AI Article Synopsis
- Atomistic simulations were used to explore how uranium (U) interacts within three types of iron-rich minerals: goethite, magnetite, and hematite, focusing on the distances and coordination related to U's incorporation.
- In goethite, adjustments in the mineral's structure allowed U to substitute iron (Fe) with minimal distortion, while U in unoccupied sites caused more significant changes regardless of its oxidation state.
- The findings indicate that U is structurally incorporated into these minerals rather than just adsorbing to their surfaces, bolstering previous experimental results.
Article Abstract
Atomistic simulations were carried out to characterize the coordination environments of U incorporated in three Fe-(hydr)oxide minerals: goethite, magnetite, and hematite. The simulations provided information on U-O and U-Fe distances, coordination numbers, and lattice distortion for U incorporated in different sites (e.g., unoccupied versus occupied sites, octahedral versus tetrahedral) as a function of the oxidation state of U and charge compensation mechanisms (i.e., deprotonation, vacancy formation, or reduction of Fe(III) to Fe(II)). For goethite, deprotonation of first shell hydroxyls enables substitution of U for Fe(III) with a minimal amount of lattice distortion, whereas substitution in unoccupied octahedral sites induced appreciable distortion to 7-fold coordination regardless of U oxidation states and charge compensation mechanisms. Importantly, U-Fe distances of ∼3.6 Å were associated with structural incorporation of U and cannot be considered diagnostic of simple adsorption to goethite surfaces. For magnetite, the octahedral site accommodates U(V) or U(VI) with little lattice distortion. U substituted for Fe(III) in hematite maintained octahedral coordination in most cases. In general, comparison of the simulations with available experimental data provides further evidence for the structural incorporation of U in iron (hydr)oxide minerals.
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| http://dx.doi.org/10.1021/es1037639 | DOI Listing |
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