2-羟基-3-甲氧基苯甲醛与α-萘胺Schiff碱硝酸稀土配合物的合成与表征

合成邻香兰素(2-羟基-3-甲氧基苯甲醛)与α-萘胺Schiff碱硝酸稀土配合物[LnL~2(NO~3)~2]NO~3(Ln: 镧系元素, L: Schiff碱配体)。配合物由一个中心稀土离子, 两个Schiff碱和三个硝酸根组成, 两个Schiff碱都是氮、氧双配位, 两个硝酸根是双齿配位, 另一硝酸根在配合物外界。中心稀土离子是八配位的, 满足稀土八配位的稳定结构。     

镍, 锌, 钴(II)-N-(间甲苯基)亚氨基二乙酸-氮三乙酸的量热研究

使用改进的RD-1型热导式量热计测量了镍(II), 锌(II),钴(II)-N-(间甲苯基)亚氨基二乙酸-氮三乙酸三元配合物的生成焓, 发现其大小按金属离子来说符合Irving-William序列。利用配体的多环水化结构等讨论了该三元配合物的生成焓和相应的二元配合物的生成焓, 同时求得了上述三元体系的热力学参数, 指出上述三元体系的生成熵是导致这些三元体系具有较大稳定性的根本原因。     

新型二茂稀土烃硫基配合物的合成与表征

本文用三茂基稀土[(C~5H~5)~3Ln(Ln=Ho(1)，Yb(2)，La(3)，Y(4)]与等摩尔的2-巯基嘧啶(HSC:NCH:CHCH:N·)在四氢呋喃溶剂中于室温下反应，合成了四个对空气敏感的二茂稀土嘧啶巯基配合物。产物经元素分析、红外光谱及质谱鉴定确定其组成为：(C~5H~5)~2LnSC:NCH:CHCH:N·THF[Ln=Ho(1)，Yb(2)，La(3)，Y(4)]。     

VIB金属蝎型配合物(Scorpionate)的研究进展

综述了VIB金属(Mo、W)多吡唑硼配合物近年来的研究进展。详细地叙述了第二代多吡唑硼配体的合成与表征。     

镍, 锌, 钴(II)-N-(间甲苯基)亚氨基二乙酸-氮三乙酸的量热研究

使用改进的RD-1型热导式量热计测量了镍(II), 锌(II),钴(II)-N-(间甲苯基)亚氨基二乙酸-氮三乙酸三元配合物的生成焓, 发现其大小按金属离子来说符合Irving-William序列。利用配体的多环水化结构等讨论了该三元配合物的生成焓和相应的二元配合物的生成焓, 同时求得了上述三元体系的热力学参数, 指出上述三元体系的生成熵是导致这些三元体系具有较大稳定性的根本原因。     

2-羰基丙酸(4-吡啶甲酰基)腙与碱土金属配合物的晶体结构及热 稳定性

报道了2-羰基丙酸(4-吡啶甲酰基)腙(H~2L)与碱土金属(Ca,Mg,Sr,Ba)四种配合物的合成,结构及热稳定性。同时,用X射线单晶衍射仪测定了Mg和Ba两种配合物的晶体结构,结构分析表明两种配合物均属单斜晶系,空间群均为P2~1/c。此外,还比较讨论了各配合物不同成键方式所对应的IR特征及热稳定性变化规律。     

具有非正规自旋态结构的新型Mn(Ⅱ)-Cu(Ⅱ)-Mn(Ⅱ)三核配合物的合成和磁性

合成和表征了四种新的异三核配合物, {[Mn(L)2]2[Cu(bpa)]{(ClO4)2,其中pba表示为亚丙基-1, 3-双(草胺酸根); L表示1, 10-菲咯啉(phen)、5-硝基-1, 10-菲咯啉(NO2-phen)、2, 2'-联吡啶(bpy)、4, 4'-二甲基-2, 2'-联吡啶(Me2bpy)。基于{[Mn(phen)2]2[Cu(pba)]}(ClO4)2.H2O的变温磁化率测量(4.2~300K), 求出交换积分J=41.5cm^-^1, 表明Mn(Ⅱ)和Cu(Ⅱ)离子间为反铁磁耦合。在XMT-T图上, XMT在175K附近呈现出一极小值, 这是具有非正规自旋态结构的多金属耦合体系的典型特征。     

吡咯基金属络合物的制备及其在有机合成中的应用

本文综述了近年来吡咯基金属络合物的研究进展, 详细讨论了σ~N-、σ~C-、π-型吡咯基金属络合物的制备方法, 以及各类吡咯基金属络合物在有机合成中的应用。     

三硫氰酸根三乙二胺合镉(II)钾(I)的晶体结构

含钾和二价金属离子的双金属硫氰酸根配合物的晶体结构研究已有一些报道。在K~2Pb(SCN)~4^[^1^]和K~2Cd(SCN)~4.2H~2O^[^2^]这两个化合物中,晶体结构都是由K^+和M(SCN)~4^2-组成。本文报道了Cd(en)~3K(NCS)~3的晶体结构,其基本构型与上述两个化合物有显著的不同(en为乙二胺)。     

手性过渡金属(Mn, Co, Ni)-Salen配合物催化NaOCl不对称环氧化苯乙烯的反应研究

本文论述了由手性1, 2-二苯基乙二胺与适当取代的邻羟基苯甲醛生成的希佛碱作为过渡金属Co(II)、Ni(II)、Mn(II)的配体合成的6种过渡金属-Salen配合物在NaOCl下均相催化苯乙烯不对称环氧化反应的效果。对环氧化反应进行控制性研究, 我们发现环氧化反应与中心金属离子的相关性可能主要源于配体结构、金属离子的选择及二者结合形成的配合物的空间构型。好的不对称环氧化反应催化剂要求中心金属离子具有适当的氧化还原电位, 对底物烯烃因其取代基的大小, 催化剂结构的空间构型应有好坏之分, 我们得到的循环伏安数据及实验结果部分说明这一点。同时对手性镍(II)-Salen及手性锰(III)-Salen配合物的催化反应机理配合实验现象分别作出假设, 都经过自由基历程, 但却是截然不同的活性氧化物种, 同时, 由于起主要作用的不对称诱导因素不同, 不对称诱导方向有异。对同一催化剂在不同pH值下起作用的活性氧化物种类别也可能不同。     

Investigation of aromatic hydroxyoxime-transition metal complexes by infrared spectroscopy

The preparation and infrared spectroscopic studies of coordination compounds of salicylaldoxime, 2-hydroxy-acetophenone oxime, 2-hydroxy-benzophenone oxime and 2-hydroxy-4-methoxy-benzophenone oxime with copper (II), nickel (II), cobalt (II) and iron (II) are described. The frequency of the C=N stretching vibration is usually higher in the complex than that in the ligand. The higher this frequency is, the larger the stability constant of the complex will be, but there is no quantitative relationship. In the case of complexes of salicylaldoxime with Cu (II), Ni (II), Co (II) and Fe (II), v_O=N values are correlated linearly with the ionization potentials of the central metal ions. The frequency of the OH stretching vibration is closely related to the geometric configuration of the complex. Thus aromatic hydroxyoximes form coordination compounds with Co (II) and Fe (II) with cis configuration possessing six-membered hydrogen-bonded ring. This is indicated in the infrared spectra by the complete absence of the OH stretching band, or by the appearance of an extremely broad and flat band of very low intensity. However, Cu (II) or Ni (II) complex possesses trans configuration with five-membered hydrogen-bonded bridge showing characteristic OH absorption band in the infrared region. The v_oh's of complexes investigated are closely related to the polar nature of substituents on the benzene ring. By examining the spectra of ⁶³Cu and ⁶⁵Cu complexes with 2-hydroxy-4(5)-substituted benzophenone oximes in the far infrared region, the characteristic frequency of M-O and M-N were assigned for a series of aromatic hydroxyoxime-transition metal complexes.     

芳香族羟肟及其过渡金属配合物的质谱研究

本文报道某些芳香族羟肟及其过渡金属铜、镍、钴和铁配合物的EI质谱,借助亚稳跃迁、高分辨质谱和稳定同位素^1^5N、^6^3Cu、和^6^5Cu标记物,讨论其断裂途径,总结断裂规律.     

The Coordination Structure of the Extracted Nickel(II) Complex with a Synergistic Mixture Containing Lix63 and Versatic10

In the present work, the nickel(II ) synergist complex with isobutyric acid (HL^I ) and 5‐hydroxy‐4‐octanone oxime (HB^I ), which were the corresponding short‐chain analogs of the active synergistic mixture of Versatic10 (HL ) and Lix63 (5,8‐diethyl‐7‐hydroxy‐6‐dodecanoneoxime, HB ), was prepared and studied by single‐crystal X‐ray diffraction (XRD ). The crystal structure of the nickel(II ) synergist complex showed that the composition of the complex was Ni(L^I )₂(HB^I )₂ with a cis ‐form octahedron geometry structure. Both intra‐ and intermolecular hydrogen bonding were observed in the crystal lattice. Compared with the free ligands, similar band shifts of Fourier transform infrared (FT‐IR ) spectra assigned to the stretching vibration of carbon–oxygen single bond (C O), the stretching vibration of carbon–nitrogen double bond (CN), and the disappearance of the scissoring vibration of α‐hydroxy (OH ) were correspondingly found in both the nickel(II ) synergist complex and the extracted nickel(II ) complex in the nonpolar organic phase. Combined with the results from ESI‐MS , XRD , and slope analysis, it was concluded that the major species of the extracted nickel(II ) complex in the nonpolar organic phase might possess a similar coordination structure [Ni(HB )₂(L)₂] as the nickel(II ) synergist complex, along with the neutral complex [Ni(HB )(B)₂].     

二(μ-叠氮)二[N,N'-二(2-吡啶甲基)乙二胺]合二镍(Ⅱ)配 合物的结构与磁性

合成并通过元素分析、红外光谱、电子光谱等方法表征了叠氮桥联的双核配合物[Ni2(bispicen)2(μ-N3)2](ClO4)2[bispicen=N,N'-二(2-吡啶甲基)乙二胺].用单晶X射线衍射技术测定了配合物的晶体结构,晶体属正交晶系,P212121空间群,镍(Ⅱ)离子处于变形八面体配位环境,并采取cis-α构型,两个以μ-1,3桥联方式配位的叠氮离子之间呈罕见的交错式非平面排列。变温磁化率测定表明配合物两个镍(Ⅱ)离子之间存在反铁磁相互作用,基于H^=-2JS1^S2^的磁性分析表明磁交换积分J=-28.1cm^-1。     

铜(Ⅱ)-羟肟络合物的电子自旋共振谱研究

本文报导芳香族羟肟铜(Ⅱ)络合物的电子自旋共振(ESR)谱的研究。讨论了这类配位体上取代基的电子效应对络合物中铜(Ⅱ)的超精细分裂常数A_(Cu)值的影响,以及A_(Cu)值与这些配位体萃取铜的分配系数的关系。     

3,5-二氯水杨醛缩邻苯二胺铜配合物的合成、晶体结构及光谱学性质

合成了3,5-二氯水杨醛缩邻苯二胺铜配合物[Cu(C₂₀H₁₀Cl₄O₂N₂)]·DMF。 通过元素分析、红外光谱、热重测试技术对其进行了表征,同时用X射线单晶衍射确定了其晶体结构;利用紫外-可见光吸收光谱、荧光激发和发射光谱研究了该配合物的光物理性能。 结果表明,该晶体属于单斜晶系,空间群为P2(1)/n,a=0.81316(8) nm,b=1.53101(18) nm,c=1.87819(19) nm,β=92.4530(10)°,Z=4,最终偏差因子R₁=0.0584,ωR₂=0.1482,配合物的中心铜离子与席夫碱的2个O和2个N配位,形成1个五元环和2个六元环,从而构成了1个四配位的平面构型;配合物的热分解温度为384 ℃,具有很好的热稳定性;在DMF溶液体系中,配合物的荧光激发带位于360～480 nm,荧光发射峰在507 nm处,为蓝绿色荧光,最佳激发波长为440 nm,禁带宽度2.59 eV。     

四（对—羟基）苯基卟啉配合物的傅里叶变换红外光声光谱

四（对-羟基）苯基卟啉（H2THPP）不仅能作为分析试剂，而且有一定的抗癌活性，还可作为合成卟啉类液晶材料的中间体．这种配体及其配合物由于颜色深、透光性能差和散射较强，用普通红外光谱法开展其振动光谱研究存在一定的困难．我们在用红外光声光谱（FTIR－PAS）技术[1]成功地研究了部分过渡金属、稀土金属叶琳配合物的基础上[2，3]，测试并研究了H2THPP及其Cr（III）、Mn（III）、Fe（III）、Co（II）、Ni（II）、Cu（II）、Zn（II）配合物在3700～200cm－1范围内的FTIR－PAS．对主要谱带进行了经验归属，讨论了配…     

Vibrational dynamics of hydrogen‐bonded HCN complexes with OH and NH acids: Computational DFT systematic study

Vibrational properties (band position, infrared [IR], and Raman intensities) of C?N stretching mode were studied in 65 gas phase hydrogen‐bonded 1:1 complexes of HCN with OH acids and NH acids using density functional theory (DFT) calculations at the B3LYP‐6‐311++G(d,p) level. Furthermore, general characteristics of the hydrogen bonds and vibrational changes in acids OH/NH stretching bands were also considered. Experimentally observed blue shift of the C?N stretching band promoted by hydrogen bonding, which shortens the triple bond length, is very well reproduced and quantitatively depends on the hydrogen bond length. Both IR and Raman ν(C?N) band intensities are enhanced, also in good agreement with the experimental results. IR intensity increase is a direct function of the hydrogen bond energy. However, the predicted Raman intensity raise is a more complex function, depending simultaneously on characteristics of both the hydrogen bond (C?N bond length) and the H‐donating acid (polarizability). With these two parameters, ν (C?N) Raman intensities of the complexes are explained with a mean error of ±2.4%. © 2006 Wiley Periodicals, Inc. Int J Quantum Chem, 2007