Kinetics and mechanism of base hydrolysis of cis-(ammine) bis (ethylenediamine) (substituted salicylato) cobalt(III) complexes

The kinetics of base hydrolysis of cis-(ammine) bis (ethylenediamine) (substituted salicylato) cobalt(III) complexes, [Co{CO₂C₆H₃(X)(OH)}(NH₃)(en)₂]²⁺ (X = H, 5-SO₃⁻, 5-Br, 5-NO₂ and 3-NO₂), have been investigated in aqueous medium of I = 1.0 M. The phenate species, [Co{CO₂C₆H₃(X)(0)}(NH₃)(en)₂]⁺, have been found to undergo base hydrolysis via two path ways, i.e. one zero order in [OH⁻] (k₁ path) and another first order in [OH⁻] (k₂ path). The alkali independent rate constant (k₁) increases with the basicity of the phenate group and the plot of log k₁ against pK_OH of the complexes is a straight line with a positive gradient of 0.98±0.03. In contrast to this the plot of log k₂ against pK_OH has a gradient of −0.15±0.02. The latter correlation indicates that the electron withdrawing substituents in the salicylate moiety enhance the rate of base hydrolysis in the alkali dependent path. The reaction is not subject to imidazole catalysis in both k₁ and k₂ paths. Substantially high positive values of ΔS^≠ for both the paths are observed. Several mechanistic possibilities have been considered. SN₁CB mechanism involving the rate limiting CoO bond fission in the triagonal bipyramidal transition state appears to be best suited for both the paths. For the alkali independent path the unbound phenate group is suggested to generate the reactive conjugate base by abstracting the NH proton from the coordinated amine.     

Base hydrolysis ofcis-(methyl/ethylamine)bis(ethylenediamine) (salicylato)cobalt(III) complexes

The kinetics of the base hydrolysis ofcis-[Co(en)₂(RNH₂)-(SalH)]²⁺ (R=Me or Et; SalH=HOC₆H₄CO ₂ ⁻ ) were investigated in aqueous ClO ₄ ⁻ in the 0.004–0.450 mol dm⁻³ [OH⁻] range, I=0.50 mol dm⁻³ at 30–40°C. The phenoxide species is hydrolysed via [OH⁻]-independent and [OH⁻]-dependent paths, the latter being first order in [OH⁻]. The high rate of alkali-independent hydrolysis of the phenoxide species is associated with high ΔH^≠ and ΔS^≠ values, in keeping with the SNICB mechanism involving an amido conjugate base generated by the phenoxide-assisted NH-deprotonation of the coordinated amine. The [OH⁻]-dependent path also involves the conventional SN₁ CB mechanism. The rate constant, k₁, for the SNICB path exhibits a steric acceleration with the increasing size of the non-labile alkylamine, whereas the rate constant, k₂, for the SN₁CB path shows a reverse trend. TMC 2578     

Reactions of cis-(aqua)(amine)bis(ethylenediamine)cobalt(III) complexes with sulfur(IV) in aqueous medium

The kinetics of the formation/acid-catalysed aquation (SO2 elimination), CoIII-OSO2+CoIII-SO3+ isomerization, intramolecular reduction and base hydrolysis of the O-bonded sulfito complexes, cis-[Co(en)2(RNH2) (OSO2)]+ (en=ethylenediamine; R=H, Me, Et, PhCH2 and C6H11) have been investigated. The spontaneous and base-catalysed isomerization involve loss of monodentate amine ligands from the CoIII centre to give trans-[Co(en)2(SO3-S)2]– (in excess SO32–) or trans-[Co(en)2(OH)(SO3-S)] (under base hydrolysis conditions). This result is presumably associated with a cis-labilizing action of the O-bonded sulfite. Steric retardation is observed for the formation and acid-catalysed aquation of the O-sulfito complex, the effect being relatively larger for the latter reaction. Steric acceleration is observed in the isomerization and intramolecular reduction and base hydrolysis of the O-sulfito complexes.¶ The trans-S-disulfito complex is prone to fast H+-catalysed aquation {k=(1.52±0.06)×104 dm3 mol–1 s–1, H=81 ± 2 kJ mol–1, S= 108 ± 5 J K–1 mol–1 at 25°C, I = 1.0 mol dm–3} yielding trans-[Co(en)2 (SO3-S)(OH2)]+.     

Kinetics and mechanism of hydrolysis ofcis-bis(ethylenediamine)imidazole(salicylato)cobalt(III) ion

Summary The kinetics of aquation and base hydrolysis reactions ofcis-[(en)₂Co(imH)O₂CC₆H₄OH-o-o]²⁺ (imH = imidazole) have been investigated in a medium of 1.0 M ionic strength, In the 0,1–1,0 M [H⁺] range (60–70°) aquation proceedsvia spontaneous and acid catalysed paths . In the 0,05–1.0 M [OH^–] range (30–40°), the complex exists predominantly as the bis-deprotonated species,cis-[(en)₂Co(im)O₂CC₆H₄O-o], and the pseudo-first-order rate constant fits the relationship k_obs = k_b + k_b° [OH^–] satisfactorily. The labilizing action of coordinated imidazolate anion(im^–) on the cobalt(III)-bound salicylate is 10³ times stronger than that of imidazole. The mechanism is essentially I_d in the aquation paths and SN₁cb (Co-O bond fission) in the alkali independent and dependent paths respectively.     

Kinetics and mechanism of base hydrolysis oftrans-bis(Hmalonato)bis(ethylenediamine)cobalt(III) ion

Summary The kinetics of the first step of base hydrolysis oftrans-bis(Hmalonato)bis(ethylenediamine)cobalt(III) [malH^–=HO₂CCH₂CO ₂ ^– ] has been investigated in the 15–35° C range, I=0.3 mol dm^–3 (NaClO₄) and [OH^–]=0.015–0.29 mol dm^–3. The rate law is given by –d In[complex]_T/dt=k₁[OH^–] and at 30° C, k₁=8.5×10^–3 dm³ mol^–1s^–1, H=117.0±7.0 kJ mol^–1 and S=99.0±24.0 JK^–1mol^–1. The activation parameters data are consistent with the SN₁ cb mechanism.     

Kinetics and mechanism of acid and base hydrolysis ofcis-chloro-(benzotriazole)bis(ethylenediamine)cobalt(III) andcis-chloro-(N-methylbenzotriazole)bis(ethylenediamine)cobalt(III) cations

Summary The kinetics of acid hydrolysis ofcis-[CoCl(btzH)(en)₂]²⁺ andcis-[CoCl(btzMe)(en)₂]²⁺ complexes (where btzH = benzotriazole, btzMe =N-methylbenzotriazole and en = ethylenediamine) have been investigated in HClO₄ at ionic strength 1 = 0.25 mol dm^–3 in the 30–40° range. In the 1.0 x 10^–1 to 1.0 X 10^–3 mol dm^–3 acid strength range, the rate of aquation of the [CoCl(btzH)(en)₂]²⁺ cation follows the relationship:-d ln[complex]/dt = k₁ + k₂K_NH[^H+]^–1, where k₁ and k₂ are aquation rate constants of the acid independent and acid dependent steps respectively, and K_NH is the acid dissociation constant of the coordinated benzotriazole.cis-[CoCl(btzMe)-(en)₂]²⁺ undergoes acid independent hydrolysis presumably due to the absence of a labile N-H proton. The base hydrolysis could be followed for thecis-[CoCl(btzMe)(en)₂]²⁺ complex only by measuring hydrolysis rates at 0°.     

The kinetics of aquation and racemization of some cis- chloro-, hydroxo-, and aquabis(ethylenediamine)(amine)cobalt(III) complexes

Aquation rates forcis-CoCl(en)₂(A)²⁺ (A = 3,5-lutidine, imidazole, N-methylimidazole, benzimidazole) have been determined by halide release titration in 1.0 M HNO₃ at 50–80°C. Kinetic parameters are (in the above order of A) 10⁷k₂₉₈ (sec^?1), 7.4, 5.7, 1.3, 9.7; E_a (kJ/mole), 103, 101, 130, 112; log PZ (sec^?1), 11.89, 11.53, 16.04, 13.58; ΔS₂₉₈^? (J/°K· mole),?26, ?32, +54,+7. Rates of racemization for active cis-Co(en)₂(A)-(OH₂)³⁺ were measured spectropolarimetrically in 0.1 M HClO₄, 0.02 M Hg²⁺ for A = ammonia, cyclohexylamine, 3,5-lutidine, N-methylimidazole. Kinetic parameters are (units as above) 10⁹k₂₉₈ = 1.8, 38.0, 7.7, 1.7; E_a = 150, 135, 152, 157; log PZ = 17.49, 16.18, 18.56, 18.87; ΔS₂₉₈^? = +82, +57, +102,+108. Rates of racemization of the active hydroxo complexes cis-Co(en)₂(A)(OH)²⁺ (A = NH₃, CH₃NH₂, 3,5-lutidine, imidazole) were measured similarly at pH = 8 (π = 2.0, NaClO₄). The racemization of the hydroxo is ca. (3–4) × 10³ faster than for the corresponding aqua complex. Kinetic parameters are 10⁶k₂₉₈ = 2.55, 7.2, 30.1, 7.0; E_a = 138, 123, 122, 128; log PZ = 18.58, 16.39, 16.85, 17.18; ΔS₂₉₈^? = +102,+60, +69,+76. Racemization rates for aquahydroxo mixtures (A = CH₃NH₂, 3,5-lutidine, imidazole) were also determined in the pH range of 4–8 (θ = 2.0, NaClO₄) at 50.6°C, and pK_a data calculated from the pH versus k plot are 5.50, 5.65, and 6.40, respectively, for A.     

Kinetics and mechanism of complexation of iron(III) bycis-(salicylato)(methyl/ethylamine)bis(ethylenediamine)cobalt(III) ions

The formation and dissociation of the binuclear complexes of Fe^III withcis-[Co(en)₂(RNH₂)SalH]²⁺ [R=Me, Et and SalH=C₆H₄(OH)CO ₂ ⁻ ] were studied by a stopped-flow technique at 20–35°C, and I=1.0 mol dm⁻³ (ClO ₄ ⁻ ). The formation of the binuclear species, N₅CoSalFe⁴⁺, involves reactions of the phenol form of the Co^III substrates with Fe(OH₂) ₆ ³⁺ and Fe(OH₂)₅OH²⁺. The mechanism of reaction of Fe(OH₂)₅OH²⁺ is essentially Id, while that of Fe(OH₂) ₆ ³⁺ appears to be Ia. The formation rate constant, k₁, for Fe(OH₂) ₆ ³⁺ /N₅CoSalH²⁺ reaction decreases as the amine chain length increases, whereas the same (k₂) for the Fe(OH₂)₅OH²⁺/N₅CoSalH²⁺ reaction does not show any such trend. The binuclear species, N₅CoSalFe⁴⁺, dissociates to yield a Co^III substrate and Fe^III speciesvia a predominantly spontaneous dissociation path and a minor acid catalysed path which are relatively insensitive to the variation in size of the non-labile amine chain length.     

Kinetics of acid- and iron(III)-catalysed aquation of cis-(salicylato)-(methyl/ethylamine) bis(ethylenediamine)cobalt(III)

Summary The kinetics of spontaneous, acid- and Fe^III-catalysed aquation of cis-[Co(en)₂(RNH₂)(SalH)]²⁺ complexes (R = Me, Et; SalH = C₆H₄(OH)CO _inf2 ^sup- ) were studied in acid perchlorate medium, I = 1.5 mol dm^–3 (NaClO₄) at 70–80°C. The Fe^III-catalysed aquation proceeds via formation of a binuclear species, the evidence of which follows from aquation, complexation and equilibrium studies. The spontaneous aquation rate shows steric acceleration with the increase of the nonlabile amine chain length, while that of acid- and Fe^III-catalysed aquation shows the opposite trend. An attempt is made to explain the discrepancy in the rate on the basis of solvent cosphere effects.     

Effect of solvent on the reactions of coordination complexes part VII: Kinetics of solvolysis of cis-(bromo) (imidazole) bis-(ethylenediamine)cobalt (III) and cis-(bromo) (N-methyl imidazole)bis-(ethylenediamine) cobalt(III) in methanol-water media

The kinetics of the solvolytic aquation of cis-(Bromo) (imidazole) bis(ethylenediamine) cobalt (III) and cis-(Bromo) (N-methylimidazole) bis(ethylenediamine) cobalt(III) have been investigated in aqueous methanol media with methanol content 0–80% by weight and at temperatures 40–55°C. The pseudo-first order rate constant decreases with increasing methanol content. Plots of log k vs. D (where D_s is the bulk-dielectric constant of the solvent mixture) and log k vs. the Grunwald-Winstein Y-solvent parameter are nonlinear, the curvature of the plots is relatively more significant for the imidazole complex. The plots of log k vs. molfraction of methanol (X_MeOH) for both the substrates also deviate from linearity, the deviation being less and less marked, particularly for the N-methyl imidazole complex, as the temperature is increased. Hence preferential solvation phenomenon appears to be less significant when the N-H proton of imidazole is replaced by -CH₃ group. The plots of calculated values of the transfer free energy of the dissociative transition state, cis-{[(en)₂Co(B)]³⁺}* (B = imidazole, N-methylimidazole), relative to that of the initial state, cis-[Co(en)₂(B)Br]²⁺, for the transfer of the ions from water to the mixed solvent, against X_MeOH exhibit maxima at X_MeOH = 0.06, 0.27, and 0.12, 0.36 and minima at X_MeOH = 0.12 and 0.19 for cis-[(en)₂Co(imH)Br]²⁺ and its N-methylimidazole analogue respectively which are in keeping with the solvent structural changes around the initial state and transition state of these substrates as the solvent composition is varied. Plots of activation enthalpy and entropy against molfraction of the solvent mixtures exhibit maxima and minima. This type of variations of the activation parameters, ΔH^≠ and ΔS^≠, with X_MeOH speaks of the enthalpy and entropy changes associated with the solvent-shell reorganization of the complex ions both in the initial and in the transition states which contribute appreciably to the overall activation enthalpy and entropy of the aquation reaction.     

The first oxygen-bonded sulfenate ion: crystal and molecular structures of bis(ethylenediamine)(2-pyridinesulfenato-O)cobalt(III) and bis(ethylenediamine)(2-pyridinesulfinato-O)cobalt(III)

The first O-bonded sulfenate species [Co(en)2(py-SO-O)]2+ has been synthesized by isomerization of its S-bonded linkage isomer, [Co(en)2(pyridine-2-sulfenate-S]2+. The sulfenate ion in both forms is stabilized by coordination to the electropositive cobalt(III) ion. The driving force for the formation of the O-bonded sulfenate linkage isomer comes from the four to five membered ring expansion which accompanies the rearrangement. Crystal structures of the green O-sulfenate confirm the formulation and reveal varying amounts of a cocrystallized O-bonded sulfinate diastereomer. The cations have essentially identical structures except for the extra oxygen in the O-sulfinate. Differences in packing of cations and perchlorates give rise to two different structural types for the salts, corresponding to sulfenate-rich and sulfinate-rich phases.     

Kinetics of aquation and base hydrolysis ofcis-(carboxylato) (ethylamine)bis(ethylenediamine)cobalt(III) ions

Summary The aquation ofcis-[Co(en)₂(NH₂Et)O₂CR]²⁺ [R=H or Me] is strongly acid-catalysed and the rate and activation parameters for this process are reported. No significant rate difference is observed in the spontaneous aquation path for the complexes. The acetato complex undergoes acid catalysed aquation at a rate comparable to the of the corresponding formato complex, in contrast with the relative basicities of the coordinated formate and acetate. This result is interpreted in terms of relative solvation effects of the initial and transition states of both complexes.The base hydrolysis of both complexes obeys overall second order kinetics in the 0.05[OH^–]_T 0.35 mol dm^–3 range (I=0.5 mol dm^–3). The formato complex reacts five times faster than its acetato analogue under comparable conditions, which is fully consistent with the dissociative mode of activation of the amido conjugate base involving Co–O bond heterolysis. A substantially large positive value for the activation entropy supports SN₁CB mechanism for base hydrolysis.     

Reactions of coordinated ligands,part II1). Kinetics of iodination of salicylate in bis(ethylenediamine)(salicylato)cobalt(III) cation

Summary The rates of iodination of Salicylate in the bis-(ethylenediamine)(salicylato)cobalt(lII) complex and free Salicylate have been measured in acetate buffer at 40° and I = 0.1 M. The reaction is catalysed by acetate and water. The reactivity order for both acetate- and water-catalysed paths is: [HSal]^– < [(en)₂CoSal]⁺ < [Sal]^2–, where [HSaI]^– and [Sal]^2– stand for the phenol and phenate forms of Salicylate respectively. Chelation of [Sal]^2– to cobalt(III) results in a rate reduction of its iodination by 10⁷.     

Kinetics and mechanisms of the reactions of thiosulphato-amine complexes of cobalt(III). Part II. Base hydrolysis of the bis(ethylenediamine)thiosulphatocobalt(III) ion

Summary Base hydrolysis of the bis(ethylenediamine)thiosulphatocobalt(III) was investigated spectrophotometrically between 35 and 65 °C and with base concentrations (NaOH) up to 2.0 mol dm^–3. The hydrolysis consists of a one-stage reaction, followed by a slow dechelation step, and then by a fast ligand loss. The reaction is base-dependent. The products of the reaction are an equilibrium mixture ofcis- andtrans-Coen₂ (OH) ₂ ⁺ . Activation parameters for the reaction as determined by the Eyring equation, are H=77.8±4.6 kJ mol^–1 and S=–75±20 JK^–1 mol^–1.     

Effect of solvent on reactions of coordination complexes. Part 12: Kinetics and mechanism of chloride substitution reactions ofcis-(chloro)(2-aminoethanol)bis(ethylenediamine) cobalt(III) andcis-(chloro)(1-aminopropan-2-ol)-bis(ethylenediamine) cobalt(III) ions in acidic and basic ethylene glycol-water media

Summary The loss of chloride ion from the title complexes resulted in the predominant formation of the chelated amino-alcohol productscis-[Co(en)₂(NH₂CH₂CH(X)O/H)]^2+/3+ (X=H or Me). The kinetics of chloride release were investigated in aqueous ethylene glycol (EG) media (0 to 80% by wt of EG) at 40°–65°C in acidic media and at 20°–35°C in basic media. The rate constants decreased linearly with increasing mol fraction of the cosolvent. The plots of log kversus D _s ^–1 (S_s=bulk dielectric constant, k=first order or second order rate constants) were essentially linear with negative slopes for the reactions in an acidic medium, and tended to be curved for the base catalysed reactions. The activation enthalpies and entropiesversus X_EG (X_EG=mol fraction of EG) plots indicated extrema which might be associated with the effects of the solvent structural changes on these thermodynamic parameters. The observed solvent isotope effect at 50°C, [HClO₄]=0.010 mol dm^–3 for Cl^– release was lower than the value for the aquation ofcis-[Co(en)₂(alkylamine)Cl]²⁺ complexes reported in the literature. This is consistent with the lack of direct solvent molecule participation in the actual act of substitution at the cobalt(III) centre, as expected for a true intramolecular reaction.Part-11: A. C. Dash and J. Pradhan,Ind. J. Chem.,29A, 167 (1990).     

Kinetics and mechanism of the base hydrolysis of thecis-chlorobis(ethylenediamme)(benzimidazole)cobalt(III) cation

Summary The hydrolysis ofcis-[CoCl(en)₂(bzmH)]²⁺ (en=ethylenediamine, bzmH=benzimidazole) has been studied over the pH range 8.31–11.58 at I=0.1 mol dm^–3 and 25°. Potentiometric titration of aqueous solutions of the [Co(en)₂(bzmH)OH₂]³⁺ complex obtained by silver(I) catalysed aquation of the chloro-complex give pK₁=5.81 and pK₂ = 8.84 for Equilibria (1) and (2) at 25° and I=0.1 mol dm^–3. Spectrophotometric titration of the hydroxy complex also gives a value of pK₂=8.88 for the ionisation of the coordinated benzimidazole. The kinetic data can be interpreted in terms of base hydrolysis ofcis-[CoCl(en)₂(bzmH)]²⁺ (k_OH=220 dm³ mol^–1s^–1) andcis-[CoCl(en)₂(bzm)]⁺ (k_OH=14.9 dm³ mol^–1s^–1). Comparisons with the corresponding imidazole and pyridine complexes are made.     

Kinetics and mechanism of an unique hydrolysis reaction of (hexafluoroacetylacetonato)bis(ethylenediamine)cobalt(III) in aqueous solution

Summary Addition of base to the title complex results in the rapid reversible formation of the hydrolysed species Co(en)₂-(hfac · OH)⁺ in which the coordinated hexafluoroacetylacetonato ligand contains a hydroxyl group on the carbonyl carbon atom. The kinetics of both the forward hydrolysis and reverse acidolysis reactions were followed spectrophotometrically using stopped-flow and T-jump techniques. The corresponding rate constants areca. 3×106 and 1×10⁸ M^–1s^–1, respectively, for various buffer systems at 25 °C and ionic strength 1.0 M. A combination of the kinetic and equilibrium data enables the estimation of the uncatalyzed (spontaneous) forward and reverse reaction components. The results are discussed with reference to similar data reported for the hydrolysis and reverse acidolysis reactions of the uncoordinated acetylacetonato ligand.