Biogeochemical Cycling of Tc-99 in Alkaline Sediments

Williamson Adam J.; Lloyd Jonathan R.; Boothman ChristopherLaw Gareth T. W.Shaw SamuelSmall Joe S.Vettese Gianni F.Williams Heather A.Morris Katherine

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Biogeochemical Cycling of Tc-99 in Alkaline Sediments

机译：Biogeochemical Cycling of Tc-99 in Alkaline Sediments

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Tc-99 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 similar to 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(-11), 10(-6), and 10(-4) mol L-1). In the 10(-6) mol L-1 Tc experiments with no added Fe(III), similar to 35% Tc(VII) removal occurred during bioreduction. Solvent extraction of the residual solution phase indicated that similar to 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 TcO2-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 (similar to 50%), yet this was coupled to only modest Tc remobilization (similar to 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.

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《Environmental Science & Technology: ES&T》 |2021年第23期|15862-15872|共11页
作者
Williamson Adam J.; Lloyd Jonathan R.; Boothman ChristopherLaw Gareth T. W.Shaw SamuelSmall Joe S.Vettese Gianni F.Williams Heather A.Morris Katherine;
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作者单位

Univ Manchester;

Univ Helsinki;

Manchester Royal Infirm;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
原文格式 PDF
正文语种英语
中图分类环境科学、安全科学;
关键词
technetium; geological disposal; elevated pH; iron(II); bioreduction; reoxidation; incorporation; X-RAY-ABSORPTION; TECHNETIUM-CONTAMINATED GROUNDWATER; LONG-TERM IMMOBILIZATION; MICROBIAL REDUCTION; REOXIDATION BEHAVIOR; CONDITIONS RELEVANT; IRON; PERTECHNETATE; FE(II); BIOREMEDIATION;

Biogeochemical Cycling of Tc-99 in Alkaline Sediments

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