Oxidation of Biogenic U(IV) in the Presence of Bioreduced Clay Minerals and Organic Ligands

Abstract: Bioreduction of soluble U(VI) to sparingly soluble U(IV) is proposed as an effective approach to remediating uranium contamination. However, the stability of biogenic U(IV) in natural environments remains unclear. We conducted U(IV) reoxidation experiments following U(VI) bioreduction in the presence of ubiquitous clay minerals and organic ligands. Bioreduced Fe-rich nontronite (rNAu-2) and Fe-poor montmorillonite (rSWy-2) enhanced U(IV) oxidation through shuttling electrons between oxygen and U(IV). Ethylened… Show more

“…Uranium (U) present in wastewaters produced via its mining, processing, and use in the nuclear fuel cycle is a significant environmental concern , with a range of potential ecotoxicological effects identified. , This includes the presence of U in the remediation of contaminated solutes produced during various processes associated with the nuclear fuel cycle, including U-mining, effluents from spent nuclear fuel reprocessing, nuclear fuel storage facilities, , U enrichment sites that are subject to decommissioning, , or cleanup procedures following the nuclear accidents. , To address these challenges, and especially when other radionuclides including transuranics such as plutonium and americium isotopes, and fission products including 90 Sr and 137 Cs may also be present, several studies have investigated U capture using various materials − including layered double hydroxides (LDHs) formed in situ − or prefabricated LDHs as adsorbents. ,− …”

Interaction between Uranyl Cations and Layered Double Hydroxide Nanoparticles: Implications for Nuclear Wastewater Management

“…Uranium (U) present in wastewaters produced via its mining, processing, and use in the nuclear fuel cycle is a significant environmental concern , with a range of potential ecotoxicological effects identified. , This includes the presence of U in the remediation of contaminated solutes produced during various processes associated with the nuclear fuel cycle, including U-mining, effluents from spent nuclear fuel reprocessing, nuclear fuel storage facilities, , U enrichment sites that are subject to decommissioning, , or cleanup procedures following the nuclear accidents. , To address these challenges, and especially when other radionuclides including transuranics such as plutonium and americium isotopes, and fission products including 90 Sr and 137 Cs may also be present, several studies have investigated U capture using various materials − including layered double hydroxides (LDHs) formed in situ − or prefabricated LDHs as adsorbents. ,− …”

Interaction between Uranyl Cations and Layered Double Hydroxide Nanoparticles: Implications for Nuclear Wastewater Management