2,2';6,2"-联三吡啶——一种现代配位化学中不同寻常的三齿配体

作为典型的三齿有机配体2,2';6,2"-联三吡啶,在超分子化学与材料化学领域得到广泛应用.联三吡啶可以与大多数过渡金属离子络合,金属络合物的性质可通过引入不同的取代基团进行调控.重点介绍了联三吡啶配体的结构、与酸的作用、光谱性质以及与过渡金属离子络合的特点.     

2,2′;6,2″-联三吡啶——一种现代配位化学中不同寻常的三齿配体

作为典型的三齿有机配体2,2′;6,2＂-联三吡啶,在超分子化学与材料化学领域得到广泛应用。联三吡啶可以与大多数过渡金属离子络合,金属络合物的性质可通过引入不同的取代基团进行调控。重点介绍了联三吡啶配体的结构、与酸的作用、光谱性质以及与过渡金属离子络合的特点。     

2,2′;6,2″-联三吡啶——一种现代配位化学中不同寻常的三齿配体

作为典型的三齿有机配体2,2′;6,2″-联三吡啶,在超分子化学与材料化学领域得到广泛应用。联三吡啶可以与大多数过渡金属离子络合,金属络合物的性质可通过引入不同的取代基团进行调控。重点介绍了联三吡啶配体的结构、与酸的作用、光谱性质以及与过渡金属离子络合的特点。     

稀土-其它过渡金属混合催化剂用于共轭双烯烃的聚合——Ⅱ烷基铝对丁二烯聚合及产物微观结构的影响

某些过渡金属组成的Ziegler-Natta催化剂聚合共轭双烯烃,所得聚合物的微观结构易随聚合条件和主催化剂配体的改变而异.具有d电子的钴、钛催化体系聚合丁二烯,既可得cis-1,4结构聚丁二烯,又可得1,2结构的聚丁二烯;而具有f电子的稀土催化剂聚合共轭双烯烃,无论怎样改变其聚合条件和配体,一般皆得高顺式聚合物.一般认为:这种定向性的特征是由单体向活性中心上配位、插入时的环境及活性中心的本质所决定的.在第一报中作者利用同一种配位体,使具有d电子的过渡金属Fe和具有f电子的稀土     

吡啶亚胺基酞菁镍系催化剂催化乙烯齐聚性能及其动力学研究

以四氨基镍酞菁、吡啶-2-甲醛和NiCl2·6H2O为原料,先后经过席夫碱反应和络合反应得到一种新型吡啶亚胺基酞菁配体及其镍系催化剂。合成产物的结构通过红外光谱(FTIR)、紫外(UV-Vis)、核磁共振氢谱(¹H-NMR)、电感耦合等离子体质谱(ICP-MS)、同步热分析(TG-DSC)及电喷雾电离质谱(ESI-MS)等方法进行表征。对其催化乙烯齐聚性能进行考察,并研究了该反应的动力学。催化乙烯齐聚实验结果表明,当溶剂为环己烷、助催化剂为甲基铝氧烷(MAO)、催化剂用量为5μmol/L、齐聚压力为1.0 MPa、齐聚温度为35℃、Al/Ni摩尔比为500时,吡啶亚胺基酞菁镍系催化剂的活性可达8.82×10⁵ g/(mol Ni·h),丁烯和己烯的含量分别为58.22%和39.85%。对吡啶亚胺基酞菁镍系催化剂催化乙烯齐聚反应动力学方程进行拟合计算,结果表明该反应对催化剂摩尔浓度的反应级数为1.24,对齐聚压力的反应级数为0.95,当活性中心的浓度为5μmol/L、齐聚压力为1.0 MPa、齐聚温度为5～35℃时,该反应的表观活化能为71.4...     

树枝状共轭聚合物研究

本文介绍了树枝状共轭聚合物的最新发展,包括全共轭、部分共轭树枝状聚合物及树枝化共轭聚合物的特点及其在电致发光、电极、传感器以及光探测等领域的功能化应用;详细讨论了包括代数、支化单元、端基、核、金属离子的络合等结构因素以及溶剂和浓度等工艺因素对电荷传输的影响;并进一步提出该领域研究前景及有待于解决的问题.     

树枝状共轭聚合物研究

本文介绍了树枝状共轭聚合物的最新发展,包括全共轭、部分共轭树枝状聚合物及树枝化共轭聚合物的特点及其在电致发光、电极、传感器以及光探测等领域的功能化应用;详细讨论了包括代数、支化单元、端基、核、金属离子的络合等结构因素以及溶剂和浓度等工艺因素对电荷传输的影响;并进一步提出该领域研究前景及有待于解决的问题.     

基于配位自组装的全共轭三联吡啶-过渡金属环状超分子的构筑及其光、电化学性能*

2,2':6,2"-三联吡啶全共轭衍生物在与过渡金属离子配位络合后形成的全共轭配合物,因具有特殊的大π-π电子结构和金属-配体相互作用,成为构筑新型功能材料的重要基元,被广泛应用于光电转换、化学/生物检测、催化有机合成等领域。本文主要介绍近年来全共轭“三联吡啶-过渡金属离子（tpy-Mt）”环状超分子配合物的合成及其在光、电化学性能方面的研究进展,并探讨了该领域存在的问题及今后的发展方向。     

含手性联萘冠醚侧基的聚苯型共轭聚合物的合成与表征

用钯催化的Suzuki缩聚法合成了一类新型主链为共轭聚苯结构,侧基数手性联萘冠醚取代基团的光学活性共轭聚合物。用1^H-NMR、紫外吸收光谱、园二色性、荧光光谱、热失重及差热分析等方法进行了表征。结果表明该光学活性聚苯具有良好的热稳定性和高的比旋度,在溶液中能络合碱金属离子,其荧光发射强度随着离子浓度的增大而逐渐降低。该光学活性聚苯的荧光光谱在410nm处出现最大发射峰,是一类潜在的发蓝光材料。     

胺基功能化咔唑共轭聚合物的合成及其光电性能研究

发展了新型含有胺基的支化烷基修饰的咔唑单元,并且与芴、咔唑、苯等单元通过Suzuki偶联反应共聚得到不同主链结构的水/醇溶共轭聚合物界面修饰材料,研究了主链结构的变化对材料光物理、电化学性能的影响.所有聚合物均被用作阴极界面材料应用于器件结构为ITO/PEDOT：PSS/P-PPV/界面层/Al的聚合物发光二极管中.在相同器件制备条件下,系统比较了不同主链结构的界面修饰材料在器件中的性能,并研究了性能差异的原因.器件研究结果表明,在高功函数金属Al阴极的聚合物发光二极管中,含胺基功能化咔唑单元的水/醇溶共轭聚合物材料由于界面偶极的形成,均表现出很好的电子注入/传输性能,与之对应的器件性能得到大幅提升.     

Iron-catalyzed [2pi + 2pi] cycloaddition of alpha,omega-dienes: the importance of redox-active supporting ligands

The bis(imino)pyridine iron bis(dinitrogen) complex, (iPrPDI)Fe(N2)2 (iPrPDI = 2,6-(2,6-iPr2C6H3NCR)2C5H3N), serves as an efficient precursor for the catalytic [2pi + 2pi] cycloaddition of alpha,omega-dienes to yield the corresponding bicycles. For amine substrates, the rate of catalytic turnover increases with the size of the nitrogen substituents, demonstrating competing heterocycle coordination and product inhibition. In one case, a bis(imino)pyridine iron azobicycloheptane product was characterized by X-ray diffraction. Preliminary mechanistic studies highlight the importance of the redox activity of the bis(imino)pyridine ligand to maintain the ferrous oxidation state throughout the catalytic cycle.     

Synthesis of iron(II), manganese(II) cobalt(II) and ruthenium(II) complexes containing tridentate nitrogen ligands and their application in the catalytic oxidation of alkanes

A series of Fe(II), Mn(II), Co(II) and Ru(II) complexes containing bis(imino)pyridine or bis(amino)pyridine ligands and weakly coordinating triflate (OTf-) or non-coordinating SbF6- anions have been prepared. The complexes have been fully characterized including several solid-state structure analyses. Two unusual mono-chelate six-coordinate bis(imino)pyridine Fe(II) and Mn(II) complexes have been observed. The catalytic properties of the complexes for the oxidation of cyclohexane with H2O2 have been evaluated. Only the Fe(II) complexes have shown catalytic activity, which is mainly due to Fenton-type free radical auto-oxidation.     

Carbon–Carbon Bond Formation in a Weak Ligand Field: Leveraging Open‐Shell First‐Row Transition‐Metal Catalysts

Unique features of earth‐abundant transition‐metal catalysts are reviewed in the context of catalytic carbon–carbon bond‐forming reactions. Aryl‐substituted bis(imino)pyridine iron and cobalt dihalide compounds, when activated with alkyl aluminum reagents, form highly active catalysts for the polymerization of ethylene. Open‐shell iron and cobalt alkyl complexes have been synthesized that serve as single‐component olefin polymerization catalysts. Reduced bis(imino)pyridine iron and cobalt dinitrogen compounds have also been discovered that promote the unique [2+2] cycloaddition of unactivated terminal alkenes. Studies of the electronic structure support open‐shell intermediates, a deviation from traditional strong‐field organometallic compounds that promote catalytic C−C bond formation.     

Thio-Pybox and Thio-Phebox complexes of chromium, iron, cobalt and nickel and their application in ethylene and butadiene polymerisation catalysis

A series of bis(thiazolinyl)- and bis(thiazolyl)pyridine Thio-Pybox ligands and their metal complexes of chromium(III), iron(II), cobalt(II) and nickel(II) has been prepared, as well as a nickel(II) complex containing a monoanionic bis(thiazolinyl)phenyl Thio-Phebox ligand. These new metal complexes have been characterised and used as catalysts, in combination with the co-catalyst MAO, for the polymerisation of ethylene and for the polymerisation of butadiene. In the case of ethylene polymerisation, the Thio-Pybox and Thio-Phebox metal complexes have shown relatively low polymerisation activities, much lower compared to the related bis(imino)pyridine complexes of the same metals. In the polymerisation of butadiene, several Thio-Pybox cobalt(II) complexes show very high activities, significantly higher than the other metal complexes with the same ligand. It is the metal, rather than the ligand, that appears to have the most profound effect on the catalytic activity in butadiene polymerisation, unlike in the polymerisation of ethylene, where bis(imino)pyridine ligands provide highly active catalysts for a range of 1st row transition metals.     

Synthesis, electronic structure, and ethylene polymerization activity of bis(imino)pyridine cobalt alkyl cations

A new spin on polymers: the title cations comprise low-spin Co(II) centers with neutral bis(imino)pyridine chelating ligands. These complexes serve as single-component ethylene polymerization catalysts and offer insight into the mechanism of chain growth and catalyst deactivation, which occurs by forming inactive cationic bis(imino)pyridine cobalt complexes with a diethyl ether ligand.     

Iron-catalyzed intermolecular [2π+2π] cycloaddition

The bis(imino)pyridine iron dinitrogen compounds, ((iPr)PDI)Fe(N(2))(2) and [((Me)PDI)Fe(N(2))](2)(μ(2)-N(2)) ((R)PDI = 2,6-(2,6-R(2)-C(6)H(3)N═CMe)(2)C(5)H(3)N; R = (i)Pr, Me), promote the catalytic intermolecular [2π + 2π] cycloaddition of ethylene and butadiene to form vinylcyclobutane. Stoichiometric experiments resulted in isolation of a catalytically competent iron metallocycle intermediate, which was shown to undergo diene-induced C-C reductive elimination. Deuterium labeling experiments establish competitive cyclometalation of the bis(imino)pyridine aryl substituents during catalytic turnover.     

Computational Study of Formic Acid Dehydrogenation Catalyzed by AlIII–Bis(imino)pyridine

The mechanism of formic acid dehydrogenation catalyzed by the bis(imino)pyridine‐ligated aluminum hydride complex (PDI^2?)Al(THF)H (PDI=bis(imino)pyridine) was studied by density functional theory calculations. The overall transformation is composed of two stages: catalyst activation and the catalytic cycle. The catalyst activation begins with O?H bond cleavage of HCOOH promoted by aluminum–ligand cooperation, followed by HCOOH‐assisted Al?H bond cleavage, and protonation of the imine carbon atom of the bis(imino)pyridine ligand. The resultant doubly protonated complex (^H,HPDI)Al(OOCH)₃ is the active catalyst for formic acid dehydrogenation. Given this, the catalytic cycle includes β‐hydride elimination of (^H,HPDI)Al(OOCH)₃ to produce CO₂, and the formed (^H,HPDI)Al(OOCH)₂H mediates HCOOH to release H₂.     

The interplay of metal and supporting ligand in labile coordination to pincer complexes of Ag(I)

The bis(imino)pyridine scaffold provides support for the synthesis and characterization of unique Ag(I) pincer complexes [{ArN=CPh}(2)(NPh)]Ag(+)(OTf)(-) (Ar = 2,5-(t)Bu(2)C(6)H(3)3; 2,6-(i)Pr(2)C(6)H(3) 4). The bonding interactions between the cation-anion and between the bis(imino)pyridine ligand and the Ag centre are presented. Coordination of pyridine, toluene, 2-butyne and cyclooctene to the Ag centre led to the isolation and crystallographic characterization of labile transient adduct species. Bonding analysis of the adducts revealed conventional ligand-Ag coordination and important unconventional electron donation from the ligand to a π*-orbital of the bis(imino)pyridine group.     

Bis(imino)pyridine palladium(II) complexes: Synthesis, structure and catalytic activity

Bis(imino)pyridine palladium(II) complexes 3-6 were synthesized by two different methods. The structure of complexes 3 and 4 has been confirmed by X-ray structure analysis. The catalytic studies show that bis(imino)pyridine palladium(II) complexes are highly efficient catalysts in the Suzuki-Miyaura reaction and the complex 4 was used to catalyze the synthesis of fluorinated liquid crystalline compounds via Suzuki coupling reaction.