(2)(∞)[Co{1,4-C6H4(CN)2}2{NTf2}2][SnI{Co(CO)4}3](2)--a 2D coordination network with an intercalated carbonyl cluster

Dark red transparent crystals of [Co{1,4-C(6)H(4)(CN)(2)}(2){NTf(2)}(2)][SnI{Co(CO)(4)}(3)](2) are obtained by reacting SnI(4), Co(2)(CO)(8) and 1,4-C(6)H(4)(CN)(2) in the ionic liquid [EMIm][NTf(2)] (EMIm: 1-ethyl-3-methylimidazolium; NTf(2): bis(trifluoromethylsulfonyl)imide). According to X-ray structure analysis based on single crystals, the title compound crystallizes in a triclinic manner and contains the novel (2)(∞)[Co{1,4-C(6)H(4)(CN)(2)}(2){NTf(2)}(2)] coordination network. This infinite 2D network is composed of Co(2+) ions that are planarily interlinked by four 1,4-dicyanobenzene ligands. As a non-charged 2D network, Co(2+) is furthermore coordinated by two [NTf(2)](-) anions. The (2)(∞)[Co{1,4-C(6)H(4)(CN)(2)}(2){NTf(2)}(2)] layers are stacked on top of each other with SnI[Co(CO)(4)](3) molecules intercalated in distorted cubic gaps between the layers. The title compound is furthermore characterized by energy dispersive X-ray (EDX) analysis, thermogravimetry (TG), infrared spectroscopy (FT-IR) and optical spectroscopy (UV-Vis).     

tBuN = VCl2 · 1,2-Dimethoxoethan,eine Schlüsselverbindung zur Darstellung von zweikernigen,diamagnetischen tert-Butylimidovanadium(IV)-Verbindungen

^tBuN = VCl₂ · 1,2-Dimethoxoethane, a Precursor in the Synthesis of Binuclear Diamagnetic tert -Butylimidovanadium(IV) Compounds Syntheses of the paramagnetic tert-butylimidovanadium(IV) complexes ^tBuN = VCl₂ · DME ( 7 ), ^tBuN = VCl₂ · 2 L (L = 1,4-dioxane, thf, PMe₃, PEt₃, pyridine) and ^tBuN = VBr₂ · DME are described; the free Lewis acids has been found by mass spectroscopy to be the binuclear compounds [(μ-N^tBu)₂V₂Cl₄] und [(μ-N^tBu)₂V₂Br₄]. 7 reacts with LiOR, LiOAr and LiNR₂ forming binuclear diamagnetic tert-butylimidovanadium(IV) compounds: [(μ-N^tBu)₂V₂Cl₂(OⁱPr)₂] ( 18 ), [(μ-N^tBu)₂V₂(OR)₄], [(μ-N^tBu)₂V₂Cl₂(OAr)₂], [(μ-N^tBu)₂V₂(OAr)₄] and [(μ-N^tBu)₂V₂Cl₂(NR₂)₂]. In additional experiments the complexes [(μ-N^tBu)₂V₂(CH₂CMe₃)₂(OAr)₂], [(μ-N^tBu)₂V₂Me₂(NR₂)₂], [(μ-N^tBu)₂V₂Cl₄] and ^tBuN = V(OAr)₃ has been prepared. All compounds obtained are characterized by spectroscopic methods (MS; ¹H, ¹³C, ⁵¹V NMR), [(μ-N^tBu)₂V₂Cl₂(N^tBuSiMe₃)₂] ( 21 ) by single crystal x-ray diffraction. For 18 the presence of cis/trans isomeres was shown by NMR spectroscopy. The ⁵¹V NMR spectra of the binuclear diamagnetic vanadium (IV) compounds are discussed.     

Synthesis and crystal structure of a three-dimensional 3d-4f heterometallic supramolecular complex {Eu(DMF)4(H2O)2Cr(CN)6·;H2O} n

A lanthanide-transition heterometallic supramolecular complex {Eu(DMF)₄(H₂O)₂Cr(CN)₆·H₂O} _n (1) has been synthesized based on the reaction of K₃[Cr(CN)₆], N,N-dimethylformamide (DMF) and Eu(NO₃)₃·6H₂O. 1 crystallizes in the monoclinic space group P2(1)/c with a=13.130(6)Å, b=12.923(7)Å, c=19.184(9)Å and Z=4. In 1 each Eu(III) is eight-coordinate with six oxygen atoms from four DMF molecules and two H₂O molecules and two nitrogen atoms from two cis-bridging CN ligands to form a distorted dodecahedron. 1 has a three-dimensional network created by the incorporation of coordinative linkage, three inter-molecular and an intrachain hydrogen bond.     

Koordinationschemie tripodaler Triisocyanid-Liganden: Synthese von Komplexen des Typs CH3C[CH2NC-M(CO)x]3 (M = Cr,W, χ = 5; M = Fe, χ = 4) und Kristallstruktur von CH3C[CH2NC-W(CO)5]3

The triisocyanide ligand CH₃C(CH₂NC)₃, time, reacts with metal carbonyls M(CO)_x (M = Cr, W, χ = 6; M = Fe, χ = 5) to give the triply metal carbonyl substituted complexes CH₃C[CH₂NCM(CO)_x]₃ (M = Cr, W, χ = 5; M = Fe, χ = 4). CH₃C[CH₂NCW(CO)₅]₃ was characterized by an X-ray structure determination.     

Platinum(II) cyclo-hexamethylenedithiocarbamate complex, [Pt{S2CN(CH2)6}2] and its solvated form, [Pt{S2CN(CH2)6}2] · CHCl3: Crystal and molecular structures, 13C CP/MAS NMR data, and thermal behavior

Platinum(II) cyclo-hexamethylenedithiocarbamate (HmDtc) complex, [Pt{S₂CN(CH₂)₆}₂] (I), and its solvated form, Pt{S₂CN(CH₂)₆}₂] · CHCl₃ (II), are synthesized and characterized by the ¹³C MAS NMR data. The HmDtc ligands in structure I are not equivalent, whereas the solvation of the complex is accompanied by the structural unification of the initially nonequivalent HmDtc ligands. In addition, the spectra are characterized by the ¹³C-¹⁹⁵Pt spin-spin coupling. The noncentrosymmetric molecular structure of compound I determined by X-ray diffraction analysis includes two nonequivalent dithiocarbamate ligands coordinated by the metal in the S,S′-bidentate mode. The central atom forming the [PtS₄] chromophore (intraorbital dsp ²-hybrid state of platinum) shifts from the plane of four sulfur atoms by 0.07 Å in the vertex of the flattened tetragonal pyramid. The seven-membered heterocycles ?N(CH₂)₆ of the HmDtc ligands are oppositely directed in space relative to the [S₄] plane (trans orientation). The thermal behavior of compounds I and II are studied by simultaneous thermal analysis. In both cases, the final product of the multistage thermal destruction of the complexes is reduced metallic platinum.     

Komplexe des 2-(Trimethylsiloxy)phenylisocyanids als Vorstufen für die Darstellung von N,O-Heterocarben-Komplexen

The reaction of 2-(trimethylsiloxy)phenylisocyanide 1 with PdI₂ or CoI₂ leads to the square-planar complex trans-[Pd(l)₂I₂] 2 and the octahedral complex trans-[CO(1₄I₂] 3, respectively. Both 2 and 3 were characterized by X-ray structure analysis. Cleavage of the Si-O bond gives complexes with coordinated 2-hydroxyphenylisocyxanide ligands which rearrange via an intramolecular nucleophilic attack of the hydroxyl oxygen at the isocyanide carbon to give complexes with cyclic N,O-heterocarbene ligands.     

Cluster cyanide-bridged heterometallic coordination polymers: synthesis and crystal structures of compounds [{Cu2(dien)2(CN)}2{Mo4Te4(CN)12}]·14.5H2O and (H3O)3K[{Mn(H2O)2}2{Mn(H2O)2(NO3)}4{W4Te4(CN)12}2]·8H2O

The reactions of anionic molybdenum and tungsten cyanide cuboidal clusters with Cu^II and Mn^II salts afforded two new cyanide-bridged heterometallic coordination polymers with the composition [{Cu₂(dien)₂(CN)}₂{Mo₄Te₄(CN)₁₂}]?14.5H₂O (1) and (H₃O)₃K[{Mn(H₂O)₂}₂{Mn(H₂O)₂(NO₃)}₄{W₄Te₄(CN)₁₂}₂]·8H₂O (2). The structures of these compounds were established by X-ray diffraction analysis. Compound 1 has a layered structure, in which the cuboidal cluster fragments {Mo₄Te₄(CN)₁₂}^6? are linked to the copper atoms of the dinuclear fragments {(H₂O)(dien)Cu(μ-CN)Cu(dien)(H₂O)} through the bridging CN groups. Coordination polymer 2 has a framework structure, in which the cluster fragments {W₄Te₄(CN)₁₂}^6? are linked to the manganese(II) aqua complexes of two types, viz., the dinuclear fragment {Mn(μ₂-H₂O)₂Mn} and the tetranuclear cyclic fragment {(H₂O)₂Mn(μ₂-NO₃)}₄, through the bridging CN groups.     

CRYSTAL STRUCTURE OF {Mo_3(μ_3-S)(μ-S)_3 [S_2P(OEt}_2]_4·PhCH_2CN}

<正> Mr=2548.12, Triclinic, P1, a=15.941(5), b=15.957(2),c=20.240(6)A, α=76.41(2),β=83.87(2),γ=74.41(2)°,V=4814.6A3, Z=4, Dc=1.757g.cm-3, Final R=0.053 for 11867 reflections. There are two crystallographically independent M1 type trinuclear Mo cluster molecules with 'loose coordination site', A and B, in an asymmetric unit of the title crystal. They are formulated as {Mo3S4(u-dtp)(dtp)3.PhCH2CN}(dtp=[S2P(OEt)2]-) and have essentially identical cluster molecular configuration, but differ from each other in the conformations for the phenyl rings of the ligands PhCH2CN. The lengths of the Mo-Mo bonds are 2.750(1), 2.753(1),and 2.768(1)A for molecule A and 2.742(1), 2.756(1), and 2.764(1)A for molecule B, while the dihedral angles betweem the phenyl ring and the {Mo3} triangle are 25.0° and 94.9° for A and B respectively.     

Syntheses and structures of chalcogen–molybdenum clusters; [Mo3XSe6{S2P(OEt)2}3]Cl, [Mo3X(SeS)3{S2P(OEt)2}3]I and [Mo3 XSe3{S2P(OEt)2}4(py)] (X=0.65S+0.35Se,py= C5H5N)

The trinuclear Mo cluster [Mo3(3–X)(2–Se2)3{S2P-(OEt)2}3]Cl (X=0.65S+0.35Se) (1) has been synthesised by reacting MoCl3·3H2O with ZnSe and [Me4N][S2P(OEt)2] in an EtOH/HCl medium. Reduction of (1) by Ph3P in the presence of [Me4N]-[S2P(OEt)2] and pyridine gave [Mo3(3–X)(2–Se)3 {S2P(OEt)2}4(py)] (X=0.65S+0.35Se, py=C5H5N) (2). Complex (2) was, in turn, converted into [Mo3(3–X)(2–SeS)3{S2P(OEt)2}3]I (X=0.65S+0.35Se) (3) by treatment with H2S and I2. The structures of complexes (1), (2) and (3) were established by X-ray crystallography.     

Novel Low Dimensional Cluster Compounds: Syntheses and Crystal Structures of Cs[{Me3Sn}3{Re6Se8(CN)6}], [{Me3Sn(H2O)}2{Me3Sn}{Re6Se8(CN)6}] · H2O, and [(Me3Sn)3(OH)2][{Me3Sn}3{Re6Se8(CN)6}]. pH Control of the Structural Dimensionality

Three novel cluster complex compounds Cs[{Me₃Sn}₃{Re₆Se₈(CN)₆}] (1), [{Me₃Sn(H₂O)}₂{Me₃Sn}{Re₆Se₈(CN)₆}] · H₂O (2) and [(Me₃Sn)₃(OH)₂][{Me₃Sn}₃{Re₆Se₈(CN)₆}] (3) have been synthesized by reaction of Cs₃KRe₆Se₈(CN)₆ with SnMe₃Cl in aqueous solutions at different pH values (pH ～7 for 1, pH <7 for 2 and pH >7 for 3). The crystal structures of all compounds have low dimensional features (linear chains in 1, zig-zag chains in 2; layers in 3), they are polymeric ones based on ${-}{\rm Re}_{6}{-}{\rm CN}{-}{\rm SnMe}_{3}{-}{\rm NC}{-}{\rm Re}_{6}{-}$ bonding. The connectivity of these structures is determined strongly by reaction conditions, in particular, pH of reaction solutions.     

Übergangsmetall-Carbin-Komplexe: CIII. Aktivierung von Ethylisocyanid an elektronenreichen Metallzentren; Synthese von einkernigen Wolfram-Aminocarbin-Komplexen des Typs Tp′(CO)2 WCN(R)Et (R  Me,Et)

A large-scale, high-yield synthesis of the aminocarbyne complexes Tp′(CO)₂WCN(R)Et (5: R  Me; 6: R  Et) [Tp′ = hydridotris(3,5-dimethylpyrazol-1-yl)borate] is reported, starting from Tp′W(CO)₃I (2). The first step of the synthetic procedure involves thermal decarbonylation of 2 with EtNC to give cis-Tp′W(CO)₂(CNEt)I (3). Complex 3 is then reduced with Na/Hg to give the metallate Na[Tp′W(CO)₂(CNEt)] (4). Finally, complex 4 is alkylated with RI (R  Me, Et) exclusively at the isocyanide nitrogen to give the aminocarbyne complexes 5 and 6. In contrast, the metallates Na[(η⁵-C₅R′₅)W(CO)₂(CNEt)] (R′  H, Me) undergo alkylation with RI at the metal centre to afford the W^II alkyl complexes cis/trans-(η-C₅R′₅)W(CO)₂(CNEt)R. This difference in reactivity is ascribed to the steric demands of the Tp′ ligand, which shields the metal centre from the incoming electrophile.     

STRUCTURE OF PLATINUM HYDRIDE WITH BULKY PHOSPHINE LIGANDS trans-PtH (PCy_3)_2 {S_2CN (CH_2C_6H_5)_2}

<正> trans-PtH(PCy3)2[S2CN(CH2C6H5)2] crystallizes in triclinic space group P1 with a=10. 961 (9),b= 13. 247 (6), c= 18. 331(4) A ,α=82. 97(2) ,β= 103. 89(5),γ=103. 79(7)°,Mr=1029. 39,V = 2503(4)A3,Z = 2,Dc = 1. 366g/cm3, μ= 30. 06cm-1,F(000) = 1068,R=0. 033 and Rw = 0. 039 for 6940 unique observed reflections. The platinum atom is coordinated by one hydrogen,one sulfur and two phosphorus atoms to form a distorted square plane.     

Electrochemistry of Interaction Between Flavin Mononucleotide (FMN) and PM-17 as Antitumoral ε-Keggin Core Compound, \left[ {{\text{H}}_{ 2} {\text{Mo}}_{ 1 2}^{\text{V}} {\text{O}}_{ 2 8} \left( {\text{OH}} \right)_{ 1 2} \left( {{\text{Mo}}^{\text{VI}} {\text{O}}_{ 3} } \right)_{ 4} } \right]^{ 6- } at pH 7.5

In order to obtain a clue to the antitumor mechanism of $\left[ {{\text{Me}}_{ 3} {\text{NH}}} \right]_{ 6} \left[ {{\text{H}}_{ 2} {\text{Mo}}_{ 1 2}^{\text{V}} {\text{O}}_{ 2 8} \left( {\text{OH}} \right)_{ 1 2} \left( {{\text{Mo}}^{\text{VI}} {\text{O}}_{ 3} } \right)_{ 4} } \right]$ ·2H₂O (PM-17), the interaction of PM-17 with flavin mononucleotide (FMN) as a prosthetic group of the flavoprotein has been investigated by both polarographic analysis and isothermal titration calorimetry (ITC) technique at the physiological solution pH (7.5). The half-wave potential (?0.50 V vs. Ag/AgCl) of the d.c. polarogram for the quasi-reversible one-electron reduction of FMN was shifted by PM-17 toward a more positive potential with a resultant deviation from one-electron reduction to formally more than one-electron reduction waves. The PM-17 effect on the d.c. polarogram could be explained by a variety of FMN···(PM-17)_n (n > 0) aggregates with multiple conformations which was supported by the thermodynamic parameters (ΔH = ?29.7 kJ mol^?1, ΔS = ?28.2 J mol^?1 K^?1, ΔG = ?21.5 kJ mol^?1, and number of FMN in the binding with PM-17 (N) = 0.053 at 20 °C) estimated by the ITC technique. A large conformational change of the FMN domain by the FMN···(PM-17)_n aggregates is suggested to prevent the movement of the FMN centers into close proximity with nicotinamide adenine dinucleotide (NADH) with a resultant depression of the electron transport in NADH dehydrogenase.     

Chemisorption of the [AuCl4]− anion by cadmium cyclo-pentamethylenedithiocarbamate and the resulting bound-gold(III) species: The supramolecular structure and thermal behavior of the polynuclear complexes ([Au{S2CN(CH2)5}2]2[CdCl4]) n and ([Au{S2CN(CH2)5}Cl2]) n

The interaction between cadmium cyclo-pentamethylenedithiocarbamate (chemisorbent Ia) and the [AuCl₄]^? anion in 2 M HCl has been investigated. The state of the chemisorbent in contact with AuCl₃ solutions has been probed by ¹¹³Cd MAS NMR spectroscopy. The heterogeneous reactions in the system, including gold(III) chemisorption from the solution and partial ion exchange, yield the gold(III)-cadmium heteropolynuclear complex ([Au{S₂CN(CH₂)₅}₂]₂[CdCl₄]) _n (I) and the polynuclear mixed-ligand complex ([Au{S₂CN(CH₂)₅}Cl₂]) _n (II). The crystal and molecular structures of these compounds have been determined by X-ray crystallography. The main structural units of the compounds are the complex cation [Au{S₂CN(CH₂)₅}₂]⁺, [CdCl₄]^2? anion (in I), and Au{S₂CN(CH₂)₅}Cl₂ molecule (in II). The further structural self-organization of the complexes at the supramolecular level is due to secondary Au...S and Au...Au bonds. [Au₂{S₂CN(CH₂)₅}₄]²⁺ dinuclear cations form in the structure of I, which then polymerize into ([Au₂{S₂CN(CH₂)₅}₄]²⁺) _n chains. In the structure of II, adjacent Au{S₂CN(CH₂)₅}Cl₂ molecules join by forming pairs of asymmetric secondary Au...S bonds, producing polymer chains with alternating antiparallel monomer units. The chemisorption capacity values calculated for cadmium cyclo-pentamethylenedithiocarbamate from gold(III) binding reactions are 455 and 910 mg of gold per gram of sorbent. The gold recovery conditions have been determined by investigating the thermal behavior of I and II by synchronous thermal analysis. The multistep thermal destruction of ionic complex I includes the thermolysis of its carbamate moiety and [CdCl₄]_2? (which liberates gold metal and cadmium chloride and yield some amount of CdS) and CdCl₂ and CdS evaporation. The thermolysis of II proceeds via the formation of Au₂S and AuCl as intermediate compounds. In both cases, the ultimate pyrolysis product is elemental gold.     

Fixation mode of gold(III) in [Cd{S2CN(CH2)4O}2] n -[AuCl4]−/2 M HCl chemisorption system: Preparation, supramolecular self-organization and thermal behavior of the heteropolynuclear complex ([Au{S2CN(CH2)4O}2]2[CdCl4] · H2O) n

A capability of freshly deposited cadmium complex with cyclic morpholinodithiocarbamate ligand (MfDtc) to bind gold(III) from 2 M HCl solutions was studied. The individual form of bound gold (III) isolated from solution was found to be the hydrated heteropolynuclear complex of ionic type ([Au{S₂CN(CH₂)₄O}₂]₂[CdCl₄] · H₂O) _n (I). Molecular and supramolecular structure of preparatively isolated compound I was established by X-ray diffraction study, the structure includes four (1: 1: 1: 1) structurally nonequivalent centrosymmetric complex cations [Au{S₂CN(CH₂)₄O}₂]⁺ which relate to each other in agreement with appeared structural differences as conformers: A, B, C, and D cations with Au(1), Au(2), Au(3), and Au(4), respectively. At the supramolecular level, the isomeric complex cations undergo structural self-organization to form independent polymeric chains of two types: (-A-C-) _n and (-B-D-) _n on account of pairs of unsymmetrical secondary Au…S bonds (3.463, 3.496, and 3.627, 3.669 Å). Distorted tetrahedral [CdCl₄]^2? anions are located in the space between these chains. The chemisorption capacity of cadmium morpholinodithiocarbamate calculated from gold(III) binding is 450.8 mg Au³⁺ per 1 g of sorbent (i.e., each mononuclear fragment of the chemisorbent complex [Cd{S₂CN(CH₂)₄O}₂] binds one gold atom. The conditions of recovery of bound gold were found in the study of thermal behavior of I by simultaneous thermal analysis (STA). The multistep process of thermal destruction includes complex dehydration, thermolysis of its dithiocarbamate fragment and [CdCl₄]^2? to release gold metal, cadmium chloride, and partially CdS.     

Unique seven-node rare-earth octacyanomolybdate(IV) three-dimensional molecular frameworks: {[Er(H2O)5(Er(H2O)4)3][Mo(CN)8]3·11H2O}n and {[Eu(H2O)5(Eu(H2O)4)3][Mo(CN)8]3·11H2O}n

The crystal structure analyses of {[Er(H₂O)₅(Er(H₂O)₄)₃][Mo(CN)₈]₃·11H₂O}_n (1) and {[Eu(H₂O)₅(Eu(H₂O)₄)₃][Mo(CN)₈]₃·11H₂O}_n (2), show that they are not only new neutral three-dimensional rare-earth octacyanomolybdate(IV) molecular frameworks, but that they also belong to an unknown structure type having seven different nodes. To the best of our knowledge this is different to any other known molybdenum(IV) octacyanide complexes published to date. Both compounds crystallize in the triclinic system, space group P-1, and are isostructural and isotypic. The coordination polyhedra of the molybdenum atoms in the three different [Mo(CN)₈]⁴⁻ anions are trigonal prisms, with two additional atoms. A new bridging mode for octacyanometallates is also observed with five of the eight cyanide groups involved in bridging either three or four rare-earth atoms, while the three remaining cyanide groups are terminal and are involved in hydrogen bonding. The four rare-earth atoms in 1 and 2 have different coordination polyhedra in the form of trigonal prisms with two additional atoms. The three-dimensional structures are made up of infinite two-dimensional slabs linked by one of the rare-earth metal atoms. In both compounds, apart from the 17 coordinated water molecules, there are 11 lattice water molecules of crystallization present in the cavities of the three-dimensional frameworks. The 28 water molecules and the terminal CN⁻ groups are involved in an extensive O–H⋯O and O–H⋯N hydrogen bonding network.     

Synthesis,chemical, and electrochemical characterization of the [Ag13{μ3-Fe(CO)4}] n− (n = 3, 4, 5) cluster anions: X-Ray structural determination of [N(PPh3)2]3 [Ag12(μ12-Ag){μ3Fe(CO)4}8]1

The oxidation of the [Fe(CO)₄]^2– dianion with Ag⁺ salts occurs through a particularinner-sphere mechanism, which involves an intermediate cascade of silver clusters stabilized by Fe(CO)₄ ligands. The last detectable Ag-Fe cluster of the sequence is the [Ag₁₃{-Fe(CO)₄}₈]^3– trianion, which has been selectively obtained by using ca. 1.7 equivalents of Ag⁺ per mole of [Fe(CO)₄]^2–. The [Ag₁₃{-Fe(CO)₄}₈]^3–- trianion has been isolated in a crystalline state with several quaternary cations, and has been characterized by X-ray diffraction studies of its bis(triphenylphosphine)iminium salt. [N(PPh₃)₂]₃ [Ag₁₃{ ₃-Fe(CO)₄}₈]·2(CH₃)₂CO, monoclinic, space group P2₁ (No.4),a = 16.284(2) Å,b =18.767(5) Å,c = 25.905(4) Å, = 90.46(1)°,V = 7916(3) ų,Z = 2,R = 0.0324. The molecular structure of the anion consists of a centered cuboctahedron of silver atoms with the triangular faces capped by Fe(CO)₄ units. Chemical reduction of ( Ag₁₃{ ₃-Fe(CO)₄}₈]^3– affords the corresponding [Ag₁₃{ ₃-Fe(CO)₄)₈]^4–, which in turn gives [Ag₁₃{ ₃-Fe(CO)₄)₈]^5– and [Ag₆{ ₃-Fe(CO)₄}₄]^– upon further reduction. Electrochemical investigations confirm the reversibility of the [Ag₁₃{ ₃-Fe(CO)₄}₈]^3–/4– redox change. Furthermore, in spite of some electrode poisoning effects, evidence of the existence of the [Ag₁₃{ ₃-Fe(CO)₄}₈]^5– pentaanion was obtained. The yet structurally uncharacterized [Ag₆{ ₃-Fe(CO)₄)₄]^2– dianion is quantitatively obtained by reaction of [Fe(CO)₄]^2– with ca. 1.5 equivalents of Ag⁺ or by addition of one equivalent of Ag⁺ to solutions of the [Ag₅{Fe(CO)₄}₄]^3– trianion. All attempts to isolate its quaternary salts as crystalline materials failed owing to formation of amorphous insoluble precipitates. The above series of ₃-Fe(CO)₄ octa-capped cuboctahedral Ag₁₃ clusters can be envisioned as the Ag⁺ . Ag and Ag^– cryptates of the [Ag₁₂{}₃-Fe(CO)₄}₈]^4– cryptand. respectively.Dedicated to Prof L. F. Dahl on his 65th birthday.     

Binding of Gold(III) from Solutions by Tetranuclear Lead(II) Dipropyldithiocarbamate [Pb4{S2CN(C3H7)2}8] and Chemisorption Synthesis of the Double Ionic Polymer Complex ([Au{S2CN(C3H7)2}2][PbCl3] · 0.5CH3–C6H5)n: Heteronuclear ( 13 C, 15 N) CP-MAS NMR,Structural Organization,and Construction Principles of Cationic and Anionic Polymer Chains

Russian Journal of Coordination Chemistry - Solid-state 13C and 15N CP-MAS NMR data adequately reflected the presence of four nonequivalent PrDtc ligands in the tetranuclear lead(II)...