Thermodynamic and Kinetic Studies on the Iron(III)-Hydroxamate Interaction in Acid Media

Abstract

Thermodynamics and kinetics of 1:1 complexation of iron(III) with benzo- and several ortho-substituted (CH₃, NH₂, Cl and OH) benzohydroxamic acids (HL) forming FeL²⁺ have been investigated spectropho-tometrically in aqueous perchloric acid solution. Under the experimental conditions ([H⁺] « T_Fc « T_HL) complexation involves reactions of HL with Fe³⁺ (k₁ path) and FeOH²⁺ (k₂ path) ions leading to an equilibrium. Both k₁ and k₂ have been evaluated by stopped-flow spectrophotometry following the formation of FeL²⁺ and the dissociation of FeL²⁺ in acid solution. The AH* value (42.5 ± 4.8 Hmol^-1) for the k₂ path is close to that for the water exchange of FeOH²⁺ species, suggesting essentially a dissociative (I_d) process, but that (54.5 + 3.8 kJmol^-1) corresponding to the k₁ path is perceptibly lower than that for the water exchange of Fe³⁺ species indicating associative (I_a) character. The reverse rate constants (k_-1 and k_{_2}) for the dissociation of the complexes by the two paths have also been evaluated from experimental values of k₁, k₂, and equilibrium constants (Q) for formation of FeL²⁺ from Fe³⁺ and HL, and the hydrolysis constant (K_h) of the Fe³⁺ ion. There is good agreement for Q values determined by equilibrium and kinetic experiments. Q follows an increasing value of k₁ and a decreasing order of k_-1 and thus both contribute favourably to the stability of the complex. Formation of a 1:1:1 ternary complex Fe(Nta)L^- in the reaction of Fe(Nta) with benzohydroxamic acid (HL) has also been studied. Results indicate that Nta^3- considerably destabilizes the iron(III)-hydroxamate interaction which is due to a considerable increase in the dissociation rate by a factor of ca 5 × 10³, whereas the formation rate is enhanced by a factor of only ca 4 at 25[ddot]C. Thus the strong sigma donor Nta^3- labilizes the strong sigma donor hydroxamate more than H₂O bound to iron(III).