Solvatothermal Syntheses and Structural Characterizations of Polyoxoalkoxometalates: The Heptanuclear [{Fe(OH)(CH3CN)2} Fe6OCl6{(OCH2)3CCH2OH}4], the Decanuclear [Fe10O2Cl8{(OCH2)3CCH2CH3}6], and the Bimetallic [(VO)2Fe8O2Cl6{(OCH2)3CCH2CH3}6]

Solvatothermal syntheses have been exploited to effect the isolation of three novel polyoxoalkoxometalate clusters, [{Fe(OH)(CH₃CN)₂} Fe₆OCl₆{(OCH₂)₃CCH₂OH}₄] (1), [Fe₁₀O₂Cl₈{(OCH₂)₃CCH₂CH₃}₆] (2), and [(VO)₂Fe₈O₂Cl₆{(OCH₂)₃CCH₂CH₃}₆] (3). The structure of 1 may be described as a hexametalate core {Fe₆OCl₆}¹⁰⁺, consisting of a octahedral arrangement of chloride ligands encasing an octahedron of six Fe(III) sites, with a central oxo group. The remaining four coordination sites at each octahedral iron center are occupied by doubly bridging oxygen donors from the trisalkoxo ligands. One triangular face of this substructure, defined by three oxygen atoms, from three adjacent trisalkoxo ligands, is capped by the {Fe(OH)(CH₃CN)₂}²⁺ subunit. The structure of 2 is based on the decametalate core of edge-sharing octahedra. The eight peripheral Fe(III) sites of the cluster bond to four oxygen donors from the trisalkoxo ligands, a terminal Cl^– ligand, and one of the ⁶-oxo groups. The two central iron sites are linked to four oxygen donors from the trisalkoxo ligands and to both of the ⁶-oxo groups. Cluster 3 is structurally related to 2 with two {FeCl}²⁺ units replaced by {VO}²⁺ groups.     

Alkoxo‐Verbindungen des dreiwertigen Eisen: Synthese und Charakterisierung von [Fe2(OtBu)6], [Fe2Cl2(OtBu)4], [Fe2Cl4(OtBu)2] und [N(nBu)4]2[Fe6OCl6(OMe)12]

Alkoxo Compounds of Iron(III): Syntheses and Characterization of [Fe₂(OtBu)₆], [Fe₂Cl₂(OtBu)₄], [Fe₂Cl₄(OtBu)₂] and [N(nBu)₄]₂[Fe₆OCl₆(OMe)₁₂] The reaction of iron(III)chloride in diethylether with sodium tert‐butylat yielded the homoleptic dimeric tert‐‐butoxide Fe₂(OtBu)₆ ( 1 ). The chloro‐derivatives [Fe₂Cl₂(OtBu)₄] ( 2 ), and [Fe₂Cl₄(OtBu)₂] ( 3 ) could be synthesized by ligand exchange between 1 and iron(III)chloride. Each of the molecules 1 , 2 , and 3 consists of two edge‐sharing tetrahedrons, with two tert‐butoxo‐groups as μ₂‐bridging ligands. For the synthesis of the alkoxides 1 , 2 , and 3 diethylether plays an important role. In the first step the dietherate of iron(III)chloride FeCl₃(OEt₂)₂ ( 4 ) is formed. The reaction of iron(III)chloride with tetrabutylammonium methoxide in methanol results in the formation of a tetrabutylammonium methoxo‐chloro‐oxo‐hexairon cluster [N(nBu)₄]₂[Fe₆OCl₆(OMe)₁₂] ( 5 ). Crystal structure data: 1 , triclinic, P1¯, a = 9.882(2) Å, b = 10.523(2) Å, c = 15.972(3) Å, α = 73.986(4)°, β = 88.713(4)°, γ = 87.145(4)°, V = 1594.4(5) ų, Z = 2, d_c = 1.146 gcm^—1, R₁ = 0.044; 2 , monoclinic, P2₁/n, a = 11.134(2) Å, b = 10.141(2) Å, c = 12.152(2) Å und β = 114.157(3)°, V = 1251.8(4) ų, Z = 2, d_c = 1.377 gcm^—1, R₁ = 0.0581; 3 , monoclinic, P2₁/n, a = 6.527(2) Å, b = 11.744(2) Å, c = 10.623(2), β = 96.644(3)°, V = 808.8(2) ų, Z = 2, d_c = 1.641 gcm^—1, R₁ = 0.0174; 4 , orthorhombic, Iba2, a = 23.266(5) Å, b = 9.541(2) Å, c = 12.867(3) Å, V = 2856(2) ų, Z = 8, d_c = 1.444 gcm^—1, R₁ = 0.0208; 5 , trigonal, P3₁, a = 13.945(2) Å, c = 30.011(6) Å, V = 5054(2) ų, Z = 6, d_c = 1.401 gcm^—1; R_c = 0.0494.     

Two iron-containing tungstogermanates: [K(H2O)(beta-Fe2GeW10O37(OH))(gamma-GeW10O36)]12- and [{beta-Fe2GeW10O37(OH)2}2]12-

Interaction of the dilacunary polyanion precursor [gamma-GeW(10)O(36)](8-) with Fe(3+) ions in aqueous buffer medium (pH 4.8) results in the formation of two dimeric tungstogermanates depending on the reactant ratios. When using an Fe3+ to [gamma-GeW(10)O(36)](8-) ratio of 1:1, the asymmetric anion [K(H(2)O)(beta-Fe(2)GeW(10)O(37)(OH))(gamma-GeW(10)O(36))](12-) (1) is formed, whereas [{beta-Fe(2)GeW(10)O(37)(OH)2}2]12- (2) is formed when using a ratio of 2:1. Single-crystal X-ray analyses were carried out on Cs(3)K(9)[K(H(2)O)(beta-Fe(2)GeW(10)O(37)(OH))(gamma-GeW(10)O(36))].19H(2)O (CsK-1), which crystallizes in the triclinic system, space group P1, a = 11.4547(2), b = 19.9181(5), c = 21.0781(6) A, alpha = 66.7977(12), beta = 89.1061(12), gamma = 84.4457(11) degrees, and Z = 2 and on Cs(7)K(4)Na[{beta-Fe(2)GeW(10)O(37)(OH)(2)}(2)].39H(2)O (CsKNa-2), which crystallizes in the monoclinic system, space group C2/m, a = 32.7569(13), b = 12.2631(5), c = 14.2895(5) A, beta = 104.135(2) degrees , and Z = 2. Polyanion 1 consists of (beta-Fe(2)GeW(10)O(37)) and (gamma-GeW(10)O(36)) units linked via two Fe-O-W bridges and a central potassium ion. Two equivalent FeO(6) octahedra complete the belt of the beta-Keggin unit and link to the (gamma-GeW(10)O(36)) fragment. On the other hand, 2 consists of two {beta-Fe(2)GeW(10)O(37)(OH)(2)} units with four bridging hydroxo groups linking the four Fe(3+) ions, forming an eight-membered ring. The magnetic properties of CsK-1 and CsKNa-2 have been studied by magnetic susceptibility and magnetization measurements and fitted according to an isotropic exchange model. Both polyanions 1 and 2 exhibit diamagnetic ground states with a small amount of paramagnetic impurity. Electrochemistry studies on 1 and 2 were carried out in a pH 5 acetate medium. The two polyanions have in common the simultaneous reduction of all of their Fe(3+) centers. This observation suggests the existence of identical or almost-identical influences on these centers and their equivalence, especially in the reduced state. Controlled potential coulometry results indicate the presence of two Fe(3+) centers in 1 and four in 2. The splitting of the tungsten wave of 1 compared to the single tungsten wave of 2 is attributed to a difference in acid-base properties of the polyanions. Voltammetric peak-potential shifts as a function of pH were studied in the case of 2.     

Preparation of New Derivatives of the closo-Dodecaborate Anion [B12H10(OC(O)CH3){OC(O)(CH2)3CH3}]2–, [B12H10(OH){OC(O)(CH2)3CH3}]2–, [B12H10(SCN){OC(O)(CH2)3CH3}]2–, and [B12H10(I){OC(O)(CH2)3CH3}]2–

Nucleophilic substitution reactions of the monosubstituted anions [B₁₂H₁₁X]^2–, where X = OC(O)CH₃, OH, SCN, and I, with pentanoic acid were studied. The obtained compounds were shown to contain the [B₁₂H₁₀X{OC(O)(CH₂)₃CH₃}]^2– anions.     

Syntheses and structural study of trinuclear iron acetates [Fe3O(CH3COO)6(H2O)3]Cl· 6H2O and [Fe3O(CH3COO)6(H2O)3] [FeCl4]· 2CH3COOH

The structure of two trinuclear iron acetates [Fe₃O(CH₃COO)₆(H₂O)₃]Cl· 6H₂O (I) and [Fe₃O(CH₃COO)₆(H_2O)₃][FeCl₄] · 2CH₃COOH (II) was determined by X-ray diffraction analysis. Crystals I and II are ionic and belong to the orthorhombic system with parameters a = 13.704(3), b = 23.332(5), c = 9.167(2) Å, R = 0.0355, space goup P2₁2₁2 for I and a = 10.145(4), b = 15.323(6), c = 22.999(8) Å, R = 0.0752, space group Pbc2₁ for II. The complex cation [Fe₃O(CH₃COO)₆(H₂O)₃]⁺ has a μ₃-O-bridged structure typical for trinuclear iron (III) compounds. As shown by Mössbauer spectroscopy, the iron(III) ions are in the high-spin state. In trinuclear cations, antiferromagnetic exchange interaction takes place between the Fe(III) ions with the exchange parameter J = -26.69 cm^?1 for II (Heisenberg-Dirac-Van Vleck model for D_3h, symmetry).     

Vibrational coupling in oxo-centred trinuclear clusters: oxygen-16/18 isotopic substitution studies of [Fe3III(O)(O2CC(CH3)3)6(py)3][FeCl4] and [Fe2(III)FeII(O)(O2CC(CH3)3)6(py)3

IR spectra are reported for the compounds [Fe3O(O2CC(CH3)3)6(py)3][FeCl4] and [Fe3O(O2CC(CH3)3)6(py)3]. Using isotopic substitution at the central oxygen atom, the assignments of the in-plane and out-of-plane vibrations of this atom are confirmed, and coupling is demonstrated between the in-plane modes v(as)(Fe3O) and carboxylate deformation modes rho(r)(C-CO2).     

鼓形有机锡氧杂环羧酸簇合物[PhCH2Sn(O)(O2CC4H3S)]6·2CH2Cl2和[PhCH2Sn(O)(O2CC3H2NO)]6·2CH2Cl2的合成和晶体结构

利用三苄基氧化锡与2-噻吩甲酸和2-唑甲酸反应, 合成了六聚体苄基锡氧2-噻吩甲酸酯(1)和六聚体苄基锡氧2-唑甲酸酯(2) 鼓形簇合物. 通过元素分析、红外光谱和X射线单晶衍射对其结构进行了表征. 测试结果表明: 化合物1属三斜晶系, 空间群P1, a=1.276 0(3) nm, b=1.305 6(3) nm, c=1.334 3(3) nm, α=105.65(3)°, β=96.27(3)°, γ=97.20(3)°, Z=1, V=2.099 7(7) nm3, Dc=1.809 g/cm3, μ=2.097 mm-1, F(000)=1 116, R=0.065 1, wR=0.129 2. 化合物2属三斜晶系, 空间群P1, a=1.224 0(4) nm, b=1.367 3(4) nm, c=1.374 4(4) nm, α=107.760(4)°, β=98.069(5)°, γ=91.480(5)°, Z=2, V=2.163 1(12) nm3, Dc=3.373 g/cm3, μ=3.799 mm-1, F(000)=2 136, R=0.038 2, wR=0.079. 它们均为鼓形簇状结构, 锡原子呈畸变的八面体构型. 化合物1通过分子间S…S近距离作用, 形成一维链状结构.     

脂氧合酶模型化合物[Fe(CTB)Cl]Cl·3CH3CH2OH·H2O的合成、晶体结构与氧化活性

合成了含Fe2+的脂氧合酶模型化合物[Fe(CTB)Cl]Cl.3CH3CH2OH.H2O(CTB为N,N,N,'N'-四(2'-苯并咪唑甲基)邻二胺反式-环己烷).该配合物属单斜晶系,P21/n空间群.晶胞参数a=1.12938(7)nm,b=1.49004(9)nm,c=2.69346(17)nm,β=91.9530(10),°V=4.5300(5)nm3,Z=4;R=0.0602,wR=0.1629.中心离子Fe2+只与六齿配体CTB的3个苯并咪唑的3-位氮和两个烷胺氮配位,氯离子占据着第六配位位点,整个配合物呈变形八面体构型.该化合物可催化亚油酸氧化断链成丙二醛(酸)、壬烯醛和壬醛酸等低分子醛和ω-氧酸.     

[{Rh(CO)(MeO)2PNEtP(OMe)2Cl}2]: A molecule with a symmetrical formula and an asymmetric structure

[{Rh(CO)(MeO)₂PNEtP(OMe)₂Cl)}₂], synthesised by reaction of [{Rh(CO)₂Cl)}₂] with (MeO)₂PNEtP(OMe)₂, has an unusual asymmetric structure in which one carbonyl group adopts a terminal position while the other is bridging; the two chlorines are both terminal.     

Neue amido‐ und imidoverbrückte Kupferkomplexe – Synthesen und Strukturen von [{Li(OEt2)}2][Cu(NPh2)3], [ClCuN(SnMe3)3], [{CuN(SnMe3)2}4], [Cu16(NH2tBu)12Cl16], [{CuNHtBu}8], [Li(dme)3][Cu6(NHMes)3(NMes)2], [PPh3(C6H4)CuNHMes], [{[Li(dme)][Cu(NHMes)(NHPh)]}2] und [{Li(dme)3}3][Li(dme)2][Cu12(NPh)8]

New Amido and Imido Bridged Complexes of Copper – Syntheses and Structures of [{Li(OEt₂)}₂][Cu(NPh₂)₃], [ClCuN(SnMe₃)₃], [{CuN(SnMe₃)₂}₄], [Cu₁₆(NH₂^tBu)₁₂Cl₁₆], [{CuNH^tBu}₈], [Li(dme)₃][Cu₆(NHMes)₃(NMes)₂], [PPh₃(C₆H₄)CuNHMes], [{[Li(dme)][Cu(NHMes)(NHPh)]}₂], and [{Li(dme)₃}₃][Li(dme)₂][Cu₁₂(NPh)₈] The reactions of stannylated and lithiated amines with coppersalts (halogenides, thiocyanates) lead to amido and imido bridged complexes which contain one to twelve metal atoms. [{Li(OEt₂)}₂][Cu(NPh₂)₃] ( 1 ) results from the reaction of CuCl with LiNPh₂ in the presence of trimethylphosphine. With N(SnMe₃)₃, CuCl reacts to the donor‐acceptor complex [ClCuN(SnMe₃)₃] ( 2 ) that is transformed into the tetrameric complex [{CuN(SnMe₃)₂}₄] ( 3 ) by thermolysis. 3 can also be obtained by the reaction of LiN(SnMe₃)₂ with Cu(SCN)₂. While terminally bound in 1 , the amido ligand is μ₂‐bridging between copper atoms in compound 3 . The influence of the alkyl amide's leaving group can be seen from a comparison of the reactivity of Me₃SnNH^tBu and LiNH^tBu, respectively. With Me₃SnNH^tBu, CuCl₂ forms the polymeric compound [Cu₁₆(NH₂^tBu)₁₂Cl₁₆] ( 4 ) whereas in the case of LiNH^tBu with both CuCl and CuSCN, the complex [{CuNH^tBu}₈] ( 5 ) is obtained. The latter contains two planar Cu₄N₄‐rings similar to those in 3 . If a mesityl group is introduced at the lithium amide, different products are accessible. Both, CuBr and CuSCN, lead to the formation of [Li(dme)₃][Cu₆(NHMes)₃(NMes)₂] ( 6 ) whose anion consists of a prismatic copper core with μ₂‐bridging amido and μ₃‐bridging imido ligands. In the presence of PPh₄Cl, a mixture of Cu(SCN)₂ and LiNHMes enables an ortho‐metallation reaction that produces [PPh₃(C₆H₄)CuNHMes] ( 7 ). From the reaction of CuSCN with LiNHMes and LiNHPh either the dimeric complex [{[Li(dme)][Cu(NHMes)(NHPh)]}₂] ( 8 ) or the cluster [{Li(dme)₃}₃][Li(dme)₂][Cu₁₂(NPh)₈] ( 9 ) results. The anion in 9 exhibits a cubo‐octahedron of copper atoms μ₃‐bridged by (NPh)^2–‐ligands. The solid state structures of compounds 1 – 9 have been determined by single crystal X‐ray diffraction.