含混合配体双核铜(I)配合物的合成与荧光光谱

合成了含双二苯基膦甲烷(dppm)和邻菲咯啉(phen)混合配体的双核铜(I)配合物[Cu(dppm)(phen)]2(NO3)2 1,并经X射线单晶结构分析表征了配合物的结构,研究了配合物的荧光光谱特征,配合物1的结构分析表明,dppm作为桥式双齿配体、phen作为双齿配体分别与铜原子形成四面体配位结构,硝酸根离子位于配合物外界.     

新型配位聚合物[Zn（tca）2（4,4′-bpy）]的合成、晶体结构及荧光性质

利用水热法合成了新型配合物[Zn(tca)2(4,4′-bpy)](tca=trans-cinnamic acid,4,4’-bpy=4,4’-bipyridine).通过元素分析、红外、荧光和单晶X-射线对配合物进行了结构和性质表征.结构测定显示配合物属六方晶系,P-3空间群.配体tca呈现2种配位模式,分别是顺-顺桥式双齿和螯合双齿,最终配合物形成新颖的三维结构.性质测定表明配合物具有蓝色荧光性质.     

含混合配体双核铜（I）配合物的合成及荧光光谱

合成了含双二苯基膦甲烷（dppm)和邻菲咯啉（phen)混合配体的双核铜（I）配合物[Cu(dppm)(phen)]2(NO3)21,并经X射线单晶结构分析表征了配合物的结构，研究了配合物的荧光光谱特征，配合物1的结构分析表明，dppm作为桥式双齿配体、phen作为双齿配体分别与铜原子形成四面体配位结构，硝酸根离子位于配合物外界。     

含水杨醛缩苯胺双Schiff碱和吡啶配体的Zn(Ⅱ)配合物的电子结构和二阶非线性光学性质

以实验测定的晶体结构为基础, 用密度泛函理论的B3LYP方法, 在6-31G(d)基组水平上计算4个水杨醛缩苯胺类双Schiff碱和吡啶为配体的Zn(Ⅱ)配合物的电子结构, 并结合有限场(FF)方法得到二阶NLO系数. 结果表明, 在4个五配位配合物中, 双Schiff碱配体的共轭性减弱, 在Schiff碱配体引入叔丁基以及连接双Schiff碱的桥对配合物的结构影响很小. 同时4个配合物的配键性质、原子电荷分布、前线分子轨道能级等方面具有相似性. 但引入叔丁基改变了配合物前线分子轨道组成, Zn—O配位键的极性有所加强, 从而使配合物的极化率和二阶NLO系数增加, 而连接两个Schiff碱的桥对配合物二阶NLO性质影响不大.     

手性多齿胺膦钌配合物的设计合成和在芳香酮不对称氢化反应中的应用

简要介绍了多齿胺膦金属配合物的设计合成。这些多齿配合显示了单齿胺或膦金属配合物所不具有的丰富结构类型和特殊催化性质，合成和表征了含有结构类似的双亚胺双膦钌配合物（Ｒ，Ｒ）－３和双胺双膦钌配合物（Ｒ，Ｒ）－４。配合物（Ｒ，Ｒ）－４可作为多种芳香酮不对称氢化的手性催化剂，其光学收率最高达９７％。讨论了钌配合物的催化作用机理。     

1,2-双烷基(芳基)硫代乙烷对金的萃取性质和配合物的研究

本文研究了1,2-双烷基(芳基)硫代乙烷(L)——1,2-双(正辛基硫代)乙烷(BOTE)、1,2-双(正戊基硫代)乙烷(BATE)、1,2-双(苯基硫代)乙烷(BPTE)对金的萃取及其配合物的性质.双烷基硫代乙烷对金具有很强的萃取能力,可定量地萃取金.在溶液中,当[L]≥[Au~(3 )]时,Au与L形成1∶1Au-L配合物,而在[L]<[Au~(3 )]时,则为2∶1Au-L配合物.固态时,Au(Ⅲ)、Au(Ⅰ)与L只形成2∶1配合物(AuCl_3)_2L和AaCl)_2L.讨论了BOTE和BATE与Au(Ⅲ)、Au(Ⅰ)配合物的IR和~1H NMR谱.IR谱证实了关于Au(Ⅰ)配合物为线型结构的推断,并借助金原子的交换机理,解释了配合物与配位体的~1H NMR谱外观相似的原因.详细分析了Au(Ⅲ)配合物低频区的IR数据,提出了配合物有离子型结构的新证据.     

Zn2+,Cu2+及Ni2+对二甲双胍的配合作用及降血糖活性研究

二甲双胍盐酸盐、硝酸盐及与Zn²⁺, Cu²⁺, Ni²⁺三种金属离子配合物的结构特点、电荷分布和二甲双胍配合物对四氧嘧啶糖尿病小鼠血糖影响的研究表明:Zn²⁺配合物表现为较为少见的单齿配位,而Cu²⁺, Ni²⁺配合物表现为双齿配位.进一步电荷分布计算发现,与端基N原子相比,二甲双胍的桥基N原子具有较高的负电荷.三种金属离子配合物对四氧嘧啶糖尿病小鼠血糖的影响研究显示,桥基N配位掩蔽后,二甲双胍的降血糖功能丧失.说明桥基N对二甲双胍的降血糖作用具有重要意义.     

多羟乙基双核大环多胺La（Ⅲ）配合物对双对硝基苯酚磷酸二酯和DNA催化水解作用研究

合成了一类新型多羟乙基双核大环多胺La(Ⅲ)配合物,其结构经1H NMR,MS,元素分析等表征.通过紫外分光光谱法和琼脂糖凝胶电泳技术,研究了双核大环多胺La(Ⅲ)配合物催化双对硝基苯酚磷酸二酯的水解反应和对质粒DNA(pUC18)的催化水解作用.结果表明:双核大环多胺La(Ⅲ)配合物可以有效催化双对硝基苯酚磷酸二酯水解和促进质粒DNA在生理条件下的水解裂解.双对硝基苯酚磷酸二酯的水解速率提高了2.36×104倍.讨论了配合物结构对水解反应的影响.     

多羟乙基双核大环多胺La(III)配合物对双对硝基苯酚磷酸二酯和DNA 催化水解作用研究

合成了一类新型多羟乙基双核大环多胺La(III)配合物, 其结构经1H NMR, MS, 元素分析等表征. 通过紫外分光光谱法和琼脂糖凝胶电泳技术, 研究了双核大环多胺La(III)配合物催化双对硝基苯酚磷酸二酯的水解反应和对质粒DNA(pUC18)的催化水解作用. 结果表明: 双核大环多胺La(III)配合物可以有效催化双对硝基苯酚磷酸二酯水解和促进质粒DNA在生理条件下的水解裂解. 双对硝基苯酚磷酸二酯的水解速率提高了2.36×104倍. 讨论了配合物结构对水解反应的影响.     

Schiff碱配合物模拟酶催化性能的结构效应研究

研究了新型Schiff碱双锰及双铁配合物在模拟酶催化PhIO单加氧化环己烷反应及被PhIO氧化破坏反应中的结构效应.结果表明,随着这些配合物的环内空腔逐渐增大,其抗氧化稳定性、催化活性及催化反应产率依次降低.配合物中最佳螯合环为五元环.     

双二苯基膦甲烷和μ^4-S的四核铜(Ⅰ)配合物的 合成与结构

室温下,双核配合物[Cu(dppm)(NO~3)]~2与二硫化碳反应制备了四核铜(Ⅰ)配合物[Cu~4(S)(dppm)~4](PF~6)~2·CH~2Cl~2(dppm=双二苯基膦甲烷),并经光谱学方法表征了配合物的物理化学性质。X射线四圆衍射测定结果表明dppm属桥式双齿配位,S^2^-以μ^4形式与中心铜离子配位,PF~6^-位于配合物的外界,铜离子呈现三角平面配位构型。     

Synthesis and reactivity of the ruthenium(II) dithiocarbonate complex [Ru(kappa2-S2C=O)(dppm)2] (dppm = bis(diphenylphosphino)methane)

Reaction of cis-[RuCl2(dppm)2] (dppm = bis(diphenylphosphino)methane) with CS2 and NaOH yields the first ruthenium dithiocarbonate complex, [Ru(kappa2-S2C=O)(dppm)2]. Protonation with tetrafluoroboric acid affords the xanthate complex [Ru(kappa2-S2COH)(dppm)2]BF4 in a reversible manner, suggesting that this may be an intermediate in dithiocarbonate formation. [Ru(kappa2-S2C=O)(dppm)2] reacts with methyl iodide or [Me3O]BF4 to give [Ru(kappa2-S2COMe)(dppm)2]+, also obtained from the reaction of cis-[RuCl2dppm)2] with CS2 and NaOMe. Two modifications of [Ru(kappa2-S(2)C=O)(dppm)2] were examined crystallographically and the structure of [Ru(kappa2-S2COMe)(dppm)2]BF4 and a new modification of cis-[RuCl2(dppm)2] are also reported.     

Novel double insertion of carbon disulfide into two Ru-H bonds of [(dppm)(2)Ru(H)(2)] (dppm = Ph(2)PCH(2)PPh(2)): synthesis and crystal structure of a methanedithiolate complex

Addition of excess carbon disulfide to cis/trans-[(dppm)(2)Ru(H)(2)] results in the methanedithiolate complex [(dppm)(2)Ru(eta(2)-S(2)CH(2))] 4 via the intermediacy of cis-[(dppm)(2)Ru(H)(SC(S)H)] 2. The X-ray crystal structure of this species has been determined.     

Utilization of CS2 as a source of C1 synthetic units for the preparation of bis(alkylthio)methanes and alkyl dithioformates

Double insertion of CS2 into two Ru-H bonds of [(dppm)2Ru(H)2] (dppm = Ph2PCH2PPh2) affords the methanedithiolate complex [(dppm)2Ru(eta2-S2CH2)]. The methanedithiolate moiety has been functionalized using 2 equiv of RX resulting in bis(alkylthio)methane derivatives [(dppm)2Ru(RSCH2SR)][X]2. The bis(alkylthio)methane complex loses the bis(alkylthio)methane moiety under very mild conditions and in turn affords the [(dppm)2RuX2] complex from which the starting dihydride [(dppm)2Ru(H)2] has been regenerated via reaction with KOH/EtOH. On the other hand, insertion of CS2 into one Ru-H bond of [(dppe)2Ru(H)2] (dppe = Ph2PCH2CH2PPh2) followed by functionalization using RX results in alkyl dithioformate complex trans-[(dppe)2Ru(H)(SC(SR)H)][X]. In this case also, the alkyl dithioformate moiety gets eliminated under very mild conditions to afford the [(dppe)2Ru(H)(X)] derivative from which the starting dihydride has been regenerated via reaction with NaBH4. The reactions presented here constitute utilization of CS2 as a C1 synthetic source for the generation of useful organic compounds.     

Synthesis of nonanuclear heterometallic carbide clusters. Unexpected formation of the [Ru6(CO)16]2-[Pt2(CO)2(dppm)2]2+ ion pair on the way to [Ru6C(CO)16Pt3(dppm)2

A novel trimetallic cluster [Ru5CRh2Pt2(CO)16(dppm)2] was synthesized via coupling of two neutral clusters-[Ru5C(CO)15] and [Rh2Pt2(CO)6(dppm)2]. The structure of this mixed metal complex was established using X-ray crystallography and 31P NMR spectroscopy. It was found that the reaction between [Ru6C(CO)17] and [Pt2(CO)3(dppm)2] leads to spontaneous electron transfer between these polynuclear complexes and results in the formation of an unusually stable cluster "salt" {[Ru6(CO)16]2-[Pt2(CO)2(dppm)2]2+}, which was characterized by crystallographic and spectroscopic methods. Heating of the Ru6-Pt2 ion pair in an autoclave (145 degrees C, 15 atm N2) results in fusion of the metal frameworks to give a nonanuclear mixed metal [Ru6C(CO)16Pt3(dppm)2] cluster in a good yield. The latter complex was obtained earlier as a minor product of another thermal reaction and now has been additionally characterized by 31P NMR spectroscopy.     

Multiple silicon-hydrogen bond activations at adjacent rhodium and iridium centers

The reaction of 1 equiv of primary silanes, SiH(3)R (R = Ph, Mes), with [RhIr(CO)(3)(dppm)(2)] yields mono(silylene)-bridged complexes of the type [RhIr(H)(2)(CO)(2)(μ-SiHR)(dppm)(2)] (R = Ph or Mes), while for R = Ph the addition of 2 equiv yields the bis(silylene)-bridged complexes, [RhIr(CO)(2)(μ-SiHPh)(2)(dppm)(2)]. The kinetic isomer of this bis(silylene)-bridged product has the phenyl substituent axial on one silylene unit and equatorial on the other, and in the presence of excess silane this rearranges to the thermodynamically preferred "axial-axial" isomer, in which the phenyl substituents on each bridging silylene unit are axial and parallel to one another. The reaction of 1 equiv of diphenylsilane with [RhIr(CO)(3)(dppm)(2)] produces the mono(silylene)-bridged product, [RhIr(H)(2)(CO)(2)(μ-SiPh(2))(dppm)(2)], and the subsequent addition of silane in the presence of CO yields the silyl/silylene product [RhIr(H)(SiPh(2)H)(CO)(3)(κ(1)-dppm)(μ-SiPh(2))(dppm)]. The reaction of [RhIr(CO)(3)(dppm)(2)] with 2 equiv of SiH(2)Me(2) yields the analogous product [RhIr(H)(SiMe(2)H)(CO)(3)(κ(1)-dppm)(μ-SiMe(2))(dppm)]. Low-temperature NMR spectroscopic observation of some key intermediates, such as [RhIr(H)(SiH(2)Ph)(CO)(2)(μ-CO)(dppm)(2)], formed during the formation of the mono(silylene)-bridged species provides evidence for a mechanism involving initial Si-H bond activation at Rh, followed by the subsequent Si-H bond activation at Ir. The Si-H bond activation of a second equivalent of silane seems to be initiated by dissociation of the Rh-bound end of one diphosphine. The reaction of diphenylsilane with the cationic complex [RhIr(CH(3))(CO)(2)(dppm)(2)][CF(3)SO(3)] gives rise to a different reactivity pattern in which Si-H bond activation is initiated at Ir. In this case, the cationic silyl-bridged species, [RhIr(CH(3))(CO)(2)(κ(1):η(2)-SiHPh(2))(dppm)(2)][CF(3)SO(3)], contains an agostic Si-H interaction with Rh. In solution, at ambient temperature, this complex converts to two species, [RhIr(H)(COCH(3))(CO)(μ-H)(μ-SiPh(2))(dppm)(2)][CF(3)SO(3)] and [RhIr(CO)(2)(μ-H)(μ-SiPh(2))(dppm)(2)] [CF(3)SO(3)], formed by the competing methyl migration to CO and reductive elimination of methane, respectively. In the diphenylsilylene dihydride product, a weak interaction between the bridging silicon and the terminal Ir-bound hydride is proposed on the basis of NMR evidence.     

双齿膦参与的非均三脚架配位银化合物的合成、结构与表征

近年来,由于在发光材料及一些生物酶的模拟方面有着重要的价值,研究三脚 架有机配体与金属离子自组装形成的配合物引起了人们的极大兴趣。有许多稀土及 银的配合物被报道。从结构的角度来看,非均三脚架配体的三个支架可以有不同类 型的翻转,加上所其带基团的多样性,使其可具有较均三脚架配体更丰富多变的配 位方式,为具有新颖结构的功能材料的设计提供了新思路。     

Synthesis, Crystal Structure and Photoluminescent Properties of a New Dinuclear Copper(I) Complex [Cu_2(μ_2-dppm)_2(MeCN)_2(μ_2-MeCN)](ClO_4)_2·MeCN

The title compound [Cu_2(μ_2-dppm)_2(MeCN)_2(μ_2-MeCN)](ClO_4)_2·MeCN (dppm = bis(diphenylphosphino)methane) has been prepared and characterized. It crystallizes in the monoclinic system, space group P2_1/n, with a = 11.904(6), b = 20.755(11), c = 24.744(13) (A),β = 98.226(12)°, C_(58)H_(56)Cl_2Cu_2N_4O_8P_4,M_r= 1258.93, V=6051(5) (A)~3, Z = 4,D_c= 1.382 g/cm~3,μ = 9.52 mm~(-1), F(000) = 2592, R = 0.0533 and wR = 0.1295 for 6175 observed reflections with I > 2σ(I). Each Cu(I) center is tetrahedrally coordinated by two phosphine atoms from two bridging dppm ligands, one nitrogen atom from a terminally coordinated acetonitrile molecule, and another nitrogen atom from a μ_2-acetonitrile molecule. The two Cu(I) centers are bridged by two dppm ligands as well as a unique acetonitrile molecule. The full molecule exhibits a 'chair-like' configuration. This dinuclear complex exhibits intense or middle photoluminescence at room temperature in the solid state or actonitrile solution at 486 nm.     

β-二酮双核铜(Ⅰ)配合物的合成与结构

室温下,通过双二苯基膦甲烷还原[Cu(tfac)