Research Centre for Radwaste Disposal and Williamson Research Centre for Molecular Environmental Science, Department of Earth, Atmospheric and Environmental Sciences, The University of Manchester, Manchester M13 9PL, U.K.
CENBG-Équipe Radioactivité et Environnement, UMR 5797, CNRS-IN2P3/Université de Bordeaux, 19 chemin du Solarium, CS 10120, 33175 Gradignan, France.
Environ Sci Technol. 2021 Dec 7;55(23):15862-15872. doi: 10.1021/acs.est.1c04416. Epub 2021 Nov 26.
Tc will be present in significant quantities in radioactive wastes including intermediate-level waste (ILW). The internationally favored concept for disposing of higher activity radioactive wastes including ILW is via deep geological disposal in an underground engineered facility located ∼200-1000 m deep. Typically, in the deep geological disposal environment, the subsurface will be saturated, cement will be used extensively as an engineering material, and iron will be ubiquitous. This means that understanding Tc biogeochemistry in high pH, cementitious environments is important to underpin safety case development. Here, alkaline sediment microcosms (pH 10) were incubated under anoxic conditions under "no added Fe(III)" and "with added Fe(III)" conditions (added as ferrihydrite) at three Tc concentrations (10, 10, and 10 mol L). In the 10 mol L Tc experiments with no added Fe(III), ∼35% Tc(VII) removal occurred during bioreduction. Solvent extraction of the residual solution phase indicated that ∼75% of Tc was present as Tc(IV), potentially as colloids. In both biologically active and sterile control experiments with added Fe(III), Fe(II) formed during bioreduction and >90% Tc was removed from the solution, most likely due to abiotic reduction mediated by Fe(II). X-ray absorption spectroscopy (XAS) showed that in bioreduced sediments, Tc was present as hydrous TcO-like phases, with some evidence for an Fe association. When reduced sediments with added Fe(III) were air oxidized, there was a significant loss of Fe(II) over 1 month (∼50%), yet this was coupled to only modest Tc remobilization (∼25%). Here, XAS analysis suggested that with air oxidation, partial incorporation of Tc(IV) into newly forming Fe oxyhydr(oxide) minerals may be occurring. These data suggest that in Fe-rich, alkaline environments, biologically mediated processes may limit Tc mobility.
锝将大量存在于放射性废物中,包括中低放废物(ILW)。目前,国际上普遍采用的处置高放射性废物(包括 ILW)的方法是在地下工程设施中进行深部地质处置,该设施位于地下 200-1000 米深处。通常,在深部地质处置环境中,地下将处于饱和状态,水泥将被广泛用作工程材料,而铁将无处不在。这意味着了解高 pH 值、水泥环境中的锝地球化学对于支持安全案例的发展非常重要。在这里,碱性沉积物微宇宙(pH 值 10)在缺氧条件下进行培养,条件为“无外加 Fe(III)”和“外加 Fe(III)”(作为水铁矿添加),三个锝浓度(10、10 和 10 摩尔 L)。在没有外加 Fe(III)的 10 摩尔 L Tc 实验中,生物还原过程中约有 35%的 Tc(VII)被去除。对残留溶液相的溶剂萃取表明,约 75%的 Tc 以 Tc(IV)的形式存在,可能以胶体形式存在。在添加 Fe(III)的生物活性和无菌对照实验中,生物还原过程中形成了 Fe(II),超过 90%的 Tc 从溶液中去除,这很可能是由于 Fe(II)介导的非生物还原。X 射线吸收光谱(XAS)表明,在生物还原沉积物中,Tc 以含水 TcO 样相存在,存在一些与 Fe 结合的证据。当添加 Fe(III)的还原沉积物被空气氧化时,在 1 个月内(约 50%)会有大量的 Fe(II)损失,但这与适度的 Tc 再移动(约 25%)相关。在这里,XAS 分析表明,随着空气氧化,部分 Tc(IV)可能会被掺入新形成的铁氧氢氧化物矿物中。这些数据表明,在富铁、碱性环境中,生物介导的过程可能会限制 Tc 的迁移性。
