Kinetics and mechanism of Pb2+ ion promoted aquation of tris-oxalatochromate(III) in acid perchlorate media

Summary In low acid (0.02 M HClO₄) media, Pb²⁺ ion strongly catalyses the aquation of Cr(ox) ₃ ^3– to givecis-Cr(ox)₂(OH₂) ₂ ^– ion. The catalytic efficiency of Pb²⁺ as represented by the second order rate constant, k_pb (3.76 × 10^–4 M^–1 s^–1 at 25 °C; I, 1.0 M perchlorate), for the Pb²⁺ catalysed path is remarkably higher than might be expected on the basis of K_pb-ox, the first formation constant for the lead-oxalate complex. This catalytic superiority of Pb²⁺ has been found to result mainly from a comparatively much lower H (65.2 ±0.8 kJ mol^–1) value which more than compensates for the relatively unfavourable S value (–93.2 ±2.4 JK^–1mol^–1) for this catalysed path. This low S value is, however, in line with the entropy of hydration of Pb²⁺ ion. These facts, together with the different LFER plots, have been utilised to propose a plausible mechanism for such catalysed reactions.     

Gold nano particles catalyzed oxidation of hydrazine by a metallo-superoxide complex: experimental evidences for surface activity of gold nano particles

Gelatin-capped gold nano particles (GNPs) of diameter 23, 28 and 36 nm were prepared and characterized as almost monodispersed, near-spherical solids. In acidic media, these GNPs at their very low concentration level (～10(-13) M) catalyze the oxidation of hydrazine by the metallo-superoxide, [(NH(3))(4)Co(III)(μ-NH(2),μ-O(2))Co(III)(NH(3))(4)](NO(3))(4) (1). In the presence of a large excess of hydrazine over [1], the catalyzed oxidation is first-order in [1], [GNPs] and media alkalinity. The pure first-order dependence implies that the size as well as the nature of the catalyst remained unchanged during the reaction. The catalytic efficacies increased with increased total surface area of the GNPs. Increasing T(Hydrazine) (T(Hydrazine) is the analytical concentration of hydrazine) tends to saturate the first-order rate constant (k(o)) for hydrazine oxidation and a plot of 1/k(o)versus T(Hydrazine) was found to be linear at a particular [GNPs], indicating the GNPs assisted deprotonation of N(2)H(5)(+) to N(2)H(4). The rate constants show a non-linear behavior with temperature studied in the range 288-308 K. At a lower temperature interval, viz. 288-298 K, k(o) increases with increasing temperature whereas at temperature interval, viz. 303-308 K, k(o) decreases with temperature. Such a variation indicates the important process of absorption and desorption of the reactants on and from the surface. A plausible mechanism for the GNPs catalyzed oxidation of hydrazine is suggested.     

Kinetics of oxidation of nitrosodisulfonate anion radical with a metallo-superoxide

The metal bound superoxide in μ-superoxo-bis[pentaamminecobalt(III)](5+) (1) oxidizes the nitrosodisulfonate anion radical (NDS(2-)) by two electrons. Oxidized NDS(2-) quickly decomposes to SO(4)(2-) and NO. 1 is itself reduced to the corresponding hydroperoxo complex which also decomposes fast to Co(ii), NH(4)(+) ions and oxygen. 1.5 moles of volatile products formed per mole of 1 mixed with excess NDS(2-). In the absence of superoxide in a bridged complex, e.g. the μ-amido-bis[pentaamminecobalt(III)](5+) complex fails to oxidize the nitroxyl radicals, NDS(2-), TEMPO and 4-oxo TEMPO. With excess NDS(2-) over 1, the reaction is first-order with respect to [1], [NDS(2-)] and inverse first order in [H(+)]. The activation entropy, ΔS(≠), is largely negative, increased ionic strength decreased the rate and a Br?nsted plot is fairly linear with a negative slope. Oxidant μ-superoxo-bis[(ethylenediamine)(diethylenetriamine)cobalt(III)](5+) has ligands sterically more crowded though more basic than ammonia in 1. It oxidizes NDS(2-) much more slowly. No solvent kinetic isotope effect (k(H(2)O/D(2)O)≈ 1) could be seen; a spin-adduct formation by the conjugate base of 1 followed by electron transfer is postulated.     

Tris(salicylhydroxamato)manganese(III)

Summary Hydroxamic acids show a degree of selectivity towards transition metal ions having symmetrical d-electron configuration, e.g. vanadium(V) (d⁰) and iron(III) (d⁶⁵). Hydroxamato complexes of metal ions having unsymmetrical d-electron distribution are rare. Thus for manganese(III) (d⁴) only some thiohydroxamato complexes⁽¹⁾ have been characterised so far. In this communication we report on the first synthesis of a salicylhydroxamato complex of manganese(III). Such investigations are of interest because these higher valent manganese complexes are potentially models for the water-splitting complex present in photosystem II⁽²).     

Kinetics of oxidation of hydrogen peroxide by [Mn3 IV(μ-O)4(phen)4(H2O)2]4+ (phen = 1,10-phenanthroline) in weakly acidic aqueous media

In the 3.33–4.95 pH range, buffered with an excess of phenanthroline (phen), [Mn ₃ ^IV (-O)₄(phen)₄(H₂O)₂]⁴⁺ (1) quantitatively oxidises H₂O₂ to O₂; the only manganese product is [Mn ₂ ^III,IV (-O)₂(phen)₄]³⁺ (2), provided a large excess of H₂O₂ is avoided; an excess of H₂O₂ [ > 7 × (1)] reduces (1) to Mn²⁺. When (1) and H₂O₂ were mixed in the stoichiometric molar proportion (1:0.75), the measured second-order rate constant for the reduction of (1) to (2) increased with increasing [H⁺], tending to saturate at lower pH. Added phenanthroline did not affect the rate constant. The results suggest an inner-sphere mechanism, ca. 10 times higher kinetic activity for (1) than for its hydroxo derivative [Mn ₃ ^IV (-O)₄(phen)₄(OH)(H₂O)]³⁺ (1h), and a hydrolysis constant K _a = (2.9 ± 1) × 10^–4 mol dm^–3 for (1) (1h) + H⁺.     

Decomposition kinetics ofbis(biguanide)silver(III) cation in acid perchlorate media

Summary In acid perchlorate media, the title complex undergoes intramolecular redox decomposition generating ultimately Ag⁺ ion and oxidation products of the ligand. The reaction follows a simple first-order process, and the observed pseudo-first-order rate constant is given by k_obs=k₀+kK_a/[H⁺] where K_a is the deprotonation constant of the parent complex; pK_a is approximately 5.9 at 30°. The values of 10⁵ k₀(s^–1) and 10⁷ kK_a (Ms^–1) at 30°, I=1.0 M, are 9.3±0.1 and 11.8±1.3; corresponding H (kJ/mol), S (JK^–1 M^–1) values are 105±0.5, 23±1 and 79±8,-96±5, respectively. The results are compared with those for similar reaction of (ethylenebisbiguanide)silver(III) and effect of change in ligand structure on kinetic behaviours of these complexes is discussed.     

Mechanistic Studies on the Oxidation of Hydrazine by Tris(biguanide)manganese(IV) in Aqueous Acidic Media

The title Mn^IV complex, [Mn(LH₂)₃]⁴⁺ (LH₂ = biguanide = H₂NC(NH)NHC(NH)NH₂), an authentic two‐electron oxidant, quantitatively oxidizes hydrazine (H₂NNH₂) to dinitrogen in the pH interval 2.00–3.50. The net four‐electron oxidation of hydrazine is provided by two Mn^IV as established by stoichiometric studies. The overall reaction is composed of two parallel paths:     

Kinetics of reactions of N1-phenylbiguanidine with CeIV and [MnO4]− in aqueous sulphuric acid media

Summary In the title reaction each mole of N¹-phenylbiguanidine, R–HNC(=X)NHC(=NH)NH₂ (R=Ph, X=NH), consumes 4 moles of Ce^IV and produces guanylurea (R=H, X=O), 1,4-benzoquinone and ammonia. On the other hand, the reaction of N¹-phenylbiguanidine (pbg) with [MnO₄]^– proceeds with variable stoicheiometry which depends on reaction conditions. In the case of [MnO₄]^– no benzoquinone is detected among the reaction products; instead, carbon dioxide, guanylurea, and ammonia were identified. Pbg itself in acid solution slowly hydrolyses to aniline which rapidly reacts with Ce^IV and [MnO₄]^–. The kinetics for the reactions of pbg with the oxidants is consistent with the rate law –d[oxidant]/dt=k[pbg].The k values and the corresponding activation enthalpies and entropies for the reaction of bpg with Ce^IV, [MnO₄]^–, and Cr^VI lie within a narrow range. These results are interpreted in terms of rate-determining hydrolysis of pbg in all the three cases.     

Kinetics and Mechanism of Oxidation of S2O32− by a Co‐Bound μ‐Amido‐μ‐Superoxo Complex

In acetate buffer media (pH 4.5–5.4) thiosulfate ion (S₂O₃^2?) reduces the bridged superoxo complex, [(NH₃)₄Co^III(μ‐NH₂,μ‐O₂)Co^III(NH₃)₄]⁴⁺ ( 1 ) to its corresponding μ‐peroxo product, [(NH₃)₄Co^III(μ‐NH₂,μ‐O₂)Co^III(NH₃)₄]³⁺ ( 2 ) and along a parallel reaction path, simultaneously S₂O₃^2? reacts with 1 to produce the substituted μ‐thiosulfato‐μ‐superoxo complex, [(NH₃)₄Co^III(μ‐S₂O₃,μ‐O₂)Co^III(NH₃)₄]³⁺ ( 3 ). The formation of μ‐thiosulfato‐μ‐superoxo complex ( 3 ) appears as a precipitate which on being subjected to FTIR shows absorption peaks that support the presence of Co(III)‐bound S‐coordinated S₂O₃^2? group. In reaction media, 3 readily dissolves to further react with S₂O₃^2? to produce μ‐thiosulfato‐μ‐peroxo product, [(NH₃)₄Co^III(μ‐S₂O₃,μ‐O₂)Co^III(NH₃)₄]²⁺ ( 4 ). The observed rate (k₀) increases with an increase in [T_Thio] ([T_Thio] is the analytical concentration of S₂O₃^2?) and temperature (T), but it decreases with an increase in [H⁺] and the ionic strength (I). Analysis of the log A_t versus time data (A is the absorbance of 1 at time t) reveals that overall the reaction follows a biphasic consecutive reaction path with rate constants k₁ and k₂ and the change of absorbance is equal to {a₁ exp(–k₁t) + a₂ exp(–k₂t)}, where k₁ > k₂.