The Role of Redox Processes in Determining the Iron Isotope Compositions of Minerals, Melts, and Fluids

Abstract: Stable isotope fractionation is a response to the minimisation of free energy associated with differences in vibrational frequencies during substitution of isotopic masses between two phases. Site properties are dictated by the bonding environment of iron, and influence its 'force constant', a descriptor for bond strength. Because iron readily transitions between its ferrous (Fe 2+ ) and ferric (Fe 3+ ) state over the oxygen fugacities (fO 2 ) of terrestrial magmas, redox processes are presumed to control iron… Show more

“…for an oceanic island, comparable to those observed in Samoan rejuvenated lavas [3]. Previous modelling shows similar heavy δ 57 Fe signatures in mantle-derived melts cannot be explained solely by fractionation during partial melting from any common mantle source [4,5]. Instead, these high values require a source enriched in heavy Fe isotopes prior to melt generation.…”

Rejuvenated lavas resolve enriched ponded melt at the lithosphere-asthenosphere boundary

“…for an oceanic island, comparable to those observed in Samoan rejuvenated lavas [3]. Previous modelling shows similar heavy δ 57 Fe signatures in mantle-derived melts cannot be explained solely by fractionation during partial melting from any common mantle source [4,5]. Instead, these high values require a source enriched in heavy Fe isotopes prior to melt generation.…”

Rejuvenated lavas resolve enriched ponded melt at the lithosphere-asthenosphere boundary

Application of isotope dilution and double spiking in geochemistry

Reduction of iron with no systematic isotope fractionation during continental subduction observed in metamorphic rocks from the Dabie-Sulu orogen, China