Pentavalent U Reactivity Impacts U Isotopic Fractionation during Reduction by Magnetite

Environ Sci Technol. 2024 Apr 16;58(15):6595-6604. doi: 10.1021/acs.est.3c10324. Epub 2024 Apr 4.

Abstract

Meaningful interpretation of U isotope measurements relies on unraveling the impact of reduction mechanisms on the isotopic fractionation. Here, the isotope fractionation of hexavalent U [U(VI)] was investigated during its reductive mineralization by magnetite to intermediate pentavalent U [U(V)] and ultimately tetravalent U [U(IV)]. As the reaction proceeded, the remaining aqueous phase U [containing U(VI) and U(V)] systematically carried light isotopes, whereas in the bicarbonate-extracted solution [containing U(VI) and U(V)], the δ238U values varied, especially when C/C0 approached 0. This variation was interpreted as reflecting the variable relative contribution of unreduced U(VI) (δ238U < 0‰) and bicarbonate-extractable U(V) (δ238U > 0‰). The solid remaining after bicarbonate extraction included unextractable U(V) and U(IV), for which the δ238U values consistently followed the same trend that started at 0.3-0.5‰ and decreased to ∼0‰. The impact of PIPES buffer on isotopic fractionation was attributed to the variable abundance of U(V) in the aqueous phase. A few extremely heavy bicarbonate-extracted δ238U values were due to mass-dependent fractionation resulting from several hypothesized mechanisms. The results suggest the preferential accumulation of the heavy isotope in the reduced species and the significant influence of U(V) on the overall isotopic fractionation, providing insight into the U isotope fractionation behavior during its abiotic reduction process.

Keywords: isotope fractionation; pentavalent uranium; redox tracer; uranium remediation.

MeSH terms

  • Bicarbonates
  • Chemical Fractionation
  • Ferrosoferric Oxide*
  • Isotopes
  • Uranium*

Substances

  • Ferrosoferric Oxide
  • Uranium
  • Bicarbonates
  • Isotopes