Tetraphenylantimony(V) hexachloroplatinate, tetrachloroaurate, and hexachlorostannate [Ph4Sb] 2+ [PtCl6]2?, [Ph4Sb]+[AuCl4]?, and [Ph4Sb] 2+ [SnCl6]2?: Synthesis and crystal structures

The reactions of tetraphenylantimony with hexachloroplatinic and chloroauric acids in benzene afford bis(tetraphenylantimony) hexachloroplatinate (I) and tetraphenylantimony tetrachloroaurate (II), respectively. Compound II is also synthesized from tetraphenylantimony chloride and chloroauric acid in acetone. Bis(tetraphenylantimony) hexachlorostannate (III) is synthesized from tin dichloride and tetraphenylantimony chloride in acetone or from tin tetrachloride and tetraphenylantimony chloride in benzene. The crystal structures of compounds I–III are determined by X-ray diffraction analysis. The antimony atoms in the [Ph₄Sb]⁺ cations have a distorted tetrahedral coordination (CSbC bond angles range from 105.7(1)° to 118.5(1)° (I), from 106.2(3)° to 114.4(3)° (II), and from 106.0(1)° to 117.1(1)° (III)). The Sb-C bond lengths vary in intervals of 2.094(2)–2.098(2), 2.087(7)–2.111(7), and 2.093–2.100(3) ?, respectively. The coordination of the Pt and Sn atoms in complexes I and III is close to an ideal octahedral coordination with ClPtCl and ClSnCl bond angles of 88.68(2)°–91.32(3)° and 88.84(3)°–91.16(3)°, respectively. The square coordination of the Au atom in complex II is slightly distorted: the Au-Cl bond lengths are 2.266(2)–2.277(2) ?, the ClAuCl bond angles are equal to 89.7(1)°–90.5(1)°, the root-mean-square deviation of the atoms from the coordination plane being 0.004 ?. Original Russian Text ? V.V. Sharutin, V.S. Senchurin, O.A. Fastovets, A.P. Pakusina, O.K. Sharutina, 2008, published in Koordinatsionnaya Khimiya, 2008, Vol. 34, No. 5, pp. 373–379.     

Synthesis and structure of the platinum complexes [Bu4N]+[PtBr5(DMSO)]?, [Ph4P]+[PtBr5(DMSO)]?, and [Ph3(n-Am)P]+[PtBr5(DMSO)]?

The complexes [Bu₄N]₂⁺[PtBr₆]²⁻ (I), [Ph₄P]₂⁺[PtBr₆]²⁻ (II), and [Ph₃(n-Am)P]₂⁺ (III) are synthesized by the reactions of tetrabutylammonium bromide, tetraphenylphosphonium bromide, and triphenyl(n-amyl)-tetraphenylphosphonium bromide, respectively, with potassium hexabromoplatinate (mole ratio 2: 1). After recrystallization from dimethyl sulfoxide, complexes I, II, and III transform into [Bu₄N]⁺[PtBr₅(DMSO)]⁻ (IV), [Ph₄P]⁺[PtBr₅(DMSO)]⁻ (V), and [Ph₃(n-Am)P]⁺[PtBr₅(DMSO)]⁻ (VI). According to the X-ray diffraction data, the cations of complexes IV–VI have a slightly distorted tetrahedral structure. The N-C and P-C bond lengths are 1.492(7)–1.533(6) and 1.782(10)–1.805(10) ?, respectively. The platinum atoms in the mononuclear anions are hexacoordinated. The dimethyl sulfoxide ligands are coordinated with the Pt atom through the sulfur atom (Pt-S 2.3280(18)–2.3389(11) ?). The Pt-Br bond lengths are 2.4330(6)–2.4724(6) ?.     

Synthesis and structure of gold and copper complexes: [Ph3PhCH2P]+[AuCl4]?, [NH(C2H4OH)3]+[AuCl4]? · H2O, and [Ph3EtP] 2+ [Cu2Cl6]2?

Triphenylbenzylphosphonium tetrachloroaurate (I) and triethanolammonium tetrachloroaurate hydrate (II) were prepared by reacting tetrachloroauric acid in acetone with triphenylbenzylphosphonium and triethanolammonium, respectively. Triphenylethylphosphonium hexachlorodicuprate (III) was synthesized from triphenylethylphosphonium chloride and copper chloride in acetone. The crystal structures of complexes I to III were determined by single-crystal X-ray diffraction. The phosphorus atoms in complex I have a nearly undistorted tetrahedral coordination (CPC, 108.3°–110.6°; P-C, 1.788–1.793 ?). The coordination of nitrogen atoms in the cations of complex II is a distorted tetrahedron (CNC, 111.7°–112.4°). The square coordination of aurum in I and II is only slightly distorted: the ClAuCl angles are 89.6°–90.3° (I) and 89.5°–90.6° (II) and the Au-Cl distances are 2.256–2.278 ? I) and 2.280–2.285 ? (II). The phosphorus atoms in complex III are tetracoordinated (CPC, 106.34°–111.73°; P-C, 1.790–1.795 ?). The copper atoms in III have a distorted tetrahedral coordination (ClCuCl, 98.48°–144.85°; Cu-Cl, 2.1999–2.3263 ?). The central fragment Cu₂Cl₂ in the anion of complex III is bent relative to the Cu₂ axis (the chlorine atom deviates from the Cu₂Cl plane by 0.27 ?).     

Synthesis and structure of cobalt complexes [Me3EtN] 2+ [CoI4]2? and [Me3BuN] 2+ [CoI4]2?

Complexes [Me₃EtN]₂⁺[CoI₄]²⁻ (I) and [Me₃EtN]₂⁺[CoI₄]²⁻ (II) were synthesized by reacting trimethylalkylammonium iodide with cobalt(II) iodide in acetone. According to X-ray diffraction data, complexes I and II consist of tetrahedral tetraalkylammonium cations (for I, N-C is 1.481(5)–1.590(8) CNC is 107.3(3)°–111.6(3)°; for II, N-C is 1.485(8)–1.506(10) ? and CNC is 106.9(7)°–111.7(5)°) and [CoI₄]²⁻ anions (for I, Co-I is 2.5951(5)–2.6127(5) ? and ICoI is 104.67(2)°–113.23(2)°; for II, Co-I is 2.5914(8)–2.5943(9) ? and ICoI is 107.05(2)°–114.42(5)°).     

Phosphonium salts [Ph3AlkP] 2+ [Hg2I6]2? and [Ph3AlkP] 2+ [Hg4I10]2?: Synthesis and structure

Mercury complexes [Ph₃AlkP]₂⁺[Hg₂I₆]²⁻ and [Ph₃AlkP]₂⁺[Hg₄I₁₀]²⁻ (R = Me, Et, Pr, iso-Pr, Bu, iso-Bu) are synthesized by the reactions of triphenylalkylphosphonium Ph₃AlkPI with mercury iodide in acetone with the mole ratio 1: 1 and 1: 2, respectively. According to X-ray diffraction data, the phosphorus atom in the cations of the [Ph₃(iso-Pr)P]₂⁺[Hg₂I₆]²⁻, [Ph₃BuP]₂⁺[Hg₂I₆]²⁻, and [Ph₃(iso-Pr)P]₂⁺[Hg₄I₁₀]²⁻ complexes has a distorted tetrahedral coordination. The CPC bond angles and P-C bond lengths vary within 107.3(4)°-112.0(4)° and 1.774(8)-1.827(7) ?. In the [Hg₂I₆]²⁻ centrosymmetric binuclear anions, the mercury atoms of tetrahedral coordination lie in two near-perpendicular Hg₂I₆planes. Hg₄I₄ eight-membered cycles of the [Hg₄I₁₀]²⁻ tetranuclear anion are joined into polymeric chains through Hg … I coordination bonds (3.334, 3.681 &OA) due to which Hg atoms have a trigonal bipyramidal coordination. Original Russian Text ? V.V. Sharutin, V.S. Senchurin, N.N. Klepikov, O.K. Sharutina, 2009, published in Zhurnal Neorganicheskoi Khimii, 2009, Vol. 54, No. 2, pp. 267–273.     

Die halbquantitative Bestimmung von Cl?, Br?, J?, SCN?, AsO43?, Cr2O72? und [Fe(CN)6]3?

Ohne Zusammenfassung     

Unusual ion UO4? formed upon collision induced dissociation of [UO2(NO3)3]?, [UO2(ClO4)3]?, [UO2(CH3COO)3]? ions

The following ions [UO₂(NO₃)₃]⁻, [UO₂(ClO₄)₃]⁻, [UO₂(CH₃COO)₃]⁻ were generated from respective salts (UO₂(NO₃)₂, UO₂(ClO₄)₃, UO₂(CH3COO)2) by laser desorption/ionization (LDI). Collision induced dissociation of the ions has led, among others, to the formation of UO₄ ⁻ ion (m/z 302). The undertaken quantum mechanical calculations showed this ion is most likely to possess square planar geometry as suggested by MP2 results or strongly deformed geometry in between tetrahedral and square planar as indicated by DFT results. Interestingly, geometrical parameters and analysis of electron density suggest it is an U^VI compound, in which oxygen atoms bear unpaired electron and negative charge.     

Synthesis and structure of cobalt complexes [Ph3(n-Pr)P 2+ [CoI4]2? and [Ph3(n-Am)P 2+ [CoI4]2?

Complexes Ph₃(n-Pr)P₂⁺[CoI₄]²⁻ (I) and [Ph₃(n-Am)P]₂⁺ [CoI₄]²⁻ (II) were synthesized by reactions of triphenyl(alkyl)phosphonium iodide with cobalt(II) iodide in acetone. According to the X-ray diffraction data, complexes I and II consist of tetrahedral triphenyl(alkyl)phosphonium cations (for I, P-C is 1.787(4)–1.804(4) ? and CPC is 106.73(18)°–111.4(18)°; for II P-C is 1.786(6)–1.802(6) ? and CPC is 107.6(3)°–111.7(3)°) and [CoI₄]²⁻ anions (Co-I 2.5923(6)–2.6189(6) ?, ICoI 101.86(2)°–113.25(2)° for I; Co-I 2.5899(9)–2.6171(9) 107.01(3)°–110.47(3)° for II).     

Double complex salts with [Ru(NH3)5Cl]2+ cation and [OsCl6]2? anion: Synthesis and properties. Crystal structure of [Ru(NH3)5Cl]2[OsCl6]Cl2

Double complex salts [Ru(NH₃)₅Cl][OsCl₆] and [Ru(NH₃)₅Cl]₂[OsCl₆]Cl₂ were prepared and characterized. An X-ray diffraction study showed that [Ru(NH₃)₅Cl][OsCl₆] is isostructural to the previously synthesized [Rh(NH₃)₅Cl][OsCl₆]. The structure of [Ru(NH₃)₅Cl]₂[OsCl₆]Cl₂ was solved by X-ray diffraction (a = 11.1849(8) ?, b = 7.9528(6) ?, c = 13.4122(9) ?; β = 99.765(2)°; V= 1175.75 ?³; space group C2/m; Z = 2). Thermolysis of the compounds under hydrogen and helium was studied. According to X-ray diffraction, nanosized metallic powders of the corresponding alloys are formed as the final products of thermolysis. The compositions of the obtained solid solutions are consistent with the phase diagram of the Ru-Os system.     

Multiple-layer heterometallic MnII–AgI coordination polymers constructed from [Ag 2I (CN)3]? and [AgI(CN)2]? units

Two multiple-layer heterometallic Mn^II–Ag^I coordination polymers, {Mn^II(ampyz)(H₂O)[Ag₂^I(CN)₃][Ag^I(CN)₂]·ampyz} _n (1) and {[Mn^II(benzim)₂[Ag^I(CN)₂]₂][(benzim)Ag^I(CN)]·H₂O} _n (2) where ampyz = 2-aminopyrazine and benzim = benzimidazole, have been prepared and structurally characterized. Compound 1 reveals a multiple-layer two-dimensional network with strong hexanuclear argentophilic interactions leading to an infinite three-dimensional framework. Compound 2 has an unprecedented double-layer two-dimensional squared grid-type network with (4,4) topology through Ag^I···Ag^I and π–π interactions between two adjacent squared layers. These double-layer networks of 2 are linked to others by π–π interactions, leading to a three-dimensional framework.     

Bismuth compounds [Ph3BuP]+I?, [Ph3BuP] 2+ [Bi2I8 · 2Me2C=O]2?, and [Ph3BuP] 2+ [Bi2I8 · 2Me2S=O]2?: Syntheses and crystal structures

The complexes [Ph₃BuP]₂⁺[Bi₂I₈ · 2Me₂C=O]²⁻ (II) and [Ph₃BuP]₂⁺[Bi₂I₈ · 2Me₂S=O]²⁻ (III) are synthesized by the reactions of triphenyl(n-butyl)phosphonium iodide (I) with bismuth iodide in acetone and dimethyl sulfoxide. In the cations of complexes I–III, the P atoms have a distorted tetrahedral coordination (CPC angles 106.3(2)°–112.0(3)°). The butyl group in cation I is disordered over two positions. In the binuclear centrosymmetric anions of structures II and III, the octahedrally coordinated bismuth atoms are linked in pairs by two bridging (br) iodine atoms (Bi-I_br 3.1508(7) and 3.2824(8) ? in compound II, 3.1961(3) and 3.3108(3) ? in complex III), which are coplanar to four terminal (t) iodine atoms (Bi-I_t 2.9260(7) and 2.9953(6) ? in complex II, 2.9206(3) and 2.9786(3) ? in complex III). The two remaining positions at the bismuth atom are occupied by the iodine atom (Bi-I_t 2.8531(7) ? in complex II, 2.8984(3) ? in complex III) and O atom of the organic molecule (Bi-O 2.747(6) ? in complex II, 2.507(3) ? in complex III). Original Russian Text ? V.V. Sharutin, I.V. Egorova, N.N. Klepikov, E.A. Boyarkina, O.K. Sharutina, 2009, published in Koordinatsionnaya Khimiya, 2009, Vol. 35, No. 3, pp. 188–192.     

Coordination polymers based on [Re6Se8(CN)6]4? cluster anion, lanthanide cations, and tetraatomic alcohol erythritol

By the interaction of aqueous solutions of salts of the [Re₆Se₈(CN)₆]⁴⁻ cluster anion with salts of Nd(III), Tb(III), and Yb(III) lanthanides in the presence of tetraatomic alcohol erythritol (butane-1,2R,3S,4-tetraol) three new compounds are obtained: K[Nd(C₄H₁₀O₄)(H₂O)₄{Re₆Se₈(CN)₆}]·4H₂O (P $ \bar 1 $ \bar 1 space group, a = 11.544 ?, b = 13.643 ?, c = 13.838 ?, α = 111.97°, β = 108.08°, γ = 90.08°) (1); [{Yb₂(C₄H₉O₄)₂ × (H₂O)₂}{Re₆Se₈(CN)₆}]·5H₂O (P $ \bar 1 $ \bar 1 space group, a = 10.308 ?, b = 10.505 ?, c = 11.154 ?, α = 88.21°, β = 81.83°, γ = 78.50°) (2); [{Tb₂(C₄H₉O₄)₂(C₄H₁₀O₄)}{Re₆Se₈(CN)₆}]·4H₂O (P $ \bar 1 $ \bar 1 space group, a = 10.002 ?, b = 10.276 ?, c = 11.762 ?, α = 91.32°, β = 104.01°, γ = 106.02°) (3). The structures of these compounds are the coordination polymers (chain (2) and grids (1 and 3)) with different coordination modes of erythritol to the lanthanide cations.     

12,52-二羟基-15,55-二甲基-14,16,34,36,54,56,74,76-八硝基-2,4,6,8-四氧桥连-1,3,5,7（1,3）-杯[4]芳烃的合成

以1,5-二氟-2,4-二硝基苯和3,4,5-三甲氧基甲苯为起始原料,经环化、甲基化、硝化和去甲基化反应，合成了一种新型杯芳烃衍生物，其结构经¹H NMR，¹³C NMR，¹⁵N NMR和元素分析表征。      

Synthesis, crystal and electronic structure, and theoretical investigations of charge-transfer, optical, and bonding properties of a [VF6]3? anion compound

Abstract  

A green-colored V(III) compound, imidazolium hexafluorovanadium(III), [C₃H₅N₂)]₃[VF₆], has been prepared and characterized. The geometric and electronic structure, together with charge-transfer, optical, and bonding properties, were thoroughly investigated by X-ray crystallography, density functional theory (DFT), and time-dependent density functional theory (TDDFT) calculations. The low-energy charge-transfer bands responsible for its green color may be theoretically assigned to a F(2p) → V(4p) ligand-to-metal charge-transfer transition. The ligand-field charge-transfer bands (d → d bands) occur at a lower energy region; they are too weak and will be obscured by the quite intense ligand-to-metal bands in the optical spectrum. Partial density of states analysis clearly shows that the nature of metal–ligand interactions in [VF₆]³⁻ is mainly ionic.     

Radiometrische Titrationen mit [60Co(CN)6]3?-Ionen

Ohne Zusammenfassung     

[Pt2(P2O4H2)4]4-和[Pt2(P2O4CH4)4]4-基态和激发态性质的理论研究

采用从头计算MP2和CIS方法分别优化等电子双核d⁸配合物[Pt₂(P₂O₄H₂)₄]^4-和[Pt₂(P₂O₄CH₄)₄]^4-的基态和激发态结构。结果表明基态Pt-Pt距离分别为0.290 5和0.298 7 nm，与实验的0.292 5和0.298 0 nm符合。NBO计算的Pt-Pt键级以及Pt原子间伸缩振动说明Pt-Pt相互作用具有吸引本质。CIS计算揭示电子激发到Pt-Pt的σ(p_z)成键轨道使得相互作用增强。保持激发态几何，含时密度泛函理论(TD-DFT)计算的溶液发射分别为449和475 nm，与实验值512和510 nm接近。     

Titanium(IV) polynuclear hydroxo complexes stabilized in solution by [PW11O39]7? heteropolyanion

[PW₁₁O₃₉]^7– heteropolyanion (HPA) stabilizes Ti(IV) in aqueous solution at Ti:PW₁₁ ratios from 1 to 12 and pH 1–3. Ti(IV) is completely precipitated under these conditions in the absence of HPA. Differential dissolution phase analysis, optical, IR,³¹P and¹⁷O NMR spectra show that one Ti(IV) ion is incorporated into the Keggin lattice. The other ions, most probably, are located on the HPA surface in the form of oligomeric hydroxo fragments: [PW₁₁Ti^IVO₄₀·Ti_n–1 ^IVO_xH_y]^k–. Both types of Ti(IV) ions bind peroxo groups on interaction of the complex with H₂O₂.     

Measurement of mean ionic activity coefficients for tetra-n-butyl ammonium salts of PF 6? and [B(C6F5)4]? in tetrahydrofuran and acetonitrile

Osmotic coefficients were measured for tetra-n-butylammonium hexafluorophosphate (TBA PF₆) and tetra-n-butylammonium tetrakis(pentafluorophenyl)borate (TBABARF) in tetrahydrofuran and in acetonitrile. These osmotic coefficients were fit using equations first derived by Pitzer. Mean ionic activity coefficients were determined using the integrated form of the Pitzer equations. Densities were measured for each of the solutions and the results were used to convert mean ionic activity coefficients on the molal scale to the molar scale. Remarkably, over concentrations ranging from 0.1 to 1.0 m in acetonitrile, the behavior of TBABARF is consistent with the simple Debye-Hückel equation. Published in Russian in Elektrokhimiya, 2008, Vol. 44, No. 1, pp. 66–73. The text was submitted by the authors in English.     

新型微孔磷酸铝[C4N2H14]2+[H2Al3P3O14]2-的合成、结构及相转变

以3-甲氨基丙胺为结构导向剂,在水热条件下合成了1个具有三维开放骨架结构的微孔磷酸铝化合物[C4N2H14][H2Al3P3O14](1),并通过X射线单晶衍射确定了其结构,用粉末X射线衍射(PXRD)、热重(TG)、元素分析(ICP及CHN)和扫描电子显微镜(SEM)对其进行表征.结果表明,化合物1属正交晶系,Pbca空间群,晶胞参数a=1.59839(11)nm,b=0.99402(6)nm,c=1.82261(11)nm,V=2.8958(3)nm3.化合物1的无机骨架由铝氧多面体(AlO5/AlO6)和磷氧四面体(PO4)严格交替连接构筑而成,形成了在[010]方向上具有一维十元环孔道的三维阴离子开放骨架.每个P原子通过桥氧原子与相邻的4个Al原子相连,而Al原子除了通过桥氧原子与相邻的4个P原子相连之外,还通过羟基的桥氧原子与1个或2个Al原子相连,分别形成五配位和六配位的Al.化合物1在550℃空气或氧气气氛下灼烧5 h后转变为具有ATV分子筛结构的微孔磷酸铝分子筛AlPO4-25,且一直稳定到800℃.     

同时含α-[Mo8O26]4-和β-[Mo8O26]4-的新型超分子化合物的合成、表征及其抗肿瘤活性

以(NH4)2[Mo4O13]·2H2O, NiCl2·6H2O和2-(1H-吡唑-3-基)吡啶为原料, 通过水热方法合成了一个新颖的[Ni(C8N3H7)3]4[Mo8O26]2·7H2O超分子化合物. 采用元素分析、红外光谱和单晶X射线衍射法表征了该无机-有机杂化配合物的结构. 晶体解析表明, 该化合物同时含有α-[Mo8O26]4-和β-[Mo8O26]4-, 在[Ni(C8N3H7)3]2+阳离子和[Mo8O26]4-阴离子之间通过氢键作用结合, 在[Ni(C8N3H7)3]2+阳离子之间通过芳香环的π-π堆积作用连接, 两种[Mo8O26]4-阴离子作为客体共存于一个具有三维蜂窝状的超分子结构中. 同时研究了该化合物对人卵巢癌细胞SK-OV-3、肺癌细胞A549、宫颈癌细胞Hela和乳腺癌细胞MCF-7等细胞的体外抗肿瘤活性. 结果表明, 该化合物对3种不同来源的肿瘤细胞均有一定的增殖抑制作用, 其中对MCF-7细胞的IC50值为6.48 μmol/L, 具有进一步研究的价值.