eCLAY: Redox reactivity of iron-bearing clay minerals

Iron is the most abundant redox-active element in the Earth’s crust and the Fe(II)/Fe(III) redox couple plays a key role in biogeochemical cycles and pollutant dynamics. While the reactivity of iron in iron oxides and its implications for subsurface redox processes have been studied extensively, little is known on the contributions of reactive iron in clay minerals to the toxicity, mobility, and persistence of contaminants. Despite the importance of iron redox processes of clay minerals, few studies have characterized iron-bearing minerals with respect to redox properties thus compromising a general assessment of the availability and reactivity of structural iron in clays. Here, we propose a comprehensive approach that aims at quantifying the thermodynamic parameters as well as the redox capacities and kinetics of iron oxidation and reduction in a broad set of clay minerals. Our experimental setup makes use of novel electrochemical techniques for the mediated electrochemical reduction and oxidation using soluble radical redox mediators to facilitate electron transfer between the structural iron in a clay mineral and an electrode. Using Mössbauer spectroscopy, we will explore the binding and structural arrangement of iron in the clay lattice that gives rise to the electrochemically determined redox properties. Finally, these insights will be applied to establish an understanding of how the electrochemical properties of the characterized iron-bearing clay minerals determine their reactivity in the environment with electron transfer shuttles of biogeochemical relevance and important organic soil and groundwater contaminants.

Partners

• Michael Sander (ETHZ / IBP)
• Michelle Scherer (University of Iowa)