Connecting bacterial colonization to physical and biochemical changes in a sand box infiltration experiment

Rubol, S.; Freixa, Anna; Brangarí, Albert C.; Fernàndez-García, Daniel; Romaní, Anna M.; Sánchez-Vila, Xavier

doi:10.1016/j.jhydrol.2014.05.041

Cited by 40 publications

(32 citation statements)

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“…At both probe positions the mean temperatures in phases III and IV, when most substrate was available and metabolized by P. fluorescens in the sand of the SSC were significantly higher than in phase I, II and V, when less soluble organic material was supplied in the medium for respiration. An increased temperature in a sand box experiment of 0.5 -1 °C during respiration of pollutants was also observed by [45]. In the SSC experiment the temperature changes resulted from bacterial heat production during respiration and presumably decreasing heat losses by a decreasing evaporation during accumulation of EPS.…”

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confidence: 69%

“…Single aspects of biofilm formation have been reviewed previously by [43], covering among others the changes of the "morphological structure of the extracellular polymeric substances (EPS) matrix under varying hydration states, its role in maintenance of aquatic microhabitats and facilitating nutrient diffusion under desiccated conditions, and potential modification of macroscopic hydrologic properties of host porous media". Biofilm formation by a mixed population of soil bacteria and flow characteristics during vertical infiltration of slightly polluted water in the low mg/L-range, into a water-saturated soil of 1.2 m depth in a lysimeter was investigated by [45]. Microbial processes in the heterogeneous soil of the lysimeter apparently reduced the infiltration rate.…”

Section: Introductionmentioning

confidence: 99%

“…Whereas mainly aerobic bacteria, fungi and protozoa colonize soil surface layers, the proportion of mainly anaerobic bacteria (most of them are "fermenters") and of Actinomycetes increases with depth in the underground in the vicinity and below the groundwater table. These population changes are accompanied by a significantly decreasing diversity of microorganisms [17] and by a decrease of physiological functions [45]. Groundwater bacteria tend to form a biofilm on mineral surfaces of soil particles and may cause preferential flow paths or clogging in heterogeneous soil compartments [45].…”

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confidence: 99%

“…These population changes are accompanied by a significantly decreasing diversity of microorganisms [17] and by a decrease of physiological functions [45]. Groundwater bacteria tend to form a biofilm on mineral surfaces of soil particles and may cause preferential flow paths or clogging in heterogeneous soil compartments [45]. In contrast aerobic motile bacteria can even move into the top zone of the capillary fringe (CF, spanning from the groundwater table to still visible moisture above it in a quartz sand aquifer) above the water-saturated zone of quartz sand and form a dense biofilm in the still highly saturated interface region of the CF [31].…”

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confidence: 99%

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Influence of Increasing Concentrations of Organic Pollutants on Biofilm Formation and Flow Parameters in a Sand-aquifer and Its Capillary Fringe.

Jost¹,

Winter²,

Gallert³

2017

EPP

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Abstract. We followed the development of a Pseudomonas fluorescens biofilm on quartz sand in an instrumented horizontal flow-through stainless steel container (SSC) in lysimeter-scale, to investigate its impact on physical soil parameters within the aquifer and the capillary fringe (CF). Increasingly concentrated biodegradable substances in a liquid medium were pumped through the sand in the SSC creating an artificial aquifer. Biofilm development and its influence on flow parameters and oxygen concentration profiles, as well as temperature or water suction changes with time were determined. After more than 19 weeks of medium flow, at DOC concentrations of finally about 300 mg/L, P. fluorescens formed a strong biofilm and the highest biomass concentrations with up to 2.8 mg volatile solids per g dry sand were found in the transition zone of the CF. The soil temperature, which was slightly increased, or the water suction was significantly influenced during the experiment. The effects were strongest within the first 0.3 m of flow stretch, where the highest biomass values were detected. During the total experimental duration of 54 weeks the average flow velocity was reduced by up to 15 % due to clogging effects and the oxygen profiles were changed drastically. Results may be representative for real polluted aquifers. Keywords:Pseudomonas fluorescens, sand aquifer, capillary fringe, soil contamination, biofilm formation, biological clogging. IntroductionSoil and groundwater are naturally inhabited by a vast variety of prokaryotes. It was estimated that 2.5 x 10 29 microorganisms live in the top 8 m of the terrestrial subsurface and at least 2.5 x 10 30 microorganisms below 8 m depth, either suspended in the water phase or attached onto organic and mineral compounds of top soil and the underground [53]. Anaerobic bacteria in deep soil layers may ferment organic pollutants to mainly fatty acids whereas aerobic bacteria in upper soil layers may respire organic pollutants in the presence of oxygen to carbon dioxide and thus contribute to "clean-up". There seems to be a spatial heterogeneity of microorganisms. Whereas mainly aerobic bacteria, fungi and protozoa colonize soil surface layers, the proportion of mainly anaerobic bacteria (most of them are "fermenters") and of Actinomycetes increases with depth in the underground in the vicinity and below the groundwater table. These population changes are accompanied by a significantly decreasing diversity of microorganisms [17] and by a decrease of physiological functions [45]. Groundwater bacteria tend to form a biofilm on mineral surfaces of soil particles and may cause preferential flow paths or clogging in heterogeneous soil compartments [45]. In contrast aerobic motile bacteria can even move into the top zone of the capillary fringe (CF, spanning from the groundwater table to still visible moisture above it in a quartz sand aquifer) above the water-saturated zone of quartz sand and form a dense biofilm in the still highly saturated interface region of the CF [31]. Biofi...

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confidence: 69%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Influence of Increasing Concentrations of Organic Pollutants on Biofilm Formation and Flow Parameters in a Sand-aquifer and Its Capillary Fringe.

Jost¹,

Winter²,

Gallert³

2017

EPP

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“…Because bacteria generally have diameters that range between 0.1 and 1 microns, the small effective porosity of clays typically restricts the ability of bacteria to move and reproduce effectively. Also, the natural occurrence of preferential flow channels in porous media (typically represented as a mobile region in the multirate model) favors the movement of groundwater and dissolved elements through certain pathways, which typically harbor larger bacterial densities and microbial activities compare to the adjacent porous media (Pivetz and Steenhuis, 1995;Mallawatantri et al, 1996;Rubol et al, 2014). In fact, Vinther et al (1999) and Bundt et al (2001) found that both substrate availability and nutrient supply are largest in preferential flow paths, enhancing bacterial biomass and associated microbial processes.…”

Section: Conceptual Modelmentioning

confidence: 99%

A random walk solution for modeling solute transport with network reactions and multi-rate mass transfer in heterogeneous systems: Impact of biofilms

Henri

Fernàndez-García

2015

Advances in Water Resources

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The interplay between the spatial variability of aquifer properties, mass transfer and chemical reactions often complicates reactive transport simulations. It is well documented that hydro-biochemical properties are ubiquitously heterogeneous and that rate-limited mass transfer typically leads to the conceptualization of an aquifer as a multi-porosity system. Within this context, chemical reactions taking place in mobile/immobile water regions can be substantially different between each other. This paper presents a particle-based method that can efficiently simulate heterogeneity, network reactions and multi-rate mass transfer. The approach is based on the development of transition probabilities that describe the likelihood that particles belonging to a given species and mobile/immobile domain at a given time will be transformed into another species and mobile/immobile domain afterwards. The joint effect of mass transfer and sequential degradation is shown to be non-trivial. A characteristic double peak of daughter products occurs when the degradation capacity in the immobile domain is relatively small. This late rebound of concentrations is not driven by any change in the flow regime (e.g., pumping ceases in the pump-and-treat remediation strategy) but due to the natural interplay between mass transfer and chemical reactions. To illustrate that the method can simultaneously represent mass transfer, spatially varying properties and network reactions without numerical problems, we have simulated the degradation of tetrachloroethylene (PCE) in a three-dimensional fully heterogeneous aquifer subjected to rate-limited mass transfer. Two types of degradation modes were considered to compare the effect of an active biofilm with that of clay pods present in the aquifer. Results of the two scenarios display significantly differences. Biofilms that promote the degradation of compounds in an immobile region are shown to significantly enhance degradation, rapidly producing daughter products and less tailing.

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A mechanistic model (BCC‐PSSICO) to predict changes in the hydraulic properties for bio‐amended variably saturated soils

Brangarí

Sánchez-Vila

Freixa

et al. 2017

Water Resources Research

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This is the peer reviewed version of the following article: [Carles Brangarí, A., X. Sanchez-Vila, A. Freixa, A. M. Romaní, S. Rubol, and D. Fernàndez-Garcia (2017), A mechanistic model (BCC-PSSICO) to predict changes in the hydraulic properties for bio-amended variably saturated soils, Water Resour. Res., 53, 93–109, doi:10.1002/2015WR018517], which has been published in final form at http://onlinelibrary.wiley.com/doi/10.1002/2015WR018517/abstract. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Self-Archiving.The accumulation of biofilms in porous media is likely to influence the overall hydraulic properties and, consequently, a sound understanding of the process is required for the proper design and management of many technological applications. In order to bring some light into this phenomenon we present a mechanistic model to study the variably saturated hydraulic properties of bio-amended soils. Special emphasis is laid on the distribution of phases at pore-scale and the mechanisms to retain and let water flow through, providing valuable insights into phenomena behind bioclogging. Our approach consists in modeling the porous media as an ensemble of capillary tubes, obtained from the biofilm-free water retention curve. This methodology is extended by the incorporation of a biofilm composed of bacterial cells and extracellular polymeric substances (EPS). Moreover, such a microbial consortium displays a channeled geometry that shrinks/swells with suction. Analytical equations for the volumetric water content and the relative permeability can then be derived by assuming that biomass reshapes the pore space following specific geometrical patterns. The model is discussed by using data from laboratory studies and other approaches already existing in the literature. It can reproduce (i) displacements of the retention curve toward higher saturations and (ii) permeability reductions of distinct orders of magnitude. Our findings also illustrate how even very small amounts of biofilm may lead to significant changes in the hydraulic properties. We, therefore, state the importance of accounting for the hydraulic characteristics of biofilms and for a complex/more realistic geometry of colonies at the pore-scale.Peer ReviewedPostprint (author's final draft

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Connecting bacterial colonization to physical and biochemical changes in a sand box infiltration experiment

Cited by 40 publications

References 58 publications

Influence of Increasing Concentrations of Organic Pollutants on Biofilm Formation and Flow Parameters in a Sand-aquifer and Its Capillary Fringe.

Influence of Increasing Concentrations of Organic Pollutants on Biofilm Formation and Flow Parameters in a Sand-aquifer and Its Capillary Fringe.

A random walk solution for modeling solute transport with network reactions and multi-rate mass transfer in heterogeneous systems: Impact of biofilms

A mechanistic model (BCC‐PSSICO) to predict changes in the hydraulic properties for bio‐amended variably saturated soils

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