Synthesis, spectroscopy, electrochemistry, and photochemistry of cyano-bridged mixed-valence coordination compounds containing two different types of intervalent charge-transfer bands

The tetranuclear and pentanuclear mixed-valence coordination compounds Na[(NC)₅Fe^II-μ(CN)-Pt^IV(NH₃)₄-μ(NC)-Fe^II(CN)₄-μ(CN)-Ru^III(NH₃)₅], or FePtFeRu, and [Ru^III(NH₃)₅-μ(NC)-Fe^II(CN)₄-μ(CN)-Pt^IV(NH₃)₄-μ(NC)-Fe^II(CN)₄-μ(CN)-Ru^III(NH₃)₅](OSO₂CF₃)₂, or RuFePtFeRu, were synthesized and characterized by IR and UV-Vis spectroscopy, electron microprobe analysis (EPMA), inductively coupled plasma (ICP), and cyclic voltammetry (CV). Both molecules exhibit Fe^II → Pt^IV intervalent charge transfer (IVCT) absorptions in the 400-450 nm range and Fe^II → Ru^III transition(s) between 750 and 950 nm. The energies, intensities, and half-widths of these transitions correspond well with those of model compounds. The cyclic voltammogram of FePtFeRu between 0.00 and 0.90 V versus SCE exhibits two quasi-reversible Fe waves at 0.56 and 0.74 V versus SCE, while that for RuFePtFeRu has only one Fe redox event at 0.72 V versus SCE. When the potential of the working electrode is scanned negative of −0.38 V versus SCE, however, both complexes undergo an ECE (electrochemical-chemical-electrochemical) mechanism whereby the electrochemical reduction of Ru(III) is followed by a double electron transfer to reduce Pt(IV) to Pt(II). Upon reduction to Pt(II), the cyanide bridges break and the complexes dissociate into smaller fragments. Irradiation of the Fe^II → Pt^IV IVCT transition in both compounds leads to a photolysis solution that contains dissociated Fe(II)-Ru(III) as one of its products. Irradiation of the Fe^II → Ru^III IVCT transition yields a similar UV-Vis spectrum, suggesting that the same intermediate is common to both photolysis mechanisms. The implications of this research within the larger context of multiple electron transfer are also discussed.     

Biochemical effects of binding [(H2O)(NH3)5RuII]2+ to DNA and oxidation to[(NH3)5RuIII]n—DNA.

The reaction of [(H₂O)(NH₃)₅Ru^II]²⁺ with calf thymus and salmon sperm DNA has been studied over a wide fange of transition metal ion concentrations. Kinetic studies revealcd a biphasic reaction with an initial fairly rapid coordination of the metal ion being followed by slower reactions. Binding studies were done under pseudo-equilibrium conditions following completion of the initial rapid reaction. Spectra and HPLC of acid-hydrolyzed samples of [(NH3)₅Ru^II]n-DNA prepared by incubation of [(H₂O)(NH₃)₅Ru^II]²⁺ with DNA (where [P_DNA] = 1.5 mM and reactant [Ru^II]/[P_DNA] ratios were in the fange 0.1 to 0.3) followed by air oxidation showed the predominant binding site on helical DNA to be in the major groove at the N-7 of guanine. The equilibrium constant for [(H₂O)(NH₃)₅Ru^II]²⁺ binding to the G⁷ site in helical CT DNA is 5.1 x 103. Differential pulse voltammetry exhibited a single peak at 48 mV, which is attributed to the reduction of Rum on the G⁷ sites.At [Run]/[P_DNA] <0.5, Tm values for the DNA decreased linearly with increasing ruthenium concentration and an increase in the intensity of the 565 nm dG→ Ru(III) charge transfer band was noted upon melting. The UV and CD spectra of these samples indicated no extensive destacking or alteration in geometry (B family) compared to unsubstituted DNA. At [Run]/[P_DNA]〉 0.5 or when single-stranded DNA was used, increased absorbance at 530 nm and 480 nm suggested additional binding to the exocyclic amine sites of adenine and cytosine residues. HPLC and individual spectrophotometric identification of the products derived from hydrolysis of these spec~es yielded both [(Gua)(NH₃)₅Ru^III] and [(Ade)(NH₃)₅Ru^III]. Earlier studies have established the cytidine and adenosine binding sites of [(NH₃)₅Ru^III] to be at their exocyclic amines (C4 and A6). Coordination to these positions indicates disruption of the double helix since these amines are involved in hydrogen bonding on the interior of B-DNA.Agrose gel electrophoresis of superhelical pBR322 plasmid DNA after exposure to various complexes of [(nh₃)₅Ruⁱⁱⁱ] in the presence of a reductant and air generally revealed moderately efficient cleavage of the DNA, presumably due to the generation of hydroxyl radical via Fenton's chemistry. However, similar studies involving [(NH₃)₅Ru^III] directly coordinated to the DNA showed no strand cutting above background. Polyacrylamide gel electrophoresis of a 381 bp, 3′-³²P-labeled fragment of pBR322 plasmid DNA containing low levels of bound [(NH₃)₅ Ru^III] further indicated negligible DNA cutting by the coordinated metal ion.     

Trans-pyridine tetraammine complexes of RuII and RuIII with N7-coordninated purine nucleosides

 The synthesis, spectroscopic, and electrochemical properties of trans-[L(Pyr)(NH₃)₄Ru^II/III] (Pyr=py, 3-phpy, 4-phpy, 3-bnpy, or 4-bnpy; L=H₂O, Guo, dGuo, 1MeGuo, Gua, Ino, or G⁷-DNA) are reported. As expected, the Pyr ligand slows DNA binding by trans-[(H₂O)(Pyr)(NH₃)₄Ru^II]²⁺ relative to [(H₂O)(NH₃)₅Ru^II]²⁺ and favors reduction of Ru^III by about 150 mV. The pyridine ligand also promotes the disproportionation of Ru^III to afford the corresponding complexes of Ru^II and, presumably, Ru^IV. For L=Ino, disproportionation follows the rate law: d[Ru^II]/dt=k ₀[Ru^III]+k ₁[OH^–][Ru^III], k ₀=(2.7±0.7)×10^–4s^–1 and k ₁=70±1 M^–1s^–1. Received: 11 May 1998 / Accepted: 3 March 1999     

Disproportionation of pentaammineruthenium(III)–nucleoside complexes leads to two-electron oxidation of nucleosides without involving oxygen molecules

Pentaammineruthenium(III) complexes of deoxyinosine (dIno) and xanthosine (Xao) ([Ru^III(NH₃)₅(L)], L?is?dIno, Xao) in basic solution were studied by UV?Cvis spectroscopy, liquid chromatography/electrospray ionization mass spectrometry, and high-performance liquid chromatography. Both Ru^III complexes disproportionate to Ru^II and Ru^IV. Disproportionation followed the rate law d[Ru^II]/dt?=?(k _o?+?k ₁[OH^?])[Ru^III]. k _o and k ₁ of disproportionation at 25?°C were 2.1 (±0.1)?×?10^?3?s^?1 and 21.4?±?3.2?M^?1 s^?1, respectively, for [Ru^III(NH₃)₅(dIno)], and 3.5 (±0.7)?×?10^?4?s^?1 and 59.7?±?3.6?M^?1?s^?1, respectively, for [Ru^III(NH₃)₅(Xao)]. The [Ru^III(NH₃)₅(Xao)] complex disproportionates at a faster rate than [Ru^III(NH₃)₅(dIno)] owing to the stronger electron-withdrawing effect of exocyclic oxygen in Xao. The activation parameters ??H ^? and ??S ^? for k ₁ of [Ru^III(NH₃)₅(dIno)] were 80.2?±?15.2?kJ?mol^?1 and 47.6?±?9.8?J?K^?1 mol^?1, respectively, indicating that the disproportionation of Ru^III to Ru^II and Ru^IV is favored owing to the positive entropy of activation. The final products of both complexes in basic solution under Ar were compared with those under O₂. Under both conditions [Ru(NH₃)₅(8-oxo-L)] was produced, but via different mechanisms. In both aerobic and anaerobic conditions, the deprotonation of highly positively polarized C8-H of Ru-L by OH^? initiates a two-electron redox reaction. For the next step, we propose a one-step two-electron redox reaction between L and Ru^IV under anaerobic conditions, which differentiates from Clarke??s mechanism of two consecutive one-electron redox reactions between L, Ru^III, and O₂.     

Structure and magnetic properties of LnIII[Ru2(CO3)4] · 8H2O

Ln^III[Ru₂(CO₃)₄] · 8H₂O (Ln = Gd, Nd, Ho, Yb) is formed from the reaction of Ln^III and [Ru₂(CO₃)₄]^3? in water. These Ln^III materials have a 3D network structure composed of linked chains and μ_n-CO₃ linkages to both Ru and Ln^III sites, and are best described as Ln^III(OH₂)₄[Ru₂(CO₃)₄]_1/2[Ru₂(CO₃)₄(OH₂)₂]_1/2 · 3H₂O. Complete characterization of the Gd^III species is presented, as the other Ln^III are isostructural and exhibit large spin–orbit coupling leading to complex magnetic behavior. Magnetic ordering is not observed above 2 K.     

Effects of trans-pyridine ligands on the interactions of RuII and RuIII ammine complexes N7-coordinated to purine nucleosides and DNA

 DNA binding by trans-[(H₂O)(Pyr)(NH₃)₄Ru^II]²⁺ (Pyr=py, 3-phpy, 4-phpy, 3-bnpy, 4-bnpy) is highly selective for G⁷ with K _G=1.1×10⁴ to 2.8×10⁴, with the more hydrophobic Pyr ligands exhibiting slightly higher binding. A strong dependence on ionic strength indicates that ion-pairing with DNA occurs prior to binding. At μ=0.05, d[Ru^II-DNA]/dt=k[Ru^II][DNA], where k=0.17–0.21 M^–1s^–1 with the various Pyr ligands. The air oxidation of [(py)(NH₃)₄Ru^II] _n -DNA to [(py)(NH₃)₄Ru^III] _n -DNA at pH 6 occurs with a pseudo-first-order rate constant of k _obs=5.6×10^–4s^–1 at μ=0.1, T=25  °C. Strand cleavage of plasmid DNA appears to occur by both Fenton/Haber-Weiss chemistry and by base-catalyzed routes, some of which are independent of oxygen. Base-catalyzed cleavage is more efficient than O₂ activation at neutral pH and involves the disproportionation of covalently bound Ru^III and, in the presence of O₂, Ru-facilitated autoxidation to 8-oxoguanine. Disproportionation of [py(NH₃)₄Ru^III] _n -DNA occurs according to the rate law: d[Ru^II–G_DNA]/dt=k ₀[Ru^III–G_DNA]+k ₁[Ru^III–G_DNA][OH^–], where k ₀=5.4×10^–4s^–1 and k ₁=8.8 M^–1s^–1 at 25  °C, μ=0.1. The appearance of [(Gua)(py)(NH₃)₄Ru^III] under argon, which occurs according to the rate law: d[Ru^III–G]/dt=k ₀[Ru^III–G_DNA]+k ₁[OH^–][Ru^III–G_DNA] (k ₀=5.74×10^–5 s^–1, k ₁=1.93×10^–2M^–1s^–1 at T=25  °C, μ=0.1), is consistent with lysis of the N-glycosidic bond by Ru^IV-induced general acid hydrolysis. In air, the ratio of [Ru-8-OG]/[Ru-G] and their net rates of appearance are 1.7 at pH 11, 25  °C. Small amounts of phosphate glycolate indicate a minor oxidative pathway involving C4′ of the sugar. In air, a dynamic steady-state system arises in which reduction of Ru^IV produces additional Ru^II. Received: 11 November 1998 / Accepted: 3 March 1999     

Stepwise syntheses, structure and spectroscopic studies of ruthenium complexes of 2,6-bis(benzimidazol-2-yl)pyridine with o-iminoquinone ancillary ligand

The ruthenium complexes [Ru^II(bbp)(L)(Cl)] (1), [Ru^II(bbp)(L)(H₂O)] (2) and [Ru^II(bbp)(L)(DMSO)] (3) {bbp = 2,6-bis(benzimidazol-2-yl)pyridine, L = o-iminoquinone} have been synthesized in a stepwise manner starting from [Ru^III(bbp)Cl₃]. The single crystal X-ray structures, except for the complex 2, have been determined. All the complexes were characterized by UV-Vis, FT-IR, ¹H NMR, Mass spectroscopic techniques and cyclic voltammetry. The Ru^III/Ru^II couple for complexes 1, 2, and 3 appears at 0.63, 0.49, 0.55 V, respectively versus SCE. It is observed that complex 2, on refluxing in acetonitrile, results into [Ru^II(bbp)(L)(CH₃CN)], 4 which has been prepared earlier in a different method. The structural, spectral and electrochemical properties of complexes 1, 2 and 3 were compared to those of earlier reported complex 4, [Ru^II(bbp)(L)(CH₃CN)].     

Dinuclear ruthenium sawhorse-type complexes containing carboxylato bridges and ferrocenyl substituents: Synthesis and electrochemistry

The ferrocenyl-containing diruthenium complexes [Ru₂(CO)₄(μ₂-η²-OOCFc)₂L₂] (Fc = ferrocenyl, fc = ferrocen-1,1′-diyl; 1: L = NC₅H₄-COOC₆H₄-OC₁₀H₂₁, 2: L = NC₅H₄-COOC₆H₄-OC₁₆H₃₃, 3: L = NC₅H₄-OOC-fc-C₁₂H₂₅) and [Ru₂(CO)₄(μ₂-η²-OOC₆H₅)₂(NC₅H₄-OOC-fc-C₁₂H₂₅)₂] (4) have been synthesized from Ru₃(CO)₁₂, ferrocene carboxylic or benzoic acid and the corresponding pyridine derivative. The synthesis of the new pyridine derivative NC₅H₄-OOC-fc-C₁₂H₂₅ used for the preparation of 3 and 4 is also reported. Complexes 1-4 posses a so-called sawhorse structure consisting of the Ru₂(CO)₄ backbone and two bridging carboxylato ligands, while the coordination sphere around the ruthenium atoms is completed by the pyridine-derived ligands bonded in the axial positions. The electrochemical behavior of 1-4 and their known analogues [Ru₂(CO)₄(μ₂-η²-OOCFc)₂L₂] (5: L = NC₅H₅, 6: L = P(C₆H₅)₃, 7: L = NC₅H₄-OOCFc) has been studied by voltammetry on rotating disc electrode and by cyclic voltammetry.     

Preparation and structure of [Ru2(O2CMe)4]2[Fe(CN)5NO] and magnetically ordered Hx[Ru2(O2CMe)4]3−x[Cr(CN)5NO] possessing interpenetrating lattices

Reaction of [Ru₂(O₂CMe)₄]Cl with K₃[Cr(CN)₅NO] in water forms H_x[Ru^II/III₂(O₂CMe)₄]_3−x-[Cr(CN)₅NO]·zH₂O (x = 0.2) that magnetically orders at 4.0 K and possesses an interpenetrating body centered cubic [a = 13.2509(2) Å] structure with random locations of the bridging nitrosyl ligands, and x/3 vacant cation sites. Similarly, the aqueous reaction of [Ru₂(O₂CMe)₄]Cl with Na₂[Fe(CN)₅NO] forms paramagnetic [Ru₂(O₂CMe)₄]₂[Fe(CN)₅NO]·H₂O, which has a similar tetragonal interpenetrating structure [a = 13.0186(1) Å, c = 13.0699(2) Å] where the NO ligands are presumably nonbridging and 1/3 of the expected cation sites are unoccupied. The presence of uncoordinated NO sites in addition to missing neighboring [Ru₂(O₂CMe)₄]⁺ units, results in significant vacancies (or holes) in the lattice.     

Complexes of the imine/thioether mixed-donor ligand 8-methylthioquinoline with d-configurated transition metal centers: synthesis, structures and comparison with complexes of 1-methyl-2-(methylthiomethyl)-1H-benzimidazole

Coordination compounds of chelating 8-methylthioquinoline (MTQ) with the complex fragments Re^I(CO)₃Cl, [Ru^II(bpy)₂]²⁺, [Rh^III(C₅Me₅)Cl]⁺, [Ir^III(C₅Me₅)Cl]⁺, and Pt^IVMe₄ were synthesized and structurally characterized. Whereas the ruthenium(II) complex displays the strongest preference of bonding to N versus S, the compound (MTQ)PtMe₄ shows the most balanced metal-donor bonding within the chelate ring due to a relatively short bond to S (2.319 Å) versus N (2.150 Å). The complex fac-(MTQ)Re(CO)₃Cl exhibits a particularly long metal-sulfur bond at 2.472 Å. Cyclic voltammetry of [(MTQ)Ru(bpy)₂](PF₆)₂ reveals one reversible oxidation to Ru^III and three closely spaced reduction waves for the coordinated ligands. In comparison with the imine/thioether chelate ligand 1-methyl-2-(methylthiomethyl)-1H-benzimidazole (mmb) the MTQ ligand with its more rigid chelate setting N(sp²)-C(sp²)-C(sp²)-S forms generally shorter M-S bonds and displays stronger π acceptor behaviour.     

Assisted self-association of dicyanoaurate, [Au(CN)2], and dicyanoargentate, [Ag(CN)2], through hydrogen bonding to metal ammonia complexes

The salts - yellow [Cr(NH₃)₆][Ag(CN)₂]₃ · 2H₂O, red [Co(NH₃)₆][Ag(CN)₂]₃ · 2H₂O, red [Co(NH₃)₆][Au(CN)₂]₃ · 2H₂O, pale yellow [Ru(NH₃)₆][Ag(CN)₂]₃ · 2H₂O, yellow K[Cr(NH₃)₆]₂[Au(CN)₂]₇ · 4H₂O, and colorless [(μ²-NH₂)₂Pt₂(NH₃)₁₀][Au(CN)₂]₆ · 5.5{OS(CH₃)₂} · 0.5H₂O - have been prepared by evaporation of aqueous solutions of potassium dicyanoargenate or potassium dicyanoaurate and salts of the appropriate cations. Hydrogen bonding between the cations and the cyano groups of the anions facilitates the formation of structures with strong metallophilic interactions between the anions. Thus, the [Au(CN)₂]⁻ or [Ag(CN)₂]⁻ ions self-associate into linear trimers in the isostructural set of crystals, [Cr(NH₃)₆][Ag(CN)₂]₃ · 2H₂O (Ag?Ag distance; 3.1610(4) Å), [Co(NH₃)₆][Ag(CN)₂]₃ · 2H₂O (Ag?Ag distance; 3.1557(2) Å), [Co(NH₃)₆][Au(CN)₂]₃ · 2H₂O (Au?Au distance; 3.0939(4) Å), and [Ru(NH₃)₆][Ag(CN)₂]₃ · 2H₂O (Ag?Ag distance; 3.1584(5) Å). Crystalline [(μ²-NH₂)₂Pt₂(NH₃)₁₀][Au(CN)₂]₆ · 5.5{OS(CH₃)₂} · 0.5H₂O also contains nearly linear trimers of the dicyanoaurate ion. Yellow crystals of K[Cr(NH₃)₆]₂[Au(CN)₂]₇ · 4H₂O contain a centrosymmetric, bent chain of seven dicyanoaurate ions with Au?Au separations of 3.1806(3), 3.2584(4), and 3.1294(4) Å.     

Formation and structural chemistry of the unusual cyanide-bridged dinuclear species [Ru2(NN)2(CN)7] (NN = 2,2′-bipyridine or 1,10-phenanthroline)

Crystallisation of simple cyanoruthenate complex anions [Ru(NN)(CN)₄]²⁻ (NN = 2,2′-bipyridine or 1,10-phenanthroline) in the presence of Lewis-acidic cations such as Ln(III) or guanidinium cations results, in addition to the expected [Ru(NN)(CN)₄]²⁻ salts, in the formation of small amounts of salts of the dinuclear species [Ru₂(NN)₂(CN)₇]³⁻. These cyanide-bridged anions have arisen from the combination of two monomer units [Ru(NN)(CN)₄]²⁻ following the loss of one cyanide, presumably as HCN. The crystal structures of [Nd(H₂O)_5.5][Ru₂(bipy)₂(CN)₇] · 11H₂O and [Pr(H₂O)₆][Ru₂(phen)₂(CN)₇] · 9H₂O show that the cyanoruthenate anions form Ru-CN-Ln bridges to the Ln(III) cations, resulting in infinite coordination polymers consisting of fused Ru₂Ln₂(μ-CN)₄ squares and Ru₄Ln₂(μ-CN)₆ hexagons, which alternate to form a one-dimensional chain. In [CH₆N₃]₃[Ru₂(bipy)₂(CN)₇] · 2H₂O in contrast the discrete complex anions are involved in an extensive network of hydrogen-bonding involving terminal cyanide ligands, water molecules, and guanidinium cations. In the [Ru₂(NN)₂(CN)₇]³⁻ anions themselves the two NN ligands are approximately eclipsed, lying on the same side of the central Ru-CN-Ru axis, such that their peripheries are in close contact. Consequently, when NN = 4,4′-^tBu₂-2,2′-bipyridine the steric bulk of the t-butyl groups prevents the formation of the dinuclear anions, and the only product is the simple salt of the monomer, [CH₆N₃]₂[Ru(^tBu₂bipy)(CN)₄] · 2H₂O. We demonstrated by electrospray mass spectrometry that the dinuclear by-product [Ru₂(phen)₂(CN)₇]³⁻ could be formed in significant amounts during the synthesis of monomeric [Ru(phen)(CN)₄]²⁻ if the reaction time was too long or the medium too acidic. In the solid state the luminescence properties of [Ru₂(bipy)₂(CN)₇]³⁻ (as its guanidinium salt) are comparable to those of monomeric [Ru(bipy)(CN)₄]²⁻, with a ³MLCT emission at 581 nm.     

Syntheses, structures and magnetic properties of heterobimetallic complexes based on a new tetracyanometalate precursor

A new mononuclear tetracyanometallic complex, (n-Bu₄N)[(dbphen)Fe(CN)₄] (1, dbphen = 5,6-dibromo-1,10-phenanthroline), has been prepared by reacting [(dbphen)Fe^II(py)₂(SCN)₂] and KCN in water and further oxidized with chlorine. With the use of 1 as building block, two trinuclear Fe₂M complexes, [(dbphen)₂Fe₂(CN)₈Cu(Me₃tacn)]·3H₂O (2), [(dbphen)₂Fe₂(CN)₈Ni(dabhctd)]·2H₂O (3) and a chain complex of squares [(dbphen)₂Fe₂(CN)₈Co(MeOH)₂]_n (4), have been synthesized and structurally characterized. Magnetic studies show ferromagnetic coupling between Fe^III and M^II (M = Cu, 2; Ni, 3) ions bridged by cyanides in complexes 2 and 3, while complex 4 exhibits meta-magnetic behavior.     

Structural, spectroscopic and redox studies of a new ruthenium(III) complex with an imidazole-rich tripodal ligand

The present paper describes a new tripodal ligand containing imidazole and pyridine arms and its first cis-[Ru^III(L)(Cl)₂]ClO₄ complex (1). The crystal structure of 1 shows Ru^III in a distorted octahedral geometry, in which two chloride ions, cis-positioned to each other, are coordinated besides the four nitrogen atoms from the tetradentate ligand L. The cyclic voltammogram of 1 exhibits three redox processes at −67, +73 and +200 mV versus SCE, which are attributed to the Ru^III/Ru^II couple in the cis-[Ru^III(L)(Cl)₂]⁺, cis-[Ru^II(L)(H₂O)(Cl)]⁺ and cis-[Ru^II(L)(H₂O)₂]²⁺, respectively. After chemical reduction (Zn(Hg) or Eu^II) only the cis-[Ru^II(L)(H₂O)₂]²⁺ species is observed in the cyclic voltammetry. Complex 1 absorbs at 470 nm (ε=1.4×10³ mol⁻¹ L cm⁻¹), 335 nm (ε=7.9×10³ mol⁻¹ L cm⁻¹), 301 nm (ε=6.7×10³ mol⁻¹ L cm⁻¹) and 264 nm (ε=9.9×10³ mol⁻¹ L cm⁻¹), in water solution (CF₃COOH, 0.01 mol L⁻¹, μ=0.1 mol L⁻¹ with CF₃COONa). Spectroelectrochemical experiments show a decrease of the bands at 335 and 301 nm, which are attributed to LMCT transitions from the chloride to the Ru^III center and the appearance of a broad band at 402 nm ascribed to MLCT transition from the Ru^II center to the pyridine ligand. The lability of the water ligands in the cis-[Ru^II(L)(H₂O)₂]²⁺ species has been investigated using the auxiliary ligand pyrazine. Reactions in the presence of stoichiometric and excess of pyrazine yield the same species, cis-[Ru^II(L)(H₂O)(pz)]²⁺, which exhibits a reversible redox process at 493 mV versus SCE and absorbs at 438 nm (ε=5.1×10³ mol⁻¹ L cm⁻¹) and 394 nm (ε=4.2×10³ mol⁻¹ L cm⁻¹). Experiments performed with a large excess of pyrazine gave a specific rate constant k₁=(2.8±0.5)×10⁻² M⁻¹ s⁻¹, at 25 °C, in CF₃COOH, 0.01 mol L⁻¹, μ=0.1 mol L⁻¹ (with CF₃COONa).     

Synthesis and characterization of new imidorhenium(V) and imidorhenium(VI) complexes of pyridyltriazines and pyrazinyltriazine with halide coligands including rare iodide

The blue colored imido complexes [Re(NC₆H₄Cl)X₃(L)] have been synthesized by three methods: (i) reaction of [Re^VOX₃(L)] with p-ClC₆H₄NH₂, (ii) reaction of [Re^III(OPPh₃)X₃(L)] with p-ClC₆H₄NH₂ and (iii) reaction of [Re^VOX₃(PPh₃)₂] with L followed by the addition of p-ClC₆H₄NH₂ in boiling toluene. Here, X = Cl, Br, I and L are 5,6-diphenyl-3-(2-pyridyl)-1,2,4-triazine (L²) and its dimethyl (L¹) and pyrazinyl (L³) analogues. The [Re(NC₆H₄Cl)Cl₃(L¹)] (1a), [Re(NC₆H₄Cl)Cl₃(L²)] (1b), [Re(NC₆H₄Cl)Br₃(L²)] (1c), [Re(NC₆H₄Cl)I₃(L²)] (1d), [Re(NC₆H₄Cl)Cl₃(L³)] (1e), [Re(NC₆H₄Cl)Br₃(L³)] (1f), [Re(NC₆H₄Cl)I₃(L³)] (1g), complexes have been characterized electrochemically and spectroscopically. The X-ray structures of [Re(NC₆H₄Cl)Cl₃(L²)] and [Re(NC₆H₄Cl)I₃(L³)] reveal that the ReCl₃ fragment is meridionally disposed and that the L ligand is N,N-coordinated such that the pyridine/pyrazine nitrogen lies trans to the imide nitrogen. The feasibility of generating the rhenium(VI) congener of the imidorhenium(V) complex is also examined with the help of six-line EPR spectra at room temperature.     

Synthesis, structure and reactivity of complexes containing [M(S2)2] fragments (M=Ru, Os; (S2)=1,2-benzenedithiolate (2−))

Subsequent addition of 1,2-benzenedithiol (S₂-H₂) and nBuLi to a solution of [Ru(NO)Cl₃ · xMeOH] in THF afforded exclusively the monomeric species NBu₄[Ru^II(NO)(S₂)₂] (1). Formation of dimeric (NBu₄)₂[Ru^II(NO)(S₂)₂]₂ (2) has been confirmed when the deprotonated ligand S₂-Li₂ was added to [Ru(NO)Cl₃ · xMeOH] and allowed to stir for 30 h. The monomer 1 undergoes aerial oxidation to give (NBu₄)₂[Ru^IV(S₂)₃] (3). The reaction between RuCl₃ · xH₂O and S₂-H₂ in the presence of NaOMe, afforded the dinulear Ru^III species (NMe₄)₂[Ru^III(S₂)₂]₂ (4). A modified method for the preparation of 1 is being employed to synthesize the osmium analogue NBu₄[Os(NO)(S₂)₂] (5) effectively. The solid state structures of 1, 2 and 3 were determined by X-ray crystal structure analysis. A comparison of relevant bond distance data suggests that 1,2-benzenedithiolate acts as an “innocent” ligand.     

The azidopentacyanoferrate(III) ion as a tecton in constructing heterometallic complexes: Synthesis, crystal structure and magnetic properties of [Mn(valphen)(H2O)2]2[(H2O)(valphen)Mn(μ-CN)Fe(CN)4(N3)]·8H2O

By employing the common precursor Na₃[Fe(CN)₅(NH₃)]·3H₂O in a new synthetic approach, the azidopentacyanoferrate(III) ion has been isolated and structurally characterized as (Ph₄As)₂[Na(H₂O)₄][Fe(CN)₅(N₃)] 1. In order to confirm its building block ability, compound 1 has been reacted with the mononuclear complex [Mn(valphen)(H₂O)₂]ClO₄ (H₂valphen represents the Schiff base resulting from the condensation of o-vanillin with 1,2-phenylenediamine in a 2:1 M ratio) to afford the new Mn^III-Fe^III heterometallic system [Mn(valphen)(H₂O)₂]₂[(H₂O)(valphen)Mn(μ-CN)Fe(CN)₄(N₃)]·8H₂O 2. The crystal structure of compound 2 reveals a supramolecular assembly generated by [(H₂O)(valphen)Mn(μ-CN)Fe(CN)₄(N₃)]²⁻ dianions and discrete [Mn(valphen)(H₂O)₂]⁺ counterions. The dynamic magnetic measurements of compound 2 point to a slow relaxation of the magnetization.     

Water replacement on the decaaqua-di-rhodium(II) cation; synthesis of superoxo and peroxo rhodium(III) complexes with N-donor ligands

The decaaqua-di-rhodium(II) cation has been found to be an interesting starting material in the preparation of dioxygen complexes with different N-donor ligands. Treatment of aqueous HClO₄ solution of [Rh₂(H₂O)₁₀]⁴⁺ with NH₄OH/NH₃, py and/or en results in water exchange and the formation of corresponding [Rh₂^II(H₂O)_10−m(base)_n(OH)_m]^(4−m)+ derivatives. Reaction of the latter with dioxygen afforded superoxo and/or peroxo complexes, depending on reaction conditions: [Rh₂^III(O₂ ⁻)(NH₃)₈(OH)₂](ClO₄)₃ (1), [Rh₂^III(O₂ ⁻)(NH₃)₈(OH)(H₂O)](ClO₄)₄ (2), [Rh₂^III(O₂ ²⁻)(NH₃)₁₀](ClO₄)₄ · 6H₂O (3), [Rh₂^III(O₂ ⁻)(py)₈(H₂O)₂](ClO₄)₅ (4), [Rh₂^III(O₂ ²⁻)(en)₄(H₂O)₂](ClO₄)₄ (5) and [Rh₂^III(O₂ ⁻)(en)₄(H₂O)₂](ClO₄)₅ (6). All the obtained complexes were characterized by elemental analysis, mass spectrometry, UV-Vis, IR and ESR spectroscopies and magnetic measurements.     

Exploring the properties of mixed valence cyanide bridged dinuclear complexes: Solvent stabilization of electronic isomers

We report here the synthesis and properties of a family of mixed-valence cyanide-bridged dinuclear complex ions trans-[(L′L₄Ru^II(μ-NC)Fe^III(CN)₅]⁻ (with L = pyridine or 4-dimethylaminopyridine (dmap) and L′ = pyridine, 4-methoxypyridine (meopy) or 4-dimethylaminopyridine)) whose properties could be adjusted smoothly by changing the acceptor properties of the solvent and the σ donor properties of the L′ pyridine ligand. In solution these complexes exhibit an intense solvent-dependent MM′CT (Ru^II → Fe^III) absorption in the near infrared region. Analysis of this band in different complexes and solvents suggests an enhanced interaction as the energies of the metal centers come closer. From this trend the anion trans-[(dmap)₅Ru(μ-NC)Fe(CN)₅]⁻ (dmap = 4-dimethylaminopyridine) in water is expected to belong to the class II-III, but its spectral properties indicates a ground state with Ru(III)-Fe(II) character. The stabilization of this electronic isomer is probably related to the better donor properties of the hexacyanoferrate(II) moiety and its stronger interaction with water.     

New open-framework phosphate and phosphite compounds of gallium

Five new open-framework compounds of gallium have been synthesized by hydrothermal methods and their structures determined by single crystal X-ray diffraction studies. The compounds, [C₈N₄H₂₆][Ga₆F₄(PO₄)₆], I, [C₅N₃H₁₁][Ga₃F₂(PO₄)₃]·H₂O, II, [C₆N₃H₁₉][Ga₄(C₂O₄)(PO₄)₄(H₂PO₄)]·2H₂O, III, [Ga₂F₃(HPO₄)(PO₄)]·2H₃O, IV, and [C₃N₂H₅]₂[Ga₄(H₂O)₃(HPO₃)₇], V, possess three-dimensional structures. All the compounds are formed by the connectivity between the Ga polyhedra and phosphite/phosphate units. The observation of SBU-6 (I and II) and spiro-5 (IV) secondary building units (SBUs) are noteworthy. The flexibility of the formation of gallium phosphate frameworks has been established by the isolation of two related structures (I and II) from the same SBU units but different organic amines. Some of the present structures have close resemblance to the gallium phosphate phases known earlier. The compounds have been characterized by CHN analysis, powder XRD, IR, and TGA.