Ferrate(VI) and ferrate(V) oxidation of cyanide,thiocyanate, and copper(I) cyanide

Cyanide (CN⁻), thiocyanate (SCN⁻), and copper(I) cyanide (Cu(CN)₄³⁻) are common constituents in the wastes of many industrial processes such as metal finishing and gold mining, and their treatment is required before the safe discharge of effluent. The oxidation of CN⁻, SCN⁻, and Cu(CN)₄³⁻ by ferrate(VI) (Fe^VIO₄²⁻; Fe(VI)) and ferrate(V) (Fe^VO₄³⁻; Fe(V)) has been studied using stopped-flow and premix pulse radiolysis techniques. The rate laws for the oxidation of cyanides were found to be first-order with respect to each reactant. The second-order rate constants decreased with increasing pH because the deprotonated species, FeO₄²⁻, is less reactive than the protonated Fe(VI) species, HFeO₄⁻. Cyanides react 10³–10⁵ times faster with Fe(V) than with Fe(VI). The Fe(V) reaction with CN⁻ proceeds by sequential one-electron reductions from Fe(V) to Fe(IV) to Fe(III). However, a two-electron transfer process from Fe(V) to Fe(III) occurs in the reaction of Fe(V) with SCN⁻ and Cu(CN)₄³⁻. The toxic CN⁻ species of cyanide wastes is converted into relatively non-toxic cyanate (NCO⁻). Results indicate that Fe(VI) is highly efficient in removing cyanides from electroplating rinse water and gold mill effluent.     

Nickel(O)-Komplexe mit anionischen Liganden des Typs E(C6H5) (E = Si,Ge, Sn)

Nickel(O) Complexes with the Anionic Ligands E (C₆H₅)^?₃ (E = Si, Ge, Sn) Complexes of the type Me^I_XNi(EPH₃)_X(THF)_Y are formed from Ni(COD)₂ by substitution with Me^IEPh₃ (E = Si, Ge, Sn) in THF (COD = Cyclooctadiene-1,5). In the case of the ligands GePh^?₃ and SnPh^?₃ nickel(O) is fourfold coordinated, but in the case of SiPh^?₃ it is only two-fold or threefold coordinated. Products of the reaction between Ni(COD)₂ and LiPbPh₃ are Li₂Ni(COD)Ph₂(THF)₅ and Ph₃PbPbPh₃. The ¹H-n.m.r., ²⁹Si-n.m.r., and ¹¹⁹Sn-Mössbauer spectra of the complexes Me^I_XNi(EPh₃)_X(THF)_Y are compared with the spectra of the corresponding alkali compounds Me^IEPh₃. The magnetic anisotropy effects of the atomes Ge, Sn, Pb and Ni are of high importance for ¹H- and ²⁹Si-chemical shifts. The donor action of SnPh^?₃ is shown by the Mössbauer spectrum of Na₄Ni(SnPh₃)₄(THF)₄. But there is no direct evidence of π-back donation in the compound.     

Mercury(II) polyphosphate,Hg(PO3)2

Single crystals of mercury(II) polyphosphate, Hg(PO₃)₂, were prepared from HgO in an acidic polyphosphate melt. The structure is isotypic with α‐Cd(PO₃)₂ and comprises infinite polyphosphate chains with a period of four phosphate units. Chains of the form ¹_∞[PO₃^?] are linked by Hg²⁺ to form a three‐dimensional network. The Hg atom is located at the centre of a distorted octahedron of O atoms with distances 2.173 (5) < (Hg—O)_mean < 2.503 (6) Å. The [HgO₆] polyhedra form zigzag‐like chains of the form ¹_∞[HgO₂O_4/2] parallel to the c axis.     

Polymeric bis(N,N‐dimethylacetamide)tetrakis(thiocyanato)cadmium(II)mercury(II)

The title complex, {[CdHg(SCN)₄(C₄H₉NO)₂]₂}_n, contains two crystallographically independent Cd^II centres and two Hg^II centres. Each Cd^II atom is bound to four N atoms belonging to SCN groups and to two O atoms from N,N‐di­methyl­acet­amide (DMA) ligands in an octahedral geometry. Each Hg^II centre is tetrahedrally coordinated by four SCN S atoms.     

A density functional study of Fe(SINGLE BOND)N2, Fe(SINGLE BOND)N+2, and Fe(SINGLE BOND)N−2

The interaction of an iron atom with molecular nitrogen was studied using density functional theory. Calculations were of the all-electron type and both conventional local and gradient-dependent models were used. A ground state of linear structure was found for Fe(SINGLE BOND)N₂, with 2S + 1 = 3, whereas the triangular Fe(SINGLE BOND)N₂ geometry, of C_2v symmetry, was located 2.1 kcal/mol higher in energy, at least for the gradient-dependent model. The reversed order was found using the conventional local approximation. In Fe(SINGLE BOND)N₂, the N(SINGLE BOND)N bond is strongly perturbed by the iron atom: It has a bond order of 2.4, a vibrational frequency of 1886 cm⁻¹, and an equilibrium bond length of 1.16 Å: These values are 3.0, 2359 cm⁻¹, and 1.095 Å, respectively, for the free N₂ molecule. With the gradient-dependent model and corrections for nonsphericity of the Fe atom, a very small binding energy, 8.8 kcal/mol, was calculated for Fe(SINGLE BOND)N₂. Quartet ground states were found for both Fe(SINGLE BOND)N⁺₂ and Fe(SINGLE BOND)N⁻₂. The adiabatic ionization potential, electron affinity, and electronegativity were also computed; the predicted values are 7.2, 1.22, and 4.2 eV, respectively. © 1997 John Wiley & Sons, Inc.     

Reactions of tungsten(VI) and molybdenum(V) chlorides,and tungsten(VI) and molybdenum(VI) oxychlorides,with azoxybenzene

Reactions of W^VI and Mo^V chlorides with azoxybenzene yield ionic species of W^VI and Mo^VI oxychlorides in which the cation is a protonated azobenzene. The reaction between MoCl₅ or MoOCl₄ and azoxybenzene gives, after extraction with methylene chloride—ethanol mixture, the complex [trans-MoOCl₄(OC₂H₅)]^? [C₁₂H₁₀N₂H]⁺. In contrast, WOCl₄ reacts with azoxybenzene to give a stable non-ionic adduct in which the organic moiety is coordinated through its oxygen atom trans to the WO bond. Several complexes of substituted azoxybenzene having similar structures are described.     

Bis(N-octylsalicylideniminato-N,O)copper(II)

In the title compound, [Cu(C₁₅H₂₂NO)₂], the Cu^II cation lies on a centre of symmetry. The coordination geometry about the Cu^II ion is a parallelogram, formed by the N₂O₂ donor set of the two bidentate long alkane chain Schiff base imine–phenol ligands. The Cu—N and Cu—O distances are 2.009 (3) and 1.888 (3) Å, respectively.     

Conformational Properties of (Z,Z)-, (E,Z)-, and (E,E)-Cycloocta-1,4-dienes

Summary.  Ab initio calculations at the HF/6-31G^* level of theory for geometry optimization and the MP2/6-31G^*//HF/6-31G^* level for a single point total energy calculation are reported for (Z,Z)-, (E,Z)-, and (E,E)-cycloocta-1,4-dienes. The C ₂-symmetric twist-boat conformation of (Z,Z)-cycloocta-1,4-diene was calculated to be by 3.6 kJ·mol⁻¹ more stable than the C _S-symmetric boat-chair form; the calculated energy barrier for ring inversion of the twist-boat conformation via the C _S-symmetric boat-boat geometry is 19.1 kJ·mol⁻¹. Interconversion between twist-boat and boat-chair conformations takes place via a half-chair (C ₁) transition state which is 43.5 kJ·mol⁻¹ above the twist-boat form. The unsymmetrical twist-boat-chair conformation of (E,Z)-cycloocta-1,4-diene was calculated to be by 18.7 kJ·mol⁻¹ more stable than the unsymmetrical boat-chair form. The calculated energy barrier for the interconversion of twist-boat-chair and boat-chair is 69.5 kJ·mol⁻¹, whereas the barrier for swiveling of the trans-double bond through the bridge is 172.6 kJ·mol⁻¹. The C _S symmetric crown conformation of the parallel family of (E,E)-cycloocta-1,4-diene was calculated to be by 16.5 kJ·mol⁻¹ more stable than the C _S-symmetric boat-chair form. Interconversion of crown and boat-chair takes place via a chair (C _S) transition state which is 37.2 kJ·mol⁻¹ above the crown conformation. The axial- symmetrical twist geometry of the crossed family of (E,E)-cycloocta-1,4-diene is 5.9 kJ·mol⁻¹ less stable than the crown conformation. Corresponding author. E-mail: isayavar@yahoo.com Received March 25, 2002; accepted April 3, 2002     

31P- und 195Pt-NMR-Untersuchungen an Diplatin(I)-Komplexen des Typs [Pt2(μ-SPR2)2L2] (L = PR3, PhP(OPh)2, P(OPh)3, CNR)

³¹P and ¹⁹⁵Pt N.M.R. Investigations on Diplatinum (I) Complexes of the Type [Pt₂(μ-SPR₂)₂L₂] (L = PR₃, PhP(OPh)₂, P(OPh)₃, CNR) ³¹P-, ¹⁹⁵Pt-chemical shifts and ¹⁹⁵Pt–³¹P- resp. ³¹P–³¹P-coupling constants of a series of doubly bridged diplatinum(I) complexes are reported. ³¹P-coordination chemical shifts of the terminal ligands of complexes of type [Pt₂(μ-SPR₂)₂(P′R₃′)₂] and some of the various coupling constants are strongly influenced by the π-acceptor strength of these ligands. J(¹⁹⁵Pt–¹⁹⁵Pt) is found to change the sign among the series of complexes investigated. Thermal singlett triplet exitation giving rise to the paramagnetism of these complexes observed by preliminary EPR-measurements and confirmed by EHT-calculations is deduced from the large values of ²J(P–P′) and ³J(P′P′) as well as the unusually high temperature dependence of some coupling constants and other NMR features. The chemical stability of the doubly bridged core, the coordination shifts of the bridging phosphorus atoms and EHT-calculations suggest a view of aromaticity of the [Pt₂(μ-SPR₂)₂](M–M) unit of these complexes.     

Hydrolysis and Photolysis of Tris(tetraethylammonium) Pentacyanoperoxynitritocobaltate(III): Evidence for a Novel Complex,Pentacyanonitratocobaltate(III)

At pH 2, the rate constant of hydrolysis of tris(tetraethylammonium) pentacyanoperoxynitritocobaltate(III) in H₂O is 9.6×10⁻⁶ s⁻¹. In the absence of any light, ONOO⁻ is not replaced by H₂O and isomerizes within the coordination sphere to NO₃⁻. The novel complex [Co(CN)₅NO₃]³⁻ released NO₃⁻ slowly, as detected by ion chromatography. At pH 6, no hydrolysis is observed. Direct photolysis, both at pH 2 and pH 6, of tris(tetraethylammonium) pentacyanoperoxynitritocobaltate(III) by irradiation (YAG laser) at 355 nm destroys the coordinated ONOO⁻ and releases NO₂^., which hydrolyzes to NO₃⁻ and NO₂⁻. We also measured the ⁵⁹Co‐NMR spectra of [Co(CN)₅OONO]³⁻ and [Co(CN)₅H₂O]²⁻; the chemical shifts correspond very well to those predicted and are in agreement with the expected contribution to the ligand field by H₂O and ONOO⁻.     

Ruthenium(III)-Phthalocyanine: Darstelllung und Eigenschaften von Di(halogeno)phthalocyaninato(1−)ruthenium(III), [Ru(X)2Pc] (X = Cl,Br, I)

Ruthenium(III) Phthalocyanines: Synthesis and Properties of Di(halo)phthalocyaninato(1?)ruthenium(III) Di(halo)phthalocyaninato(1?)ruthenium(III), [Ru(X)₂Pc^?] (X = Cl, Br, I) is prepared by oxidation of [Ru(X)₂Pc^2?]^? (Cl, Br, OH) with halogene in dichloromethane. The magnetic moment of [Ru(X)₂Pc^?] is 2,48 μ_B (X = Cl) resp. 2,56 μ_B (X = Br) in accordance with a systeme of two independent spins (low spin Ru^III and Pc^?: S = 1/2). The optical spectra of the red violet solution of [Ru(X)₂Pc^?] (Cl, Br) are typical for the Pc^? ligand with the “B” at 13.5 kK, “Q₁” at 19.3 kK and “Q₂ region” at 31.9 kK. Sytematic spectral changes within the iron group are discussed. The presence of the Pc^? ligand is confirmed by the vibrational spectra, too. Characteristic are the metal dependent bands in the m.i.r. spectra at 1 352 and 1 458 cm^?1 and the strong Raman line at 1 600 cm^?1. The antisymmetric Ru? X stretch (v_as(Ru? X)) is observed at 189 cm^?1 (X = I) resp. 234 cm^?1 (X = Br). There are two interdependent bands at 295 and 327 cm^?1 in the region expected for v_as(Ru? Cl) attributed to strong interaction of v_as(Ru? Cl) with an out-of-plane Pc^? tilting mode of the same irreducible representation. Only the symmetric Ru? Br stretch at 183 cm^?1 is selectively enhanced in the resonance-Raman(RR) spectra. The Raman line at 168 cm^?1 of the diiodo complex is assigned to loosely bound iodine. The broad band at 978 cm^?1 in the RR spectra of the dichloro complex is due to an intraconfigurational transition within the electronic ground state of low spin Ru^III split by spin orbit coupling.     

Amine-containing tertiary phosphine-substituted diiron ethanedithioate (edt) complexes Fe2(μ-edt)(CO)6-nLn (n= 1, 2): Synthesis,protonation, and electrochemical properties

As diiron subsite models of [FeFe]-hydrogenases for catalytic proton reduction to hydrogen (H₂), a new series of the phosphine-substituted diiron ethanedithiolate complexes Fe₂(μ-edt)(CO)_6-nL_n (n = 1, 2) were prepared from the variable substitutions of all-CO precursor Fe₂(μ-edt)(CO)₆ ( A ) and tertiary phosphines (L1-L4) under different reaction conditions. While the Me₃NO-assisted substitutions of A and one equiv. ligands L1-L4 [L = Ph₂P(CH₂NHBu^t), Ph₂P(CH₂CH₂NH₂), Ph₂P(NHBu^t), and Ph₂P(C₆H₄Me-p)] produced the monosubstituted complexes Fe₂(μ-edt)(CO)₅L ( 1 – 4 ) in good yields, the refluxing xylene solution of A and two equiv. ligand L1 prepared complex Fe₂(μ-edt)(CO)₅{κ¹-Ph₂P(CH₂NHBu^t)} ( 1 ) in low yield. Meanwhile, the UV-irradiated toluene solution of A and two equiv. ligand L3 resulted in the rare formation of the disubstituted complex Fe₂(μ-edt)(CO)₄{κ¹, κ¹-(Ph₂PNHBu^t)₂} ( 5 ) in low yield, whereas the Me₃NO-assisted substitution of A and two equiv. ligand L4 afforded the disubstituted complex Fe₂(μ-edt)(CO)₄{κ¹, κ¹-(Ph₂PC₆H₄Me-p)₂} ( 6 ) in good yield. All the model complexes 1 – 6 have been characterized by elemental analysis, FT-IR, NMR spectroscopy, and particularly for 1 , 3 , 5 by X-ray crystallography. Further, the protonations of complexes 1 – 4 are studied and compared with excess acetic acid (HOAc) and trifluoroacetic acid (TFA) by using FT-IR and NMR techniques. Additionally, the electrochemical and electrocatalytic properties of model complexes 1 – 6 are investigated and compared by cyclic voltammetry (CV), suggesting that they are electrocatalytically active for proton reduction to H₂ in the presence of HOAc.     

Bis(trifluoromethyl)fluorsulfonium(IV)-metallate(V) [1] (CF3)2SF+MF6- (M = As,Sb)

The preparation of (CF₃)₂SF⁺MF₆^- (M = As, Sb) is reported. New salts have been synthesized from the reaction of (CF₃)₂SF₂ with strong Lewis acids and CF₃SCF₃ with XeF⁺MF₆^- (M = As, Sb). They are characterised by Raman- and NMR - spectroscopy.     

Palladium(II)-, Platin(II)-, Ruthenium(II)-, Rhodium(III)- und Iridium(III)-Komplexe von Desoxyfructosazin

Metal Complexes of Biologically Important Ligands. CIII. [1] Palladium(II), Platinum(II), Ruthenium(II), Rhodium(III), and Iridium(III) Complexes of Desoxyfructosazine The reactions of the pyrazine derivative desoxyfructosazin(pz) with K₂PtCl₄ and with the chlorobridged [M(PR₃)Cl₂]₂ (M = Pd, Pt), [(η⁵-C₅Me₅)MCl₂]₂ and [(η⁶-p-Cymol)RuCl₂]₂ give the watersoluble complexes cis-Cl₂Pt(pz)₂, (R₃P)(Cl)M(pz)M(Cl)(PR₃) (M = Pd, Pt), (η⁵-C₅Me₅)(Cl)₂M(pz)M(Cl)₂(η⁵-C₅Me₅) (M = Rh, Ir), (η⁶-p-Cymol)(Cl₂)Ru(pz)Ru(Cl)₂(η⁶-p-Cymol).     

Diorganotin(IV) bis(O,O-alkylenedithiophosphates)

O,O-Alkylenedithiophosphates of diorganotin(IV) of the type R₂Sn[SP(S)O₂G]₂ (R = Me, Et, n-Bu, Ph; G = CH₂CMe₂CH₂, CMe₂CMe₂, CMe₂CH₂CHMe) have been synthesized by the reactions of diorganotin(IV) dichlorides with ammonium O,O-alkylenedithiophosphates or that of diorganotin(IV) oxides with O,O-alkylenedithiophosphoric acids in 1:2 molar ratio in benzene. These new complexes are white solids which are soluble in common organic solvents and are monomeric in refluxing benzene; and they have been characterized by elemental analysis and by different spectroscopic (IR, ¹H, ¹³C, ³¹P and ¹¹⁹Sn NMR) studies, on the basis of which a six coordinated octahedral structure has been suggested in solution.     

Gold(III)pentafluorophenylarylazoimidazole: Synthesis and spectral (H, C, COSY, HMQC NMR) characterisation

Reaction of [Au^III(C₆F₅)₃(tht)] with RaaiR′ in dichloromethane medium leads to [Au^III(C₆F₅)₃ (RaaiR′)] [RaaiR′=p-R-C₆H₄-N=N-C₃H₂-NN-l-R′, (1-3), R = H (a), Me (b), Cl (c) and R′= Me (1), CH₂CH₃ (2), CH₂Ph (3), tht is tetrahydrothiophen]. The nine new complexes are characterised by ES/MS as well as FAB, IR and multinuclear NMR (¹H,¹³C,¹⁹F) spectroscopic studies. In addition to dimensional NMR studies as¹H,¹H COSY and¹H¹³C HMQC permit complete assignment of the complexes in the solution phase.     

Complex equilibria of molybdenum(V) and molybdenum(VI) witho-hydroxybenzylamine-N,N,O-triacetic acid (HBATA)

Summary Complex reactions between Mo^V.VI ando-hydroxybenzylamine-N,N,O-triacetic acid (HBATA) have been investigated in the 1–3 and 2.8–6.5 pH range by potentiometric titration at 30° C in 0.5 mol dm^–3 NaCl. The equilibrium data were analyzed with the SCOGS2 and MINIQUAD programs, taking into account side reactions of Mo^V.VI and HBATA with hydrogen ion. The favorable reaction model comprises two complexes, (1,1,1)⁺ and (1,2,2)^–, with formation constants log ₁₁₁ = 14.85 ± 0.11 and log ₁₂₂ = 28.51 ± 0.08 for the Mo^V-HBATA system and the two complexes (1,1,2)^3– and (1,1,3)^2– with formation constants log ₁₁₂ = 17.36 ± 0.01 and log ₁₁₃ = 20.60 ± 0.01 for the Mo^VI-HBATA system. The numbers in brackets refer to the chemical stoichiometric coefficients of molybdenum, HBATA and hydrogen ion in the complexes. The structure and coordinating behaviours of Mo^V and Mo^VI complexes are discussed. The equilibria studied for the polymerization of Mo^V indicates that dimeric, trimeric and tetrameric species are present at pH 1–3.     

The solid state chemistry of uranium: Part IV. The thermal decomposition and kinetics of tetrachlorobis(N,N, N1, N1-tetramethylurea) uranium(IV)

The thermal decomposition of UCl₄2tmu in an oxygen atmosphere was studied. Decomposition of single crystals begins around 180° C and approximates to UCl₄2tmu_(s) + O_2(g) → UO₂Cl₂tmu_(s) + tmu_(g) + gases and is exothermic (ΔH = −270 ± 5 kJ mol⁻¹). The apparent activation energy for the initial stages (nucleation process) of the reaction was estimated as 362 kJ mol⁻¹. The growth period is described by a one-dimensional diffusion process and the decay period by the contracting-area model.     

Synthesis,characterization, reactivity,and antifungal activity of chlorobis(2,4-dinitrophenoxo) monooxovanadium(V)

[VOCl(OC₆H₃(NO₂)₂-2,4)₂] (1) has been synthesized by the reaction of VOCl₃ with bimolar amounts of Me₃SiOC₆H₃(NO₂)₂-2,4 in toluene and characterized by elemental analyses, molar conductance, infrared (IR), ¹H and ¹³C NMR and mass spectral, and thermal studies. Molecular modeling dynamics of the complex suggests tetrahedral geometry around vanadium. The reaction of 1 with sodium alkoxides, NaOR (OR?=?OMe (methoxy); OEt (ethoxy), OBuⁿ(n-butoxy); OPrⁱ (isopropoxy); and OAmⁱ(isoamyloxy)) afforded mixed alkoxo–phenoxo complexes, [VO(OR)(OC₆H₃(NO₂)₂-2,4)₂] authenticated by physicochemical and IR spectral studies. The antifungal activities of the ligand and complexes against three fungi, namely Aspergillus niger, Byssachlamys fulva, and Mucor circinelloides have been assayed by the minimum inhibitory concentration method. The complexes have improved antifungal activity compared to free ligand.     

Bis(dimethylmetall(III)glyoximato)metallate(II) (metall(III) = Al,Ga, In,metall(II) = Ni,Pd, Pt,Cu)

When the trimethyl derivatives of aluminium, gallium and indium react with glyoximato metallates, (R₂C₂N₂(O)OH)₂Met^II (R = H, CH₃; Met^II = Ni, Pd, Pt, Cu), in a $\text{2}\text{1}$ molar ratio, 2 mol of methane are evolved and monomeric bis(dimethylmetal(III)glyoximato)metallates(II) (metal(III) = Al, Ga, In) are formed in high yields. The vibrational and NMR spectra of the new complexes were measured and were partly resolved. The X-ray structure determinations of two of these compounds show non-planar structures of approximate C_2h and C₂ symmetry, respectively, with weak metal(III)?metal(II) π-interactions.