Journal
APPLIED SCIENCES-BASEL
Volume 11, Issue 6, Pages -Publisher
MDPI
DOI: 10.3390/app11062875
Keywords
sludge pond; aquifers; uranyl ion; bioremediation; 16S rRNA analysis; denitrification
Categories
Funding
- Russian Foundation for Basic Research [20-05-00602 A]
- Russian Science Foundation [18-77-10029]
- State Assignment of the Sobolev Institute of Geology and Mineralogy, Siberian Branch of the Russian Academy of Sciences
- Russian Science Foundation [18-77-10029] Funding Source: Russian Science Foundation
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This study reveals that nitrate influences the redox conditions in groundwater, impacting the behavior of uranium, and highlights the need to assess the long-term stability of uranium in environments related to radioactive sludge storage facilities.
Nitrate is a substance which influences the prevailing redox conditions in groundwater, and in turn the behaviour of U. The study of groundwater in an area with low-level radioactive sludge storage facilities has shown their contamination with sulphate and nitrate anions, uranium, and some associated metals. The uranyl ion content in the most contaminated NO3-Cl-SO4-Na borehole is 2000 times higher (1.58 mg/L) than that in the background water. At the same time, assessment of the main physiological groups of microorganisms showed a maximum number of denitrifying and sulphate-reducing bacteria (e.g., Sulfurimonas) in the water from the same borehole. Biogenic factors of radionuclide immobilization on sandy rocks of upper aquifers have been experimentally investigated. Different reduction rates of NO3-, SO42-, Fe(III) and U(VI) with stimulated microbial activity were dependent on the pollution degree. Moreover, 16S rRNA gene analysis of the microbial community after whey addition revealed a significant decrease in microbial diversity and the activation of nonspecific nitrate-reducing bacteria (genera Rhodococcus and Rhodobacter). The second influential factor can be identified as the formation of microbial biofilms on the sandy loam samples, which has a positive effect on U sorption (an increase in Kd value is up to 35%). As PHREEQC physicochemical modelling numerically confirmed, the third most influential factor that drives U mobility is the biogenic-mediated formation of a sulphide redox buffer. This study brings important information, which helps to assess the long-term stability of U in the environment of radioactive sludge storage facilities.
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