固固反应合成三碘化锑、三碘化铋的硫脲配合物(英文)

通过三碘化锑和三碘化铋与硫脲间的室温固固反应合成了三碘化锑、三碘化铋的硫脲配合物 ,其组成通式为 :M(CS(NH2 ) 2 ) 3 I3 (M =Sb ,Bi) .两种配合物的晶体结构均属于单斜晶系 ,锑配合物Sb(CS(NH2 ) 2 ) 3 I3 的晶胞参数为 :a =1.4 772nm ,b=1.6 5 82nm ,c =2 .0 6 74nm ,β =90 .81°,铋配合物Bi(CS(NH2 ) 2 ) 3 I3 的晶胞参数为 :a =1.4 0 10nm ,b =2 .0 16 8nm ,c =2 .0 397nm ,β =90 .84° .远红外光谱表明硫脲中的N原子而非硫原子参与了配位     

固固反应合成三碘化锑、三碘化铋与硫脲配合物

通过三碘化锑和三碘化铋与硫脲间的室温固固反应合成了三碘化锑、三碘化铋的硫脲配合物 ,其组成为 :M[CS( NH2 ) 2 ]3 I3 ( M=Sb,Bi)。两种配合物的晶体结构均属于单斜晶系 ,锑配合物 Sb[CS( NH2 ) 2 ]3 I3 的晶胞参数为 :a=1 .4 772 nm,b=1 .6 5 82 nm,c=2 .0 6 74 nm,β=90 .81°,铋配合物 Bi[CS( NH2 ) 2 ]3 I3 的晶胞参数为 :a=1 .4 0 1 0 nm,b=2 .0 1 6 8nm,c=2 .0 397nm,β=90 .84°。远红外光谱表明硫脲中的 N原子而非硫原子参与了配位     

氨基酸锑(Ⅲ)双核配合物的固相合成与表征

采用室温固相反应法合成了甘氨酸锑和苯丙氨酸锑双核配合物 ,用元素分析、远红外光谱、热重差热分析及X射线粉末衍射进行了表征 .两种配合物Sb2 L5X·2 5H2 O(L =gly ,phe;X =Cl或I)的晶体结构均属于单斜晶系 ,甘氨酸锑配合物的晶胞参数为 :a =0 6 5 2 6nm ,b =1.2 2 2 7nm ,c=1.3877nm ,β=97.88°,V =1.0 96 8nm3 ,苯丙氨酸锑配合物的晶胞参数为 :a =1.0 6 17nm ,b =0 .7839nm ,c =1.5 72 5nm ,β =92 .32°,V =1.30 77nm3 .远红外光谱表明O ,N ,Cl或I原子参与配位     

三草酸合铁(Ⅲ)酸钾的室温固相合成与晶体结构表征

以草酸钾和氯化铁为原料,通过室温固固反应合成了三草酸合铁(Ⅲ)酸钾配合物,用ICP、元素分析、X-射线单晶衍射、X-射线粉末衍射、红外光谱及热分析等方法对其组成和结构进行了表征.实验结果表明:三草酸合铁(Ⅲ)酸钾K3[Fe(C2O4)3]·3H2O的晶体结构属于单斜晶系,P2(1)/n空间群,晶胞参数a=0.774 52(4) nm,b=1.990 39(10) nm,c=1.034 31(5) nm,β=107.704(2)°,Z=4,Dc=2.148 g/cm~3.草酸根中的O原子与Fe原子形成了配位数为6的变形八面体配合物,在N2气氛中的热分解过程分4步,最后的残余物为FeO和K_2CO_3.     

[Zn(phen)3]·2TsTausH的合成及晶体结构

在水溶液中合成了配合物[Zn(phen)3]·2TsTausH(化学式为C54H48N8O11S4Zn), 其结构经X-射线衍射、IR 和元素分析等表征.X-射线衍射分析结果表明此配合物属单斜晶系,空间群为C2/c,晶胞参数为a=2.9246(8) nm, b=1.0375(2) nm, c=2.1361(5) nm, β=126.07(1)°, V=5.242(2) nm3, Z=4, Dc=1.496 g·cm-3, μ=0.699 mm-1, F(000)=2448.配合物中的金属锌离子与三个邻菲咯啉配位,而与对甲苯磺酰牛磺酸中的氧原子没有配位.该配合物是一个变形的八面体构型.     

Na24P2W22O83的固相合成与表征

用固相反应法由Na4P2O7@10H2O,Na2WO4@2H2O和WO3合成了新型杂多酸盐配合物Na24P2W22O23.其结构经元素分析、m和x-射线粉末衍射等分析手段确证,新配合物属正交晶系,晶胞参数:a=1.4745nm,b=1.1933nm,c=1.1119nm,z=1,属D24P212121(No.19)空间群.并推测了其配位方式和结构.     

六亚甲基四胺锑(Ⅲ)、铋(Ⅲ)配合物的固相合成与表征

通过固相反应,合成了新的配合物六亚甲基四胺锑(Ⅲ)、铋(Ⅲ):SbCl3(C6H12N4)2·H2O(1)、BiCl3(C6H12N4)2·H2O(2).经元素分析、X 射线粉末衍射、远红外光谱和差热 热重分析进行表征,确定了配合物的组成和结构.对XRD谱指标化,确定其晶系和晶胞参数.SbCl3(C6H12N4)2·H2O(1):a=1.2490nm,b=1.4583nm,c=1.6870nm,β=91.78°,V=3.0706nm3;BiCl3(C6H12N4)2·H2O(2):a=1.3250nm,b=1.3889nm,c=1.7449nm,β=98.94°,V=3.1725nm3.     

含水杨醛缩对硝基苯甲酰腙的钒酰配合物和钴配合物的合成和晶体结构

本文合成了含水杨醛缩对硝基苯甲酰腙(简写为H2L)的钒酰配合物VOL(CH3OH)(CH3O)(1,C16H16N3O7V,Mr=413.26)和钴配合物[CoL(C5H5N)3]NO3C5H5N(2,C34H29N8O7Co,Mr=720.58)。配合物1属单斜晶系,空间群为P21/c,a=7.3253(3),b=18.8237(9),c=12.9014(5)?b=91.672(1),V=1778.2(1)3,Z=4,F(000)=848,m(MoKa)=0.603mm1,R=0.0470,wR=0.1312。配合物2属单斜晶系,空间群为P21/c,a=11.4196(8),b=17.157(1),c=17.081(1)?b=96.8233(9),V=3323.0(4)3,Z=4,F(000)=1488,m(MoKa)=0.578mm1,R=0.0455,wR=0.1311。在配合物1中,钒(V)原子由周围的酰氧基原子、配体L2的3个配位原子,去质子化甲醇的甲氧基原子和配位甲醇的氧原子配位,形成畸变的VO(ONO)(O)(O)八面体配位构型。晶体内每2个分子间通过氢键作用缔合成中心对称的分子对,OH…N氢键键长为2.861(4)?键角163.20。晶体中存在着弱p-p共轭作用。在配合物2中,钴(Ⅲ)原子由1个L2的3个配位原子和3个配位吡啶分子的3个氮原子配位,呈N4O2八面体配位构型。     

3-羧基水杨醛·邻菲咯啉合铜(Ⅱ)配合物的合成与晶体结构

合成了铜(Ⅱ)与3-羧基水杨醛和邻菲咯啉的配合物[Cu(sal)(phen)].4 H2O(sal为3-羧基水杨醛负二价离子,phen为邻菲咯啉),采用单晶X射线衍射法测定了配合物的晶体结构.结果表明,合成的晶体属于三斜晶系p墿空间群;晶体参数a=0.673 02(10)nm,b=1.102 11(19)nm,c=1.488 3(2)nm,α=109.275(2)°,β=91.991(2)°,γ=103.514(2)°;分子中Cu(Ⅱ)离子处于平面四方场配位环境中.     

Schiff碱(C_7H_7NO)钯(Ⅱ)配合物的合成与晶体结构

合成了N—H水杨醛Sch iff碱的钯(Ⅱ)配合物.X射线单晶衍射表明,配合物晶体属于单斜晶系,Pī空间群,分子式为C48H50N8O8Pd3,晶体学参数:a=0.945 8(19)nm,b=1.059 9(2)nm,c=1.396 5(3)nm,α=74.61(3),°β=75.18(3)°,γ=68.49(3)°,V=1.236(4)nm3,Dc=1.594 Mg/m3,Mr=1 186.16,Z=1,F(000)=596,R1=0.029 9,wR2=0.073 4.晶体结构表明,钯原子为四配位,位于配合物的中心与配体的氮原子和氧原子结合形成六元环.     

Solid Phase Synthesis, Characterization of Hexamethylenetetramine Complexes of Antimony and Bismuth Trichloride

New hexamethylenetetramine complexes of antimony and bismuth trichloride were synthesized through a solid phase reaction of hexamethylenetetramine and antimony or bismuth trichloride. The formula of the complex is MCl₃(C₆H₁₂N₄)₂⋅H₂O (M=Sb, Bi).The crystal structure of the complexes belongs to monoclinic system and the lattice parameters: a=1.249 nm, b=1.4583 nm, c=1.6780 nm andβ=91.78° for SbCl₃(C₆H₁₂N₄)₂⋅H₂O and a=1.3250 nm, b=1.3889 nm, c=1.7449 nm and β=98.94° for BiCl₃(C₆H₁₂N₄)₂⋅H₂O. Far-infrared spectra reveal that the antimony or bismuth ion is coordinated by the nitrogen atom of the hexamethylenetetramine. The thermal analysis also demonstrates the complex formation between the antimony or bismuth ion and hexamethylenetetramine. The intermediate and final residues in the thermal decomposition process have been analyzed to check the pyrolysis reaction. This revised version was published online in August 2006 with corrections to the Cover Date.     

Synthesis, characterization and thermal decomposition of thiourea complexes of antimony and bismuth triiodide

The thiourea complexes of antimony and bismuth triiodide were synthesized by a direct reaction of antimony and bismuth triiodide with thiourea powder at room temperature. The formula of the complex is MI₃[SC(NH₂)₂]₃(M=Sb, Bi). The crystal structure of the complexes belongs to monoclinic system and the lattice parameters are a=1.4772 nm, b=1.6582 nm, c=2.0674 nm and β=90.81° for SbI₃(SC(NH₂)₂)₃ and a=1.4009 nm, b=2.0170 nm, c=2.0397 nm and β=90.84° for BiI₃[SC(NH₂)₂]₃. The infrared spectra reveal that the trivalent antimony or bismuth ion is coordinated by the nitrogen atom, not the sulfur atom of the thiourea. Thermal analysis shows that there are two times structure rearrangements or phase transformation in the complexes from 100 to 170°C.     

Syntheses,Crystal Structures and Antibacterial Activities of Complexes [（C_9H_（18）NS_2）_3M（Ⅲ）]（M = Sb and Bi）

Two novel complexes,[(C9H18NS2)3Sb(III)](1) and [(C9H18NS2)3Bi(III)](2),were synthesized and characterized by elemental analysis,IR,TG and X-ray single-crystal diffraction.Both 1 and 2 crystallize in the monoclinic system,P21/c space group.The data for 1:a = 1.6964(3),b = 1.02149(17),c = 2.5650(3) nm,β = 121.824(8)°,Z = 4,V = 3.7766(10) nm3,Dc = 1.293 g·cm-3,F(000) = 1536,μ = 1.082 mm-1,the final R = 0.0500,wR = 0.1562 and S =1.072.The data for 2:a = 1.6802(9),b = 1.0256(6),c = 2.5083(10) nm,β = 121.77(3)°,Z = 4,V = 3.675(3) nm3,Dc = 1.486 g·cm-3,F(000) = 1664,μ = 5.159 mm-1,the final R = 0.0481,wR = 0.1055 and S =1.076.The coordinated geometry of the central M(III) with six sulfur atoms from three ligands is a distorted pentagonal pyramid configuration.The dimer structural system is formed by the weak interactions of M…S and C-H…S between two molecules.The complexes were valued for their antibacterial activities by agar-streak method.It was found that 1 is active against the four test bacterial organisms.     

非天然氨基酸水杨醛席夫碱铜配合物的合成与表征

合成了N-亚水杨基β-丙氨酸铜(1)和N-亚水杨基牛磺酸铜(2)两种新配合物,用元素分析、摩尔电导、红外光谱、热重差分析、X-射线粉末衍射对所合成的配合物进行了表征,并对X-射线粉末衍射数据进行了指标化.两种配合物的组成分别为Cu(sal-β-ala)*H2O(1),Cu(sal-tau)*2H2O(2),X-射线粉末衍射数据指标化结果表明,两种配合物均属于正交晶系,晶胞参数分别是1a=1.4981nm,b=1.8246nm,c=2.1985nm;2a=0.9454,b=1.7092nm,c=2.2254.     

铌取代型杂多钨酸盐的合成、表征、生物活性及晶体结构

合成了铌、过氧化铌取代的钨硅、钨锗杂多配合物M     

Cation-directed synthesis of tungstosilicates. 2. Synthesis, structure, and characterization of the open Wells-Dawson anion alpha-[{K(H2O)2}(Si2W18O66)]15- and its transiton-metal derivatives [{M(H2O)}(mu-H2O)2K(Si2W18O66)]13- and [{M(H2O)}(mu-H2O)2K{M(H2O)4}(Si2W18O66)]11-

The dimer alpha-[{K(H2O)2}(Si2W18O66)]15- (1), synthesized by reacting K10A-alpha-[SiW9O34] with two equivalents of H+ in aqueous solution, has been characterized by polarography and 183W NMR spectroscopy. Nine resonance signals have been observed with the tetrabutylammonium salt in dimethylformamide/acetonitrile solution, in agreement with the crystal structure of the anion which consists of two A-alpha-[SiW9O34]10- associated through two W-O-W junctions. This anion derives from the Wells-Dawson structure by breaking four W-O-W junctions. The pocket between the two-half-anions can be filled by several metal cations. Reaction of transition-metal cations with 1 leads to the formation of [{M(H2O)}(mu-H2O)2K(Si2W18O66)]13- (1M) (M = Co, Ni, Cu) and [{M(H2O)}(mu-H2O)2K{M(H2O)4}(Si2W18O66)]11- (1M2) (M = Mn, Co, Ni) complexes. One potassium is always included in the pocket with one or two transition metals. Because of the shift of the potassium cation to one side of the anion, the coordination modes of the two transition metals are different. Crystals of 1, 1M, and 1Co2 potassium salts are triclinic (P-1, Z = 2) and crystals of 1M2 potassium salts are monoclinic (P2(1)/n, Z = 4). The symmetry of 1Mand 1M2 complexes is C1 and they are present in the crystal as racemate inversion pairs.     

Ligand effects in the syntheses and structures of novel heteroleptic and homoleptic bismuth(III) formamidinate complexes

Metathesis reactions of the alkali metal formamidinates M(RNC(H)NR), M = Li or K; R = C(6)H(3)-2,6-Pr(i)(2) (L(1)), C(6)H(3)-2,6-Et(2) (L(2)); C(6)H(2)-2,4,6-Me(3) (L(3)), C(6)H(3)-2,6-Me(2) (L(4)) or C(6)H(4)-2-Ph (L(5)), with BiX(3) (X = Cl or Br) gave a range of bismuth(iii) formamidinate complexes [Bi(L)Br(micro-Br)(thf)](2) (L = L(1), L(4)), [{Bi(L(1))Cl(2)(thf)}(2)Bi(L(1))Cl(2)], [Bi(L)(2)X] (L = L(2), L(5), X = Br; L = L(1), X = Cl), and [Bi(L)(3)] (L = L(2), L(3)). An analogous organometallic complex Bi(L(1))(2)Bu(n) was also isolated as a side product in one instance. Structural characterisation of the di-halide complexes show symmetrical dimers for X = Br, with two bromide bridges, and a coordinated thf molecule on each Bi atom, whereas for X = Cl a thf deficient species was crystallised, and has a weakly associated trinuclear array with two coordinated thf molecules per three Bi atoms. Complexes of the form Bi(L)(2)X (X = Br, Cl, Bu(n)) and Bi(L)(3) all have monomeric structures but the Bi(L)(3) species show marked asymmetry of the formamidinate binding, suggesting that they have reached coordination saturation.