Triazamethylenemethane complexes of zirconium and tantalum

Addition of [Li₂(THF)₄][C(NPh)₃] (2) to a THF solution of Cp^*ZrCl₃ (Cp^*=C₅Me₅) yields, after recrystallization in Et₂O, the zwitterionic species Cp^*[C(NPh)₃]ZrCl₂Li(Et₂O)(THF) (3). Treating 3 with excess methylaluminoxane (MAO) affords a homogeneous Ziegler–Natta catalyst for ethylene polymerization. Addition of LiNPh₂ to 3 allows for Cl substitution to give the new product Cp^*[C(NPh)₃]Zr(NPh₂)ClLi(THF)₂ (4). A single crystal diffraction study of 4 reveals that the [C(NPh)₃] ligand is η²-bound. The group 5 complex Cp^*[C(NPh)₃]TaMe₂ (5) was prepared by addition of 2 to Cp^*TaMe₂Cl(OSO₃CF₃). The X-ray diffraction structure of 5 shows that the [C(NPh)₃] ligand is η²-bound to tantalum and that, when compared to 4, there is less electron delocalization across the inner core of [C(NPh)₃].     

Phenoxazine-based supramolecular tetrahedron as biomimetic lectin for glucosamine recognition

The design and synthesis of a phenoxazine-based metal-organic tetrahedro n(Zn_4L_4) as biomimetic lectin for selectively recognition of glucosamine(GlcN) was reported.Different from the free phenoxazinebased ligand(L),Zn_4L_4 displayed the highest fluorescent intensity enhancement efficiency toward GlcN over other related natural mono-and disaccharides.Fluorescence titration demonstrated a 1:1 stoichiometric host-guest complex was formed with an association constant about 4.03 × 10~4 L/mol.~1H NMR spectroscopic studies confirmed this selectivity resulted from the multiple hydrogen bonding interactions formed between GlcN and Zn_4L_4.The present results suggested that rational arrangement of recognition sites in the confined space of metal-organic cage is crucial for the selectivity toward target guests.     

Silver(I) complexes with (1-pyrazolyl)pyridazine ligands: Synthesis,crystal structures and luminescent properties

Four Ag(I) coordination complexes formulated as {[Ag(L¹)(ClO₄)]}_n (1), {[Ag(L¹)(NO₃)]}_n (2), {[Ag(L¹)(PF₆)]}₂ (3) and {[Ag(L²)](ClO₄)·CH₃OH}_n (4), (L¹ = 3,6-bis(1-pyrazolyl)pyridazine, L² = 3,6-bis(3,5-dimethyl-1-pyrazolyl)pyridazine) have been synthesized in the presence of different anions [ClO₄^? (1) and (4), NO₃^? (2), PF₆^? (3)] and structurally characterized by FT-IR spectra, elemental analysis and X-ray diffraction. Studies of X-ray diffraction reveal that complexes 1, 2 and 4 show infinite helical chains, which are the alternate left- and right-handed helical chains. Furthermore, helical chains are arranged to 2D sheet via C–H?O (from anion O atoms) hydrogen bonds. As the anion changed to PF₆^?, a dinuclear molecule is formed in complex 3, further constructing a 2D sheets by C–H?F hydrogen bonds. The photoluminescence properties of all the complexes 1–4 have been investigated in the solid state at room temperature.     

Coordination networks constructed with supramolecular synthon RX–CCAgn (n = 4, 5; RX = halophenyl)

Eight new silver(I) double salts: AgL¹·2AgCF₃COO (1), AgL¹·3AgNO₃ (2), 2AgL²·5AgCF₃COO·2CH₃CN·H₂O (3), 4AgL³·6AgCF₃COO·5CH₃CN (4), 4AgL⁴·6AgCF₃COO·5CH₃CN (5), 2AgL⁵·4AgCF₃COO·NC(CH₂)₄CN (6), 2AgL⁵·4AgCF₃COO·2CH₃CN (7) and AgL⁶·2CF₂(CF₂COOAg)₂·2CH₃CN (8) (L¹ = 4-iodophenylethynide; L² = 3,4-dichlorophenylethynide; L³ = 3-chlorophenylethynide; L⁴ = 3-bromophenylethynide; L⁵ = 2-chlorophenylethynide; L⁶ = 2-fluorophenylethynide) have been synthesised and characterized by X-ray crystallography. All compounds contain the silver–halophenylethynide supramolecular synthon R_X−CCAg_n (n = 4, 5). In particular, the three-dimensional supramolecular structures in 1 and 2 are stabilized by strong AgI interactions, while that in 3 is consolidated by both AgCl and van der Waals type FCl interactions. In isomorphous compounds 4 and 5, the presence of respective FCl or FBr contact contributes to the stability of the network. The silver aggregates in 6, 7 and 8 are stabilized by AgCl or AgF interactions between the ortho-halo substituent and the Ag_n basket.     

Reactions of half-sandwich rhodium(III) and iridium(III) compounds with pyridinethiolate ligands: Mono-, di-, and tri-nuclear complexes

Neutral trinuclear metallomacrocycles, [Cp^*RhCl(μ-4-PyS)]₃ (3) and [Cp^*IrCl(μ-4-PyS)]₃ (4) [Cp^* = pentamethylcyclopentadienyl, 4-PyS = 4-pyridinethiolate], have been synthesized by self-assembly reactions of [Cp^*RhCl₂]₂ (1) and [Cp^*IrCl₂]₂ (2) with lithium 4-pyridinethiolate, respectively. In situ reaction of complex 3 with three equivalent of lithium 4-pyridinethiolate resulted in [Cp^*Rh(μ-4-PyS)(4-PyS)]₃ (5) containing both skeleton and pendent 4-PyS groups. Chelating coordination of 2-pyridinethiolate broke down the triangular skeleton to give mononuclear metalloligands Cp^*Rh(2-PyS)(4-PyS) (6) and Cp^*Ir(2-PyS)(4-PyS) (7) [2-PyS = 2-pyridinethiolate], which could also be synthesized from Cp^*RhCl(2-PyS) (10) and Cp^*IrCl(2-PyS) (11) with lithium 4-pyridinethiolate. The coordination reactions of 6 with complexes 1 and 2 gave dinuclear complexes [Cp^*Rh(2-PyS)(μ-4-PyS)][Cp^*RhCl₂] (8) and [Cp^*Rh(2-PyS)(μ-4-PyS)][Cp^*IrCl₂] (9), respectively. Molecular structures of 3, 4, 6 and 11 were determined by X-ray crystallographic analysis. All the complexes have been well characterized by elemental analysis, NMR and IR spectra.     

Reactions of diphenylpyridylphosphine with H2Os3(CO)10 and H4Ru4(CO)12, P–C bond splitting in the coordinated ligand and isolation of the oxidative addition products

The reactions of diphenylpyridylphosphine ligand with H₂Os₃(CO)₁₀ and H₄Ru₄(CO)₁₂ were studied. It was found that the thermodynamic products of these reactions, (μ-H)Os₃(CO)₉(μ₃,κ²-PhP(2-C₅H₄N)) (2) and H₃Ru₄(CO)₁₀(μ₃,κ²-PhP(2-C₅H₄N)) (4), are formed through the oxidative addition of a P–Ph bond in the coordinated ligand and subsequent reductive elimination of benzene. In the case of triosmium cluster an unusually stable intermediate compound, (μ-H)₂Os₃(CO)₈(μ₃,κ²-PhP(2-C₅H₄N))(Ph) (1), containing cis hydride and σ-bonded phenyl was isolated and fully characterized. This cluster eliminates benzene to give (2) only under heating above 50 °C. Reaction of H₄Ru₄(CO)₁₂ with diphenylpyridylphosphine gives first the H₄Ru₄(CO)₁₀(μ,κ²-Ph₂P(2-C₅H₄N)) cluster (3) with a bridging (P,N) coordination of the starting ligand, which easily converts into the phosphide cluster (4) at room temperature. The structures of the clusters (1)–(4) were established using ¹H and ³¹P NMR spectroscopy and X-ray crystallography. Variable temperature ¹H NMR study of (3) and (4) showed that the hydride environment in (3) is stereochemically nonrigid and complete exchange of all hydrides was observed at room temperature. The cluster (4) exists in solution as an equilibrium mixture of two isomers with different disposition of hydrides relative to the bridging pyridylphosphide moiety.     

Synthesis and electrochemical properties of calix[4]arene derivatives containing ferrocene units in the cone and 1,3-alternate conformation

Two novel calix[4]arene receptors containing ferrocene units in cone (L₁) and 1,3-alternate (L₂) conformations have been synthesized from 25,27-dihydroxy-26,28-bis[(3-aminopropyl)oxy]calix[4]arene 4 or 25,26,27,28-tetra[(3-aminopropyl)oxy]calix[4]arene 6 and ferrocenecarboxaldehyde via condensation, respectively. Their structures have been characterized by ¹H, ¹³C, APT, COSY NMR, FTIR, HSMR, and UV–vis spectral data. The electrochemical behavior of L₁ and L₂ has been investigated in the presence of F^?, Cl^?, Br^?, H₂PO₄^?, CH₃COO^? anions. Electrochemical studies show that these receptors electrochemically recognize CH₃COO^?, H₂PO₄^?, and Cl^?, anions. Using an UV–vis study, the selectivity to these anions in DMSO solution was confirmed.     

Optically active transition metal complexes. Part 117:Synthesis,crystal structure and properties of chiral (η6-arene)ruthenium complexes with N,O- and N,N-ligands

The complexes [(η⁶-p-ⁱPrC₆H₄Me)Ru(NO₂pesa)Cl] 2, [(η⁶-p-ⁱPrC₆H₄Me)Ru(oxazsa)Cl] 3 and [(η⁶-p-ⁱPrC₆H₄Me)Ru(pepy)Cl] 4, chiral in the chelate ligand and chiral at the ruthenium atom, have been prepared by reaction of [(η⁶-p-ⁱPrC₆H₄Me)RuCl₂]₂ with the anions of the (S)-configured bidentate N,O- and N,N-ligands. [(η⁶-p-ⁱPrC₆H₄Me)Ru(pesa)I] 5 was synthesized by halide exchange. The diastereomer ratios of compounds 2–4 with respect to the stereogenic ruthenium atom are in CDCl₃ 2a:2b=81:19, 3a:3b=77:23 and 4a:4b=61:39. Compound 5 is obtained diastereomerically pure. An X-ray structure analysis of 3 shows (R_Ru,S_C)-configuration     

1,1′ Ferrocenylenediol as chelating ligand for cobalt in fivefold and sixfold coordination geometry: Synthesis,Electrochemistry and X-ray crystal structure of [{((1,1′ O2(η5-C5H5)2Fe)2}Co(OEt2){(η5-Me5C5)Co}2] and [{((1,1′ O2(η5-C5H5)2Fe)3}Co((η5-EtMe4C5)Co)2]

The title compounds 3 and 4 were synthesized by reaction of 1,1′ ferrocenylenediol with the Co triple decker compounds [{(η⁵-Me₅C₅)Co}₂(η⁶:η⁶-toluene)] and [{(η⁵-EtMe₄C₅)Co}₂(η⁶:η⁶-toluene)], respectively. The central Co atom of 3 is coordinated by five O atoms in a square-pyramidal manner. The remaining two Co atoms of 3 are coordinated to a Me₅C₅ ligand in a η⁵-fashion and by the two O atoms of two 1,1′ ferrocenylenediolato ligands which serve as chelating ligands. In 4, the central Co atom is coordinated to all six O atoms of three ferrocenylenediolato ligands in a trigonal-prismatic manner, whereas the two other Co atoms are coordinated by an EtMe₄C₅ ligand in a η⁵-fashion and by three O atoms of three ferrocenylenediolato ligands resulting in an overall tripoidal structure for 4.     

Five- and six-membered palladacycles derived from [(η5-C5H5)Fe{(η5-C5H4)-CH=N-(C6H4-2-C6H5)}]

The reaction of the novel ferrocenyl Schiff base: [(η⁵-C₅H₅)Fe{(η⁵-C₅H₄)-CH=N-(C₆H₄-2-C₆H₅)}] (1) with Na₂[PdCl₄] and Na(CH₃COO)·3H₂O in a 1:1:1 molar ratio in methanol is reported. In this reaction two different di-μ-chloro-bridged cyclopalladated complexes: [Pd{[(η⁵-C₅H₃)-CH=N-(C₆H₄-2-C₆H₅)]Fe(η⁵-C₅H₅)}(μ-Cl)]₂ (2a) and [Pd{[(C₆H₄-2-C₆H₄)-N=CH-(η⁵-C₅H₄)]Fe(η⁵-C₅H₅)}(μ-Cl)]₂ (2b) can be formed depending on the experimental conditions. Compounds 2a and 2b, which differ in the nature of the metallated carbon atom (C_{sp²,ferrocene} or C_{sp²,biphenyl}, respectively), undergo cleavage of the ‘Pd(μ-Cl)₂Pd’ bridges in the presence of thallium (I) acetylacetonate, deuterated pyridine or triphenylphosphine giving the monomeric derivatives: [Pd(C^∧N)(acac)] (3a, 3b) and [Pd(C^∧N)Cl(L)] {with L=py- d₅(4a, 4b), PPh₃(5a, 5b)}. The reactions of 2 with 1,2-bis(diphenylphosphino)ethane (dppe) reveal that the two isomers (2a and 2b) exhibit different reactivity versus dppe. These results have been interpreted on the basis of steric effects.     

Preparation and reactivity of CpRu(OMe)PCy3 and CpRuHL2 (L = PCyPh2, PCy2H) from [CpRu(OMe)]2 and bulky phosphines

The reaction of [CpRu(OMe)]₂ (1) with PCy₃ yields the 16-electron alkoxo derivative, CpRu(OMe)(PCy₃) (2). 2 reacts with H₂ and HBF₄ to give the known CpRuH₃PCy₃ (3) and [CpRu(C₆H₉PCy₂)]BF₄ (4). The reaction of 1 with one or two equivalents of L yields CpRuHL₂ (L = PCyPh₂ (5), PCy₂H (6)) through a β-elimination process. Upon protonation, 5 and 6 are converted into [CpRuH₂L₂]BF₄ (L = PCyPh₂ (7), PCy₂H (8)).     

Synthesis and the crystal structures of a monoanionic tetrafluorodentate ligand and its complex with lanthanum ion

New organotitanium fluorides [Hdmpy]⁺[(C₅Me₄R)₂Ti₂F₇]⁻ (R=Me 4, Et 5, dmpy=2,6-dimethylpyridine, lutidine) have been prepared from (C₅Me₄R)TiF₃ and 2,6-dimethylpyridine·(HF)₂. The compounds 4 and 5 react with La(CF₃SO₃)₃ to give [La{(C₅Me₄R)₂Ti₂F₇}₃] (R=Me 6, Et 7) containing the [(C₅Me₄R)₂Ti₂F₇]⁻ anion as a tetrafluorodentate ligand in the crystal structures of 4 and 7. The cation–anion pair is connected by a hydrogen bond in 4 and the all-fluorine environment of 12 fluorine atoms coordinated to a lanthanum ion is found in 7.     

Exchange bias in Ni4 single-molecule magnets

The syntheses and physical properties are reported for three single-molecule magnets (SMMs) with the composition [Ni(hmp)(ROH)Cl]₄, where R is CH₃ (complex 1), CH₂CH₃ (complex 2) or CH₂CH₂C(CH₃)₃ (complex 3) and hmp⁻ is the monoanion of 2-hydroxymethylpyridine. The core of each complex is a distorted cube formed by four Ni^II ions and four alkoxide hmp⁻ oxygen atoms at alternating corners. Ferromagnetic exchange interactions give a S=4 ground state. Single crystal high-frequency EPR spectra clearly indicate that each of the complexes has a S=4 ground state and that there is negative magnetoanisotropy, where D is negative for the axial zero-field splitting DŜ_z². Magnetization versus magnetic field measurements made on single crystals with a micro-SQUID magnetometer indicate these Ni₄ complexes are SMMs. Exchange bias is seen in the magnetization hysteresis loops for complexes 1 and 2.     

Synthesis, crystal structures and spectroscopic characterization of two neutral heterobimetallic clusters MS4Cu4(pz)6X2 (where M = Mo (1) or W (2), X = Cl (1) or disordered Cl/Br (2), and pz = 3,5-dimethylpyrazole)

The title complexes were synthesized in acetone by the reaction of [n-Bu₄N]₂[MoS₄Cu₄Cl₄] and pz^Me2 for compound 1, and n-Bu₄NBr, [NH₄]₂[WS₄], CuCl and pz^Me2 for compound 2. X-ray diffraction studies of 1 and 2 demonstrate that four of the six edges of the tetrahedral [MS₄]²⁻ core are bridged by four copper atoms, giving a pentanuclear structure MS₄Cu₄(pz^Me2)₆X₂ (M = Mo, W) with the five metal atoms essentially coplanar. The four Cu atoms exhibit two different coordination modes. Each of one pair of mutually trans Cu atoms is coordinated by two (μ₃-S) atoms and two nitrogen atoms of pz^Me2 rings, giving a distorted tetrahedral CuS₂N₂ arrangement. The other two mutually trans Cu atoms are coordinated by two (μ₃-S) atoms, one nitrogen atom of pz^Me2 and one terminal Cl or Br ligand, giving a distorted tetrahedral CuS₂NX unit. In addition to being structurally studied by X-ray diffraction, the title compounds have been characterized by IR, UV–Vis and ¹H NMR spectroscopy. The IR results, which include low-frequency M–S_b stretching bands, are consistent with the X-ray structural analysis and confirm that the [MS₄]²⁻ cores are coordinated through all four sulfur atoms in the complexes 1 and 2.     

Reaction of [Ru3(CO)12] with tri(2-furyl)phosphine: Di- and tri-substituted triruthenium and phosphido-bridged diruthenium complexes

Reaction of [Ru₃(CO)₁₂] with tri(2-furyl)phosphine, P(C₄H₃O)₃, at 40 °C in the presence of a catalytic amount of Na[Ph₂CO] furnishes two triruthenium complexes [Ru₃(CO)₁₀{P(C₄H₃O)₃}₂] (1) and [Ru₃(CO)₉{P(C₄H₃O)₃}₃] (2) with the ligand coordinated through the phosphorus atom. Treatment of 1 and 2 with Me₃NO at 40 °C affords the dinuclear phosphido-bridged complexes [Ru₂(CO)₆(μ-η¹,η²-C₄H₃O){μ-P(C₄H₃O)₂}] (3) and [Ru₂(CO)₅(μ-η¹,η²-C₄H₃O){μ-P(C₄H₃O)₂}{P(C₄H₃O)₃}] (4), respectively, that are formed via phosphorus–carbon bond cleavage of a coordinated phosphine followed by coordination of the dissociated furyl moiety to the diruthenium center in a σ,π-alkenyl mode. Reaction of [Ru₃(CO)₁₂] with tri(2-furyl)phosphine in refluxing benzene gives, in addition to 3 and 4, low yields of the cyclometallated complex [Ru₃(CO)₉{μ-η¹,η¹-P(C₄H₃O)₂(C₄H₂O)}₂] (5). Treatment of 3 with EPh₃ (E = P, As, Sb) at room temperature yields the monosubstituted derivatives [Ru₂(CO)₅(μ-η¹,η²-C₄H₃O){μ-P(C₄H₃O)₂}(EPh₃)] (E = P, 8; E = As, 9; E = Sb, 10). Similar reactions of 3 with P(C₄H₃O)₃, P(OMe)₃ and Bu^tNC yield 4, [Ru₂(CO)₅(μ-η¹,η²-C₄H₃O){μ-P(C₄H₃O)₂}{P(OMe)₃}] (11) and [Ru₂(CO)₅(μ-η¹,η²-C₄H₃O){μ-P(C₄H₃O)₂}(NCBu^t)] (12), respectively. The molecular structures of complexes 3, 4 and 8 have been elucidated by single crystal X-ray diffraction studies. Each complex contains a bridging σ,π-alkenyl group and while in 4 the phosphine is bound to the σ-coordinated metal atom, in 8 it is at the π-bound atom. Protonation of 3 and 4 gives the hydride complexes [(μ-H)Ru₂(CO)₆(μ-η¹,η²-C₄H₃O){μ-P(C₄H₃O)₂}]⁺ (6) and [(μ-H)Ru₂(CO)₅(μ-η¹,η²-C₄H₃O){μ-P(C₄H₃O)₂}{P(C₄H₃O)₃}]⁺ (7), respectively, while heating 3 with dimethylacetylenedicarboxylate (DMAD) in refluxing toluene gives the cyclotrimerization product, C₆(CO₂Me)₆.     

Synthesis and structural characterization of nickel(II), copper(II) and zinc(II) complexes with the hexadentate ligand 2,13-bis(2-pyridylmethyl)-3,14-dimethyl-2,6,13,17-tetraazatricyclo[14,4,01.18,07.12]docosane

The complexes [Ni(L²)]Cl₂·10H₂O (1), [Cu(L²)](ClO₄)₂·3H₂O (2), [Cu₂(L²)(H₂O)₂Cl₂]Cl₂ (3) and [Zn(L²)]Cl₂·10H₂O (4) (L²=2,13-bis(2-pyridylmethyl)-3,14-dimethyl-2,6,13,17-tetraazatricyclo[14,4,0^1.18,0^7.12]docosane) have been synthesized and characterized by X-ray crystallography, electronic absorption, ¹³C NMR and magnetic susceptiblity as well as cyclic voltammetry. The crystal structures of 1 and 4 show that the metal ion has a slightly distorted octahedral geometry with two nitrogen atoms of the pendant arms at the axial positions. However, 2 exhibits a square-planar geometry, coordinated by secondary and tertiary nitrogen donors of the macrocycle. Furthermore, 3 reveals a binuclear structure and a center of symmetry in which the each copper ion is coordinated by a distorted square-pyramidal geometry with an N₃Cl basal plane and a water molecule in the apical position. The magnetic behavior for 3 shows that a ferromagnetic interaction between the copper(II) ions is predominant at intermediate temperature and then a weaker antiferromagnetic coupling is involved at lower temperature. Cyclic voltammetric studies for 1–3 indicate that 1 undergoes quasi-reversible one-electron oxidation to the Ni(III) and reversible one-electron reduction to the Ni(I), 2 undergoes a irreversible one-electron reduction to the Cu(I) state, while 3 undergoes an overall quasi-reversible two-electron reduction to the binuclear Cu(I) complex.     

Mn4 single-molecule magnets with a planar diamond core and S=9

The syntheses and magnetic properties are reported for three Mn₄ single-molecule magnets (SMMs): [Mn₄(hmp)₆(NO₃)₂(MeCN)₂](ClO₄)₂·2MeCN (3), [Mn₄(hmp)₆(NO₃)₄]·(MeCN) (4), and [Mn₄(hmp)₄(acac)₂(MeO)₂](ClO₄)₂·2MeOH (5). In each complex there is a planar diamond core of Mn^III ₂Mn^II ₂ ions. An analysis of the variable-temperature and variable-field magnetization data indicate that all three molecules have intramolecular ferromagnetic coupling and a S=9 ground state. The presence of a frequency-dependent alternating current susceptibility signal indicates a significant energy barrier between the spin-up and spin-down states for each of these three Mn^III ₂Mn^II ₂ complexes. The fact that these complexes are SMMs has been confirmed by the observation of hysteresis in the plot of magnetization versus magnetic field measured for single crystals of complexes 3 and 4. The hysteresis loops for both of these complexes exhibit steps characteristic of quantum tunneling of magnetization. Complex 4 shows its first step at zero field, whereas the first step for complex 3 is shifted to −0.10 T. This shift is attributable to weak intermolecular antiferromagnetic exchange interactions present for complex 3.     

Electrical conductivities of bis(1,3-dithiole-2-thione-4,5-dithiolato)rhodate anion salts

RhCl₃·3H₂O reacted with Na₂dmit (dmit²⁻; 1,3-dithiole-2-thione-4,5-dithiolate anion) and [NBu₄ⁿOH in methanol to afford [NBu₄ⁿ][Rh(dmit)₂] (1) and [NBu₄ⁿ]_1.5[Rh(dmit)₂] (2). Salt 1 was oxidized electrochemically in acetonitrile to afford [NBu₄ⁿ]_0.4[Rh(dmit)₂] (3). Suspended powders of 1 or 2 reacted with iodine in hexane to afford [NBu₄ⁿ][Rh(dmit)₂][I₃]_1.3 (4) or [NBu₄ⁿ]_1.5[Rh(dmit)₂[I₃]_0.4 (5). On the other hand, 1 dissolved in acetonitrile, reacted with bromine and iodine to yield [NBu₄ⁿ]_0.25[Rh(dmit)₂Br] (6) and [NBu₄ⁿ]_0.35[Rh(dmit)₂I] (7), respectively. All the salts behave as semi-conductors with electrical conductivities of 1 x (10⁻⁵ − 10⁻⁸) S cm⁻¹ at 25°C measured for compacted pellets. Electronic absorption, ESR and X-ray photoelectron spectra of the salts are discussed.     

Novel tetranuclear cubane-like Co(II) complexes involving chelate phosphoramide ligands

Interaction of cobalt(II) ions and sodium carbacylamidophosphates Na(L) (HL=PhC(O)NHP(O)(NR₂)₂; where NR₂ are morpholyl, HL¹; NMe₂, HL²; NEt₂, HL³) in methanol solution afforded polynuclear alkoxo complexes [Co₄{L¹}₃(OCH₃)₄(OH)(H₂O)₅·3H₂O] 1 and [Co₄{L}₄(OCH₃)₄(CH₃OH)₄] (L=L² 2, L³ 3). Data of spectral and TGA studies are presented. Coordination compounds 1 and 3 have been characterized by means of X-ray diffraction. Both the structures consist of tetranuclear cubane alkoxo clusters with methoxide ions bridging three metal centers (CoO 2.068(3)–2.093(4) Å) and phosphorylic ligands coordinated in a bidentatechelate fashion via the carbonyl oxygen atoms (CoO 1: 2.050(2); 3: 2.031(4) Å) and the phosphoryl groups (2.093(2) and 2.106(4) Å). Isolation of these cubane alkoxo complexes is an important proof for close resemblance in behavior of carbacylamidophosphate systems and β-diketonates towards transition metal ions.     

Co(III) complexes of Me-salpn and Me-salbn and the ring size effect on the coordination modes and electrochemical properties: The crystal structures of trans-[Co(Me-salpn)(py)2]PF6 and cis-α-[Co(Me-salbn)(4-Mepy)2]BPh4 · 4-Mepy

The synthesis and characterization of a series of cobalt(III) complexes of the general type [Co(N₂O₂)(L₂)]⁺ are described. The N₂O₂ Schiff base ligands used are Me-salpn (H₂Me-salpn = N,N′-bis(methylsalicylidene)-1,3-propylenediamine) (1–3) and Me-salbn (H₂Me-salbn = N,N′-bis(methylsalicylidene)-1,4-butylenediamine) (4–5). The two ancillary ligands L include: pyridine (py) 1, 3-metheylpyridine (3-Mepy) 2, 1-methylimidazole (1-MeIm) 3, 4-methylpyridine (4-Mepy) 4 and pyridine (py) 5. These complexes have been characterized by elemental analyses, IR, UV–Vis, and ¹H NMR spectroscopy. The crystal structures of trans-[Co^III(Me-salpn)(py)₂]PF₆, 1, and cis-α-[Co^III(Me-salbn)(4-Mepy)₂]BPh₄ · 4-Mepy, 4, have been determined by X-ray diffraction. Examination of the solution and crystalline structures revealed that the outer coordination sphere of the complexes exerts a noticeable influence on the inner coordination sphere of the Co(III) ion. The electrochemical reduction of these complexes at a glassy carbon electrode in acetonitrile solution indicates that the first reduction process corresponding to Co^III–Co^II is electrochemically irreversible, which is accompanied by the dissociation of the axial (R-py)–cobalt bonds. It has also been observed that the Co(III) state is stabilized with increasing the flexibility of the ligand environment.