Oak Ridge Associated Universities, U.S. Environmental Protection Agency, Office of Research and Development, National Risk Management Research Laboratory, Groundwater, Watershed, and Ecosystem Restoration Division, Ada, OK, 74820, United States.
U.S. Environmental Protection Agency, Office of Research and Development, National Risk Management Research Laboratory, Groundwater, Watershed, and Ecosystem Restoration Division, Ada, OK, 74820, United States.
J Hazard Mater. 2019 Sep 5;377:315-320. doi: 10.1016/j.jhazmat.2019.05.101. Epub 2019 May 30.
Understanding the factors that govern aqueous solubility of uranyl minerals is important for predicting uranium mobility in groundwater and for designing effective remediation strategies. The uranyl-containing minerals metaschoepite [UO∙(2HO)] and uranophane [Ca(UO)(SiOOH)·5HO] were synthesized and evaluated in batch solubility experiments conducted in the presence of common groundwater ions: calcium, bicarbonate/carbonate, and dissolved silica. Solid-phase characterization revealed the expected structural and thermogravimetric properties of metaschoepite and uranophane. Metaschoepite solubility in carbonate-free water followed a u-shaped pH dependency with minimum solubility near pH 8.5; uranium concentrations at pH ≳ 8.5 were approximately equivalent to the reference value for safe drinking water established by the EPA (30 μg/L). With increasing bicarbonate/carbonate concentration (1 mM - 50 mM) the solubility of metaschoepite increased, presumably due to the formation of uranyl-carbonate complexes. However, the experimental concentrations of uranium were lower than concentrations predicted from accepted complexation constants. For uranophane, equilibrium uranium concentrations were < 75 μg/L at typical groundwater concentrations of calcium and dissolved silica (pH > 7). The diversity of uranyl minerals that possibly form in the presence of common groundwater species: Ca-Mg-Na-K-Si-bicarbonate/carbonate-sulfate-chloride, has not been fully explored with respect to understanding potential mineral transformations and impacts on uranium solubility and mobility.
了解控制铀矿物水溶解度的因素对于预测地下水铀的迁移性以及设计有效的修复策略非常重要。含铀矿物水硅钙铀矿 [(UO)·(2HO)] 和钙铀云母 [Ca(UO)(SiOOH)·5HO] 被合成并在存在常见地下水离子的批处理溶解度实验中进行了评估:钙、碳酸氢盐/碳酸盐和溶解的硅。固相特性研究表明水硅钙铀矿和钙铀云母具有预期的结构和热重特性。在无碳酸盐的水中,水硅钙铀矿的溶解度随 pH 值呈 U 形依赖性变化,最小溶解度在 pH 8.5 附近;在 pH ≳ 8.5 时,铀浓度与 EPA 确定的安全饮用水参考值(30μg/L)大致相当。随着碳酸氢盐/碳酸盐浓度(1mM-50mM)的增加,水硅钙铀矿的溶解度增加,这可能是由于形成了铀碳酸盐配合物。然而,实验中铀的浓度低于从公认的络合常数预测的浓度。对于钙铀云母,在典型的地下水钙和溶解硅浓度(pH > 7)下,平衡铀浓度 < 75μg/L。对于可能在常见地下水物种存在下形成的铀矿物的多样性:Ca-Mg-Na-K-Si-碳酸氢盐/碳酸盐-硫酸盐-氯化物,尚未充分探讨其对潜在矿物转化以及对铀溶解度和迁移性的影响。