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Proton-Assisted Air Oxidation Mechanisms of Iron(II) bis-Thiosemicarbazone Complexes at Physiological pH: a Kinetico-Mechanistic Study

Abstract

The kinetics of oxidation for different biologically-active FeII bis-thiosemicarbazone complexes in water has been monitored at varying dioxygen concentration, temperature, pressure, and pH. The oxidation reactions observed can be resolved as a single-step process, producing the expected ferric complex, with rates increasing with decreasing pH. From the pH-dependence of the observed rate constants, a rate law with two terms can be derived, one of them being independent of the acid concentration and the other one showing a saturation behaviour with respect to [H+]. Those results indicate the existence of two parallel pathways for oxidation: the acid-independent pathway is only operative for the complexes with ligands bearing terminal, non-coordinated, unsubstituted amines, whereas the term with a [H+]-limiting kinetic behaviour is observed for all the complexes and indicates that the reacting species has to be protonated prior to the oxidation step. From the data collected, the rate law and the thermal and pressure activation parameters have been used to interpret the operating reaction mechanisms. Given the fact that the empirical trends rule out an outer-sphere oxidation process, DFT calculations have been carried out to explain the results and suggest the likely formation, under steady-state very low concentration conditions, of FeIII superoxo and hydroperoxo intermediates.

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Publication details

The article was received on 03 Sep 2019, accepted on 11 Oct 2019 and first published on 11 Oct 2019


Article type: Paper
DOI: 10.1039/C9DT03557E
Dalton Trans., 2019, Accepted Manuscript

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    Proton-Assisted Air Oxidation Mechanisms of Iron(II) bis-Thiosemicarbazone Complexes at Physiological pH: a Kinetico-Mechanistic Study

    M. Gonzálvez Noguera, A. G. Algarra, M. G. Basallote, P. V. Bernhardt, M. J. Fernández-Trujillo and M. Martinez, Dalton Trans., 2019, Accepted Manuscript , DOI: 10.1039/C9DT03557E

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