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Poster De Conférence Année : 2021

Antimony isotopic fractionation in the environment: first insights from theoretical and experimental investigations

Eléonore Resongles
Corinne Casiot
R. Freydier

Résumé

Antimony is a toxic metalloid commonly found at high concentrations in sulfide mining environments. Yet its environmental cycling is largely unknown. Antimony stable isotopes (121Sb and 123Sb) are promising geochemical tracers. However, very little is known about Sb isotopic fractionation occurring during key geochemical processes controlling the mobility of Sb in surface environments (e.g. redox reactions, adsorption...), thus hampering a proper interpretation of Sb isotopic signatures measured in the environment. In this contribution, we present preliminary results obtained from complementary theoretical and experimental approaches carried out to characterize mass-dependent Sb isotopic fractionation associated with some of these processes. On one hand, first-principle calculations based on density functional theory (DFT) were carried out to estimate equilibrium fractionation factors between antimony minerals representative of Sb primary ore and secondary phases commonly found in mining-impacted environments (i.e. stibnite, valentinite, cervantite). Modeling was performed using Quantum Espresso software to calculate mineral lattices parameters, vibrational frequencies and isotopic fractionation factors. Computed data were compared with published experimental data (structural data, Raman spectroscopy) to ensure the validity of the method. The results predicted that cervantite (SbIIISbVO4) and valentinite (Sb2O3) were isotopically heavier compared to stibnite (Sb2S3) by ~1.6 and ~1.0‰ at 20 °C, respectively, showing the influence of Sb ligand (Sb-O vs Sb-S bond) and Sb redox state (SbV vs SbIII) on Sb isotopic variations. On the other hand, Sb isotopic fractionation was experimentally determined during adsorption of SbV onto an iron oxyhydroxide (ferrihydrite) which represents an important process limiting Sb mobility in surface waters. Adsorption onto synthetic ferrihydrite was carried out at different pH and Sb:ferrihydrite ratios at 20 °C. Isotopic composition (δ123Sb) was determined in the dissolved and solid phases by HG-MC-ICP-MS [1]. Antimony light isotope was preferentially adsorbed onto ferrihydrite, leaving the solution isotopically heavier (Δ123Sbsolution-solid = 0.35 ± 0.08‰). The data can be explained by a closed-system model, suggesting that fractionation resulted from an equilibrium exchange between dissolved and adsorbed Sb. These results provide a preliminary basis to interpret isotopic variations observed during the transport of Sb from its primary sources to contaminated environments. [5] Ferrari et al. (2021). JAAS, in press.
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Dates et versions

hal-03404634 , version 1 (26-10-2021)

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  • HAL Id : hal-03404634 , version 1

Citer

Colin Ferrari, Eléonore Resongles, Corinne Casiot, R. Freydier, Merlin Méheut. Antimony isotopic fractionation in the environment: first insights from theoretical and experimental investigations. Goldschmidt2021, Jul 2021, Online, France. . ⟨hal-03404634⟩
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