Redox Potentials of Magnetite Suspensions under Reducing Conditions.
Thomas C RobinsonDrew E LattaJohna LeddyMichelle M SchererPublished in: Environmental science & technology (2022)
Predicting the redox behavior of magnetite in reducing soils and sediments is challenging because there is neither agreement among measured potentials nor consensus on which Fe(III) | Fe(II) equilibria are most relevant. Here, we measured open-circuit potentials of stoichiometric magnetite equilibrated over a range of solution conditions. Notably, electron transfer mediators were not necessary to reach equilibrium. For conditions where ferrous hydroxide precipitation was limited, Nernstian behavior was observed with an E H vs pH slope of -179 ± 4 mV and an E H vs Fe(II) aq slope of -54 ± 4 mV. Our estimated E H o of 857 ± 8 mV closely matches a maghemite|aqueous Fe(II) E H o of 855 mV, suggesting that it plays a dominant role in poising the solution potential and that it's theoretical Nernst equation of E H [mV] = 855 - 177 pH - 59 log [Fe 2+ ] may be useful in predicting magnetite redox behavior under these conditions. At higher pH values and without added Fe(II), a distinct shift in potentials was observed, indicating that the dominant Fe(III)|Fe(II) couple(s) poising the potential changed. Our findings, coupled with previous Mössbauer spectroscopy and kinetic data, provide compelling evidence that the maghemite/Fe(II) aq couple accurately predicts the redox behavior of stoichiometric magnetite suspensions in the presence of aqueous Fe(II) between pH values of 6.5 and 8.5.