Spectrophotometric study of the reaction between cobalt(II)-dipeptide complexes and molecular oxygen

Summary The influence of pH and ligand structure on the reaction of cobalt(II) complexes with various dipeptides and molecular oxygen was examined. The minimum pH value required for the formation of dioxygen adducts was found to be about 6.5. This value should be related to amidic deprotonation of dipeptides, which seems to occur in the examined systems at particularly low values. The location and steric hindrance of the side chains of the dipeptides have a strong influence on the reaction rate. The presence of a substituent group on the N-terminal amino acid promotes oxygen coordination, while, when the substituent group is on the C-terminal residual, a decrease of reaction rate is observed.A stabilizing effect of the aromatic ring on the dioxygen adducts is found only when the substituent is in the C-terminal position, and seems to be independent of the presence of additional coordinating groups.Some information regarding the mechanism of the irreversible decomposition of the cobalt(II) complexes has been obtained by studying the effect of pH and ligand structure on the reaction rate.Work supported by National Research Council of Italy.     

Formation and reactivity of a cobalt (II) hydroperoxide intermediate

Reaction of Tpt-Bu,MeCo-H with O2 proceeds via a spectroscopically observable hydroperoxide whose reactivity in solution and in the solid state differ dramatically.     

Formation of cyanide complexes of cobalt(II) and manganese(II)

The formation of complexes of the cyanide ion with Co(II) and Mn(II) has been studied potentiometrically in an aqueous sodium perchlorate medium of unit ionic strength at 298 K. Studies of the equilibria in the cobalt(II)-cyanide system show that at least one strong mononuclear complex exists, while in the manganese(II)-cyanide system two mononuclear complexes can be formed in the concentration range studied.     

Allylation and oxidation reactions promoted by cobalt(II) complexes

Two examples of radical reactions involving cobalt complexes are described. The first one concerns the reactions of allylcobaloximes with 2-bromo 2-phenylacetonitriles leading to the corresponding monoallyl derivatives. It is shown that both the rate and regioselectivity of the reactions are affected by the nature of the substituents on the phenyl group: electron-withdrawing groups give higher rates and highly regiospecific reactions. The second type of radical reaction which finds useful synthetic applications is the oxidation of phenols by 02 catalyzed by Schiff base cobalt complexes. By choosing carefully the catalyst and the solvent, these oxidations can be highly selective, quinones being the major oxidation products in most cases.     

Diazabutadiene cobalt(II) complexes

Summary Studies on the chelates of cobalt(II) with the bidentate ligands 1,4-diphenyl(2,3-dimethyl-1,4-diazabutadiene) (PMB) and 1,4-di(p-methoxyphenyl)-2,3-dimethyl-1,4-diazabutadiene (MPMB) have been carried out. On the basis of elemental analyses, the complexes are [Co(PMB)Cl₂], [Co(PMB)₂(C1O₄)₂], [Co(MPMB)Cl₂] and [Co(MPMB)₂(ClO₄)₂].Both ligands are bidentatevia nitrogen atoms in all the complexes. The magnetic susceptibility and i.r. and u.v.-visible spectra are reported and discussed. The chloro-compounds involving two chlorine ligands and, in the perchlorate compounds, the ClO ₄ ^– groups are bound to the cobalt(II) centre.     

Formation equilibria of copper(II) complexes with some pyridinols in various solvents

Complexation of copper(II) with two different pyridinols in three solvents has been studied by visible spectrophotometry and flow-microcalorimetry. The influence of the solvent on tautomeric equilibrium of the ligand, on distribution, on stability and on formation enthalpies of the main complex species is discussed.     

Activation volumes for peroxodisulphate oxidation of cobalt(III), iron(II) and nickel(II) complexes

Summary Dependences of rate constants on pressure (in aqueous solution up to 1.25 kbar) are reported for peroxodisulphate oxidation of hexacyanoferrate(II), tris(2,2-bipyridyl)iron(II), tris(1,10-phenanthroline)iron(II), bis(1,4,7-triazacyclononane)nickel(II) and bis(1,2-ethanediamine)cysteinatocobalt(III) and its thioglycollato-analogue, and for periodate oxidation of the two last-named complexes. Derived activation volumes are reported and discussed in terms of intrinsic and solvational contributions. Rate laws and pressure effects on reactivity are reported for the reaction of peroxodisulphate with pentacyanoferrates(II) containing N-alkylpyrazinium ligands.     

Reversible formation of binuclear complexes between pyridine-2-carboxylato(tetraethylenepentamine)cobalt(III) and nickel(II)/cobalt(II) in aqueous solution. Anomalous behaviour in the dissociation of binuclear complexes

The kinetics of the reversible formation of binuclear species between M(OH₂) ₆ ²⁺ (M = Ni^II and Co^II) and oxygen-bonded (tetren)Co(pycH)³⁺ (tetren = tetraethylenepentamine, pycH = N-protonated pyridine-2-carboxylate) have been investigated by stopped-flow spectrophotometry at 25°C, I = 0.3 mol dm^-3. Both the protonated (pyridine-N) and deprotonated forms of the Co^III complex were involved in the formation of the binuclear complex (tetren)Co(pyc)Co⁴⁺, whereas only the deprotonated form of the complex was involved in the formation of (tetren)Co(pyc)Ni⁴⁺. The rate date forthe formation of the binuclear complex are consistent with an Id mechanism. Interestingly, the dissociation of the binuclear Co^II complex (tetren)Co(pyc)Co⁴⁺ was acid-catalysed while that with Ni^II was acid-independent. A suitable explanation for this anomalous behaviour has been discussed.     

Cymantrenecarboxylate complexes of nickel(II) and cobalt(II)

Reactions of cymantrenecarboxylic acid (CO)₃MnC₅H₄COOH (CymCOOH) with Ni(II) and Co(II) pivalates in boiling THF followed by extraction of the products with diethyl ether or benzene and treatment with triphenylphosphine gave the binuclear complexes LM(CymCOO)₄ML (M = Ni (I) and Co (II); L = PPh₃). Treatment of the benzene extract of the intermediate cobalt cymantrenecarboxylate with 2,6-lutidine (L’) yielded the trinuclear complex L’Co(CymCOO)₃Co(CymCOO)₃CoL’ (III). Complex I is antiferromagnetic; μ_eff decreases from 3.7 to 0.9 μ_B in a temperature range from 300 to 2 K. Structures I-III were identified using X-ray diffraction. The frameworks of complexes I and II are like Chinese lanterns, having four carboxylate bridges and axial ligands L (Ni-P, 2.358(1) Å; Co-P, 2.412(2) Å). The metal atoms are not bonded to each other (Ni…Ni, 2.7583(9) Å; Co…Co, 2808 (2) Å). In complex III, either terminal Co atom is coordinated to one ligand L’ (Co-N, 2.059(2) Å). The Co atoms form a linear chain showing no M-M bonds (Co…Co, 3.346(1) Å), in which either terminal Co atom is linked with the central Co atom by three carboxylate bridges (on average, Co_centr-O, 2.164 Å; CO_term-O, 2.094 Å). In one of three carboxylate groups, only one carboxylate O atom serves as a bridge, while the other is bonded to the terminal Co atom only (Co_term-O, 2.094 and 2.389 Å); so this carboxylate group is a bridging and chelating ligand.     

Nickel(II) and cobalt(II) complexes of rhodanine

Summary Nickel(II) and cobalt(II) complexes of rhodanine (Hrd) were prepared from the metal chloride or acetate and the ligand. With an excess of NH3, the octahedral [Ni(NH₃)₆](Rd)₂ and [Co(NH₃)₅Rd]Rd complexes are ob-tained; use of only two NH₃ equivalents per metal ion yields the Ni(Rd)₂ sd HRd · NH₃ and [Co(Rd)₂ ] · 1.5 H₂O complexes, the first with tetragonally distorted hexacoordination and the second with polymeric octahedral coordination. By using two equivalents of NaOH per metal ion, the binuclear [Ni(Rd)₂][Ni(Rd)₂ · (HRd)₂] · 2 H₂O complex is formed having one diamagnetic planar and one high spin octahedral chromophore. Rhodanine is coordinated through the thiocarbonylic sulphur in the neutral form and through the thiocarbonylic sulphur and the deprotanated nitrogen atoms in the rhodanidato anionic form.     

Formation of cobalt(II), nickel(II) and copper(II) chloro complexes in alcohols and the Irving-Williams order of stabilities

Summary Co^II chloro complexes were studied in MeOH at 25 °C and at constant ionic strength of 1 mol dm^–3. Formation of three complexes is postulated for which the overall stability constants are calculated: log ₁ = 1.2, log ₂ = 1.7 and log ₃ = 1.4. The electronic spectra and the formation curves of the identified species are presented for the first time in this medium. The results are compared with those obtained in other alcohols and increasing stability with increasing molecular weight of the solvents is established. Further comparative study showed that the maximum stability of the chloro complexes is found with the Cu^II ion as the central atom. This confirms the Irving-Williams order of stabilities for the first transition metal complexes in this alcoholic medium and the result is explained in terms of the second ionization potential of the elements.     

Formation of cobalt (ɪɪɪ) polyaminopolycarboxylate complexes in aqueous solutions by the peroxide oxidation of the cobalt (ɪɪ) complexes

The dynamics of the formation of cobalt(iii) complexes with anions of iminodiacetic, nitrilotriacetic, ethylenediaminetetraacetic, and diethylenetriaminepentaacetic acids in aqueous solutions by the peroxide oxidation of cobalt(ii) polyaminopolycarboxylates was studied by spectrophotometry and potentiometry. The optimum conditions for the formation of coordination cobalt particles in the highly oxidized state were selected, and the composition of the formed cobalt(iii) chelates was determined. Data on the thermodynamic stability of the coordinatively bound cobalt particles, specific features of the kinetics of peroxide oxidation, and the influence of the concentrations of the main components and acidity of the solutions on the rate of redox processes of cobalt(iii) polyaminopolycarboxylate formation were obtained. It was found that a strong catalytic decomposition of the reagent-oxidant at pH > 4.0 occurs during the formation of oxygenated intermediates in solutions of mononuclear ethylenediaminetetraacetate and binuclear diethylenetriamine-pentaacetate complexes of cobalt(ii). Based on the NMR spectroscopy data, a mechanism for the formation of the oxygenated particles was proposed. It was shown that diamagnetic binuclear oxygenated chelates of cobalt(iii) are characterized by low kinetic stability, which leads to the deoxygenation and formation of weakly paramagnetic mononuclear complexes of cobalt(iii).

     

Simple and mixed complexes of cobalt(II) and cobalt(III) ions

Summary Bivalent and trivalent cobalt complexes with 1-(2-pyridylazo)-2-naphthol (PAN), PAN+1, 10-phenanthroline and PAN+2, 2-bipyridyl were prepared and characterized by physico-chemical and magnetic measurements. The spectral studies suggest that PAN behaves as a bidentate ligand and is coordinated to metal ions through oxygen and (pyridine) nitrogen, whereas 1, 10-phenanthroline and 2, 2-bipyridyl are coordinated through (pyridine) nitrogen. The tentative (M–O) and (M–N) band assignments in the lower i.r. region, and magnetic moment data favour four coordination for the complexes studied.     

Chloro complexes of cobalt(II) in acetone

Equilibria of cobalt(II) perchlorate with lithium chloride in 0.1 M LiClO₄ acetone solution have been investigated by means of potentiometry and spectrophotometry at 25.0°C. By the addition of a large excess of medium salt (LiClO₄), the ionic dissociation of electrolytes are surpressed and the ion-pairs predominate in this medium. It was confirmed that AgAgCl electrode gives rise to the Nernstian response in this medium. The potentiometry reveals the formation of following chloro complexes of cobalt (II): $\text{Co(ClO}{}_4\text{)}{}_2\text{+LiCl}\text{⇌}\text{K}{}_1\text{CoCl(ClO}{}_4\text{)+LiClO}{}_4$$\text{Co(ClO}{}_4\text{)+LiCl}\text{⇌}\text{K}{}_2\text{CoCl}{}_2\text{+LiClO}{}_4$$\text{CoCl}{}_2\text{+LiCl}\text{⇌}\text{K}{}_3\text{LiCoCl}{}_3$Successive formation constants were determined as log K₁ = 5.0 ± 0.3, log K₂ = 6.2 ± 0.3 (log β₂ = log K₁K₂ = 11.15 ± 0.03) and log K₃ = 5.97 ± 0.03. By the spectrophotometric titration at higher concentration of lithium chloride, we have the following equilibrium: $\text{LiCoCl}{}_3\text{+LiCl}\text{⇌}\text{K}{}_4\text{LiCoCl}{}_3$ with formation constant of log K₄ = 2.64 ± 0.05. Absorption spectra of these complexes are presented.     

Formation and dissociation kinetics of Cu(II) and Ni(II) complexes with N2S2-macrocycles

The kinetics of the formation and dissociation of the Cu(2+) and Ni(2+) complexes with a series of N(2)S(2) macrocycles, in which the ring size and the geometry of the arrangement of the donor groups have been varied, have been measured at 25 [degree]C and I= 0.5 (KNO(3)). Both the deprotonated (L) and the monoprotonated (LH(+)) form of the ligands are reactive species in the formation step. In their deprotonated form, first bond formation, in some cases supported by an ICB effect, is rate determining, independently of the ring size. In the monoprotonated form, we find slower rates, due to the charge repulsion and/or conformation changes induced by hydrogen bonds. In contrast the mechanism of the dissociation is very dependent on the ring size. The complexes with the smaller rings react as flexible open-chain ligands directly with H(+). In contrast, the complexes with the larger rings react in a similar way as rigid ligands: first the metal amine bond slowly dissociates so that the free electron pair of the amine can take the "out conformation" and then it is protonated. The 14-membered macrocycle L(3) forms complexes in which the metal ions are ideally coordinated so that their dissociation becomes extremely slow.     

Iron(II), manganese(II) and cobalt(II) complexes containing tetradentate biphenyl-bridged ligands and their application in alkane oxidation catalysis

A series of manganese(II), iron(II) and cobalt(II) bis(triflate) complexes containing linear tetradentate bis(imine) and bis(amine) ligands with a biphenyl bridge have been synthesized. The twist in the ligand backbone due to the biphenyl unit leads in the case of the bis(imine) ligands (1 and 2) containing sp2 hybridised N donors, to a distorted cis-alpha coordination geometry, whereas in the case of the biphenyl- and biphenylether-bridged bis(amine) ligands (7 - 9 and 12), a trans coordination geometry is observed. The catalytic properties of the complexes for the oxidation of cyclohexane, using H2O2 as the oxidant, have been evaluated. Only the iron complexes show any catalytic activity under the conditions used, but the low conversions and selectivies observed indicate that these catalysts lead predominantly to free radical auto-oxidation.     

N-acetyl-DL-leucinate cobalt(II), nickel(II) and zinc(II) complexes

Summary Complexes of the type M(AcLeu)₂ · B₂ (M = Co^II, Ni^II or Zn^II; B = H₂O, py, 3-pic, 4-pic; AcLeu =N-acetyl-DL-leucinate ion) and M(AcLeu)₂ B (M = Co^II or Zn^II and B = o-phen) were prepared and investigated by means of magnetic and spectroscopic measurements. The i.r. spectra of all the complexes are consistent with bidentate coordination of the amino acid to the metal ion. The room temperature solid state electronic spectra indicate that the symmetry of this species is closer toD _4h and that MO₆ and MO₄N₂ chromophores are present in the M(AcLeu)₂ · 2 H₂O and M(AcLeu)₂B_n · x H₂O (B = py, 3-pic, 4-pic, n=2 and x=0 for M = Ni^II; B = o-phen, n=1 and x=0 for M = Co^II; B = py, 3-pic, 4-pic, n=1 and x=1 for M = Co^II) complexes, respectively. By comparing the Dq values of the amino acid and those of other N-substituted amino acids previously studied, a spectrochemical series of the the cobalt(II) and nickel(II) complexes is proposed. The¹ H n.m.r. spectra of the zinc(II) complexes confirm the proposed stereochemistry.