Microbiology of formation waters from the deep repository of liquid radioactive wastes Severnyi

Назина, Т. Н.; Kosareva, I. M.; Petrunyaka, Vladimir V.; Savushkina, M. K.; Kudriavtsev, E.; Lebedev, V. A.; Ahunov, Viktor D.; Revenko, Yuriy A.; Khafizov, R. R.; Осипов, Г. А.; Belyaev, S. S.; Ivanov, Mikhail

doi:10.1016/j.femsec.2004.02.017

Cited by 30 publications

(18 citation statements)

References 44 publications

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“…Not surprisingly, the contamination often resulted in an apparent enrichment for microbes that could degrade or otherwise utilize the contaminants (e.g., Lowe et al 2002;de Lipthay et al 2003), or microbes that were comparatively resistant to highly toxic contaminants (e.g., Fredrickson et al 2004;Reardon et al 2004). Contamination has also been associated with increased cultivatability (de Lipthay et al 2003) or metabolic activity (Nazina et al 2004) of microbes within the contaminant plume. In contrast, some types of contaminants appeared to have little or no affect on subsurface • Viable bacterial numbers low (∼10 4 CFU g 2 ) but cultures recovered from 11 of 16 samples, including most radioactive (e.g., >10 µCi of 137 Cs/g) • Isolates/clones from contaminated sediments dominated by Gram-positive species; Arthrobacter most common but other high-G+C phyla present • Two isolates related to Deinococcus radiodurans able to survive doses of ionizing radiation up to 20 kGy; many Gram-positive isolates resistant to lower levels of gamma radiation Vadose-zone, nutrient-poor glacial melt water sand; influence of petroleum hydrocarbon vapors on microbial community structure…”

Section: Microbial Diversity and Community Structurementioning

confidence: 99%

Geomicrobial Processes and Biodiversity in the Deep Terrestrial Subsurface

Fredrickson

Balkwill

2006

Geomicrobiology Journal

119

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The concept of a deep microbial biosphere has advanced over the past several decades from a hypothesis viewed with considerable skepticism to being widely accepted. Phylogenetically diverse prokaryotes have been cultured from or detected via characterization of directly-extracted nucleic acids from a wide range of deep terrestrial environments. Recent advances have linked the metabolic potential of these microorganisms, determined directly or inferred from phylogeny, to biogeochemical reactions determined via geochemical measurements and modeling. Buried organic matter or kerogen is an important source of energy for sustaining anaerobic heterotrophic microbial communities in deep sediments and sedimentary rock although rates of respiration are among the slowest rates measured on the planet. In contrast, Subsurface Lithoautotrophic Microbial Ecosystems based on H 2 as the primary energy source appear to dominate in many crystalline rock environments. These photosynthesis-independent ecosystems remain an enigma due to the difficulty in accessing and characterizing appropriate samples. Deep mines and dedicated rock laboratories, however, may offer unprecedented opportunities for investigating subsurface microbial communities and their interactions with the geosphere.

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Section: Microbial Diversity and Community Structurementioning

confidence: 99%

Geomicrobial Processes and Biodiversity in the Deep Terrestrial Subsurface

Fredrickson

Balkwill

2006

Geomicrobiology Journal

119

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“…In deep levels in Hungary (198-229 m), which are to be used for waste disposal [14], the population of aerobic microorganisms does not exceed 10 2 and anaerobic organisms 10 4 per 1 cm 3 . Close values were also found in waters in the deep liquid-wastes repository at the Severnyi site [6,7]. Investigations [6,7,12,13]have shown that microorganisms living in underground formations are capable of forming gasesmethane, carbon dioxide, hydrogen, hydrogen sulfide, nitrogen, and others -from possible macrocomponents of the liquid wastes.…”

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confidence: 82%

“…Constant geological and hydrogeological monitoring (measurement of the temperature, pressure, piezolevels, and so forth) in injection and observation wells is performed on these sites, and the composition of the gases released from the injection wells is also analyzed [5]. In recent years, serious attention has been devoted to investigating the microflora in underground levels used for burying liquid wastes [6,7]. The main objects of investigation were samples of formation water from observational wells in the second level (Fig.…”

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confidence: 99%

“…The population of microorganisms was determined on elective nutrient media [7]. The distribution of the population of microorganisms in the samples of formation liquids studied is presented in Table 3.…”

mentioning

confidence: 99%

“…The rate of sulfate reduction and methane generation was measured in 2001-2004 in 11 samples of formation waters using tagged compounds (Na 2 35 SO 4 , NaH 14 CO 3 , and 14 CH 3 -COONa) [7]. The rate of both processes is extremely low (see Table 4).…”

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Physicochemical and biological monitoring of deep repositories for liquid radioactive wastes

et al. 2007

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The objective of this work was to study the physicochemical conditions and the microbiological composition of underground water in the second level of the Severnyi site at the Mining and Chemical Works and to clarify the possibility of biogenic gas production by formation microflora from macrocomponents of the wastes (nitrates and sulfate ions). Chemical analysis of samples of formation liquid from wells located in the dispersion zone of the wastes showed an increase in the content of dissolved carbonic acid, sodium nitrate, and nitrates of radionuclides and an increase of their concentrations in the sampling part. In all other samples, the contents of the main cations and anions were close to the background values. Microbiological investigations showed an increase in the number of microorganisms capable of forming gases from possible macrocomponents of the wastes and in the rate of sulfate reduction and methane generation processes within the propagation boundary of the wastes.One method of final removal of low-and medium-level wastes from the human environment is burial of the wastes in deep (200-500 m) water-bearing levels, isolated from lower and upper layers by clay interlayers which are impermeable to water. This method was first used in 1963, and more than 50·10 6 m 3 of liquid wastes with initial activity exceeding 4 billion Ci are now localized in deep repository formations [1]. Since the wastes removed contained, aside from radionuclides, inactive macrocomponents, deep repositories now contain a substantial quantity of toxic compounds -nitrates, acetates, and sulfates of alkali metals, iron, nickel, chromium, and so forth, which can contaminate underground and, possibly, surface ecosystems.Radioactive and inactive components of wastes in deep repositories interact with formation minerals and formation liquid and are heated by radiation-chemical and microbiological activity. The contribution of each of these processes depends on, first and foremost, the activity of the wastes. The action of medium-and high-level wastes on the formation and on the components of the wastes is determined by the energy released as result of the natural decay of the radionuclides. The ionizing radiation generated in the process and absorbed in the rock and formation liquid, containing macrocomponents, increases the temperature of the formation on the one hand and intensifies the purely chemical interaction of components with the

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