic Pī space group. Complexes 1–5 are isostructural, and each of the central metal ions has a coordination number of 9. The asymmetric unit of complexes 1–5 consists of one Ln³⁺, one 5, 5'-DM-2, 2'-bipy ligand, and three 2, 4, 6-TMBA^- moieties with three coordination modes: chelation bidentate, bridging bidentate, and bridging tridentate. The coordination geometry of Ln³⁺ is distorted monocapped square antiprismatic. The binuclear units of complexes 1–5 form a one-dimensional (1D) supramolecular chain along the c-axis via π–π stacking interactions between the 2, 4, 6-trimethylbenzoic acid rings. The 1D chains are linked to form a supramolecular two-dimensional (2D) sheet in the bc plane via π–π stacking interactions between the pyridine rings. Although the molecular formulae of complex 6 and complexes 1–5 are similar, the coordination environment of the lanthanide ions is different in the two cases. The asymmetric unit of complex 6 contains a Dy³⁺ ion coordinated by a bidentate 5, 5'-DM-2, 2'-bipy and three 2, 4, 6-TMBA^- ligands adopting bidentate and bridging bidentate coordination modes. The Dy³⁺ metal center has a coordination number of 8, with distorted square antiprismatic molecular geometry. The binuclear molecule of 6 is assembled into a six-nuclear unit by π–π weak staking interactions between two 5, 5'-DM-2, 2'-bipy ligands; then, adjacent six-nuclear units form a 1D chain via offset π–π interactions between 5, 5'-DM-2, 2'-bipy ligands on different adjacent units. The adjacent 1D chains are linked by C―H···O hydrogen bonding interactions to form a 2D supramolecular structure. The thermal stability and thermal decomposition mechanism of all the complexes are investigated by the combination of thermogravimetry and infrared spectroscopy (TG/FTIR) techniques under a simulated air atmosphere in the temperature range of 298–973 K at a heating rate of 10 K·min^-1. Thermogravimetric studies show that this series of complexes have excellent thermal stability. During the thermal decomposition of the complex, the neutral ligand is lost first, followed by the acid ligand, and finally, the complex is decomposed into rare earth oxides. The three-dimensional infrared results are consistent with the thermogravimetric results. The photoluminescence spectra of complex 4 show the strong characteristic luminescence of Eu³⁺. The five typical emission peaks at 581, 591, 621, 651, and 701 nm correspond to the ⁵D₀ → ⁷F₀, ⁵D₀ → ⁷F₁, ⁵D₀ → ⁷F₂, ⁵D₀ → ⁷F₃, and ⁵D₀ → ⁷F₄ electronic transitions of Eu³⁺, respectively. The emission at 621 nm is due to the electric dipole transition ⁵D₀ → ⁷F₂, while that at 591 nm is assigned to the ⁵D₀ → ⁷F₁ the magnetic dipole transition. The lifetime (τ) of complex 4 is calculated as 1.15 ms based on the equation τ = (B₁τ₁² + B₂τ₂²))/(B₁τ₁ + B₂τ₂), and the intrinsic quantum yield is calculated to be 45.1%. Further, the magnetic properties of complex 6 in the temperature range of 2–300 K are studied under an applied magnetic field of 1000 Oe.     

稀土氮杂环配合物的合成、 结构及抑菌活性

采用溶液合成法, 在室温下合成了一系列稀土配合[Ln(IAA)₂(phen)₂]·(NO₃)[Ln=Ce(1), Gd(2), Tb(3), Dy(4), Ho(5), HIAA=吲哚乙酸, phen=1,10-菲咯啉], 并通过元素分析、 红外光谱、 热重分析、 X射线单晶衍射、 X射线粉末衍射等方法对配合物进行了表征. 结果表明, 配合物15具有相同的结构, 对配合物2的单晶结构分析表明, 配合物2为超分子网络结构, 通过分子间氢键形成2D网络, 中心金属Gd(Ⅲ)为九配位, 具有单帽四方反棱柱几何构型. 此外, 对该系列配合物进行了抑菌活性的研究, 得到了抑菌活性与配合物组成的构效关系.     

Nd(Gly)2Cl3·3H2O和Pr(Ala)3Cl3·3H2O的热力学性质

利用精密自动绝热热量计测定了Nd(Gly)₂Cl₃·3H₂O在80-357K和Pr(Ala)₃Cl₃·3H₂O在80-374K温区的热容. 根据两个化合物的热容计算出了相对于参考温度298.15K的热力学函数(H_T?H_298.15)和(S_T?S_298.15). 根据热重(TG)分析结果, 提出了这两个稀土化合物可能的热分解机理. 利用溶解-反应恒温热量计测定相关化合物的溶解焓并设计盖斯热化学循环, 计算出了两个化合物的标准摩尔生成焓.     

稀土吲哚-3-乙酸和吲哚-3-丁酸配合物的合成、表征及成键特性研究

在乙醇水溶液体系中合成了8种新的稀土吲哚-3-乙酸和吲哚-3-丁酸配合物,其通式为Ln(lA)₃·2H₂O和Ln(IB)₃·2H₂O(Ln=La,Nd,Sm,Er;IA=C₁₀H₈NO₂;IB=C₁₂H₁₂NO₂)。用元素分析、电导测定、电子吸收光谱、红外光谱、X光电子能谱和热重-差热分析确定了配合物的组成和成键特性。     

Non-isothermal Decomposition Kinetics of [Cu（en）2H2O] （FOX-7）2·H2O

The thermal behavior and non-isothermal decomposition kinetics of [Cu（en）2H2O]（FOX-7）2·H2O （en=ethylenediamine） were studied with DSC and TG-DTG methods.The kinetic equation of the exothermal process is dα/dt=（10^17.92/β）4α^3/4exp（-1.688×10^5/RT）.The self-accelerating decomposition temperature and critical temperature of the thermal explosion are 163.3 and 174.8 ℃,respectively.The specific heat capacity of [Cu（en）2H2O]（FOX-7）2·H2O was determined with a micro-DSC method,with a molar heat capacity of 661.6 J·mol^-1·K^-1 at 25 ℃.Adiabatic time-to-explosion was also estimated as 23.2 s.[Cu（en）2H2O]（FOX-7）2·H2O is less sensitive.     

Tetrakis(triphenylphosphine oxide) complexes of the lanthanide nitrates; synthesis, characterisation and crystal structures of [La(Ph3PO)4(NO3)3]·Me2CO and [Lu(Ph3PO)4(NO3)2]NO3

The reaction of Ln(NO₃)₃·6H₂O (Ln=La, Ce, Pr or Nd) with a sixfold excess of Ph₃PO in acetone formed [Ln(Ph₃PO)₄(NO₃)₃]·Me₂CO. The crystal structure of the La complex shows a nine-coordinate metal centre with four phosphine oxides, two bidentate and one monodentate nitrate groups, and PXRD studies show the same structure is present in the other three complexes. In CH₂Cl₂ or Me₂CO solutions, ³¹P NMR studies show that the complexes are essentially completely decomposed into [Ln(Ph₃PO)₃(NO₃)₃] and Ph₃PO. Similar reactions in ethanol gave [Ln(Ph₃PO)₃(NO₃)₃] only. In contrast for Ln=Sm, Eu or Gd, only the [Ln(Ph₃PO)₃(NO₃)₃] are formed from either acetone or ethanol solutions. For the later lanthanides Ln=Tb–Lu, acetone solutions of Ln(NO₃)₃·6H₂O and Ph₃PO gave [Ln(Ph₃PO)₃(NO₃)₃] only, even with a large excess of Ph₃PO, but from cold ethanol [Ln(Ph₃PO)₄(NO₃)₂]NO₃ (Ln=Tb, Ho–Lu) were obtained. The structure of [Lu(Ph₃PO)₄(NO₃)₂]NO₃ shows an eight-coordinate metal centre with four phosphine oxides and two bidentate nitrate groups. In solution in CH₂Cl₂ or Me₂CO the tetrakis-complexes show varying amounts of decomposition into mixtures of [Ln(Ph₃PO)₃(NO₃)₃], [Ln(Ph₃PO)₄(NO₃)₂]NO₃ and Ph₃PO as judged by ³¹P{¹H} NMR spectroscopy. The [Ln(Ph₃PO)₃(NO₃)₃] also partially decompose in solution for Ln=Dy–Lu, forming some tetrakis(phosphine oxide) species.     

系列Ln(Ⅲ)配聚物的合成、结构及近红外发光性能

通过水热反应合成5种结构新颖的配聚物:{[Ln_2(1,3-bdc)_3(H_2O)_4](DMF(H_2O}_n[Ln=Pr(1),Nd(2),Gd(3)]和{[Ln_4(1,3-bdc)_6(H_2O)_4(DMF)](DMF(2H_2O}_n[Ln=Er(4),Ho(5)](1,3-bdc:间苯二甲酸,DMF:N,N-二甲基酰胺)。通过单晶X射线衍射、红外光谱、紫外-可见-近红外(UV-Vis-NIR)光谱、荧光光谱等技术手段对产物的结构和性能进行了表征。结果表明,配聚物1~3是同构的,属单斜晶系,P2(1)/n空间群;配聚物4、5是同构的,属三斜晶系,P-1空间群。在晶体中,间苯二甲酸根采用多样的配位模式,使配聚物呈现多维的结构。除配聚物4,其余均呈现Ln(Ⅲ)的特征NIR发光,并与其UV-Vis-NIR吸收光谱相关联。