缺氧水域
碳酸盐
铀
化学
环境化学
溶解
碳酸氢盐
遗传算法
水溶液
氧化还原
孵化
无机化学
生态学
有机化学
冶金
材料科学
物理化学
生物
生物化学
作者
Marina Seder-Colomina,Arnaud Mangeret,Lucie Stetten,Pauline Merrot,Olivier Diez,Anthony Julien,Evelyne Barker,Antoine Thouvenot,John Bargar,Charlotte Cazala,Guillaume Morin
标识
DOI:10.1021/acs.est.8b01255
摘要
Sorbed U(IV) species can be major products of U(VI) reduction in natural reducing environments as sediments and waterlogged soils. These species are considered more labile than crystalline U(IV) minerals, which could potentially influence uranium migration in natural systems subjected to redox oscillations. In this study, we examined the role of oxygen and carbonate on the remobilization of uranium from lake sediments, in which ∼70% of the 150-300 ppm U is under the form of mononuclear U(IV) sorbed species. Our results show that both drying and oxic incubation only slightly increase the amount of remobilized U after 8 days, compared to anoxic drying and anoxic incubation. In contrast, the amount of remobilized U increases with the quantity of added bicarbonate even under anoxic conditions. Moreover, U LIII-edge XANES data show that a significant amount of the solid U(IV) is mobilized in such conditions. Thermodynamic speciation calculations based on the supernatant composition indicates the predominance of aqueous UO2(CO3)34- and, to a lesser extent, CaUO2(CO3)32- complexes. These results suggest that monomeric U(IV) species could be oxidized into aqueous U(VI) carbonate complexes even under anoxic conditions via carbonate promoted oxidative dissolution, which emphasizes the need for considering such a process when modeling U dynamics in reducing environments.
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