Study of the microbial communities of core and water samples in a chloroethenes contaminated aquifer

Guillaume Laulan
2009
Projet étudiant

Résumé

Widely used in industrial activities, chloroethenes have become common groundwater contaminants. Dehalorespiration is an anaerobic bacterial respiration coupling their sequential degradation to energy production. The interactions between the dehalorespiring bacteria and the other guilds and environmental variables are presumed to influence the dehalorespiration efficiency. Here, water and core samples were extracted from the PCE-contaminated site of Lyss (BE, Switzerland). Bacterial DNA was extracted and the 16S rRNA gene amplified by PCR. Terminal restriction fragment length polymorphism (T-RFLP) was used to assess the diversity of the bacterial communities. Core and groundwater environmental variables were analyzed as well. The T-RFLP profiles and the environmental data obtained were processed using statistical multivariate analysis. Within a period of two months, the bacterial communities remained relatively specific to their respective sampling origins. Communities from the oxic layer shared a similar set of bacterial species whereas piezometers from the anoxic layer had a specific one. The T-RFLP profiles obtained from single depth and multi-level piezometers were clearly distinct, probably due to differences in the pumping flow rates and their associated transport regimes, which can have an impact on i) the sediments extracted from the aquifer, ii) the hydraulic zone reached and iii) a potential selective bacterial adsorption onto the pumping tube wall. Environmental factors related to the groundwater redox state appeared as the major variables influencing the bacterial populations. Bacterial communities from core samples clustered into two distinct sets: i) samples from the strongly reductive silt layer, and ii) samples from the coarser and less reductive layer. Grain size distribution and redox state both had a major influence on the bacterial communities of core samples. Finally, it was shown that microbial populations extracted from groundwater differed from the ones extracted from core material, and thus were not representative of the overall aquifer microbial diversity.

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https://infoscience.epfl.ch/record/142890?ln=fr

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Guillaume Laulan
2009
Projet étudiant

Résumé

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https://infoscience.epfl.ch/record/142890?ln=fr

À propos de ce résultat

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Since their discovery around 1930, the synthetic compounds of the class of chlorofluorocarbons (CFCs) have been produced and used worldwide at very large scale. Their physico-chemical properties (non-flammability, chemical inertia, miscibility with water and oil, compatibility with many metals and plastics, solvent capacity) have made them ideal candidates for several applications, such as refrigerant fluids, aerosol propellants, foam blowing agents, or as solvents or intermediates of chemical synthesis. In the 70', it was demonstrated that following their release in the atmosphere, they are implicated in the process leading to the commonly called stratospheric ozone hole. The governments of several industrialised country have thus signed a protocol with the objective to stop the production and use of CFCs. CFCs have been increasingly replaced by compounds with similar structure, the hydrochlorofluorocarbons (HCFCs), but whose reactivity in the lower layers of the atmosphere is quite different from that of CFCs. Due to their chemical inertia, CFCs has been used as tracers for surface and groundwater datation. During such investigations, the biodegradability of these compounds and the existence of punctual pollution sources in soil and groundwater have been evidenced. It has been demonstrated that some of these compounds can be dechlorinated under anoxic conditions producing other compounds with sometimes higher toxicity and higher water solubility, and resulting in a risk linked to the consumption of natural groundwater. The goal of this thesis was to get indications about reductive transformations of CFCs and especially HCFCs in Swiss aquifers and landfills, on the potential of different microbial communities to reductively dechlorinate certain compounds, and under which redox conditions the transformations occur in aquifer systems. Data concerning the production, use, emission, regulation, as well as the biodegradability and toxicity of these compounds are presented in chapter 1 and in the appendix. The analytical methods developed and used during this work are presented in chapter 2. Particularly, a versatile analytical system allowing the measure of trace but also higher concentrations in different media, solid or aqueous, has been set up and used during this work. CFCs and HCFCs were analyzed at 3 sites in Switzerland. Samples were collected from a natural groundwater in which a chloroethene plume had been observed, from an old landfill closed in 1980, and from a more recent bioactive landfill constructed in horizontal layers. In addition, the behaviour of different CFCs and HCFCs was studied in microcosms inoculated with sludge originating from several sewage treatment plants in the canton of Vaud, and with a sediment originating from a contaminated aquifer in Holland. The studied CFCs and HCFCs were furthermore injected at the inlet of a 1.2 m height column filled with the aquifer sediment from Holland. In this quasi natural aquifer, the oxido-reductive conditions were modified during the experiment in order to investigate the conditions at which the biodegradation occurred. The field studies showed that CFCs and HCFCs are present in aquifers and landfills, and there were indications that their transformation also occurs there. Estimations of half-life times indicated that the reductive dechlorination occurred at slow rates. This could be due to the low temperatures of natural groundwater systems and other factors linked to the hydro-geological properties of the natural environment such as dispersion, sorption or partitionning. In the microcosms inoculated with sludge, CFC-11 was transformed to HCFC-21, the latter being further dechlorinated to HCFC-31. HCFC-123a and chlorotrifluoroethene (CTFE) were produced simultaneously from CFC-113. Inhibition of methanogesis with 2 bromoethane sulfonate decreased significantly the degradation rate of CFC-11, emphasizing the importance of the role of methanogens in the degradation process. In the microcosms inoculated with the contaminated sediment, the transformation of CFC-11 also occurred, but was not accompanied with methane production, as it was the case in the suldge microcosms. Moreover, the presence of acetate, lactate and butyrate in the microcosms containing CFC-11 suggested that methanogens were inhibited in the presence of CFC-11. CFC-113 was transformed in the same way as in the microcosms inoculated with the sludge; however, the produced CTFE was further transformed to trifluoroethene (TFE). Production of HCFC-151b from HCFC-141b was also observed. In the column filled with aquifer material, only the transformations of CFC-11 and CFC-113 were observed, which is probably due to the short residence time in the column (~10 days), during which the transformation of the other compounds was not sufficiently pronounced. The increasingly reducing conditions in the column were accompanied with an increase of the degradation rates of CFC-11 and CFC-113, with a maximum reached in presence of methanogenesis. The addition of sulfate in the artificial groundwater decreased the biodegradation rates of the two compounds, and the concentration of their transformation products was simultaneously increased. This suggests that these products become more persistent under sulfate-reducing conditions. Natural attenuation designates all the processes leading to the decrease of the concentration of organic compounds migrating from a pollution source throughout a natural environment. Whereas natural attenuation or enhanced natural attenuation seem adequate for several classes of compounds, the absence of defluorination reaction of CFCs and HCFCs reported in this work suggests the use of other remediation techniques for the decontamination of sites polluted with these compounds. Indeed, the transformation products of CFCs and HCFCs still contain a fluorine atom and are not less harmfull to the environment than the parent compounds. In addition, the use of CFCs as age-dating tracers in groundwater is not recommended under anoxic conditions, as it was demonstrated here that they are not stable in such environments. The HCFCs on the other hand seem to be more persistent, and it is primordial to decrease rapidly their production and release in the environment.

EPFL2004

Chargement

Typologie des eaux souterraines de la molasse entre Chambéry et Linz (France, Suisse, Allemagne, Autriche)

The geochemical typology of natural subsurface waters of the Molasse basin is part of the AQUITYP project, initiated by the Geology Laboratory (GEOLEP) of the Swiss Federal Institute of Technology in Lausanne (EPFL). This study provides an overview of the variation in space of the hydrochemical parameters, especially of trace elements, in order to determine the geological origin of their aquifers. Our data base is mainly made up of two observation networks: a subsurface water network and a deep groundwater network. Complete analyses of all samples have been executed using standard methods for anions and silicium, and high resolution inductively coupled mass spectrometry (HR-ICP-MS) for major cations and trace elements down to the detection limit of about 0.2 µg/l. Subsurface water network It is the main observation network of this investigation and comprises 112 water samples from different springs, collected all over the Molasse basin between Chambéry (France) and Linz (Austria), but mainly in the Swiss Molasse basin. For this region, four groups are generally distinguished, according to the sediment deposition in a continental or marine environment, in ascending stratigraphic order: (1) the Lower Marine Molasse (UMM and North Helvetic "flysch" p.p.), (2) the Lower Freshwater Molasse (USM), (3) the Upper Marine Molasse (OMM) and (4) the Upper Freshwater Molasse (OSM). Our water samples originate from typical sedimentary deposits which we divided in about 30 different sub-type aquifers according to their geological origin and their depositional environment. They are defined on the basis of lithological and structural homogeneity. Therefore, only catchments that completely drain a single, lithologically homogenous, Molasse terrain unit are considered here. Spring catchments selected were generally not affected by runoff from towns, or paved roads. Agricultural activities have been avoided as well as possible. Such spring water should be free of major human influences and only in few cases contain a certain amount of fertilizer products (p.ex: nitrates). Leachate tests of crushed rocks and comparison with snow and soil water compositions allowed to decipher the geogene origin of the dissolved ions in natural groundwaters. The water withdrawn can be generally classified as a calcium-magnesium-hydrogenocarbonate (Ca-Mg-HCO3)-type water. The trace analyses allowed to distinguish several subtypes within this homogenous water type group. The general spacial distribution of the trace elements show, that spring waters in the Bavarian Molasse basin are caracterized by elements as lithium and uranium linked to acid rocks, while those of the Swiss Molasse basin are preferentially influenced by elements derived from mafic or ultramafic rocks, such as chromium and cobalt. The following elements show specific links between aquifer rock type and groundwater. Sulfates: Total mineralisation of spring waters issued from the gypse-bearing Molasse (USM) and the "Glimmersande" (OSM) are highly influenced by high sulfate contents. It can be demonstrated that sulfate ions are produced from two different sources within this two sub-type aquifers: from the dissolution of gypsum in water, producing high calcium contents as well, and from the oxydation of sulfurous ore minerals, especially pyrite, which are abundant in the "Glimmersande". The "Glimmersand" aquifers in NE Switzerland are furtheron caracterized by high lithium, molybdenum and uranium concentrations, reflecting the granitic composition of this sandstones. High barium contents (>150 µg/l) have been found in spring waters issued from aquifers with a dominant fissure permeability ("Grès de la Cornalle", "Gibloux-Delta" and "Rigi-Schüttung"). Its origin is supposed to be the mineral barite, which tends to precipitate in fractures. Therefore, high barium concentrations may indicate the presence of fracture flow within the aquifer. Considerably high silicon contents are linked to the quartzitic and fine grained aquifers of the brackish marine molasse in Bavaria. Both, petrographical composition and slow flow rate are favouring the water-rock interaction. Caracteristic lithium footprints are found in several waters, as in the aquifers composed of the "Glimmersande", the gypse-bearing molasse, the Rigi-conglomerates, the brackish and the estuarine marine molasse. Chromium strongly marks the waters originating from the Swiss marine Molasse aquifers. It is probably related to ophiolithic detritus derived from the flysch of the Prealpes. A couple of waters show weak anomalies of cobalt, which are nevertheless intimately linked to the presence of ophiolithic components in the sediments. Cobalt might be used as a hydrostratigraphical tool to identify greenstone inputs. Analysed colloidal aluminum may serve as a hydrodynamical parameter, indicating microturbidity within the aquifer. High amounts of aluminum varying in time, have been found in estuarin deposits of the OMM. Generally speaking, we propose three main origins of trace elements in the spring water of the Molasse basin: presence of certain petrographical components within the sediments such as basic and ultrabasic rocks, heavy minerals and evaporites. a small flow rate through interstitial porosity of fine grained sediments, favouring water-rock interaction. the abundance of colloidal material in the waters which depends on the petrographical composition of the aquifer and on sample treatment, e.g. filtration techniques. Deep groundwater network A second observation network composed of 21 borehole waters has been added for comparison. Compared to the subsurface waters, deep water chemistry might differ. The following reasons seem to be responsible: Long residence times of water in the underground favours slow reaction kinetics. Chemistry of very deep water can be influenced by mixing with older formation waters. Most of the deep boreholes in the Swiss Molasse basin are situated in the OMM and therefore represent a likely homogenous lithology. Borehole waters, because of different aquifer rock types and unknown surface and borehole influences, are least likely to represent typical Molasse water composition.

EPFL1995

Chargement

Assessment of bioremediation potential and monitoring of biological reductive dechlorination in sites contaminated with chlorinated ethenes

Christof Holliger, Pierre Rossi, Sonia Estelle Tarnawski

Chlorinated ethenes (CEs), such as perchloroethene (PCE) and trichloroethene, are one of the most common classes of groundwater contaminants. In this project, the contaminant biodegradation capacities of two aquifers, presenting both dichloroethene (DCE) and vinyl chloride (VC) accumulation, was carried out. Aquifers are considered nowadays as dynamic ecosystems, showing multiple interactions between the physical, chemical and biotic components. In this sense, an integrative methodology using multivariate statistics and combining together bacterial community structures, detection of dechlorinating bacteria and genes, and water geochemical data were used to investigate these aquifers. Results from multifactorial analysis of data collected from a PCE-contaminated site in Switzerland (25 groundwater samples) showed that manganese reduction (MR) was a key terminal electron accepting process, suggesting a potential competition between MR and DCE degradation to VC and ethene. Dehalococcoides sp. and VC reductive dehalogenase genes were detected but ethene concentration was below 0.007mg/L. Potential for a complete natural biodegradation of PCE was present in this aquifer. However, DCE reduction is strongly inhibited under local conditions as long as oxidized manganese resources are present. The second site located in Czech Republic (Velamos) and sampled at 7 different dates (35 groundwater samples) was under an active biostimulation process. Multifactorial analysis showed that successive cheese whey injections modified the aquifer habitat that became favourable not only for a complete dechlorination, but also for sulfate reduction (SR) and methanogenesis. DCE and VC accumulated along with the production of ethene, methane and hydrogen sulphide, indicating a competition between CEs dechlorination and SR and methanogenesis. This possibly explained the transitional slower reaction of CEs dechlorination observed during the remediation process. In conclusion, the used methodology allowed evaluation of the bioremediation potential present in contaminated aquifers and monitoring biostimulation processes.

2014

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Typologie des eaux souterraines de la molasse entre Chambéry et Linz (France, Suisse, Allemagne, Autriche)

EPFL1995

EPFL2004

Assessment of bioremediation potential and monitoring of biological reductive dechlorination in sites contaminated with chlorinated ethenes

Christof Holliger, Pierre Rossi, Sonia Estelle Tarnawski

2014